RPL26L1 Gene

HGNC Family L ribosomal proteins (RPL)
Name ribosomal protein L26-like 1
Description This gene encodes a protein that shares high sequence similarity with ribosomal protein L26. Alternative splicing results in multiple transcript variants encoding the same protein. [provided by RefSeq, Dec 2015]
Summary
{"type": "root", "children": [{"type": "p", "children": [{"type": "t", "text": "\nThe collection of abstracts provided offers extensive insight into the multifaceted roles of voltage‐gated potassium channels—most notably Kv1.3—in the regulation of immune cell activation, apoptotic signaling, metabolic homeostasis, and sensory as well as neural functions. In these studies, Kv1.3 channels are shown to participate in apoptotic processes via interactions with pro‐apoptotic proteins, to modulate cytokine secretion and proliferation in lymphocytes and macrophages, and to influence metabolic responses such as insulin sensitivity and weight gain. In the nervous system, alterations in Kv1.3 activity associate with enhanced olfactory discrimination and modified synaptic architectures, while in immune‐mediated and neurodegenerative disease models, pharmacological inhibition of Kv1.3 is linked to attenuation of pro‐inflammatory responses and neuroprotection. Collectively, these works emphasize Kv1.3’s potential as a strategic therapeutic target in conditions ranging from autoimmunity and obesity to neurodegeneration and sensory dysfunction."}, {"type": "fg", "children": [{"type": "fg_fs", "start_ref": "1", "end_ref": "41"}]}, {"type": "t", "text": "\n"}]}, {"type": "t", "text": "\n\n"}, {"type": "p", "children": [{"type": "t", "text": "\nIt is important to note that although these abstracts richly document diverse functions and regulatory mechanisms of Kv1.3 and its associated channel complexes, none of the studies provide any discussion or functional characterization of RPL26L1. RPL26L1, which is known to be a ribosomal protein paralog involved in aspects of ribosome structure and function, is not mentioned in this body of literature. Consequently, no information regarding the cellular or molecular role of RPL26L1 can be deduced from these sources, and further inquiry into dedicated studies will be necessary to ascertain its function."}, {"type": "fg", "children": [{"type": "fg_fs", "start_ref": "1", "end_ref": "41"}]}, {"type": "t", "text": "\n"}]}, {"type": "rg", "children": [{"type": "r", "ref": 1, "children": [{"type": "t", "text": "Rubén Vicente, Artur Escalada, Mireia Coma, et al. 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"}, {"type": "b", "children": [{"type": "t", "text": "Kv1.3 channel gene-targeted deletion produces \"Super-Smeller Mice\" with altered glomeruli, interacting scaffolding proteins, and biophysics."}]}, {"type": "t", "text": " "}, {"type": "i", "children": [{"type": "t", "text": "Neuron (2004)"}]}, {"type": "t", "text": " DOI: "}, {"type": "a", "children": [{"type": "t", "text": "10.1016/s0896-6273(03)00844-4"}], "href": "https://doi.org/10.1016/s0896-6273(03"}, {"type": "t", "text": "00844-4) PMID: "}, {"type": "a", "children": [{"type": "t", "text": "14766178"}], "href": "https://pubmed.ncbi.nlm.nih.gov/14766178"}]}, {"type": "r", "ref": 3, "children": [{"type": "t", "text": "Jianchao Xu, Peili Wang, Yanyan Li, et al. 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"}, {"type": "b", "children": [{"type": "t", "text": "Pharmacological inhibition of Kv1.3 fails to modulate insulin sensitivity in diabetic mice or human insulin-sensitive tissues."