Localization of the Po2 locus in the S, Phi, Hal, H, Po2, Pgd linkage group in pigs

The localization of the Po2 locus controlling a polymorphic serum postalbumin was studied in 41 families of the Czech Landrace breed. The haplotypes involving six closely linked loci (S, Phi, Hal, H, Po2, Pgd) were determined for each family member. The crossovers observed between the H, Po2 and Pgd loci indicated that Po2 is located between H and Pgd. The Po2 locus appears to be closer to H [theta = 0.54% (0.06%-1.92%)] than to Pgd [theta = 4.02% (1.67%-7.96%)]. A strong Ha-Po2S association (r = 0.96, P less than 0.001) and H-PO2 linkage disequilibrium (D = 0.2218, P less than 0.01, D/DMax = 0.98) were found.     

Associations between marker genotypes, halothane reaction, CC activity and meat quality characters in a sample of German Landrace pigs

Routine blood typing of German Landrace pedigree populations and an earlier study revealed very low frequencies of the favourable alleles at the marker loci Phi, Pgd and H . The hypothesis was that in this population the whole linkage group of favourable alleles at the halothane and neighbouring marker loci may have been lost as a consequence of intense selection for leanness and type. The present study of 1050 German Landrace pigs at the Relliehausen experimental station, where some effort has been made to maintain a higher frequency of the favourable alleles Phi^A (0.48), H- (0.43) and Pgd^A (0.70) gave quite different results.
The frequency of halothane-positive pigs found by using a severe test was only 30 %. Only 5.4 %, 8.8 %, 13.4 % and 13.9 7% of animals with Phi^AIA, H^-I-, Pgd^A/A and Phi^A/B genotypes respectively were halothane-positive. Forty to sixty per cent of pigs with these marker genotypes could therefore be expected to be homozygous halothane-negative ( N/N ) animals. Creatine kinase activity and three selected meat quality characters showed highly significant differences between the A/A and the B/B genotypes for the marker loci Phi and Pgd , with the heterozygotes being intermediate. These differences are greater than those observed between halothane-negative and halothane-positive phenotypes. The only other consistently superior marker genotype in this population was the H blood group genotype H -^I- . In contrast to findings from Sweden and Switzerland, the postalbumin locus Po2 and the suppressor locus S for the A-O blood groups did not exhibit useful marker qualities.
It is concluded that in the German Landrace the marker loci Phi, Pgd and H could also be helpful in breeding homozygous halothane-negative pigs with distinctly better meat quality characteristics.     

Gene order and recombination rates in the linkage group S-Phi-Hal-H-(Po2)-Pgd in pigs

Families of Czech Landrace (94 litters and 636 offspring) were tested for halothane sensitivity, A-O (S), H, PHI and PGD phenotypes. Informative matings for the estimation of recombination rates between marker loci were selected. The following recombination frequencies were established: S-Phi = 4.8 % (2.5 % -10.7 %);S-H = 6.8 % (4.3 %-11.7 %); Phi-H = 2.6 % (0.9 %-5.3 9%); H-Pgd = 4.4 % (1.6 %-8.0 %). CCCC-overs were observed also between S- Hal, Hal-H andHal - Pgd, but were not found between Phi - Hal. On the basis of these results it has been possible to revise the position of the S locus in this linkage group. The most probable gene order would be: S - Phi - Hal (or Hal - Phi) -H- (P02) - Pgd.
A striking difference was found between the number of halothane-sensitive pigs (87) and HalⁿHal ⁿ genotypes determined by haplotyping (123). Segregation rates in 19 backcross matings and experimental matings of the animals proved that this difference is mostly due to incomplete CCC or low expression of halothane sensitivity.     

Genetic variation at a pig serum protein locus, Po-2 and its assignment to the Phi, Hal, S, H, Pgd linkage group

Two-dimensional agarose gel (pH 5.4)-polyacrylamide gel (pH 9.0) electropho-resis of pig serum samples revealed a new serum protein (postalbumin-2, PO-2) polymorphism. Family data supported the hypothesis that the three PO-2 phenotypes observed were controlled by two codominant, autosomal alleles ( Po-2^F and Po-2^S ) at a single locus. The frequency of Po-2^F in Swedish Landrace and in Swedish Yorkshire breeds was estimated at 0.74 and 0.65, respectively. Evidence was presented for close genetic linkage between Po-2 and the red cell phospho-hexose isomerase locus ( Phi ). A recombination frequency of 3.2 % was obtained from double backcross material. Data obtained in a Danish Landrace material showing linkage between the Po-2 locus and the H blood group locus, the Pgd locus and Hal (locus for halothane sensitivity) are also given. A total of seven re-combinants were observed. They show that Po-2 is a new locus in a previously established linkage group. The likely sequence of the loci is: Phi, Hal, S, H, Po-2, Pgd .     

