The human alpha-amylase multigene family consists of haplotypes with variable numbers of genes

Polymorphic amylase protein patterns have suggested the presence in the human genome of various haplotypes encoding these allozymes. To investigate the genomic organization of the human alpha-amylase genes, we isolated the pertinent genes from a cosmid library constructed of DNA from an individual expressing three different salivary amylase allozymes. From the restriction maps of the overlapping cosmids and a comparison of these maps with the restriction enzyme patterns of DNA from the donor and family members, we were able to identify two haplotypes consisting of very different numbers of salivary amylase genes. The short haplotype contains two pancreatic genes (AMY2A and AMY2B) and one salivary amylase gene (AMY1C), arranged in the order 2B-2A-1C, encompassing a total length of approximately 100 kb. The long haplotype spans about 300 kb and contains six additional genes arranged in two repeats, each one consisting of two salivary amylase genes (AMY1A and AMY1B) and a pseudogene lacking the first three exons (AMYP1). The order of the amylase genes within the repeat is 1A-1B-P1. All genes are in a head-to-tail orientation except AMY1B, which has the reverse orientation with respect to the other genes. Analysis of somatic cell hybrids confirmed the presence of these short and long haplotypes. Furthermore, we present evidence for the existence of additional haplotypes in the human population and propose a general model for the evolution of the human alpha-amylase multigene family. A general designation 2B-2A-(1A-1B-P)n-1C can describe these haplotypes, n being 0 and 2 for the short and the long haplotypes presented in this paper, respectively.     

Evolution of the human alpha-amylase multigene family through unequal, homologous, and inter- and intrachromosomal crossovers

Human amylase haplotypes differ from each other by different numbers of a long direct repeat unit of approximately 100 kb, encompassing two complete salivary amylase genes and one amylase pseudogene lacking the first three exons. The two salivary genes are part of a 75-kb-long inverted repeat. Two short sequences, hybridizing with a probe containing exons 1-3, were found in the central part of the inverted repeat. Sequencing showed that these fragments, designated r, contain exon 3 sequences. We present evidence that these r-fragments and the pseudogene most likely are remnants of the same ancestral pancreatic gene. We determined the orientation of the exon 3 sequences present in the r-fragment and show that an inversion can explain their origination. Hybridization studies, using random fragments from the intergenic region of the AMY gene cluster as probes, enabled us to detect more extended homologous regions in this cluster than were found previously on the basis of restriction maps only. Together, these results allow us to present a model for the evolution of the human amylase multigene family by a number of consecutive events involving inter- and intrachromosomal crossovers.     

The mouse alpha-amylase multigene family. Sequence organization of members expressed in the pancreas, salivary gland and liver

The DNAs that specify the α-amylase messenger RNAs found in the pancreas, salivary gland and liver of mouse strain A have been isolated by molecular cloning in phage λ. Amylase clones were studied by mRNA/DNA hybrid analysis in the electron microscope, restriction endonuclease site mapping and DNA sequencing. The Amy-2^a gene, which specifies pancreatic α-amylase mRNA, measures 10·1 kb from cap to polyadenylation site and is interrupted by at least 9 intervening sequences. Amy-1^a, which specifies both salivary gland and liver α-amylase mRNAs contains at least 10 introns. The distance between the cap and polyadenylation sites used in the salivary gland and the liver measures 22·9 kb and 20 kb, respectively. Introns are located at very similar, if not identical, positions within comparable regions of Amy-1^a and Amy-2^a. The first intron of Amy-1^a, which interrupts sequences specifying 5′ non-translated regions of salivary gland and liver α-amylase mRNAs, has no counterpart in Amy-2^a. Some introns exhibit considerable sequence homology, suggesting that Amy-1^a and Amy-2^a have evolved by duplication from a common split ancestor sequence. Repetitive sequence elements occur in the introns and flanking regions of these genes. Gene titration by quantitative autoradiography reveals only one copy of Amy-1^a, but two copies of Amy-2^a per haploid mouse genome. In addition to Amy-1^a and Amy-2^a, several other amylase-like DNA sequences exist in the mouse genome. No gross rearrangements of amylase DNA sequences can be detected between germline DNA and that of various mouse tissues.     

