The nucleotide sequence of bovine MHC class IIDQB andDRB genes

The nucleotide sequences of most of the exons and parts of the introns of twoBoLA-DQB genes and twoBoLA-DRB genes have been determined. The structure of these genes is very similar to that of human major histocompatibility complex (MHC) class II genes. The twoDQB genes probably represent true alleles. Based on the exons sequenced, bothDQB genes and one of theDRB genes seem to be functional. The otherDRB gene is a pseudogene; stopcodons are found in the exons encoding the second and transmembrane domain and, furthermore, a 2 base pair (bp) deletion has occured in the leader exon which places the initiation start codon out of frame. Also in this pseudogene, an almost perfect inverted repeat of 200 bp is found flanking the exon encoding the first domain, which might have been the result of a duplication/inversion event. The sequences presented in this paper do not contain any repetitions. Therefore, DNA fragments containing these sequences can be used as homologous bovine probes in restriction fragment length polymorphism (RFLP) analysis to study disease association in cattle.The nucleotide sequence data reported in this paper have been submitted to the GenBank nucleotide sequence database and have been assigned the accession numbers M30002–M30014. Address correspondence and offprint requests to: M. A. M. Groenen.     

Overlapping two genes in human DNA: a salivary amylase gene overlaps with a gamma-actin pseudogene that carries an integrated human endogenous retroviral DNA

The human salivary amylase gene (amy1), consisting of eleven exons, is expressed in the salivary gland and in some amylase-producing tumors. Its uppermost exon and the following intron, along with the 5'-flanking region of this gene, are shown to be superimposed with a gamma-actin pseudogene sequence, a portion of which is transcribed into salivary amylase mRNA and another portion of which serves as a promoter for the amy1 gene. In the further upstream region, the gamma-actin pseudogene sequence is interrupted by a human endogenous retroviral nucleotide sequence.     

Primary structure of human pancreatic alpha-amylase gene: its comparison with human salivary alpha-amylase gene

We have determined the entire structure of the human pancreatic alpha-amylase (Amy2) gene. It is approx. 9 kb long and is separated into ten exons. This gene (amy2) has a structure very similar to that of human salivary alpha-amylase (Amy1) gene [Nishide et al. Gene 41 (1986a) 299-304] in the nucleotide sequence and the size and location of the exons. The major difference lies in the fact that amy1 has one extra exon on the 5' side. Other differences are at the 5' border of exon 1 and the 3' border of exon 10. The close similarity of these two genes, as compared with mouse pancreatic and salivary amylase genes, suggests that during evolution, the divergence into the two amylase genes may have occurred after the divergence of mice and man.     

Evolution of collagen IV genes from a 54-base pair exon: A role for introns in gene evolution

The exon structure of the collagen IV gene provides a striking example for collagen evolution and the role of introns in gene evolution. Collagen IV, a major component of basement membranes, differs from the fibrillar collagens in that it contains numerous interruptions in the triple helical Gly-X-Y repeat domain. We have characterized all 47 exons in the mouse alpha 2(IV) collagen gene and find two 36-, two 45-, and one 54-bp exons as well as one 99- and three 108-bp exons encoding the Gly-X-Y repeat sequence. All these exons sizes are also found in the fibrillar collagen genes. Strikingly, of the 24 interruption sequences present in the alpha 2-chain of mouse collagen IV, 11 are encoded at the exon/intron borders of the gene, part of one interruption sequence is encoded by an exon of its own, and the remaining interruptions are encoded within the body of exons. In such "fusion exons" the Gly-X-Y encoding domain is also derived from 36-, 45-, or 54-bp sequence elements. These data support the idea that collagen IV genes evolved from a primordial 54-bp coding unit. We furthermore interpret these data to suggest that the interruption sequences in collagen IV may have evolved from introns, presumably by inactivation of splice site signals, following which intronic sequences could have been recruited into exons. We speculated that this mechanism could provide a role for introns in gene evolution in general.     

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.     

