Family and population studies on the human pepsinogen A multigene family.

Human pepsinogen A (PGA) displays highly polymorphic isozymogen patterns after polyacrylamide gel electrophoresis and activity staining. The patterns differ with respect to the presence and the relative intensity of the individual fractions. Family studies strongly suggest that these isozymogen patterns are encoded by allelic haplotypes, encompassing different numbers and types of PGA genes. In this paper, we confirm the essential features of this multigene model. We establish the relationship between the haplotypes and the corresponding isozymogen patterns by determination of the PGA polymorphism at both the DNA and the protein level in 117 Dutch individuals, 60 of whom were unrelated. The combination of HindIII and EcoRI restriction fragment length polymorphisms (RFLPs) has enabled us to define different haplotypes, which are shown to segregate within families. Most genes are characterized by their specific EcoRI fragments. The HindIII RFLP is in strong linkage disequilibrium with PGA genes showing strong expression of the relevant isozymogen. Although a general picture of the relationship between genotypes and phenotypes is emerging, there are exceptions, suggesting that rare haplotypes evolve by unique crossover events.

Nucleotide sequence comparison of five human pepsinogen A (PGA) genes: evolution of the PGA multigene family.

To unravel the genetic basis for the pepsinogen A (PGA) protein polymorphism, we have isolated and characterized a number of PGA genes, distinguishable by polymorphic EcoRI fragments of 12.0, 15.0, and 16.6 kb. Using a HindIII or AvaII polymorphism, we can discriminate between different 15.0 (15.0 and 15.0*) and 12.0 (12.0s and 12.0l) genes, respectively. The coding sequences of a 15.0 and a 16.6 gene were determined, together with considerable stretches of the 5'- and 3'-flanking regions and introns. The genes were demonstrated to encode Pg5 and Pg4, respectively. Because substitutions in codons 43 and 207 appeared to be critical in the determination of the encoded proteins, we sequenced only these regions in the two 12.0 genes and the 15.0* gene. On the basis of these partial sequences, we assume that these genes encode Pg3. In the evolutionary model of the PGA gene cluster presented here, the 12.0 genes arose by an unequal, but homologous crossover. The results of sequence analysis of the second intron of the 12.0s, 12.0l, 15.0, and 16.6 genes suggest that the two 12.0 genes have arisen from two different crossover events.

Cloning and sequencing of rhesus monkey pepsinogen A cDNA.

The complete nucleotide sequence of Rhesus monkey (Macaca mulatta) pepsinogen A (PGA) cDNA was determined from two partially overlapping cDNA clones, covering the whole coding sequence and part of the flanking sequences. The nucleotide and deduced amino acid sequences were compared to known PGA sequences from other species. The degree of similarity with human PGA appeared to be 96% at the nucleotide sequence level and 94% at the amino acid sequence level. In the coding region the divergence was highest in the activation peptide. The amino acid sequence similarity between Japanese monkey (Macaca fuscata) PGA and Rhesus monkey PGA was shown to be 99%. Using the cDNA as probe in Southern hybridization of EcoRI-digested human and Rhesus monkey genomic DNAs, PGA patterns with inter-individual differences were observed. The hybridization patterns are compatible with the existence of a PGA multigene family in both species.

Genomic structure and evolution of the human pepsinogen A multigene family.

A human cosmid library was screened with a pepsinogen A (PGA) cDNA probe, yielding 18 clones with (parts of) one, two or three PGA genes. By aligning these cosmids a restriction map of a PGA gene quadruplet was obtained in which the four genes are arranged in a highly ordered fashion in a head-to-tail orientation. Using the length in kilobases of the large polymorphic EcoRI fragment of the PGA genes, this quadruplet can be described as 15.0-12.0-12.0-16.6. An AvaII polymorphism allowed us to identify the two PGA haplotypes of the individual whose DNA had been cloned in the cosmid library to be a gene triplet and a gene quadruplet. By comparing the restriction maps of the central 12.0 genes in these multiplets to those of the flanking 15.0 and 16.6 genes, we postulate that these central genes arose from unequal but homologous crossing over between two 15.0-16.6 gene pairs. This hypothesis provides for the creation of a variety of haplotypes by additional cross overs and mutations. Southern blots of family and population material supports the existance of at least five common PGA haplotypes, including a single-gene haplotype, giving rise to a large number of different EcoRI patterns. The single PGA gene is probably the reciprocal crossing over product. Comparison between the DNA and protein polymorphisms suggests further micro-heterogeneity in the different PGA haplotypes.

Molecular cloning of a pair of human pepsinogen A genes which differ by a Glu----Lys mutation in the activation peptide.

Three human cosmid clones containing pepsinogen A (PGA) encoding sequences were isolated from a genomic bank derived from a single individual. One cosmid contains two PGA genes in tandem in a head-to-tail orientation, while the other two cosmids each contain a single PGA gene. The three cosmids were characterized by restriction mapping and sequence analysis (exons 1 and 2 and flanking regions). As judged from these data, three of the four PGA genes isolated appear to be nearly identical, but one of the tandem genes is clearly different from the other genes. The first exon of all four genes codes for the same amino acid sequence. However, in the second exon of one of the tandem genes we found a nucleotide substitution giving rise to a Glu----Lys substitution of the 43rd amino acid residue of the activation peptide, leading to a charge difference of the corresponding isozymogens. The presence of two distinct PGA genes in the isolated gene pair conclusively proves the multigene structure of the PGA system. These genes might be responsible for at least part of the electrophoretic polymorphism at the protein level.