The plasma protease inhibitor system (Pi) of Standardbred horses

The plasma protease inhibitor system (Pi) of Standardbred horses was studied by thin-layer, high-voltage, acid polyacrylamide gel electrophoresis (pH 4.6) followed by protein staining and staining for trypsin and chymotrypsin inhibition. In addition to the eight Thoroughbred alleles ( Pi^{F, g, i, L, N, S1, S2, u)} , another 10 alleles, designated PiH, j, k, ^o, ^p, ^q , ^r, ^v, ^{x, z}, were postulated to account for the 98 Pi types which were observed in Standardbreds. Detailed inhibitory spectra of the 'new' alleles were determined and further exceptions to the Pil, Pi2 classification of Juneja et al. (1979) were found. Limited family data demonstrated the genetic nature of the 'new' variants and confirmed the allelic inheritance of the 'new' Pi variants.     

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

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 alpha-protease inhibitors (protease inhibitor -1 and -2, PI1 and PI2; post-albumin -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 Pi1-Po1A-Po1B-Pi2. The alleles observed were two of Pi1, 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 alpha-protease inhibitor genes in humans and in rodents, reported recently in the literature, indicate evolutionary conservation of a homologous linkage group in these species.     

Genetic variants of serum alpha-1-antitrypsin (Pi types) in Bretons.

The results of Pi typing on 280 Bretons from Morbihan (Southern Brittany) are reported. 6 phenotypes and 5 alleles have been found in this study. Pi M is the most frequent as in other populations. Pi S and Pi F apears as the two main variants in population genetics.     

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.     

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 serum protease inhibitor linkage group in Belgian pig breeds

Genetic variants of pig serum alpha-protease inhibitors (protease inhibitors-1 and -2, PI1 and PI2; postalbumin-1A and -1B, PO1A and PO1B) were studied by 2-D electrophoresis of serum samples. The inheritance data confirmed the close linkage between the loci of these inhibitors. The order between these loci was indicated as Pi1-Po1A-Po1B-Pi2 and these were spread over a distance of about 1 cM. Very strong linkage disequilibrium was observed between the alleles at these loci. The two breeds studied (Belgian Landrace and Piétrain) showed very different allele and haplotype frequencies. Both breeds showed extensive polymorphism at Po1A and Pi2 loci.     

Genetic polymorphism and close linkage of two alpha 1-protease inhibitors in horse serum.

Two-dimensional electrophoretic analysis of horse serum proteins was done by a first-dimension separation in agarose gel (pH 5.4) followed by a second-dimension separation in horizontal polyacrylamide gel (pH 9.0). This method resulted in improved and reproducible separation of many alpha-globulins. Two groups of alpha 1-globulins, designated Pi1 and Pi2, were found to be protease inhibitors. Preliminary studies indicated that Pi1 and Pi2 proteins differed from each other in molecular weight and in protease inhibiting spectra. Extensive polymorphism was observed for both these proteins. Family data supported the hypothesis that Pi1 and Pi2 types were controlled by autosomal codominant alleles. For both Pi1 and Pi2 systems, most of the homozygous types showed two fractions each while the heterozygous types had 4 fractions. Six Pi1 and five Pi2 alleles were observed in two breeds of Swedish horses. Complete genetic linkage was observed for Pi1 and Pi2 loci as no recombinant type was observed in 40 informative matings studied.     

Genetic polymorphism of alpha 1-antitrypsin in green monkeys studied by isoelectric focusing and family analysis

24 variants of alpha 1-antitrypsin (alpha 1-AT) were recognized in sera of 120 wild and capture-born African green monkeys by isoelectrofocusing in Ampholine PAG-plates (pH 4-6.5) and western blotting with antihuman alpha 1-AT serum. All variants had much more cathodal position than human alpha 1-AT and revealed very high microheterogeneity which was slightly different from the observed in human alpha 1-AT. The alpha 1-AT banding pattern allowed to postulate existence of 10 codominant alleles in the Pi locus of African green monkeys. The reality of 8 alleles was proved by family analysis which included 45 monkey birth cases. Two other alleles were absent in the parents available. Thus, alpha 1-AT is the most polymorphic among the known serum proteins of African green monkeys. The latter can be useful for molecular systematics of these primates.     

