WDR88


WDR88 is a protein, which in humans, is encoded by the gene WDR88. It consists of seven WD40 repeats, which form a seven-bladed beta-propeller. Mutations within the WDR88 gene are associated with a variety of cancers, as well as schizophrenia and fungal infections.
The protein structure of WDR88 is characterized by the presence of seven WD40 repeats, which are short structural motifs of approximately 40 amino acids that often terminate in a tryptophan-aspartic acid dipeptide. These repeats typically form a beta-propeller structure, suggesting a potential role in protein-protein interactions.

Transcripts

The gene WDR88 has 3 isoforms. The splice variants of the WDR88 transcript vary according to their first and last exon and their last two introns. This isoform has an mRNA sequence of 1702 nucleotides.
mRNA VariantGene LengthProtein Length5' UTR3' UTR
aAug10170247256227
bAug10183542678476
cAug10-unspliced561121-195

Tissue Expression

WDR88 RNA is expressed lowly and ubiquitously in most tissue types. It is expressed in slightly higher levels in the prostate, thyroid, thymus, and salivary gland. Its presence in these tissues may relate to associated diseases- WDR88 has been associated with prostate cancer, as well as an increased susceptibility of Candidiasis. Thymus cell dysfunction may also lead to cancer.
Other tissues with moderate expression include the heart, skeletal muscle, brain, kidney, lymph nodes, and ovaries.

Protein

The WDR88 protein is a nuclear protein. The protein is 472 amino acids long and has a calculated molecular weight of 53kDa. Its isoelectric point is approximately a pH of 7.0. In addition, there is an increased abundance of cysteine, aspartic acid, and serine residues. Its increased abundance of serine may contribute to its ability to be hyperphosphorylated. Human WDR88 displays a somewhat similar and isoelectric point to selected orthologs.
Species TypeCommon nameScientific nameMolecular Weight Isoelectric Point
MammalsHumanHomo sapiens537.0
MammalsKoalaPhascolarctos cinereus486.3
MammalsLarge flying fox batPteropus vampyrus556.7
MammalsSmall madagascar hedgehogEchinops telfairi548.9
MammalsAustralian echidnaTachyglossus aculeatus478.2
MammalsCattleBos taurus636.7
BirdsSouth African ostrichStruthio camelus australis447.2
BirdsBarn owlTyto alba445.9
BirdsEmperor penguinAptenodytes forsteri526.5
ReptilesChinese soft shelled turtlePelodiscus sinensis465.9
ReptilesAustralian saltwater crocodileCrocodylus porosus456.0
ReptilesKomodo DragonVaranus komodoensis446.1
ReptilesEuropean leaf toed geckoEuleptes europaea488.9
ReptilesTiger rattlesnakeCrotalus tigris445.7
AmphibiansCommon frogRana temporaria446.1
AmphibiansCommon toadBufo bufo446.9
AmphibiansTwo-lined caecilianRhinatrema bivittatum756.0
FishW. African LungfishProtopterus annectens445.6
FishThorny SkateAmblyraja radiata445.6
FishSea LampreyPetromyzon marinus479.0

Secondary Structure

The 5' untranslated region is 56 base pairs long, and the 3' untranslated region is 227 base pairs in length, spanning from base 1475 to 1702. The 5' UTR is predicted to have 1 stem loop, while the 3' UTR can have as many as 4 stem loops, although its most stable structure has 2 stem loops.

Tertiary Structure

The WDR88 protein has 7 WD40 repeats each of which form an antiparallel blade, all together forming a beta propeller. The presence of a 7-bladed beta propeller is generally conserved in orthologs from mammals to fish.

Transcript Level Regulation

Transcription Factors

Notable transcription factors include: Nr1h::Rxra, EBF1, and PLAG1. ZNFs and SOX transcription factors are common.
Nr1h3::Rxra play a role in lipid metabolism, inflammation, and cholesterol homeostasis. Dysregulation of these processes are implicated in prostate cancer progression. Decreased expression of this factor means pro-inflammatory gene expression can increase, leading to inflammation. This factor can also interfere with androgen receptor pathways, which may influence androgen-dependent prostate cancer cell growth.
EBF1 may contribute to the development of schizophrenia through its role in neurodevelopment and immune system function. Specifically, EBF1 can work with microRNAs to create regulatory loops to influence the onset and progression of schizophrenia.
PLAG1 is associated with pleomorphic adenomas of the salivary gland. Chromosomal translocations of the target sequence can over-activate PLAG1, leading to an overactivation of downstream factors/targets that are involved in cell proliferation, leading to cancerous growths. Cancer of the salivary gland can lead to dry mouth, which is a risk factor of Candidiasis and other oral fungal infections.

microRNA

microRNA binding sites are only found within the 3' untranslated region. Notably, the miRNA hsa-miR-191-5p is associated with various types of cancer due to its ability to act as an oncogene by promoting cell differentiation & migration