Linkage of genes for PHI,halothane sensitivity,A-O inhibition,H red blood cell antigens and 6-PGD variants in pigs*

Data from one apparent crossover between S and H, two between PHI and HAL on one side and S on the other, and one between PHI on one side and HAL, S and H on the other, indicate a gene order in pigs of Phi-Hal-S-H-Pgd for genes for PHI, halothane sensitivity, inhibition of expression of A and O, H red blood cell antigens and 6-PGD types. Rasmusen et al. (1980) provided data for a gene order in pigs ofPhi-Hal-H-Pgd for genes for phosphohexose isomerase (PHI) isozyme variants, halothane sensitivity (HAL), H red cell antigens and 6-phosphogluconate dehydrogenase (6-PGD) variants, and suggested that there might be a locus for a gene for inhibition of expression of A and O separate from the locus for H. This is contrary to an earlier proposal by Rasmusen (1972) that the H-system genotype directly influences expression of A and O. Imlah (1980) suggested that the recessive gene for halothane sensitivity has a suppressant effect on the expression of A and O. Andresen (1981) proposed that the locus for inhibition of A and O (for which Rasmusen, 1964, proposed the symbol S) was between the loci for HAL and H types. Data presented in Table 1, which includes haplotypes for three recombinant offspring described by Rasmusen et al. (1980) (883-1, 233-3 and 3864-1) as well as one other recombinant (296-2) provide evidence for the gene order for five genes proposed by Andresen. Types for 6-PGD are listed for all pigs, although they do not provide evidence for gene order in these cases. Male 883-1 (Table 1, and Rasmusen et al., 1980, Table 5) provided the original evidence for recombination between S and H. His phenotype, as well as his genotype as revealed by progeny test (Rasmusen et al., 1980, Table 6) indicated that recombination had occurred between the genes for PHI, HAL and S and the gene for H type in his dam, so that the S locus mapped between H and the loci for the other three traits. The phenotype of one of his sons (233-3, Table 1, and Rasmusen et al., 1980, Table 6) indicated that there had been a recombination between genes for PHI and HAL types on one side and S and H types on the other, providing evidence that the S locus was separate from PHI and HAL as well as H. Another pig listed in Table 1,3864-1, was also described by Rasmusen et al. (1980, Table 9) as a recombinant. This pig provides evidence for recombination between PHI on one side and HAL, S and H on the other, establishing a gene order of Phi-Hal-S-H-Pgd. The last pig listed in Table 1,296-2, is a recombinant comparable to 233-3. The H type of his dam provides markers indicating the recombination was between PHI and HAL on one side and S and H on the other, although the unusual expression of HAL phenotype in both parents of 296-2 makes her haplotypes somewhat uncertain. (Recombination may have been between PHI and HAL rather than as indicated in Table 1.) In spite of incomplete penetrance for HAL (Ollivier et al., 1975; Smith & Bampton, 1977) which makes haplotypes for HAL questionable in some cases, the other genetic markers available are useful to show that recombination has taken place. Without considering the results of halothane testing, if the apparent recombinants are accepted as being as indicated, the order of the genes at the other four loci seems established. Alleles for S types appear to be separable by recombination from those for PHI and H, and the S locus appears to be between the loci for PHI and H. For the five loci, data obtained thus far are cohsistent with a gene order of Phi-Hal-S-H-Pgd.     

Prediction of the halothane (Hal) genotypes of pigs by deducing Hal, Phi, Po2, Pgd haplotypes of parents and offspring: results from a large-scale practice in Swedish breeds

