Your search keyword '"Uzair, Muhammad"' showing total 23 results

1. Partial replacement of inorganic fertilizer with organic inputs for enhanced nitrogen use efficiency, grain yield, and decreased nitrogen losses under rice-based systems of mid-latitudes

Author

Farooq, Muhammad Shahbaz, Majeed, Abid, Ghazy, Abdel‑Halim, Fatima, Hira, Uzair, Muhammad, Ahmed, Shafiq, Murtaza, Maryam, Fiaz, Sajid, Khan, Muhammad Ramzan, Al-Doss, Abdullah A., and Attia, Kotb A.

Published

2024

2. Country-wide, multi-location trials of Green Super Rice lines for yield performance and stability analysis using genetic and stability parameters

Author

Ahmed, Muhammad Shahzad, Majeed, Abid, Attia, Kotb A., Javaid, Rana Arsalan, Siddique, Faiza, Farooq, Muhammad Shahbaz, Uzair, Muhammad, Yang, Seung Hwan, and Abushady, Asmaa M.

Published

2024

3. The comparative transcriptome analysis of two green super rice genotypes with varying tolerance to salt stress

Author

Zahra, Nageen, Uzair, Muhammad, Zaid, Imdad Ullah, Attia, Kotb A., Inam, Safeena, Fiaz, Sajid, Abdallah, Rizk M., Naeem, Muhammad Kashif, Farooq, Umer, Rehman, Nazia, Ali, Ghulam Muhammad, Xu, Jianlong, Li, Zhikang, and Khan, Muhammad Ramzan

Published

2024

4. Male sterility systems and their applications in hybrid wheat breeding.

Author

Farooq, Ayesha, Khan, Uzair Muhammad, Khan, Muhammad Ahsan, Ali, Zulfqar, Maqbool, Rizwana, and Sajjad, Muhammad

Subjects

WHEAT breeding, MALE sterility in plants, CANOLA, HYBRID rice, FUNCTIONAL genomics, RICE, WHEAT farming, CYTOPLASMIC male sterility

Abstract

To ensure food security for ~ 10 billion human population in 2050 a sustainable increase in food production is indispensable. Wheat is the third most consumed cereal crop worldwide after rice and maize. It is estimated that the current wheat yield will be insufficient to cope with future needs. In the past hybrid seed production has revolutionized rice and maize production; however, wheat is still lagging behind other crops, such as rice, corn, soybeans, and canola in terms of variety/hybrid development and trait development. The potential of hybrid wheat is undeniable but these challenges need to be overcome if we want to commercialize it. Despite a century of efforts we still do not have a reliable hybrid breeding system to attempt large-scale production due to certain issues like self-pollination, polyploid nature, low variability in germplasm (less than 1% cross-pollination), and higher seed rates. Moreover, a limited number of GMS genes and their regulatory pathways has narrowed our selection; further research is required to identify and understand the genetic and molecular mechanisms involved. There are few successful examples of hybrid wheat, only 1% of its total wheat growing area is hybrid wheat. There is no simple way to produce a stable wheat hybrid, until this point no one knows how to commercialize wheat on a larger scale. The use of comparative functional genomics and biotechnological tools combined with conventional breeding is likely the possible key to guarantee a stable hybrid wheat breeding and to help overcome global food security issues. This paper would provide an overview of techniques to induce male sterility in wheat and their use in commercialized hybrid seed production systems. [ABSTRACT FROM AUTHOR]

Published

2024

5. The comparative transcriptome analysis of two green super rice genotypes with varying tolerance to salt stress.

Author

Zahra, Nageen, Uzair, Muhammad, Zaid, Imdad Ullah, Attia, Kotb A., Inam, Safeena, Fiaz, Sajid, Abdallah, Rizk M., Naeem, Muhammad Kashif, Farooq, Umer, Rehman, Nazia, Ali, Ghulam Muhammad, Xu, Jianlong, Li, Zhikang, and Khan, Muhammad Ramzan

Abstract

Background: Salinity is one of the main abiotic factors that restrict plant growth, physiology, and crop productivity is salt stress. About 33% of the total irrigated land suffers from severe salinity because of intensive underground water extraction and irrigation with brackish water. Thus, it is important to understand the genetic mechanism and identify the novel genes involved in salt tolerance for the development of climate-resilient rice cultivars. Methods and results: In this study, two rice genotypes with varying tolerance to salt stress were used to investigate the differential expressed genes and molecular pathways to adapt under saline soil by comparative RNA sequencing at 42 days of the seedling stage. Salt-susceptible (S3) and -tolerant (S13) genotypes revealed 3982 and 3463 differentially expressed genes in S3 and S13 genotypes. The up-regulated genes in both genotypes were substantially enriched in different metabolic processes and binding activities. Biosynthesis of secondary metabolites, phenylpropanoid biosynthesis, and plant signal transduction mechanisms were highly enriched. Salt-susceptible and -tolerant genotypes shared the same salt adaptability mechanism with no significant quantitative differences at the transcriptome level. Moreover, bHLH, ERF, NAC, WRKY, and MYB transcription factors were substantially up-regulated under salt stress. 391 out of 1806 identified novel genes involved in signal transduction mechanisms. Expression profiling of six novel genes further validated the findings from RNA-seq data. Conclusion: These findings suggest that the differentially expressed genes and molecular mechanisms involved in salt stress adaptation are conserved in both salt-susceptible and salt-tolerant rice genotypes. Further molecular characterization of novel genes will help to understand the genetic mechanism underlying salt tolerance in rice. [ABSTRACT FROM AUTHOR]

Published

2023

6. INVESTIGATION OF HEAVY METALS CONTAMINANTION LEVEL IN THE LOCALLY CULTIVATED RICE USING ATOMIC ABSORPTION SPECTROSCOPY (AAS).

