Your search keyword '"Dongliang Cheng"' showing total 79 results

1. Histone deacetylase inhibition enhances extracellular vesicles from muscle to promote osteogenesis via miR-873-3p

Author

Ming Chen, Yi Li, Mingming Zhang, Siliang Ge, Taojin Feng, Ruijing Chen, Junmin Shen, Ran Li, Zhongqi Wang, Yong Xie, Duanyang Wang, Jiang Liu, Yuan Lin, Feifan Chang, Junyu Chen, Xinyu Sun, Dongliang Cheng, Xiang Huang, Fanfeng Wu, Qinxiang Zhang, Pingqiang Cai, Pengbin Yin, Licheng Zhang, and Peifu Tang

Subjects

Medicine, Biology (General), QH301-705.5

Abstract

Abstract Regular physical activity is widely recognized for reducing the risk of various disorders, with skeletal muscles playing a key role by releasing biomolecules that benefit multiple organs and tissues. However, many individuals, particularly the elderly and those with clinical conditions, are unable to engage in physical exercise, necessitating alternative strategies to stimulate muscle cells to secrete beneficial biomolecules. Histone acetylation and deacetylation significantly influence exercise-induced gene expression, suggesting that targeting histone deacetylases (HDACs) could mimic some exercise responses. In this study, we explored the effects of the HDAC inhibitor Trichostatin A (TSA) on human skeletal muscle myoblasts (HSMMs). Our findings showed that TSA-induced hyperacetylation enhanced myotube fusion and increased the secretion of extracellular vesicles (EVs) enriched with miR-873-3p. These TSA-EVs promoted osteogenic differentiation in human bone marrow mesenchymal stem cells (hBMSCs) by targeting H2 calponin (CNN2). In vivo, systemic administration of TSA-EVs to osteoporosis mice resulted in significant improvements in bone mass. Moreover, TSA-EVs mimicked the osteogenic benefits of exercise-induced EVs, suggesting that HDAC inhibition can replicate exercise-induced bone health benefits. These results demonstrate the potential of TSA-induced muscle-derived EVs as a therapeutic strategy to enhance bone formation and prevent osteoporosis, particularly for individuals unable to exercise. Given the FDA-approved status of various HDAC inhibitors, this approach holds significant promise for rapid clinical translation in osteoporosis treatment.

Published

2024

2. Trait divergence and opposite above- and below-ground strategies facilitate moso bamboo invasion into subtropical evergreen broadleaf forest

Author

Hua Yu, Xingui Le, Josep Peñuelas, Jordi Sardans, Chaobin Xu, Yuxing Zou, Xue Zhang, Conghui Li, Zhenwei Mao, Dongliang Cheng, and Quanlin Zhong

Subjects

moso bamboo (Phyllostachys edulis) invasion, trait divergence, phenotypic integration, conservation gradient, collaboration gradient, evergreen broadleaf forest, Plant culture, SB1-1110

Abstract

Understanding the invasion of moso bamboo (Phyllostachys edulis) into adjacent evergreen broadleaf forest based on functional traits is crucial due to its significant influence on ecosystem processes. However, existing research has primarily focused on above- or below-ground traits in isolation, lacking a comprehensive integration of both. In this study, we conducted a trait-based analysis including 23 leaf traits and 11 root traits in three forest types - bamboo forest, mixed bamboo and broadleaf forest, and evergreen broadleaf forest - to investigate trait differences, phenotypic integration, and above- and below-ground resource strategies in bamboo and broadleaf species. Our findings demonstrated significant differences in leaf and root key traits between bamboo and broadleaf species, strongly supporting the “phenotypic divergence hypothesis”. Bamboo exhibited stronger trait correlations compared to broadleaf species, indicating higher phenotypic integration. Above- and below-ground strategies were characterized by trade-offs rather than coordination, resulting in a multi-dimensional trait syndrome. Specifically, a unidimensional leaf economics spectrum revealed that bamboo with higher leaf N concentrations (LNC), P concentrations (LPC), and specific leaf area (SLA) adopted a “fast acquisitive” above-ground strategy, while broadleaf species with thicker leaves employed a “slow conservative” above-ground strategy. A two-dimensional root trait syndrome indicated a “conservation” gradient with bamboo adopting a “slow conservative” below-ground strategy associated with higher root tissue density (RTD), and broadleaf species exhibiting a “fast acquisitive” below-ground strategy linked to higher root N concentrations (RNC) and P concentrations (RPC), and a “collaboration” gradient probably ranging from broadleaf species with a “do-it-yourself” strategy characterized by high specific root length (SRL), to bamboo adopting an “outsourcing” strategy with thicker roots. In conclusion, key trait divergence from coexisting broadleaf species, higher phenotypic integration, and multi-dimensional opposite above- and below-ground resource strategies confer competitive advantages to moso bamboo, shedding light on the mechanistic understanding of its invasion into subtropical evergreen broadleaf forest and providing theoretical guidance for maintaining the stability of subtropical forest ecosystem.

Published

2024

3. Evaluating magnetic resonance imaging characteristics and risk factors for hemifacial spasm

Author

Bo Li, Chun Luo, Yabin Jin, Ying Yi, Dongliang Cheng, Linwen Huang, Guofu Wang, Xuguang Zhong, Hai Zhao, and Mingyong Gao

Subjects

facial nerve, hemifacial spasm, magnetic resonance imaging, neurovascular compression, Neurosciences. Biological psychiatry. Neuropsychiatry, RC321-571

Abstract

Abstract Purpose The specific neurovascular compression (NVC) event responsible for the symptomatic manifestation of hemifacial spasm (HFS) remains difficult to assess accurately using magnetic resonance imaging (MRI). We aim to evaluate the MRI characteristics of HFS. Method We retrospectively included patients with HFS and divided them into a test group (n = 186) and a validation group (n = 28). The presence, severity, and offending vessel type of NVC in each portion, and the orientation of the offending vessel around the facial nerve, were recorded. Conditional logistic regression analyses were performed to evaluate correlations using test group. The validation group was used to verify whether our findings improved diagnostic performance. Results Deformity in the proximal cisternal segment was significantly correlated with HFS occurrence (odds ratio [OR]: 256.58, p = .002), whereas contact was not (p = .233). Both contact and deformity in the root detachment point (OR: 19.98 and 37.22, p

Published

2024

4. Unraveling the spatial–temporal distribution patterns of soil abundant and rare bacterial communities in China’s subtropical mountain forest

Author

Panpan Wu, Dandan Hu, Jiaheng Guo, Jinlong Li, Quanlin Zhong, and Dongliang Cheng

Subjects

abundant bacteria, elevation, rare bacteria, season, soil physico-chemical properties, subtropical mountain ecosystems, Microbiology, QR1-502

Abstract

IntroductionThe pivotal roles of both abundant and rare bacteria in ecosystem function are widely acknowledged. Despite this, the diversity elevational patterns of these two bacterial taxa in different seasons and influencing factors remains underexplored, especially in the case of rare bacteria.MethodsHere, a metabarcoding approach was employed to investigate elevational patterns of these two bacterial communities in different seasons and tested the roles of soil physico-chemical properties in structuring these abundant and rare bacterial community.Results and discussionOur findings revealed that variation in elevation and season exerted notably effects on the rare bacterial diversity. Despite the reactions of abundant and rare communities to the elevational gradient exhibited similarities during both summer and winter, distinct elevational patterns were observed in their respective diversity. Specifically, abundant bacterial diversity exhibited a roughly U-shaped pattern along the elevation gradient, while rare bacterial diversity increased with the elevational gradient. Soil moisture and N:P were the dominant factor leading to the pronounced divergence in elevational distributions in summer. Soil temperature and pH were the key factors in winter. The network analysis revealed the bacteria are better able to adapt to environmental fluctuations during the summer season. Additionally, compared to abundant bacteria, the taxonomy of rare bacteria displayed a higher degree of complexity. Our discovery contributes to advancing our comprehension of intricate dynamic diversity patterns in abundant and rare bacteria in the context of environmental gradients and seasonal fluctuations.

Published

2024

5. Development of a novel combined nomogram model integrating deep learning radiomics to diagnose IgA nephropathy clinically

Author

Xiachuan Qin, Linlin Xia, Qianqing Ma, Dongliang Cheng, and Chaoxue Zhang

Subjects

IgA nephropathy, ultrasound, superb microvascular imaging, deep learning, radiomics, Diseases of the genitourinary system. Urology, RC870-923

Abstract

This study aimed to develop and validate a combined nomogram model based on superb microvascular imaging (SMI)-based deep learning (DL), radiomics characteristics, and clinical factors for noninvasive differentiation between immunoglobulin A nephropathy (IgAN) and non-IgAN. We prospectively enrolled patients with chronic kidney disease who underwent renal biopsy from May 2022 to December 2022 and performed an ultrasound and SMI the day before renal biopsy. The selected patients were randomly divided into training and testing cohorts in a 7:3 ratio. We extracted DL and radiometric features from the two-dimensional ultrasound and SMI images. A combined nomograph model was developed by combining the predictive probability of DL with clinical factors using multivariate logistic regression analysis. The proposed model’s utility was evaluated using receiver operating characteristics, calibration, and decision curve analysis. In this study, 120 patients with primary glomerular disease were included, including 84 in the training and 36 in the test cohorts. In the testing cohort, the ROC of the radiomics model was 0.816 (95% CI:0.663–0.968), and the ROC of the DL model was 0.844 (95% CI:0.717–0.971). The nomogram model combined with independent clinical risk factors (IgA and hematuria) showed strong discrimination, with an ROC of 0.884 (95% CI:0.773–0.996) in the testing cohort. Decision curve analysis verified the clinical practicability of the combined nomogram. The combined nomogram model based on SMI can accurately and noninvasively distinguish IgAN from non-IgAN and help physicians make clearer patient treatment plans.

Published

2023

6. Hepatocyte-targeting and tumor microenvironment-responsive liposomes for enhanced anti-hepatocarcinoma efficacy

Author

Dongliang Cheng, Zhiwei Wen, Hui Chen, Shiyuan Lin, Wei Zhang, Xin Tang, and Wei Wu

Subjects

Sodium taurocholate cotransporting polypeptide, matrix metalloproteinase-2, enzyme sensitive liposomes, liver targeting, hydroxycamptothecin, Therapeutics. Pharmacology, RM1-950

Abstract

To increase the antitumor drug concentration in the liver tumor site and improve the therapeutic effects, a functionalized liposome (PPP-LIP) with tumor targetability and enhanced internalization after matrix metalloproteinase-2 (MMP2)-triggered cell-penetrating peptide (TATp) exposure was modified with myrcludex B (a synthetic HBV preS-derived lipopeptide endowed with compelling liver tropism) for liver tumor-specific delivery. After intravenous administration, PPP-LIP was mediated by myrcludex B to reach the hepatocyte surface. The MMP2-overexpressing tumor microenvironment deprotected PEG, exposing it to TATp, facilitating tumor penetration and subsequent efficient destruction of tumor cells. In live imaging of small animals and cellular uptake, PPP-LIP was taken up much more than typical unmodified liposomes in the ICR mouse liver and liver tumor cells. Hydroxycamptothecin (HCPT)-loaded PPP-LIP showed a better antitumor effect than commercially available HCPT injections among MTT, three-dimensional (3 D) tumor ball, and tumor-bearing nude mouse experiments. Our findings indicated that PPP-LIP nanocarriers could be a promising tumor-targeted medication delivery strategy for treating liver cancers with elevated MMP2 expression.

