The lipoprotein lipase-encoding human gene: sequence from intron-6 to intron-9 and presence in intron-7 of a 40-million-year-old Alu sequence

The complete nucleotide sequence of the 3877-bp segment spanning the 3′ region of intron-6 to the 5′ region of intron-9 of the human lipoprotein lipase (LPL)-encoding ten-exon gene, LPL, is reported. An Alu repeat present in intron-7 was found by sequence analysis to belong to the 40–55-million-year-old Alu-Se subclass.     

Complete Genomic Sequence of the Human Retinoblastoma Susceptibility Gene

A 180,388-bp contig encompassing the human retinoblastoma gene was sequenced in its entirety. Partial analysis of the sequence revealed (1) a high (A + T)/(G + C) ratio and a high density of Line-1 (L1) repeat sequences, suggesting that the locus maps to G-bands 13q14.12 or 13q14.2; (2) Alu repeats that are asymmetrically oriented over a region extending 87 kb; (3) an overabundance of non-Alu-associated poly(A) tracts 10 bp or larger oriented in the antisense rather than the sense direction (36 vs 6); (4) an Alu sequence nested within an L1 repeat, indicating that the expansion of L1 repeats predates at least some of the Alu expansions; (5) at least three newly discovered microsatellite polymorphisms, one of which was subsequently found to be identical to a polymorphism in a microsatellite-based linkage map of the human genome published by another group; and (6) the basis of previously discovered intragenic RFLPs. This sequence should enhance studies of this locus and of the organization of the human genome.     

Alu elements of the primate major histocompatibility complex

The chromosomal region constituting the major histocompatibility complex (MHC) has undergone complex evolution that is often difficult to decipher. An important aid in the elucidation of the MHC evolution is the presence of Alu elements (repeats) which serve as markers for tracing chromosomal rearrangements. As the first step toward the establishment of sets of evolutionary markers for the MHC, Alu elements present in selected MHC haplotypes of the human species, the gorilla, and the chimpanzee were identified. Restriction fragments of cosmid clones from the libraries of the three species were hybridized with Alu-specific probes, Alu elements were amplified by the polymerase chain reaction, and the amplification products were sequenced. In some cases, sequences of the regions flanking the Alu elements were also obtained. Altogether, 31 new Alu elements were identified, representing six Alu subfamilies. The average density of Alu elements in the MHC is one element per four kilobases (kb) of sequence. Alu elements have apparently been inserted steadily into the MHC over the last 65 million years (my). On average, one Alu element is inserted into the primate MHC every 4 my. Analysis of the human DR3 haplotype supports its origin by duplication from an ancestral haplotype consisting of DRB1 and DRB2 genes. The sharing of an old Alu element by the DRB1 and DRB2 genes, in turn, supports their divergence from a common ancestor more than 55 my ago.     

Recombinations between Alu repeat sequences that result in partial deletions within the C1 inhibitor gene

Genomic DNA sequence analysis was used to define the extent of deletions within the C1 inhibitor gene in two families with type I hereditary angioneurotic edema. Southern blot analysis initially indicated the presence of the partial deletions. One deletion was approximately 2 kb and included exon VII, whereas the other was approximately 8.5 kb and included exons IV–VI. Genomic libraries from an affected member of each family were constructed and clones containing the deletions were analyzed. Sequence analysis of the deletion joints of the mutants and corresponding regions of the normal gene in the two families demonstrated that both deletion joints resulted from recombination of two Alu repetitive DNA elements. Alu repeat sequences from introns VI and VII combined to make a novel Alu in family A, and Alu sequences in introns III and VI were spliced to make a new Alu in family B. The splice sites in the Alu sequences of both mutants were located in the left arm of the Alu element, and both recombination joints overlapped one of the RNA polymerase III promoter sequences. Because the involved Alu sequences, in both instances, were oriented in the same direction, unequal crossingover is the most likely mechanism to account for these mutations.     

The Human Cystathionine β-Synthase (CBS) Gene: Complete Sequence, Alternative Splicing, and Polymorphisms

Cystathionine β-synthase [CBS; -serine hydro-lyase (adding homocysteine), EC 4.2.1.22] catalyzes the first committed step of transsulfuration and is the enzyme deficient in classical homocystinuria. In this report, we describe the molecular cloning and the complete nucleotide sequence of the human CBS gene. We report a total of 28,046 nucleotides of sequence, which, in addition to the CBS gene, contains 5 kb of the 5′ flanking region. The human CBS gene contains 23 exons ranging from 42 to 209 bp. The 5′ UTR is formed by 1 of 5 alternatively used exons and 1 invariably present exon, while the 3′ UTR is encoded by exons 16 and 17. We also describe the identification of two alternatively used promoter regions that are GC rich (80%) and contain numerous putative binding sites for Sp1, Ap1, Ap2, and c-myb, but lack the classical TATA box. The CBS locus contains an unusually high number ofAlurepeats, which may predispose this gene to deleterious rearrangements. Additionally, we report on a number of DNA sequence repeats that are polymorphic in North American and European Caucasians.     

