Christoph Knorr

Polymorphisms in the bovine HSP90AB1 gene are associated with heat tolerance in Thai indigenous cattle.

Heat shock proteins act as molecular chaperones that have preferentially been transcribed in response to severe perturbations of the cellular homeostasis such as heat stress. Here the traits respiration rate (RR), rectal temperature (RT), pack cell volume (PCV) and the individual heat tolerance coefficient (HTC) were recorded as physiological responses on heat stress (environmental temperatures) in Bos taurus (crossbred Holstein Friesian; HF) and B. indicus (Thai native cattle: White Lamphun; WL and Mountain cattle; MT) animals (n = 47) in Thailand. Polymorphisms of the heat shock protein 90-kDa beta gene (HSP90AB1) were evaluated by comparative sequencing. Nine single nucleotide polymorphisms (SNP) were identified, i.e. three in exons 10 and 11, five in introns 8, 9, 10 and 11, and one in the 3′UTR. The exon 11 SNP g.5082C>T led to a missense mutation (alanine to valine). During the period of extreme heat (in the afternoon) RR and RT were elevated in each of the three breeds, whereas the PCV decreased. Mountain cattle and White Lamphun heifers recorded significantly better physiologic parameters (p < 0.05) in all traits considered, including or particularly HTC than Holstein Friesian heifers. The association analysis revealed that the T allele at SNP g.4338T>C within intron 3 improved the heat tolerance (p < 0.05). Allele T was exclusively found in White Lamphun animals and to 84% in Mountain cattle. Holstein Friesian heifers revealed an allele frequency of only 18%. Polymorphisms within HSP90AB1 were not causative for the physiological responses; however, we propose that they should at least be used as genetic markers to select appropriate breeds for hot climates.

Genome-wide QTL mapping for three traits related to teat number in a White Duroc × Erhualian pig resource population

BackgroundTeat number is an important fertility trait for pig production, reflecting the mothering ability of sows. It is also a discrete and often canalized trait presenting bilateral symmetry with minor differences between the two sides, providing a potential power to evaluate fluctuating asymmetry and developmental instability. The knowledge of its genetic control is still limited. In this study, a genome-wide scan was performed with 183 microsatellites covering the pig genome to identify quantitative trait loci (QTL) for three traits related to teat number including the total teat number (TTN), the teat number at the left (LTN) and right (RTN) sides in a large scale White Duroc × Erhualian resource population.ResultsA sex-average linkage map with a total length of 2350.3 cM and an average marker interval of 12.84 cM was constructed. Eleven genome-wide significant QTL for TTN were detected on 8 autosomes including pig chromosomes (SSC) 1, 3, 4, 5, 6, 7, 8 and 12. Six suggestive QTL for this trait were detected on SSC6, 9, 13, 14 and 16. Eight chromosomal regions each on SSC1, 3, 4, 5, 6, 7, 8 and 12 showed significant associations with LTN. These regions were also evidenced as significant QTL for RTN except for those on SSC6 and SSC8. The most significant QTL for the 3 traits were all located on SSC7. Erhualian alleles at most of the identified QTL had positive additive effects except for three QTL on SSC1 and SSC7, at which White Duroc alleles increased teat numbers. On SSC1, 6, 9, 13 and 16, significant dominance effects were observed on TTN, and predominant imprinting effect on TTN was only detected on SSC12.ConclusionThe results not only confirmed the QTL regions from previous experiments, but also identified five new QTL for the total teat number in swine. Minor differences between the QTL regions responsible for LTN and RTN were validated. Further fine mapping should be focused on consistently identified regions with small confidence intervals, such as those on SSC1, SSC7 and SSC12.

Molecular characterization of the porcine testis-specific phosphoglycerate kinase 2 (PGK2) gene and its association with male fertility.

