TY - JOUR
T1 - The human gene connectome as a map of short cuts for morbid allele discovery
AU - Itan, Yuval
AU - Zhang, Shen Ying
AU - Vogt, Guillaume
AU - Abhyankar, Avinash
AU - Herman, Melina
AU - Nitschke, Patrick
AU - Fried, Dror
AU - Quintana-Murci, Lluis
AU - Abel, Laurent
AU - Casanova, Jean Laurent
PY - 2013/4/2
Y1 - 2013/4/2
N2 - High-throughput genomic data reveal thousands of gene variants per patient, and it is often difficult to determine which of these variants underlies disease in a given individual. However, at the population level, there may be some degree of phenotypic homogeneity, with alterations of specific physiological pathways underlying the pathogenesis of a particular disease. We describe here the human gene connectome (HGC) as a unique approach for human Mendelian genetic research, facilitating the interpretation of abundant genetic data from patients with the same disease, and guiding subsequent experimental investigations. We first defined the set of the shortest plausible biological distances, routes, and degrees of separation between all pairs of human genes by applying a shortest distance algorithm to the full human gene network. We then designed a hypothesis-driven application of the HGC, in which we generated a Toll-like receptor 3-specific connectome useful for the genetic dissection of inborn errors of Toll-like receptor 3 immunity. In addition, we developed a functional genomic alignment approach from the HGC. In functional genomic alignment, the genes are clustered according to biological distance (rather than the traditional molecular evolutionary genetic distance), as estimated from the HGC. Finally, we compared the HGC with three state-of-the-art methods: String, FunCoup, and HumanNet. We demonstrated that the existing methods are more suitable for polygenic studies, whereas HGC approaches are more suitable for monogenic studies. The HGC and functional genomic alignment data and computer programs are freely available to noncommercial users from http://lab. rockefeller. edu/casanova/HGC and should facilitate the genome-wide selection of disease-causing candidate alleles for experimental validation.
AB - High-throughput genomic data reveal thousands of gene variants per patient, and it is often difficult to determine which of these variants underlies disease in a given individual. However, at the population level, there may be some degree of phenotypic homogeneity, with alterations of specific physiological pathways underlying the pathogenesis of a particular disease. We describe here the human gene connectome (HGC) as a unique approach for human Mendelian genetic research, facilitating the interpretation of abundant genetic data from patients with the same disease, and guiding subsequent experimental investigations. We first defined the set of the shortest plausible biological distances, routes, and degrees of separation between all pairs of human genes by applying a shortest distance algorithm to the full human gene network. We then designed a hypothesis-driven application of the HGC, in which we generated a Toll-like receptor 3-specific connectome useful for the genetic dissection of inborn errors of Toll-like receptor 3 immunity. In addition, we developed a functional genomic alignment approach from the HGC. In functional genomic alignment, the genes are clustered according to biological distance (rather than the traditional molecular evolutionary genetic distance), as estimated from the HGC. Finally, we compared the HGC with three state-of-the-art methods: String, FunCoup, and HumanNet. We demonstrated that the existing methods are more suitable for polygenic studies, whereas HGC approaches are more suitable for monogenic studies. The HGC and functional genomic alignment data and computer programs are freely available to noncommercial users from http://lab. rockefeller. edu/casanova/HGC and should facilitate the genome-wide selection of disease-causing candidate alleles for experimental validation.
KW - Gene prioritization
KW - High-throughput genomics
KW - Human genetics
KW - Next generation sequencing
KW - Pathway prediction
UR - http://www.scopus.com/inward/record.url?scp=84875826166&partnerID=8YFLogxK
U2 - https://doi.org/10.1073/pnas.1218167110
DO - https://doi.org/10.1073/pnas.1218167110
M3 - مقالة
C2 - 23509278
SN - 0027-8424
VL - 110
SP - 5558
EP - 5563
JO - Proceedings of the National Academy of Sciences of the United States of America
JF - Proceedings of the National Academy of Sciences of the United States of America
IS - 14
ER -