Published

2022

7. 'Diminishing returns' and leaf area-biomass scaling of ferns in subtropical ecosystems

Author

Shubing Chen, Jinlong Li, Jun Sun, Quanlin Zhong, Dandan Hu, and Dongliang Cheng

Subjects

leaf area-biomass relationship, diminishing returns hypothesis, elevation, subtropical ecosystem, ferns, Plant culture, SB1-1110

Abstract

Foliage leaves are the primary photosynthetic organ of the majority of vascular plants, and their area vs. biomass scaling relationships provide valuable insights into the capacity and investment in light interception, which is critical to plant growth and performance. The “diminishing returns” hypothesis (DRH), which is based primarily on data from gymnosperms and angiosperms, posits that leaf (lamina) area scales with leaf dry mass. on average with a scaling exponent less than 1.0. However, it remains uncertain whether DRH applies to ferns or whether ecological factors affect the scaling exponents governing fern leaf morphometrics. To address this issue, 182 individuals of 28 subtropical ferns species were studied at low, medium, and high elevations (i.e., 600 m, 900 m, and 1200 m, respectively) in Mount Wuyi National Park, Jiangxi Province, China. The scaling relationships between leaf area and leaf biomass for individual and total leaf of ferns at different elevations were examined by using standardized major axis regression protocols. Analyses of the 28 fern species (using Blomberg K-value protocols) indicated no phylogenetic biases among the species compositions of the three different elevations. In addition, at the individual plant level, individual leaf area (ILA) did not differ significantly among the three different elevations (P > 0.05). However, individual leaf mass (ILM) was significantly higher at 900m than at 1200m (P < 0.05), resulting in a significantly higher leaf mass per area (LMA) at the 900m elevation than at the 600m and 1200m elevations (P < 0.05). The ILA and ILM at the 900m elevation were significantly higher than at the 600m elevation (P < 0.05). At the species level, ILA and ILM did not differ significantly among the three elevations (P > 0.05). The total leaf area per individual (TLA) did not differ significantly across the different elevations (P > 0.05). However, total leaf mass per individual (TLM) did differ significantly (P < 0.05). At the individual plant level, the scaling exponents for ILA vs. ILM and TLA vs. TLM at the three different elevations were all significantly less than 1.0 (P < 0.05), which was consistent with the DRH. At the species level, the scaling exponents for the ILA vs. ILM were significantly less than 1.0 at the middle and high elevations, but not at the low elevation. The scaling exponents of the TLA and TLM were numerically highest in the middle elevation, and all were less than 1.0 for the three elevations. These results indicate that the scaling relationships of leaf area versus mass of subtropical ferns at different elevations support the DRH hypothesis. The study further informs our understanding of the resource allocation strategies of an ancient and diverse plant lineage.

Published

2023

8. The morphology and nutrient content drive the leaf carbon capture and economic trait variations in subtropical bamboo forest

Author

Jun Sun, Jinlong Li, Kohei Koyama, Dandan Hu, Quanlin Zhong, and Dongliang Cheng

Subjects

bamboo, leaf economic traits, trade-off, subtropical, allometric, Plant culture, SB1-1110

Abstract

Carbon absorption capability and morphological traits are crucial for plant leaf function performance. Here, we investigated the five bamboos at different elevations in Wuyi Mountain to clarify how the leaf trait responds to the elevational gradient and drives the photosynthetic capacity variations. The Standardized Major Axis Regression (SMA) analyses and the Structural Equation Model (SEM) are applied to identify how the bamboo leaf trait, including the ratio of leaf width to length (W/L), leaf mass per area (LMA), photosynthesis rates (Pn), leaf nitrogen, and phosphorus concentration (Leaf N and Leaf P) response to elevation environment, and the driving mechanism of Pn changes. Across the five bamboo species, our results revealed that leaf P scaled isometrically with respect to W/L, leaf N scaled allometrically as the 0.80-power of leaf P, and leaf N and leaf P scaled allometrically to Pn, with the exponents of 0.58 and 0.73, respectively. Besides, the SEM result showed altitude, morphological trait (W/L and LMA), and chemical trait (leaf N and leaf P) could together explain the 44% variations of Pn, with a standard total effect value of 70.0%, 38.5%, 23.6% to leaf P, leaf N, and W/L, respectively. The five bamboo species along the different elevational share an isometric scaling relationship between their leaf P and W/L, providing partial support for the general rule and operating between morphological and chemical traits. More importantly, the leaf W/L and leaf P as the main trait that affects leaf area and P utilization in growth and thus drives bamboo leaf photosynthetic capacity variations in different elevations.

Published

2023

9. Numerical and theoretical investigations of the effect of the gangue-coal density ratio on the drawing mechanism in longwall top-coal caving

Author

Jinwang Zhang, Dongliang Cheng, Yinchao Yang, Weijie Wei, Zhaolong Li, and Zhengyang Song

Subjects

Longwall top-coal caving, Gangue-coal density ratio, Drawing body, Top-coal boundary, Recovery of top coal, Mining engineering. Metallurgy, TN1-997

Abstract

Abstract Discrete element calculations of the top-coal drawing process for different gangue-coal density ratios were conducted to investigate the effect of the gangue-coal density ratio on the drawing mechanism in longwall top-coal caving. The effects were analyzed for the drawing body, the top-coal boundary, and the recovery of top coal. The results show that for increasing density ratio, the initial drawing body on the goaf side is farther away from the drawing support and its width and volume gradually increase. The upper part of the sickle-shaped drawing body extends near the initial drawing body with increasing density ratio in the normal cycling stage, and the distance from the drawing body to the initial drawing body is its maximum width. The larger the density ratio, the smaller the height of the top coal above the goaf at the end of the initial drawing process. The height of the top-coal boundary decreases with increasing density ratio, until it reaches a limit. In a normal cycle, due to hysteretic development, the top-coal boundary moves toward the goaf until the density ratio is approximately 2.0, which is consistent with the physical experiment results. Finally, increasing the advance length of the working face is beneficial for increasing the overall recovery of top coal.

Published

2022

10. Biomimetic nanomaterial-facilitated oxygen generation strategies for enhancing tumour treatment outcomes

Author

Zhongwen Yang, Changsong Shi, Dongliang Cheng, Yu Wang, Yan Xing, Fanfan Du, Fangfang Wu, Yao Jin, Yueli Dong, and Mengli Li

Subjects

tumour hypoxia, nanomaterials, biomimetics, tumour microenvironment, tumour treatment, Biotechnology, TP248.13-248.65

Abstract

Hypoxia, as a typical hallmark of the tumour microenvironment (TME), has been verified to exist in most malignancies and greatly hinders the outcome of tumour treatments, including chemotherapy, photodynamic therapy, radiotherapy, and immunotherapy. Various approaches to alleviate tumour hypoxia have been reported. Among them, biomimetic nanomaterial-facilitated tumour oxygenation strategies, based on the engagement of human endogenous proteins, red blood cells, the cell membrane, and catalase, are the most impressive due to their excellent tumour active-targeting ability and superior tumour-selective capability, which, however, have not yet been systematically reviewed. Herein, we are ready to describe the current progress in biomimetic nanomaterial-facilitated tumour oxygenation strategies and corresponding improvements in tumour treatment outputs. In this review, the underlying mechanism behind the superior effect of these biomimetic nanomaterials, compared with other materials, on alleviating the hypoxic TME is highlighted. Additionally, the ongoing problems and potential solutions are also discussed.

Published

2022

11. The value of oxygen index and base excess in predicting the outcome of neonatal acute respiratory distress syndrome

Author

Hui Wu, Xiaoyang Hong, Yangming Qu, Zhenqiu Liu, Zhe Zhao, Change Liu, Qiong Ji, Jie Wang, Quan Xueli, Sun Jianwei, Dongliang Cheng, Zhi-Chun Feng, and Shi Yuan

Subjects

Acute respiratory distress syndrome, Newborn, Oxygen index, Base excess, Predictor, Pediatrics, RJ1-570

Abstract

Objective: This study aimed to identify the predictors and threshold of failure in neonatal acute respiratory distress syndrome. Methods: Newborns with severe acute respiratory distress syndrome aged 0–28 days and gestational age ≥36 weeks were included in the study if their cases were managed with non-extra corporal membrane oxygenation treatments. Patients were divided into two groups according to whether they died before discharge. Predictors of non-extra corporal membrane oxygenation treatment failure were sought, and the threshold of predictors was calculated. Results: A total of 103 patients were included in the study. A total of 77 (74.8%) survived hospitalization and were discharged, whereas 26 (25.2%) died. Receiver operating characteristic analysis of oxygen index, pH, base excess, and combinations of these indicators demonstrated the advantage of the combination of oxygen index and base excess over the others variables regarding their predictive ability. The area under the curve for the combination of oxygen index and base excess was 0.865. When the cut-off values of oxygen index and base excess were 30.0 and −7.4, respectively, the sensitivity and specificity for predicting death were 77.0% and 84.0%, respectively. The model with base excess added a net reclassification improvement of 0.090 to the model without base excess. Conclusion: The combination of oxygen index and base excess can be used as a predictor of outcomes in neonates receiving non-extra corporal membrane oxygenation treatment for acute respiratory distress syndrome. In neonates with acute respiratory distress syndrome, if oxygen index >30 and base excess

Published

2021

12. Estrogen Mediates an Atherosclerotic-Protective Action via Estrogen Receptor Alpha/SREBP-1 Signaling

Author

Fei Xie, Xiandong Li, Yue Xu, Dongliang Cheng, Xianru Xia, Xi Lv, Guolin Yuan, and Chunyan Peng

Subjects

estrogen, estrogen receptor α, SREBP-1, atherosclerosis, dyslipidemia, Diseases of the circulatory (Cardiovascular) system, RC666-701

Abstract

Menopause is associated with dyslipidemia and an increased risk of cardiovascular disease, the underlying mechanism of dyslipidemia is attributed to an insufficiency of estrogen. In this study, we find that estrogen mediates an atherosclerotic-protective action via estrogen receptor alpha/SREBP-1 signaling. Increased lipid accumulation and low-density lipoprotein (LDL)-uptake in HepG2 cells and THP-1 macrophages were induced by treatment of mixed hyperlipidemic serum from postmenopausal women; 17β-estradiol [estrogen (E2)] (10 nM) administration significantly improved hyperlipidemic profiles, relieved fatty-liver damage and attenuated the plaque area in the heart chamber of high-fat diet (HFD)-fed ovariectomized (OVX) ApoE–/– mice. Expression of sterol regulatory element-binding protein (SREBP)-1 mRNA of circulating leukocytes in postmenopausal women was strongly correlated to the serum E2 level. Exploration of data from the Gene Expression Profiling Interactive Analysis (GEPIA) database revealed that expression of SREBP-1 protein correlated to expression of estrogen receptor (ESR)α protein in the liver, blood and in normal tissue. Genetic overexpression/inhibition of ESRα resulted in increased/decreased SREBP-1 expression as well as attenuated/deteriorated lipid deposition in vitro. An inhibitor of the protein kinase B/mammalian target of rapamycin (AKT/mTOR) pathway, AZD8055, abolished ESRα-induced SREBP-1 expression in HepG2 cells. Moreover, E2 and statin co-treatment significantly reduced lipid accumulation in vitro and hindered the progression of atherosclerosis and fatty-liver damage in OVX ApoE–/– mice. Collectively, our results suggest that estrogen could exerted its atherosclerotic-protective action via ESRα/SREBP-1 signaling. E2 might enhance the cellular sensitivity of statins and could be used as a novel therapeutic strategy against atherosclerotic disorders in postmenopausal women.

Published

2022

13. Landscape ecological risk projection based on the PLUS model under the localized shared socioeconomic pathways in the Fujian Delta region

Author

Shihe Zhang, Quanlin Zhong, Dongliang Cheng, Chaobin Xu, Yunni Chang, Yuying Lin, and Baoyin Li

Subjects

Landscape ecological risk, PLUS model, Localized shared socioeconomic pathways, Muti-scenario projection, Fujian Delta region, Ecology, QH540-549.5

Abstract

Social-economic development and urbanization greatly modify landscape patterns and their associated ecological processes at regional scales, resulting in serious landscape ecological risk (LER). Effectively evaluating the LER is the basis for sustainable land use and development of regions. Because of the uncertainties in future socioeconomic development, precisely projecting future LER distribution is still challenging. To overcome this weakness, by using the Fujian Delta region as a case study, we employed patch-generating land use simulation (PLUS) model coupled with multiple linear regression and a Markov chain model to project the landscape patterns in 2050. The Shared Socioeconomic Pathways (SSPs) proposed by the Intergovernmental Panel on Climate Change (IPCC) were selected as the scenario framework. Thus, the spatiotemporal characteristics of the landscape pattern changes and LER from 2000 to 2020 and the projections for 2050 under different localized SSPs scenarios were explored. The results show that the cropland and water areas changed remarkably during 2000–2020. The PLUS model based on the couple of multiple linear regression and Markov chain model has higher prediction accuracy (FoM = 0.244) than that without the multiple linear regression (FoM = 0.146). The simulation results show that the urban land continued to expand westward and northward in 2050. Large amounts of cropland will be transformed into urban land in the eastern part. The conversion area is the largest under the SSP2 scenario, and the smallest area occurs under the SSP4 scenario. From 2000 to 2020, the LER exhibited the characteristics of an east–west polarized spatial distribution, and the LER gradually increased. The localized SSP4 scenario is projected to have the largest LER, and the smallest LER occurs under the SSP1 scenario. The conversions from cropland to urban land will lead to the most significant increases in LER, followed by the conversion of grassland to urban land.

