A multi-omic analysis of human naïve CD4+ T cells

Christopher J. Mitchell; Derese Getnet; Min Sik Kim; Srikanth S. Manda; Praveen Kumar; Tai Chung Huang; Sneha M. Pinto; Raja Sekhar Nirujogi; Mio Iwasaki; Patrick G. Shaw; Xinyan Wu; Jun Zhong; Raghothama Chaerkady; Arivusudar Marimuthu; Babylakshmi Muthusamy; Nandini A. Sahasrabuddhe; Rajesh Raju; Caitlyn Bowman; Ludmila Danilova; Jevon Cutler; Dhanashree S. Kelkar; Charles G. Drake; T. S. Keshava Prasad; Luigi Marchionni; Peter N. Murakami; Alan F. Scott; Leming Shi; Jean Thierry-Mieg; Danielle Thierry-Mieg; Rafael Irizarry; Leslie Cope; Yasushi Ishihama; Charles Wang; Harsha Gowda; Akhilesh Pandey

doi:10.1186/s12918-015-0225-4

A multi-omic analysis of human naïve CD4+ T cells

Christopher J. Mitchell, Derese Getnet, Min Sik Kim, Srikanth S. Manda, Praveen Kumar, Tai Chung Huang, Sneha M. Pinto, Raja Sekhar Nirujogi, Mio Iwasaki, Patrick G. Shaw, Xinyan Wu, Jun Zhong, Raghothama Chaerkady, Arivusudar Marimuthu, Babylakshmi Muthusamy, Nandini A. Sahasrabuddhe, Rajesh Raju, Caitlyn Bowman, Ludmila Danilova, Jevon CutlerDhanashree S. Kelkar, Charles G. Drake, T. S. Keshava Prasad, Luigi Marchionni, Peter N. Murakami, Alan F. Scott, Leming Shi, Jean Thierry-Mieg, Danielle Thierry-Mieg, Rafael Irizarry, Leslie Cope, Yasushi Ishihama, Charles Wang, Harsha Gowda, Akhilesh Pandey

Research output: Contribution to journal › Article › peer-review

26 Scopus citations

Abstract

Background: Cellular function and diversity are orchestrated by complex interactions of fundamental biomolecules including DNA, RNA and proteins. Technological advances in genomics, epigenomics, transcriptomics and proteomics have enabled massively parallel and unbiased measurements. Such high-throughput technologies have been extensively used to carry out broad, unbiased studies, particularly in the context of human diseases. Nevertheless, a unified analysis of the genome, epigenome, transcriptome and proteome of a single human cell type to obtain a coherent view of the complex interplay between various biomolecules has not yet been undertaken. Here, we report the first multi-omic analysis of human primary naïve CD4+ T cells isolated from a single individual. Results: Integrating multi-omics datasets allowed us to investigate genome-wide methylation and its effect on mRNA/protein expression patterns, extent of RNA editing under normal physiological conditions and allele specific expression in naïve CD4+ T cells. In addition, we carried out a multi-omic comparative analysis of naïve with primary resting memory CD4+ T cells to identify molecular changes underlying T cell differentiation. This analysis provided mechanistic insights into how several molecules involved in T cell receptor signaling are regulated at the DNA, RNA and protein levels. Phosphoproteomics revealed downstream signaling events that regulate these two cellular states. Availability of multi-omics data from an identical genetic background also allowed us to employ novel proteogenomics approaches to identify individual-specific variants and putative novel protein coding regions in the human genome. Conclusions: We utilized multiple high-throughput technologies to derive a comprehensive profile of two primary human cell types, naïve CD4+ T cells and memory CD4+ T cells, from a single donor. Through vertical as well as horizontal integration of whole genome sequencing, methylation arrays, RNA-Seq, miRNA-Seq, proteomics, and phosphoproteomics, we derived an integrated and comparative map of these two closely related immune cells and identified potential molecular effectors of immune cell differentiation following antigen encounter.

Original language	English (US)
Article number	75
Journal	BMC Systems Biology
Volume	9
Issue number	1
DOIs	https://doi.org/10.1186/s12918-015-0225-4
State	Published - Nov 6 2015

Keywords

Epigenomics
Innate immunity
Integrative -omics
Phosphoproteomics
Proteomics
Transcriptomics
Whole genome sequencing

ASJC Scopus subject areas

Structural Biology
Modeling and Simulation
Molecular Biology
Computer Science Applications
Applied Mathematics

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10.1186/s12918-015-0225-4

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Mitchell, C. J., Getnet, D., Kim, M. S., Manda, S. S., Kumar, P., Huang, T. C., Pinto, S. M., Nirujogi, R. S., Iwasaki, M., Shaw, P. G., Wu, X., Zhong, J., Chaerkady, R., Marimuthu, A., Muthusamy, B., Sahasrabuddhe, N. A., Raju, R., Bowman, C., Danilova, L., ... Pandey, A. (2015). A multi-omic analysis of human naïve CD4+ T cells. BMC Systems Biology, 9(1), Article 75. https://doi.org/10.1186/s12918-015-0225-4