We have isolated and characterized the porcine testis-specific phosphoglycerate kinase 2 (PGK2) gene, and 1665 bp of full-length PGK2 cDNA were also compiled using modified rapid amplification 5′-RACE and 3′-RACE information. The results of genomic and cDNA sequences of the porcine PGK2 gene demonstrated that it is a single-exon intronless gene with a complete open reading frame of 1251 bp encoding a PGK protein of 417 amino acids. Real-time quantitative PCR results showed that PGK2 mRNA was solely expressed in the testis. There was a lower amount of PGK2 expression in the testis of a 10-month-old herniated boar and a very small amount of PGK2 expression in the testis of an 8–week-old cryptorchid piglet compared to an adult boar. Two SNPs in the PGK2 gene (SNP-A: T427C; SNP-B: C914A) resulting in amino acid substitutions (SNP-A: Ser102–Pro102; SNP-B: Thr264–Lys264) were detected and genotyped among six pig breeds. The nucleotide C at SNP-A responsible for the amino acid exchange to proline could lead to the loss of a casein kinase II (CK2) phosphorylation site in the PGK2 peptide. Association analyses between PGK2 genotypes and several traits of sperm quantity and quality were performed. The results showed that SNP-B has a positive significant effect on semen volume in the breed Pietrain (p = 0.08), i.e., boars carrying genotype CC revealed an increased volume of 49 ml compared with boars having the genotype AA.

A single nucleotide polymorphism in the CYP2E1 gene promoter affects skatole content in backfat of boars of two commercial Duroc-sired crossbred populations.

The prevention of unpleasant boar taint is the main reason for castration of male piglets. This study aimed to investigate how the malodorous compound skatole is affected by a single nucleotide polymorphism (g.2412 C>T at -586 ATG) in the porcine cytochrome p450 II E1 (CYP2E1) gene. 119 boars of two commercial Duroc-sired crossbred populations raised at different farms were investigated. Skatole and androstenone in backfat averaged 114±125 ng/g and 1206±895 ng/g melted fat, respectively. The frequency of the genotypes CC, CT, and TT was 25, 52, and 23%, respectively. CC boars had the highest average skatole levels (175 ng/g) compared to CT (92 ng/g) and TT (93 ng/g). Applying suggested sensory threshold levels for skatole (>150 ng/g) and androstenone (>2000 ng/g), 30% of the carcasses may be unacceptably tainted while the proportion of tainted carcasses is significantly higher within genotype CC (56.7%) compared to genotypes CT (24.3%) and TT (14.8%). Effective reduction of tainted carcasses appears feasible applying marker assisted selection.

Targeted oligonucleotide-mediated microsatellite identification (TOMMI) from large-insert library clones

BackgroundIn the last few years, microsatellites have become the most popular molecular marker system and have intensively been applied in genome mapping, biodiversity and phylogeny studies of livestock. Compared to single nucleotide polymorphism (SNP) as another popular marker system, microsatellites reveal obvious advantages. They are multi-allelic, possibly more polymorphic and cheaper to genotype. Calculations showed that a multi-allelic marker system always has more power to detect Linkage Disequilibrium (LD) than does a di-allelic marker system [1]. Traditional isolation methods using partial genomic libraries are time-consuming and cost-intensive. In order to directly generate microsatellites from large-insert libraries a sequencing approach with repeat-containing oligonucleotides is introduced.ResultsSeventeen porcine microsatellite markers were isolated from eleven PAC clones by t argeted o ligonucleotide-m ediated m icrosatellite i dentification (TOMMI), an improved efficient and rapid flanking sequence-based approach for the isolation of STS-markers. With the application of TOMMI, an average of 1.55 (CA/GT) microsatellites per PAC clone was identified. The number of alleles, allele size distribution, polymorphism information content (PIC), average heterozygosity (HT), and effective allele number (NE) for the STS-markers were calculated using a sampling of 336 unrelated animals representing fifteen pig breeds (nine European and six Chinese breeds). Sixteen of the microsatellite markers proved to be polymorphic (2 to 22 alleles) in this heterogeneous sampling. Most of the publicly available (porcine) microsatellite amplicons range from approximately 80 bp to 200 bp. Here, we attempted to utilize as much sequence information as possible to develop STS-markers with larger amplicons. Indeed, fourteen of the seventeen STS-marker amplicons have minimal allele sizes of at least 200 bp. Thus, most of the generated STS-markers can easily be integrated into multilocus assays covering a broader separation spectrum. Linkage mapping results of the markers indicate their potential immediate use in QTL studies to further dissect trait associated chromosomal regions.ConclusionThe sequencing strategy described in this study provides a targeted, inexpensive and fast method to develop microsatellites from large-insert libraries. It is well suited to generate polymorphic markers for selected chromosomal regions, contigs of overlapping clones and yields sufficient high quality sequence data to develop amplicons greater than 250 bases.