Published

2022

14. Thermal Acclimation of Foliar Carbon Metabolism in Pinus taiwanensis Along an Elevational Gradient

Author

Min Lyu, Mengke Sun, Josep Peñuelas, Jordi Sardans, Jun Sun, Xiaoping Chen, Quanlin Zhong, and Dongliang Cheng

Subjects

carbon metabolism, climate change, thermal acclimation, temperature sensitivity, Pinus taiwanensis, Plant culture, SB1-1110

Abstract

Climate change could negatively alter plant ecosystems if rising temperatures exceed optimal conditions for obtaining carbon. The acclimation of plants to higher temperatures could mitigate this effect, but the potential of subtropical forests to acclimate still requires elucidation. We used space-for-time substitution to determine the photosynthetic and respiratory-temperature response curves, optimal temperature of photosynthesis (Topt), photosynthetic rate at Topt, temperature sensitivity (Q10), and the rate of respiration at a standard temperature of 25°C (R25) for Pinus taiwanensis at five elevations (1200, 1400, 1600, 1800, and 2000 m) in two seasons (summer and winter) in the Wuyi Mountains in China. The response of photosynthesis in P. taiwanensis leaves to temperature at the five elevations followed parabolic curves, and the response of respiration to temperature increased with temperature. Topt was higher in summer than winter at each elevation and decreased significantly with increasing elevation. Q10 decreased significantly with increasing elevation in summer but not winter. These results showed a strong thermal acclimation of foliar photosynthesis and respiration to current temperatures across elevations and seasons, and that R25 increased significantly with elevation and were higher in winter than summer at each elevation indicating that the global warming can decrease R25. These results strongly suggest that this thermal acclimation will likely occur in the coming decades under climate change, so the increase in respiration rates of P. taiwanensis in response to climatic warming may be smaller than predicted and thus may not increase atmospheric CO2 concentrations.

Published

2022

15. The Leaf Economics Spectrum Constrains Phenotypic Plasticity Across a Light Gradient

Author

Xiaoping Chen, Jun Sun, Mantang Wang, Min Lyu, Karl J. Niklas, Sean T. Michaletz, Quanlin Zhong, and Dongliang Cheng

Subjects

leaf functional traits, within-canopy, plasticity, sun and shade-leaves, convergent LES relationships, Plant culture, SB1-1110

Abstract

The leaf economics spectrum (LES) characterizes multivariate correlations that confine the global diversity of leaf functional traits onto a single axis of variation. Although LES is well established for traits of sun leaves, it is unclear how well LES characterizes the diversity of traits for shade leaves. Here, we evaluate LES using the sun and shade leaves of 75 woody species sampled at the extremes of a within-canopy light gradient in a subtropical forest. Shading significantly decreased the mean values of LMA and the rates of photosynthesis and dark respiration, but had no discernable effect on nitrogen and phosphorus content. Sun and shade leaves manifested the same relationships among Nmass, Pmass, Amass, and Rmass (i.e., the slopes of log–log scaling relations of LES traits did not differ between sun and shade leaves). However, the difference between the normalization constants of shade and sun leaves was correlated with functional trait plasticity. Although the generality of this finding should be evaluated further using larger datasets comprising more phylogenetically diverse taxa and biomes, these findings support a unified LES across shade as well as sun leaves.

Published

2020

16. Coupling Coordination Analysis and Prediction of Landscape Ecological Risks and Ecosystem Services in the Min River Basin

Author

Shihe Zhang, Quanlin Zhong, Dongliang Cheng, Chaobin Xu, Yunni Chang, Yuying Lin, and Baoyin Li

Subjects

landscape fragmentation, patch-generating land use simulation (PLUS) model, shared socioeconomic pathways, multiple-scenario, Min River Basin, Agriculture

Abstract

Watershed landscape ecological security and ecosystem service functions are the material basis and environmental guarantee for promoting socioeconomic development. Analyzing the spatiotemporal characteristics of landscape ecological risks (LERs) and ecosystem services (ESs) and exploring the coupling coordination relationship between the two are of great significance for promoting the construction of ecological civilization and achieving sustainable development in the watershed. With the Min River Basin as the study area, the landscape ecological risk assessment, Integrated Valuation of Ecosystem Services and Tradeoffs (InVEST), and Carnegie Ames–Stanford Approach (CASA) models were used to evaluate the LERs and ESs based on the shared socioeconomic pathways (SSPs), and the patch-generating land use simulation (PLUS) model was used to predict the land use distribution of the Min River Basin in 2030. On this basis, the coupling coordination degree model was used to explore the coupling coordination relationship between the LERs and ESs. The results show that, from 2000 to 2020, the LER of the Min River Basin gradually decreased, and the overall spatial distribution pattern was “high in the north and low in the south”. The ES of the Min River Basin initially decreased and then increased, showing a spatial distribution pattern of “low in the south and high in the north”. Among the SSPs in 2030, the LER is the largest under the SSP3 scenario and the smallest under the SSP4 scenario. The ES improvement is the most significant under the SSP1 scenario and the lowest under the SSP3 scenario. From 2000 to 2030, the coupling coordination degree of the Min River Basin first decreased and then increased, showing a spatial distribution pattern of “high in the south and low in the north”. Among the five SSPs, the coupling coordination degree was the highest under SSP1. The spatial distribution of urban area is the main driving factor affecting the coupling coordination relationship between the LER and ES, and the development of social and economy is the beginning of landscape pattern optimization.

Published

2022

17. Stem Diameter (and Not Length) Limits Twig Leaf Biomass

Author

Jun Sun, Mantang Wang, Min Lyu, Karl J. Niklas, Quanlin Zhong, Man Li, and Dongliang Cheng

Subjects

allometry, annual growth, biomass allocation, elevation gradient, forest types, isometry, Plant culture, SB1-1110

Abstract

The relationship between leaf and stem biomass as well as the relationship between leaf biomass and stem length and diameter are important to our understanding of a broad range of important plant scaling relationship because of their relationship to photosynthesis and thus growth. To understand how twig architecture (i.e., current year leaves, and stem diameter and length) affects stem diameter and length, and leaf number and biomass, we examined the twigs of 64 woody species collected from three forest types along an elevational gradient in the Wuyi Mountains, Jiangxi Province, China. We also compared the scaling relationships we observed with biomass allocation patterns reported at the whole tree level. Our results revealed isometric relationship between leaf and stem biomass on twigs despite differences in forest communities and despite changes in environmental factors along an elevational gradient. Across the 64 species, from twigs to individual trees, leaf biomass scaled approximately as the 2.0-power of stem diameter (but not for stem length or leaf number). These results help to identify a general rule that operates at two different levels of biological organization (twigs and whole trees). The scaling relationship between leaf biomass and stem diameter in twigs is insensitive to differences in species composition, elevation, or forest type. We speculate that this rule emerges because stem diameter serves as a proxy for the amount of resources supplied per unit cross section to developing leaves and for the flow of photosynthates from mature leaves to the rest of the plant body.

Published

2019

18. Fumed SiO2-H2SO4-PVA Gel Electrolyte CO Electrochemical Gas Sensor

Author

Yuhang Zhang, Dongliang Cheng, Zicheng Wu, Feihu Li, Fang Fang, and Zili Zhan

Subjects

fumed SiO2, gel electrolyte, electrochemical sensor, CO gas sensor, Biochemistry, QD415-436

Abstract

The conventional CO electrochemical gas sensor uses aqueous H2SO4 solution as electrolyte, with inevitable problems, such as the drying and leakage of electrolyte. Thus, research on new alternative electrolytes is an attractive field in electrochemical gas sensors. In this paper, the application of a new fumed SiO2 gel electrolyte was studied in electrochemical gas sensors. The effects of fumed SiO2 and H2SO4 contents on the performance of the CO gas sensor were investigated. The results showed that the optimized composition of the SiO2 gel electrolyte was 4.8% SiO2, 38% H2SO4, and 0.005% polyvinyl alcohol (PVA). Compared with aqueous H2SO4, the gel electrolyte had better water retention ability. The signal current of the sensor was proportional to the CO concentration. The sensitivity to CO was 78.6 nA/ppm, and the response and recovery times were 31 and 38 s, respectively. The detection limit was 2 ppm. The linear range was from 2 to 500 ppm. The gel electrolyte CO sensor possesses equivalent performance to that with aqueous electrolyte.

Published

2020

19. Scaling relationships of twig biomass allocation in Pinus hwangshanensis along an altitudinal gradient.

Author

Man Li, Yuan Zheng, RuiRui Fan, QuanLin Zhong, and DongLiang Cheng

Subjects

Medicine, Science

Abstract

Understanding the response of biomass allocation in twigs (the terminal branches of current-year shoots) to environmental change is crucial for elucidating forest ecosystem carbon storage, carbon cycling, and plant life history strategies under a changing climate. On the basis of interspecies investigations of broad-leaved plants, previous studies have demonstrated that plants respond to environmental factors by allocating biomass in an allometric manner between support tissues (i.e., stems) and the leaf biomass of twigs, where the scaling exponent (i.e., slope of a log-log linear relationship, α) is constant, and the scaling constant (i.e., intercept of a log-log linear relationship, log β) varies with respect to environmental factors. However, little is known about whether the isometric scaling exponents of such biomass allocations remain invariant for single species, particularly conifers, at different altitudes and in different growing periods. In this study, we investigated how twig biomass allocation varies with elevation and period among Pinus hwangshanensis Hsia trees growing in the mountains of Southeast China. Specifically, we explored how twig stem mass, needle mass, and needle area varied throughout the growing period (early, mid-, late) and at three elevations in the Wuyi Mountains. Standardized major axis analysis was used to compare the scaling exponents and scaling constants between the biomass allocations of within-twig components. Scaling relationships between these traits differed with growing period and altitude gradient. During the different growing periods, there was an isometric scaling relationship, with a common slope of 1.0 (i.e., α ≈ 1.0), between needle mass and twig mass (the sum of the total needle mass and the stem mass), whereas there were allometric scaling relationships between the stem mass and twig mass and between the needle mass and stem mass of P. hwangshanensis. The scaling constants (log β) for needle mass vs. twig mass and for needle mass vs. stem mass increased progressively across the growing stages, whereas the scaling constants of stem mass vs. twig mass showed the opposite pattern. The scaling exponents (α) of needle area with respect to needle biomass increased significantly with growing period, changing from an allometric relationship (i.e., α < 1.0) during the early growing period to a nearly isometric relationship (i.e., α ≈ 1.0) during the late growing period. This change possibly reflects the functional adaptation of twigs in different growing periods to meet their specific reproductive or survival needs. At different points along the altitudinal gradient, the relationships among needle mass, twig mass, and stem mass were all isometric (i.e., α ≈ 1.0). Moreover, significant differences were found in scaling constants (log β) along the altitudinal gradient, such that species had a smaller stem biomass but a relatively larger needle mass at low altitude. In addition, the scaling exponents remained numerically invariant among all three altitudes, with a common slope of 0.8, suggesting that needle area failed to keep pace with the increasing needle mass at different altitudes. Our results indicated that the twig biomass allocation pattern was significantly influenced by altitude and growing period, which reflects the functional adaptation of twigs to meet their specific survival needs under different climatic conditions.

