C1orf185
C1orf185 | |||||||||||||||||||||||||||||||||||||||||||||||||||
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Identifiers | |||||||||||||||||||||||||||||||||||||||||||||||||||
Aliases | C1orf185, chromosome 1 open reading frame 185 | ||||||||||||||||||||||||||||||||||||||||||||||||||
External IDs | MGI: 1914896; HomoloGene: 49856; GeneCards: C1orf185; OMA:C1orf185 - orthologs | ||||||||||||||||||||||||||||||||||||||||||||||||||
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Chromosome 1 open reading frame 185, also known as C1orf185, is a protein that in humans is encoded by the C1orf185 gene. In humans, C1orf185 is a lowly expressed protein that has been found to be occasionally expressed in the circulatory system.[5][6]
Gene
[edit]C1orf185 is located on chromosome 1 in humans on the positive strand between bases 51,102,221 and 51,148,086.[7] There are 5 exons in the main splice isoform, however the number and selection of exons varies based on the isoform[7]
mRNA and Protein Isoforms
[edit]C1orf185 has 5 different splice isoforms in humans.[7]
Isoform | mRNA Accession | Protein Accession | Transcript Length (bp) | Protein Length (AA) |
---|---|---|---|---|
uncharacterized protein C1orf185 | NM_001136508.2 | NP_001129980.1 | 921 | 199 |
uncharacterized protein C1orf185 isoform X1 | XM_011541282.2 | XP_011539584.1 | 787 | 195 |
uncharacterized protein C1orf185 isoform X2 | XM_024446525.1 | XP_024302293.1 | 586 | 116 |
uncharacterized protein C1orf185 isoform X3 | XM_024446528.1 | XP_024302296.1 | 420 | 116 |
uncharacterized protein C1orf185 isoform X4 | XM_024446529.1 | XP_024302297.1 | 367 | 107 |
Protein
[edit]C1orf185 is a member of the pfam15842 protein family, containing a domain of unknown function, DUF4718.[10] This family of proteins is between 130 and 224 amino acids long, and is found only in eukaryotes..
The main splice isoform of C1orf185 has a molecular weight of 22.4 kDa[11] and an isoelectric point of 7.67.[12] It contains a transmembrane domain spanning from positions 15 to 37.[7] There is also a conserved serine-rich region from S123 to S142, which could possibly indicate function as a "splicing activator".[13]
C1orf185 contains 3 primary subcellular domains: an extracellular domain which spans the amino acids from positions 1 to 14, a transmembrane domain from positions 15–37, and a large intracellular domain from positions 38–199.[14]
Below are predicted secondary and tertiary structures of C1orf185, modeled using the Chou-Fasman[15] secondary structure prediction tool and the I-TASSER[16] protein structure and function prediction tool. Chou-Fasman predicts a mixture of α-helices, β-sheets, and other structural turns and coils, which can be seen modeled on the I-TASSER prediction.