Mitchell, CJ, Getnet, D, Kim, MS, Manda, SS, Kumar, P, Huang, TC, Pinto, SM, Nirujogi, RS, Iwasaki, M, Shaw, PG, Wu, X, Zhong, J, Chaerkady, R, Marimuthu, A, Muthusamy, B, Sahasrabuddhe, NA, Raju, R, Bowman, C, Danilova, L, Cutler, J, Kelkar, DS, Drake, CG, Keshava Prasad, TS, Marchionni, L, Murakami, PN, Scott, AF, Shi, L, Thierry-Mieg, J, Thierry-Mieg, D, Irizarry, R, Cope, L, Ishihama, Y, Wang, C, Gowda, H & Pandey, A 2015, 'A multi-omic analysis of human naïve CD4+ T cells', BMC Systems Biology, vol. 9, no. 1, 75. https://doi.org/10.1186/s12918-015-0225-4

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title = "A multi-omic analysis of human na{\"i}ve CD4+ T cells",

abstract = "Background: Cellular function and diversity are orchestrated by complex interactions of fundamental biomolecules including DNA, RNA and proteins. Technological advances in genomics, epigenomics, transcriptomics and proteomics have enabled massively parallel and unbiased measurements. Such high-throughput technologies have been extensively used to carry out broad, unbiased studies, particularly in the context of human diseases. Nevertheless, a unified analysis of the genome, epigenome, transcriptome and proteome of a single human cell type to obtain a coherent view of the complex interplay between various biomolecules has not yet been undertaken. Here, we report the first multi-omic analysis of human primary na{\"i}ve CD4+ T cells isolated from a single individual. Results: Integrating multi-omics datasets allowed us to investigate genome-wide methylation and its effect on mRNA/protein expression patterns, extent of RNA editing under normal physiological conditions and allele specific expression in na{\"i}ve CD4+ T cells. In addition, we carried out a multi-omic comparative analysis of na{\"i}ve with primary resting memory CD4+ T cells to identify molecular changes underlying T cell differentiation. This analysis provided mechanistic insights into how several molecules involved in T cell receptor signaling are regulated at the DNA, RNA and protein levels. Phosphoproteomics revealed downstream signaling events that regulate these two cellular states. Availability of multi-omics data from an identical genetic background also allowed us to employ novel proteogenomics approaches to identify individual-specific variants and putative novel protein coding regions in the human genome. Conclusions: We utilized multiple high-throughput technologies to derive a comprehensive profile of two primary human cell types, na{\"i}ve CD4+ T cells and memory CD4+ T cells, from a single donor. Through vertical as well as horizontal integration of whole genome sequencing, methylation arrays, RNA-Seq, miRNA-Seq, proteomics, and phosphoproteomics, we derived an integrated and comparative map of these two closely related immune cells and identified potential molecular effectors of immune cell differentiation following antigen encounter.",

keywords = "Epigenomics, Innate immunity, Integrative -omics, Phosphoproteomics, Proteomics, Transcriptomics, Whole genome sequencing",

author = "Mitchell, {Christopher J.} and Derese Getnet and Kim, {Min Sik} and Manda, {Srikanth S.} and Praveen Kumar and Huang, {Tai Chung} and Pinto, {Sneha M.} and Nirujogi, {Raja Sekhar} and Mio Iwasaki and Shaw, {Patrick G.} and Xinyan Wu and Jun Zhong and Raghothama Chaerkady and Arivusudar Marimuthu and Babylakshmi Muthusamy and Sahasrabuddhe, {Nandini A.} and Rajesh Raju and Caitlyn Bowman and Ludmila Danilova and Jevon Cutler and Kelkar, {Dhanashree S.} and Drake, {Charles G.} and {Keshava Prasad}, {T. S.} and Luigi Marchionni and Murakami, {Peter N.} and Scott, {Alan F.} and Leming Shi and Jean Thierry-Mieg and Danielle Thierry-Mieg and Rafael Irizarry and Leslie Cope and Yasushi Ishihama and Charles Wang and Harsha Gowda and Akhilesh Pandey",

note = "Publisher Copyright: {\textcopyright} 2015 Mitchell et al.",

year = "2015",

month = nov,

day = "6",

doi = "10.1186/s12918-015-0225-4",

language = "English (US)",

volume = "9",

journal = "BMC Systems Biology",

issn = "1752-0509",

publisher = "BioMed Central",

number = "1",

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TY - JOUR

T1 - A multi-omic analysis of human naïve CD4+ T cells

AU - Mitchell, Christopher J.

AU - Getnet, Derese

AU - Kim, Min Sik

AU - Manda, Srikanth S.

AU - Kumar, Praveen

AU - Huang, Tai Chung

AU - Pinto, Sneha M.

AU - Nirujogi, Raja Sekhar

AU - Iwasaki, Mio

AU - Shaw, Patrick G.

