Your search keyword '"Transport network"' showing total 7 results

1. Network topology enables efficient response to environment in Physarum polycephalum .

Author

Chen S and Alim K

Subjects

Models, Biological, Physarum polycephalum physiology

Abstract

The network-shaped body plan distinguishes the unicellular slime mould Physarum polycephalum in body architecture from other unicellular organisms. Yet, network-shaped body plans dominate branches of multi-cellular life such as in fungi. What survival advantage does a network structure provide when facing a dynamic environment with adverse conditions? Here, we probe how network topology impacts P. polycephalum 's avoidance response to an adverse blue light. We stimulate either an elongated, I-shaped amoeboid or a Y-shaped networked specimen and subsequently quantify the evacuation process of the light-exposed body part. The result shows that Y-shaped specimen complete the avoidance retraction in a comparable time frame, even slightly faster than I-shaped organisms, yet, at a lower almost negligible increase in migration velocity. Contraction amplitude driving mass motion is further only locally increased in Y-shaped specimen compared to I-shaped-providing further evidence that Y-shaped's avoidance reaction is energetically more efficient than in I-shaped amoeboid organisms. The difference in the retraction behaviour suggests that the complexity of network topology provides a key advantage when encountering adverse environments. Our findings could lead to a better understanding of the transition from unicellular to multicellularity., (Creative Commons Attribution license.)

Published

2023

2. Fungal Wound Healing through Instantaneous Protoplasmic Gelation.

Author

Nguyen TA, Le S, Lee M, Fan JS, Yang D, Yan J, and Jedd G

Subjects

Fungal Proteins genetics, Hydrodynamics, Hyphae cytology, Intravital Microscopy, Loss of Function Mutation, Mucor cytology, Protein Domains, Protein Multimerization physiology, Cytoplasm metabolism, Fungal Proteins metabolism, Hyphae metabolism, Mucor physiology

Abstract

Multicellular organisms employ fluid transport networks to overcome the limit of diffusion and promote essential long-distance transport. Connectivity and pressurization render these networks especially vulnerable to wounding. To mitigate this risk, animals, plants, and multicellular fungi independently evolved elaborate clotting and plugging mechanisms. In the septate filamentous fungi, membrane-bound organelles plug septal pores in wounded hyphae. By contrast, vegetative hyphae in the early-diverging Mucoromycota are largely aseptate, and how their hyphae respond to wounding is unknown. Here, we show that wounding in the Mucorales leads to explosive protoplasmic discharge that is rapidly terminated by protoplasmic gelation. We identify Mucoromycota-specific Gellin proteins, whose loss of function leads to uncontrolled wound-induced protoplasmic bleeding. Gellins contain ten related β-trefoil Gll domains, each of which possesses unique features that impart distinct gelation-related properties: some readily unfold and form high-order sheet-like structures when subjected to mechanical force from flow, while others possess hydrophobic motifs that enable membrane binding. In cell-free reconstitution, sheet-like structures formed by a partial Gellin incorporate membranous organelles. Together, these data define a mechanistic basis for regulated protoplasmic gelation, and provide new design principles for the development of artificial flow-responsive biomaterials., Competing Interests: Declaration of Interests The authors declare no competing interests., (Copyright © 2020 Elsevier Inc. All rights reserved.)

Published

2021

3. Scaling effect in COVID-19 spreading: The role of heterogeneity in a hybrid ODE-network model with restrictions on the inter-cities flow.

Author

Miranda JGV, Silva MS, Bertolino JG, Vasconcelos RN, Cambui ECB, Araújo MLV, Saba H, Costa DP, Duverger SG, Oliveira MT, Neto HSA, Franca-Rocha WJS, Jorge DCP, de Oliveira JF, Andrade RFS, and do Rosário RS

Abstract

The new Covid-19 pandemic has left traces of suffering and devastation to individuals of almost all countries worldwide and severe impact on the global economy. Understanding the clinical characteristics, interactions with the environment, and the variables that favor or hinder its dissemination help the public authorities in the fight and prevention, leading for a rapid response in society. Using models to estimate contamination scenarios in real time plays an important role. Population compartments models based on ordinary differential equations (ODE) for a given region assume two homogeneous premises, the contact mechanisms and diffusion rates, disregarding heterogeneous factors as different contact rates for each municipality and the flow of contaminated people among them. This work considers a hybrid model for covid-19, based on local SIR models and the population flow network among municipalities, responsible for a complex lag dynamic in their contagion curves. Based on actual infection data, local contact rates ( β ) are evaluated. The epidemic evolution at each municipality depends on the local SIR parameters and on the inter-municipality transport flow. When heterogeneity of β values and flow network are included, forecasts differ from those of the homogeneous ODE model. This effect is more relevant when more municipalities are considered, hinting that the latter overestimates new cases. In addition, mitigation scenarios are assessed to evaluate the effect of earlier interventions reducing the inter-municipality flux. Restricting the flow between municipalities in the initial stage of the epidemic is fundamental for flattening the contamination curve, highlighting advantages of a contamination lag between the capital curve and those of other municipalities in the territories., Competing Interests: The authors declare that they have no known competing financial interests or personal relationships that could have appeared to influence the work reported in this paper., (© 2020 Elsevier B.V. All rights reserved.)

