C9orf135

C9orf135 is a gene that encodes a 229 amino acid protein. It is located on Chromosome 9 of the Homo sapiens genome at 9q12.21.[5] The protein has a transmembrane domain from amino acids 124-140 and a glycosylation site at amino acid 75. C9orf135 is part of the GRCh37 gene on Chromosome 9 and is contained within the domain of unknown function superfamily 4572.[6] Also, c9orf135 is known by the name of LOC138255 which is a description of the gene location on Chromosome 9.1.[7]

c9orf135 location on chromosome 9 and the neighboring genes.
C9orf135
Identifiers
AliasesC9orf135, chromosome 9 open reading frame 135
External IDsMGI: 1914733 HomoloGene: 49850 GeneCards: C9orf135
Gene location (Human)
Chr.Chromosome 9 (human)[1]
Band9q21.12Start69,820,817 bp[1]
End69,906,227 bp[1]
Orthologs
SpeciesHumanMouse
Entrez

138255

67483

Ensembl

ENSG00000204711

ENSMUSG00000033053

UniProt

Q5VTT2

Q9CQC3

RefSeq (mRNA)

NM_001010940
NM_001308084
NM_001308085
NM_001308086

NM_026188

RefSeq (protein)

NP_001010940
NP_001295013
NP_001295014
NP_001295015

NP_080464

Location (UCSC)Chr 9: 69.82 – 69.91 MbChr 19: 23.56 – 23.65 Mb
PubMed search[3][4]
Wikidata
View/Edit HumanView/Edit Mouse

There is some evidence associating the c9orf135 gene with premature ovarian failure.[8] In affected women, an autosomal recessive microduplication occurs which may be linked to premature ovarian failure. A Single Nucleotide Polymorphism (SNP) the c9orf135 gene has been linked to Parkinson’s disease; a statistically significant mutation has been seen on a Manhattan plot.[9] Further research is required to establish whether c9orf135 relates to Parkinson’s disease.[9]

mRNA

Splice Variants of c9orf135 based on NCBI AceView

The mRNA of c9orf135 is 906 nucleotides in length.[10] The 5' and 3' Untranslated regions (UTR) contain hairpin loops[11]. The 3' UTR comprises 123 nucleotides and the 5' UTR comprises 18 nucleotides. The mRNA encodes a protein with a secondary structure composed of both beta-sheets and alpha-helices.[12]

Protein

Properties of c9orf135

It is likely that c9orf135 is a nuclear protein because it has properties that match attributes of nuclear proteins rather than secretory pathways.[13][14] Furthermore, there is a nuclear localization signal (PEKVKKL) from amino acid 67 to 73 on c9orf135.[15] C9orf135 is soluble with an average hydrophobicity of -0.772. The negative hydrophobicity value is due to its slightly acidic properties.[16]

Post-translational modifications

Serine phosphorylation sites were seen at amino acid positions 7, 50, 86, 98, and 194. Threonine phosphorylation occurs at 34, 129, 155, and 201. Tyrosine phosphorylation sites occur at 78, 160, 177, and 209. Also, a N-terminal acetylation site is present at amino acid 3. A Signal cleavage site is present between amino acids 11 and 12.[17]

Protein Interaction

PB2 interacts with c9orf135 which was found from a two-hybrid yeast assay. The information provided about PB2 (Polymerase Basic Protein 2) is that it is a viral protein that is involved with the influenza A virus. It is primarily involved in Cap stealing in which it binds the pre-mRNA cap an ultimately cleaves 10-13 nucleotides off. PB2 is also important for starting the replication of viral genomes. PB2 is also known to inhibit type 1 interferon by inhibiting the mitochondrial antiviral signalling protein MAVS.[18]

Mutations

Eleven different common DNA genome variants of the human c9orf135 gene have been identified. All of the mutations within those genome variants have been compiled into the following table.[19] Mutations that were present at levels of 0.01 frequency or higher have been incorporated into the table; synonymous mutations were excluded.

