Russell G. Snell scite author profile

Recently, DGAT1 was identified as the gene that underlies the QTL for bovine milk production on chromosome 14. This study investigated the effect of the reported polymorphism in three dairy breeds in New Zealand. Statistically significant results were identified for milk fat, milk protein, and volume for Jersey and Holstein-Friesian breeds, and only milk volume for Ayrshires. The average allele substitution effects were 2 to 3 kg of protein and 120 to 130 l milk for both the Jersey and Holstein-Friesian breeds. For milk fat, the average allele substitution effect was 6 kg for Holstein-Friesians and 3 kg for Jerseys. In all breeds, where the polymorphism increased milk fat yield, it decreased milk protein yield and milk volume.

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DNA and RNA-sequence based GWAS highlights membrane-transport genes as key modulators of milk lactose content

Lopdell

et al. 2017

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BackgroundLactose provides an easily-digested energy source for neonates, and is the primary carbohydrate in milk in most species. Bovine lactose is also a key component of many human food products. However, compared to analyses of other milk components, the genetic control of lactose has been little studied. Here we present the first GWAS focussed on analysis of milk lactose traits.ResultsUsing a discovery population of 12,000 taurine dairy cattle, we detail 27 QTL for lactose concentration and yield, and subsequently validate the effects of 26 of these loci in a distinct population of 18,000 cows. We next present data implicating causative genes and variants for these QTL. Fine mapping of these regions using imputed, whole genome sequence-resolution genotypes reveals protein-coding candidate causative variants affecting the ABCG2, DGAT1, STAT5B, KCNH4, NPFFR2 and RNF214 genes. Eleven of the remaining QTL appear to be driven by regulatory effects, suggested by the presence of co-locating, co-segregating eQTL discovered using mammary RNA sequence data from a population of 357 lactating cows. Pathway analysis of genes representing all lactose-associated loci shows significant enrichment of genes located in the endoplasmic reticulum, with functions related to ion channel activity mediated through the LRRC8C, P2RX4, KCNJ2 and ANKH genes. A number of the validated QTL are also found to be associated with additional milk volume, fat and protein phenotypes.ConclusionsOverall, these findings highlight novel candidate genes and variants involved in milk lactose regulation, whose impacts on membrane transport mechanisms reinforce the key osmo-regulatory roles of lactose in milk.Electronic supplementary materialThe online version of this article (doi:10.1186/s12864-017-4320-3) contains supplementary material, which is available to authorized users.

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Hyperekplexia associated with compound heterozygote mutations in the beta-subunit of the human inhibitory glycine receptor (GLRB)

Rees

Lewis²,

Kwok³

et al. 2002

177

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Hyperekplexia (MIM: 149400) is a neurological disorder characterized by an excessive startle response which can be caused by mutations in the alpha1-subunit (GLRA1) of the heteropentameric human inhibitory glycine receptor (hGlyR). These receptors facilitate fast-response, inhibitory glycinergic neurotransmission in the brainstem and spinal cord leading to a rapid modification and reduction of the excitatory startle response. Mutations in the beta-subunit of GlyR (glrb) occur in a murine model of hyperekplexia (spastic), but have not been detected in human hyperekplexia. Following mutation analysis of the human beta-subunit of hGlyR (GLRB) in a cohort of 22 hyperekplexia patients, we provide evidence to confirm that GLRB mutations can cause human hyperekplexia. A missense (G920A resulting in G229D) and a splice site mutation (IVS5+5G-->A) occurred together in a compound heterozygote with a transient hyperekplexia phenotype. Exon trap analysis revealed that IVS5+5G-->A results in the exclusion of exon 5 from GLRB transcripts. Electrophysiological studies showed reduced sensitivity to agonist mediated activation of the alpha1beta (G229D) GlyR suggesting that GlyR beta-subunits are not restricted to conferring modulatory influences and maintaining structural integrity, but may also play a functional role in hGlyR ligand binding.

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Brain urea increase is an early Huntington’s disease pathogenic event observed in a prodromal transgenic sheep model and HD cases

Handley

Reid

Bräuning

et al. 2017

Proc. Natl. Acad. Sci. U.S.A.