Linkage map of two HLA-SB beta and two HLA-SB alpha-related genes: an intron in one of the SB beta genes contains a processed pseudogene

Three overlapping cosmid clones contain coding sequences for four HLA Class II genes, provisionally identified as two HLA-SB alpha and two HLA-SB beta genes. The genes are in the order beta, alpha, beta, alpha, inverted with respect to each other. One of the SB beta genes contains a 513 bp sequence that appears to be a processed pseudogene, flanked by direct 17 bp repeat sequences, in the intron upstream of the beta 1 exon. The pseudogene is homologous to a family of sequences of approximately 25-40 members, most of which are not on chromosome 6. A cDNA clone, highly homologous to the pseudogene, except for its 5' end, contains a normal poly(A) addition site and a poly(A) tail. The cDNA clone is homologous to a single-copy gene in both man and mouse, encoded on human chromosome 15. A search of published DNA sequences identified a mouse sequence, with about 77% similarity to the pseudogene sequence, in the negative strand of an intron in a mouse dihydrofolate reductase gene. The second SB beta gene does not contain the pseudogene sequence.     

Structure of human immunoglobulin gamma genes: implications for evolution of a gene family

We have cloned five human immunoglobulin gamma genes from a fetal liver gene library. Four of them encode the known human immunoglobulin gamma chains gamma 1, gamma 2, gamma 3 and gamma 4. A fifth gamma gene seems to be a pseudogene. Nucleotide sequence determination demonstrates that the gamma 3 gene contains four separate hinge exons. Comparison of these hinge exons with those of the other gamma genes indicates that the first hinge exon is homologous to that of the pseudogene, and that the other three hinge exons are homologous to that of the gamma 1 gene, suggesting that the gamma 3 gene ancestor is a hybrid gene created by unequal crossing-over between the ancestral gamma 1 and psi gamma genes. Amplification of the gamma 1-type hinge exon probably followed to complete the gamma 3 gene. This hypothesis inevitably postulates the gene order 5'-gamma 1-gamma 3-psi gamma-3'. Cloning of overlapping chromosomal segments demonstrates that the gamma 2 gene is located 19 kb 5' to the gamma 4 gene. These analyses indicate that the human gamma-gene family has evolved by several types of DNA rearrangemet, including duplication of a complete gene; duplication of a hinge exon; and reassortment of exons by unequal cross-over between two adjacent genes.     

Interpretation of polymorphic DNA patterns in the human alpha-amylase multigene family.

Previous molecular studies have clearly shown that the human amylase locus has a very complicated structure. Multiple salivary and pancreatic amylase genes are present on haplotypes with variable numbers of genes. To study the population heterogeneity, human genomic DNA from family members and random individuals was digested with a number of different restriction enzymes and hybridized with probes representing various parts of the human pancreatic amylase cDNA. The complex patterns obtained were, in most cases, compatible with predictions from the restriction enzyme maps of cloned human amylase genes. With some enzymes deviations from the predicted intensities of the bands associated with the pancreatic amylase gene AMY2A were observed. These findings can be explained by unequal homologous crossovers between AMY2A and AMY1A, resulting in haplotypes with one gene less or one gene more than the haplotypes described thus far. Moreover, a very complicated TaqI polymorphism was found that can be explained by homologous crossovers between different salivary amylase genes. Because some salivary amylase genes have an inverted orientation with respect to the others, these data provide evidence for the occurrence of intrachromosomal, homologous crossovers, as proposed by us previously (P. C. Groot et al., 1990, Genomics 8: 97-105).     

The primate psi beta 1 gene. An ancient beta-globin pseudogene

The human beta-globin gene cluster contains five functional genes plus a single pseudogene termed psi beta 1. Hybridization and comparative sequence analysis show that this pseudogene is not the product of a recent gene duplication, but is ancient and has been maintained in all major primate groups ranging from prosimians to anthropoids, at the same position as in man, between gamma- and delta-globin genes. In the lemur, a prosimian, the central exons of the psi beta 1 and delta-globin genes have undergone an unequal exchange, which has resulted in a contraction of the beta-globin gene cluster and the formation of a Lepore-type psi beta 1-delta globin pseudogene. Comparisons of defects shared by prosimian, New World monkey and human psi beta 1 sequences suggest that the ancestral primate gene was probably a pseudogene with an abnormal initiation codon but few if any additional defects, and that most contemporary pseudogene defects were accumulated relatively recently by slow neutral drift. We suggest that psi beta 1 arose early in primate evolution by silencing of a pre-existing discrete functional gene, and show that psi beta 1-related sequences are also present in other mammalian orders. In view of the antiquity of psi beta 1-related sequences, we propose that this gene be renamed the eta-globin gene.     