Results from a large-scale study, comprising 75 different breeding herds, are reported on predicting the halothane ( Hal ) genotypes of individual pigs by making use of the known close linkage between Hal and three C blood marker loci ( Phi, Po2, Pgd ). The parents haplotypes (involving Hal and marker loci) were determined from the HAL phenotypes (halothane test results) and marker loci phenotypes of their offspring in the first one or two litters studied. In subsequent litters of the Hal -marker loci haplotyped parents, the offspring's expected Hal genotypes could be predicted on the basis of the marker loci haplotypes inherited by them. By comparing the expected and observed HAL phenotypes of offspring in subsequent litters, the predicted Hal genotype was found to be correct in 90–95 % of the 4000 offspring (from Nn × Nn and Nn × nn matings) of Swedish Landrace and Yorkshire breeds studied.
The order of the three marker loci was confirmed as Phi-Po2-Pgd but the position of Hal with regards to Phi could not be resolved. The recombination frequencies between the most distant loci in this region, viz. Hal-Pgd and Phi-Pgd , were estimated to be 3–4.5 % and 4–6 % , respectively. The easy and rapid electrophoretic techniques described in the study to phenotype PHI, PO2, PGD, also allowed phe-notyping of six other polymorphic protein systems on the same gels. Thus Hal genotyping and effective parentage control can be conducted simultaneously.     

Halothane sensitivity and linkage of genes for H red blood cell antigens,phosphohexose isomerase (PHI) and 6-phosphogluconate dehydrogenase (6-PGD) variants in pigs*

Data from matings appropriate to test linkage in pigs of genes for halothane sensitivity (HAL), H red cell antigens, phosphohexose isomerase (PHI) and 6-phosphogluconate dehydrogenase (6-PGD) red cell isoenzyme variants were consistent with a gene order of Phi-Hal-H-Pgd. There was no unequivocal evidence for a Hal locus separate from Phi, although the phenotype of one pig not tested for halothane sensitivity suggested recombination between Hal and Phi. Breeding tests confirmed that in two cases there had been recombination between Hal and H. Offspring of one of these recombinant types provided evidence for a locus for a gene for inhibition of expression of A and O separate from the locus for H.     

The position of the epistatic S locus in the halothane linkage group in pigs

The linkage of the Phi, Pgd, Po2, S, H and halothane sensitivity loci was followed in a Belgian Landrace family, heterozygous for these systems over 6 generations. Recombination next to the S locus occurred mainly in pigs belonging to this particular family. From this investigation the position of the S locus is proved to be outwith the Phi-Pgd region, next to Phi. Therefore the gene sequence S - Phi - Hal - H - Po2 - Pgd is proposed. Higher recombination rates were observed in the female parental line of the multiheterozygous family when compared to the male parental line. Additional data from animals, unrelated to this strain, confirm the evidence of close linkage of the S system to the nearest marker loci.     

Linkage studies between the halothane (Hal), phosphohexose isomerase (Phi) and the S(A -O) and H red blood cell loci of Pietrain/ Hampshire and Landrace pigs

Frequency of blood group factors at the A-O and H loci were markedly altered within halothane positive (HP) and halothane negative (HN) composite synthetic Pietrain/Hampshire lines (PTH) over four generations of selection.
Linkage studies on the litters from 45 double backcross and 20 mixed and intercross matings, involving the S(A-O), H, Phi and Hal loci, were made in the PTH line and halothane positive and negative selected British Landrace lines. Crossing-over frequencies of 0.05 ± 0.04, 0.05 ± 0.03 and 0.1 ± 0.03 were established between Phi and Hal, H and Hal , and Phi and H respectively. An unequal crossing-over frequency between Phi and H was found when the alleles Ha and Hcd were compared. The difference in recombination frequency between the Ha and Hcd alleles amounted to 0.04 to 0.06.
No cross-overs were observed between the S(A -O ) and Phi, H or Hal loci in 15 families studied. The position of the S locus in relation to the other loci could not be established, but statistical evidence of association favours a haplotype sequence of Phi-Hal-S-H .     

Trends in economic traits, halothane sensitivity, blood group and enzyme systems of Swiss Landrace and Large White pigs

Pigs deriving from 150 breeding centres constituting a representative section of elite breeding herds (2496 Swiss Landrace pigs, 587 Swiss Large White pigs) were subjected to blood typing during the period 1981 to 1984. Production traits such as daily gain, feed conversion ratio, lean meat content and meat quality score were available to show the trend in these performance traits since 1978. Field data on the halothane reaction of 14 270 Swiss Landrace (SL) pigs were used to assess the porcine stress syndrome during the period 1978–1983.
In SL pigs the frequency of the alleles H^a, Phi^B and Ada^A decreased significantly, and that of the H^c and Phi^A increased during the period of the study. The frequency of the H^a allele dropped from 0.36 in 1981 to 0.20 in 1984, whereas the H^c allele rose from 0.22 to 0.37. In Swiss Large White (SLW) pigs, on the other hand, the frequency of the H^a allele increased constantly from 0.31 to 0.37 during this period.
An initial frequency of 17.7 % (1978) halothane reactors in SL pigs was lowered to 0.7 % (1982) after five years of halothane testing.
In SL pigs the meat quality scores improved regularly, whereas in SLW pigs it did not change very much. The percentage of PSE animals in the SL breed was reduced from 32.7 % in 1978 to 7.1 % in 1983.
Because the Hal locus is associated with production traits such as meat quality, linkage disequilibria could explain the observed associations between the H and Phi types and production traits.     