}]}, {"type": "t", "text": " "}, {"type": "i", "children": [{"type": "t", "text": "Am J Physiol Endocrinol Metab (2011)"}]}, {"type": "t", "text": " DOI: "}, {"type": "a", "children": [{"type": "t", "text": "10.1152/ajpendo.00076.2011"}], "href": "https://doi.org/10.1152/ajpendo.00076.2011"}, {"type": "t", "text": " PMID: "}, {"type": "a", "children": [{"type": "t", "text": "21586699"}], "href": "https://pubmed.ncbi.nlm.nih.gov/21586699"}]}, {"type": "r", "ref": 19, "children": [{"type": "t", "text": "Torsten K Roepke, Vikram A Kanda, Kerry Purtell, et al. "}, {"type": "b", "children": [{"type": "t", "text": "KCNE2 forms potassium channels with KCNA3 and KCNQ1 in the choroid plexus epithelium."}]}, {"type": "t", "text": " "}, {"type": "i", "children": [{"type": "t", "text": "FASEB J (2011)"}]}, {"type": "t", "text": " DOI: "}, {"type": "a", "children": [{"type": "t", "text": "10.1096/fj.11-187609"}], "href": "https://doi.org/10.1096/fj.11-187609"}, {"type": "t", "text": " PMID: "}, {"type": "a", "children": [{"type": "t", "text": "21859894"}], "href": "https://pubmed.ncbi.nlm.nih.gov/21859894"}]}, {"type": "r", "ref": 20, "children": [{"type": "t", "text": "Debra Ann Fadool, Kristal Tucker, Paola Pedarzani "}, {"type": "b", "children": [{"type": "t", "text": "Mitral cells of the olfactory bulb perform metabolic sensing and are disrupted by obesity at the level of the Kv1.3 ion channel."}]}, {"type": "t", "text": " "}, {"type": "i", "children": [{"type": "t", "text": "PLoS One (2011)"}]}, {"type": "t", "text": " DOI: "}, {"type": "a", "children": [{"type": "t", "text": "10.1371/journal.pone.0024921"}], "href": "https://doi.org/10.1371/journal.pone.0024921"}, {"type": "t", "text": " PMID: "}, {"type": "a", "children": [{"type": "t", "text": "21966386"}], "href": "https://pubmed.ncbi.nlm.nih.gov/21966386"}]}, {"type": "r", "ref": 21, "children": [{"type": "t", "text": "Pilar Cidad, Laura Jiménez-Pérez, Daniel García-Arribas, et al. "}, {"type": "b", "children": [{"type": "t", "text": "Kv1.3 channels can modulate cell proliferation during phenotypic switch by an ion-flux independent mechanism."}]}, {"type": "t", "text": " "}, {"type": "i", "children": [{"type": "t", "text": "Arterioscler Thromb Vasc Biol (2012)"}]}, {"type": "t", "text": " DOI: "}, {"type": "a", "children": [{"type": "t", "text": "10.1161/ATVBAHA.111.242727"}], "href": "https://doi.org/10.1161/ATVBAHA.111.242727"}, {"type": "t", "text": " PMID: "}, {"type": "a", "children": [{"type": "t", "text": "22383699"}], "href": "https://pubmed.ncbi.nlm.nih.gov/22383699"}]}, {"type": "r", "ref": 22, "children": [{"type": "t", "text": "K Tucker, J M Overton, D A Fadool "}, {"type": "b", "children": [{"type": "t", "text": "Diet-induced obesity resistance of Kv1.3-/- mice is olfactory bulb dependent."}]}, {"type": "t", "text": " "}, {"type": "i", "children": [{"type": "t", "text": "J Neuroendocrinol (2012)"}]}, {"type": "t", "text": " DOI: "}, {"type": "a", "children": [{"type": "t", "text": "10.1111/j.1365-2826.2012.02314.x"}], "href": "https://doi.org/10.1111/j.1365-2826.2012.02314.x"}, {"type": "t", "text": " PMID: "}, {"type": "a", "children": [{"type": "t", "text": "22435906"}], "href": "https://pubmed.ncbi.nlm.nih.gov/22435906"}]}, {"type": "r", "ref": 23, "children": [{"type": "t", "text": "Sanjeev Kumar Upadhyay, Kristin L Eckel-Mahan, M Reza Mirbolooki, et al. 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"}, {"type": "b", "children": [{"type": "t", "text": "Epigenetic regulation of Kcna3-encoding Kv1.3 potassium channel by cereblon contributes to regulation of CD4+ T-cell activation."}]}, {"type": "t", "text": " "}, {"type": "i", "children": [{"type": "t", "text": "Proc Natl Acad Sci U S A (2016)"}]}, {"type": "t", "text": " DOI: "}, {"type": "a", "children": [{"type": "t", "text": "10.1073/pnas.1502166113"}], "href": "https://doi.org/10.1073/pnas.1502166113"}, {"type": "t", "text": " PMID: "}, {"type": "a", "children": [{"type": "t", "text": "27439875"}], "href": "https://pubmed.ncbi.nlm.nih.gov/27439875"}]}, {"type": "r", "ref": 33, "children": [{"type": "t", "text": "Hai M Nguyen, Eva M Grössinger, Makoto Horiuchi, et al. "}, {"type": "b", "children": [{"type": "t", "text": "Differential Kv1.3, KCa3.1, and Kir2.1 expression in \"classically\" and \"alternatively\" activated microglia."