PICKLE 2.0: A human protein-protein interaction meta-database employing data integration via genetic information ontology

Gioutlakis, Aris; Klapa, Maria I.; Moschonas, Nicholas Κ.

doi:10.1371/journal.pone.0186039

Cited by 42 publications

(53 citation statements)

References 24 publications

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“…We also tested if proportion of Neanderthal ancestry was positively correlated with local population-scaled recombination rate (as inferred by Myers et al (2005)), which would be suggestive of selec- If DMIs were the cause of selection against introgression, then we would expect that genes that code for proteins with more binding partners would be less likely to be introgressed; each proteinprotein interaction (PPI) can be thought of as a possible DMI. To test this hypothesis, we used the PICKLE2.0 PPI network (Gioutlakis, Klapa, & Moschonas, 2017;Klapa, Tsafou, Theodoridis, Tsakalidis, & Moschonas, 2013) and associated a number of binding partners to each gene by counting the number of PPIs in which the protein coded by that gene participates. We found an insignificant correlation between number of binding partners and mean frequency of introgression in both populations (Spearman's q = À.016, p = .314 in CEU, q = À0.003, p = .858 in CHB + CHS, two-sided bootstrap-like test), which provide weak indirect evidence against the DMI hypothesis.…”

Section: Causes Of Selection Against Neanderthal Introgressionmentioning

confidence: 99%

Model‐based detection and analysis of introgressed Neanderthal ancestry in modern humans

et al. 2018

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Genetic evidence has revealed that the ancestors of modern human populations outside Africa and their hominin sister groups, notably Neanderthals, exchanged genetic material in the past. The distribution of these introgressed sequence tracts along modern-day human genomes provides insight into the selective forces acting on them and the role of introgression in the evolutionary history of hominins. Studying introgression patterns on the X-chromosome is of particular interest, as sex chromosomes are thought to play a special role in speciation. Recent studies have developed methods to localize introgressed ancestries, reporting long regions that are depleted of Neanderthal introgression and enriched in genes, suggesting negative selection against the Neanderthal variants. On the other hand, enriched Neanderthal ancestry in hair- and skin-related genes suggests that some introgressed variants facilitated adaptation to new environments. Here, we present a model-based introgression detection method called dical-admix. We demonstrate its efficiency and accuracy through extensive simulations and apply it to detect tracts of Neanderthal introgression in modern human individuals from the 1000 Genomes Project. Our findings are largely concordant with previous studies, consistent with weak selection against Neanderthal ancestry. We find evidence that selection against Neanderthal ancestry was due to higher genetic load in Neanderthals resulting from small effective population size, rather than widespread Dobzhansky-Müller incompatibilities (DMIs) that could contribute to reproductive isolation. Moreover, we confirm the previously reported low level of introgression on the X-chromosome, but find little evidence that DMIs contributed to this pattern.

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Section: Causes Of Selection Against Neanderthal Introgressionmentioning

confidence: 99%

Model‐based detection and analysis of introgressed Neanderthal ancestry in modern humans

et al. 2018

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“…If DMIs were the cause of selection against introgression, then we would expect that genes that code for proteins with more binding partners would be less likely to be introgressed; each protein-protein interaction (PPI) can be thought of as a possible DMI. To test this hypothesis, we used the PICKLE2.0 PPI network (Klapa et al, 2013;Gioutlakis et al, 2017) and associated a number of binding partners to each gene by counting the number of PPIs in which the protein coded by that gene participates. We found an insignificant correlation between number of binding partners and mean frequency of introgression in both populations (Spearman's ρ = −0.002, p = 0.915 in CEU, ρ = 0.007, p = 0.648 in CHB+CHS, two-sided bootstrap-like test), which provides indirect evidence against the DMI hypothesis.…”

Section: Causes Of Selection Against Neanderthal Introgressionmentioning

confidence: 99%

Model-based detection and analysis of introgressed Neanderthal ancestry in modern humans