Polyphenol oxidase in potato. A multigene family that exhibits differential expression patterns.

Polyphenol oxidase (PPO) activity in potato (Solanum tuberosum) plants was high in stolons, tubers, roots, and flowers but low in leaves and stems. PPO activity per tuber continued to increase throughout tuber development but was highest on a fresh weight basis in developing tubers. PPO activity was greatest at the tuber exterior, including the skin and cortex tissue 1 to 2 mm beneath the skin. Flowers had high PPO activity throughout development, particularly in the anthers and ovary. Five distinct cDNA clones encoding PPO were isolated from developing tuber RNA. POT32 was the major form expressed in tubers and was found in all parts of the tuber and at all stages of tuber development. It was also expressed in roots but not in photosynthetic tissues. POT33 was expressed in tubers but mainly in the tissue near the skin. POT72 was detected in roots and at low levels in developing tubers. NOR333 was identical with the P2 PPO clone previously isolated from potato leaves (M.D. Hunt, N.T. Eannetta, Y. Haifeng, S.M. Newman, J.C. Steffens [1993] Plant Mol Biol 21: 59-68) and was detected in young leaves and in tissue near the tuber skin but was highly expressed in flowers. The results indicate that PPO is present as a small multigene family in potato and that each gene has a specific temporal and spatial pattern of expression.     

DNA sequence of a human Sm autoimmune antigen. The multigene family contains a processed pseudogene

The sequence of a complementary DNA clone coding for a human autoimmune antigen has been determined. This DNA sequence predicts the amino acid sequence of a small protein ("E") which is associated with small nuclear RNA in human cells. Analysis of the predicted protein sequence suggests that the E protein is not closely related to other nucleic acid binding proteins. Screening of a human genomic DNA library has led to the isolation of several members of the E protein multigene family. Sequence analysis of one member of this family reveals that it is flanked by direct repeats and contains several mutations. One of these mutations, an insertion, terminates the long open reading frame. These features are compatible with the designation of this sequence as a processed pseudogene.     

The olfactory multigene family.

A novel multigene family has been identified that is likely to encode odorant receptors on olfactory sensory neurons. Further studies on this gene family are likely to shed light on the molecular mechanisms underlying information coding in the mammalian olfactory system. This review is also published in Current Opinion in Genetics and Development 1992, 2:467-473.     

The olfactory multigene family.

A novel multigene family has been identified that is likely to encode odorant receptors on olfactory sensory neurons. Further studies on this gene family are likely to shed light on the molecular mechanisms underlying information coding in the mammalian olfactory system. This review is also published in Current Opinion in Neurobiology 1992, 2:282-288.     

DNA repair in man: regulation by a multigene family and association with human disease

The major mechanism of repair of damage to DNA involves a conceptually simple process of enzymatic excision and resynthesis of small regions of DNA. In man and other mammals, this process is regulated by several gene loci; up to 15 mutually complementary genes or gene products may be involved. Repair deficiency results in an array of clinical symptoms in skin, central nervous system, and hematopoietic and immune systems, the major example being xeroderma pigmentosum (XP), a disease with a high incidence of cancer. Cloning repair genes by straightforward methods has proved difficult, but we have begun the effort by demonstrating that correction of a human repair deficiency can be achieved by transferring very small fragments of DNA from normal hamsters into XP cells. One of the complementation groups of XP cells (group C) appears to express a change in gene regulation such that these cells repair only a small clustered region of the DNA with high efficiency.     

