Phenotypes

See also: 'OMIA:001009-9915 : Hemimelia, tibial in Bos indicus'

Jacinto et al. (2023): "A trio whole-genome sequencing approach [of an affected 5 month old Wagyu calf and its parents] identified a deleterious homozygous missense variant in DGKG (p.Thr721Ile). The allele frequency in 209 genotyped Wagyu was 7.2%."

By cloning and sequencing a very likely comparative candidate gene (based on the homologous disorder in humans and mice), Pierce et al. (2001) identified a causal mutation as a "a cytidine to adenine transversion at position 156 of the Glra1 gene (156C>A). The 156A allele is predicted to substitute a termination codon for a tyrosine codon (Y24*) in exon 2 . . . This substitution is predicted to result in a prematurely truncated protein that...

Because of the obvious homology of this disorder with the homologous human disorder, Drögemüller et al. (2001) proposed that the bovine disorder be called by the name of its human homologue, which is now done in this catalogue. The earlier names are listed here as species-specific names [Frank Nicholas 20 June 2002].

By comparing whole-genome sequenced data (from 2 affecteds and one control) in the candidate region (see Mapping section), and filtering resultant candidate variants, Duchesne et al. (2018) narrowed the field down to "a single substitution in exon 5 of KIF1C (chr19:27041449 C/T). For easier comprehension and since KIF1C gene in cattle is on the reverse strand, the substitution will be referred as KIF1C G>A in order to match with the transcr...

In a conference abstract, Marron and Beever (2012) reported the causal mutation of hypotrichosis in Belted Galloway cattle to be "an A1684T substitution in exon 9 of hephaestin-like 1 (HEPHL1) resulting in a premature stop codon (K562X)". They further noted that "Hephaestin-like 1 is responsible for copper ion transport. Copper deficiency has been shown to cause anemia, poor immune function, slower growth rates and discolored or poor hair coat...

Jacinto et al. (2021): "Protein-coding exons of six positional candidate genes with known hair or hair follicle function were re-sequenced. This revealed a protein-changing variant in the KRT71 gene that encodes a type II keratin specifically expressed in the IRS of the hair follicle (c.281delTGTGCCCA; p.Met94AsnfsX14)." This variant was previously reported by Markey et al. (2010).

In the words of Charlier et al. (2008): "a missense mutation in exon 39 (A5804G) resulting in an H1935R substitution in the fourth extracellular loop". The His (normal) form of the peptide is conserved in all vertebrates sequenced to date. (FN 080330) Whole-genome sequencing of the affected Shorthorn calf described by O'Rourke et al. (2017), and subsequent checking for deleterious variants in functional candidate genes, enabled Woolley et al. ...

Häfliger et al. (2022) report a Scottish Highland calf with "combined lesions compatible with congenital ichthyosis, alopecia, acantholysis of the tongue and corneal defects associated with a DSP missense variant as the most likely underlying cause."

Häfliger et al. (2020): "Variant calling and filtering against the 1000 Bull Genomes variant catalogue resulted in the detection of a single homozygous protein-changing variant exclusively present in both sequenced genomes. This single-nucleotide deletion in exon 3 of IL17RA on bovine chromosome 5 was predicted to have a deleterious impact on the encoded protein due to a frameshift leading to a truncated gene product."

Illustrating the enormous power of genomic tools, Wiedemar et al. (2015) were able to identify a likely causal mutation for a previously unrecorded disease phenotype in just a single calf.

Shan et al. (2020) reported "a Holstein sire named Tarantino who had been approved for artificial insemination that is based on normal semen characteristics (i.e., morphology, thermoresistance, motility, sperm concentration), but had no progeny after 412 first inseminations".

Using targeted DNA capture and massively parallel resequencing of the 1.2 Mb region that contained 24 genes, Testoni et al. (2012) identified a causal mutation as a "KDM2B missense mutation (c.2503G>A) leading to an amino acid exchange (p.D835N) in an evolutionary strongly conserved domain". As the same authors report, "The KDM2B gene (also known as JHDM1B and FBXL10) encodes a histone H3 lysine 36 dimethyl (H3K36me2)-specific demethylase ....

Bourneuf et al. (2017) detected COL6A3 g.117453719G>A; p.T1894M; omia.variant:1184 as a de novo recessive potentially lethal mutation from an analysis of whole-genome-sequence of a Holstein AI bull. No information was provided on the descendants of this bull.

By cloning and sequencing a very likely comparative candidate gene (based on the same disorder in humans), Shuster et al. (1992; PNAS) showed that this disorder in Holstein cattle is due to a missense mutation (c.383A>G) in the CD18 gene, now known as ITGB2. This mutation was confirmed in Daetwyler et al. (2014)'s analysis of whole-genome sequence data from 234 cattle, including key ancestors of the Holstein-Friesian, Fleckvieh and Jersey b...