Functional annotations of diabetes nephropathy susceptibility loci through analysis of genome-wide renal gene expression in rat models of diabetes mellitus

Yaomin Hu; Pamela J Kaisaki; Karène Argoud; Steven P Wilder; Karin J Wallace; Peng Y Woon; Christine Blancher; Lise Tarnow; Per-Henrik Groop; Samy Hadjadj; Michel Marre; Hans-Henrik Parving; Martin Farrall; Roger D Cox; Mark Lathrop; Nathalie Vionnet; Marie-Thérèse Bihoreau; Dominique Gauguier

doi:10.1186/1755-8794-2-41

Functional annotations of diabetes nephropathy susceptibility loci through analysis of genome-wide renal gene expression in rat models of diabetes mellitus

Yaomin Hu, Pamela J Kaisaki, Karène Argoud, Steven P Wilder, Karin J Wallace, Peng Y Woon, Christine Blancher, Lise Tarnow, Per-Henrik Groop, Samy Hadjadj, Michel Marre, Hans-Henrik Parving, Martin Farrall, Roger D Cox, Mark Lathrop, Nathalie Vionnet, Marie-Thérèse Bihoreau, Dominique Gauguier

Institut for Klinisk Medicin

Publikation: Bidrag til tidsskrift › Tidsskriftartikel › Forskning › peer review

14 Citationer (Scopus)

Abstract

Udgivelsesdato: 2009

Originalsprog	Engelsk
Tidsskrift	B M C Medical Genomics
Vol/bind	2
Sider (fra-til)	41
ISSN	1755-8794
DOI	https://doi.org/10.1186/1755-8794-2-41
Status	Udgivet - 2009

Bibliografisk note

Export Date: 4 November 2009Source: ScopusArt. No.: 41

Adgang til dokumentet

10.1186/1755-8794-2-41

Citationsformater

Hu, Y., Kaisaki, P. J., Argoud, K., Wilder, S. P., Wallace, K. J., Woon, P. Y., Blancher, C., Tarnow, L., Groop, P.-H., Hadjadj, S., Marre, M., Parving, H.-H., Farrall, M., Cox, R. D., Lathrop, M., Vionnet, N., Bihoreau, M.-T., & Gauguier, D. (2009). Functional annotations of diabetes nephropathy susceptibility loci through analysis of genome-wide renal gene expression in rat models of diabetes mellitus. B M C Medical Genomics, 2, 41. https://doi.org/10.1186/1755-8794-2-41

Hu, Y, Kaisaki, PJ, Argoud, K, Wilder, SP, Wallace, KJ, Woon, PY, Blancher, C, Tarnow, L, Groop, P-H, Hadjadj, S, Marre, M, Parving, H-H, Farrall, M, Cox, RD, Lathrop, M, Vionnet, N, Bihoreau, M-T & Gauguier, D 2009, 'Functional annotations of diabetes nephropathy susceptibility loci through analysis of genome-wide renal gene expression in rat models of diabetes mellitus', B M C Medical Genomics, bind 2, s. 41. https://doi.org/10.1186/1755-8794-2-41

@article{9915ed506a3b11df928f000ea68e967b,

title = "Functional annotations of diabetes nephropathy susceptibility loci through analysis of genome-wide renal gene expression in rat models of diabetes mellitus",

abstract = "BACKGROUND: Hyperglycaemia in diabetes mellitus (DM) alters gene expression regulation in various organs and contributes to long term vascular and renal complications. We aimed to generate novel renal genome-wide gene transcription data in rat models of diabetes in order to test the responsiveness to hyperglycaemia and renal structural changes of positional candidate genes at selected diabetic nephropathy (DN) susceptibility loci. METHODS: Both Affymetrix and Illumina technologies were used to identify significant quantitative changes in the abundance of over 15,000 transcripts in kidney of models of spontaneous (genetically determined) mild hyperglycaemia and insulin resistance (Goto-Kakizaki-GK) and experimentally induced severe hyperglycaemia (Wistar-Kyoto-WKY rats injected with streptozotocin [STZ]). RESULTS: Different patterns of transcription regulation in the two rat models of diabetes likely underlie the roles of genetic variants and hyperglycaemia severity. The impact of prolonged hyperglycaemia on gene expression changes was more profound in STZ-WKY rats than in GK rats and involved largely different sets of genes. These included genes already tested in genetic studies of DN and a large number of protein coding sequences of unknown function which can be considered as functional and, when they map to DN loci, positional candidates for DN. Further expression analysis of rat orthologs of human DN positional candidate genes provided functional annotations of known and novel genes that are responsive to hyperglycaemia and may contribute to renal functional and/or structural alterations. CONCLUSION: Combining transcriptomics in animal models and comparative genomics provides important information to improve functional annotations of disease susceptibility loci in humans and experimental support for testing candidate genes in human genetics.",