Published

2021

4. Are Hong Kong and Taiwan stepping-stones for invasive species to the mainland of China?

Author

Lu J, Li SP, Wu Y, and Jiang L

Abstract

Understanding the origins and introduction pathways of invasive species is a fundamental issue for invasion biology, which is necessary for predicting and preventing future invasion. Once an invasive species is established in a new location, this location could serve as a stepping-stone for further invasions. However, such "stepping-stone" effect has not been widely investigated. Using the published literature and records, we compiled the first found locations of 127 top invasive species in China. Our study showed that the most common landing spots of these invasive species were Hong Kong (22 species) and Taiwan (20 species), which accounted for one-third of the invasive species in China. Our analysis revealed that the invasive species in mainland China were more likely to transport from Hong Kong than Macau, a neighboring region with a similar area and colonial history. Similarly, more invasive species were also first landed on Taiwan than Hainan, a nearby island sharing similar climate conditions. Together, our findings indicate that Hong Kong and Taiwan are the most important stepping-stones for invasive species to the mainland of China and suggesting that the increasing trade exchange of China's coastal ports constitutes a potential risk for the spread of more invasive species. We suppose that they would be the future stepping-stones for invasive species to the mainland of China and these coastal ports regions where improved biosecurity is needed now.

Published

2018

5. Global network centrality of university rankings.

Author

Guo W, Del Vecchio M, and Pogrebna G

Abstract

Universities and higher education institutions form an integral part of the national infrastructure and prestige. As academic research benefits increasingly from international exchange and cooperation, many universities have increased investment in improving and enabling their global connectivity. Yet, the relationship of university performance and its global physical connectedness has not been explored in detail. We conduct, to our knowledge, the first large-scale data-driven analysis into whether there is a correlation between university relative ranking performance and its global connectivity via the air transport network. The results show that local access to global hubs (as measured by air transport network betweenness ) strongly and positively correlates with the ranking growth (statistical significance in different models ranges between 5% and 1% level). We also found that the local airport's aggregate flight paths ( degree ) and capacity ( weighted degree ) has no effect on university ranking, further showing that global connectivity distance is more important than the capacity of flight connections. We also examined the effect of local city economic development as a confounding variable and no effect was observed suggesting that access to global transportation hubs outweighs economic performance as a determinant of university ranking. The impact of this research is that we have determined the importance of the centrality of global connectivity and, hence, established initial evidence for further exploring potential connections between university ranking and regional investment policies on improving global connectivity., Competing Interests: We declare we have no competing interests.

Published

2017

6. Mechanism of signal propagation in Physarum polycephalum .

Author

Alim K, Andrew N, Pringle A, and Brenner MP

Subjects

Models, Biological, Physarum polycephalum physiology, Signal Transduction physiology

Abstract

Complex behaviors are typically associated with animals, but the capacity to integrate information and function as a coordinated individual is also a ubiquitous but poorly understood feature of organisms such as slime molds and fungi. Plasmodial slime molds grow as networks and use flexible, undifferentiated body plans to forage for food. How an individual communicates across its network remains a puzzle, but Physarum polycephalum has emerged as a novel model used to explore emergent dynamics. Within P. polycephalum , cytoplasm is shuttled in a peristaltic wave driven by cross-sectional contractions of tubes. We first track P. polycephalum 's response to a localized nutrient stimulus and observe a front of increased contraction. The front propagates with a velocity comparable to the flow-driven dispersion of particles. We build a mathematical model based on these data and in the aggregate experiments and model identify the mechanism of signal propagation across a body: The nutrient stimulus triggers the release of a signaling molecule. The molecule is advected by fluid flows but simultaneously hijacks flow generation by causing local increases in contraction amplitude as it travels. The molecule is initiating a feedback loop to enable its own movement. This mechanism explains previously puzzling phenomena, including the adaptation of the peristaltic wave to organism size and P. polycephalum 's ability to find the shortest route between food sources. A simple feedback seems to give rise to P. polycephalum 's complex behaviors, and the same mechanism is likely to function in the thousands of additional species with similar behaviors., Competing Interests: The authors declare no conflict of interest.

Published

2017

7. Combining flow cytometry and 16S rRNA gene pyrosequencing: a promising approach for drinking water monitoring and characterization.

Author

Prest EI, El-Chakhtoura J, Hammes F, Saikaly PE, van Loosdrecht MC, and Vrouwenvelder JS

Subjects

DNA, Bacterial genetics, Netherlands, RNA, Ribosomal, 16S genetics, Sequence Analysis, DNA, Water Supply, DNA Fingerprinting, Drinking Water microbiology, Environmental Monitoring methods, Flow Cytometry, Water Quality

Abstract

The combination of flow cytometry (FCM) and 16S rRNA gene pyrosequencing data was investigated for the purpose of monitoring and characterizing microbial changes in drinking water distribution systems. High frequency sampling (5 min intervals for 1 h) was performed at the outlet of a treatment plant and at one location in the full-scale distribution network. In total, 52 bulk water samples were analysed with FCM, pyrosequencing and conventional methods (adenosine-triphosphate, ATP; heterotrophic plate count, HPC). FCM and pyrosequencing results individually showed that changes in the microbial community occurred in the water distribution system, which was not detected with conventional monitoring. FCM data showed an increase in the total bacterial cell concentrations (from 345 ± 15 × 10(3) to 425 ± 35 × 10(3) cells mL(-1)) and in the percentage of intact bacterial cells (from 39 ± 3.5% to 53 ± 4.4%) during water distribution. This shift was also observed in the FCM fluorescence fingerprints, which are characteristic of each water sample. A similar shift was detected in the microbial community composition as characterized with pyrosequencing, showing that FCM and genetic fingerprints are congruent. FCM and pyrosequencing data were subsequently combined for the calculation of cell concentration changes for each bacterial phylum. The results revealed an increase in cell concentrations of specific bacterial phyla (e.g., Proteobacteria), along with a decrease in other phyla (e.g., Actinobacteria), which could not be concluded from the two methods individually. The combination of FCM and pyrosequencing methods is a promising approach for future drinking water quality monitoring and for advanced studies on drinking water distribution pipeline ecology., (Copyright © 2014 Elsevier Ltd. All rights reserved.)

Published

2014