Genome-wide reverse genetics framework to identify novel functions of the vertebrate secretome

Michael A. Pickart; Eric W. Klee; Aubrey L. Nielsen; Sridhar Sivasubbu; Eric M. Mendenhall; Brent R. Bill; Eleanor Chen; Craig E. Eckfeldt; Michelle Knowlton; Mara E. Robu; Jon D. Larson; Yun Deng; Lisa A. Schimmenti; Lynda B.M. Ellis; Catherine M. Verfaillie; Matthias Hammerschmidt; Steven A. Farber; Stephen C. Ekker

doi:10.1371/journal.pone.0000104

Genome-wide reverse genetics framework to identify novel functions of the vertebrate secretome

Michael A. Pickart, Eric W. Klee, Aubrey L. Nielsen, Sridhar Sivasubbu, Eric M. Mendenhall, Brent R. Bill, Eleanor Chen, Craig E. Eckfeldt, Michelle Knowlton, Mara E. Robu, Jon D. Larson, Yun Deng, Lisa A. Schimmenti, Lynda B.M. Ellis, Catherine M. Verfaillie, Matthias Hammerschmidt, Steven A. Farber, Stephen C. Ekker

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Abstract

Background. Understanding the functional role(s) of the more than 20,000 proteins of the vertebrate genome is a major next step in the post-genome era. The approximately 4,000 co-translationally translocated (CTT) proteins - representing the vertebrate secretome - are important for such vertebrate-critical processes as organogenesis. However, the role(s) for most of these genes is currently unknown. Results. We identified 585 putative full-length zebrafish CTT proteins using cross-species genomic and EST-based comparative sequence analyses. We further investigated 150 of these genes (Figure 1) for unique function using morpholino-based analysis in zebrafish embryos. 12% of the CTT protein-deficient embryos resulted in specific developmental defects, a notably higher rate of gene function annotation than the 2%-3% estimate from random gene mutagenesis studies. Conclusion(s). This initial collection includes novel genes required for the development of vascular, hematopoietic, pigmentation, and craniofacial tissues, as well as lipid metabolism, and organogenesis. This study provides a framework utilizing zebrafish for the systematic assignment of biological function in a vertebrate genome.

Original language	English (US)
Article number	e104
Journal	PloS one
Volume	1
Issue number	1
DOIs	https://doi.org/10.1371/journal.pone.0000104
State	Published - Dec 20 2006

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Pickart, M. A., Klee, E. W., Nielsen, A. L., Sivasubbu, S., Mendenhall, E. M., Bill, B. R., Chen, E., Eckfeldt, C. E., Knowlton, M., Robu, M. E., Larson, J. D., Deng, Y., Schimmenti, L. A., Ellis, L. B. M., Verfaillie, C. M., Hammerschmidt, M., Farber, S. A., & Ekker, S. C. (2006). Genome-wide reverse genetics framework to identify novel functions of the vertebrate secretome. PloS one, 1(1), Article e104. https://doi.org/10.1371/journal.pone.0000104

Pickart, MA, Klee, EW, Nielsen, AL, Sivasubbu, S, Mendenhall, EM, Bill, BR, Chen, E, Eckfeldt, CE, Knowlton, M, Robu, ME, Larson, JD, Deng, Y, Schimmenti, LA, Ellis, LBM, Verfaillie, CM, Hammerschmidt, M, Farber, SA & Ekker, SC 2006, 'Genome-wide reverse genetics framework to identify novel functions of the vertebrate secretome', PloS one, vol. 1, no. 1, e104. https://doi.org/10.1371/journal.pone.0000104

