SNRPD2-dependency Fuels an Oncogenic Alternative Splicing Repertoire Driving Disease Aggressiveness in Glioma

Dayu Li; Jinshan Wang; Guofeng Zhang; Emily Shang; Farhana Akter; Jiaming Wang; Xingping Qin; Haipeng Liu; Ailiang Zeng; Shun Yao; Yanmei Tie; Kashif Rafiq Zahid; Shaolei Guo

doi:10.21873/cgp.20570

SNRPD2-dependency Fuels an Oncogenic Alternative Splicing Repertoire Driving Disease Aggressiveness in Glioma

Dayu Li
, Jinshan Wang
, Guofeng Zhang
, Emily Shang
, Farhana Akter
, Jiaming Wang
, Xingping Qin
, Haipeng Liu
, Ailiang Zeng
, Shun Yao
, Yanmei Tie
, Kashif Rafiq Zahid
, Shaolei Guo

Dongguan Dalang Hospital
First Affiliated Hospital of Sun Yat-sen University
Wellesley College
Harvard University
National Medical Research Association
Cardiovascular Analytics Group
Icahn School of Medicine at Mount Sinai
Harvard Medical School
University of Alabama at Birmingham

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

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Abstract

Background/Aim: Gliomas are the most common primary brain tumors, yet the molecular circuits that drive their malignancy remain incompletely defined. Here, using an integrative, multi-dimensional approach, we aimed to pinpoint key molecular drivers having both functional and clinical relevance to disease progression and tumor aggressiveness in gliomas. Materials and Methods: Genome-wide CRISPR-Cas9 dependency screen across 70 glioma cell lines was paired with tumor aggressiveness-targeted transcriptomic differential expression and survival analyses to pinpoint critical drivers of disease progression in gliomas. Functional and gene set enrichments as well as protein-protein interaction network analyses were used to identify dominant pathways and key hub genes, followed by independent validation across external transcriptomic and proteomic datasets. Upstream regulator analyses and alternative splicing profiling were performed to nominate regulatory drivers and derive a small nuclear ribonucleoprotein D2 polypeptide (SNRPD2)-associated splicing signature. Results: Initial screening uncovered 222 essential genes (Chronos<−1) in gliomas, 87 of which were overexpressed in tumors displaying proliferative, epithelial-mesenchymal transition, glycolytic, hypoxic, and inflammatory signatures, and were associated with poor overall survival, consistent with aggressive disease biology. These genes converged on alternative splicing regulation, proteasome function, and cell cycle, with spliceosome core component, SNRPD2 emerging as the top hub gene. High SNRPD2 expression was associated with disease aggressiveness, tumor progression, and adverse clinical outcomes. MYC was identified as a putative transcriptional driver of SNRPD2. High SNRPD2 expression was also linked to differential (oncogenic) alternative splicing of multiple cancer-associated genes, correlating with disease aggressiveness and poor clinical outcomes. Conclusion: These data establish SNRPD2 and its associated alternatively spliced repertoire as a central adaptive node linked to disease aggressiveness in gliomas, highlighting it as a potential therapeutic target in glioma patients.

Original language	English
Pages (from-to)	169-194
Number of pages	26
Journal	Cancer genomics & proteomics
Volume	23
Issue number	2
Early online date	1 Mar 2026
DOIs	https://doi.org/10.21873/cgp.20570
Publication status	E-pub ahead of print - 1 Mar 2026

Bibliographical note

This is an open access article under the terms of the Creative Commons Attribution License, which permits use, distribution and reproduction in any medium, provided the original work is properly cited.

Funding

This work is supported by Guangdong Province Key Technologies R&D Program for “Brain Science and Brain-like Intelligence Research” (2023B0303020002) and Guangdong Basic and Applied Basic Research Foundation (2024A1515011697).

Funders	Funder number
Guangdong Province Key Technologies R&D Program	2023B0303020002
Basic and Applied Basic Research Foundation of Guangdong Province	2024A1515011697

UN SDGs

This output contributes to the following UN Sustainable Development Goals (SDGs)

SDG 3 Good Health and Well-being

Keywords

tumor aggressiveness
Glioma
MYC
SNRPD2
oncogenic alternative splicing
spliceosome

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10.21873/cgp.20570Licence: CC BY-NC-ND

Liu2026VoRFinal published version, 11.8 MBLicence: CC BY-NC-ND

Cite this

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title = "SNRPD2-dependency Fuels an Oncogenic Alternative Splicing Repertoire Driving Disease Aggressiveness in Glioma",

abstract = "Background/Aim: Gliomas are the most common primary brain tumors, yet the molecular circuits that drive their malignancy remain incompletely defined. Here, using an integrative, multi-dimensional approach, we aimed to pinpoint key molecular drivers having both functional and clinical relevance to disease progression and tumor aggressiveness in gliomas. Materials and Methods: Genome-wide CRISPR-Cas9 dependency screen across 70 glioma cell lines was paired with tumor aggressiveness-targeted transcriptomic differential expression and survival analyses to pinpoint critical drivers of disease progression in gliomas. Functional and gene set enrichments as well as protein-protein interaction network analyses were used to identify dominant pathways and key hub genes, followed by independent validation across external transcriptomic and proteomic datasets. Upstream regulator analyses and alternative splicing profiling were performed to nominate regulatory drivers and derive a small nuclear ribonucleoprotein D2 polypeptide (SNRPD2)-associated splicing signature. Results: Initial screening uncovered 222 essential genes (Chronos<−1) in gliomas, 87 of which were overexpressed in tumors displaying proliferative, epithelial-mesenchymal transition, glycolytic, hypoxic, and inflammatory signatures, and were associated with poor overall survival, consistent with aggressive disease biology. These genes converged on alternative splicing regulation, proteasome function, and cell cycle, with spliceosome core component, SNRPD2 emerging as the top hub gene. High SNRPD2 expression was associated with disease aggressiveness, tumor progression, and adverse clinical outcomes. MYC was identified as a putative transcriptional driver of SNRPD2. High SNRPD2 expression was also linked to differential (oncogenic) alternative splicing of multiple cancer-associated genes, correlating with disease aggressiveness and poor clinical outcomes. Conclusion: These data establish SNRPD2 and its associated alternatively spliced repertoire as a central adaptive node linked to disease aggressiveness in gliomas, highlighting it as a potential therapeutic target in glioma patients.",