}]}, {"type": "t", "text": " "}, {"type": "i", "children": [{"type": "t", "text": "Glia (2017)"}]}, {"type": "t", "text": " DOI: "}, {"type": "a", "children": [{"type": "t", "text": "10.1002/glia.23078"}], "href": "https://doi.org/10.1002/glia.23078"}, {"type": "t", "text": " PMID: "}, {"type": "a", "children": [{"type": "t", "text": "27696527"}], "href": "https://pubmed.ncbi.nlm.nih.gov/27696527"}]}, {"type": "r", "ref": 34, "children": [{"type": "t", "text": "Laura Solé, Sara R Roig, Albert Vallejo-Gracia, et al. "}, {"type": "b", "children": [{"type": "t", "text": "The C-terminal domain of Kv1.3 regulates functional interactions with the KCNE4 subunit."}]}, {"type": "t", "text": " "}, {"type": "i", "children": [{"type": "t", "text": "J Cell Sci (2016)"}]}, {"type": "t", "text": " DOI: "}, {"type": "a", "children": [{"type": "t", "text": "10.1242/jcs.191650"}], "href": "https://doi.org/10.1242/jcs.191650"}, {"type": "t", "text": " PMID: "}, {"type": "a", "children": [{"type": "t", "text": "27802162"}], "href": "https://pubmed.ncbi.nlm.nih.gov/27802162"}]}, {"type": "r", "ref": 35, "children": [{"type": "t", "text": "Mireia Pérez-Verdaguer, Jesusa Capera, María Ortego-Domínguez, et al. 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Synonyms RPL26P1
Proteins RL26L_HUMAN
NCBI Gene ID 51121
API
Download Associations
Predicted Functions View RPL26L1's ARCHS4 Predicted Functions.
Co-expressed Genes View RPL26L1's ARCHS4 Predicted Functions.
Expression in Tissues and Cell Lines View RPL26L1's ARCHS4 Predicted Functions.

Functional Associations

RPL26L1 has 6,132 functional associations with biological entities spanning 8 categories (molecular profile, organism, chemical, functional term, phrase or reference, disease, phenotype or trait, structural feature, cell line, cell type or tissue, gene, protein or microRNA) extracted from 97 datasets.

Click the + buttons to view associations for RPL26L1 from the datasets below.

If available, associations are ranked by standardized value

Dataset Summary
Allen Brain Atlas Adult Human Brain Tissue Gene Expression Profiles tissues with high or low expression of RPL26L1 gene relative to other tissues from the Allen Brain Atlas Adult Human Brain Tissue Gene Expression Profiles dataset.
Allen Brain Atlas Aging Dementia and Traumatic Brain Injury Tissue Sample Gene Expression Profiles tissue samples with high or low expression of RPL26L1 gene relative to other tissue samples from the Allen Brain Atlas Aging Dementia and Traumatic Brain Injury Tissue Sample Gene Expression Profiles dataset.
Allen Brain Atlas Developing Human Brain Tissue Gene Expression Profiles by RNA-seq tissue samples with high or low expression of RPL26L1 gene relative to other tissue samples from the Allen Brain Atlas Developing Human Brain Tissue Gene Expression Profiles by RNA-seq dataset.
Allen Brain Atlas Prenatal Human Brain Tissue Gene Expression Profiles tissues with high or low expression of RPL26L1 gene relative to other tissues from the Allen Brain Atlas Prenatal Human Brain Tissue Gene Expression Profiles dataset.
BioGPS Cell Line Gene Expression Profiles cell lines with high or low expression of RPL26L1 gene relative to other cell lines from the BioGPS Cell Line Gene Expression Profiles dataset.
BioGPS Human Cell Type and Tissue Gene Expression Profiles cell types and tissues with high or low expression of RPL26L1 gene relative to other cell types and tissues from the BioGPS Human Cell Type and Tissue Gene Expression Profiles dataset.
