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Identification, assembly, and characterization of tumor Immunoglobulin transcripts from RNA sequencing data using IgSeqR

Identification, assembly, and characterization of tumor Immunoglobulin transcripts from RNA sequencing data using IgSeqR
Identification, assembly, and characterization of tumor Immunoglobulin transcripts from RNA sequencing data using IgSeqR
Immunoglobulin gene analysis provides fundamental insight into B cell receptor structure and function. In B cell tumors, it can provide information on the cell of origin and predict clinical outcomes. Its clinical value has been established in the two main types of chronic lymphocytic leukemia, which are distinguished by the expression of unmutated or mutated immunoglobulin heavy chain variable region (IGHV) genes, and is emerging in other B cell tumors. The traditional PCR and Sanger sequencing-based techniques for immunoglobulin gene analysis are labor-intensive and rely on attaining either a dominant sequence or a small number of subclonal sequences. Extraction of the expressed tumor immunoglobulin transcripts by using high-throughput RNA-sequencing (RNA-seq) can be faster, allow the collection of the tumor immunoglobulin sequence and match this with the rest of the RNA-seq data. Analytical tools are regularly sought to increase the accuracy, depth and speed of acquisition of the immunoglobulin transcript sequences and combine the immunoglobulin characteristics with other tumor features. We provide here a user-friendly protocol for the rapid (~1 h) de novo assembly, identification and accurate characterization of the full (leader to constant region) tumor immunoglobulin templated and non-templated transcript sequence from RNA-seq data (https://github.com/ForconiLab/IgSeqR). The derived amino acid sequences can be interrogated for their physicochemical characteristics and, in certain lymphomas, be used to predict tumor glycan types occupying acquired N-glycosylation sites. These features will then be available for association studies with the tumor transcriptome. The resulting information can also help refine diagnosis, prognosis and potential therapeutic targeting in the most common lymphomas.
1754-2189
Bryant, Dean
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Sale, Ben
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Chiodin, Giorgia
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Tatterton, Dylan James
ea972585-da97-46b7-bbac-7025ff42e294
Stevens, Benjamin Kristian
f6fde136-3f94-40ad-b092-97dc37189d69
Adlaon, Alyssa
98c4be5d-6bba-4ef5-8bb6-05c69f0d4d50
Snook, Erin
3b64eebf-b74a-4196-a638-125c9f2e6862
Batchelor, James
e53c36c7-aa7f-4fae-8113-30bfbb9b36ee
Orfao, Alberto
33ebfb71-8264-478b-b692-d0193b024aa7
Forconi, Francesco
ce9ed873-58cf-4876-bf3a-9ba1d163edc8
Bryant, Dean
10ed83e8-8080-4d9c-bba5-df9d4eec3a10
Sale, Ben
9dead432-5956-4b59-9d10-9d9db8a10ba1
Chiodin, Giorgia
4b3e9525-b377-4d16-b69a-e05d2e7854fe
Tatterton, Dylan James
ea972585-da97-46b7-bbac-7025ff42e294
Stevens, Benjamin Kristian
f6fde136-3f94-40ad-b092-97dc37189d69
Adlaon, Alyssa
98c4be5d-6bba-4ef5-8bb6-05c69f0d4d50
Snook, Erin
3b64eebf-b74a-4196-a638-125c9f2e6862
Batchelor, James
e53c36c7-aa7f-4fae-8113-30bfbb9b36ee
Orfao, Alberto
33ebfb71-8264-478b-b692-d0193b024aa7
Forconi, Francesco
ce9ed873-58cf-4876-bf3a-9ba1d163edc8

Bryant, Dean, Sale, Ben, Chiodin, Giorgia, Tatterton, Dylan James, Stevens, Benjamin Kristian, Adlaon, Alyssa, Snook, Erin, Batchelor, James, Orfao, Alberto and Forconi, Francesco (2025) Identification, assembly, and characterization of tumor Immunoglobulin transcripts from RNA sequencing data using IgSeqR. Nature Protocols. (doi:10.1038/s41596-025-01172-6).

Record type: Article

Abstract

Immunoglobulin gene analysis provides fundamental insight into B cell receptor structure and function. In B cell tumors, it can provide information on the cell of origin and predict clinical outcomes. Its clinical value has been established in the two main types of chronic lymphocytic leukemia, which are distinguished by the expression of unmutated or mutated immunoglobulin heavy chain variable region (IGHV) genes, and is emerging in other B cell tumors. The traditional PCR and Sanger sequencing-based techniques for immunoglobulin gene analysis are labor-intensive and rely on attaining either a dominant sequence or a small number of subclonal sequences. Extraction of the expressed tumor immunoglobulin transcripts by using high-throughput RNA-sequencing (RNA-seq) can be faster, allow the collection of the tumor immunoglobulin sequence and match this with the rest of the RNA-seq data. Analytical tools are regularly sought to increase the accuracy, depth and speed of acquisition of the immunoglobulin transcript sequences and combine the immunoglobulin characteristics with other tumor features. We provide here a user-friendly protocol for the rapid (~1 h) de novo assembly, identification and accurate characterization of the full (leader to constant region) tumor immunoglobulin templated and non-templated transcript sequence from RNA-seq data (https://github.com/ForconiLab/IgSeqR). The derived amino acid sequences can be interrogated for their physicochemical characteristics and, in certain lymphomas, be used to predict tumor glycan types occupying acquired N-glycosylation sites. These features will then be available for association studies with the tumor transcriptome. The resulting information can also help refine diagnosis, prognosis and potential therapeutic targeting in the most common lymphomas.

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16951_4_merged_1741707724 - Accepted Manuscript
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16951_4_supp_0_srxspp - Accepted Manuscript
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More information

Accepted/In Press date: 6 March 2025
e-pub ahead of print date: 24 April 2025
Published date: 24 April 2025

Identifiers

Local EPrints ID: 500370
URI: http://eprints.soton.ac.uk/id/eprint/500370
DOI: doi:10.1038/s41596-025-01172-6
ISSN: 1754-2189
PURE UUID: 230ce5d4-96aa-4d10-bfa4-d23173de7f61
ORCID for Dean Bryant: ORCID iD orcid.org/0000-0003-3163-608X
ORCID for Ben Sale: ORCID iD orcid.org/0000-0003-3292-1886
ORCID for Giorgia Chiodin: ORCID iD orcid.org/0000-0002-1456-8997
ORCID for Dylan James Tatterton: ORCID iD orcid.org/0000-0002-1453-7496
ORCID for James Batchelor: ORCID iD orcid.org/0000-0002-5307-552X
ORCID for Francesco Forconi: ORCID iD orcid.org/0000-0002-2211-1831

Catalogue record

Date deposited: 28 Apr 2025 16:42
Last modified: 27 Aug 2025 02:05

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Contributors

Author: Dean Bryant ORCID iD
Author: Ben Sale ORCID iD
Author: Giorgia Chiodin ORCID iD
Author: Dylan James Tatterton ORCID iD
Author: Benjamin Kristian Stevens
Author: Alyssa Adlaon
Author: Erin Snook
Author: James Batchelor ORCID iD
Author: Alberto Orfao
Author: Francesco Forconi ORCID iD

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