Genetic polymorphism and close linkage of two α1-protease inhibitors in horse serum

Two-dimensional electrophoretic analysis of horse serum proteins was done by a first-dimension separation in agarose gel (pH 5.4) followed by a second-dimension separation in horizontal polyacrylamide gel (pH 9.0). This method resulted in improved and reproducible separation of many α-globulins. Two groups of aj-globulins, designated Pi1 and Pi2, were found to be protease inhibitors. Preliminary studies indicated that Pi1 and Pi2 proteins differed from each other in molecular weight and in protease inhibiting spectra. Extensive polymorphism was observed for both these proteins. Family data supported the hypothesis that Pi1 and Pi2 types were controlled by autosomal codominant alleles. For both Pi1 and Pi2 systems, most of the homozygous types showed two fractions each while the heterozygous types had 4 fractions. Six Pi1 and five Pi2 alleles were observed in two breeds of Swedish horses. Complete genetic linkage was observed for Pi1 and Pi2 loci as no recombinant type was observed in 40 informative matings studied.     

Protease inhibitor system in horses: classification and detection of a new allele

A method of horizontal thin layer polyacrylamide gel electrophoresis at acid pH has been developed for the separation of the prealbumins in equine plasma. Using this method, it has been possible to split the S allele into two, S₁ and S₂, bringing the total number of prealbumin alleles in Thoroughbred horses to eight. The gene frequencies of these eight alleles in Australian Thoroughbreds are presented. All eight prealbumin types exhibit antiprotease activity and therefore, it is suggested that the name prealbumin (Pr) should be abandoned in favour of protease inhibitor (Pi) although at this stage it is not known whether this incorporates the Pi1 and Pi2 described by Juneja et al. (1979).     

Characterisation of the alpha 1-protease inhibitor system in Thoroughbred horse plasma by horizontal two-dimensional (ISO-DALT) electrophoresis. 1. Protein staining

The isoelectric points and the molecular weights of the major components of the eight Thoroughbred protease inhibitor (Pi) types have been determined by polyacrylamide gel isoelectric focusing and polyacrylamide gel pore gradient (ISO-DALT) electrophoresis respectively. The major Pi proteins focus in the range pH 3.74-4.43 and have molecular weights ranging from 55 000-72 000 daltons. Using the ISO-DALT method of electrophoresis, protein maps for the eight Thoroughbred Pi types have been presented for the first time. None of the homozygous Pi types are identical except for the types S1 and S2 which show partial identity. The results do not necessarily support Juneja et al.'s (1979) contention of two closely linked alpha 1 Pi systems based on molecular weight differences. It is suggested that the traditional nomenclature originally proposed by Braend (1970) be maintained to describe the eight Pi alleles in Thoroughbred horse plasma. The ISO-DALT method provides a sensitive technique which is superior to existing techniques for the analysis of the horse Pi system.     

Biochemical genetics of Zea mays L. I. Isozymes and the linkage relationship between AP-1 and AP-2 loci

Following starch gel electrophoresis and a modified staining method, three distinct groups of acid phosphatase isozymes (AP-1, AP-2, and AP-3) have been identified in scutellum extracts of different inbred maize lines. The AP-2 group includes three electrophoretic variants: a fast (F), an intermediate (I), and a slow (S) type. Genetic analysis showed that AP-2 variants are under the control of three codominant alleles at the AP-2 locus. A linkage test between AP-1 and AP-2 indicated that a close linkage between these two loci is ruled out.     

Genetic Variation of the Equine Serum Protease Inhibitor System Pi (Pr) Characterized By an Enzyme Binding Staining Technique After Starch Gel Electrophoresis

A modification of Uriel & Berges (1968) staining technique has been developed for starch gels. This method, which makes use of the Pi proteins ability to bind trypsin and chymotrypsin, allows for the recognition of the Pi zones which migrate into slower positions than originally described by Braend (1970). The Pi zones appear as white bands against a lilac background. Serum samples from 18 sire families selected according to the Pi type of the sires have been studied. Ten families were Norwegian Trotter, 8 were Warm-blood Trotter (Standardbred). In each family 12 dam-offspring pairs were examined. In trypsin-treated gels the white zones usually correspond to those previously recognized by protein-staining. In addition, the products of the PiG, Pi1, PiL and PiW alleles each had 1 distinct slow band, but in different positions. The products of the PiN and PiU alleles lacked slow zones. The Pis and PiT alleles differed with respect to the positions of their slow bands. A new allele PiT1 was identified. This has a slow band in a different position from that of the PiL allele. An allele indistinguishable from PiZ was recognized in Norwegian Trotter in which also a new alle Je temporarily called PiY could be demonstrated. In chymotrypsin-treated gels the zone patterns of some of the allele products differed from those seen after trypsin-treatment.     