Author

Yalwa, Lawan Musa, Durumin-Iya, Sani Garba, Abdulhamid, Abdulhamid Mikail, Uzair, Muhammad, Adamu, Suleiman Bashir, and Shitu, Ibrahim Garba

Subjects

HEAVY metals, ATOMIC absorption spectroscopy, LEAD, HEAVY metals in the body, COPPER, RICE, LUNG cancer

Abstract

Rice (Oryza sativa) is a stable food in many countries in the world including Africa. The present of heavy metals in the environment which are toxics affect the nutritional value of the rice. The accumulation of heavy metals in the body may lead to different health problems such as cancer, diabetes, liver and kidney failure. The study was conducted to access the presence of some selected heavy metals (Pb, Cu, Cd, As, Ni, Zn) in rice sample using atomic absorption spectroscopy technique. Five sample of rice (EXCHINA, CP, WHEETER-4, ROBBER, and YERMALINTA) which were cultivated in Damashewa village of Kirikasamma local government area were collected. Wet digestion method was used to destroy organic matter in the sample. The result of analysis showed that the concentration of Zinc(Zn) in all the four sample of rice range from (16.50-36.02mg/kg) and that of Cadmium Cd (0.05-0.18mg/kg) and that of copper Cu (7.02-22.20mg/kg) which is far below the safety limit of 50-100mg/kg for zinc and 0.4mg/kg for cadmium, and copper is 73.3mg/kg set up by the FAO/WHO (2001), this could lead to anaemia, renal damage, bones disorder and cancer of the lungs. While the concentration of lead Pb (3.57-16.24mg/kg), nickel Ni (2.50-11.24mg/kg) and that of Arsenic As (0.98-4.33mg/kg) is also above the set safety limit of 0.3mg/kg for lead. Based on this research all rice sample were highly contaminated with lead, arsenic and nickel as a pollutant. Thus, the need for physical examination of the consumers and inhabitants within the study area. [ABSTRACT FROM AUTHOR]

Published

2023

7. Genome-wide and molecular characterization of the DNA replication helicase 2 (DNA2) gene family in rice under drought and salt stress.

Author

Saleem, Bilal, Farooq, Umer, Ur Rehman, Obaid, Aqeel, Muhammad, Farooq, Muhammad Shahbaz, Naeem, Muhammad Kashif, Inam, Safeena, Ajmal, Wajya, Rahim, Amna Abdul, Ming Chen, Kalsoom, Rabia, Uzair, Muhammad, Fiaz, Sajid, Attia, Kotb, Alafari, Hayat Ali, Khan, Muhammad Ramzan, and Guoping Yu

Subjects

GENE families, GENE expression, CHROMOSOME duplication, DROUGHTS, DNA repair, DNA helicases, DNA replication

Abstract

Rice plants experience various biotic (such as insect and pest attack) and abiotic (such as drought, salt, heat, and cold etc.) stresses during the growing season, resulting in DNA damage and the subsequent losses in rice production. DNA Replication Helicase/Nuclease2 (DNA2) is known to be involved in DNA replication and repair. In animals and yeast DNA2 are well characterized because it has the abilities of both helicase and nuclease, it plays a crucial role in DNA replication in the nucleus and mitochondrial genomes. However; they are not fully examined in plants due to less focused on plants damage repair. To fill this research gap, the current study focused on the genome-wide identification and characterization of OsDNA2 genes, along with analyses of their transcriptional expression, duplication, and phylogeny in rice. Overall, 17 OsDNA2 members were reported to be found on eight different chromosomes (2, 3, 4, 6, 7, 9, 10, and 11). Among these chromosomes (Chr), Chr4 contained a maximum of six OsDNA2 genes. Based on phylogenetic analysis, the OsDNA2 gene members were clustered into three different groups. Furthermore, the conserved domains, gene structures, and cis-regulatory elements were systematically investigated. Gene duplication analysis revealed that OsDNA2_2 had an evolutionary relationship with OsDNA2_14, OsDNA2_5 with OsDNA2_6, and OsDNA2_1 with OsDNA2_8. Moreover, results showed that the conserved domain (AAA_11 superfamily) were present in the OsDNA2 genes, which belongs to the DEAD-like helicase superfamily. In addition, to understand the post-transcriptional modification of OsDNA2 genes, miRNAs were predicted, where 653 miRNAs were reported to target 17 OsDNA2 genes. The results indicated that at the maximum, OsDNA2_1 and OsDNA2_4 were targeted by 74 miRNAs each, and OsDNA2_9 was less targeted (20 miRNAs). The three-dimensional (3D) structures of 17 OsDNA2 proteins were also predicted. Expression of OsDNA2 members was also carried out under drought and salt stresses, and conclusively their induction indicated the possible involvement of OsDNA2 in DNA repair under stress when compared with the control. Further studies are recommended to confirm where this study will offer valuable basic data on the functioning of DNA2 genes in rice and other crop plants. [ABSTRACT FROM AUTHOR]

Published

2022

8. Unraveling the stable green super rice lines across the multi-environment yield trials.

Author

Naeem, Muhammad Kashif, Habib, Madiha, Zafar, Syed Adeel, Uzair, Muhammad, Naveed, Shehzad Amir, Jianlong Xu, Ali, Jauhar, Zhikang Li, and Khan, M. Ramzan

Subjects

GENOTYPE-environment interaction, GRAIN yields, RICE

Abstract

The stable performance of cultivars is a prerequisite for enhanced yield production to ensure food security. Identification of the stable yield performing genotype is the necessity of any breeding program to improve the livelihood of farmers. The present study was performed to evaluate the genotype and environment interaction of 22 green super rice (GSR) genotypes at eight different locations in Pakistan. The genotype × environment interaction was assessed by univariate and multivariate analysis for yield and yield-related traits. The harvest index, grain yield, total biomass, and straw yield showed higher variation among the genotypes, evaluated by PCA biplot analysis. The multiplicative interactions (AMMI) analysis of variance was found significant among genotypes, environments (locations), and genotype × environment interaction (G × E). The AMMI model demonstrated that genotypes S8 and S16 performed best across the environments, whereas, genotypes S18, S17, S15, and S5 revealed stable performance across the environments. The two-dimensional GGE biplot explained 56.74% variation for all studied traits across the environments. The GGE biplot results indicated that genotypes S13, S15, S18, S1, and S5 showed stable yield performance across the environments, whereas genotypes S16 and S8 demonstrated the high yield genotypes with low stability. Based on these multivariate analyses, genotype S5 depicted stable performance across the environments, while genotypes S8 and S16 were high yielding with low stability across the environments. Among the environments, Islamabad, Muzaffargarh, and Sahiwal are the most suitable environments for GSR genotypes cultivation. These results could be helpful in the selection of genotypes and will be recommended for commercial cultivation in the future. [ABSTRACT FROM AUTHOR]

Published

2022

9. Inquiring the inter-relationships amongst grain-filling, grain-yield, and grain-quality of Japonica rice at high latitudes of China.