LocationAmino Acid PositionMutationFrequency
5' UTR57N/A0.386
5' UTR93N/A0.047
5' UTR138N/A0.018
Exon169Missense K30T0.018
Exon237Missense R53K0.047
Exon456Missense E126K0.01

Gene Expression

c9orf135 is expressed in connective tissue and testicular tissue at high levels.[20] It is likely that the expression of c9orf135 is expressed at low levels throughout human cells. It was also found that c9orf135 is found at significantly higher levels in the adult human umbilical cord versus the foetal human umbilical cord.[21] Furthermore, in women with ovarian adenocarcinoma the expression of c9orf135 is much higher in the epithelial cells within the ovaries.[22] Women with polycystic ovarian syndrome have a lower expression of c9orf135 than those people who do not have the condition.[23]

Amino Acid Quantity

A comparison between the c9orf135 from Mus musculus (House Mouse) and Pteropus alecto (Black Flying Fox) is described here. There were no significant amino acids that differed in c9orf135 from the rest of the mouse body. However, in the Black Flying Fox, it was valine poor and tryptophan rich. As seen from the human results, the Black Flying fox only shared the tryptophan surplus results. The House Mouse and Black Flying Fox were both used because they shared 64% and 79% similarity in the c9orf135 genome respectively. Analysis demonstrates that alanine and tyrosine could predict points of interest because they both contained results differing from the rest of the human gene averages.[16]

Amino Acid of InterestCompositional Percentage

Compared to normal protein amounts in H. sapiens

Alanine3.1%Less than Average
Tyrosine5.2%More than Average
Trytophan3.1%More than average

Homology

c9orf135 is conserved through eukaryotes, ranging from mammals, reptiles and Annelida.

Orthologs

The orthologs of c9orf135 were sequenced in BLAST and 20 orthologs were picked. The orthologs were all multicellular organisms and were limited to aquatic animals, reptiles, amphibians, and warm-blooded animals. Also, protists, bacteria, archea, and fungi did not have orthologs. However, no paralogs were found when c9orf135 was sequenced in BLAST. Please refer to the spreadsheet for the complete list of orthologs to c9orf135. Time tree was a program that was used to find the evolutionary branching shown in MYA[24] There were no paralogs found for c9orf135.

Genus/SpeciesCommon nameDivergence from Humans (MYA)Accession numberAmino Acid LengthSequence identitySequence similarity
Homo sapiensHuman--Q5VTT2229----
Pongo abeliiSumatran Orangutan15.8XP_00281990420686%87%
Rhinopithecus roxellanaGolden Snub-Nosed Monkey29.1XP_01036125022993%95%
Mus musculusHouse Mouse90.9EDL4160422864%73%
Pteropus alectoBlack Flying Fox97.5XP_78596423079%86%
Equus przewalskiiPrzewalski's horse97.5XP_00850480618377%86%
Panthera tigris altaicaSiberian Tiger97.5XP_00707753718773%83%
Ovis ariesSheep97.5XP_01494867020769%77%
Elephantulus edwardiiCape Elephant Shrew105XP_00689448525472%82%
Pelodiscus sinensisChinese Softshell Turtle320.5XP_00613790221755%68%
Gekko japonicusGekko320.5XP_01527599922152%64%
Alligator mississippiensisAmerican Alligator320.5XP_01446414421251%64%
Ophiophagus hannahKing Cobra320.5ETE6172021543%59%
Salmo SalarAtlantic Salmon429.6XP_0139988409934%55%
Esox luciusNorthern Pike429.6XP_01090169115430%47%
Branchiostoma floridaeLancelet733XP_00259178622145%59%
Strongylocentrotus purpuratusSea Urchin747.8XP_78596424147%62%
Saccoglossus kowalevskiiAcorn Worm747.8XP_00273341015338%58%
Lingula anatinaOcean Clam847XP_01339860522043%59%
Crassostrea gigasPacific Oyster847XP_01142694421540%57%
Helobdella robustaLeech847XP_00901986125629%44%

Divergence of c9orf135

A divergence comparison of c9orf135 with fast diverging cytochrome C, and slow diverging fibrinogen is shown in the chart. Overall, c9orf135 has diverged significantly quicker than fibrinogen and slightly slower than cytochrome C.