Published

2017

20. Short-Term Nitrogen Addition Does Not Significantly Alter the Effects of Seasonal Drought on Leaf Functional Traits in Machilus pauhoi Kanehira Seedlings

Author

Hua Yu, Dongliang Cheng, Baoyin Li, Chaobin Xu, Zhongrui Zhang, Yaqi Zhong, and Quanlin Zhong

Subjects

leaf functional trait, seasonal drought, short-term N deposition, additive effect, soil properties, M. pauhoi Kanehira seedling, Plant ecology, QK900-989

Abstract

Research Highlights: Short-term nitrogen (N) addition did not significantly alter the effects of seasonal drought on the leaf functional traits in Machilus pauhoi Kanehira seedlings in N-rich subtropical China. Background and Objectives: Seasonal drought and N deposition are major drivers of global environmental change that affect plant growth and ecosystem function in subtropical China. However, no consensus has been reached on the interactive effects of these two drivers. Materials and Methods: We conducted a full-factorial experiment to analyze the single and combined effects of seasonal drought and short-term N addition on chemical, morphological and physiological traits of M. pauhoi seedlings. Results: Seasonal drought (40% of soil field capacity) had significant negative effects on the leaf N concentrations (LNC), phosphorus (P) concentrations (LPC), leaf thickness (LT), net photosynthetic rate (A), transpiration rate (E), stomatal conductance (Gs), and predawn leaf water potential (ψPD), and significant positive effects on the carbon:N (C:N) ratio and specific leaf area (SLA). Short-term N addition (50 kg N·hm−2·year−1 and 100 kg N·hm−2·year−1) tended to decrease the C:N ratio and enhance leaf nutrient, growth, and photosynthetic performance because of increased LNC, LPC, LT, leaf area (LA), SLA, A, E, and ψPD; however, it only had significant effects on LT and Gs. No significant interactive effects on leaf traits were detected. Seasonal drought, short-term N addition, and their interactions had significant effects on soil properties. The soil total C (STC), nitrate N (NO3−-N) and soil total N (STN) concentrations were the main factors that affected the leaf traits. Conclusions: Seasonal drought had a stronger effect on M. pauhoi seedling leaf traits than short-term N deposition, indicating that the interaction between seasonal drought and short-term N deposition may have an additive effecton M. pauhoi seedling growth in N-rich subtropical China.

Published

2019

21. Plant Photosynthesis-Irradiance Curve Responses to Pollution Show Non-Competitive Inhibited Michaelis Kinetics.

Author

Maozi Lin, Zhiwei Wang, Lingchao He, Kang Xu, Dongliang Cheng, and Genxuan Wang

Subjects

Medicine, Science

Abstract

Photosynthesis-irradiance (PI) curves are extensively used in field and laboratory research to evaluate the photon-use efficiency of plants. However, most existing models for PI curves focus on the relationship between the photosynthetic rate (Pn) and photosynthetically active radiation (PAR), and do not take account of the influence of environmental factors on the curve. In the present study, we used a new non-competitive inhibited Michaelis-Menten model (NIMM) to predict the co-variation of Pn, PAR, and the relative pollution index (I). We then evaluated the model with published data and our own experimental data. The results indicate that the Pn of plants decreased with increasing I in the environment and, as predicted, were all fitted well by the NIMM model. Therefore, our model provides a robust basis to evaluate and understand the influence of environmental pollution on plant photosynthesis.

Published

2015

22. Development of a magnetic resonance imaging-derived radiomics model to predict microvascular invasion in patients with hepatocellular carcinoma

Author

Jianping Liu, Dongliang Cheng, Yuting Liao, Chun Luo, Qiucheng Lei, Xin Zhang, Luyi Wang, Zhibo Wen, and Mingyong Gao

Subjects

Radiology, Nuclear Medicine and imaging

Published

2023

23. A whole‐plant economics spectrum including bark functional traits for 59 subtropical woody plant species

Author

Xiaoping Chen, Karl J. Niklas, Dongliang Cheng, Jun Sun, Dandan Hu, Zhaoying Wang, Jinlong Li, and Quanlin Zhong

Subjects

Ecology, visual_art, Botany, visual_art.visual_art_medium, Bark, Plant Science, Subtropics, Biology, Trade-off, Ecology, Evolution, Behavior and Systematics, Woody plant, Conservative strategy

Published

2021

24. Divergent leaf nutrient-use strategies of coexistent evergreen and deciduous trees in a subtropical forest

Author

Xiaoping Chen, Xingui Le, Karl J Niklas, Dandan Hu, Quanlin Zhong, and Dongliang Cheng

Subjects

Ecology, Plant Science, Ecology, Evolution, Behavior and Systematics

Abstract

Evergreen and deciduous species coexist in the subtropical forests in southeastern China. It has been suggested that phosphorus (P) is the main limiting nutrient in subtropical forests, and that evergreen and deciduous species adopt different carbon capture strategies to deal with this limitation. However, these hypotheses have not been examined empirically to a sufficient degree. In order to fill this knowledge gap, we measured leaf photosynthetic and respiration rates, and nutrient traits related to P-, nitrogen (N)- and carbon (C)-use efficiencies and resorption using 75 woody species (44 evergreen and 31 deciduous species) sampled in a subtropical forest. The photosynthetic N-use efficiency (PNUE), respiration rate per unit N and P (Rd,N and Rd,P, respectively) of the deciduous species were all significantly higher than those of evergreen species, but not in the case of photosynthetic P-use efficiency. These results indicate that, for any given leaf P, evergreen species manifest higher carbon-use efficiency (CUE) than deciduous species, a speculation that is empirically confirmed. In addition, no significant differences were observed between deciduous and evergreen species for nitrogen resorption efficiency, phosphorus resorption efficiency or N:P ratios. These results indicate that evergreen species coexist with deciduous species and maintain dominance in P-limited subtropical forests by maintaining CUE. Our results also indicate that it is important to compare the PNUE of deciduous species with evergreen species in other biomes. These observations provide insights into modeling community dynamics in subtropical forests, particularly in light of future climate change.

Published

2022

25. Prediction of photosynthetic light‐response curves using traits of the leaf economics spectrum for 75 woody species: effects of leaf habit and sun–shade dichotomy

Author

Dongliang Cheng, Mantang Wang, Min Lyu, Quanlin Zhong, Jun Sun, Dandan Hu, and Xiaoping Chen

Subjects

0106 biological sciences, Canopy, Plant Science, Forests, Evergreen, Biology, Photosynthesis, 010603 evolutionary biology, 01 natural sciences, Trees, Plant Leaves, Habits, Deciduous, Agronomy, Genetics, Habit (biology), Ecosystem, Allometry, Shading, Ecology, Evolution, Behavior and Systematics, 010606 plant biology & botany

Abstract

Premise Photosynthetic light-response (PLR) curves for leaves are important components of models related to carbon fixation in forest ecosystems, linking the Mitscherlich equation and Michaelis-Menten equation to traits of the leaf economics spectrum (LES). However, models do not consider changes in leaf habits (i.e., evergreen and deciduous) and within-canopy shading variation in these PLR curves. Methods Here, we measured the PLR curves in sun and shade leaves of 44 evergreen and 31 deciduous species to examine the relationships between variables of the Mitscherlich equation and Michaelis-Menten equation, leaf nitrogen (N) and phosphorus (P) content, and leaf mass per area (LMA). Results Small changes were caused by different leaf habits and shade variations in relationships linking variables of the two equations to leaf N and P content and LMA. Values of the scaling exponents for PLR curve parameters did not differ regardless of canopy position and leaf habit (P > 0.05). The PLR curves in species with different leaf habits (i.e., evergreen and deciduous) at different canopy positions could be predicted using the general allometric relations between leaf traits and PLR parameters in the two equations. For photosynthetic photon flux densities from 0 to 2000 μmol m-2 s-1 , approximately 71% (Mitscherlich equation) and 70% (Michaelis-Menten equation) of the net assimilation rates could be predicted. Conclusions These findings indicate that leaf net assimilation rates can be predicted through the large available data for LES traits. Incorporation of values for these traits available in the LES databases into ecosystem models of forest productivity and carbon fixation warrants further investigation.

Published

2021

26. Application of leaf size and leafing intensity scaling across subtropical trees

Author

Quanlin Zhong, Jinlong Li, Mantang Wang, Jun Sun, Dongliang Cheng, and Xiaoping Chen

Subjects

leafing intensity, 0106 biological sciences, 0303 health sciences, Ecology, Intensity scaling, stem size, Subtropics, 010603 evolutionary biology, 01 natural sciences, broad scope, Twig, 03 medical and health sciences, Horticulture, functional groups, leaf size, Habit (biology), Pooled data, Leaf size, Scaling, Ecology, Evolution, Behavior and Systematics, Intensity (heat transfer), Original Research, 030304 developmental biology, Nature and Landscape Conservation, Mathematics

Abstract

Understanding the scaling between leaf size and leafing intensity (leaf number per stem size) is crucial for comprehending theories about the leaf costs and benefits in the leaf size–twig size spectrum. However, the scaling scope of leaf size versus leafing intensity changes along the twig leaf size variation in different leaf habit species remains elusive. Here, we hypothesize that the numerical value of scaling exponent for leaf mass versus leafing intensity in twig is governed by the minimum leaf mass versus maximum leaf mass (M min versus M max) and constrained to be ≤−1.0. We tested this hypothesis by analyzing the twigs of 123 species datasets compiled in the subtropical mountain forest. The standardized major axis regression (SMA) analyses showed the M min scaled as the 1.19 power of M max and the ‐α (−1.19) were not statistically different from the exponents of M min versus leafing intensity in whole data. Across leaf habit groups, the M max scaled negatively and isometrically with respect to leafing intensity. The pooled data's scaling exponents ranged from −1.14 to −0.96 for M min and M max versus the leafing intensity based on stem volume (LIV). In the case of M min and M max versus the leafing intensity based on stem mass (LIM), the scaling exponents ranged from −1.24 to −1.04. Our hypothesis successfully predicts that the scaling relationship between leaf mass and leafing intensity is constrained to be ≤−1.0. More importantly, the lower limit to scaling of leaf mass and leafing intensity may be closely correlated with M min versus M max. Besides, constrained by the maximum leaf mass expansion, the broad scope range between leaf size and number may be insensitive to leaf habit groups in subtropical mountain forest., Our hypothesis successfully predicts that the scaling relationship between leaf mass and leafing intensity is constrained to be ≤−1.0. The broad scope range between leaf size and number may not be sensitive to leaf habit groups in the subtropical mountain forest.

Published

2020

27. Preparation, Characterization, and in vivo Evaluation of NK4-Conjugated Hydroxycamptothecin-Loaded Liposomes

Author

Jianfang Feng, Wei Wu, Dongliang Cheng, Xin Tang, Wei Zhang, and Ting Zhou

Subjects

Biophysics, Pharmaceutical Science, Bioengineering, 02 engineering and technology, 010402 general chemistry, 01 natural sciences, High-performance liquid chromatography, Biomaterials, Pharmacokinetics, In vivo, Drug Discovery, medicine, MTT assay, Liposome, Chromatography, Chemistry, Organic Chemistry, Area under the curve, General Medicine, 021001 nanoscience & nanotechnology, 0104 chemical sciences, stomatognathic diseases, Targeted drug delivery, 0210 nano-technology, Camptothecin, medicine.drug

Abstract

Purpose In this study, NK4-conjugated hydroxycamptothecin liposomes (NK4-HCPT-Lips) were prepared with the aim of improving drug targeting to the liver. Methods NK4-HCPT-Lips were prepared using the thin-film dispersion method. In vitro antitumor activities were evaluated by MTT assay. HCPT levels in plasma and tissues were determined via high-performance liquid chromatography (HPLC) with camptothecin as the internal standard, and the characteristics, pharmacokinetics, and bio-distribution of NK4-HCPT-Lips were evaluated. Results The liposomes showed a regular spherical-shaped morphology, and the entrapment efficiency and drug loading capacity reached 82.5 ± 2.4% and 3.01 ± 0.23%, respectively, with a particle size of 155.6 ± 2.6 nm and a zeta potential of -24.8 ± 3.3 mV. Inhibition effect experiments found that NK4-HCPT-Lips had a good inhibition on the HepG2 cells. Pharmacokinetic studies revealed an increase in the area under the curve and mean residence time as well as a decrease in plasma clearance (p < 0.05) of the NK4-HCPT-Lips compared to those of HCPT liposomes and a commercial HCPT injection. Tissue distribution studies showed that NK4-HCPT-Lips were present at high levels in the liver but were cleared from the kidneys. Conclusion These results demonstrate that NK4-HCPT-Lips possess excellent liver-targeting attributes, which could enhance the therapeutic effects of drug treatments for hepatic diseases.