Regulation of Expression
[edit]Gene Level Regulation
[edit]Below is a diagram showing the locations of predicted transcription factor binding sites in the C1orf185 promoter, along with a table describing the attributes of each individual binding site. The transcription factors were found and analyzed using the ElDorado tool from Genomatix.[17]
Transcription Factor | Detailed matrix info | Matrix similarity | Sequence | +/- |
VTATA.02 | Mammalian C-type LTR TATA box | 0.91 | tgtcaTAAAaacattcc | + |
NKX25.05 | Homeodomain factor Nkx-2.5/Csx | 0.986 | tttttTGAGtgaagtcttg | - |
CDX1.01 | Intestine specific homeodomain factor CDX-1 | 0.988 | ttgccctTTTAtgaaaaaa | + |
VTATA.02 | Mammalian C-type LTR TATA box | 0.914 | tacttTAAAaataagca | - |
ERG.02 | v-ets erythroblastosis virus E26 oncogene homolog | 0.942 | gtctcaaaGGAAaataaaaag | - |
SPI1.02 | SPI-1 proto-oncogene; hematopoietic transcription factor PU.1 | 0.992 | attaaagaGGAAgtctcaaag | - |
FHXB.01 | Fork head homologous X binds DNA with a dual sequence specificity (FHXA and FHXB) | 0.831 | ttctaaATAAcacattt | - |
TGIF.01 | TG-interacting factor belonging to TALE class of homeodomain factors | 1 | tctataaatGTCAatta | + |
ZNF219.01 | Kruppel-like zinc finger protein 219 | 0.913 | ctccaCCCCcgtcagcccaaagg | + |
ZBP89.01 | Zinc finger transcription factor ZBP-89 | 0.956 | catctccaCCCCcgtcagcccaa | + |
CREB.02 | cAMP-responsive element binding protein | 0.922 | cctttgggcTGACgggggtgg | - |
FOXP1_ES.01 | Alternative splicing variant of FOXP1, activated in ESCs | 1 | tcataaaAACAttccag | - |
VTATA.02 | Mammalian C-type LTR TATA box | 0.895 | tgtcaTAAAaacattcc | - |
CREB1.02 | cAMP-responsive element binding protein 1 | 0.949 | tggaaGTGAtgtcataaaaac | - |
SPI1.02 | SPI-1 proto-oncogene; hematopoietic transcription factor PU.1 | 0.979 | atttgagtGGAAgtgatgtca | - |
NKX25.05 | Homeodomain factor Nkx-2.5/Csx | 0.994 | gaattTGAGtggaagtgat | - |
MESP1_2.01 | Mesoderm posterior 1 and 2 | 0.917 | cagtCATAtggct | + |
MESP1_2.01 | Mesoderm posterior 1 and 2 | 0.929 | aagcCATAtgact | - |
DELTAEF1.01 | deltaEF1 | 0.99 | gcttcACCTaaag | + |
ERG.02 | v-ets erythroblastosis virus E26 oncogene homolog | 0.93 | gaagaagaGGAAaatatattt | + |
Matrix similarity correlates to the confidence in the prediction for each individual binding sites. +/- correlates to presence on either the positive or negative strand. The transcription factors are listed in order of appearance from beginning to end of the promoter.
C1orf185 has a very low expression pattern, with the only site in the body showing any signs of expression being the circulatory system. Two NCBI GEO profiles have shown that C1orf185 was consistently overexpressed in whole blood samples within a group of postmenopausal women,[18] as well as being somewhat overexpressed in the peripheral blood of Parkinson's patients compared to controls.[19]
Transcript Level Regulation
[edit]Below is a figure produced by mfold[20] showing predicted mRNA structure of the 3' UTR of C1orf185.
C1orf185 has one conserved miRNA binding site of type 7mer-A1 among several orthologs.[21] The presence of a 7mer-A1 binding site indicates that C1orf185 is likely to be post-transcriptionally repressed.[22]
Protein Level Regulation
[edit]Below is a figure and table showing predicted post-translational modification sites for C1orf185.
Type of Modification | Tool | Positions in Homo sapiens |
---|---|---|
Phosphorylation | NetPhos[23] | S61, S69, S104, S130, S142, S147, S165, S186 |
Glycation | NetGlycate,[24] NetNGlyc[25] | K5, K50, K98, K113 |
O-GlcNAc | YinOYang[26] | T121, S122, S130 |
The presence of multiple leucine glycation sites indicate that there may be ways to deter the function of the protein, as glycation has been associated with the loss of protein function in blood vessels[27]
Clinical Significance
[edit]C1orf185 has been shown to play a role in the circulatory system, likely in a more reactive role, as it is lowly expressed across many species. It appears in studies surrounding atrial fibrillation[6] and abnormal QRS duration,[5] which implies it may play a role in those circulatory diseases.