Allelic Variant in the Anti-Müllerian Hormone Gene Leads to Autosomal and Temperature-Dependent Sex Reversal in a Selected Nile Tilapia Line

Owing to the demand for sustainable sex-control protocols in aquaculture, research in tilapia sex determination is gaining momentum. The mutual influence of environmental and genetic factors hampers disentangling the complex sex determination mechanism in Nile tilapia (Oreochromis niloticus). Previous linkage analyses have demonstrated quantitative trait loci for the phenotypic sex on linkage groups 1, 3, and 23. Quantitative trait loci for temperature-dependent sex reversal similarly reside on linkage group 23. The anti-Müllerian hormone gene (amh), located in this genomic region, is important for sexual fate in higher vertebrates, and shows sexually dimorphic expression in Nile tilapia. Therefore this study aimed at detecting allelic variants and marker-sex associations in the amh gene. Sequencing identified six allelic variants. A significant effect on the phenotypic sex for SNP ss831884014 (p<0.0017) was found by stepwise logistic regression. The remaining variants were not significantly associated. Functional annotation of SNP ss831884014 revealed a non-synonymous amino acid substitution in the amh protein. Consequently, a fluorescence resonance energy transfer (FRET) based genotyping assay was developed and validated with a representative sample of fish. A logistic linear model confirmed a highly significant effect of the treatment and genotype on the phenotypic sex, but not for the interaction term (treatment: p<0.0001; genotype: p<0.0025). An additive genetic model proved a linear allele substitution effect of 12% in individuals from controls and groups treated at high temperature, respectively. Moreover, the effect of the genotype on the male proportion was significantly higher in groups treated at high temperature, giving 31% more males on average of the three genotypes. In addition, the groups treated at high temperature showed a positive dominance deviation (+11.4% males). In summary, marker-assisted selection for amh variant ss831884014 seems to be highly beneficial to increase the male proportion in Nile tilapia, especially when applying temperature-induced sex reversal.

Molecular characterization of porcine hyaluronidase genes 1, 2, and 3 clustered on SSC13q21

Hyaluronidase genes (HYAL) encode hyaluronidase enzymes required for hyaluronan degradation. Both in humans and in mouse, clustered hyaluronidase genes have been identified. Here, the porcine hyaluronidase cluster consisting of genes HYAL1, HYAL2 and HYAL3 was characterized. The porcine cDNA sequences and proteins share homologies to human orthologs of 85 and 81% for HYAL1, 87 and 89% for HYAL2 and 86 and 83% for HYAL3, respectively. The porcine hyaluronidase proteins approximately share a 40% homology with each other. Furthermore, genes FUS1 and FUS2 were found within this cluster, which was assigned to SSC13q21. A total of seven SNPs were detected in the genes (four in HYAL1, two in HYAL2 and one in HYAL3). Three of the four SNPs in HYAL1 led to amino acid exchanges (C622G → Asp24 to Glu; C633T → Pro28 to Leu, and G1298T → Ala250 to Ser). The amino acid replacements induce putative changes in the extended strand at Asp24, in the extended strand and the random coil at Pro28, and finally in the random coil and the alpha helix at Ala250. Frequency estimations for four SNPs located in genes HYAL1 and HYAL3 using animals (n = 295) of nine European and six Chinese pig breeds indicated several significant deviations. For example, there were no significant differences in allele frequencies between pigs representing breeds Hampshire and Jiangquhai at SNP C633T (HYAL1), but between Hampshire respectively Jiangquhai animals and Rongchang pigs. Analysis of the same breeds at SNP C588T (HYAL3) indicates significant differences between Hampshire and Jiangquhai respectively Rongchang, but not between Jiangquhai and Rongchang. The breed Göttingen Minipig displayed significant differences concerning two SNPs with respect to the other European pig breeds tested. For all three hyaluronidase genes, N-glycosylation sites are typical. For HYAL2 the lysosomal character was proven. The catalytic site responsible for HAase activity is conserved in the three enzymes. Expression of hyaluronidases was determined by RT-PCR and quantitative PCR. Broad gene expression was observed in different tissues for the three genes, respectively.

