C22orf23 (Chromosome 22 Open Reading Frame 23) is a protein which in humans is encoded by the C22orf23 gene. Its predicted secondary structure consists of alpha helices and disordered/coil regions. It is expressed in many tissues and highest in the testes and it is conserved across many orthologs.
C22orf23 | |||||||||||||||||||||||||||||||||||||||||||||||||||
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Aliases | C22orf23, EVG1, dJ1039K5.6, chromosome 22 open reading frame 23 | ||||||||||||||||||||||||||||||||||||||||||||||||||
External IDs | MGI: 1920774; HomoloGene: 13062; GeneCards: C22orf23; OMA:C22orf23 - orthologs | ||||||||||||||||||||||||||||||||||||||||||||||||||
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Gene
editSize and locus
editC22orf23 is a gene found in homo sapiens. It is located on Chromosome 22 on the minus strand, map position 22q13.1. It spans 10,620 base pairs.[5][6] Its mRNA transcript is 1988 base pars long and has 7 exons.[7] Its predicted function is protein binding, and molecular function.[5]
Common aliases
editC22orf23's aliases are: UPF0193 Protein EVG1, DJ1039K5.6, EVG1[8] FLJ32787, and LOC84645.[9]
Protein
editPrimary sequence
editThe protein encoded by the mRNA sequence is 217 amino acids in length[6] and has a predicted molecular mass of 25 kDa.[8][10] The predicted isoelectric point is 9.8.[11] It is located in the nucleus.[10]
Domains and motifs
editIt is predicted to be an intracellular protein[10] and does not have any predicted transmembrane domains.[10][12][13] Due to its location and lack of predicted transmembrane domains, the protein structure is likely a globular protein.
Post-Translational Modifications
editC22orf23 has many predicted post-translational modifications such as: phosphorylation sites,[15] cell attachment sequences, N-myristoylation sites,[16] O-linked glycosylation sites,[17] glycation sites,[18] Ac-ASQK cleaved-acetylated sites, and Sumoylation sites.[19][20] Many of the predicted phosphorylation sites were also predicted to be O-linked glycosylation sites thus the phosphorylation site could be blocked altering that domain's structure or function.
Secondary Structure
editThe predicted secondary structure consists of alpha helices and disordered/coil regions.[14][21][22][23][24] The predicted secondary structure model has a 28% coverage of the amino acid sequence with a 42.9% confidence.[14]
Homology
editParalogs
editThere are currently no known paralogs to C22orf23.[25][26][27]
Orthologs
editOrthologs can be found in most major groups of species ranging from most similar in primates to most distant in a member of phylum Chytridiomycota. This includes: mammals, reptiles, birds, amphibian, bony fish, cartilaginous fish, invertebrates, and fungi. Orthologs may have first appeared in plants or fungi however it is uncertain.[26]
This table lists several orthologs for C22orf23 and includes their species name, common name, taxonomic order, accession number, sequence length, sequence similarity,[26] and evolutionary date of divergence.[28]
Genus and Species | Common Name | Taxonomic Group (Order) | Date of Divergence (MYA) | Accession # | Sequence Length (aa) | Sequence Identity (%) |
---|---|---|---|---|---|---|
Homo sapiens | Human | Primate | 0 | AAH31998.1 | 217 | 100 |
Piliocolobus tephrosceles | Ugandan Red Colobus | Primate | 29 | XP_023077818 | 217 | 95 |
Propithecus coquereli | Coquerel's Sifaka | Primate | 74 | XP_012493592 | 217 | 84 |
Marmota marmota marmota | Alpine Marmot | Rodent | 90 | XP_015338208 | 217 | 73 |
Mus caroli | Ryukyu Mouse | Rodent | 90 | XP_021038824 | 216 | 81 |
Physeter catodon | Sperm Whale | Even-toed ungulates | 96 | XP_007111804 | 217 | 85 |
Odocoileus virginianus texanus | White Tailed Deer | Artiodactyla | 96 | XP_020752151 | 217 | 86 |
Panthera pardus | Leopard | Carnivores | 96 | XP_019302406 | 217 | 85 |
Rousettus aegyptiacus | Egyptian Fruit Bat | Bat | 96 | XP_016017249 | 217 | 83 |
Condylura cristata | Star-nosed Mole | Eulipotyphla | 96 | XP_004676507 | 217 | 80 |
Vombatus ursinus | Common Wombat | Diprotodontia | 159 | XP_027727589 | 263 | 61 |
Nothoprocta perdicaria | Chilean Tinamou | Tinamiformes | 312 | XP_025895660 | 234 | 61 |
Serinus canaria | Atlantic Canary | Passeriformes | 312 | XP_009084739 | 223 | 57 |
Notechis scutatus | Tiger Snake | Squamata | 312 | XP_026550684 | 234 | 56 |
Nanorana parkeri | High Himalaya Frog | Frog | 352 | XP_018428081 | 225 | 51 |
Salvelinus alpinus | Arctic char | Salmoniformes | 435 | XP_023998646 | 217 | 49 |
Rhincodon typus | Whale Shark | Carpet shark | 473 | XP_020370272 | 232 | 48 |