Author

Farooq, Muhammad Shahbaz, Khaskheli, Maqsood Ahmed, Uzair, Muhammad, Yinlong Xu, Wattoo, Fahad Masood, Rehman, Obaid ur, Amatus, Gyilbag, Fatima, Hira, Khan, Sher Aslam, Fiaz, Sajid, Yousuf, Muhammad, Khan, Muhammad Ramzan, Khan, Naeem, Attia, Kotb A., Ercisli, Sezai, and Golokhvast, Kirill S.

Subjects

GRAIN yields, GRAIN, RICE, CLIMATE change, LATITUDE, RICE quality

Abstract

The widespread impacts of projected global and regional climate change on rice yield have been investigated by different indirect approaches utilizing various simulation models. However, direct approaches to assess the impacts of climatic variabilities on rice growth and development may provide more reliable evidence to evaluate the effects of climate change on rice productivity. Climate change has substantially impacted rice production in the mid-high latitudes of China, especially in Northeast China (NEC). Climatic variabilities occurring in NEC since the 1970s have resulted in an obvious warming trend, which made this region one of the three major rice-growing regions in China. However, the projections of future climate change have indicated the likelihood of more abrupt and irregular climatic changes, posing threats to rice sustainability in this region. Hence, understanding the self-adaptability and identifying adjustive measures to climate variability in high latitudes has practical significance for establishing a sustainable rice system to sustain future food security in China. A well-managed field study under randomized complete block design (RCBD) was conducted in 2017 and 2018 at two study sites in Harbin and Qiqihar, located in Heilongjiang province in NEC. Four different cultivars were evaluated: Longdao-18, Longdao-21 (longer growth duration), Longjing-21, and Suijing-18 (shorter growth duration) to assess the inter-relationships among grain-filling parameters, grain yield and yield components, and grain quality attributes. To better compare the adaptability mechanisms between grain-filling and yield components, the filling phase was divided into three sub-phases (start, middle, and late). The current study evaluated the formation and accumulation of the assimilates in superior and inferior grains during grain-filling, mainly in the middle sub-phase, which accounted for 59.60% of the yield. The grain yields for Suijing-18, Longjing-21, Longdao-21, and Longdao-18 were 8.02%, 12.78%, 17.19%, and 20.53% higher in Harbin than those in Qiqihar, respectively in 2017, with a similar trend observed in 2018. At Harbin, a higher number of productive tillers was noticed in Suijing-18, with averages of 17 and 15 in 2017 and 2018, respectively. The grain-filling parameters of yield analysis showed that the filling duration in Harbin was conducive to increased yield but the low dry weight of inferior grains was a main factor limiting the yield in Qiqihar. The average protein content values in Harbin were significantly higher (8.54% and 9.13%) than those in Qiqihar (8.34% and 9.14%) in 2017 and 2018, respectively. The amylose content was significantly higher in Harbin (20.03% and 22.27%) than those in Qiqihar (14.44% and 14.67%) in 2017 and 2018, respectively. The chalkiness percentage was higher in Qiqihar, indicating that Harbin produced good quality rice. This study provides more direct evidence of the relative changes in rice grain yield due to changes in grain-filling associated with relative changes in environmental components. These self-adaptability mechanisms to climatic variability and the inter-relationships between grain-filling and grain yield underscore the urgent to investigate and explore measures to improve Japonica rice sustainability, with better adaptation to increasing climatic variabilities. These findings may also be a reference for other global rice regions at high latitudes in addressing the impacts of climate change on future rice sustainability. [ABSTRACT FROM AUTHOR]

Published

2022

10. Recent trends in nitrogen cycle and eco-efficient nitrogen management strategies in aerobic rice system.

Author

Farooq, Muhammad Shahbaz, Xiukang Wang, Uzair, Muhammad, Fatima, Hira, Fiaz, Sajid, Maqbool, Zubaira, Ur Rehman, Obaid, Yousuf, Muhammad, and Khan, Muhammad Ramzan

Subjects

NITROGEN cycle, RICE, OZONE layer depletion, PLANT residues, CROPS, GREEN manuring, MICROBIAL diversity