Characterization of two SNPs (single nucleotide polymorphisms) in the porcine INSL3 gene and their exclusion as a common genetic basis of hernia inguinalis in pigs.

The INSL3 gene encoding Leydig cell insulin-like hormone is an important candidate gene for congenital disorders of the reproductive tract in pigs. Comparative sequencing using phenotypically hernia inguinalis affected and unaffected animals showed that the porcine gene is remarkably conserved. No polymorphisms were found in the two exons or in the intron. Two single-nucleotide polymorphisms (SNPs) were detected in the promoter region (G-224A and A-164C) of the sequenced pigs and fast screening methods were developed for large scale studies. Some significant breed differences exist for allele frequencies at both SNPs in the INSL3 gene. Screening of the two SNPs in a population of hernia inguinalis affected full and half sib piglets (n = 223) revealed that the SNPs can be excluded as a common genetic basis for this congenital disorder in this pedigree.

Sequence analysis of the equine SLC26A2 gene locus on chromosome 14q15→q21

The solute carrier family 26, member 2 (SLC26A2) gene belongs to a family of multifunctional anion exchangers. Mutations in the human SLC26A2 gene are associated with autosomal recessively inherited chondrodysplasias. Hence, we postulate that the equine SLC26A2 could be a candidate gene for conformational traits in horses. An equine BAC clone harboring the SLC26A2 gene was isolated. The complete 142,625 bp insert sequence of this clone was determined by transposon sequencing. Together with the SLC26A2 gene the BAC clone contains four genes, i.e. the macrophage colony stimulating factor 1 receptor precursor (CSF1R), KIAA0194 protein gene similar to the SMF protein (KIAA0194), a tigger transposable element derived 14 (TIGD14), the 3′-5′-cyclic GMP phosphodiesterase alpha-chain (EC 3.1.4.35) and one unidentified open reading frame. The equine SLC26A2 gene encompassing 6,152 bp consists of two exons. The complete open reading frame of 2,211 bp encodes a protein of 736 amino acids. A comparison of the amino acid sequence with other mammalian orthologs revealed homologies with identity in a range between 80% and 88%. By contrast, the equine SLC26A2 protein lacks five C-terminal amino acids. Four single nucleotide polymorphisms (SNP) were identified (three synonymous and one non-synonymous variant Ser210Leu) in the coding region by comparative sequencing of 50 DNA samples representing the German Riding horse. Allele frequencies and distribution were further evaluated in a variety of different breeds: Arabians (for all four SNPs), Old Kladrub Horses, Draught Horses (including Westphalian Draught Horses, Rheinish Westphalian Draught Horses, Saxon-Thuringia Coldbloods, Altmärker Coldbloods), American Saddlebreds, Miniature Horses, Australian Riding Ponies, Appaloosa, Morgan Horses, and Lipizzaner for C629T (Ser210Leu) alone. No animal carrying the homozygous genotype TT has been detected. The overall frequency of the newly described variant T is low (between 2% and 6%). Simulation studies on the protein conformation predict structural protein changes mediated by the SNP.

