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Integration of Sequence Data from a Consanguineous Family with Genetic Data from an Outbred Population Identifies PLB1 as a Candidate Rheumatoid Arthritis Risk Gene

Author

Listed:
  • Yukinori Okada
  • Dorothee Diogo
  • Jeffrey D Greenberg
  • Faten Mouassess
  • Walid A L Achkar
  • Robert S Fulton
  • Joshua C Denny
  • Namrata Gupta
  • Daniel Mirel
  • Stacy Gabriel
  • Gang Li
  • Joel M Kremer
  • Dimitrios A Pappas
  • Robert J Carroll
  • Anne E Eyler
  • Gosia Trynka
  • Eli A Stahl
  • Jing Cui
  • Richa Saxena
  • Marieke J H Coenen
  • Henk-Jan Guchelaar
  • Tom W J Huizinga
  • Philippe Dieudé
  • Xavier Mariette
  • Anne Barton
  • Helena Canhão
  • João E Fonseca
  • Niek de Vries
  • Paul P Tak
  • Larry W Moreland
  • S Louis Bridges Jr
  • Corinne Miceli-Richard
  • Hyon K Choi
  • Yoichiro Kamatani
  • Pilar Galan
  • Mark Lathrop
  • Towfique Raj
  • Philip L De Jager
  • Soumya Raychaudhuri
  • Jane Worthington
  • Leonid Padyukov
  • Lars Klareskog
  • Katherine A Siminovitch
  • Peter K Gregersen
  • Elaine R Mardis
  • Thurayya Arayssi
  • Layla A Kazkaz
  • Robert M Plenge

Abstract

Integrating genetic data from families with highly penetrant forms of disease together with genetic data from outbred populations represents a promising strategy to uncover the complete frequency spectrum of risk alleles for complex traits such as rheumatoid arthritis (RA). Here, we demonstrate that rare, low-frequency and common alleles at one gene locus, phospholipase B1 (PLB1), might contribute to risk of RA in a 4-generation consanguineous pedigree (Middle Eastern ancestry) and also in unrelated individuals from the general population (European ancestry). Through identity-by-descent (IBD) mapping and whole-exome sequencing, we identified a non-synonymous c.2263G>C (p.G755R) mutation at the PLB1 gene on 2q23, which significantly co-segregated with RA in family members with a dominant mode of inheritance (P = 0.009). We further evaluated PLB1 variants and risk of RA using a GWAS meta-analysis of 8,875 RA cases and 29,367 controls of European ancestry. We identified significant contributions of two independent non-coding variants near PLB1 with risk of RA (rs116018341 [MAF = 0.042] and rs116541814 [MAF = 0.021], combined P = 3.2×10−6). Finally, we performed deep exon sequencing of PLB1 in 1,088 RA cases and 1,088 controls (European ancestry), and identified suggestive dispersion of rare protein-coding variant frequencies between cases and controls (P = 0.049 for C-alpha test and P = 0.055 for SKAT). Together, these data suggest that PLB1 is a candidate risk gene for RA. Future studies to characterize the full spectrum of genetic risk in the PLB1 genetic locus are warranted.

Suggested Citation

  • Yukinori Okada & Dorothee Diogo & Jeffrey D Greenberg & Faten Mouassess & Walid A L Achkar & Robert S Fulton & Joshua C Denny & Namrata Gupta & Daniel Mirel & Stacy Gabriel & Gang Li & Joel M Kremer &, 2014. "Integration of Sequence Data from a Consanguineous Family with Genetic Data from an Outbred Population Identifies PLB1 as a Candidate Rheumatoid Arthritis Risk Gene," PLOS ONE, Public Library of Science, vol. 9(2), pages 1-12, February.
    • Handle: RePEc:plo:pone00:0087645
    DOI: 10.1371/journal.pone.0087645
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    References listed on IDEAS

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