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References

  1. GRCh38: Ensembl release 89: ENSG00000204711 - Ensembl, May 2017
  2. GRCm38: Ensembl release 89: ENSMUSG00000033053 - Ensembl, May 2017
  3. "Human PubMed Reference:". National Center for Biotechnology Information, U.S. National Library of Medicine.
  4. "Mouse PubMed Reference:". National Center for Biotechnology Information, U.S. National Library of Medicine.
  5. NCBI, Protein, https://www.ncbi.nlm.nih.gov/protein/Q5VTT2.1
  6. BLAST protein sequence, c9orf135, http://blast.ncbi.nlm.nih.gov/Blast.cgi
  7. Result Filters. (n.d.). Retrieved February 07, 2016, from https://www.ncbi.nlm.nih.gov/protein/Q5VTT2.1
  8. Genomic analysis using high-resolution single-nucleotide polymorphism arrays reveals novel microdeletions associated with premature ovarian failure. McGuire, Megan M; Bowden, Wayne; Engel, Natalie J; Ahn, Hyo Won; Kovanci, Ertug et al.(2011) Fertility and sterility vol.95(5)p.1595-600
  9. Genomic determinants of motor and cognitive outcomes in Parkinson's disease. Chung, Sun Ju; Armasu, Sebastian M; Biernacka, Joanna M; Anderson, Kari J; Lesnick, Timothy G et al.(2012)Parkinsonism & related disorders vol. 18(7)p.881-6
  10. NCBI, Nucleotide, https://www.ncbi.nlm.nih.gov/nuccore/809279636?report=fasta
  11. Sfold, Srna, http://sfold.wadsworth.org/cgi-bin/showcentroid.pl
  12. I-Tasser, http://zhanglab.ccmb.med.umich.edu/I-TASSER/
  13. YLoc http://abi.inf.uni-tuebingen.de/Services/YLoc/webloc.cgi?id=86ac5008fd25bd20a065f49a970fd19c
  14. SOSUI Classification and Secondary Structure Prediction of Membrane Proteins, http://harrier.nagahama-i-bio.ac.jp/sosui/
  15. PSORT II, PSORT II Prediction, http://psort.hgc.jp/cgi-bin/runpsort.pl%5B%5D
  16. SDSC Biology Workbench, SAPS, http://seqtool.sdsc.edu/CGI/BW.cgi#%5B%5D!
  17. ExPasy, Sibs bioinformatics analysis, http://www.expasy.org/
  18. "1 binary interaction found for search term C9orf135". IntAct Molecular Interaction Database. EMBL-EBI. Retrieved 2018-08-25.
  19. NCBI SNP Geneview https://www.ncbi.nlm.nih.gov/SNP/snp_ref.cgi?geneId=138255&ctg=NT_008470.20&mrna=XM_011518232.1&prot=XP_011516534.1&orien=forward
  20. EST profile, NCBI, https://www.ncbi.nlm.nih.gov/nuccore/NM_001308086.1
  21. Geo Profile, NCBI https://www.ncbi.nlm.nih.gov/geoprofiles/78193260
  22. Geo Profile, Ovarian normal surface epithelia and the ovarian cancer epithelial cells, https://www.ncbi.nlm.nih.gov/geo/tools/profileGraph.cgi?ID=GDS3592:236519_at
  23. Geo Profile, Obese women with polycystic ovary syndrome and obese, healthy women: skeletal muscle, https://www.ncbi.nlm.nih.gov/geo/tools/profileGraph.cgi?ID=GDS4133:243610_at
  24. Hedges SB, Marin J, Suleski M, Paymer M & Kumar S (2015) Tree of Life Reveals Clock-Like Speciation and Diversification. Mol Biol Evol 32: 835-845

Further reading

Chromosome 9

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