Blood group association with severity and speed of the halothane reaction1

The second generation (n= 227) of British Landrace pigs from selected halothane-positive parents (36 litters) were blood-typed for the S(A-0), H and Phi loci and subjected to four 5-minute halothane tests at 21, 35, 49 and 63 days of age. Cumulative scores based on seventy and speed of reaction were analysed in relation to single-locus blood group genotypes and linkage group sequences at two and three loci. A highly significant negative correlation (r = -0.79) was found between severity and speed of reaction. Significant differences occurred between blood group genotypes and linkage groups in both severity and speed of reaction. Genotypes S s/s, H a/a or H a/- and Phi B/B and linkage groups involving these three types had the highest cumulative reaction score and the fastest reaction time, whereas genotypes Phi A/B, S S/S or S S/s and H a/cd and linkage groups with these types had the Iowest and slowest reaction scores. Some differences between genotypes and linkage groups were attributed to phenotypically halothane-positive parents and offspring being genotypically Hal N/n. These effects could result from linkage with heterozygous types such as H a/cd and S S/s. The possible role of the H ^cd allele acting as a genetic marker for a suppressor gene to the halothane reaction is discussed.     

Recombination between the S and the Hblood group loci in Pigs

The investigation of A-O blood group phenotypes in selected pig families confirms the existence of an S locus which specifically controls the expression of A and) alloantigens. Forty-five informative litters were scored for linkage between the S gene and the H blood group locus. The recombination frequency in 345 offspring was estimated to be 9.56 % (33 cross-overs). Specific difficulties involved in the determination of A-O and H phenotypes and the importance of S and H polymorphisms for the determination of Hal genotypes are discussed.     

Absence of detectable linkage between the G and H blood group loci in the pig

Morton's lod score method used for the analysis of data from 168 backcross matings (1094 offspring) did not indicate linkage between the G and H blood group loci of the pig. Linkage closer than 0.413 could be excluded at the 1% significance level.     

Molecular characterization of the human ABO blood group orthologus system in pigs

The selection and use of animals with blood group 0 in the process of transplanting pig organs or tissues into humans can positively contribute to the control of acute immune rejection due to differences in blood groups. Exon-specific PCRs for the porcine blood group A transferase gene against genomic DNA from either blood group A or 0 animals resulted in the amplification failure of the A0 blood group gene exon 8 from blood group 0 animals. To characterize the genetic abnormality in the genome of blood group 0 animals, we screened bacterial artificial chromosome (BAC) clones from a Korean native pig BAC library which had the blood group 0 allele, and carried out shotgun sequencing. The analysis showed that the 0 allele has a large deletion between exon 7 of the A0 blood group gene and the neighbouring SURF6. We also showed that the ABO blood group antigens in humans and the A0 blood group antigens in pigs are coded by mutations within the orthologous glycosyltransferase gene. In addition, we developed a multiplex genotyping method for the porcine A0 blood group gene.     

The blood group factor Kf and allele Kae in the pig

By means of alloimmune reagents used in the indirect Coombs test and the dextran test a new factor Kf in the K bloodgroup system of pigs was found, controlled by alleles K ^acf, K ^acef and K ^bf. A new allele K ^ae was also detected.
The K system with 6 alleles, 11 phenotypes and 21 combinations of genotypes remains (from the genetic point of view) an open system.     

Genetic variation and biochemical properties of esterase-18 (ES-18) in the laboratory rat (Rattus norvegicus): A new locus of esterase cluster 2 in linkage group V

A new liver-specific rat carboxylesterase isozyme (EC 3.1.1.1) designated esterase-18 (ES-18) is described. Genetic variation of ES-18 was examined in 93 inbred strains and substrains and a structural locusEs-18 was suggested, coding for either the presence (Es-18 ^a) or the absence (Es-18 ^b) of the isozyme. Linkage studies involving two backcross series revealed thatEs-18 resides in cluster 2 of LGV. No recombination betweenEs-18 and other cluster 2 loci was found in 19 lines of two RI strain sets or in the backcross series.R. K. was supported by the Sonderforschungsbereich 146 (Versuchstierforschung). O.D. was supported by the Deutsche Forschungsgemeinschaft (De 315/2). This is communication No. 65 of a research program devoted to the cellular distribution, regulation, and genetics of nonspecific esterases.     

