Genome Assembly and Geospatial Phylogenomics of the Bed Bug Cimex Lectularius

Authors

Jeffrey A. Rosenfeld, American Museum of Natural History
Darryl Reeves, Weill Cornell Medical College
Mercer R. Brugler, CUNY New York City College of TechnologyFollow
Apurva Narechania, American Museum of Natural History
Sabrina Simon, American Museum of Natural History
Russell Durrett, Weill Cornell Medical College
Jonathan Foox, American Museum of Natural History
Kevin Shianna, Wageningen University
Michael C. Schatz, Cold Spring Harbor Laboratory
Jorge Gandara, Weill Cornell Medical College
Ebrahim Afshinnekoo, Weill Cornell Medical College
Ernest T. Lam, BioNanoGenomics Inc.
Alex R. Hastie, BioNanoGenomics Inc.
Saki Chan, BioNanoGenomics Inc.
Han Cao, BioNanoGenomics Inc.
Michael Saghbini, BioNanoGenomics Inc.
Alex Kentsis, Sloan Kettering Insititute
Paul J. Planet, American Museum of Natural History
Vladyslav Kholodovych, Rutgers University - Newark
Michael Tessler, American Museum of Natural History
Richard Baker, American Museum of Natural History
Rob DeSalle, American Museum of Natural History
Louis N. Sorkin, American Museum of Natural History
Sergios-Orestis Kolokotronis, American Museum of Natural History
Mark E. Siddall, American Museum of Natural History
George Amato, American Museum of Natural History
Christopher E. Mason, Weill Cornell Medical College

Document Type

Article

Publication Date

2-2-2016

Abstract

The common bed bug (Cimex lectularius) has been a persistent pest of humans for thousands of years, yet the genetic basis of the bed bug’s basic biology and adaptation to dense human environments is largely unknown. Here we report the assembly, annotation and phylogenetic mapping of the 697.9-Mb Cimex lectularius genome, with an N50 of 971 kb, using both long and short read technologies. A RNA-seq time course across all five developmental stages and male and female adults generated 36,985 coding and noncoding gene models. The most pronounced change in gene expression during the life cycle occurs after feeding on human blood and included genes from the Wolbachia endosymbiont, which shows a simultaneous and coordinated host/commensal response to haematophagous activity. These data provide a rich genetic resource for mapping activity and density of C. lectularius across human hosts and cities, which can help track, manage and control bed bug infestations.

Comments

This article was originally published in Nature Communications, available at DOI: 10.1038/ncomms10164.

This work is licensed under a Creative Commons Attribution 4.0 International License.