Binding Proteins

RNA binding protein binding regions are found within the 5' and 3' untranslated regions. Notable examples within the 5' region include ELF4B and RBMX proteins. RBMX specifically has the ability to repair DNA damage, and can suppress tumorigenicity/progression of bladder cancer. ELF4B is important in cell growth and differentiation, and dysregulation in this interaction could lead to cancer<.
The 3' UTR binding proteins include IGF2BP1, PTBP1, RBMX proteins, and KHSRP.
IGF2BP1 is known to regulate mRNA stability, splicing, and translation. In the context of cancer, IGF2BP1 may impact tumor progression and metastasis by stabilizing oncogenic mRNAs and promoting cell proliferation.
PTBP1 is known for its role in splicing regulation. It may also influence the stability and translation of cancer-related transcripts, potentially contributing to cancer development.
KHSRP is involved in the regulation of mRNA processing, including splicing and decay. It has been implicated in the regulation of various cancer-related genes and may play a role in cancer progression.

Protein Level Regulation

Post Translational Modifications

The WDR88 protein is predicted to be hyperphosphorylated, with an additional acetylation site and ubiquitination site. The presence of multiple phosphorylation sites is conserved among orthologs. The WDR88 protein may also have N- and O-glycosylation sites<
.

Subcellular Location

The WDR88 protein is primarily located within the nucleus, with its location being conserved in orthologs.

Evolution

Paralogs

WDR88 paralogs include WDR5, APAF1, WDR38, PAF1, and DAW1.

Orthologs

WDR88 in Homo sapiens is highly conserved. Its found in many vertebrate organisms, including other mammals, birds, reptiles, amphibians, and fish. It has not been identified in invertebrates. Table 2 shows a selection of orthologs in mammals, birds, reptiles, amphibians, and fish. Many conserved regions fell within the WD repeat domain, and most WD dipeptides were conserved among close and distant orthologs.

Phylogeny & History

The WDR88 gene is evolving relatively quickly compared to cytochrome c and DAW1, but slower than the rate of fibrinogen alpha.

Interacting Proteins

Human WDR88 protein has notable interactions with the following proteins which are all associated with cell cycle regulation: KIA1429, FOS family proteins, NUDC, and WDR31. These interactions implicate human WDR88 in cell regulation processes.
WDR88 is also associated with argG, metE, GATM, and TYR, which are in arginine, methionine, creatinine, and melanin synthesis.
WDR88 can also interact with proteins associated with the bacterium Yersinia pestis, which causes plague.

Clinical Significance

In uterine & endometrial carcinoma, the WDR88 gene may serve as a relevant biomarker, and could also be a potential therapeutic target. In prostate cancer, WDR88 can function as a marker for onset
There is a significant association between a WDR88 gene variant and increased susceptibility to Candidiasis, an oral fungal infection. A single nucleotide polymorphism at position 1328 changes from a cytosine to a thymine, causing an isoleucine to mutation to an alanine at position 424.
Exome array data showed 7 rare WDR88 variants contribute to the "genetic architecture of schizophrenia". 2 of these variants are predicted to be damaging or possibly damaging.
TypePositionBase ChangeAmino Acid ChangeAssociationsrsIDLabel
Missense103365A-->GH-->QSchizophreniaexm1453333VarA
Missense166496G-->AD-->N1483589630
Missense172514T-->CW-->R1973547431VarB
Missense173517G-->CD-->H2145383159
Missense195583T-->GS-->A964934511
Missense198593G-->AG-->D1973572567
Missense229687C-->A, 687C-->TH-->Q, =1390996134
Missense236707G-->AC-->Y1973627073VarC
Missense238712T-->CF-->L1315930267
Missense258772G-->CD-->V1350318862
Missense285854G-->AG-->D1973735806
Nonsense 293878G-->A, 879G-->AW-->Ter766698986, 1454699628VarD/E
Missense300898T-->CW-->R1973736716
Nonsense 300900G-->AW-->Ter1973736779VarF
Missense320958C-->G, 958C-->TH-->D, Y571091956
Missense322964G-->AG-->S938493076VarG
Missense327979T-->C, 979T-->GC-->R, G916309262
Missense332995A-->GD-->G1973739195
Missense3391016G-->AG-->R, E753069912, 138717522
Missense3421024G-->CD-->H1973845950
Missense3481043G-->TW-->L200178208
Missense3621085A-->GH-->R1213339071
Missense3681103A-->GD-->R1973916950VarH
Missense3721115G-->TS-->I11668547
Missense3781188C-->TI-->FSchizophreniaexm1453382VarI
Missense3831148A-->GK-->R768741120
Missense3861156A-->CT-->P751290834VarJ
Missense3901168T-->C, 1168T-->GW-->R, G1291251743
Missense4241328C>TI-->A, GCandidiasisrs10422015
Missense4371311C-->G, 1311C-->TC-->W, =760463708
Nonsense 4731417T-->C, GTer-->R, G760940871VarK
Nonsense 4731419A-->GTer -->W146733199VarL