Isolation of a multigene family containing human alpha-tubulin sequences

The boundaries of the origin of polyoma DNA replication have been analyzed using a set of deletion mutants. The majority of these had small deletions, 5 to 30 base-pairs in size, which together removed most of the non-translated sequences of the genome. The phenotype of the mutants was characterized by analysis of infectivity, transforming ability and DNA synthesis. All mutants with reduced or abolished infectivity had corresponding defects of viral DNA synthesis. The effect of the deletion was cis-acting, since the replication of the mutants was not stimulated by the presence of wild-type DNA. Deletions causing a reduction of DNA synthesis were found at two sites. The first at the 32 base-pair inverted repeat sequence and the neighbouring A · T tract previously implicated in the initiation of DNA synthesis, and the second close to the late genes. The two sites were separated by at least 60 base-pairs of non-essential DNA. Only one mutant with a deletion at the second site was unable to express early gene functions.The mutants were constructed by linearization, shortening and recircularization of polyoma DNA inserted into the plasmid pBR322. The mutagenesis was directed at restriction endonuclease BglI or PvuII cleavage sites. The BglI-directed mutagenesis was focussed to polyoma DNA by using as a vector a derivative of pBR322 resistant to cleavage by BglI.     

Identification of members of the P-glycoprotein multigene family.

Overproduction of P-glycoprotein is intimately associated with multidrug resistance. This protein appears to be encoded by a multigene family. Thus, differential expression of different members of this family may contribute to the complexity of the multidrug resistance phenotype. Three lambda genomic clones isolated from a hamster genomic library represent different members of the hamster P-glycoprotein gene family. Using a highly conserved exon probe, we found that the hamster P-glycoprotein gene family consists of three genes. We also found that the P-glycoprotein gene family consists of three genes in mice but has only two genes in humans and rhesus monkeys. The hamster P-glycoprotein genes have similar exon-intron organizations within the 3' region encoding the cytoplasmic domains. We propose that the hamster P-glycoprotein gene family arose from gene duplication. The hamster pgp1 and pgp2 genes appear to be more closely related to each other than either gene is to the pgp3 gene. We speculate that the hamster pgp1 and pgp2 genes arose from a recent gene duplication event and that primates did not undergo this duplication and therefore contain only two P-glycoprotein genes.     

Genomic structure and evolution of the human pepsinogen A multigene family

Summary 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.     

Evolution of the regulators of G-protein signaling multigene family in mouse and human

The regulators of G-protein signaling (RGS) proteins are important regulatory and structural components of G-protein coupled receptor complexes. RGS proteins are GTPase activating proteins (GAPs) of Gi-and Gq-class Galpha proteins, and thereby accelerate signaling kinetics and termination. Here, we mapped the chromosomal positions of all 21 Rgs genes in mouse, and determined human RGS gene structures using genomic sequence from partially assembled bacterial artificial chromosomes (BACs) and Celera fragments. In mice and humans, 18 of 21 RGS genes are either tandemly duplicated or tightly linked to genes encoding other components of G-protein signaling pathways, including Galpha, Ggamma, receptors (GPCR), and receptor kinases (GPRK). A phylogenetic tree revealed seven RGS gene subfamilies in the yeast and metazoan genomes that have been sequenced. We propose that similar systematic analyses of all multigene families from human and other mammalian genomes will help complete the assembly and annotation of the human genome sequence.     

The cyclophilin multigene family of peptidyl-prolyl isomerases. Characterization of three separate human isoforms.

