Confirmation that a deletion in the POMC gene is associated with body weight of Labrador Retriever dogs.

A 14-bp deletion present in the proopiomelanocortin (POMC) gene of Labrador and Flat Coat Retrievers (FCR), but absent in POMC of other breeds, disrupts the ß-MSH and ß-endorphin coding sequences. This deletion was recently reported as strongly associated with increased body weight and obesity. We searched for this mutation in a cohort of 272 dogs, representing four breeds with a known predisposition to obesity (Labrador and Golden Retrievers, Beagle, and Cocker Spaniel) and, as expected, we found it only in Labradors. Further, we confirmed the association between the deletion variant and body weight of Labradors but not with a 5-point body condition score (BCS). We suspect that the deletion variant in our cohort may act as a recessive allele, unlike the previous study, which suggested its additive effect.

Sequence analysis of three canine adipokine genes revealed an association between TNF polymorphisms and obesity in Labrador dogs.

Obesity is an emerging health problem in purebred dogs. Due to their crucial role in energy homeostasis control, genes encoding adipokines are considered candidate genes, and their variants may be associated with predisposition to obesity. Searching for polymorphism was carried out in three adipokine genes (TNF, RETN and IL6). The study was performed on 260 dogs, including lean (n = 109), overweight (n = 88) and obese (n = 63) dogs. The largest cohort was represented by Labrador Retrievers (n = 136). Altogether, 24 novel polymorphisms were identified: 12 in TNF (including one missense SNP), eight in RETN (including one missense SNP) and four in IL6. Distributions of five common SNPs (two in TNF, two in RETN and one in IL6) were further analyzed with regard to body condition score. Two SNPs in the non-coding parts of TNF (c.-40A>C and c.233+14G>A) were associated with obesity in Labrador dogs. The obtained results showed that the studied adipokine genes are highly polymorphic and two polymorphisms in the TNF gene may be considered as markers predisposing Labrador dogs to obesity.

Novel polymorphisms in porcine 3'UTR of the leptin gene, including a rare variant within target sequence for MIR-9 gene in Duroc breed, not associated with production traits.

The leptin gene (LEP) is considered as a functional candidate for production traits in livestock due to its crucial role in energy homeostasis. Because polymorphisms in regulatory sequences may affect gene expression, we searched for them in the 3'UTR of LEP and analyzed their association with production traits. Four breeds and a composite line were studied. In the Polish Landrace and Polish Large White breeds, 8 SNPs and 1 indel were observed; whereas, in the Duroc breed, 9 specific SNPs were found. Pietrain and Line 990 were monomorphic. One SNP (g.+168C>T), observed in the Duroc breed only, was located within a target site for microRNA (miR-9). Association studies showed a weak association between one SNP (c.+846C>T) and abdominal fat weight in the Polish Landrace only. Thus, we concluded that contribution of polymorphisms in the 3'UTR to phenotypic variability of pig production traits is marginal. Moreover, we presented an overview of known polymorphisms (128) in the pig leptin gene.

Transcript level of the porcine ME1 gene is affected by SNP in its 3'UTR, which is also associated with subcutaneous fat thickness.

Pork quality depends on multiple factors, including fatty acid composition in muscle and fat tissues. The ME1 gene is a strong candidate for fat accumulation, as it encodes the malic enzyme, which is required for fatty acid synthesis. We identified seven new polymorphisms in 3'UTR of the ME1 gene and moreover confirmed the presence of 4 polymorphisms detected previously. Interestingly, the studied Duroc pigs were monomorphic at all these polymorphic sites, while in 3 other breeds (Pietrain, Polish Landrace and Polish Large White), the polymorphisms were unevenly distributed. One of the novel SNPs (c.*488A>G) was found in the Polish Large White and the Polish Landrace only, and the association studies revealed that it was significantly associated with backfat thickness and average daily weight gain in the Polish Landrace (N = 207) and the Polish Large White (N = 157). This SNP was differently associated with ME1 transcript level in muscle and backfat. The in silico analysis of another novel SNP (c.*548C>T) indicated that it is located within a binding sequence conserved among vertebrates for the miR-30 family in 3'UTR of the ME1. It was shown that in the longissimus muscle, but not in adipose tissue, CT gilts compared with CC ones had significantly lower levels of the ME1 transcript. This polymorphism, however, was not associated with production traits. Additionally, we observed that transcript level of the ME1 was significantly higher in subcutaneous fat than in the longissimus muscle, as well as both investigated tissues of the Polish Landrace when compared to the other breeds. However, no association was found between this polymorphism and fatty acid profiles. We conclude that the ME1 gene polymorphism (c.*488A>G) is a potential marker for porcine backfat thickness.