Nucleotide sequence of a portion of human chromosome 9 containing a leukocyte interferon gene cluster

The nucleotide sequence of a 9937 base-pair portion of human chromosome 9, which contains two complete leukocyte interferon genes (LeIF-L and J), the complete intergenic region, and part of a third related possible pseudogene (LeIF-M), has been determined. The coding regions of the L and J genes are separated by 4363 nucleotides. The coding regions for the putative L and J interferons are 96% homologous and are each surrounded by about 3500 nucleotides of flanking sequences, which are also highly homologous. The L and J genes and their respective flanking sequences comprise a 4000 nucleotide leukocyte interferon gene repeat unit; the L gene repeat unit contains two major insertions not present in the J gene repeat unit. The J gene repeat unit is flanked by sequence features reminiscent of those found surrounding transposable elements. Both the L and J gene repeat units are embedded within sequences that are highly repeated in the human genome. Structural features identified within this portion of chromosome 9 may have been important for the generation of this interferon gene cluster.     

The human glucocerebrosidase gene and pseudogene: structure and evolution

We report the sequence of the entire human gene encoding beta-glucocerebrosidase and that of the associated pseudogene. The gene contains 11 exons extending from base pair 355 to base pair 7232 in the overall sequence. The gene promoter contains TATA- and CAT-like boxes upstream of the major 5' end of the glucocerebrosidase RNA. The two TATA boxes lie between nucleotides (-23)-(-27) and (-33)-(-39) and the two possible CAT boxes reside between nucleotides (-90)-(-94) and (-96)-(-99) in relation to the major 5' end of the mRNA. The functionality of the promoter region was monitored by coupling it to the bacterial gene coding for chloramphenicol acetyltransferase (CAT) and assaying the expression of the enzyme in cells transfected with this vector. The glucocerebrosidase promoter not only directs synthesis of the bacterial enzyme but also exhibits the same pattern of tissue-specific expression as that of the endogenous gene. An apparently tightly linked pseudogene is approximately 96% homologous to the functional gene. However, introns 2, 4, 6, and 7 have large "deletions" consisting of Alu sequences 313, 626, 320, and 277 bp in length, respectively. It is entirely possible that the ancestral gene lacks these sequences and that they have been inserted into the introns of the functioning gene. There is also a 55-bp deletion from a part of exon 9 flanked by a short inverted repeat. The sequence data should facilitate development of methods for diagnosis of Gaucher disease at the molecular level.     

Retroviral and pseudogene insertion sites reveal the lineage of human salivary and pancreatic amylase genes from a single gene during primate evolution.

We have analyzed the junction regions of inserted elements within the human amylase gene complex. This complex contains five genes which are expressed at high levels either in the pancreas or in the parotid gland. The proximal 5'-flanking regions of these genes contain two inserted elements. A gamma-actin pseudogene is located at a position 200 base pairs upstream of the first coding exon. All of the amylase genes contain this insert. The subsequent insertion of an endogenous retrovirus interrupted the gamma-actin pseudogene within its 3'-untranslated region. Nucleotide sequence analysis of the inserted elements associated with each of the five human amylase genes has revealed a series of molecular events during the recent history of this gene family. The data indicate that the entire gene family was generated during primate evolution from one ancestral gene copy and that the retroviral insertion activated a cryptic promoter.     

Head-to-head arrangement of murine type IV collagen genes

The genes for the two dissimilar subunits of type IV collagen are organized in a head-to-head manner with their translation initiation codons within 874 base pairs. Murine genomic clones which contain portions of both genes have been isolated and characterized. These clones contain the first exon of the alpha 1(IV) chain and the first 3 exons for the alpha 2(IV) chain within a 1.7-kilobase HindIII fragment. The intergenic region appears not to resemble previously described bidirectional promoters. The HindIII fragment is present as a single copy in the mouse genome ruling out the presence of one of these gene fragments as a pseudogene. These findings agree with linkage studies of these two genes and differ from the known organization of human fibrillar collagen genes which have been found to be dispersed within the human genome.