Callorhinchus milii | Australian ghostshark | Chimaera | 473 | NP_001279734 | 232 | 46 |
Apostichopus japonicus | Sea Cucumber | Synallactida | 684 | PIK47438 | 221 | 48 |
Crassostrea virginica | Eastern Oyster | Ostreoida | 797 | XP_022313321.1 | 224 | 43 |
Capitella teleta | Segmented Annelid Worm | Capitellidae | 797 | ELU02060 | 221 | 39 |
Megachile rotundata | Leafcutter Bee | Hymenopterans | 797 | XP_003702438 | 230 | 36 |
Stylophora pistillata | Hood Coral | Stony corals | 824 | XP_022780055 | 219 | 42 |
Pocillopora damicornis | Cauliflower Coral | Scleractinia | 824 | XP_027046963 | 220 | 42 |
Macrostomum lignano | Flatworm | Macrostomida | 824 | PAA47644 | 270 | 38 |
Trichoplax | Trichoplax | Tricoplaciformes | 948 | RDD45244 | 239 | 39 |
Spizellomyces punctatus | Fungi | Spizellomyces punctatus | 1105 | XP_016608264[29] | 260 | 30 |
Expression
editPromoter
editThe core promoter is GXP_7541220 (-), and its coordinates are 37953445-37954669 and it is 1225 base pairs long.[30]
Tissue expression
editHuman expression
editProtein expression is highest in the testes however it is also expressed at low levels in many other tissues such as: brain, kidney, stomach, skin,[31] thyroid, urinary bladder, placenta, endometrium, esophagus, and appendix, bone marrow, adipose, lung,[32] and ovary.[33]
Ortholog expression
editExpression in orthologs Rattus norvegicus, is expressed primarily in the testes with low levels of expression in the: kidneys, lungs, heart, and uterus.[34] Mus musculus is expressed primarily in the adrenal and testes, and also notably expressed in the: bladder, abdomen, heart, lungs, ovaries, and mammary gland.[35]
Interactions
editProtein Interactions
editThere are several predicted protein interactions: Cyclin-D1-binding protein 1 which may regulate cell cycle progression, Vacuolar protein sorting-associated protein 28 homolog which is involved as a regulator of vesicular trafficking, UPF0739 protein C1orf74, and estrogen related receptor gamma. These interacting proteins were identified as either having direct interactions or physical associations. They were identified through a variety of detection methods including affinity chromatography, 2 hybrid prey pooling, and 2 hybrid array.[36][37][38] It also has predicted protein interactions with SH3 domain containing 19, EvC ciliary complex subunit 1, RIMS binding protein 3B, RIMS binding protein 3C,TSSK6-activating co-chaperone protein, V-set and immunoglobulin domain containing 8, family with sequence similarity 124 member B, small nucleolar RNA host gene 28, and transmembrane protein 200B. Evidence suggesting a functional link for these interactions were supported through Co-mention on PubMed.[36][39]
Clinical Significance
editDisease Association
editC22orf23 was identified as belonging to one of two groups of pooled serum samples in a study that analyzed the difference between serum glycoproteins of hepatocellular carcinoma and that of normal serum.[40] Deletions of parts of C22orf23 (exons 3 and 4) and several other genes including SOX10 has been observed in patients with peripheral demyelinating neuropathy, central demyelinating leukodystrophy, Waardenburg Syndrome, and Hirschsprung disease and is therefore, suggested to be a potential factor involved in these ailments.[41][42] C22orf23 was also mentioned in a study of mutation profiles from ER+ breast cancer samples taken from postmenopausal patience. There were mutations found that affected C22orf23 among many other genes.[43] In a study of epigenetic alterations involved in coronary artery disease, C22orf23 was found to have altered epigenetic modifications which could be involved in novel genes in Coronary artery disease.[44] In a study that attempts to predict imprinted genes that maybe linked to Human disorders, C22orf23 was identified as homologous of imprinted Gene candidates showing linkage to schizophrenia.[45] In another study it was listed as being a potently regulated protein in uterine leiomyoma.[46]
Mutations
editThere are a total of 3340 SNPs within the 5’ and 3’ UTR, introns, exons, as well as some genes near the 5’ and 3’ UTR. There is a total of 225 SNPs within the coding sequence. Some of the SNPs occur in conserved amino acids within the coding sequence and some reported have one or more types of validation. Some of the SNPs have high heterozygosity scores and thus have a presence in the population.[47]
References
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- ^ a b c GRCm38: Ensembl release 89: ENSMUSG00000033029 – Ensembl, May 2017
- ^ "Human PubMed Reference:". National Center for Biotechnology Information, U.S. National Library of Medicine.