Homology
[edit]Below is a table showing C1orf185 orthologs across a variety of conserved species. Orthologs were found using NCBI BLAST,[28] the dates of divergence were found using TimeTree,[29] and the global sequence identities and similarities were found using the Clustal Omega multiple sequence alignment tool.[30]
Genus and Species | Common Name | Taxonomic Group | Date of Divergence (MYA) | Accession Number | Sequence Length (aa) | Sequence Identity (Global) | Sequence Similarity (Global) |
---|---|---|---|---|---|---|---|
Homo sapiens | Human | Primates | 0 | NP_001129980.1 | 199 | 100% | 100% |
Pongo abelii | Sumatran orangutan | Primates | 15.76 | PNJ53823.1 | 195 | 93.50% | 95.50% |
Cebus capucinus imitator | Capuchin | Primates | 43.2 | XP_017404303.1 | 229 | 77.00% | 79.60% |
Galeopterus variegatus | Sunda flying lemur | Dermoptera | 76 | XP_008578352.1 | 203 | 73.70% | 77.90% |
Oryctolagus cuniculus | Rabbit | Lagomorpha | 90 | XP_008263491.1 | 225 | 69.90% | 76.40% |
Dipodomys ordii | Ord's kangaroo rat | Rodentia | 90 | XP_012877642.1 | 188 | 52.20% | 59.40% |
Mastomys coucha | Southern multimammate mouse | Rodentia | 90 | XP_031234037 | 263 | 51.50% | 61.50% |
Mus musculus | House mouse | Rodentia | 90 | NP_001186019.1 | 226 | 47.40% | 59.50% |
Peromyscus leucopus | White-footed mouse | Rodentia | 90 | XP_028745885.1 | 295 | 41% | 48.20% |
Phyllostomus discolor | Pale spear-nosed bat | Chiroptera | 96 | XP_028367083.1 | 191 | 73.40% | 80.40% |
Myotis davidii | David's myotis | Chiroptera | 96 | XP_006768446.1 | 196 | 71.40% | 78.40% |
Equus caballus | Horse | Perissodactyla | 96 | XP_023485921.1 | 243 | 63.80% | 68.30% |
Muntiacus muntjak | Indian muntjac | Artiodactyla | 96 | KAB0362285.1 | 200 | 59.40% | 65.90% |
Hipposideros armiger | Great roundleaf bat | Chiroptera | 96 | XP_019487867.1 | 157 | 54.90% | 59.20% |
Tursiops truncatus | Bottlenose dolphin | Artiodactyla | 96 | XP_033708766.1 | 189 | 54.10% | 59.00% |
Sarcophilus harrisii | Tasmanian devil | Dasyuromorhpia | 159 | XP_031825005.1 | 333 | 18.20% | 27.70% |
Ornithorhynchus anatinus | Platypus | Monotremata | 180 | XP_028902271 | 309 | 26.80% | 37.40% |
Pelodiscus sinensis | Chinese softshell turtle | Reptilia | 312 | XP_025042106.1 | 890 | 7.40% | 11.40% |
Gopherus evgoodei | Sinaloan thornscrub tortoise | Reptilia | 312 | XP_030429802.1 | 777 | 4.00% | 6.30% |
Chrysemys picta bellii | Western painted turtle | Reptilia | 312 | XP_023960730.1 | 748 | 3.70% | 5.80% |
Compared to other genes, C1orf185 appears to be evolving and changing relatively quickly, as it is only conserved in mammals and a few turtles, and more distant mammals have quite distant similarities. Primates are the only taxonomic group that heavily conserves this gene with regards to the human sequence, while other mammals and turtles only heavily conserve the transmembrane domain (positions 15–37). As primates and mammals are warm-blooded, this may further support the evidence showing a possible role in the circulatory system.
References
[edit]- ^ a b c GRCh38: Ensembl release 89: ENSG00000204006 – Ensembl, May 2017
- ^ a b c GRCm38: Ensembl release 89: ENSMUSG00000060491 – 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.
- ^ a b Sotoodehnia N, Isaacs A, de Bakker PI, Dörr M, Newton-Cheh C, Nolte IM, et al. (December 2010). "Common variants in 22 loci are associated with QRS duration and cardiac ventricular conduction". Nature Genetics. 42 (12): 1068–76. doi:10.1038/ng.716. PMC 3338195. PMID 21076409.
