Model validation of simple-graph representations of metabolism

Holme, Petter

doi:10.1098/rsif.2008.0489

Cited by 23 publications

(35 citation statements)

References 21 publications

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“…These metabolic networks are the same as those studied in [20] which were constructed using the KEGG database [13]. Note that, there are a number of ways of representing the set of metabolic reactions of an organism as a simple graph [12], the most popular of which is a substrate-product graph whereby each node corresponds to a metabolite, and a connection is made between reacting substances (substrates) and the products of the reaction. One potential caveat of such an approach, is that it can lead to the erroneous identification of metabolic pathways.…”

Section: Metabolic Network Of Bacteriamentioning

confidence: 99%

A statistical mechanics description of environmental variability in metabolic networks

Crofts

Estrada

2013

J Math Chem

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Many of the chemical reactions that take place within a living cell are irreversible. Due to evolutionary pressures, the number of allowable reactions within these systems are highly constrained and thus the resulting metabolic networks display considerable asymmetry. In this paper, we explore possible evolutionary factors pertaining to the reduced symmetry observed in these networks, and demonstrate the important role environmental variability plays in shaping their structural organization. Interpreting the returnability index as an equilibrium constant for a reaction network in equilibrium with a hypothetical reference system, enables us to quantify the extent to which a metabolic network is in disequilibrium. Further, by introducing a new directed centrality measure via an extension of the subgraph centrality metric to directed networks, we are able to characterise individual metabolites by their participation within metabolic pathways. To demonstrate these ideas, we study 116 metabolic networks of bacteria. In particular, we find that the equilibrium constant for the metabolic networks decreases significantly in-line with variability in bacterial habitats, supporting the view that environmental variability promotes disequilibrium within these biochemical reaction systems.

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Section: Metabolic Network Of Bacteriamentioning

confidence: 99%

A statistical mechanics description of environmental variability in metabolic networks

Crofts

Estrada

2013

J Math Chem

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“…6 and 7, respectively. Then we applied overlap score to quantity the similarity between the two partitions of cancers respectively generated from gene expression and protein complex profiles4546 and got the value of overlap score as 0.72. We then generated 200 pairs of random clusters of the cancers, in which the cluster sizes are the same as in the real data.…”

Section: Resultsmentioning

confidence: 99%

“…We use overlap score to measure the overlap extent of cancer clusters respectively generated from gene expression and protein complex profiles4546. Consider two different categories A and B (for example, two partitions of cancers got by different clustering methods) and assume each cancer is associated with a subset (cluster) of the partitions of A and B.…”

Section: Methodsmentioning

confidence: 99%

The Network Organization of Cancer-associated Protein Complexes in Human Tissues

Zhao

Lee

Huss

et al. 2013

Sci Rep

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Differential gene expression profiles for detecting disease genes have been studied intensively in systems biology. However, it is known that various biological functions achieved by proteins follow from the ability of the protein to form complexes by physically binding to each other. In other words, the functional units are often protein complexes rather than individual proteins. Thus, we seek to replace the perspective of disease-related genes by disease-related complexes, exemplifying with data on 39 human solid tissue cancers and their original normal tissues. To obtain the differential abundance levels of protein complexes, we apply an optimization algorithm to genome-wide differential expression data. From the differential abundance of complexes, we extract tissue- and cancer-selective complexes, and investigate their relevance to cancer. The method is supported by a clustering tendency of bipartite cancer-complex relationships, as well as a more concrete and realistic approach to disease-related proteomics.

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“…The problem of characterizing the global structure of real-world systems is further compounded by the fact there are often many ways to coarse-grain a real system to generate a network representation, each corresponding to a different way for set of interactions to be projected onto a graph. For example, metabolic networks may be represented as unipartite or bipartite graphs, depending on whether one chooses to focus solely on the statistics over molecules (or reactions) and their interactions (requiring a unipartite representation) or instead to include both molecules and reactions as explicit nodes in the graph (where molecules and reactions represent two classes of nodes in a bipartite representation) [32][33][34]. These graphs can have different large-scale topological properties, even when projected from the same underlying system.…”

Section: Sept 2020 2/23mentioning

confidence: 99%

Scarcity of scale-free topology is universal across biochemical networks

Smith

Kim

Walker

2020

Preprint

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Biochemical reactions underlie all living processes. Like many biological and technological systems, their complex web of interactions is difficult to fully capture and quantify with simple mathematical objects. Nonetheless, a huge volume of research has suggested many real-world biological and technological systems – including biochemical systems – can be described rather simply as ‘scale-free’ networks, characterized by a power-law degree distribution. More recently, rigorous statistical analyses across a variety of systems have upended this view, suggesting truly scale-free networks may be rare. We provide a first application of these newer methods across two distinct levels of biological organization: analyzing a large ensemble of biochemical networks generated from the reactions encoded in 785 ecosystem-level metagenomes and 1082 individual-level genomes (representing all three domains of life). Our results confirm only a few percent of individual and ecosystem-level biochemical networks meet the criteria necessary to be anything more than super-weakly scale-free. Leveraging the simultaneous analysis of the multiple coarse-grained projections of biochemistry, we perform distinguishability tests across properties of individual and ecosystem-level biochemical networks to determine whether or not they share common structure, indicative of common generative mechanisms across levels. Our results indicate there is no sharp transition in the organization of biochemistry across distinct levels of the biological hierarchy - a result that holds across different network projections. This suggests the existence of common organizing principles operating across different levels of organization in biochemical networks, independent of the project chosen.Author SummaryFully characterizing living systems requires rigorous analysis of the complex webs of interactions governing living processes. Here we apply statistical approaches to analyze a large data set of biochemical networks across two levels of organization: individuals and ecosystems. We find that independent of level of organization, the standard ‘scale-free’ model is not a good description of the data. Interestingly, there is no sharp transition in the shape of degree distributions for biochemical networks when comparing those of individuals to ecosystems. This suggests the existence of common organizing principles operating across different levels of biochemical organization that are revealed across different network projections.

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Model validation of simple-graph representations of metabolism

Cited by 23 publications

References 21 publications

A statistical mechanics description of environmental variability in metabolic networks

A statistical mechanics description of environmental variability in metabolic networks

The Network Organization of Cancer-associated Protein Complexes in Human Tissues

Scarcity of scale-free topology is universal across biochemical networks

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