AU - Wu, Xinyan

AU - Zhong, Jun

AU - Chaerkady, Raghothama

AU - Marimuthu, Arivusudar

AU - Muthusamy, Babylakshmi

AU - Sahasrabuddhe, Nandini A.

AU - Raju, Rajesh

AU - Bowman, Caitlyn

AU - Danilova, Ludmila

AU - Cutler, Jevon

AU - Kelkar, Dhanashree S.

AU - Drake, Charles G.

AU - Keshava Prasad, T. S.

AU - Marchionni, Luigi

AU - Murakami, Peter N.

AU - Scott, Alan F.

AU - Shi, Leming

AU - Thierry-Mieg, Jean

AU - Thierry-Mieg, Danielle

AU - Irizarry, Rafael

AU - Cope, Leslie

AU - Ishihama, Yasushi

AU - Wang, Charles

AU - Gowda, Harsha

AU - Pandey, Akhilesh

PY - 2015/11/6

Y1 - 2015/11/6

N2 - Background: Cellular function and diversity are orchestrated by complex interactions of fundamental biomolecules including DNA, RNA and proteins. Technological advances in genomics, epigenomics, transcriptomics and proteomics have enabled massively parallel and unbiased measurements. Such high-throughput technologies have been extensively used to carry out broad, unbiased studies, particularly in the context of human diseases. Nevertheless, a unified analysis of the genome, epigenome, transcriptome and proteome of a single human cell type to obtain a coherent view of the complex interplay between various biomolecules has not yet been undertaken. Here, we report the first multi-omic analysis of human primary naïve CD4+ T cells isolated from a single individual. Results: Integrating multi-omics datasets allowed us to investigate genome-wide methylation and its effect on mRNA/protein expression patterns, extent of RNA editing under normal physiological conditions and allele specific expression in naïve CD4+ T cells. In addition, we carried out a multi-omic comparative analysis of naïve with primary resting memory CD4+ T cells to identify molecular changes underlying T cell differentiation. This analysis provided mechanistic insights into how several molecules involved in T cell receptor signaling are regulated at the DNA, RNA and protein levels. Phosphoproteomics revealed downstream signaling events that regulate these two cellular states. Availability of multi-omics data from an identical genetic background also allowed us to employ novel proteogenomics approaches to identify individual-specific variants and putative novel protein coding regions in the human genome. Conclusions: We utilized multiple high-throughput technologies to derive a comprehensive profile of two primary human cell types, naïve CD4+ T cells and memory CD4+ T cells, from a single donor. Through vertical as well as horizontal integration of whole genome sequencing, methylation arrays, RNA-Seq, miRNA-Seq, proteomics, and phosphoproteomics, we derived an integrated and comparative map of these two closely related immune cells and identified potential molecular effectors of immune cell differentiation following antigen encounter.

AB - Background: Cellular function and diversity are orchestrated by complex interactions of fundamental biomolecules including DNA, RNA and proteins. Technological advances in genomics, epigenomics, transcriptomics and proteomics have enabled massively parallel and unbiased measurements. Such high-throughput technologies have been extensively used to carry out broad, unbiased studies, particularly in the context of human diseases. Nevertheless, a unified analysis of the genome, epigenome, transcriptome and proteome of a single human cell type to obtain a coherent view of the complex interplay between various biomolecules has not yet been undertaken. Here, we report the first multi-omic analysis of human primary naïve CD4+ T cells isolated from a single individual. Results: Integrating multi-omics datasets allowed us to investigate genome-wide methylation and its effect on mRNA/protein expression patterns, extent of RNA editing under normal physiological conditions and allele specific expression in naïve CD4+ T cells. In addition, we carried out a multi-omic comparative analysis of naïve with primary resting memory CD4+ T cells to identify molecular changes underlying T cell differentiation. This analysis provided mechanistic insights into how several molecules involved in T cell receptor signaling are regulated at the DNA, RNA and protein levels. Phosphoproteomics revealed downstream signaling events that regulate these two cellular states. Availability of multi-omics data from an identical genetic background also allowed us to employ novel proteogenomics approaches to identify individual-specific variants and putative novel protein coding regions in the human genome. Conclusions: We utilized multiple high-throughput technologies to derive a comprehensive profile of two primary human cell types, naïve CD4+ T cells and memory CD4+ T cells, from a single donor. Through vertical as well as horizontal integration of whole genome sequencing, methylation arrays, RNA-Seq, miRNA-Seq, proteomics, and phosphoproteomics, we derived an integrated and comparative map of these two closely related immune cells and identified potential molecular effectors of immune cell differentiation following antigen encounter.

KW - Epigenomics

KW - Innate immunity

KW - Integrative -omics

KW - Phosphoproteomics

KW - Proteomics

KW - Transcriptomics

KW - Whole genome sequencing

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DO - 10.1186/s12918-015-0225-4

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SN - 1752-0509

VL - 9

JO - BMC Systems Biology

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ER -

A multi-omic analysis of human naïve CD4+ T cells

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