Calcium-release-channel genotypes in several pig populations-associations with halothane and CK reactions.

SUMMARY DNA of 2985 pigs from different sources were tested for variants of the calcium-release-channel (CRC) gene. Frequencies of the C allele, associated with stress resistance, were 0.0 for Belgian Landrace, 0.01 for Pietrain, 0.54 for German Landrace, 0.86 for German-Landrace sowline, 0.91 for Schwäbisch-Hällisches swine, 0.95 for European Wildboar, and 0.99 for Large White. All 50 Meishan individuals tested were C/C. In the two German Landrace populations more individuals with heterozygous genotypes were observed than had been expected. These results may indicate balanced allele frequencies caused by overdominance-type selection associated with meat quantity. 6.0 % of the halothane-positive pigs were C/C or C/T, and 3.6 % of the halothane-negative animals were T/T. As some of the pig groups were crossbreeds from extremely divergent sources (e.g. European Wildboar, Meishan, Pietrain), special gene effects may have influenced the phenotypic reaction to halothane. The average CK values vary between pigs of different CRC genotypes, e.g., the CK(80) values 2.64 ± 0.023, 2.83 ± 0.027, and 3.19 ± 0.036 were measured for individuals of C/C, C/T and T/T, respectively. For the German Landrace, culling according to a threshold of CK(80) ≥ 2.70 would eliminate 29.1 % of C/C, 63.0 % of C/T, and 90.4 % of T/T individuals. Whether CK-based selection may be used for further selection in populations with a fixed CRC C allele is discussed. ZUSAMMENFASSUNG: Genotypen des Kalziumfreisetzungskanals in verschiedenen Schweinepopulationen-Zusammenhänge mit Halothan- und CK-Reaktionen Auf die Genvariante des Calciumfreisetzungskanales (CRC), die als Ursache für das Maligne Hyperthermic Syndrom beim Schwein angesehen wird, wurden 2985 Schweine verschiedener Herkünfte untersucht. Dabei ergaben sich folgende Allelfrequenzen für das C-Allel, welches in Zusammenhang mit der Streßresistenz steht: 0,0 bei der Belgischen Landrasse, 0,01 bei der Rasse Pietrain, 0,54 bei der Deutschen Landrasse, 0,86 bei der Deutschen Landrasse Sauenlinie, 0,91 beim Schwäbisch-Hällischen Schwein, 0,95 beim europäischen Wildschweine und 0,99 bei der Rasse Large White. Alle 50 untersuchten Meishan-Tiere zeigten den Genotyp C/C. Für die beiden untersuchten Populationen der Deutschen Landrasse wurden mehr heterozygote Genotypen beobachtet als erwartet waren. Dieses Ergebnis mag auf balancierte Allelfrequenzen hinweisen, die auf Überdominanzeffekten beruhen können. Insgesamt 6 % der im Halothan-Test als positiv eingestuften Schweine zeigten die Genotypen C/C bzw. C/T, während 3,6 % der Nicht-Reagenten den Genotyp T/T aufwiesen. Da manche der untersuchten Schweine Kreuzungsprodukte genetisch extrem unterschiedlicher Herkünfte sind (europäisches Wildschein, Meishan und Pietrain), wird vermutet, daß bestimmte Geneffekte die phänotypische Reaktion auf Halothan ausgelöst haben. Der CK(80) Wert unterschied sich bei den Schweinen unterschiedlicher CRC-Genotypen: 2,64 ± 0,023, 2,83 ± 0,027 und 3,19 ± 0,036 für die Tiere mit den Genotypen C/C, C/T bzw. T/T. Bei einer Selektionsschranke für den CK(80) von ≥ 2,70 müßten 29,1 % der C/C-, 63,0 % der C/T- aber lediglich 90,4 % der T/T-Tiere ausgeschlossen werden. Es wird diskutiert, wie eine Selektion nach dem CK-Wert in Populationen, in denen das C-Allel fixiert ist, wirkt.