Published

2020

28. Non-targeted metabonomic analysis of plasma in patients with atherosclerosis by liquid chromatography-mass spectrometry

Author

Xianru Xia, Xiandong Li, Fei Xie, Guolin Yuan, Dongliang Cheng, and Chunyan Peng

Subjects

Original Article, General Medicine

Abstract

BACKGROUND: This study sought to analyze non-targeted plasma metabolites in patients with atherosclerosis (AS). METHODS: The plasma of patients with AS (the patient group) and the plasma of age-matched and gender-matched healthy individuals (the control group) at the Taihe Hospital was collected. One hundred patients were included in the study (60 in the patient group and 40 in the control group). Fasting venous plasma was collected in the morning. The metabolites in the plasma were examined by liquid chromatography-mass spectrometry (LC-MS). An unsupervised principal component analysis (PCA) was conducted to observe the overall distribution of each sample and the stability of the analysis process. Next, a supervised partial least squares-discriminant analysis (PLS-DA) and an orthogonal partial least squares-discriminant analysis (OPLS-DA) were conducted to examine the overall differences among the metabolic profiles of the groups and identify different metabolites in the groups. Pathway enrichment was analyzed using the Kyoto Encyclopedia of Genes and Genomes (KEGG) database. RESULTS: In total, 1,126 different metabolites were detected in the patient and control groups. Compared to the control group, 411 species decreased, and 715 species increased in the patient group. There were 61 different metabolites with a variable weight in the projection (VIP) >1 and a P1; P

Published

2021

29. Prone Position Ventilation for Pediatric Acute Respiratory Distress Syndrome with Extracorporeal Membrane Oxygenation: A Propensity Score-Matched Retrospective Multicenter Cohort Study

Author

Zhe Zhao, Guoping Lu, Shuanglei Li, Baowang Yang, Huiling Zhang, Ye Cheng, Yiping Zhou, Yun Cui, Wenzhe Cheng, Jie Wang, Yibing Cheng, Yingfu Chen, Chengjun Liu, Dongliang Cheng, Changsong Shi, Yuxiong Guo, Yan Hu, Yi Hui, Dong Qu, Chengxiang Kong, Ping Jin, Bin Yu, Xiulan Lu, Youpeng Jin, Huiying Yan, Xiaoyang Hong, Yucai Zhang, and Zhi-Chun Feng

Subjects

Mechanical ventilation, medicine.medical_specialty, Surviving Sepsis Campaign, genetic structures, business.industry, medicine.medical_treatment, Retrospective cohort study, Guideline, Prone position, Emergency medicine, Propensity score matching, Extracorporeal membrane oxygenation, Medicine, business, Cohort study

Abstract

Background: Extracorporeal membrane oxygen (ECMO) has used for rescuing severe pediatric acute respiratory distress syndrome (PARDS) for half a century. Prone position ventilation (PPV) has been suggested according to the surviving sepsis campaign (SSC) guideline in children in 2020. We aimed to compare the outcomes and effect of PARDS patients with ECMO+PPV and ECMO only.Design: Retrospective Multicenter pair-matched StudySetting: In the present study, propensity score matching was conducted and the outcomes of severe PARDS patients were analyzed. The effect of PPV was compared as well. The efficiency of PPV included PaO2, Oxygen Index (OI), PaO2/FiO2, compliance of respiratory system and resistance of airway. The primary outcome was hospital mortality. Secondary outcomes included ECMO running time, PICU time, hospital days and mechanical ventilation time of survivors. Patients: 137 PARDS patients with criteria of ECMO from 11 hospitals in 5 years.Interventions: No interventions.Measurements and Main Results: Among 137 patients, 93 patients received ECMO+PPV at the same time and 44 patients didn’t. After matching, we got 34 pairs. For the survivors receiving ECMO+PPV, the PaO2, OI and PaO2/FiO2 increased significantly during the PPV period (PConclusions: By far, there has been no ECMO+PPV efficiency study in PARDS patients. This study found that PPV was associated with improved oxygen state during ECMO. However, PPV was not associated with survival rate with PARDS patients on ECMO. Clinical Trial Registration: This study was registered at http://www.chictr.org.cn/index.aspx (chiCTR.gov; Identifier: ChiCTR1800019555). Registered 18 November 2018. Name of the registry: Extracorporeal membrane oxygenation in critical ill children with severe acute respiratory distress syndrome - A multicenter study.Take Home Message:1. Our study investigated prone position ventilation (PPV) could improve the oxygen state during ECMO for patients with severe PARDS.2. The results indicated PPV had no influence on the mortality of PARDS with ECMO.

Published

2020

30. Fumed SiO2-H2SO4-PVA Gel Electrolyte CO Electrochemical Gas Sensor

Author

Zicheng Wu, Yuhang Zhang, Feihu Li, Dongliang Cheng, Zili Zhan, and Fang Fang

Subjects

Materials science, electrochemical sensor, 02 engineering and technology, Electrolyte, Aqueous electrolyte, 010402 general chemistry, fumed SiO2, 01 natural sciences, Polyvinyl alcohol, Analytical Chemistry, lcsh:Biochemistry, chemistry.chemical_compound, lcsh:QD415-436, Physical and Theoretical Chemistry, Leakage (electronics), Detection limit, Aqueous solution, gel electrolyte, 021001 nanoscience & nanotechnology, 0104 chemical sciences, Electrochemical gas sensor, Linear range, Chemical engineering, chemistry, CO gas sensor, 0210 nano-technology

Abstract

The conventional CO electrochemical gas sensor uses aqueous H2SO4 solution as electrolyte, with inevitable problems, such as the drying and leakage of electrolyte. Thus, research on new alternative electrolytes is an attractive field in electrochemical gas sensors. In this paper, the application of a new fumed SiO2 gel electrolyte was studied in electrochemical gas sensors. The effects of fumed SiO2 and H2SO4 contents on the performance of the CO gas sensor were investigated. The results showed that the optimized composition of the SiO2 gel electrolyte was 4.8% SiO2, 38% H2SO4, and 0.005% polyvinyl alcohol (PVA). Compared with aqueous H2SO4, the gel electrolyte had better water retention ability. The signal current of the sensor was proportional to the CO concentration. The sensitivity to CO was 78.6 nA/ppm, and the response and recovery times were 31 and 38 s, respectively. The detection limit was 2 ppm. The linear range was from 2 to 500 ppm. The gel electrolyte CO sensor possesses equivalent performance to that with aqueous electrolyte.

Published

2020

31. Nitrogen Addition Did Not Alter the Relationships Between the Leaf and Root Traits of Machilus Pauhoi seedlings

Author

Dongliang Cheng, Xingyu Deng, Quanlin Zhong, Baoyin Li, Hua Yu, Xiaoping Chen, and Yu-Xing Zou

Subjects

Machilus pauhoi, Horticulture, chemistry, fungi, food and beverages, chemistry.chemical_element, Biology, Nitrogen

Abstract

Leaves and roots are important resource acquisition organs of seedlings and both are sensitive to the environment. However, it is currently unclear whether leaf and root traits have a similar response model to nitrogen (N) deposition. Furthermore, the relationships between the responses of leaf and root traits to N deposition are still unknown.Exogenous nitrogen input experiments were conducted to simulate the effects of nitrogen deposition in Shunchang County, south of China. We measured the biomass, morphological characteristics, and nutrient concentrations (total of 12 functional traits of leaves and roots) of Machilus pauhoi seedlings. The responses of leaf and root traits to N addition were analyzed. In addition, the relationships between paired leaf and root traits were analyzed.We found that the responses of the leaves and roots to short-term nitrogen deposition were not consistent. The specific leaf area (SLA) (specific root length, SRL), tissue density (TD), carbon (C) content, N content, C/N, and N/phosphorus (P) of the leaf and root did not appear to respond to N addition. However, the biomass, P content, and C/P of the leaf and root markedly responded to N addition. The nutrient concentrations of the leaf and root were correlated, while the phenotypic traits were not. Furthermore, short-term N addition did not alter the relationship between the leaves and roots.Our results show that, in the context of global change of nitrogen deposition, the correlation between the leaves and roots of a plant has a certain tolerance for nitrogen deposition, which is of great significance for the efficient cultivation of quality seedlings and understanding how terrestrial forest ecosystems respond to nitrogen deposition.

Published

2020

32. The value of oxygen index and base excess in predicting the outcome of neonatal acute respiratory distress syndrome

Author

Hui Wu, Quan Xueli, Zhe Zhao, Change Liu, Qiong Ji, Dongliang Cheng, Yangming Qu, Zhenqiu Liu, Xiaoyang Hong, Zhichun Feng, Shi Yuan, Jie Wang, and Sun Jianwei

Subjects

chemistry.chemical_element, Acute respiratory distress, Oxygen index, Pediatrics, Oxygen, RJ1-570, 03 medical and health sciences, 0302 clinical medicine, 030225 pediatrics, Medicine, Humans, 030212 general & internal medicine, Respiratory Distress Syndrome, Respiratory Distress Syndrome, Newborn, Receiver operating characteristic analysis, Acute respiratory distress syndrome, business.industry, Base excess, Area under the curve, Infant, Newborn, Oxygen Inhalation Therapy, Gestational age, Infant, Oxygenation, Newborn, Net reclassification improvement, chemistry, Anesthesia, Pediatrics, Perinatology and Child Health, Original Article, business, Respiratory Insufficiency, Predictor

Abstract

Objective This study aimed to identify the predictors and threshold of failure in neonatal acute respiratory distress syndrome. Methods Newborns with severe acute respiratory distress syndrome aged 0-28 days and gestational age ≥36 weeks were included in the study if their cases were managed with non-extra corporal membrane oxygenation treatments. Patients were divided into two groups according to whether they died before discharge. Predictors of non-extra corporal membrane oxygenation treatment failure were sought, and the threshold of predictors was calculated. Results A total of 103 patients were included in the study. A total of 77 (74.8%) survived hospitalization and were discharged, whereas 26 (25.2%) died. Receiver operating characteristic analysis of oxygen index, pH, base excess, and combinations of these indicators demonstrated the advantage of the combination of oxygen index and base excess over the others variables regarding their predictive ability. The area under the curve for the combination of oxygen index and base excess was 0.865. When the cut-off values of oxygen index and base excess were 30.0 and −7.4, respectively, the sensitivity and specificity for predicting death were 77.0% and 84.0%, respectively. The model with base excess added a net reclassification improvement of 0.090 to the model without base excess. Conclusion The combination of oxygen index and base excess can be used as a predictor of outcomes in neonates receiving non-extra corporal membrane oxygenation treatment for acute respiratory distress syndrome. In neonates with acute respiratory distress syndrome, if oxygen index >30 and base excess

Published

2020

33. Early Prognosis Effect of Cellular Immune Paralysis on Brain Complications of Extracorporeal Membrane Oxygenation Children with Severe Sepsis

Author

Dongliang Cheng, Changsong Shi, Zhiqing Shen, and Yan Xing

Subjects

medicine.medical_specialty, Chemokine, Lipopolysaccharide, medicine.medical_treatment, Immunology, HMGB1, Gastroenterology, chemistry.chemical_compound, Endocrinology, Immune system, Extracorporeal Membrane Oxygenation, Internal medicine, Sepsis, medicine, Extracorporeal membrane oxygenation, Humans, Paralysis, Retrospective Studies, biology, Endocrine and Autonomic Systems, business.industry, Elastase, Brain, Acquired immune system, Prognosis, Neurology, chemistry, biology.protein, Base excess, business

Abstract

Objective: The aim of the study was to explore the relationship between criticality, brain complications, and immune mechanisms in extracorporeal membrane oxygenation (ECMO) children with pneumonia and severe sepsis. Methods: Patients with simple pneumonia (group I), ECMO patients with pneumonia and severe sepsis accompanied by brain complications (group II), and those without brain complication (group III) admitted to our pediatric intensive care unit were selected to be investigated. The relationship among the peripheral blood subgroups of immune cells, immune factors, adaptive immune responses, endothelial factors, and criticality and brain complications was then studied. Results: Severe paralysis of normal immunity, excess abnormal immunity, and endothelial injury were consistent with the increase in the absolute value of base excess, lactic acid (Lac) content, and average hospitalization days and brain complications involved in group II (vs. group I). The ratio of CD63+ macrophage and CD63+ neutrophil subpopulation increased (p < 0.05); the expression levels of elastase+ neutrophil denatured subgroup (p < 0.05), the ratio of CCR2highCX3CR1low/CCR2lowCX3CR1high of macrophages and neutrophils (p < 0.0001), high-mobility group box 1 (HMGB1), YTHDF1, interleukin-17 protein and mRNA, and RAGE gene decreased to some extent (p < 0.05); the expression levels of Th1 cells chemokine CXCL9 protein and mRNA and sTIE2 protein increased to some extent (p < 0.05); the adaptive immune response of CD8+ CTL stimulated by lipopolysaccharide (LPS) was slightly enhanced (p < 0.05) in group III(vs. group II), which was consistent with the improvement of criticality, average hospitalization days, and the absence of brain complications in group III (vs. group II). Conclusion: ECMO support with brain complication was related to the upregulation of HMGB1 and YTHDF1 protein; the decreased number of CD63+ macrophages and neutrophils; the increased denatured neutrophil subgroup, especially the upregulated ratio of CCR2highCX3CR1low/CCR2lowCX3CR1high of macrophages and neutrophils; the imbalance of Th17/Th1, LPS-specific CD8+ CTL adaptive immune response paralysis; and the reduced endothelial sTIE2 protein expression level which caused clinical deterioration and prolonged average hospitalization days.