Carcinogenome Chemical Perturbation Carcinogenicity Signatures small molecule perturbations changing expression of RPL26L1 gene from the Carcinogenome Chemical Perturbation Carcinogenicity Signatures dataset.
CCLE Cell Line Gene CNV Profiles cell lines with high or low copy number of RPL26L1 gene relative to other cell lines from the CCLE Cell Line Gene CNV Profiles dataset.
CCLE Cell Line Proteomics Cell lines associated with RPL26L1 protein from the CCLE Cell Line Proteomics dataset.
ChEA Transcription Factor Binding Site Profiles transcription factor binding site profiles with transcription factor binding evidence at the promoter of RPL26L1 gene from the CHEA Transcription Factor Binding Site Profiles dataset.
ChEA Transcription Factor Targets transcription factors binding the promoter of RPL26L1 gene in low- or high-throughput transcription factor functional studies from the CHEA Transcription Factor Targets dataset.
ChEA Transcription Factor Targets 2022 transcription factors binding the promoter of RPL26L1 gene in low- or high-throughput transcription factor functional studies from the CHEA Transcription Factor Targets 2022 dataset.
CMAP Signatures of Differentially Expressed Genes for Small Molecules small molecule perturbations changing expression of RPL26L1 gene from the CMAP Signatures of Differentially Expressed Genes for Small Molecules dataset.
COMPARTMENTS Curated Protein Localization Evidence Scores cellular components containing RPL26L1 protein from the COMPARTMENTS Curated Protein Localization Evidence Scores dataset.
COMPARTMENTS Curated Protein Localization Evidence Scores 2025 cellular components containing RPL26L1 protein from the COMPARTMENTS Curated Protein Localization Evidence Scores 2025 dataset.
COMPARTMENTS Experimental Protein Localization Evidence Scores cellular components containing RPL26L1 protein in low- or high-throughput protein localization assays from the COMPARTMENTS Experimental Protein Localization Evidence Scores dataset.
COMPARTMENTS Experimental Protein Localization Evidence Scores 2025 cellular components containing RPL26L1 protein in low- or high-throughput protein localization assays from the COMPARTMENTS Experimental Protein Localization Evidence Scores 2025 dataset.
COMPARTMENTS Text-mining Protein Localization Evidence Scores cellular components co-occuring with RPL26L1 protein in abstracts of biomedical publications from the COMPARTMENTS Text-mining Protein Localization Evidence Scores dataset.
COMPARTMENTS Text-mining Protein Localization Evidence Scores 2025 cellular components co-occuring with RPL26L1 protein in abstracts of biomedical publications from the COMPARTMENTS Text-mining Protein Localization Evidence Scores 2025 dataset.
COSMIC Cell Line Gene CNV Profiles cell lines with high or low copy number of RPL26L1 gene relative to other cell lines from the COSMIC Cell Line Gene CNV Profiles dataset.
COSMIC Cell Line Gene Mutation Profiles cell lines with RPL26L1 gene mutations from the COSMIC Cell Line Gene Mutation Profiles dataset.
CTD Gene-Chemical Interactions chemicals interacting with RPL26L1 gene/protein from the curated CTD Gene-Chemical Interactions dataset.
DeepCoverMOA Drug Mechanisms of Action small molecule perturbations with high or low expression of RPL26L1 protein relative to other small molecule perturbations from the DeepCoverMOA Drug Mechanisms of Action dataset.
DISEASES Experimental Gene-Disease Association Evidence Scores 2025 diseases associated with RPL26L1 gene in GWAS datasets from the DISEASES Experimental Gene-Disease Assocation Evidence Scores 2025 dataset.
DISEASES Text-mining Gene-Disease Association Evidence Scores diseases co-occuring with RPL26L1 gene in abstracts of biomedical publications from the DISEASES Text-mining Gene-Disease Assocation Evidence Scores dataset.
DISEASES Text-mining Gene-Disease Association Evidence Scores 2025 diseases co-occuring with RPL26L1 gene in abstracts of biomedical publications from the DISEASES Text-mining Gene-Disease Assocation Evidence Scores 2025 dataset.
DrugBank Drug Targets interacting drugs for RPL26L1 protein from the curated DrugBank Drug Targets dataset.
ENCODE Histone Modification Site Profiles histone modification site profiles with high histone modification abundance at RPL26L1 gene from the ENCODE Histone Modification Site Profiles dataset.
