Preliminary evidence of segregation distortion in the SLA system

Transmission ratio distortion detection by neutral genetic markers in the Pura Raza Española horse breed

Transmission Ratio Distortion (TRD) is a genetic phenomenon widely demonstrated in several livestock species, but barely in equine species. The TRD occurs when certain genotypes are over- or under-represented in the offspring of a particular mating and can be caused by a variety of factors during gamete formation or during embryonic development. For this study, 126 394 trios consisting of a stallion, mare, and offspring were genotyped using a panel of 17 neutral microsatellite markers recommended by the International Society for Animal Genetics for paternity tests and individual identification. The number of alleles available for each marker ranges from 13 to 18, been 268 the total number of alleles investigated. The TRDscan v.2.0 software was used with the biallelic procedure to identify regions with distorted segregation ratios. After completing the analysis, a total of 12 alleles (out of 11 microsatellites) were identified with decisive evidence for genotypic TRD; 3 and 9 with additive and heterosis patterns, respectively. In addition, 19 alleles (out of 10 microsatellites) were identified displaying allelic TRD. Among them, 14 and 5 were parent-unspecific and stallion-mare-specific TRD. Out of the TRD regions, 24 genes were identified and annotated, predominantly associated with cholesterol metabolism and homeostasis. These genes are often linked to non-specific symptoms like impaired fertility, stunted growth, and compromised overall health. The results suggest a significant impact on the inheritance of certain genetic traits in horses. Further analysis and validation are needed to better understand the TRD impact before the potential implementation in the horse breeding programme strategies.

Bypassing Mendel's First Law: Transmission Ratio Distortion in Mammals

Mendel's law of segregation states that the two alleles at a diploid locus should be transmitted equally to the progeny. A genetic segregation distortion, also referred to as transmission ratio distortion (TRD), is a statistically significant deviation from this rule. TRD has been observed in several mammal species and may be due to different biological mechanisms occurring at diverse time points ranging from gamete formation to lethality at post-natal stages. In this review, we describe examples of TRD and their possible mechanisms in mammals based on current knowledge. We first focus on the differences between TRD in male and female gametogenesis in the house mouse, in which some of the most well studied TRD systems have been characterized. We then describe known TRD in other mammals, with a special focus on the farmed species and in the peculiar common shrew species. Finally, we discuss TRD in human diseases. Thus far, to our knowledge, this is the first time that such description is proposed. This review will help better comprehend the processes involved in TRD. A better understanding of these molecular mechanisms will imply a better comprehension of their impact on fertility and on genome evolution. In turn, this should allow for better genetic counseling and lead to better care for human families.

Maternal Transmission Ratio Distortion in Two Iberian Pig Varieties

Transmission ratio distortion (TRD) is defined as the allele transmission deviation from the heterozygous parent to the offspring from the expected Mendelian genotypic frequencies. Although TRD can be a confounding factor in genetic mapping studies, this phenomenon remains mostly unknown in pigs, particularly in traditional breeds (i.e., the Iberian pig). We aimed to describe the maternal TRD prevalence and its genomic distribution in two Iberian varieties. Genotypes from a total of 247 families (dam and offspring) of Entrepelado (n = 129) and Retinto (n = 118) Iberian varieties were analyzed. The offspring were sired by both ungenotyped purebred Retinto and Entrepelado Iberian boars, regardless of the dam variety used. After quality control, 16,246 single-nucleotide polymorphisms (SNPs) in the Entrepelado variety and 9744 SNPs in the Retinto variety were analyzed. Maternal TRD was evaluated by a likelihood ratio test under SNP-by-SNP, adapting a previous model solved by Bayesian inference. Results provided 68 maternal TRD loci (TRDLs) in the Entrepelado variety and 24 in the Retinto variety (q < 0.05), with mostly negative TRD values, increasing the transmission of the minor allele. In addition, both varieties shared ten common TRDLs. No strong evidence of biological effects was found in genes with TRDLs. However, some biological processes could be affected by TRDLs, such as embryogenesis at different levels and lipid metabolism. These findings could provide useful insight into the genetic mechanisms to improve the swine industry, particularly in traditional breeds.

DRB3.2 gene polymorphism and its association with pashmina production in Changthangi goat

PstI and TaqI restriction fragment length polymorphism (RFLP) of caprine DRB3.2 revealed three genotypes under each RFLP in Changthangi goat. The genotypic and allelic frequency in PstI RFLP was calculated as 0.07, 0.72 and 0.20 for PP, Pp and pp genotypes and 0.43 and 0.57 for P and p alleles. In TaqI RFLP the frequencies were observed as 0.11, 0.61 and 0.27 for TT, Tt and tt genotypes and 0.41, 0.59 for T and t alleles. Alignment study indicates variability of nucleotides and amino acids between alleles and different breeds of goats. The nucleotide sequences reported in this paper have been submitted to the European Molecular Biology Laboratory GenBank and the accession numbers were AY496935, AY496061 and AY496062. A significant affect (P <or= 0.05) of MHC DRB3.2 PstI polymorphism was found on the first and second year of pashmina production.

