Categorizing Biases in High-Confidence High-Throughput Protein-Protein Interaction Data Sets

Yu, Xueping; Ivanic, Joseph; Memišević, Vesna; Wallqvist, Anders; Reifman, Jaques

doi:10.1074/mcp.m111.012500

Cited by 25 publications

(23 citation statements)

References 58 publications

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“…Note that this requirement for the availability of noise data biases analyses towards the properties of higher-abundance proteins. Fortuitously, this makes ACMS a more reliable metric of “true” PPIs [5,24], strengthening our interpretation of the results.…”

Section: Resultssupporting

confidence: 62%

Protein stickiness, rather than number of functional protein-protein interactions, predicts expression noise and plasticity in yeast

Brettner

Masel

2012

BMC Syst Biol

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BackgroundA hub protein is one that interacts with many functional partners. The annotation of hub proteins, or more generally the protein-protein interaction “degree” of each gene, requires quality genome-wide data. Data obtained using yeast two-hybrid methods contain many false positive interactions between proteins that rarely encounter each other in living cells, and such data have fallen out of favor.ResultsWe find that protein “stickiness”, measured as network degree in ostensibly low quality yeast two-hybrid data, is a more predictive genomic metric than the number of functional protein-protein interactions, as assessed by supposedly higher quality high throughput affinity capture mass spectrometry data. In the yeast Saccharomyces cerevisiae, a protein’s high stickiness, but not its high number of functional interactions, predicts low stochastic noise in gene expression, low plasticity of gene expression across different environments, and high probability of forming a homo-oligomer. Our results are robust to a multiple regression analysis correcting for other known predictors including protein abundance, presence of a TATA box and whether a gene is essential. Once the higher stickiness of homo-oligomers is controlled for, we find that homo-oligomers have noisier and more plastic gene expression than other proteins, consistent with a role for homo-oligomerization in mediating robustness.ConclusionsOur work validates use of the number of yeast two-hybrid interactions as a metric for protein stickiness. Sticky proteins exhibit low stochastic noise in gene expression, and low plasticity in expression across different environments.

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Section: Resultssupporting

confidence: 62%

Protein stickiness, rather than number of functional protein-protein interactions, predicts expression noise and plasticity in yeast

Brettner

Masel

2012

BMC Syst Biol

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“…In our analyses, we separately identified significantly activated (up-regulated) and suppressed (down-regulated) genes using an FDR-corrected p-value of 0.05 as the statistical significance cutoff. We considered upand down-regulated genes separately, as biological processes are characterized by interacting, co-regulated proteins (Yu et al, 2011). We carried out the rank product analyses separately for each combination of brain region and time point in either seizing or non-seizing rats.…”

Section: 2mentioning

confidence: 99%

Neuroprotective mechanisms activated in non-seizing rats exposed to sarin

Spradling-Reeves

Dillman

et al. 2015

Brain Research

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Exposure to organophosphate (OP) nerve agents, such as sarin, may lead to uncontrolled seizures and irreversible brain injury and neuropathology. In rat studies, a median lethal dose of sarin leads to approximately half of the animals developing seizures. Whereas previous studies analyzed transcriptomic effects associated with seizing sarin-exposed rats, our study focused on the cohort of sarin-exposed rats that did not develop seizures. We analyzed the genomic changes occurring in sarin-exposed, non-seizing rats and compared differentially expressed genes and pathway activation to those of seizing rats. At the earliest time point (0.25 h) and in multiple sarin-sensitive brain regions, defense response genes were commonly expressed in both groups of animals as compared to the control groups. All sarin-exposed animals activated the MAPK signaling pathway, but only the seizing rats activated the apoptotic-associated JNK and p38 MAPK signaling sub-pathway. A unique phenotype of the non-seizing rats was the altered expression levels of genes that generally suppress inflammation or apoptosis. Importantly, the early transcriptional response for inflammation- and apoptosis-related genes in the thalamus showed opposite trends, with significantly down-regulated genes being up-regulated, and vice versa, between the seizing and non-seizing rats. These observations lend support to the hypothesis that regulation of anti-inflammatory genes might be part of an active and sufficient response in the non-seizing group to protect against the onset of seizures. As such, stimulating or activating these responses via pretreatment strategies could boost resilience against nerve agent exposures.

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“…87 Both methods can produce high-quality interactions, but each provides fundamentally different information with unique limitations. 88,89 Protein complexes measured by AP/MS have ambiguous network interpretations because they can be represented either by the spoke model, in which interactions are inferred only between the bait and each prey protein in the purified complex, or by the fully connected model, in which each protein in the complex is assumed to interact with all other proteins. In contrast, interactions measured by Y2H are more naturally interpreted as binary, pairwise interactions.…”

Section: Ppi Networkmentioning

confidence: 99%

“…[100][101][102][103][104][105] Such analysis recovers coregulated, highly connected subnetworks (or functional protein interaction modules) that have been found to characterize biological processes 89 or to work together to produce a cellular phenotype. 80 Several algorithms exist for decomposing PPI networks into functional modules.…”

Section: Ppi Networkmentioning

confidence: 99%

Systems Biology Approaches for Discovering Biomarkers for Traumatic Brain Injury

Feala

AbdulHameed²,

Yu³

et al. 2013

Journal of Neurotrauma

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The rate of traumatic brain injury (TBI) in service members with wartime injuries has risen rapidly in recent years, and complex, variable links have emerged between TBI and long-term neurological disorders. The multifactorial nature of TBI secondary cellular response has confounded attempts to find cellular biomarkers for its diagnosis and prognosis or for guiding therapy for brain injury. One possibility is to apply emerging systems biology strategies to holistically probe and analyze the complex interweaving molecular pathways and networks that mediate the secondary cellular response through computational models that integrate these diverse data sets. Here, we review available systems biology strategies, databases, and tools. In addition, we describe opportunities for applying this methodology to existing TBI data sets to identify new biomarker candidates and gain insights about the underlying molecular mechanisms of TBI response. As an exemplar, we apply network and pathway analysis to a manually compiled list of 32 protein biomarker candidates from the literature, recover known TBI-related mechanisms, and generate hypothetical new biomarker candidates.

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Categorizing Biases in High-Confidence High-Throughput Protein-Protein Interaction Data Sets

Cited by 25 publications

References 58 publications

Protein stickiness, rather than number of functional protein-protein interactions, predicts expression noise and plasticity in yeast

Protein stickiness, rather than number of functional protein-protein interactions, predicts expression noise and plasticity in yeast

Neuroprotective mechanisms activated in non-seizing rats exposed to sarin

Systems Biology Approaches for Discovering Biomarkers for Traumatic Brain Injury

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