Cyclophilin (CyP), a major cytosolic protein possessing peptidyl-prolyl cis-trans isomerase activity, has been implicated as the specific receptor of the immunosuppressive drug cyclosporin A (CsA). To identify other potential CsA receptors related to CyP, two human cDNA libraries were screened under low stringency conditions using human CyP cDNA (encoding hCyP1) as a probe. Two cDNAs were identified which encode distinct proteins related to human hCyP1. These two novel proteins, designated hCyP2 and hCyP3, share 65 and 76% amino acid sequence homology with hCyP1, respectively. Both hCyP2 and hCyP3 contain NH2-terminal hydrophobic extensions of 32 and 42 amino acids, respectively. Protein-specific antibodies revealed the predominant association of hCyP2 and hCyP3 with membranes and subcellular organelles, which suggests that the amino-terminal leader sequences of the two CyP isoforms may act as signal peptides. In contrast to the results with hCyP1, Southern blot analysis indicated that both hCyP2 and hCyP3 gene sequences are represented infrequently in the human genome. Northern and Western blot analysis showed that the distribution of mRNA and proteins of the three hCyPs in differing tissues and cell types was similar. Each hCyP protein was expressed in Escherichia coli, purified, and shown to be an active peptidyl-prolyl isomerase. Substrate specificity was examined with 11 synthetic peptides (Suc-Xaa-Yaa-Pro-Phe-4-nitroanilide), and inhibition of the peptidyl-prolyl isomerase activities associated with hCyP1, hCyP2, and hCyP3 was studied with CsA, MeAla6-CsA and MeBm2t1-CsA. From both equilibrium considerations and the results of kinetic characterizations it is proposed that of these three CyP proteins, hCyP1 is the most likely intracellular target for CsA.     

Family and population studies on the human pepsinogen A multigene family

Summary 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.     

Structures of two HaeIII-type genes in the human salivary proline-rich protein multigene family

Two members of the human salivary proline-rich protein (PRP) multigene family have been isolated and completely sequenced. These PRP genes, PRH1 and PRH2, are of the HaeIII-type subfamily and code for acidic PRP proteins. Both genes are approximately 3.5 kilobase pairs (kb) in length and contain four exons. Exon 3 encodes the proline-rich part of the protein and includes five 63-base pair (bp) repeats. CAT and ATA boxes and several possible enhancer sequences occur in a 1-kb region 5' to exon 1. Two sets of repeats occur in the sequenced region in addition to the 63-bp repeats: one pair of about 140 bp flanks 500 bp of DNA in the first intervening sequence, and the other pair of 72 bp is tandemly repeated 1.4 kb 5' to the PRH1 gene. The 4-kb region of sequenced DNA from PRH1 differs by an average of 8.7% from the same region in PRH2, but the nucleotide sequences of the exon 3 of the two genes differ by only 0.2%. This result suggests the occurrence of a recent gene conversion event. The regions containing the 5-fold repeated sequences of 63 bp are identical in the two genes, PRH1 and PRH2. A comparison of the human HaeIII and BstNI subfamily repeats and a comparison of the human, mouse, and rat repeats suggest that the individual repeats have evolved in a concerted fashion within each gene and within the PRP gene family as a whole.     

Gene conversions within the skeletal myosin multigene family.

Comparisons of the nucleotide sequences of the light meromyosin (LMM) region of developmentally regulated fast chicken myosin heavy chain (MHC) isoforms indicates that chicken MHC isoforms are more similar to each other than to MHC isoforms in other species. The sequence data provide evidence that gene conversion events have occurred recently among the isoforms. An embryonic (Cemb1) isoform and neonatal isoform have the most extensive regions of sequence identity. Similar gene conversion events are present in the rat alpha- and beta-cardiac MHCs, but were not obvious in the LMM of developmentally regulated fast human MHC isoforms. The data suggest that gene conversion events can play a significant role in the evolution of the MHC multigene families and that concerted evolution of the chicken multigene family occurred after the divergence of mammals and avians.     

Differential tissue expression of the glutathione transferase multigene family.

The content of GSH transferase mRNAs in poly(A)-containing RNA isolated from eight rat tissues was examined by immunoprecipitation of cell-free translation products and by Northern blotting. Considerable tissue-specific distribution and heterogeneity of immunoprecipitable GSH transferase subunits 1 and 2 synthesized in vitro was observed. These results were confirmed by Northern blotting using a 32P-labelled subunit 1 cDNA probe. The same probe, used in a Southern blot analysis of genomic DNA, provided confirmation that GSH transferase subunits 1 and 2 comprise a multigenic family in the rat. The results show that the selection of cDNA clones coding for chosen subunits can be made easier by making use of qualitative and quantitative tissue differences in GSH transferase mRNAs.