Published

2020

34. Convergent nitrogen-phosphorus scaling relationships in different plant organs along an elevational gradient

Author

Dongliang Cheng, Quanlin Zhong, Min Lyu, Jun Sun, Xiao-Ping Chen, Mantang Wang, and Man Li

Subjects

Wuyi Mountains, AcademicSubjects/SCI01210, Phosphorus, plant economics spectrum (PES), limiting nutrient, chemistry.chemical_element, Plant Science, Biology, Evergreen, Elevational Diversity Gradient, Animal science, Deciduous, chemistry, Linear regression, Nutrient allocation, Studies, Tropical and subtropical moist broadleaf forests, plant organ, Scaling, Woody plant, subtropical forest

Abstract

A general relationship between the nitrogen (N) and phosphorus (P) content of all plant organs (e.g. leaf, stem, and root) is hypothesized to exist according to whole-plant economics spectrum (PES) theory, but the evidence supporting these expected patterns remains scarce. We measured the N and P content of the leaves, twigs and fine roots of 64 species in three different forest communities along an elevational gradient (evergreen broad-leaved forest, 1319 m a.s.l., coniferous and broad-leaved mixed forest, 1697 m a.s.l., and deciduous forest, 1818 m a.s.l.) in the Wuyishan National Nature Reserve, southeastern China. The scaling relationship between the N and P content and the linear regression relationship between the N:P ratio and N and P content were analysed. The leaf N and P content was significantly higher at the high-elevation site than at the low- or middle-elevation sites (P < 0.001). The N and P content followed a power-law relationship with similar scaling slopes between organs. The N (common slope, 1.13) and P (common slope, 1.03) content isometrically covaried among leaves, twigs and roots. The scaling exponents of the N–P relationship were not significantly different from 1.0 in all organs, with a common slope of 1.08. The scaling constants of N–P decreased significantly (P < 0.05) from the highest value in fine roots (β = 1.25), followed by leaves (β = 1.17), to the lowest value in twigs (β = 0.88). Standardized major axis (SMA) analyses and comparisons of 95 % confidence intervals also showed that the numerical values of the scaling slopes and the scaling constants did not differ regardless of elevation. The N content, but not the P content, accounted for a large proportion of the variation in the N:P ratio in leaves (N:P and N: r2 = 0.31, F = 33.36, P < 0.001) and fine roots (N:P and N: r2 = 0.15, F = 10.65, P < 0.05). In contrast, the N:P ratio was significantly related to both the N and P content in the twigs (N:P and N: r2 = 0.20, F = 17.86, P < 0.001; N:P and P: r2 = 0.34, F = 35.03, P < 0.001, respectively). Our results indicate that different organs of subtropical woody plants share a similar isometric scaling relationship between their N and P content, providing partial support for the PES hypothesis. Moreover, the effects of the N and P content on the N:P ratio differ between metabolic organs (leaves and fine roots) and structural organs (twigs), elucidating the stoichiometric regulatory mechanism of different organs., We found the scaling exponents of the N-P relationship were not significantly different from 1.0 in all organs, with a common slope of 1.08. The numerical values of the scaling slopes and the scaling constants did not differ regardless of elevation. These results indicated the different organs of subtropical woody plants share a similar isometric scaling relationship between their N and P content. Moreover, the effects of the N and P content on the N:P ratio differ between metabolic organs (leaves and fine roots) and structural organs (twigs), elucidating the stoichiometric regulatory mechanism of different organs.

Published

2019

35. 'Diminishing returns' in the scaling of leaf area vs. dry mass in Wuyi Mountain bamboos, Southeast China

Author

Mengke Sun, Ruirui Fan, Xiaoping Chen, Karl J. Niklas, Man Li, Dongliang Cheng, Quanlin Zhong, Fuchun Yang, and Jun Sun

Subjects

0106 biological sciences, China, Bamboo, Light, Specific leaf area, Plant Science, Biology, Poaceae, 010603 evolutionary biology, 01 natural sciences, Altitude, Dry weight, Botany, Genetics, Leaf size, Ecology, Evolution, Behavior and Systematics, fungi, food and beverages, biology.organism_classification, Plant Leaves, Light intensity, Phyllostachys edulis, Agronomy, Interception, 010606 plant biology & botany

Abstract

Premise of study Leaf area and dry mass are crucial for plant metabolic performance. The "diminishing returns" hypothesis predicts that leaf area will scale less than one with respect to leaf dry mass, indicating that the cost of light interception increases with leaf area. However, it remains unclear whether and how this scaling relationship varies among species growing in different environments. Methods More than 2000 measurements from five bamboo species adapted to high and low light and growing at different elevations in Wuyi Mountains, Southeast China, were used to explore how the leaf area vs. dry mass scaling relationship was affected by light and elevation. Key results The data indicate that (1) the normalization constants for leaf area vs. dry mass were positively but not significantly correlated with increasing leaf size and that (2) the scaling exponents remained numerically invariant among all five bamboo species, with a common slope of 0.85. Standardized major axis (SMA) analyses and comparisons of 95% confidence intervals also showed that the numerical values of the scaling exponents did not differ regardless of elevation and were similar between shaded and unshaded adapted species, whereas the numerical values of the normalization constants increased with decreasing light. Conclusions The data collected for all five bamboo species are consistent with the "diminishing returns" hypothesis, i.e., the scaling exponents governing the leaf area vs. dry mass scaling relationship are less than one within and across species and are insensitive to light conditions or elevation.

Published

2017

36. New insight on the interfacial interaction between multiwalled carbon nanotubes and elastomers

Author

Ming Tian, Youping Wu, Dongliang Cheng, Yonglai Lu, Li Liu, Liqun Zhang, Jianhua Yang, Wencai Wang, and Nanying Ning

Subjects

Materials science, General Engineering, 02 engineering and technology, 010402 general chemistry, 021001 nanoscience & nanotechnology, Multiwalled carbon, Elastomer, Microstructure, 01 natural sciences, Toluene, 0104 chemical sciences, chemistry.chemical_compound, Adsorption, Elastomer composites, chemistry, Natural rubber, visual_art, Ceramics and Composites, visual_art.visual_art_medium, Composite material, 0210 nano-technology, Macromolecule

Abstract

We studied the effect of the microstructure of multiwalled carbon nanotubes (MWCNTs) on interfacial interaction in seven kinds of MWCNT/natural rubber (NR) composites. Unexpectedly, the degree of defects (ID/IG) of MWCNTs was found to play a key role in the interfacial interaction of MWCNT/NR composites. The content of bound rubber (BR) of the composites almost linearly increased with the increase in the ID/IG of MWCNTs. Then we studied the interfacial interaction between MWCNTs with high degree of defects and NR. Interestingly, the BR of the composites consisted of loosely adsorbed BR (LBR) and tight BR (TBR). TBR occupied about half of the total BR, and cannot be removed by extraction in hot toluene for 48 h. Meanwhile, the mobilities of macromolecules in TBR were more restricted than those in LBR. We discussed in depth the molecular origin of the interfacial interaction between defected MWCNTs and NR, and then proposed that LBR was topologically confined by the steps-like structure of defected MWCNTs whereas TBR was principally chemically bonded to MWCNTs. This study provided new insight on the interfacial interaction between MWCNTs and NR and thus provides guidance for the preparation of high-performance elastomer composites with strong interfacial interaction.

Published

2017

37. Stem and leaf growth rates define the leaf size vs. number trade-off

Author

Quanlin Zhong, Jun Sun, Man Li, Dongliang Cheng, Mantang Wang, Karl J. Niklas, and Min Lyu

Subjects

leafing intensity, Carbon gain, Plant Science, Biology, Stem-and-leaf display, Trade-off, Annual growth %, Horticulture, twig architecture, leaf size, Shoot, Studies, forest communities, metabolic scaling theory, Leaf size, Interception, Elevational gradient, Intensity (heat transfer)

Abstract

The trade-off between leaf number and individual leaf size on current-year shoots (twigs) is crucial to light interception and thus net carbon gain. However, a theoretical basis for understanding this trade-off remains elusive. Here, we argue that this trade-off emerges directly from the relationship between annual growth in leaf and stem mass, a hypothesis that predicts that maximum individual leaf size (i.e. leaf mass, Mmax, or leaf area, Amax) will scale negatively and isometrically with leafing intensity (i.e. leaf number per unit stem mass, per unit stem volume or per stem cross-sectional area). We tested this hypothesis by analysing the twigs of 64 species inhabiting three different forest communities along an elevation gradient using standardized major axis (SMA) analyses. Across species, maximum individual leaf size (Mmax, Amax) scaled isometrically with respect to leafing intensity; the scaling constants between maximum leaf size and leafing intensity (based on stem cross-sectional area) differed significantly among the three forests. Therefore, our hypothesis successfully predicts a scaling relationship between maximum individual leaf size and leafing intensity, and provides a general explanation for the leaf size-number trade-off as a consequence of mechanical-hydraulic constraints on stem and leaf growth per year., The trade-off between leaf number and individual leaf size on current-year shoots (twigs) is crucial to light interception and thus net carbon gain. We present a model (stem-leaf growth hypothesis, SLGH) to provide a theoretical explanation for the trade-off between the maximum leaf size vs. leafing intensity. We found that the scaling exponents of maximum leaf size vs. the leafing intensity are close to −1.0 and are insensitive to forest types and different elevations. Therefore, our results successfully provide a general explanation for this trade-off as a consequence of mechanical-hydraulic constraints on stem and leaf growth per year.

Published

2019

38. Short-Term Nitrogen Addition Does Not Significantly Alter the Effects of Seasonal Drought on Leaf Functional Traits in Machilus pauhoi Kanehira Seedlings

Author

Baoyin Li, Dongliang Cheng, Chaobin Xu, Quanlin Zhong, Yaqi Zhong, Zhongrui Zhang, and Hua Yu

Subjects

0106 biological sciences, Stomatal conductance, Specific leaf area, leaf functional trait, Photosynthesis, 010603 evolutionary biology, 01 natural sciences, Field capacity, Nutrient, Ecosystem, Transpiration, biology, fungi, food and beverages, Forestry, lcsh:QK900-989, biology.organism_classification, additive effect, Horticulture, M. pauhoi Kanehira seedling, Seedling, soil properties, lcsh:Plant ecology, seasonal drought, short-term N deposition, 010606 plant biology & botany

Abstract

Research Highlights: Short-term nitrogen (N) addition did not significantly alter the effects of seasonal drought on the leaf functional traits in Machilus pauhoi Kanehira seedlings in N-rich subtropical China. Background and Objectives: Seasonal drought and N deposition are major drivers of global environmental change that affect plant growth and ecosystem function in subtropical China. However, no consensus has been reached on the interactive effects of these two drivers. Materials and Methods: We conducted a full-factorial experiment to analyze the single and combined effects of seasonal drought and short-term N addition on chemical, morphological and physiological traits of M. pauhoi seedlings. Results: Seasonal drought (40% of soil field capacity) had significant negative effects on the leaf N concentrations (LNC), phosphorus (P) concentrations (LPC), leaf thickness (LT), net photosynthetic rate (A), transpiration rate (E), stomatal conductance (Gs), and predawn leaf water potential (&psi, PD), and significant positive effects on the carbon:N (C:N) ratio and specific leaf area (SLA). Short-term N addition (50 kg N&middot, hm&minus, 2&middot, year&minus, 1 and 100 kg N&middot, 1) tended to decrease the C:N ratio and enhance leaf nutrient, growth, and photosynthetic performance because of increased LNC, LPC, LT, leaf area (LA), SLA, A, E, and &psi, PD, however, it only had significant effects on LT and Gs. No significant interactive effects on leaf traits were detected. Seasonal drought, short-term N addition, and their interactions had significant effects on soil properties. The soil total C (STC), nitrate N (NO3&minus, N) and soil total N (STN) concentrations were the main factors that affected the leaf traits. Conclusions: Seasonal drought had a stronger effect on M. pauhoi seedling leaf traits than short-term N deposition, indicating that the interaction between seasonal drought and short-term N deposition may have an additive effecton M. pauhoi seedling growth in N-rich subtropical China.