Comparison of Petunia inflata S-Locus F-box protein (Pi SLF) with Pi SLF like proteins reveals its unique function in S-RNase based self-incompatibility

Petunia inflata possesses S-RNase-based self-incompatibility (SI), which prevents inbreeding and promotes outcrossing. Two polymorphic genes at the S-locus, S-RNase and P. inflata S-locus F-box (Pi SLF), determine the pistil and pollen specificity, respectively. To understand how the interactions between Pi SLF and S-RNase result in SI responses, we identified four Pi SLF-like (Pi SLFL) genes and used them, along with two previously identified Pi SLFLs, for comparative studies with Pi SLF(2). We examined the in vivo functions of three of these Pi SLFLs and found that none functions in SI. These three Pi SLFLs and two other Pi SLFs either failed to interact with S(3)-RNase (a non-self S-RNase for all of them) or interacted much more weakly than did Pi SLF(2) in vitro. We divided Pi SLF(2) into FD1 (for Functional Domain1), FD2, and FD3, each containing one of the Pi SLF-specific regions, and used truncated Pi SLF(2), chimeric proteins between Pi SLF(2) and one of the Pi SLFLs that did not interact with S(3)-RNase, and chimeric proteins between Pi SLF(1) and Pi SLF(2) to address the biochemical roles of these three domains. The results suggest that FD2, conserved among three allelic variants of Pi SLF, plays a major role in the strong interaction with S-RNase; additionally, FD1 and FD3 (each containing one of the two variable regions of Pi SLF) together negatively modulate this interaction, with a greater effect on interactions with self S-RNase than with non-self S-RNases. A model for how an allelic product of Pi SLF determines the fate of its self and non-self S-RNases in the pollen tube is presented.     

Genetic polymorphism of horse serum protein 3 (SP3)

Two-dimensional agarose gel (pH 8.6)-horizontal polyacrylamide gel (pH 9.0) electrophoresis of horse serum samples, followed by general protein staining, revealed genetic polymorphism of an unidentified protein tentatively designated serum protein 3 (SP3). The SP3 fractions appeared distinctly when a 14% concentration of acrylamide was used in the separation gels. The 2-D mobilities of SP3 fractions were quite similar to that of albumin. Family data were consistent with the hypothesis that the observed SP3 phenotypes were controlled by four co-dominant, autosomal alleles (D, F, I, S). Evidence was provided that the F allele can be further divided into two alleles (F1 and F2); the mobilities of F1 and F2 variants were very similar. Each of the SP3 alleles gave rise to one fraction and each of the heterozygous types showed two fractions. More than 600 horses representing five different breeds (Swedish Trotter, North-Swedish Trotter, Thoroughbred, Arab and Polish Tarpan) were typed for SP3, and allele frequency estimates were calculated. SP3 was highly polymorphic in all breeds studied.     

ISO-DALT characterization of 12 ''new'' equine plasma protease inhibitor (Pi) alleles

Twelve equine protease inhibitory alleles, PiE, H, J, K, L2, O, P, Q, R, V, X, Z, have been characterized in terms of isoelectric point, molecular mass and inhibitory activity to bovine trypsin and chymotrypsin by ISO-DALT electrophoresis. Protein maps for 20 Pi alleles including those of the eight 'Thoroughbred' alleles (PiF, G, I, L, N, S1, S2, U) have now been determined. Five pairs of alleles, S1/S2, G/K, L/L2, P/R and U/Z, possessed varying numbers of common proteins ranging from one protein in the case of G/K and L/L2 to six in the case of U/Z. Based on these results and studies of the abnormal expressions of PiF, PiL and PiS1, a theory of at least three closely linked loci has been postulated to account for the marked heterogeneity of the equine protease inhibitory system.     