Polymorphism of pig serum alpha-protease inhibitor-3 (PI3) and assignment of the locus to the Pi1, Po1A, Po1B, Pi2, Igh linkage group

Polymorphism of an alpha-protease inhibitor, PI3, in pig serum samples was detected using 2D agarose gel (pH 5.4)--polyacrylamide gel (pH 9.0) electrophoresis. Evidence was obtained that the five variants observed (A, B1, B2, C and D) are under genetic control by codominant alleles (Pi3A, Pi3B1, Pi3B2, Pi3C and Pi3D) at one autosomal locus. Variants A, B1, B2 and C inhibited chymotrypsin; there was no appreciable inhibition of trypsin and papain. Variant D did not inhibit chymotrypsin, and therefore its classification as a PI3 variant was put in question. PI3 typing was not possible in about 50% of the studied pigs since in those cases the PI3 variants were either too weak or absent. On the basis of backcross matings and haplotyping in complete families for protease inhibitor loci Pi1, Po1A, Pi2 and Pi3 it was proved that the Pi3 locus belongs to the protease inhibitor gene cluster, and the position of the locus in the linkage group was proposed as being Pi1-Po1A-(Po1B)-Pi3-Pi2-(Igh1, Igh2, Igh3, Igh4).     

The bovine B and C blood group systems are not likely to be the orthologues of human RH: an interesting twist in the comparative map

We tested the hypothesis that either the bovine B or C blood group system is the orthologue of human RH. A comparative linkage mapping strategy was applied, using blood typing and restriction fragment length polymorphism (RFLP) analysis of four loci linked to RH on HSA1; PGD, FGR, ALPL and FUCA1. Four sires with a total of 255 half-sib offspring were used for the linkage analysis. Strong support for linkage between ALPL, FUCA1 and FGR was obtained for all sire families (lod scores >11 for all pairwise comparisons). This new linkage group was assigned to bovine synteny group U17 based on previous somatic cell mapping of the FGR locus. The most favoured order is ALPL—FUCA1—FGR (2·18:1), with ALPL and FGR 5·4 cm and 6·3 cm , respectively, from FUCA1. The B and C blood group systems and PGD were genetically independent of each other and all other markers, indicating that neither B nor C is likely to be the bovine orthologue of human RH. However, given available comparative mapping data, there is some chance that the bovine orthologue of RH is on bovine synteny group U6. Although gene order appears to be conserved with humans, the differences in recombination rates between these three loci in cattle, humans and mice strongly suggest that it is not possible to use human map distances to predict map distances in cattle, making it imperative that bovine gene mappers continue to emphasize adding type I markers to the bovine linkage map.     

Extensive genetic polymorphism of four plasma α-protease inhibitors in pigs and evidence for tight linkage between the structural loci of these inhibitors

Summary. Two-dimensional horizontal gel electrophoresis of pig plasma samples (under non-denaturing conditions) using Immobiline pH gradient gels 4.0–6.0 for the first dimension separation, resulted in clear resolution of the variants of four different α-protease inhibitors (protease inhibitor -1 and -2, P11 and P12; postalbumin -1A and -1B, PO1A and PO1B). All these variants were readily visualized by general protein staining. About 900 families each of Swedish Landrace (SL) and Yorkshire (SY) breeds were studied. The extensive inheritance data, including the recombinants encountered, indicated that each of these four inhibitors is controlled by a separate, autosomal locus and that the four loci are tightly linked (spread over a distance of 1–1.5 cM) with the order as Pil-Po1A-Po1B-Pi2 . The alleles observed were two of Pil, 14 of Po1A , 11 of Po1B and 8 of Pi2 . About 40 haplotypes were observed in each of the two breeds. The allele frequencies at Po1A, Po1B and Pi2 loci were remarkably different in the two breeds; the alleles at these three loci showed a very strong linkage disequilibrium (0.8–1.0). The females showed much higher recombination frequencies than the males in the Po1A-Pi2 interval, suggesting that gene conversion-like events may be occurring at these loci. This linkage in pigs and similar ones comprising some plasma α-protease inhibitor genes in humans and in rodents, reported recently in the literature, indicate evolutionary conservation of a homologous linkage group in these species.