Published

2019

39. 'Diminishing Returns' in the Scaling between Leaf Area and Twig Size in Three Forest Communities Along an Elevation Gradient of Wuyi Mountain, China

Author

Mantang Wang, Quanlin Zhong, Man Li, Karl J. Niklas, Min Lyu, Xiaoping Chen, Jun Sun, Dongliang Cheng, and Guojie Zhu

Subjects

leaf traits, 0106 biological sciences, Lamina, Biomass (ecology), Wuyi Mountain, plant allometry, Forestry, Evergreen, Biology, scaling exponents, 010603 evolutionary biology, 01 natural sciences, Petiole (botany), Twig, Deciduous, twig biomass allocation, Agronomy, Shoot, Scaling, diminishing returns, 010606 plant biology & botany

Abstract

Background and aims: The &ldquo, diminishing returns&rdquo, hypothesis postulates that the scaling exponent governing the lamina area versus lamina mass scaling relationships has, on average, a numerical value less than one. Theoretically, a similar scaling relationship may exist at the twig level. However, this possibility has not been explored empirically. Methods: We tested both hypotheses by measuring the lamina area and mass, petiole mass of individual leaves, and the total foliage area and stem mass of individual current-year shoots (twigs) of 64 woody species growing in three characteristic forest community types:(1) Evergreen broad-leaved, (2) mixed coniferous and broad-leaved, and (3) deciduous. Key results: The results demonstrate that lamina area vs. mass and lamina area vs. petiole mass differ significantly among the three forest types at both the individual leaf and twig levels. Nevertheless, the scaling exponents of lamina area vs. mass were &lt, 1.0 in each of the three community types, as were the corresponding exponents for lamina area vs. petiole mass, both within and across the three community types. Similar trends were observed at the individual twig level. The numerical values of the scaling exponent for lamina area vs. petiole mass and total foliage area vs. stem mass per twig decreased with increased elevation. Conclusions: These data support the &ldquo, hypothesis at both the individual leaf level and at the individual twig level, phenomena that can inform future inquiries into the mechanistic basis of biomass allocation patterns to physiological (leaf) and mechanical (stem) plant organs.

Published

2019

40. MicroRNA-34a promotes iNOS secretion from pulmonary macrophages in septic suckling rats through activating STAT3 pathway

Author

Yuan Liang, Dongliang Cheng, Yi Zhao, Hong-Xing Fang, and Chang-song Shi

Subjects

0301 basic medicine, Lipopolysaccharides, STAT3 Transcription Factor, Lipopolysaccharide, Nitric Oxide Synthase Type II, Lung injury, Pharmacology, Sepsis, Rats, Sprague-Dawley, 03 medical and health sciences, chemistry.chemical_compound, Cell Line, Tumor, Macrophages, Alveolar, Medicine, Animals, Humans, Secretion, STAT3, Cecum, Lung, U937 cell, biology, business.industry, General Medicine, U937 Cells, medicine.disease, Rats, Up-Regulation, MicroRNAs, 030104 developmental biology, medicine.anatomical_structure, chemistry, MicroRNA 34a, biology.protein, business, Signal Transduction

Abstract

Pediatric sepsis is frequently a fatal condition and a major cause of death globally. The mortality rate of sepsis remains high despite that the advanced therapeutic methods have been carried out. Our research aims to investigate the potentials of miR-34a in the treatment of pediatric sepsis. Results indicated that miR-34a was up-regulated in Lipopolysaccharide (LPS)-induced pulmonary macrophages and U937 cell lines. In addition, miR-34a silence reduced the production of iNOS through inactivating STAT3 pathway in U937 cell lines and cecal ligation and puncture (CLP)-induced lung tissues. Besides, high expression of iNOS and STAT3 in cells transfected with miR-34a mimic further validated it. Furthermore, in vivo experiment demonstrated that miR-34a silence protected CLP-induced suckling rats from lung injury. All in all, our study demonstrated that miR-34a promoted iNOS secretion from pulmonary macrophages in LPS-induced sepsis suckling rats through activating STAT3 pathway. These results provided a possibility to convert miR-34a into clinical application.

Published

2018

41. Isometric scaling of above- and below-ground biomass at the individual and community levels in the understorey of a sub-tropical forest

Author

Yuzhu Ma, Dongliang Cheng, Yusheng Yang, Karl J. Niklas, Jianhua Zhang, and Quanlin Zhong

Subjects

Normalization (statistics), China, Tropical Climate, Tree canopy, Pinus massoniana, Light, biology, Ecology, Original Articles, Plant Science, Understory, Forests, Atmospheric sciences, biology.organism_classification, Models, Biological, Trees, Tropical climate, Biomass, Allometry, Biomass partitioning, Photosynthesis, Scaling

Abstract

Background and Aims Empirical studies and allometric partitioning (AP) theory indicate that plant above-ground biomass (MA) scales, on average, one-to-one (isometrically) with below-ground biomass (MR) at the level of individual trees and at the level of entire forest communities. However, the ability of the AP theory to predict the biomass allocation patterns of understorey plants has not been established because most previous empirical tests have focused on canopy tree species or very large shrubs. Methods In order to test the AP theory further, 1586 understorey sub-tropical forest plants from 30 sites in south-east China were harvested and examined. The numerical values of the scaling exponents and normalization constants (i.e. slopes and y-intercepts, respectively) of log–log linear MA vs. MR relationships were determined for all individual plants, for each site, across the entire data set, and for data sorted into a total of 19 sub-sets of forest types and successional stages. Similar comparisons of MA/MR were also made. Key Results The data revealed that the mean MA/MR of understorey plants was 2·44 and 1·57 across all 1586 plants and for all communities, respectively, and MA scaled nearly isometrically with respect to MR, with scaling exponents of 1·01 for all individual plants and 0·99 for all communities. The scaling exponents did not differ significantly among different forest types or successional stages, but the normalization constants did, and were positively correlated with MA/MR and negatively correlated with scaling exponents across all 1586 plants. Conclusions The results support the AP theory’s prediction that MA scales nearly one-to-one with MR (i.e. MA ∝ MR ≈1·0) and that plant biomass partitioning for individual plants and at the community level share a strikingly similar pattern, at least for the understorey plants examined in this study. Furthermore, variation in environmental conditions appears to affect the numerical values of normalization constants, but not the scaling exponents of the MA vs. MR relationship. This feature of the results suggests that plant size is the primary driver of the MA vs. MR biomass allocation pattern for understorey plants in sub-tropical forests.

Published

2015

42. Divergent scaling of respiration rates to nitrogen and phosphorus across four woody seedlings between different growing seasons

Author

Quanlin Zhong, Fuchun Yang, Yuan Zheng, Man Li, Dongliang Cheng, Jun Sun, and Ruirui Fan

Subjects

0106 biological sciences, chemistry.chemical_element, Growing season, Biology, 010603 evolutionary biology, 01 natural sciences, nitrogen, Gymnosperm, respiration rates, Botany, medicine, allometry, metabolic scaling theory, phosphorus, Scaling, Ecology, Evolution, Behavior and Systematics, Nature and Landscape Conservation, Original Research, Biomass (ecology), Ecology, Phosphorus, Interspecific competition, Seasonality, growing and dormant seasons, medicine.disease, biology.organism_classification, chemistry, Allometry, 010606 plant biology & botany

Abstract

Empirical studies indicate that the exponents governing the scaling of plant respiration rates (R) with respect to biomass (M) numerically vary between three‐fourth for adult plants and 1.0 for seedlings and saplings and are affected by nitrogen (N) and phosphorus (P) content. However, whether the scaling of R with respect to M (or N and P) varies among different phylogenetic groups (e.g., gymnosperms vs. angiosperms) or during the growing and dormant seasons remains unclear. We measured the whole‐plant R and M, and N and P content of the seedlings of four woody species during the growing season (early October) and the dormant season (January). The data show that (i) the scaling exponents of R versus M, R versus N, and R versus P differed significantly among the four species, but (ii), not between the growing and dormant seasons for each of the four species, although (iii) the normalization constants governing the scaling relationships were numerically greater for the growing season compared to the dormant season. In addition, (iv) the scaling exponents of R versus M, R versus N, and R versus P were numerically larger for the two angiosperm species compared to those of the two gymnosperm species, (v) the interspecific scaling exponents for the four species were greater during the growing season than in the dormant season, and (vi), interspecifically, P scaled nearly isometric with N content. Those findings indicate that the metabolic scaling relationships among R, M, N, and P manifest seasonal variation and differ between angiosperm and gymnosperm species, that is, there is no single, canonical scaling exponent for the seedlings of woody species.

Published

2017

43. Scaling relationships of twig biomass allocation in Pinus hwangshanensis along an altitudinal gradient

Author

Ruirui Fan, Yuan Zheng, Dongliang Cheng, Quanlin Zhong, and Man Li

Subjects

0106 biological sciences, Leaves, Carbon Sequestration, Environmental Engineering, Ecological Metrics, Climate, Biomass (Ecology), lcsh:Medicine, Plant Science, Biology, 010603 evolutionary biology, 01 natural sciences, Trees, Twig, Altitude, Forest ecology, Biomass, lcsh:Science, Scaling, Flowering Plants, Plant Growth and Development, Biomass (ecology), Multidisciplinary, Ecology, Plant Anatomy, Ecology and Environmental Sciences, lcsh:R, Organisms, Biology and Life Sciences, Plants, Pinus, biology.organism_classification, Conifers, Pinus hwangshanensis, Agronomy, Shoot, Engineering and Technology, lcsh:Q, Allometry, Pines, Research Article, Developmental Biology, 010606 plant biology & botany

Abstract

Understanding the response of biomass allocation in twigs (the terminal branches of current-year shoots) to environmental change is crucial for elucidating forest ecosystem carbon storage, carbon cycling, and plant life history strategies under a changing climate. On the basis of interspecies investigations of broad-leaved plants, previous studies have demonstrated that plants respond to environmental factors by allocating biomass in an allometric manner between support tissues (i.e., stems) and the leaf biomass of twigs, where the scaling exponent (i.e., slope of a log—log linear relationship, α) is constant, and the scaling constant (i.e., intercept of a log—log linear relationship, log β) varies with respect to environmental factors. However, little is known about whether the isometric scaling exponents of such biomass allocations remain invariant for single species, particularly conifers, at different altitudes and in different growing periods. In this study, we investigated how twig biomass allocation varies with elevation and period among Pinus hwangshanensis Hsia trees growing in the mountains of Southeast China. Specifically, we explored how twig stem mass, needle mass, and needle area varied throughout the growing period (early, mid-, late) and at three elevations in the Wuyi Mountains. Standardized major axis analysis was used to compare the scaling exponents and scaling constants between the biomass allocations of within-twig components. Scaling relationships between these traits differed with growing period and altitude gradient. During the different growing periods, there was an isometric scaling relationship, with a common slope of 1.0 (i.e., α ≈ 1.0), between needle mass and twig mass (the sum of the total needle mass and the stem mass), whereas there were allometric scaling relationships between the stem mass and twig mass and between the needle mass and stem mass of P. hwangshanensis. The scaling constants (log β) for needle mass vs. twig mass and for needle mass vs. stem mass increased progressively across the growing stages, whereas the scaling constants of stem mass vs. twig mass showed the opposite pattern. The scaling exponents (α) of needle area with respect to needle biomass increased significantly with growing period, changing from an allometric relationship (i.e., α < 1.0) during the early growing period to a nearly isometric relationship (i.e., α ≈ 1.0) during the late growing period. This change possibly reflects the functional adaptation of twigs in different growing periods to meet their specific reproductive or survival needs. At different points along the altitudinal gradient, the relationships among needle mass, twig mass, and stem mass were all isometric (i.e., α ≈ 1.0). Moreover, significant differences were found in scaling constants (log β) along the altitudinal gradient, such that species had a smaller stem biomass but a relatively larger needle mass at low altitude. In addition, the scaling exponents remained numerically invariant among all three altitudes, with a common slope of 0.8, suggesting that needle area failed to keep pace with the increasing needle mass at different altitudes. Our results indicated that the twig biomass allocation pattern was significantly influenced by altitude and growing period, which reflects the functional adaptation of twigs to meet their specific survival needs under different climatic conditions.