ENCODE Transcription Factor Binding Site Profiles transcription factor binding site profiles with transcription factor binding evidence at the promoter of RPL26L1 gene from the ENCODE Transcription Factor Binding Site Profiles dataset.
ENCODE Transcription Factor Targets transcription factors binding the promoter of RPL26L1 gene in ChIP-seq datasets from the ENCODE Transcription Factor Targets dataset.
GDSC Cell Line Gene Expression Profiles cell lines with high or low expression of RPL26L1 gene relative to other cell lines from the GDSC Cell Line Gene Expression Profiles dataset.
GeneSigDB Published Gene Signatures PubMedIDs of publications reporting gene signatures containing RPL26L1 from the GeneSigDB Published Gene Signatures dataset.
GEO Signatures of Differentially Expressed Genes for Diseases disease perturbations changing expression of RPL26L1 gene from the GEO Signatures of Differentially Expressed Genes for Diseases dataset.
GEO Signatures of Differentially Expressed Genes for Gene Perturbations gene perturbations changing expression of RPL26L1 gene from the GEO Signatures of Differentially Expressed Genes for Gene Perturbations dataset.
GEO Signatures of Differentially Expressed Genes for Kinase Perturbations kinase perturbations changing expression of RPL26L1 gene from the GEO Signatures of Differentially Expressed Genes for Kinase Perturbations dataset.
GEO Signatures of Differentially Expressed Genes for Small Molecules small molecule perturbations changing expression of RPL26L1 gene from the GEO Signatures of Differentially Expressed Genes for Small Molecules dataset.
GEO Signatures of Differentially Expressed Genes for Transcription Factor Perturbations transcription factor perturbations changing expression of RPL26L1 gene from the GEO Signatures of Differentially Expressed Genes for Transcription Factor Perturbations dataset.
GEO Signatures of Differentially Expressed Genes for Viral Infections virus perturbations changing expression of RPL26L1 gene from the GEO Signatures of Differentially Expressed Genes for Viral Infections dataset.
GO Biological Process Annotations 2015 biological processes involving RPL26L1 gene from the curated GO Biological Process Annotations 2015 dataset.
GO Biological Process Annotations 2023 biological processes involving RPL26L1 gene from the curated GO Biological Process Annotations 2023 dataset.
GO Biological Process Annotations 2025 biological processes involving RPL26L1 gene from the curated GO Biological Process Annotations2025 dataset.
GO Cellular Component Annotations 2015 cellular components containing RPL26L1 protein from the curated GO Cellular Component Annotations 2015 dataset.
GO Cellular Component Annotations 2023 cellular components containing RPL26L1 protein from the curated GO Cellular Component Annotations 2023 dataset.
GO Cellular Component Annotations 2025 cellular components containing RPL26L1 protein from the curated GO Cellular Component Annotations 2025 dataset.
GO Molecular Function Annotations 2015 molecular functions performed by RPL26L1 gene from the curated GO Molecular Function Annotations 2015 dataset.
GO Molecular Function Annotations 2023 molecular functions performed by RPL26L1 gene from the curated GO Molecular Function Annotations 2023 dataset.
GTEx Tissue Gene Expression Profiles tissues with high or low expression of RPL26L1 gene relative to other tissues from the GTEx Tissue Gene Expression Profiles dataset.
GTEx Tissue Gene Expression Profiles 2023 tissues with high or low expression of RPL26L1 gene relative to other tissues from the GTEx Tissue Gene Expression Profiles 2023 dataset.
GTEx Tissue Sample Gene Expression Profiles tissue samples with high or low expression of RPL26L1 gene relative to other tissue samples from the GTEx Tissue Sample Gene Expression Profiles dataset.
GTEx Tissue-Specific Aging Signatures tissue samples with high or low expression of RPL26L1 gene relative to other tissue samples from the GTEx Tissue-Specific Aging Signatures dataset.
Heiser et al., PNAS, 2011 Cell Line Gene Expression Profiles cell lines with high or low expression of RPL26L1 gene relative to other cell lines from the Heiser et al., PNAS, 2011 Cell Line Gene Expression Profiles dataset.
HPA Cell Line Gene Expression Profiles cell lines with high or low expression of RPL26L1 gene relative to other cell lines from the HPA Cell Line Gene Expression Profiles dataset.
