Modeling antibiotic resistance in the microbiota using multi-level Petri Nets

Bardini, Roberta; Carlo, Stefano Di; Politano, Gianfranco; Benso, Alfredo

doi:10.1186/s12918-018-0627-1

Cited by 12 publications

(10 citation statements)

References 30 publications

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“…In particular, we believe that a recent approach based on the introduction of the multiple-layer networks could be of great potential interest ( e.g. to search for a general scheme behind antimicrobial resistance [ 46 - 50 ]).…”

Section: Discussionmentioning

confidence: 99%

Bacterial Protein Interaction Networks: Connectivity is Ruled by Gene Conservation, Essentiality and Function

Dilucca

Cimini

Giansanti

2021

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Background: Protein-protein interaction (PPI) networks are the backbone of all processes in living cells. In this work we relate conservation, essentiality and functional repertoire of a gene to the connectivity k (i.e. the number of interactions, links) of the corresponding protein in the PPI network. Methods: On a set of 42 bacterial genomes of different sizes, and with reasonably separated evolutionary trajectories, we investigate three issues: i) whether the distribution of connectivities changes between PPI subnetworks of essential and nonessential genes; ii) how gene conservation, measured both by the evolutionary retention index (ERI) and by evolutionary pressures, is related to the connectivity of the corresponding protein; iii) how PPI connectivities are modulated by evolutionary and functional relationships, as represented by the Clusters of Orthologous Genes (COGs). Results: We show that conservation, essentiality and functional specialisation of genes constrains the connectivity of the corresponding proteins in bacterial PPI networks. In particular, we isolated a core of highly connected proteins (connectivities k≥40), which is ubiquitous among the species considered here, though mostly visible in the degree distributions of bacteria with small genomes (less than 1000 genes). Conclusion: The genes that support this highly connected core are conserved, essential and, in most cases, belong to the COG cluster J, related to ribosomal functions and to the processing of genetic information.

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Section: Discussionmentioning

confidence: 99%

Bacterial Protein Interaction Networks: Connectivity is Ruled by Gene Conservation, Essentiality and Function

Dilucca

Cimini

Giansanti

2021

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“…It is notable that, while case–control studies evaluate risk factors involved in the transition from a step to another of the pathophysiological hypothesis, they do not discriminate the exact intra-host and host-microbiota mechanisms and dynamics involving the antibiotic in this transition, which are better approached through mathematical models and require microbiome analysis [ 10 , 81 , 82 ]. In the example discussed above, a micro-level pathophysiological hypothesis could involve further steps between asymptomatic carriage and infection with ESBL-p E. coli ST131 ( Figure 1 ): (1) depletion in other phylotypes of E. coli in the host microbiota [ 64 ]; (2) increase in lateral gene transfer of the ESBL gene within or between bacterial species [ 81 ]; (3) increase in density of ESBL-p E. coli ST131 among the host’s flora [ 64 ] (which could be important for infections such as BSI [ 63 ]), with a loss of bacterial diversity. All these steps could be happening within the host microbiota of subjects carrying ESBL-p E. coli ST131 and be influenced by the selective pressure of antibiotics.…”

Section: Pathophysiological Hypothesesmentioning

confidence: 99%

From Pathophysiological Hypotheses to Case–Control Study Design: Resistance from Antibiotic Exposure in Community-Onset Infections

et al. 2022

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Antimicrobial resistance is a global public health concern, at least partly due to the misuse of antibiotics. The increasing prevalence of antibiotic-resistant infections in the community has shifted at-risk populations into the general population. Numerous case–control studies attempt to better understand the link between antibiotic use and antibiotic-resistant community-onset infections. We review the designs of such studies, focusing on community-onset bloodstream and urinary tract infections. We highlight their methodological heterogeneity in the key points related to the antibiotic exposure, the population and design. We show the impact of this heterogeneity on study results, through the example of extended-spectrum β-lactamases producing Enterobacteriaceae. Finally, we emphasize the need for the greater standardization of such studies and discuss how the definition of a pathophysiological hypothesis specific to the bacteria–resistance pair studied is an important prerequisite to clarify the design of future studies.

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“…A model that aims to express biological complexity must consider that physical parts used in biofabrication are multi-level systems, from the single bioprocess to the multicellular aggregate [34]. To capture their complexity, models must express multi-level and quantitative information, as well as the dynamic simulation of complex biological processes [35, 36]. Multi-level and hybrid modeling approaches consistently combine models based on different formalisms and centered over different system levels to comprise more of their hierarchical organization, and heterogeneity [37].…”

Section: Introductionmentioning

confidence: 99%

Computational Methods for Biofabrication in Tissue Engineering and Regenerative Medicine - a literature review

Bardini

Carlo

2023

Preprint

Self Cite

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Biofabrication is the generation of biologically functional products from living cells and biomaterials through bioprinting and subsequent maturation processes. Technological and scientific domains are underlying biofabrication ranging from biology to automated manufacturing and culture systems. Among its application domains, Tissue Engineering and Regenerative Medicine poses strict quality requirements for biofabrication, requiring fast and disruptive innovation for processes and products to comply. Innovation in biofabrication is slow and incremental, relying on R&D processes that are inefficient (slow, risky, and costly), ineffective (products have sub-optimal quality), and challenging to replicate. While automation and digitalization support process execution, design, and innovation, they often work as tools for empirical, problem-specific, and operator-dependent approaches. On the other hand, computational approaches support biofabrication process modeling, design, and optimization of experimental activity to improve the quality of processes and products. To express their full potential, computational methods must factor in the biological complexity underlying biofabrication. This review analyzes computational approaches to biofabrication process modeling, design, and optimization with a focus on solutions explicitly accounting for biological complexity.

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Modeling antibiotic resistance in the microbiota using multi-level Petri Nets

Cited by 12 publications

References 30 publications

Bacterial Protein Interaction Networks: Connectivity is Ruled by Gene Conservation, Essentiality and Function

Bacterial Protein Interaction Networks: Connectivity is Ruled by Gene Conservation, Essentiality and Function

From Pathophysiological Hypotheses to Case–Control Study Design: Resistance from Antibiotic Exposure in Community-Onset Infections

Computational Methods for Biofabrication in Tissue Engineering and Regenerative Medicine - a literature review

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