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The neurodegenerative disorder Huntington's disease (HD) is typically characterized by extensive loss of striatal neurons and the midlife onset of debilitating and progressive chorea, dementia, and psychological disturbance. HD is caused by a CAG repeat expansion in the Huntingtin (HTT) gene, translating to an elongated glutamine tract in the huntingtin protein. The pathogenic mechanism resulting in cell dysfunction and death beyond the causative mutation is not well defined. To further delineate the early molecular events in HD, we performed RNA-sequencing (RNA-seq) on striatal tissue from a cohort of 5-y-old OVT73-line sheep expressing a human CAG-expansion HTT cDNA transgene. Our HD OVT73 sheep are a prodromal model and exhibit minimal pathology and no detectable neuronal loss. We identified significantly increased levels of the urea transporter SLC14A1 in the OVT73 striatum, along with other important osmotic regulators. Further investigation revealed elevated levels of the metabolite urea in the OVT73 striatum and cerebellum, consistent with our recently published observation of increased urea in postmortem human brain from HD cases. Extending that finding, we demonstrate that postmortem human brain urea levels are elevated in a larger cohort of HD cases, including those with low-level neuropathology (Vonsattel grade 0/1). This elevation indicates increased protein catabolism, possibly as an alternate energy source given the generalized metabolic defect in HD. Increased urea and ammonia levels due to dysregulation of the urea cycle are known to cause neurologic impairment. Taken together, our findings indicate that aberrant urea metabolism could be the primary biochemical disruption initiating neuropathogenesis in HD.is a dominantly inherited neurological disorder typified by chorea, psychological disturbance, and dementia. The symptoms progress and result in premature death, typically 10-15 y after onset. Currently no available treatment can delay or prevent the onset of HD. The gene responsible, Huntingtin (HTT), is ubiquitously expressed and encodes the large and multifunctional huntingtin protein.The disease-causing mutation is an expanded CAG repeat in exon 1 of HTT, coding for a glutamine tract within the protein (1). The disease-causing repeat lower length threshold is 36 units and is fully penetrant at 40 units and above (2, 3). There is an inverse correlation between expanded CAG repeat size and age at onset of symptoms (4-6). Although the mutation is well defined, the pathogenic process is not sufficiently understood to enable effective treatment. The majority of HD research focuses on the brain where there is characteristic neuropathology, primarily atrophy of the striatum (7).Alongside the striking neurological phenotype of HD, there is a generalized metabolic disruption. HD mutation carriers weigh less on average than non-HD individuals (8). Weight loss begins presymptomatically (9, 10), and in symptomatic individuals, energy expenditure far exceeds that utilized in movement, despite high calor...

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Castration delays epigenetic aging and feminizes DNA methylation at androgen-regulated loci

Sugrue

Zoller

Narayan

et al. 2021

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In mammals, females generally live longer than males. Nevertheless, the mechanisms underpinning sex-dependent longevity are currently unclear. Epigenetic clocks are powerful biological biomarkers capable of precisely estimating chronological age and identifying novel factors influencing the aging rate using only DNA methylation data. In this study, we developed the first epigenetic clock for domesticated sheep (Ovis aries), which can predict chronological age with a median absolute error of 5.1 months. We have discovered that castrated male sheep have a decelerated aging rate compared to intact males, mediated at least in part by the removal of androgens. Furthermore, we identified several androgen-sensitive CpG dinucleotides that become progressively hypomethylated with age in intact males, but remain stable in castrated males and females. Comparable sex-specific methylation differences in MKLN1 also exist in bat skin and a range of mouse tissues that have high androgen receptor expression, indicating it may drive androgen-dependent hypomethylation in divergent mammalian species. In characterising these sites, we identify biologically plausible mechanisms explaining how androgens drive male-accelerated aging.

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Russell G. Snell

Characterization of the DGAT1 Gene in the New Zealand Dairy Population

DNA and RNA-sequence based GWAS highlights membrane-transport genes as key modulators of milk lactose content

Hyperekplexia associated with compound heterozygote mutations in the beta-subunit of the human inhibitory glycine receptor (GLRB)

Brain urea increase is an early Huntington’s disease pathogenic event observed in a prodromal transgenic sheep model and HD cases

Castration delays epigenetic aging and feminizes DNA methylation at androgen-regulated loci

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