Abstract

Rice (Oryza sativa L.) is considered as a staple food for more than half of the global population, and sustaining productivity under a scarcity of resources is challenging to meet the future food demands of the inflating global population. The aerobic rice system can be considered as a transformational replacement for traditional rice, but the widespread adaptation of this innovative approach has been challenged due to higher losses of nitrogen (N) and reduced N-use efficiency (NUE). For normal growth and developmental processes in crop plants, N is required in higher amounts. N is a mineral nutrient and an important constituent of amino acids, nucleic acids, and many photosynthetic metabolites, and hence is essential for normal plant growth and metabolism. Excessive application of N fertilizers improves aerobic rice growth and yield, but compromises economic and environmental sustainability. Irregular and uncontrolled use of N fertilizers have elevated several environmental issues linked to higher N losses in the form of nitrous oxide (N2O), ammonia (NH3), and nitrate (NO3-), thereby threatening environmental sustainability due to higher warming potential, ozone depletion capacities, and abilities to eutrophicate the water resources. Hence, enhancing NUE in aerobic rice has become an urgent need for the development of a sustainable production system. This article was designed to investigate the major challenge of low NUE and evaluate recent advances in pathways of the N cycle under the aerobic rice system, and thereby suggest the agronomic management approaches to improve NUE. The major objective of this review is about optimizing the application of N inputs while sustaining rice productivity and ensuring environmental safety. This review elaborates that different soil conditions significantly shift the N dynamics via changes in major pathways of the N cycle and comprehensively reviews the facts why N losses are high under the aerobic rice system, which factors hinder in attaining high NUE, and how it can become an eco-efficient production system through agronomic managements. Moreover, it explores the interactive mechanisms of how proper management of N cycle pathways can be accomplished via optimized N fertilizer amendments. Meanwhile, this study suggests several agricultural and agronomic approaches, such as site-specific N management, integrated nutrient management (INM), and incorporation of N fertilizers with enhanced use efficiency that may interactively improve the NUE and thereby plant N uptake in the aerobic rice system. Additionally, resource conservation practices, such as plant residue management, green manuring, improved genetic breeding, and precision farming, are essential to enhance NUE. Deep insights into the recent advances in the pathways of the N cycle under the aerobic rice system necessarily suggest the incorporation of the suggested agronomic adjustments to reduce N losses and enhance NUE while sustaining rice productivity and environmental safety. Future research on N dynamics is encouraged under the aerobic rice system focusing on the interactive evaluation of shifts among activities and diversity in microbial communities, NUE, and plant demands while applying N management measures, which is necessary for its widespread adaptation in face of the projected climate change and scarcity of resources. [ABSTRACT FROM AUTHOR]

Published

2022

11. Agronomic and Physiological Indices for Reproductive Stage Heat Stress Tolerance in Green Super Rice.

Author

Zafar, Syed Adeel, Arif, Muhammad Hamza, Uzair, Muhammad, Rashid, Umer, Naeem, Muhammad Kashif, Rehman, Obaid Ur, Rehman, Nazia, Zaid, Imdad Ullah, Farooq, Muhammad Shahbaz, Zahra, Nageen, Saleem, Bilal, Xu, Jianlong, Li, Zhikang, Ali, Jauhar, Ali, Ghulam Muhammad, Yang, Seung Hwan, and Khan, Muhammad Ramzan

Subjects

RICE, GRAIN yields, PRINCIPAL components analysis, ATMOSPHERIC temperature, PLANT yields

Abstract

Optimum growing temperature is necessary for maximum yield-potential in any crop. The global atmospheric temperature is changing more rapidly and irregularly every year. High temperature at the flowering/reproductive stage in rice causes partial to complete pollen sterility, resulting in significant reduction in grain yield. Green Super Rice (GSR) is an effort to develop an elite rice type that can withstand multiple environmental stresses and maintain yield in different agro-ecological zones. The current study was performed to assess the effect of heat stress on agronomic and physiological attributes of GSR at flowering stage. Twenty-two GSR lines and four local checks were evaluated under normal and heat-stress conditions for different agro-physiological parameters, including plant height (PH), tillers per plant (TPP), grain yield per plant (GY), straw yield per plant (SY), harvest index (HI), 1000-grain weight (GW), grain length (GL), cell membrane stability (CMS), normalized difference vegetative index (NDVI), and pollen fertility percentage (PFP). Genotypes showed high significant variations for all the studied parameters except NDVI. Association and principal component analysis (PCA) explained the genetic diversity of the genotypes, and relationship between the particular parameters and grain yield. We found that GY, along with other agronomic traits, such as TPP, SY, HI, and CMS, were greatly affected by heat stress in most of the genotypes, while PH, GW, GL, PFP, and NDVI were affected only in a few genotypes. Outperforming NGSR-16 and NGSR-18 in heat stress could be utilized as a parent for the development of heat-tolerant rice. Moreover, these findings will be helpful in the prevention and management of heat stress in rice. [ABSTRACT FROM AUTHOR]

Published

2022

12. Decoding RNA Editing Sites Through Transcriptome Analysis in Rice Under Alkaline Stress.

Author

Rehman, Obaid, Uzair, Muhammad, Chao, Haoyu, Khan, Muhammad Ramzan, and Chen, Ming

Subjects

RNA editing, PENTATRICOPEPTIDE repeat genes, RNA, RICE, TRANSCRIPTOMES, GENE expression, DROUGHT tolerance

Abstract

Ribonucleic acid editing (RE) is a post-transcriptional process that altered the genetics of RNA which provide the extra level of gene expression through insertion, deletions, and substitutions. In animals, it converts nucleotide residues C-U. Similarly in plants, the role of RNA editing sites (RES) in rice under alkaline stress is not fully studied. Rice is a staple food for most of the world population. Alkaline stress cause reduction in yield. Here, we explored the effect of alkaline stress on RES in the whole mRNA from rice chloroplast and mitochondria. Ribonucleic acid editing sites in both genomes (3336 RESs) including chloroplast (345 RESs) and mitochondria (2991 RESs) with average RES efficiency ∼55% were predicted. Our findings showed that majority of editing events found in non-synonymous codon changes and change trend in amino acids was hydrophobic. Four types of RNA editing A-G (A-I), C-T (C-U), G-A, and T-C were identified in treated and untreated samples. Overall, RNA editing efficiency was increased in the treated samples. Analysis of Gene Ontology revealed that mapped genes were engaged in many biological functions and molecular processes. We also checked the expression of pentatricopeptide repeat (PPR), organelle zinc-finger (OZI), and multiple organellar RNA editing factors/RNA editing factor interacting proteins genes in control and treatment, results revealed upregulation of PPR and OZ1 genes in treated samples. This induction showed the role of these genes in RNA editing. The current findings report that RNA editing increased under alkaline stress which may contribute in adaptation for rice by changing amino acids in edited genes (88 genes). These findings will provide basis for identification of RES in other crops and also will be useful in alkaline tolerance development in rice. [ABSTRACT FROM AUTHOR]

Published

2022

13. Improving Nitrogen Use Efficiency in Aerobic Rice Based on Insights Into the Ecophysiology of Archaeal and Bacterial Ammonia Oxidizers.