Associations between major histocompatibility complex genes and production traits in White Leghorns

The frequency of the MHC haplotype B15 had been found in a previous study to be more than two times higher in a White Leghorn line selected for high egg production compared with the unselected control strain. To further evaluate these findings, matings were performed between chickens with the same heterozygous B genotypes, being combinations of the most frequent haplotypes, i.e., B15, B19, and B21. In total, more than 1,300 observations from two generations were analyzed. In each generation, approximately one half of the chickens were derived from the line selected for total egg mass, the other half from the control strain. The MHC genotypes were determined serologically. Additive and dominance effects of B haplotypes on production traits were analyzed using an individual animal model. The estimation of genotypic values, together with the analysis of gene substitution effects, showed that the B15 haplotype was associated with early sexual maturity and low egg production during the late production period, i.e., between 43 and 63 wk of age, whereas B19 was associated with later onset of sexual maturity. The association of B15 with early sexual maturity would thus explain the high frequency of the B15 haplotype previously observed in a line selected for high early egg production. No dominance effect of the B system was observed for any of the traits, suggesting that the present results were due predominantly to additive gene effects.

Influence of major histocompatibility complex on reproduction and production traits in swine

The effects of the swine lymphocyte antigen (SLA) system on different performance traits were investigated in Swiss pig breeds. Litter size and piglet weight at birth and at weaning were considered and in gilts the average daily weight gain, backfat and muscle thickness as well as percentage valuable cuts were measured. These data were analysed with least squares procedures. Although the effect of SLA on these traits was very small, a few haplotypes seemed to have some influence. Sows of the Large White breed carrying H12 had a significant smaller and those with H24 had a bigger litter size at weaning. Some mating studies were performed to investigate the effects of SLA homozygosity. The obtained results suggest that this has a negative effect on the litter size, especially when H19 in the Large White breed and H7 in Landrace are involved.

Swine lymphocyte alloantigens (SLA) class I serology and genetics in Belgian Landrace and Pietrain breeds

Eighty anti-SLA class I reagents were prepared resulting from skin graft and subcutaneous immunizations in 320 fattening pigs of the Belgian Landrace and Pietrain breeds. By means of these alloantisera seven internationally and five locally established specificities were recognized. Three of the locally assigned specificities were new: BM 36, BM 37 and BM 38. They were serologically and genetically defined. The typing battery was completed with French and Danish reagents, and correlation coefficients were calculated for the main alloantisera recognizing SLA class I alloantigens observed in the Belgian breeds. The SLA haplotype frequencies were estimated in 372 Belgian Landrace and 369 Pietrain pigs. The SLA haplotype distribution differs significantly between both breeds and the genetic distance (0.54) at the SLA system is quite high.

Familial polycystic ovaries: a genetic disease?

High resolution ultrasonography was used to establish the presence of polycystic ovaries (PCO) in 50 women with symptoms of polycystic ovary syndrome and in 17 women with congenital adrenal hyperplasia. One hundred and thirty-seven post-menarcheal, premenopausal female members of the families of these patients were scanned to assess the heredity of the condition. Familial PCO was found in 56 of the 61 pedigrees (92%) in which sufficient members were available for study. The frequency of PCO in the relatives of the patients with congenital adrenal hyperplasia was no different from that found in the main group. Twenty-four out of thirty-six (67%) mothers of probands and 45 out of 52 (87%) sisters of probands were affected. The segregation ratio (fraction of females affected) for all sibships was 107 out of 133 (80.5%). The volumes of the polycystic ovaries (mean 9.97 ml, 95% confidence limits (CL) +/- 0.75) were significantly different from those of the normal ovaries (mean 5.38 ml, 95% CL +/- 0.26) (P less than 0.0001), although there was no significant difference between the volumes of the ovaries of the probands and those of their affected relatives. Even after allowing for a high frequency of PCO in the general population (22%), the observed segregation ratios were significantly different from those predicted for autosomal dominant (P less than 10(-4)) and X-linked dominant (P = 0.0002) modes of inheritance. A number of mechanisms which might account for the observed segregation ratio are considered. These include meiotic drive due to a genetic segregation distorted, vertical transmission of an infective agent, and environmental factors, such as the effect of maternal androgen on gonadal development.

Segregation distortion within the equine MHC; analogy to a mouse T/t-complex trait

Segregation distortion was found for a haplotype of the equine lymphocyte antigen (ELA) system in an extended family of American Standardbred horses. In one sire family, consisting of a stallion and his 17 sons and grandsons, the gene for ELA-A10 (A10) was transmitted to 57.7% of 638 offspring scored (P = 0.001). Significant segregation distortion was not seen for mares or for unrelated stallions, regardless of the ELA markers they possessed. Since the effect was seen for this one sire family and not seen for other stallions with A10, it is unlikely that the gene for A10 is the cause of this phenomenon, but rather A10 is linked to another major histocompatibility complex (MHC) gene causing this trait. This trait appeared analogous to the segregation distortion observed for the T/t complex of the mouse. Since segregation distortion involving MHC genes has been seen in other species, genes for this trait may be a general feature of the MHC.