- ^ "Mouse PubMed Reference:". National Center for Biotechnology Information, U.S. National Library of Medicine.
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- ^ Russ C, Lang BF, Chen Z, Gujja S, Shea T, Zeng Q, Young S, Cuomo CA, Nusbaum C (August 2016). "Genome Sequence of Spizellomyces punctatus". Genome Announcements. 4 (4): e00849-16. doi:10.1128/genomeA.00849-16. PMC 4991717. PMID 27540072.
- ^ "Genomatix". Genomatix Software Suite v3.10. 2019-05-05.
- ^ "EST Profile - Hs.517612 - C22orf23". NCBI - Unigene. 2019-05-05.[dead link]
- ^ "C22orf23 chromosome 22 open reading frame 23 [ Homo sapiens (human) ]". NCBI - Gene. 2019-05-05.
- ^ "C22orf23". The Human Protein Atlas. 2019-05-05.
- ^ "RGD1359634 similar to RIKEN cDNA 1700088E04 [ Rattus norvegicus (Norway rat) ]". NCBI - Gene. 2019-05-05.
- ^ "1700088E04Rik RIKEN cDNA 1700088E04 gene [ Mus musculus (house mouse) ]". NCBI - Gene. 2019-05-05.
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- ^ Gao HJ, Chen YJ, Zuo D, Xiao MM, Li Y, Guo H, Zhang N, Chen RB (September 2015). "Quantitative proteomic analysis for high-throughput screening of differential glycoproteins in hepatocellular carcinoma serum". Cancer Biology & Medicine. 12 (3): 246–54. doi:10.7497/j.issn.2095-3941.2015.0010. PMC 4607824. PMID 26487969.
- ^ Wenzhi H, Ruijin W, Jieliang L, Xiaoyan M, Haibo L, Xiaoman W, Jiajia X, Shaoying L, Shuanglin L, Qing L (October 2015). "Heterozygous deletion at the SOX10 gene locus in two patients from a Chinese family with Waardenburg syndrome type II". International Journal of Pediatric Otorhinolaryngology. 79 (10): 1718–21. doi:10.1016/j.ijporl.2015.07.034. PMID 26296878.
- ^ Bondurand N, Dastot-Le Moal F, Stanchina L, Collot N, Baral V, Marlin S, Attie-Bitach T, Giurgea I, Skopinski L, Reardon W, Toutain A, Sarda P, Echaieb A, Lackmy-Port-Lis M, Touraine R, Amiel J, Goossens M, Pingault V (December 2007). "Deletions at the SOX10 gene locus cause Waardenburg syndrome types 2 and 4". American Journal of Human Genetics. 81 (6): 1169–85. doi:10.1086/522090. PMC 2276340. PMID 17999358.
- ^ Pascal, Gellert (December 2014). "Abstract S1-04: Exome sequencing of post-menopausal ER+ breast cancer (BC) treated pre-surgically with aromatase inhibitors (AIs) in the POETIC trial (CRUK/07/015". Cancer Research. 75 (9 Supplement): S1-04. doi:10.1158/1538-7445.SABCS14-S1-04.
- ^ Sharma P, Garg G, Kumar A, Mohammad F, Kumar SR, Tanwar VS, Sati S, Sharma A, Karthikeyan G, Brahmachari V, Sengupta S (May 2014). "Genome wide DNA methylation profiling for epigenetic alteration in coronary artery disease patients". Gene. 541 (1): 31–40. doi:10.1016/j.gene.2014.02.034. PMID 24582973.
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- ^ Ahn WS, Kim KW, Bae SM, Yoon JH, Lee JM, Namkoong SE, Kim JH, Kim CK, Lee YJ, Kim YW (December 2003). "Targeted cellular process profiling approach for uterine leiomyoma using cDNA microarray, proteomics and gene ontology analysis". International Journal of Experimental Pathology. 84 (6): 267–79. doi:10.1111/j.0959-9673.2003.00362.x. PMC 2517572. PMID 14748746.
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