The equine protease inhibitory system (Pi): Abnormal expressions of PiF,PiL, and PiS

Three cases of abnormal expression of the equine protease inhibitory alleles, Pi F, L, and S₁, were observed following the examination of 30,000 plasma samples by one-dimensional acid (pH 4.6) polyacrylamide gel electrophoresis. Characterization of the abnormal proteins in terms of isoelectric point, molecular mass, inhibitory spectra, and sialic acid content was performed using one- and two-dimensional electrophoretic techniques. The Pi F and S₁ abnormalities were postulated to be the result of amino acid substitutions causing alterations in the processing of the carbohydrate side chains. No explanation could be offered for the Pi L abnormality other than a charge shift mutation. Abnormal types, F*, L*, and S*₁ behaved as alleles but the distribution of L* in offspring from one stallion (present in only 6 of 83 offspring) differed significantly from expectation.This work was supported by a grant from the Australian Stud Book, Alison Road, Randwick, N.S.W. 2031.     

Genetic polymorphism of horse serum protein 3 (SP3)

Summary. Two-dimensional agarose gel (pH 8.6)-horizontal polyacrylamide gel (pH 9.0) electrophoresis of horse serum samples, followed by general protein staining, revealed genetic polymorphism of an unidentified protein tentatively designated serum protein 3 (SP3). The SP3 fractions appeared distinctly when a 14% concentration of acrylamide was used in the separation gels. The 2-D mobilities of SP3 fractions were quite similar to that of albumin. Family data were consistent with the hypothesis that the observed SP3 phenotypes were controlled by four co-dominant, autosomal alleles ( D,F,I,S ). Evidence was provided that the F allele can be further divided into two alleles ( F ₁ and F ₂); the mobilities of F₁ and F₂ variants were very similar. Each of the SP3 alleles gave rise to one fraction and each of the heterozygous types showed two fractions. More than 600 horses representing five different breeds (Swedish Trotter, North-Swedish Trotter, Thoroughbred, Arab and Polish Tarpan) were typed for SP3, and allele frequency estimates were calculated. SP3 was highly polymorphic in all breeds studied.     

alpha1-antitrypsin: common subtypes of Pi M.

More than 20 different alleles are so far known at the Pi locus, corresponding to a total variant phenotype frequency of about 10% in most western Europeans. The common phenotype Pi M constitutes the remaining major group. Now it has been possible to identify three subtypes M1, M1M2 and M2, corresponding to the gene products of two common alleles PiM1 and PiM2, segregating as autosomal codominant alleles. Preliminary gene frequencies are reported for eight populations, the PiM2 frequency varying from 0.20 in Maris (USSR) to 0.02 in Bantus (Kenya).     

Human haptoglobin structure and function--a molecular modelling study

Hemoglobin is the most prominent protein in blood, transporting O(2) and facilitating reactive oxygen and nitrogen species detoxification. Hemoglobin metabolism leads to the release of extra-erythrocytic hemoglobin, with potentially severe consequences for health. Extra-erythrocytic hemoglobin is complexed to haptoglobin for clearance by tissue macrophages. The human gene for haptoglobin consists of three structural alleles: Hp1F, Hp1S and Hp2. The products of the Hp1F and Hp1S alleles differ by only one amino acid, whereas the Hp2 allele is the result of a fusion of the Hp1F and Hp1S alleles, is present only in humans and gives rise to a longer alpha-chain. Haptoglobin consists of a dimer of alphabeta-chains covalently linked by a disulphide bond between the Cys15 residue of each alpha-chain. However, the presence of the Hp1 and Hp2 alleles in humans gives rise to HPT1-1 dimers (covalently linked by Cys15 residues), HPT1-2 hetero-oligomers and HPT2-2 oligomers. In fact, the HPT2 variant displays two free Cys residues (Cys15 and Cys74) whose participation in intermolecular disulphide bonds gives rise to higher-order covalent multimers. Here, the complete modelling of both haptoglobin variants, together with their basic quaternary structure arrangements (i.e. HPT1 dimer and HPT2 trimer), is reported. The structural details of the models, which represent the first complete view of the molecular details of human haptoglobin variants, are discussed in relation to the known haptoglobin function(s).