Author

Farooq, Muhammad Shahbaz, Uzair, Muhammad, Maqbool, Zubaira, Fiaz, Sajid, Yousuf, Muhammad, Yang, Seung Hwan, and Khan, Muhammad Ramzan

Subjects

NITROGEN cycle, OXIDIZING agents, NITRIFICATION inhibitors, AMMONIA, RICE, ECOPHYSIOLOGY

Abstract

The abundance and structural composition of nitrogen (N) transformation-related microbial communities under certain environmental conditions provide sufficient information about N cycle under different soil conditions. This study aims to explore the major challenge of low N use efficiency (NUE) and N dynamics in aerobic rice systems and reveal the agronomic-adjustive measures to increase NUE through insights into the ecophysiology of ammonia oxidizers. Water-saving practices, like alternate wetting and drying (AWD), dry direct seeded rice (DDSR), wet direct seeding, and saturated soil culture (SSC), have been evaluated in lowland rice; however, only few studies have been conducted on N dynamics in aerobic rice systems. Biological ammonia oxidation is majorly conducted by two types of microorganisms, ammonia-oxidizing archaea (AOA) and ammonia-oxidizing bacteria (AOB). This review focuses on how diversified are ammonia oxidizers (AOA and AOB), whose factors affect their activities and abundance under different soil conditions. It summarizes findings on pathways of N cycle, rationalize recent research on ammonia oxidizers in N-cycle, and thereby suggests adjustive agronomic measures to reduce N losses. This review also suggests that variations in soil properties significantly impact the structural composition and abundance of ammonia oxidizers. Nitrification inhibitors (NIs) especially nitrapyrin, reduce the nitrification rate and inhibit the abundance of bacterial amoA without impacting archaeal amoA. In contrast, some NIs confine the hydrolysis of synthetic N and, therefore, keep low NH4+-N concentrations that exhibit no or very slight impact on ammonia oxidizers. Variations in soil properties are more influential in the community structure and abundance of ammonia oxidizers than application of synthetic N fertilizers and NIs. Biological nitrification inhibitors (BNIs) are natural bioactive compounds released from roots of certain plant species, such as sorghum, and could be commercialized to suppress the capacity of nitrifying soil microbes. Mixed application of synthetic and organic N fertilizers enhances NUE and plant N-uptake by reducing ammonia N losses. High salt concentration promotes community abundance while limiting the diversity of AOB and vice versa for AOA, whereas AOA have lower rate for potential nitrification than AOB, and denitrification accounts for higher N2 production. Archaeal abundance, diversity, and structural composition change along an elevation gradient and mainly depend on various soil factors, such as soil saturation, availability of NH4+, and organic matter contents. Microbial abundance and structural analyses revealed that the structural composition of AOA was not highly responsive to changes in soil conditions or N amendment. Further studies are suggested to cultivate AOA and AOB in controlled-environment experiments to understand the mechanisms of AOA and AOB under different conditions. Together, this evaluation will better facilitate the projections and interpretations of ammonia oxidizer community structural composition with provision of a strong basis to establish robust testable hypotheses on the competitiveness between AOB and AOA. Moreover, after this evaluation, managing soils agronomically for potential utilization of metabolic functions of ammonia oxidizers would be easier. [ABSTRACT FROM AUTHOR]

Published

2022

14. Role of the type‐B authentic response regulator gene family in fragrant rice under alkaline salt stress.

Author

Rehman, Obaid Ur, Uzair, Muhammad, Chao, Haoyu, Fiaz, Sajid, Khan, Muhammad Ramzan, and Chen, Ming

Subjects

*REGULATOR genes, *GENE families, *DROUGHT tolerance, *ABIOTIC stress, *RNA editing, *GENE expression profiling, *RICE, *GENE expression

Abstract

Globally, rice is being consumed as a main staple food and faces different kinds of biotic and abiotic stresses such drought, salinity, and pest attacks. Through the cytokinin signaling, Type‐B authentic response regulators (ARR‐Bs) respond positively towards the environmental stimuli. ARR‐Bs are involved in abiotic stress tolerance and plant development but their molecular mechanisms in fragrant rice are still not fully explored. The current study showed the genome‐wide characterization of OsARR‐B genes under alkaline salt stress. Results showed that in total, 24 OsARR‐B genes were found and divided into four subgroups on the basis of a phylogenetic analysis. These genes were located on all rice chromosomes except 8 and 10. Analysis of gene duplications, gene structure, cis‐elements, protein–protein interactions, and miRNA were performed. Gene ontology analysis showed that OsARR‐B genes are involved in plant development through the regulation of molecular functions, biological processes, and cellular components. Furthermore, 117 and 192 RNA editing sites were detected in chloroplast and mitochondrial genes, respectively, encoding proteins of OsARR‐B. In chloroplast and mitochondrial genes, six and nine types of amino acid changes, respectively, were caused by RNA editing, showing that RNA editing has a role in the alkaline salt stress tolerance in fragrant rice. We also used a comparative transcriptome approach to study the gene expression changes in alkaline tolerant and susceptible genotypes. Under alkaline salt stress, OsARR‐B5, OsARR‐B7, OsARR‐B9, OsARR‐B10, OsARR‐B16, OsARR‐B22, and OsARR‐B23 showed higher transcript levels in alkaline salt tolerant genotypes as compared to susceptible ones. Quantitative RT‐PCR showed upregulation of gene expression in the alkaline tolerant genotypes under alkaline stress. Our study explored the gene expression profiling and RESs of two rice contrasting genotypes, which will help to understand the molecular mechanisms of alkaline salt tolerance in fragrant rice. [ABSTRACT FROM AUTHOR]

Published

2022

15. Estimation of Genetic Variances and Stability Components of Yield-Related Traits of Green Super Rice at Multi-Environmental Conditions in Pakistan.

