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Ask your administrator if you think this is wrong. ======= INSIG1 ======= == Gene Information == * **<color #00a2e8>Official Symbol</color>**: INSIG1 * **<color #00a2e8>Official Name</color>**: insulin induced gene 1 * **<color #00a2e8>Aliases and Previous Symbols</color>**: N/A * **<color #00a2e8>Entrez ID</color>**: [[https://www.ncbi.nlm.nih.gov/gene/?term=3638|3638]] * **<color #00a2e8>UniProt</color>**: [[https://www.uniprot.org/uniprot/O15503|O15503]] * **<color #00a2e8>Interactions</color>**: [[https://thebiogrid.org/search.php?search=INSIG1&organism=9606|BioGRID]] * **<color #00a2e8>PubMed articles</color>**: [[https://www.ncbi.nlm.nih.gov/pubmed/?term=gene%20INSIG1|Open PubMed]] * **<color #00a2e8>OMIM</color>**: [[https://omim.org/entry/602055|Open OMIM]] == Function Summary == * **<color #00a2e8>Entrez Summary</color>**: N/A * **<color #00a2e8>UniProt Summary</color>**: Mediates feedback control of cholesterol synthesis by controlling SCAP and HMGCR. Functions by blocking the processing of sterol regulatory element-binding proteins (SREBPs). Capable of retaining the SCAP-SREBF2 complex in the ER thus preventing it from escorting SREBPs to the Golgi. Initiates the sterol-mediated ubiquitin-mediated endoplasmic reticulum-associated degradation (ERAD) of HMGCR via recruitment of the reductase to the ubiquitin ligase, AMFR/gp78. May play a role in growth and differentiation of tissues involved in metabolic control. May play a regulatory role during G0/G1 transition of cell growth. {ECO:0000269|PubMed:12202038, ECO:0000269|PubMed:12535518, ECO:0000269|PubMed:16168377, ECO:0000269|PubMed:16399501, ECO:0000269|PubMed:16606821}. <button type='primary' size='sm' modal='Pfam_Domains'>Pfam Domains</button> <button type='primary' size='sm' modal='GO_terms'>GO Terms</button> <modal id='Pfam_Domains' size='lg' title='Pfam Domains'> |INSIG| </modal> <modal id='GO_terms' size='lg' title='GO Terms'> |negative regulation of cargo loading into COPII-coated vesicle| |SREBP-SCAP complex retention in endoplasmic reticulum| |regulation of cargo loading into COPII-coated vesicle| |negative regulation of SREBP signaling pathway| |SREBP-SCAP-Insig complex| |regulation of SREBP signaling pathway| |SREBP signaling pathway| |cellular response to sterol depletion| |cranial suture morphogenesis| |negative regulation of protein exit from endoplasmic reticulum| |response to sterol depletion| |maintenance of protein localization in endoplasmic reticulum| |negative regulation of fatty acid biosynthetic process| |regulation of ER to Golgi vesicle-mediated transport| |craniofacial suture morphogenesis| |middle ear morphogenesis| |cellular response to sterol| |negative regulation of steroid biosynthetic process| |negative regulation of steroid metabolic process| |negative regulation of fatty acid metabolic process| |regulation of protein exit from endoplasmic reticulum| |response to sterol| |ER-nucleus signaling pathway| |maintenance of protein localization in organelle| |negative regulation of intracellular protein transport| |cholesterol biosynthetic process| |secondary alcohol biosynthetic process| |regulation of fatty acid biosynthetic process| |negative regulation of fat cell differentiation| |sterol biosynthetic process| |negative regulation of lipid biosynthetic process| |negative regulation of intracellular transport| |cranial skeletal system development| |triglyceride metabolic process| |maintenance of protein location in cell| |cholesterol homeostasis| |sterol homeostasis| |negative regulation of lipid metabolic process| |regulation of fatty acid metabolic process| |regulation of steroid biosynthetic process| |roof of mouth development| |negative regulation of small molecule metabolic process| |maintenance of location in cell| |inner ear morphogenesis| |acylglycerol metabolic process| |neutral lipid metabolic process| |maintenance of protein location| |alcohol biosynthetic process| |negative regulation of cellular protein localization| |bone morphogenesis| |regulation of steroid metabolic process| |cholesterol metabolic process| |ear morphogenesis| |regulation of fat cell differentiation| |steroid biosynthetic process| |secondary alcohol metabolic process| |lipid homeostasis| |sterol metabolic process| |protein localization to endoplasmic reticulum| |maintenance of location| |regulation of cellular ketone metabolic process| |negative regulation of protein transport| |negative regulation of establishment of protein localization| |organic hydroxy compound biosynthetic process| |regulation of lipid biosynthetic process| |inner ear development| |bone development| |ear development| |regulation of intracellular protein transport| |skeletal system morphogenesis| |sensory organ morphogenesis| |steroid