Family of melanocortin receptor (MCR) genes in mammals-mutations, polymorphisms and phenotypic effects.

The melanocortin receptor gene family consists of five single-exon members, which are located on autosomes. Three genes (MC2R, MC4R and MC5R) are syntenic in the human, mouse, cattle and dog genomes, while in the pig, the syntenic group comprises MC1R, MC2R and MC5R. Two genes (MC1R and MC4R) have been extensively studied due to their function in melanogenesis (MC1R) and energy control (MC4R). Conservative organisation of these genes in five mammalian species (human, mouse, cattle, pig and dog), in terms of the encoded amino acid sequence, is higher in the case of MC4R compared to MC1R. Polymorphisms of these two genes are responsible or associated with variation of pigmentation (MC1R) and adipose tissue deposition (MC4R). Polymorphic variants in MC1R, causing coat colour variation, were described in humans and domestic mammals (cattle, horse, pig, sheep, dog), as well as farm red and arctic foxes. The MC4R gene is very polymorphic in humans and it is well known that some variants cause monogenic obesity or significantly contribute to the development of polygenic obesity. Such relationships are not so evident in domestic mammals; however, at least one missense substitution (298Asp > Asn) in the porcine MC4R significantly contributes, at least in some breeds, to fat tissue accumulation, feed conversion ratio and daily weight gain. Knowledge on the phenotypic effects of polymorphisms of MC2R, MC3R and MC5R in domestic mammals is scarce, probably due to the small number of reports addressing these genes. Thus, further studies focused on these genes should be undertaken.

Dog obesity--the need for identifying predisposing genetic markers.

Incidence of overweight and obesity in dogs exceeds 30%, and several breeds are predisposed to this heritable phenotype. Rapid progress of canine genomics and advanced knowledge on the genetic background of human obesity bring a unique opportunity to perform such studies in dogs. Natural candidate genes for obesity are these encoding adipokines. Extended studies in humans indicated that polymorphisms of three of them, i.e. ADIPOQ, IL1 and TNF, are associated with predisposition to obesity. On the other hand, the use of genome-wide association studies revealed an association between human obesity and polymorphism of more than 50 other genes. Until now only few preliminary reports on polymorphism of canine FTO, MC4R, MC3R and PPARG genes have been published. Since the dog is a valuable model organism for human diseases one can foresee that such studies may also contribute to an in-depth understanding of human obesity pathogenesis.

Crystal structure of a human tRNA(Gly) microhelix at 1.2A resolution.

The tRNA(Gly)/glycyl-tRNA synthetase (GlyRS) system belongs to the so-called 'class II aminoacyl-tRNA synthetase system' in which tRNA identity elements are assured by rather few and simple determinants mostly located in the tRNA acceptor stem. Regarding evolutionary aspects, the tRNA(Gly)/GlyRS system is a special case. There exist two different types of GlyRS, namely an archaebacterial/human type and a eubacterial type reflecting an evolutionary divergence within this system. Here we report the crystal structure of a human tRNA(Gly) acceptor stem microhelix at 1.2A resolution. The local geometric parameters of the microhelix and the water network surrounding the RNA are presented. The structure complements the previously published Escherichia coli tRNA(Gly) aminoacyl stem structure.