Author

Zaid, Imdad Ullah, Zahra, Nageen, Habib, Madiha, Naeem, Muhammad Kashif, Asghar, Umair, Uzair, Muhammad, Latif, Anila, Rehman, Anum, Ali, Ghulam Muhammad, and Khan, Muhammad Ramzan

Subjects

GENETIC variation, RICE, VARIANCES, GRAIN yields, ANALYSIS of variance, MULTIVARIATE analysis, HERITABILITY

Abstract

Identifying adopted Green Super Rice (GSR) under different agro-ecological locations in Pakistan is crucial to sustaining the high productivity of rice. For this purpose, the multi-location trials of GSR were conducted to evaluate the magnitude of genetic variability, heritability, and stability in eight different locations in Pakistan. The experimental trial was laid out in a randomized complete block (RCB) design with three replications at each location. The combined analysis of variance (ANOVA) manifested significant variations for tested genotypes (g), locations (L), years (Y), genotype × year (GY), and genotype × location (GL) interactions revealing the influence of environmental factors (L and Y) on yield traits. High broad-sense heritability estimates were observed for all the studied traits representing low environmental influence over the expression of traits. Noticeably, GSR 48 showed maximum stability than all other lines in the univariate model across the two years for grain yield and related traits data. Multivariate stability analysis characterized GSR 305 and GSR 252 as the highest yielding with optimum stability across the eight tested locations. Overall, Narowal, Muzaffargarh, and Swat were the most stable locations for GSR cultivation in Pakistan. In conclusion, this study revealed that G×E interactions were an important source of rice yield variation, and its AMMI and biplots analysis are efficient tools for visualizing the response of genotypes to different locations. [ABSTRACT FROM AUTHOR]

Published

2022

16. Screening Direct Seeding-Related Traits by Using an Improved Mesocotyl Elongation Assay and Association between Seedling and Maturity Traits in Rice.

Author

Uzair, Muhammad, Patil, Suyash B., Zhang, Hongrui, Kumar, Ashmit, Mkumbwa, Humphrey, Zafar, Syed Adeel, Chun, Yan, Fang, Jingjing, Zhao, Jinfeng, Khan, Muhammad Ramzan, Yuan, Shoujiang, and Li, Xueyong

Subjects

*RICE, *SEEDLINGS, *RICE breeding, *PRINCIPAL components analysis, *WATER shortages

Abstract

Direct seeding (DS) of rice gained much attention due to labor scarcity and unavailability of water. However, reduced emergence and poor seedling establishment are the main problems of DS which causes significant yield losses. Herein, DS-associated seedling traits of three major rice groups, i.e., Indica (Ind), Japonica (Jap), and aus-type (Aus), were evaluated by using an improved mesocotyl elongation assay. The associations among different traits at the seedling and maturity stage were also studied. Significant variation was observed among the cultivars of different rice groups. The Aus group cultivars showed higher mean values for coleoptile (C, 3.85 cm), mesocotyl (MC, 4.17 cm), shoot length (SL, 13.64 cm), panicle length (PL, 23.44 cm), tillers number (T, 15.95), culm length (CL, 105.29 cm), and plant height (PH, 128.73 cm), while the Indica and Japonica groups showed higher mean values of grain length (GL, 8.69 mm), grain length/width ratio (GL/WR, 3.07), and grain width (GW, 3.31 mm), with 1000 grain weight (TGWt, 25.53 g), respectively. Pairwise correlation analysis showed that MC, C, and SL were positively correlated among themselves and with PL, CL, and PH. Moreover, based on principal component analysis (PCA), C, MC, SL, CL, and PH were identified as the major discriminative factors in the rice cultivars. This study describes the development of desired DS rice variety with long MC and semidwarf in height and suggests that Aus group cultivars can be used as the donor parents of favorable DS-associated traits in rice breeding programs. [ABSTRACT FROM AUTHOR]

Published

2022

17. Sucrose promotes D53 accumulation and tillering in rice.

Author

Patil, Suyash B., Barbier, Francois F., Zhao, Jinfeng, Zafar, Syed A., Uzair, Muhammad, Sun, Yinglu, Fang, Jingjing, Perez‐Garcia, Maria‐Dolores, Bertheloot, Jessica, Sakr, Soulaiman, Fichtner, Franziska, Chabikwa, Tinashe G., Yuan, Shoujiang, Beveridge, Christine A., and Li, Xueyong

Subjects

SUCROSE, DRUG target, PLANT nutrients, RICE, GENE expression

Abstract

Summary: Shoot branching is regulated by multiple signals. Previous studies have indicated that sucrose may promote shoot branching through suppressing the inhibitory effect of the hormone strigolactone (SL). However, the molecular mechanisms underlying this effect are unknown.Here, we used molecular and genetic tools to identify the molecular targets underlying the antagonistic interaction between sucrose and SL.We showed that sucrose antagonizes the suppressive action of SL on tillering in rice and on the degradation of D53, a major target of SL signalling. Sucrose inhibits the gene expression of D3, the orthologue of the Arabidopsis F‐box MAX2 required for SL signalling. Overexpression of D3 antagonizes sucrose inhibition of D53 degradation and enables the SL inhibition of tillering under high sucrose. Sucrose prevents SL‐induced degradation of D14, the SL receptor involved in D53 degradation. In contrast to D3, D14 overexpression enhances D53 protein levels and sucrose‐induced tillering, even in the presence of SL.Our results show that sucrose inhibits SL response by affecting key components of SL signalling and, together with previous studies reporting the inhibition of SL synthesis by nitrate and phosphate, demonstrate the central role played by SLs in the regulation of plant architecture by nutrients. See also the Commentary on this article by Finlayson, 234: 7–9. [ABSTRACT FROM AUTHOR]

Published

2022

18. DPS1 regulates cuticle development and leaf senescence in rice.

Author

Adeel Zafar, Syed, Uzair, Muhammad, Ramzan Khan, Muhammad, Patil, Suyash B., Fang, Jingjing, Zhao, Jinfeng, Lata Singla‐Pareek, Sneh, Pareek, Ashwani, and Li, Xueyong

Subjects

*LEAF development, *CUTICLE, *LEAF aging, *REACTIVE oxygen species, *BIOMASS, *PLANT productivity