Steinrücken

Spence

Kamm

et al. 2017

Preprint

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Genetic evidence has revealed that the ancestors of modern human populations outside of Africa and their hominin sister groups, notably the Neanderthals, exchanged genetic material in the past. The distribution of these introgressed sequence-tracts along modern-day human genomes provides insight into the ancient structure and migration patterns of these archaic populations. Furthermore, it facilitates studying the selective processes that lead to the accumulation or depletion of introgressed genetic variation. Recent studies have developed methods to localize these introgressed regions, reporting long regions that are depleted of Neanderthal introgression and enriched in genes, suggesting negative selection against the Neanderthal variants. On the other hand, enriched Neanderthal ancestry in hair-and skin-related genes suggests that some introgressed variants facilitated adaptation to new environments. Here, we present a model-based method called diCal-admix and apply it to detect tracts of Neanderthal introgression in modern humans. We demonstrate its efficiency and accuracy through extensive simulations. We use our method to detect introgressed regions in modern human individuals from the 1000 Genomes Project, using a high coverage genome from a Neanderthal individual from the Altai mountains as reference. Our introgression detection results and findings concerning their functional implications are largely concordant with previous studies, and are consistent with weak selection against Neanderthal ancestry. We find some evidence that selection against Neanderthal ancestry was due to higher genetic load in Neanderthals, resulting from small effective population size, rather than Dobzhansky-Müller incompatibilities. Finally, we investigate the role of the X-chromosome in the divergence between Neanderthals and modern humans.

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“…The overall structure of MAPSD is provided in Figure 1. MAPSD starts with a large-scale protein-protein interaction (PPI) network which was assembled from multiple sources [30][31][32][33] (see Experimental Procedures). Using the PPI network, an affinity matrix is created.…”

Section: Overview Of the Mapsd Frameworkmentioning

confidence: 99%

“…Interaction networks used in this study were collected from three sources including: PICKLE 2.3 32,33 , The Human Reference Interactome 31 , and human Interactome Database 30 . Upon removing the duplicate interaction, the final network being used by MAPSD contained 232,801 interactions.…”

Section: Description Of the Data Used In The Studymentioning

confidence: 99%

Cell type-specific proteogenomic signal diffusion for integrating multi-omics data predicts novel schizophrenia risk genes

Torshizi

Duan

Wang

2020

Preprint

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Accumulation of diverse types of omics data on schizophrenia (SCZ) requires a systems approach to jointly modeling the interplay between genome, transcriptome and proteome. Proteome dynamics, as the definitive cellular machinery in human body, has been lagging behind the research on genome/transcriptome in the context of SCZ, both at tissue and single-cell resolution. We introduce a Markov Affinity-based Proteogenomic Signal Diffusion (MAPSD) method to model intra-cellular protein trafficking paradigms and tissue-wise single-cell protein abundances. MAPSD integrates multi-omics data to amplify the signals at SCZ risk loci with small effect sizes, and reveal convergent diseaseassociated gene modules in the brain interactome as well as more than 130 tissue/cell-type combinations. We predicted a set of high-confidence SCZ risk genes, the majority of which are not directly connected to SCZ susceptibility risk genes. We characterized the subcellular localization of proteins encoded by candidate SCZ risk genes in various brain regions, and illustrated that most are enriched in neuronal and Purkinje cells in cerebral cortex. We demonstrated how the identified gene set may be involved in different developmental stages of the brain, how they alter SCZ-related biological pathways, and how they can be effectively leveraged for drug repurposing. MAPSD can be applied to other polygenic diseases, yet our case study on SCZ signifies how tissue-adjusted protein-protein interaction networks can assist in generating deeper insights into the orchestration of polygenic diseases.

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PICKLE 2.0: A human protein-protein interaction meta-database employing data integration via genetic information ontology

Cited by 42 publications

References 24 publications

Model‐based detection and analysis of introgressed Neanderthal ancestry in modern humans

Model‐based detection and analysis of introgressed Neanderthal ancestry in modern humans

Model-based detection and analysis of introgressed Neanderthal ancestry in modern humans

Cell type-specific proteogenomic signal diffusion for integrating multi-omics data predicts novel schizophrenia risk genes

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