metabolic process| |embryonic organ morphogenesis| |alcohol metabolic process| |regulation of intracellular transport| |negative regulation of organelle organization| |glycerolipid metabolic process| |regulation of lipid metabolic process| |regulation of small molecule metabolic process| |embryonic organ development| |organic hydroxy compound metabolic process| |negative regulation of transport| |skeletal system development| |cellular response to lipid| |regulation of cellular protein localization| |cellular response to organic cyclic compound| |sensory organ development| |regulation of vesicle-mediated transport| |embryonic morphogenesis| |lipid biosynthetic process| |small molecule biosynthetic process| |negative regulation of cellular component organization| |regulation of protein transport| |negative regulation of cell differentiation| |regulation of cellular response to stress| |protein localization to organelle| |regulation of peptide transport| |regulation of establishment of protein localization| |response to lipid| |regulation of cellular localization| |response to organic cyclic compound| |endoplasmic reticulum membrane| |negative regulation of developmental process| |animal organ morphogenesis| |cellular lipid metabolic process| |embryo development| |endoplasmic reticulum| |regulation of protein localization| |cellular response to oxygen-containing compound| |chemical homeostasis| |lipid metabolic process| |positive regulation of transcription by RNA polymerase II| |negative regulation of signal transduction| |regulation of organelle organization| |organic cyclic compound biosynthetic process| |negative regulation of cell communication| |negative regulation of signaling| |regulation of response to stress| |negative regulation of cellular biosynthetic process| |positive regulation of transcription, DNA-templated| |negative regulation of biosynthetic process| |response to oxygen-containing compound| |cellular protein localization| |cellular macromolecule localization| |negative regulation of response to stimulus| |positive regulation of nucleic acid-templated transcription| |positive regulation of RNA biosynthetic process| |homeostatic process| |cellular response to stress| |positive regulation of RNA metabolic process| |small molecule metabolic process| |regulation of cell differentiation| |regulation of transport| |positive regulation of nucleobase-containing compound metabolic process| |positive regulation of macromolecule biosynthetic process| |positive regulation of cellular biosynthetic process| |positive regulation of gene expression| |positive regulation of biosynthetic process| </modal> \\ === CRISPR Data === <button type='primary' size='small' modal='Compound_Hit'>Compound Hit</button> <button type='primary' size='small' modal='Most_Correlated_Genes'>Most Correlated Genes in Chemogenomics</button> <button type='primary' size='small' modal='Essential_Avana'>Tissues where Essential in the Avana Dataset (DepMap 20Q1)</button> <modal id='Compound_Hit' size='lg' title='Compound Hit'> ^Screen^Score^ |[[:results:exp416|Tubacin 1.6μM R07 exp416]]|-1.98| |[[:results:exp84|UM0125461 0.74μM R02 exp84]]|-1.86| |[[:results:exp466|Cannabidiol 20μM R08 exp466]]|1.7| |[[:results:exp282|Fluvastatin 2.2μM R06 exp282]]|2.09| |[[:results:exp164|Q15 1 to 2μM on day4 R04 exp164]]|2.19| |[[:results:exp89|Vemurafenib 6.6μM R02 exp89]]|2.28| |[[:results:exp79|Q15 2.7μM R02 exp79]]|2.98| |[[:results:exp226|Cerivastatin 0.15μM R05 exp226]]|3.06| |[[:results:exp434|Vemurafenib 6.6μM R08 exp434]]|3.08| </modal> <modal id='Most_Correlated_Genes' size='lg' title='Most Correlated Genes in Chemogenomics'> ^Gene^Correlation^ |[[:human genes:t:trappc10|TRAPPC10]]|0.4| </modal> <modal id='Essential_Avana' size='lg' title='Tissues where Essential in the Avana Dataset (DepMap 20Q1)'> Global Fraction of Cell Lines Where Essential: 1/739 ^Tissue^Fraction Of Cell Lines Where Essential^ |1290807.0|0/1| |909776.0|0/1| |bile duct|0/28| |blood|0/28| |bone|0/26| |breast|0/33| |central nervous system|0/56| |cervix|0/4| |colorectal|0/17| |esophagus|0/13| |fibroblast|0/1| |gastric|0/16| |kidney|0/21| |liver|0/20| |lung|0/75| |lymphocyte|0/16| |ovary|0/26| |pancreas|0/24| |peripheral nervous system|1/16| |plasma cell|0/15| |prostate|0/1| |skin|0/24| |soft tissue|0/9| |thyroid|0/2| |upper aerodigestive|0/22| |urinary tract|0/29| |uterus|0/5| </modal> == Essentiality in NALM6 == * **<color #00a2e8>Essentiality Rank</color>**: 2625 * **<color #00a2e8>Expression level (log2 read counts)</color>**: 7.1 <button type='primary' size='small' modal='Dist_expr'>Expression Distribution</button> <modal id='Dist_expr' size='lg' title='INSIG1 Expression in NALM6 Cells: 7.1'> {{:chemogenomics:nalm6 dist.png?nolink |}} </modal> Last modified: 2026/01/07 22:36by 127.0.0.1