Abstract

Leaves are the primary food‐producing organs for a plant that carry out photosynthesis and contribute to biomass and grain yield. Leaf senescence is a developmentally regulated physiological process but early leaf senescence is known to negatively affect plant yield. The cuticle is an outer waxy protective layer on the leaf surface which protects plants from pathogens attack as well as dehydration. Our understanding of the molecular mechanisms underlying cuticle development and leaf senescence is still immature. The present study reports the role of the DEGENERATED PANICLE AND PARTIAL STERILITY 1 (DPS1) gene encoding a cystathionine β‐synthase (CBS) domain‐containing protein in cuticle development and leaf senescence in rice. The dps1 loss‐of‐function mutant showed leaf senescence phenotype with twisted leaves, significantly reduced chlorophyll content and degenerated chloroplasts characterized by a reduced number of starch granules and an abundance of osmiophilic bodies. Furthermore, dps1 leaves displayed defective cuticle development, reduced wax and cutin compounds, and lower relative water content as compared with wild type. Physiological assays showed significantly higher accumulation of reactive oxygen species (ROS) accompanied by enhanced DNA fragmentation in dps1 leaves, which could be associated with chloroplast degeneration and defective cuticle development. Transcriptome analysis revealed altered expression of several critical genes related to photosynthesis and wax/cutin pathway. This study revealed a crucial role of DPS1 in regulating leaf cuticle development and senescence by affecting the expression of several genes. Thus, a moderate expression of DPS1 is necessary for better plant growth and productivity. [ABSTRACT FROM AUTHOR]

Published

2021

19. DEGENERATED PANICLE AND PARTIAL STERILITY 1 (DPS1) encodes a cystathionine β‐synthase domain containing protein required for anther cuticle and panicle development in rice.

Author

Zafar, Syed Adeel, Patil, Suyash B., Uzair, Muhammad, Fang, Jingjing, Zhao, Jinfeng, Guo, Tingting, Yuan, Shoujiang, Luo, Qian, Shi, Jianxin, Schreiber, Lukas, and Li, Xueyong

Subjects

ANTHER, CUTICLE, PROTEIN domains, RICE, POLLEN, MITOCHONDRIAL proteins, MOLECULAR cloning

Abstract

Summary: Degeneration of apical spikelets and reduced panicle fertility are common reasons for low seed‐setting rate in rice (Oryza sativa). However, little is known about the underlying molecular mechanisms.Here, we report a novel degenerated panicle and partial sterility 1 (dps1) mutant that showed panicle apical degeneration and reduced fertility in middle spikelets. dps1 plants were characterized by small whitish anthers with altered cuticle morphology and absence of pollen grains. Amounts of cuticular wax and cutin were significantly reduced in dps1 anthers. Panicles of dps1 plants showed an accumulation of reactive oxygen species (ROS), lower antioxidant activity, and increased programmed cell death.Map‐based cloning revealed that DPS1 encodes a mitochondrial‐localized protein containing a cystathionine β‐synthase domain that showed the highest expression in panicles and anthers. DPS1 physically interacted with mitochondrial thioredoxin proteins Trx1 and Trx20, and it participated in ROS scavenging. Global gene expression analysis in dps1 revealed that biological processes related to fatty acid metabolism and ROS homeostasis were significantly affected, and the expression of key genes involved in wax and cutin biosynthesis were downregulated.These results suggest that DPS1 plays a vital role in regulating ROS homeostasis, anther cuticle formation, and panicle development in rice. [ABSTRACT FROM AUTHOR]

Published

2020

20. 水稻窄叶突变体nal20 的表型分析与基因定位.

Author

龙海馨, 邱海阳, UZAIR, Muhammad, 房静静, 赵金凤, and 李学勇

Abstract

Copyright of Acta Agronomica Sinica is the property of Crop Science Society of China and its content may not be copied or emailed to multiple sites or posted to a listserv without the copyright holder's express written permission. However, users may print, download, or email articles for individual use. This abstract may be abridged. No warranty is given about the accuracy of the copy. Users should refer to the original published version of the material for the full abstract. (Copyright applies to all Abstracts.)

Published

2018

21. An Improved Mesocotyl Elongation Assay for the Rapid Identification and Characterization of Strigolactone-Related Rice Mutants.

Author

Patil, Suyash, Zafar, Syed Adeel, Uzair, Muhammad, Zhao, Jinfeng, Fang, Jingjing, and Li, Xueyong

Subjects

RICE, PLANT hormones, STRIGOLACTONES, PLANT growth, IDENTIFICATION, CYTOKININS, PLANT parasites

Abstract

Strigolactones (SLs) constitute an important class of plant hormones involved in diverse developmental activities in plant growth and host-parasite interaction. Although substantial progress has been made to understand this pathway, the mechanism of action is still elusive especially with its interaction with other phytohormones and downstream targets. Here we have utilized the negative role of strigolactones in rice (Oryza sativa L.) mesocotyl elongation as a morphological marker for the identification and characterization of new developmental mutants. We observed that deep sown seeds develop longer mesocotyl compared with the surface-grown seeds in the dark condition. Based on this observation, we have developed a method to access mesocotyl elongation consisting of the glass vessel and vermiculite as a growth media. Mesocotyl elongation in the modified deep sown system results in a many-fold increase compared to the surface-grown seeds in the dark condition. External application of SLs analog rac-GR24 rescued the elongated mesocotyl phenotype in the mutant defective in SLs synthesis but not the signaling mutant, demonstrating its applicability in the physiological experiments. The modified mesocotyl elongation assay can be used as a rapid method for characterization and identification of suppressors/enhancers and new developmental mutants in the SLs or its associated pathway saving a huge amount of time and space. [ABSTRACT FROM AUTHOR]

Published

2019

22. Major challenges in widespread adaptation of aerobic rice system and potential opportunities for future sustainability.