Published

2017

44. Allometric scaling relationship between above- and below-ground biomass within and across five woody seedlings

Author

Dongliang Cheng, Yuzhu Ma, Weifeng Xu, and Quanling Zhong

Subjects

Biomass (ecology), Allometry, Ecology, leaf, biomass partitioning patterns, Isometric exercise, Interspecific competition, Biology, Evergreen, Intraspecific competition, isometric scaling, Horticulture, Botany, Litter, intraspecific scaling and interspecific scaling, stem and root biomass allocation, Scaling, Ecology, Evolution, Behavior and Systematics, Nature and Landscape Conservation, Original Research

Abstract

Allometric biomass allocation theory predicts that leaf biomass (M L ) scaled isometrically with stem (M S ) and root (M R ) biomass, and thus above-ground biomass (leaf and stem) (M A ) and root (M R ) scaled nearly isometrically with below-ground biomass (root) for tree seedlings across a wide diversity of taxa. Furthermore, prior studies also imply that scaling constant should vary with species. However, litter is known about whether such invariant isometric scaling exponents hold for intraspecific biomass allocation, and how variation in scaling constants influences the interspecific scaling relationship between above- and below-ground biomass. Biomass data of seedlings from five evergreen species were examined to test scaling relationships among biomass components across and within species. Model Type II regression was used to compare the numerical values of scaling exponents and constants among leaf, stem, root, and above- to below-ground biomass. The results indicated that M L and M S scaled in an isometric or a nearly isometric manner with M R , as well as M A to M R for five woody species. Significant variation was observed in the Y-intercepts of the biomass scaling curves, resulting in the divergence for intraspecific scaling and interspecific scaling relationships for M L versus M S and M L versus M R , but not for M S versus M R and M A versus M R . We conclude, therefore, that a nearly isometric scaling relationship of M A versus M R holds true within each of the studied woody species and across them irrespective the negative scaling relationship between leaf and stem.

Published

2014

45. Interspecific differences in whole-plant respiration vs. biomass scaling relationships: A case study using evergreen conifer and angiosperm tree seedlings

Author

Jianhua Zhang, Quanlin Zhong, Dongliang Cheng, Karl J. Niklas, and Yusheng Yang

Subjects

Maintenance respiration, Biomass (ecology), Cupressaceae, Range (biology), Plant Science, Interspecific competition, Biology, Evergreen, Pinus, biology.organism_classification, Models, Biological, Trees, Plant Leaves, Lauraceae, Species Specificity, Seedlings, Seedling, Botany, Genetics, Regression Analysis, Biomass, Allometry, Ecology, Evolution, Behavior and Systematics

Abstract

 Premise of the study: Empirical studies and theory indicate that respiration rates ( R ) of small plants scale nearly isometrically with both leaf biomass ( M L ) and total plant biomass ( M T ). These predictions are based on angiosperm species and apply only across a small range of body mass. Whether these relationships hold true for different plants, such as conifers, remains unclear .  Methods: We tested these predictions using the whole-plant maintenance respiration rates and the biomass allocation patterns of the seedlings of two conifer tree species and two angiosperm tree species. Model Type II regression protocols were used to compare the scaling exponents ( α ) and normalization constants ( β ) across all four species and within each of the four species.  Key results: The data show that the scaling exponents varied among the four species and that all differed signifi cantly from isometry. For conifers, scaling exponents for R vs. M T , and R and M L were numerically smaller than those of the broadleaved angiosperm species. However, across the entire data set, R scaled isometrically with M L and with M T as predicted by the West, Brown, and Enquist (WBE) theory. We also observed higher respiration rates for small conifer seedlings compared to compa- rably sized angiosperm seedlings.  Conclusions: Our data add credence to the view that the R vs. M scaling relationship differs among species, and that in general, the numerical values of this interspecifi c scaling relationship will depend on the species pooled in the analysis and on the range of body sizes within the data set.

Published

2014

46. A predictive nondestructive model for the covariation of tree height, diameter, and stem volume scaling relationships

Author

Quanlin Zhong, Karl J. Niklas, Zhongrui Zhang, Yusheng Yang, Dongliang Cheng, and Liang Cai

Subjects

0106 biological sciences, Normalization (statistics), China, Multidisciplinary, Biometry, Models, Statistical, biology, Plant Stems, Ecology, Cunninghamia, Scaling theory, biology.organism_classification, 010603 evolutionary biology, 01 natural sciences, Article, Site quality, Statistics, Scaling, Management practices, 010606 plant biology & botany, Mathematics

Abstract

Metabolic scaling theory (MST) posits that the scaling exponents among plant height H, diameter D, and biomass M will covary across phyletically diverse species. However, the relationships between scaling exponents and normalization constants remain unclear. Therefore, we developed a predictive model for the covariation of H, D and stem volume V scaling relationships and used data from Chinese fir (Cunninghamia lanceolata) in Jiangxi province, China to test it. As predicted by the model and supported by the data, normalization constants are positively correlated with their associated scaling exponents for D vs. V and H vs. V, whereas normalization constants are negatively correlated with the scaling exponents of H vs. D. The prediction model also yielded reliable estimations of V (mean absolute percentage error = 10.5 ± 0.32 SE across 12 model calibrated sites). These results (1) support a totally new covariation scaling model, (2) indicate that differences in stem volume scaling relationships at the intra-specific level are driven by anatomical or ecophysiological responses to site quality and/or management practices and (3) provide an accurate non-destructive method for predicting Chinese fir stem volume.

Published

2016

47. Relationships among the Stem, Aboveground and Total Biomass across Chinese Forests

Author

Qing Long Tang, Chunmei Gong, Dongliang Cheng, Gen-Xuan Wang, and Tao Li

Subjects

Biomass, Plant Science, Biochemistry, General Biochemistry, Genetics and Molecular Biology, Regression, Carbon cycle, Agronomy, Ordinary least squares, Botany, Environmental science, Stem biomass, Allometry, Precipitation, Aboveground biomass

Abstract

Forest biomass plays a key role in the global carbon cycle. In the present study, a general allometric model was derived to predict the relationships among the stem biomass MS, aboveground biomass MA and total biomass MT, based on previously developed scaling relationships for leaf, stem and root standing biomass. The model predicted complex scaling exponents for MT and/or MA with respect to MS. Because annual biomass accumulation in the stem, root and branch far exceeded the annual increase in standing leaf biomass, we can predict that MT∝MA∝MSas a simple result of the model. Although slight variations existed in different phyletic affiliations (i.e. conifers versus angiosperms), empirical results using Model Type II (reduced major axis) regression supported the model's predictions. The predictive formulas among stem, aboveground and total biomass were obtained using Model Type I (ordinary least squares) regression to estimate forest biomass. Given the low mean percentage prediction errors for aboveground (and total biomass) based on the stem biomass, the results provided a reasonable method to estimate the biomass of forests at the individual level, which was insensitive to the variation in local environmental conditions (e.g. precipitation, temperature, etc.).

Published

2007

48. Positive Interactions: Crucial Organizers in a Plant Community

Author

Dongliang Cheng, Gen-Xuan Wang, Bao-Ming Chen, and Xiao-Ping Wei

Subjects

Abiotic stress, Ecology, Mechanism (biology), Community organization, media_common.quotation_subject, food and beverages, Plant community, Plant Science, Biology, Biochemistry, General Biochemistry, Genetics and Molecular Biology, Competition (biology), Facilitation, Species richness, Environmental gradient, media_common

Abstract

For more than a century, ecologists have concentrated on competition as a crucial process for community organization. However, more recent experimental investigations have uncovered the striking influence of positive interactions on the organization of plant communities. Complex combinations of competition and positive interactions operating simultaneously among plant species seem to be widespread in nature. In the present paper, we reviewed the mechanism and ecological importance of positive interactions in plant communities, emphasizing the certainties and uncertainties that have made it an attractive area of research. Positive interactions, or facilitation, occur when one species enhances the survival, growth, or richness of another. The importance of facilitation in plant organization increases with abiotic stress and the relative importance of competition decreases. Only by combining plant interactions and the many fields of biology can we fully understand how and when the positive interactions occur. (Managing editor: Ya-Qin Han)

Published

2006

49. A theoretical framework for whole-plant carbon assimilation efficiency based on metabolic scaling theory: a test case using Picea seedlings

Author

Zhexuan Fan, Zhiqiang Wang, Heng Huang, Richard I. Milne, Jinzhi Ran, Xiaowei Zhang, Jiangtao Li, Qiang Zhang, Jianming Deng, Mingfei Ji, Karl J. Niklas, and Dongliang Cheng

Subjects

Analysis of Variance, biology, Scale (ratio), Physiology, Ecology, Cell Respiration, Humidity, Flux, Picea abies, Plant Science, Darkness, Photosynthesis, biology.organism_classification, Models, Biological, Carbon, Seedlings, Statistics, Growth rate, Picea, Scaling, Picea schrenkiana

Abstract

Simultaneous and accurate measurements of whole-plant instantaneous carbon-use efficiency (ICUE) and annual total carbon-use efficiency (TCUE) are difficult to make, especially for trees. One usually estimates ICUE based on the net photosynthetic rate or the assumed proportional relationship between growth efficiency and ICUE. However, thus far, protocols for easily estimating annual TCUE remain problematic. Here, we present a theoretical framework (based on the metabolic scaling theory) to predict whole-plant annual TCUE by directly measuring instantaneous net photosynthetic and respiratory rates. This framework makes four predictions, which were evaluated empirically using seedlings of nine Picea taxa: (i) the flux rates of CO(2) and energy will scale isometrically as a function of plant size, (ii) whole-plant net and gross photosynthetic rates and the net primary productivity will scale isometrically with respect to total leaf mass, (iii) these scaling relationships will be independent of ambient temperature and humidity fluctuations (as measured within an experimental chamber) regardless of the instantaneous net photosynthetic rate or dark respiratory rate, or overall growth rate and (iv) TCUE will scale isometrically with respect to instantaneous efficiency of carbon use (i.e., the latter can be used to predict the former) across diverse species. These predictions were experimentally verified. We also found that the ranking of the nine taxa based on net photosynthetic rates differed from ranking based on either ICUE or TCUE. In addition, the absolute values of ICUE and TCUE significantly differed among the nine taxa, with both ICUE and temperature-corrected ICUE being highest for Picea abies and lowest for Picea schrenkiana. Nevertheless, the data are consistent with the predictions of our general theoretical framework, which can be used to access annual carbon-use efficiency of different species at the level of an individual plant based on simple, direct measurements. Moreover, we believe that our approach provides a way to cope with the complexities of different ecosystems, provided that sufficient measurements are taken to calibrate our approach to that of the system being studied.

Published

2014

50. Scaling relationship between tree respiration rates and biomass

Author

Tao Li, Dongliang Cheng, Quanlin Zhong, and Gen-Xuan Wang

Subjects

Biomass (ecology), Nitrogen, Carbon Dioxide, Biology, Body size, Agricultural and Biological Sciences (miscellaneous), Trees, Agronomy, Respiration, Botany, Biomass, Population Ecology, Allometry, Tree (set theory), Plant metabolism, General Agricultural and Biological Sciences, Scaling, Woody plant

Abstract

The WBE theory proposed by West, Brown and Enquist predicts that larger plant respiration rate, R , scales to the three-quarters power of body size, M . However, studies on the R versus M relationship for larger plants (i.e. trees larger than saplings) have not been reported. Published respiration rates of field-grown trees (saplings and larger trees) were examined to test this relationship. Our results showed that for larger trees, aboveground respiration rates R A scaled as the 0.82-power of aboveground biomass M A , and that total respiration rates R T scaled as the 0.85-power of total biomass M T , both of which significantly deviated from the three-quarters scaling law predicted by the WBE theory, and which agreed with 0.81–0.84-power scaling of biomass to respiration across the full range of measured tree sizes for an independent dataset reported by Reich et al . (Reich et al . 2006 Nature 439 , 457–461). By contrast, R scaled nearly isometrically with M in saplings. We contend that the scaling exponent of plant metabolism is close to unity for saplings and decreases (but is significantly larger than three-quarters) as trees grow, implying that there is no universal metabolic scaling in plants.

Published

2010