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title = "Genome-wide reverse genetics framework to identify novel functions of the vertebrate secretome",

abstract = "Background. Understanding the functional role(s) of the more than 20,000 proteins of the vertebrate genome is a major next step in the post-genome era. The approximately 4,000 co-translationally translocated (CTT) proteins - representing the vertebrate secretome - are important for such vertebrate-critical processes as organogenesis. However, the role(s) for most of these genes is currently unknown. Results. We identified 585 putative full-length zebrafish CTT proteins using cross-species genomic and EST-based comparative sequence analyses. We further investigated 150 of these genes (Figure 1) for unique function using morpholino-based analysis in zebrafish embryos. 12% of the CTT protein-deficient embryos resulted in specific developmental defects, a notably higher rate of gene function annotation than the 2%-3% estimate from random gene mutagenesis studies. Conclusion(s). This initial collection includes novel genes required for the development of vascular, hematopoietic, pigmentation, and craniofacial tissues, as well as lipid metabolism, and organogenesis. This study provides a framework utilizing zebrafish for the systematic assignment of biological function in a vertebrate genome.",

author = "Pickart, {Michael A.} and Klee, {Eric W.} and Nielsen, {Aubrey L.} and Sridhar Sivasubbu and Mendenhall, {Eric M.} and Bill, {Brent R.} and Eleanor Chen and Eckfeldt, {Craig E.} and Michelle Knowlton and Robu, {Mara E.} and Larson, {Jon D.} and Yun Deng and Schimmenti, {Lisa A.} and Ellis, {Lynda B.M.} and Verfaillie, {Catherine M.} and Matthias Hammerschmidt and Farber, {Steven A.} and Ekker, {Stephen C.}",

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AU - Pickart, Michael A.

AU - Klee, Eric W.

AU - Nielsen, Aubrey L.

AU - Sivasubbu, Sridhar

AU - Mendenhall, Eric M.

AU - Bill, Brent R.

AU - Chen, Eleanor

AU - Eckfeldt, Craig E.

AU - Knowlton, Michelle

AU - Robu, Mara E.

AU - Larson, Jon D.

AU - Deng, Yun

AU - Schimmenti, Lisa A.

AU - Ellis, Lynda B.M.

AU - Verfaillie, Catherine M.

AU - Hammerschmidt, Matthias

AU - Farber, Steven A.

AU - Ekker, Stephen C.

PY - 2006/12/20

Y1 - 2006/12/20

N2 - Background. Understanding the functional role(s) of the more than 20,000 proteins of the vertebrate genome is a major next step in the post-genome era. The approximately 4,000 co-translationally translocated (CTT) proteins - representing the vertebrate secretome - are important for such vertebrate-critical processes as organogenesis. However, the role(s) for most of these genes is currently unknown. Results. We identified 585 putative full-length zebrafish CTT proteins using cross-species genomic and EST-based comparative sequence analyses. We further investigated 150 of these genes (Figure 1) for unique function using morpholino-based analysis in zebrafish embryos. 12% of the CTT protein-deficient embryos resulted in specific developmental defects, a notably higher rate of gene function annotation than the 2%-3% estimate from random gene mutagenesis studies. Conclusion(s). This initial collection includes novel genes required for the development of vascular, hematopoietic, pigmentation, and craniofacial tissues, as well as lipid metabolism, and organogenesis. This study provides a framework utilizing zebrafish for the systematic assignment of biological function in a vertebrate genome.

AB - Background. Understanding the functional role(s) of the more than 20,000 proteins of the vertebrate genome is a major next step in the post-genome era. The approximately 4,000 co-translationally translocated (CTT) proteins - representing the vertebrate secretome - are important for such vertebrate-critical processes as organogenesis. However, the role(s) for most of these genes is currently unknown. Results. We identified 585 putative full-length zebrafish CTT proteins using cross-species genomic and EST-based comparative sequence analyses. We further investigated 150 of these genes (Figure 1) for unique function using morpholino-based analysis in zebrafish embryos. 12% of the CTT protein-deficient embryos resulted in specific developmental defects, a notably higher rate of gene function annotation than the 2%-3% estimate from random gene mutagenesis studies. Conclusion(s). This initial collection includes novel genes required for the development of vascular, hematopoietic, pigmentation, and craniofacial tissues, as well as lipid metabolism, and organogenesis. This study provides a framework utilizing zebrafish for the systematic assignment of biological function in a vertebrate genome.

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Genome-wide reverse genetics framework to identify novel functions of the vertebrate secretome

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