Author

Farooq, Muhammad Shahbaz, Fatima, Hira, Rehman, Obaid Ur, Yousuf, Muhammad, Kalsoom, Rabia, Fiaz, Sajid, Khan, Muhammad Ramzan, Uzair, Muhammad, and Huo, Shuhao

Subjects

*SUSTAINABILITY, *RICE, *CEREALS as food, *NITROUS oxide, *GREENHOUSE gases, *CLIMATE change, *WEEDS, *HYBRID rice

Abstract

• Rice is one of the important cereals and staple food for more than half of the world. Climate change and diminishing resources are the major challenges in the sustainable rice production. • Aerobic rice system can be a transformational approach to replace conventional rice in face of climate change and scarcity of resources due to its high input-use efficiency. • Aerobic rice crop failure can be reduced if availability of suitable and stress resistant cultivars with early improved vigour, and short-duration characteristics is ensured for maintaining the reproductive capability under resource stressed environment. • Several constraints are associated with the shift from flooded to aerobic rice brings changes in crop water demand, organic matter (OM) turnover, N dynamics, weed flora, and greenhouse gases (GHGs) emissions. Along with N-losses, continuous monocropping, higher weed infestation, weedy rice emergence, nitrous oxide (N 2 O) emissions, nutrient disorders, higher prevalence of pathogens and diseases, increased panicle sterility, and an increase in soilborne pathogens lodging are other major constraints negatively impacting the widespread adaptation of aerobic rice. • This article reviews the climate change status, its associated impacts on the sustainability of traditional rice system, and the rationale for transforming from traditional to aerobic rice system. • Furthermore, it described the major constraints and challenges associated in the wider adaptation of the new approach for sustainable rice production under in face of projected climate change and scarcity of resources. • Lastly, this article highlights the potential management measures to reduce the associated risks in aerobic rice system. Climate change and diminishing resources are the major challenges in sustainable rice production. The aerobic rice system can be a transformational approach to replace conventional rice in the face of climate change and scarcity of resources due to its high input-use efficiency. However, it could not be adapted widely yet due to several challenges like higher weed infestation and low nitrogen (N) use efficiencies. This transformed system can only be adapted at a wider scale through investigation of associated constraints and risks and provision of potential adjustive measures. Aerobic rice crop failure can be reduced if the availability of suitable and stress-resistant cultivars with early improved vigour, and short-duration characteristics are ensured for maintaining the reproductive capability under resource stressed environment. This transformed rice system exhibits limited response to applied N because of increased losses due to higher volatilization and rapid coupled nitrification-denitrification processes under alternate wetting and drying systems. Shifting from the flooded to aerobic rice system bringing changes in crop water demand, organic matter (OM) turnover, N dynamics, weed flora, and greenhouse gases (GHGs) emissions. Along with N-losses, continuous monocropping, higher weed infestation, weedy rice emergence, nitrous oxide (N 2 O) emissions, nutrient disorders, higher prevalence of pathogens and diseases, increased panicle sterility, and an increase in soilborne pathogens lodging are other major constraints negatively impacting the widespread adaptation of aerobic rice. This article reviews the climate change status, its associated impacts on the sustainability of traditional rice systems, and the rationale for transforming from traditional to aerobic rice systems. Furthermore, it describes the major challenges associated with the aerobic rice system, thereby presenting management strategies ensuring its wider adaptation for sustainable rice production in the face of projected climate change and scarcity of resources. [ABSTRACT FROM AUTHOR]

Published

2023

23. Genome-wide investigation and expression analysis of APETALA-2 transcription factor subfamily reveals its evolution, expansion and regulatory role in abiotic stress responses in Indica Rice (Oryza sativa L. ssp. indica).

Author

Ahmed, Sohaib, Rashid, Muhammad Abdul Rehman, Zafar, Syed Adeel, Azhar, Muhammad Tehseen, Waqas, Muhammad, Uzair, Muhammad, Rana, Iqrar Ahmad, Azeem, Farrukh, Chung, Gyuhwa, Ali, Zulfiqar, and Atif, Rana Muhammad

Subjects

*RICE, *ABIOTIC stress, *TRANSCRIPTION factors, *GENES, *GENE expression profiling, *MICRORNA, *MOLECULAR phylogeny

Abstract

Rice is an important cereal crop that serves as staple food for more than half of the world population. Abiotic stresses resulting from changing climatic conditions are continuously threating its yield and production. Genes in APETALA-2 (AP2) family encode transcriptional regulators implicated during regulation of developmental processes and abiotic stress responses but their identification and characterization in indica rice was still missing. In this context, twenty-six genes distributed among eleven chromosomes in Indica rice encoding AP2 transcription-factor subfamily were identified and their diverse haplotypes were studied. Phylogenetic analysis of OsAP2 TF family-members grouped them into three clades indicating conservation of clades among cereals. Segmental duplications were observed to be principal route of evolution, supporting the higher positive selection-pressure, which were estimated to be originated about 10.57 to 56.72 million years ago (MYA). Conserved domain analysis and intron-exon distribution pattern of identified OsAP2 s revealed their exclusive distribution among the specific clades of the phylogenetic tree. Moreover, the members of osa-miR172 family were also identified potentially targeting four OsAP2 genes. The real-time quantitative expression profiling of OsAP2s under heat stress conditions in contrasting indica rice genotypes revealed the differential expression pattern of OsAP2s (6 genes up-regulated and 4 genes down-regulated) in stress- and genotype-dependent manner. These findings unveiled the evolutionary pathways of AP2-TF in rice, and can help the functional characterization under developmental and stress responses • Genome-wide analysis of AP2 transcription factor sub-family resulted in identification of 26 members in Oryza sativa L. ssp. indica • Phylogenetic analysis of OsAP2s grouped them into three clades; where members of each clade tend to share similar conserved domains and intron/exon distribution pattern. • Segmental duplication observed to be principal route of evolution, supporting the higher positive selection-pressure originated about 10.57 to 56.72 million years ago. • The micro RNAs of osa-miR172 family potentially targets four AP2 members in rice. • The qRT-PCR based expression profiling of OsAP2 genes revealed their differential regulation under heat stress conditions in heat-tolerant and heat-sensitive rice genotypes. [ABSTRACT FROM AUTHOR]

Published

2021