HPA Tissue Gene Expression Profiles tissues with high or low expression of RPL26L1 gene relative to other tissues from the HPA Tissue Gene Expression Profiles dataset.
HPA Tissue Protein Expression Profiles tissues with high or low expression of RPL26L1 protein relative to other tissues from the HPA Tissue Protein Expression Profiles dataset.
HPA Tissue Sample Gene Expression Profiles tissue samples with high or low expression of RPL26L1 gene relative to other tissue samples from the HPA Tissue Sample Gene Expression Profiles dataset.
Hub Proteins Protein-Protein Interactions interacting hub proteins for RPL26L1 from the curated Hub Proteins Protein-Protein Interactions dataset.
InterPro Predicted Protein Domain Annotations protein domains predicted for RPL26L1 protein from the InterPro Predicted Protein Domain Annotations dataset.
JASPAR Predicted Human Transcription Factor Targets 2025 transcription factors regulating expression of RPL26L1 gene predicted using known transcription factor binding site motifs from the JASPAR Predicted Human Transcription Factor Targets dataset.
JASPAR Predicted Transcription Factor Targets transcription factors regulating expression of RPL26L1 gene predicted using known transcription factor binding site motifs from the JASPAR Predicted Transcription Factor Targets dataset.
KEGG Pathways 2026 pathways involving RPL26L1 protein from the KEGG Pathways 2026 dataset.
Kinase Library Serine Threonine Kinome Atlas kinases that phosphorylate RPL26L1 protein from the Kinase Library Serine Threonine Atlas dataset.
Klijn et al., Nat. Biotechnol., 2015 Cell Line Gene CNV Profiles cell lines with high or low copy number of RPL26L1 gene relative to other cell lines from the Klijn et al., Nat. Biotechnol., 2015 Cell Line Gene CNV Profiles dataset.
Klijn et al., Nat. Biotechnol., 2015 Cell Line Gene Expression Profiles cell lines with high or low expression of RPL26L1 gene relative to other cell lines from the Klijn et al., Nat. Biotechnol., 2015 Cell Line Gene Expression Profiles dataset.
KnockTF Gene Expression Profiles with Transcription Factor Perturbations transcription factor perturbations changing expression of RPL26L1 gene from the KnockTF Gene Expression Profiles with Transcription Factor Perturbations dataset.
LINCS L1000 CMAP Chemical Perturbation Consensus Signatures small molecule perturbations changing expression of RPL26L1 gene from the LINCS L1000 CMAP Chemical Perturbations Consensus Signatures dataset.
LINCS L1000 CMAP CRISPR Knockout Consensus Signatures gene perturbations changing expression of RPL26L1 gene from the LINCS L1000 CMAP CRISPR Knockout Consensus Signatures dataset.
LINCS L1000 CMAP Signatures of Differentially Expressed Genes for Small Molecules small molecule perturbations changing expression of RPL26L1 gene from the LINCS L1000 CMAP Signatures of Differentially Expressed Genes for Small Molecules dataset.
LOCATE Predicted Protein Localization Annotations cellular components predicted to contain RPL26L1 protein from the LOCATE Predicted Protein Localization Annotations dataset.
MiRTarBase microRNA Targets microRNAs targeting RPL26L1 gene in low- or high-throughput microRNA targeting studies from the MiRTarBase microRNA Targets dataset.
MotifMap Predicted Transcription Factor Targets transcription factors regulating expression of RPL26L1 gene predicted using known transcription factor binding site motifs from the MotifMap Predicted Transcription Factor Targets dataset.
MSigDB Cancer Gene Co-expression Modules co-expressed genes for RPL26L1 from the MSigDB Cancer Gene Co-expression Modules dataset.
NIBR DRUG-seq U2OS MoA Box Gene Expression Profiles drug perturbations changing expression of RPL26L1 gene from the NIBR DRUG-seq U2OS MoA Box dataset.
NURSA Protein Complexes protein complexs containing RPL26L1 protein recovered by IP-MS from the NURSA Protein Complexes dataset.
NURSA Protein-Protein Interactions interacting proteins for RPL26L1 from the NURSA Protein-Protein Interactions dataset.
Pathway Commons Protein-Protein Interactions interacting proteins for RPL26L1 from the Pathway Commons Protein-Protein Interactions dataset.
PerturbAtlas Signatures of Differentially Expressed Genes for Gene Perturbations gene perturbations changing expression of RPL26L1 gene from the PerturbAtlas Signatures of Differentially Expressed Genes for Gene Perturbations dataset.
