Approaching a complete repository of sequence-verified protein-encoding clones for Saccharomyces cerevisiae

Yanhui Hu; Andreas Rolfs; Bhupinder Bhullar; Tellamraju V.S. Murthy; Cong Zhu; Michael F. Berger; Anamaria A. Camargo; Fontina Kelley; Seamus McCarron; Daniel Jepson; Aaron Richardson; Jacob Raphael; Donna Moreira; Elena Taycher; Dongmei Zuo; Stephanie Mohr; Michael F. Kane; Janice Williamson; Andrew Simpson; Martha L. Bulyk; Edward Harlow; Gerald Marsischky; Richard D. Kolodner; Joshua LaBaer

doi:10.1101/gr.6037607

Approaching a complete repository of sequence-verified protein-encoding clones for Saccharomyces cerevisiae

Yanhui Hu, Andreas Rolfs, Bhupinder Bhullar, Tellamraju V.S. Murthy, Cong Zhu, Michael F. Berger, Anamaria A. Camargo, Fontina Kelley, Seamus McCarron, Daniel Jepson, Aaron Richardson, Jacob Raphael, Donna Moreira, Elena Taycher, Dongmei Zuo, Stephanie Mohr, Michael F. Kane, Janice Williamson, Andrew Simpson, Martha L. BulykEdward Harlow, Gerald Marsischky, Richard D. Kolodner, Joshua LaBaer

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Abstract

The availability of an annotated genome sequence for the yeast Saccharomyces cerevisiae has made possible the proteome-scale study of protein function and protein-protein interactions. These studies rely on availability of cloned open reading frame (ORF) collections that can be used for cell-free or cell-based protein expression. Several yeast ORF collections are available, but their use and data interpretation can be hindered by reliance on now out-of-date annotations, the inflexible presence of N- or C-terminal tags, and/or the unknown presence of mutations introduced during the cloning process. High-throughput biochemical and genetic analyses would benefit from a "gold standard" (fully sequence-verified, high-quality) ORF collection, which allows for high confidence in and reproducibility of experimental results. Here, we describe Yeast FLEXGene, a S. cerevisiae protein-coding clone collection that covers over 5000 predicted protein-coding sequences. The clone set covers 87% of the current S. cerevisiae genome annotation and includes full sequencing of each ORF insert. Availability of this collection makes possible a wide variety of studies from purified proteins to mutation suppression analysis, which should contribute to a global understanding of yeast protein function.

Original language	English (US)
Pages (from-to)	536-543
Number of pages	8
Journal	Genome research
Volume	17
Issue number	4
DOIs	https://doi.org/10.1101/gr.6037607
State	Published - Apr 2007
Externally published	Yes

ASJC Scopus subject areas

Genetics
Genetics(clinical)

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Hu, Y., Rolfs, A., Bhullar, B., Murthy, T. V. S., Zhu, C., Berger, M. F., Camargo, A. A., Kelley, F., McCarron, S., Jepson, D., Richardson, A., Raphael, J., Moreira, D., Taycher, E., Zuo, D., Mohr, S., Kane, M. F., Williamson, J., Simpson, A., ... LaBaer, J. (2007). Approaching a complete repository of sequence-verified protein-encoding clones for Saccharomyces cerevisiae. Genome research, 17(4), 536-543. https://doi.org/10.1101/gr.6037607

Hu, Y, Rolfs, A, Bhullar, B, Murthy, TVS, Zhu, C, Berger, MF, Camargo, AA, Kelley, F, McCarron, S, Jepson, D, Richardson, A, Raphael, J, Moreira, D, Taycher, E, Zuo, D, Mohr, S, Kane, MF, Williamson, J, Simpson, A, Bulyk, ML, Harlow, E, Marsischky, G, Kolodner, RD & LaBaer, J 2007, 'Approaching a complete repository of sequence-verified protein-encoding clones for Saccharomyces cerevisiae', Genome research, vol. 17, no. 4, pp. 536-543. https://doi.org/10.1101/gr.6037607

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abstract = "The availability of an annotated genome sequence for the yeast Saccharomyces cerevisiae has made possible the proteome-scale study of protein function and protein-protein interactions. These studies rely on availability of cloned open reading frame (ORF) collections that can be used for cell-free or cell-based protein expression. Several yeast ORF collections are available, but their use and data interpretation can be hindered by reliance on now out-of-date annotations, the inflexible presence of N- or C-terminal tags, and/or the unknown presence of mutations introduced during the cloning process. High-throughput biochemical and genetic analyses would benefit from a {"}gold standard{"} (fully sequence-verified, high-quality) ORF collection, which allows for high confidence in and reproducibility of experimental results. Here, we describe Yeast FLEXGene, a S. cerevisiae protein-coding clone collection that covers over 5000 predicted protein-coding sequences. The clone set covers 87% of the current S. cerevisiae genome annotation and includes full sequencing of each ORF insert. Availability of this collection makes possible a wide variety of studies from purified proteins to mutation suppression analysis, which should contribute to a global understanding of yeast protein function.",

author = "Yanhui Hu and Andreas Rolfs and Bhupinder Bhullar and Murthy, {Tellamraju V.S.} and Cong Zhu and Berger, {Michael F.} and Camargo, {Anamaria A.} and Fontina Kelley and Seamus McCarron and Daniel Jepson and Aaron Richardson and Jacob Raphael and Donna Moreira and Elena Taycher and Dongmei Zuo and Stephanie Mohr and Kane, {Michael F.} and Janice Williamson and Andrew Simpson and Bulyk, {Martha L.} and Edward Harlow and Gerald Marsischky and Kolodner, {Richard D.} and Joshua LaBaer",

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Approaching a complete repository of sequence-verified protein-encoding clones for Saccharomyces cerevisiae

Abstract

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