Systematic Generation of High-resolution Deletion Coverage of the Drosophila Melanogaster Genome

Overview

Journal Nat Genet

Specialty Genetics

Date 2004 Feb 26

PMID 14981519

Citations 464

Authors

Annette L Parks

Kevin R Cook

Marcia Belvin

Nicholas A Dompe

Robert Fawcett

Kari Huppert

Lory R Tan

Christopher G Winter

Kevin P Bogart

Jennifer E Deal

Megan E Deal-Herr

Deanna Grant

Marie Marcinko

Wesley Y Miyazaki

Stephanie Robertson

Kenneth J Shaw

Mariano Tabios

Valentina Vysotskaia

Lora Zhao

Rachel S Andrade

Kyle A Edgar

Elizabeth Howie

Keith Killpack

Brett Milash

Amanda Norton

Doua Thao

Kellie Whittaker

Millicent A Winner

Lori Friedman

Jonathan Margolis

Matthew A Singer

Casey Kopczynski

Daniel Curtis

Thomas C Kaufman

Gregory D Plowman

Geoffrey Duyk

Helen L Francis-Lang

Affiliations

Soon will be listed here.

Abstract

In fruit fly research, chromosomal deletions are indispensable tools for mapping mutations, characterizing alleles and identifying interacting loci. Most widely used deletions were generated by irradiation or chemical mutagenesis. These methods are labor-intensive, generate random breakpoints and result in unwanted secondary mutations that can confound phenotypic analyses. Most of the existing deletions are large, have molecularly undefined endpoints and are maintained in genetically complex stocks. Furthermore, the existence of haplolethal or haplosterile loci makes the recovery of deletions of certain regions exceedingly difficult by traditional methods, resulting in gaps in coverage. Here we describe two methods that address these problems by providing for the systematic isolation of targeted deletions in the D. melanogaster genome. The first strategy used a P element-based technique to generate deletions that closely flank haploinsufficient genes and minimize undeleted regions. This deletion set has increased overall genomic coverage by 5-7%. The second strategy used FLP recombinase and the large array of FRT-bearing insertions described in the accompanying paper to generate 519 isogenic deletions with molecularly defined endpoints. This second deletion collection provides 56% genome coverage so far. The latter methodology enables the generation of small custom deletions with predictable endpoints throughout the genome and should make their isolation a simple and routine task.

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