- ^ a b Roselli C, Chaffin MD, Weng LC, Aeschbacher S, Ahlberg G, Albert CM, et al. (June 2018). "Multi-ethnic genome-wide association study for atrial fibrillation". Nature Genetics. 50 (9): 1225–1233. doi:10.1038/s41588-018-0133-9. PMC 6136836. PMID 29892015.
- ^ a b c d "C1orf185 chromosome 1 open reading frame 185 [Homo sapiens (human)] - Gene - NCBI". www.ncbi.nlm.nih.gov. Retrieved 2020-05-01.
- ^ "Genome Data Viewer". www.ncbi.nlm.nih.gov. Retrieved 2020-05-01.
- ^ "Home | Integrative Genomics Viewer". software.broadinstitute.org. Retrieved 2020-05-01.
- ^ "CDD Conserved Protein Domain Family: DUF4718". www.ncbi.nlm.nih.gov. Retrieved 2020-05-01.
- ^ "SAPS < Sequence Statistics < EMBL-EBI". www.ebi.ac.uk. Retrieved 2020-05-01.
- ^ "ExPASy - Compute pI/Mw tool". web.expasy.org. Retrieved 2020-05-01.
- ^ Graveley BR, Maniatis T (April 1998). "Arginine/serine-rich domains of SR proteins can function as activators of pre-mRNA splicing". Molecular Cell. 1 (5): 765–71. doi:10.1016/s1097-2765(00)80076-3. PMID 9660960.
- ^ "TMHMM Server, v. 2.0". www.cbs.dtu.dk. Retrieved 2020-05-01.
- ^ a b "CFSSP: Chou & Fasman Secondary Structure Prediction Server". www.biogem.org. Retrieved 2020-05-01.
- ^ a b "I-TASSER server for protein structure and function prediction". zhanglab.ccmb.med.umich.edu. Retrieved 2020-05-01.
- ^ "Genomatix - NGS Data Analysis & Personalized Medicine". www.genomatix.de. Retrieved 2020-05-01.
- ^ "13889230 - GEO Profiles - NCBI". www.ncbi.nlm.nih.gov. Retrieved 2020-05-01.
- ^ "129780050 - GEO Profiles - NCBI". www.ncbi.nlm.nih.gov. Retrieved 2020-05-01.
- ^ a b "The Mfold Web Server | mfold.rit.albany.edu". unafold.rna.albany.edu. Retrieved 2020-05-01.
- ^ a b "TargetScanHuman 7.2". www.targetscan.org. Retrieved 2020-05-01.
- ^ Grimson A, Farh KK, Johnston WK, Garrett-Engele P, Lim LP, Bartel DP (July 2007). "MicroRNA targeting specificity in mammals: determinants beyond seed pairing". Molecular Cell. 27 (1): 91–105. doi:10.1016/j.molcel.2007.06.017. PMC 3800283. PMID 17612493.
- ^ "NetPhos 3.1 Server". www.cbs.dtu.dk. Retrieved 2020-05-01.
- ^ "NetGlycate 1.0 Server". www.cbs.dtu.dk. Retrieved 2020-05-01.
- ^ "NetNGlyc 1.0 Server". www.cbs.dtu.dk. Retrieved 2020-05-01.
- ^ "YinOYang 1.2 Server". www.cbs.dtu.dk. Retrieved 2020-05-01.
- ^ Kim CS, Park S, Kim J (September 2017). "The role of glycation in the pathogenesis of aging and its prevention through herbal products and physical exercise". Journal of Exercise Nutrition & Biochemistry. 21 (3): 55–61. doi:10.20463/jenb.2017.0027. PMC 5643203. PMID 29036767.
- ^ "BLAST: Basic Local Alignment Search Tool". blast.ncbi.nlm.nih.gov. Retrieved 2020-05-01.
- ^ "TimeTree :: The Timescale of Life". www.timetree.org. Retrieved 2020-05-01.
- ^ "Clustal Omega < Multiple Sequence Alignment < EMBL-EBI". www.ebi.ac.uk. Retrieved 2020-05-01.