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note = "This is an open access article under the terms of the Creative Commons Attribution License, which permits use, distribution and reproduction in any medium, provided the original work is properly cited. ",

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doi = "10.21873/cgp.20570",

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T1 - SNRPD2-dependency Fuels an Oncogenic Alternative Splicing Repertoire Driving Disease Aggressiveness in Glioma

AU - Li, Dayu

AU - Wang, Jinshan

AU - Zhang, Guofeng

AU - Shang, Emily

AU - Akter, Farhana

AU - Wang, Jiaming

AU - Qin, Xingping

AU - Liu, Haipeng

AU - Zeng, Ailiang

AU - Yao, Shun

AU - Tie, Yanmei

AU - Zahid, Kashif Rafiq

AU - Guo, Shaolei

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PY - 2026/3/1

Y1 - 2026/3/1

N2 - Background/Aim: Gliomas are the most common primary brain tumors, yet the molecular circuits that drive their malignancy remain incompletely defined. Here, using an integrative, multi-dimensional approach, we aimed to pinpoint key molecular drivers having both functional and clinical relevance to disease progression and tumor aggressiveness in gliomas. Materials and Methods: Genome-wide CRISPR-Cas9 dependency screen across 70 glioma cell lines was paired with tumor aggressiveness-targeted transcriptomic differential expression and survival analyses to pinpoint critical drivers of disease progression in gliomas. Functional and gene set enrichments as well as protein-protein interaction network analyses were used to identify dominant pathways and key hub genes, followed by independent validation across external transcriptomic and proteomic datasets. Upstream regulator analyses and alternative splicing profiling were performed to nominate regulatory drivers and derive a small nuclear ribonucleoprotein D2 polypeptide (SNRPD2)-associated splicing signature. Results: Initial screening uncovered 222 essential genes (Chronos<−1) in gliomas, 87 of which were overexpressed in tumors displaying proliferative, epithelial-mesenchymal transition, glycolytic, hypoxic, and inflammatory signatures, and were associated with poor overall survival, consistent with aggressive disease biology. These genes converged on alternative splicing regulation, proteasome function, and cell cycle, with spliceosome core component, SNRPD2 emerging as the top hub gene. High SNRPD2 expression was associated with disease aggressiveness, tumor progression, and adverse clinical outcomes. MYC was identified as a putative transcriptional driver of SNRPD2. High SNRPD2 expression was also linked to differential (oncogenic) alternative splicing of multiple cancer-associated genes, correlating with disease aggressiveness and poor clinical outcomes. Conclusion: These data establish SNRPD2 and its associated alternatively spliced repertoire as a central adaptive node linked to disease aggressiveness in gliomas, highlighting it as a potential therapeutic target in glioma patients.

AB - Background/Aim: Gliomas are the most common primary brain tumors, yet the molecular circuits that drive their malignancy remain incompletely defined. Here, using an integrative, multi-dimensional approach, we aimed to pinpoint key molecular drivers having both functional and clinical relevance to disease progression and tumor aggressiveness in gliomas. Materials and Methods: Genome-wide CRISPR-Cas9 dependency screen across 70 glioma cell lines was paired with tumor aggressiveness-targeted transcriptomic differential expression and survival analyses to pinpoint critical drivers of disease progression in gliomas. Functional and gene set enrichments as well as protein-protein interaction network analyses were used to identify dominant pathways and key hub genes, followed by independent validation across external transcriptomic and proteomic datasets. Upstream regulator analyses and alternative splicing profiling were performed to nominate regulatory drivers and derive a small nuclear ribonucleoprotein D2 polypeptide (SNRPD2)-associated splicing signature. Results: Initial screening uncovered 222 essential genes (Chronos<−1) in gliomas, 87 of which were overexpressed in tumors displaying proliferative, epithelial-mesenchymal transition, glycolytic, hypoxic, and inflammatory signatures, and were associated with poor overall survival, consistent with aggressive disease biology. These genes converged on alternative splicing regulation, proteasome function, and cell cycle, with spliceosome core component, SNRPD2 emerging as the top hub gene. High SNRPD2 expression was associated with disease aggressiveness, tumor progression, and adverse clinical outcomes. MYC was identified as a putative transcriptional driver of SNRPD2. High SNRPD2 expression was also linked to differential (oncogenic) alternative splicing of multiple cancer-associated genes, correlating with disease aggressiveness and poor clinical outcomes. Conclusion: These data establish SNRPD2 and its associated alternatively spliced repertoire as a central adaptive node linked to disease aggressiveness in gliomas, highlighting it as a potential therapeutic target in glioma patients.

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KW - Glioma

KW - MYC

KW - SNRPD2

KW - oncogenic alternative splicing

KW - spliceosome

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SN - 1790-6245

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JO - Cancer genomics & proteomics

JF - Cancer genomics & proteomics

IS - 2

ER -

SNRPD2-dependency Fuels an Oncogenic Alternative Splicing Repertoire Driving Disease Aggressiveness in Glioma

Abstract

Bibliographical note

Funding

UN SDGs

Keywords

Access to Document

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