PFOCR Pathway Figure Associations 2023 pathways involving RPL26L1 protein from the PFOCR Pathway Figure Associations 2023 dataset.
PFOCR Pathway Figure Associations 2024 pathways involving RPL26L1 protein from the Wikipathways PFOCR 2024 dataset.
Reactome Pathways 2014 pathways involving RPL26L1 protein from the Reactome Pathways dataset.
Reactome Pathways 2024 pathways involving RPL26L1 protein from the Reactome Pathways 2024 dataset.
Replogle et al., Cell, 2022 K562 Essential Perturb-seq Gene Perturbation Signatures gene perturbations changing expression of RPL26L1 gene from the Replogle et al., Cell, 2022 K562 Essential Perturb-seq Gene Perturbation Signatures dataset.
Replogle et al., Cell, 2022 K562 Genome-wide Perturb-seq Gene Perturbation Signatures gene perturbations changing expression of RPL26L1 gene from the Replogle et al., Cell, 2022 K562 Genome-wide Perturb-seq Gene Perturbation Signatures dataset.
Replogle et al., Cell, 2022 RPE1 Essential Perturb-seq Gene Perturbation Signatures gene perturbations changing expression of RPL26L1 gene from the Replogle et al., Cell, 2022 RPE1 Essential Perturb-seq Gene Perturbation Signatures dataset.
Roadmap Epigenomics Histone Modification Site Profiles histone modification site profiles with high histone modification abundance at RPL26L1 gene from the Roadmap Epigenomics Histone Modification Site Profiles dataset.
RummaGEO Drug Perturbation Signatures drug perturbations changing expression of RPL26L1 gene from the RummaGEO Drug Perturbation Signatures dataset.
RummaGEO Gene Perturbation Signatures gene perturbations changing expression of RPL26L1 gene from the RummaGEO Gene Perturbation Signatures dataset.
Sanger Dependency Map Cancer Cell Line Proteomics cell lines associated with RPL26L1 protein from the Sanger Dependency Map Cancer Cell Line Proteomics dataset.
Sci-Plex Drug Perturbation Signatures drug perturbations changing expression of RPL26L1 gene from the Sci-Plex Drug Perturbation Signatures dataset.
SILAC Phosphoproteomics Signatures of Differentially Phosphorylated Proteins for Drugs drug perturbations changing phosphorylation of RPL26L1 protein from the SILAC Phosphoproteomics Signatures of Differentially Phosphorylated Proteins for Drugs dataset.
TargetScan Predicted Nonconserved microRNA Targets microRNAs regulating expression of RPL26L1 gene predicted using nonconserved miRNA seed sequences from the TargetScan Predicted Nonconserved microRNA Targets dataset.
TCGA Signatures of Differentially Expressed Genes for Tumors tissue samples with high or low expression of RPL26L1 gene relative to other tissue samples from the TCGA Signatures of Differentially Expressed Genes for Tumors dataset.
TISSUES Curated Tissue Protein Expression Evidence Scores tissues with high expression of RPL26L1 protein from the TISSUES Curated Tissue Protein Expression Evidence Scores dataset.
TISSUES Curated Tissue Protein Expression Evidence Scores 2025 tissues with high expression of RPL26L1 protein from the TISSUES Curated Tissue Protein Expression Evidence Scores 2025 dataset.
TISSUES Experimental Tissue Protein Expression Evidence Scores tissues with high expression of RPL26L1 protein in proteomics datasets from the TISSUES Experimental Tissue Protein Expression Evidence Scores dataset.
TISSUES Experimental Tissue Protein Expression Evidence Scores 2025 tissues with high expression of RPL26L1 protein in proteomics datasets from the TISSUES Experimental Tissue Protein Expression Evidence Scores 2025 dataset.
TISSUES Text-mining Tissue Protein Expression Evidence Scores tissues co-occuring with RPL26L1 protein in abstracts of biomedical publications from the TISSUES Text-mining Tissue Protein Expression Evidence Scores dataset.
TISSUES Text-mining Tissue Protein Expression Evidence Scores 2025 tissues co-occuring with RPL26L1 protein in abstracts of biomedical publications from the TISSUES Text-mining Tissue Protein Expression Evidence Scores 2025 dataset.