author = "Yaomin Hu and Kaisaki, {Pamela J} and Kar{\`e}ne Argoud and Wilder, {Steven P} and Wallace, {Karin J} and Woon, {Peng Y} and Christine Blancher and Lise Tarnow and Per-Henrik Groop and Samy Hadjadj and Michel Marre and Hans-Henrik Parving and Martin Farrall and Cox, {Roger D} and Mark Lathrop and Nathalie Vionnet and Marie-Th{\'e}r{\`e}se Bihoreau and Dominique Gauguier",

note = "Export Date: 4 November 2009Source: ScopusArt. No.: 41",

year = "2009",

doi = "10.1186/1755-8794-2-41",

language = "English",

volume = "2",

pages = "41",

journal = "B M C Medical Genomics",

issn = "1755-8794",

publisher = "BioMed Central Ltd.",

}

TY - JOUR

T1 - Functional annotations of diabetes nephropathy susceptibility loci through analysis of genome-wide renal gene expression in rat models of diabetes mellitus

AU - Hu, Yaomin

AU - Kaisaki, Pamela J

AU - Argoud, Karène

AU - Wilder, Steven P

AU - Wallace, Karin J

AU - Woon, Peng Y

AU - Blancher, Christine

AU - Tarnow, Lise

AU - Groop, Per-Henrik

AU - Hadjadj, Samy

AU - Marre, Michel

AU - Parving, Hans-Henrik

AU - Farrall, Martin

AU - Cox, Roger D

AU - Lathrop, Mark

AU - Vionnet, Nathalie

AU - Bihoreau, Marie-Thérèse

AU - Gauguier, Dominique

N1 - Export Date: 4 November 2009Source: ScopusArt. No.: 41

PY - 2009

Y1 - 2009

N2 - BACKGROUND: Hyperglycaemia in diabetes mellitus (DM) alters gene expression regulation in various organs and contributes to long term vascular and renal complications. We aimed to generate novel renal genome-wide gene transcription data in rat models of diabetes in order to test the responsiveness to hyperglycaemia and renal structural changes of positional candidate genes at selected diabetic nephropathy (DN) susceptibility loci. METHODS: Both Affymetrix and Illumina technologies were used to identify significant quantitative changes in the abundance of over 15,000 transcripts in kidney of models of spontaneous (genetically determined) mild hyperglycaemia and insulin resistance (Goto-Kakizaki-GK) and experimentally induced severe hyperglycaemia (Wistar-Kyoto-WKY rats injected with streptozotocin [STZ]). RESULTS: Different patterns of transcription regulation in the two rat models of diabetes likely underlie the roles of genetic variants and hyperglycaemia severity. The impact of prolonged hyperglycaemia on gene expression changes was more profound in STZ-WKY rats than in GK rats and involved largely different sets of genes. These included genes already tested in genetic studies of DN and a large number of protein coding sequences of unknown function which can be considered as functional and, when they map to DN loci, positional candidates for DN. Further expression analysis of rat orthologs of human DN positional candidate genes provided functional annotations of known and novel genes that are responsive to hyperglycaemia and may contribute to renal functional and/or structural alterations. CONCLUSION: Combining transcriptomics in animal models and comparative genomics provides important information to improve functional annotations of disease susceptibility loci in humans and experimental support for testing candidate genes in human genetics.

AB - BACKGROUND: Hyperglycaemia in diabetes mellitus (DM) alters gene expression regulation in various organs and contributes to long term vascular and renal complications. We aimed to generate novel renal genome-wide gene transcription data in rat models of diabetes in order to test the responsiveness to hyperglycaemia and renal structural changes of positional candidate genes at selected diabetic nephropathy (DN) susceptibility loci. METHODS: Both Affymetrix and Illumina technologies were used to identify significant quantitative changes in the abundance of over 15,000 transcripts in kidney of models of spontaneous (genetically determined) mild hyperglycaemia and insulin resistance (Goto-Kakizaki-GK) and experimentally induced severe hyperglycaemia (Wistar-Kyoto-WKY rats injected with streptozotocin [STZ]). RESULTS: Different patterns of transcription regulation in the two rat models of diabetes likely underlie the roles of genetic variants and hyperglycaemia severity. The impact of prolonged hyperglycaemia on gene expression changes was more profound in STZ-WKY rats than in GK rats and involved largely different sets of genes. These included genes already tested in genetic studies of DN and a large number of protein coding sequences of unknown function which can be considered as functional and, when they map to DN loci, positional candidates for DN. Further expression analysis of rat orthologs of human DN positional candidate genes provided functional annotations of known and novel genes that are responsive to hyperglycaemia and may contribute to renal functional and/or structural alterations. CONCLUSION: Combining transcriptomics in animal models and comparative genomics provides important information to improve functional annotations of disease susceptibility loci in humans and experimental support for testing candidate genes in human genetics.

U2 - 10.1186/1755-8794-2-41

DO - 10.1186/1755-8794-2-41

M3 - Journal article

C2 - 19586551

SN - 1755-8794

VL - 2

SP - 41

JO - B M C Medical Genomics

JF - B M C Medical Genomics

ER -