Isolation of the CD7 gene from the DNA of transfected L cells

Using DNA from L cells which expressed high levels of the CD7 (Leu-9 or HuLy-m2) antigen obtained after two cycles of transfection, a genomic library was constructed in the lambda phage Charon 4A. Recombinant clones containing the gene coding for this antigen were identified by first screening the library with both the HSVtk gene and a probe detecting the human repetitive (Alu) sequences. DNA from 10 tk⁺ and 12 Alu⁺ recombinant clones was used to transfect L cells which were analyzed for the cell-surface expression of CD7 either early (48–72 h posttransfection) or later when hypoxanthine aminopterin thymidine-resistant colonies were obtained. Transfection with either Alu⁺ or tk⁺ recombinant phages led to transient early expression of CD7, and stable CD7⁺ transfectants were also established. Thus the CD7 gene has been isolated in a number of clones in association with either the Alu repetitive sequence or with the HSV-tk gene; the insert size in one of the genomic clones was 13.5 kb.     

A large Alu-mediated deletion, identified by PCR, as the molecular basis for glycogen storage disease Type II (GSDII)

Glycogen storage disease type II (GSDII) is an autosomal recessive disorder resulting from inherited deficiency of the enzyme lysosomal acid α-glucosidase. Over 40 different mutations have been described but no large deletions have been previously identified. We now describe a homozygous large (9-kb) deletion extending from IVS15 to 4 kb downstream of the terminal exon (exon 20), detected by polymerase chain reaction (PCR)-based methods. The deletion was initially suspected because of failure to amplify a contiguous group of exons by PCR. We hypothesized an Alu/Alu recombination, based on our prior demonstration by Southern blotting of Alu elements in the regions potentially flanking the deletion. Additional sequence analysis of genomic fragments confirmed the presence of Alu elements and allowed the design of flanking primers for PCR amplification. Amplification resulted in a smaller than normal fragment (0.7 vs 10 kb) in homozygosity in the proband and in heterozygosity in her parents. Cloning and sequencing of the smaller than normal 0.7-kb deletion fragment revealed an Alu/Alu deletion junction. In heterozygosity this deletion would not be detected by currently standard PCR mutation detection methods. Based on other Alu-mediated deletions, this deletion is likely to be recurrent and should be screened for in all non-consanguineous GSDII patients, particularly when only one mutation has been identified and none of the 12 single-nucleotide polymorphisms in the deleted region are heterozygous. These observations also suggest that initial characterization of genes at disease-causing loci should include a search for Alu and other repetitive elements to facilitate subsequent PCR-based mutation analysis. Received: 24 August 1998 / Accepted: 13 November 1998     

The Structure and Organization of the Human Erythroid Anion Exchanger (AE1) Gene

The AE1 (anion exchanger, band 3) protein is expressed in erythrocytes and in the A-type intercalated cells of the kidney distal collecting tubule. In both cell types it mediates the electroneutral transport of chloride and bicarbonate ions across the lipid bilayer, and, in erythrocytes, it also serves as the critical attachment site of the peripheral membrane skeleton. We have characterized the human AE1 gene using overlapping clones isolated from a phage library of human genomic DNA. The gene spans 20 kb and consists of 20 exons separated by 19 introns. The structure of the human AE1 gene corresponds closely with that of the previously characterized mouse AE1 gene, with a high degree of conservation of exon/intron junctions, as well as exon and intron nucleotide sequences. The putative upstream and internal promoter sequences of the human AE1 gene used in erythroid and kidney cells, respectively, are described. We also report the nucleotide sequence of the entire 3′ noncoding region of exon 20, which was lacking in the published cDNA sequences. In addition, we have characterized 9 Alu repeat elements found within the body of the human AE1 gene that are members of 4 related subfamilies that appear to have entered the genome at different times during primate evolution.     

Cloning of the rat steroid sulfatase gene (Sts), a non-pseudoautosomal X-linked gene that undergoes X inactivation

Although the human steroid sulfatase (STS) gene has been cloned and characterized in detail, several attempts to clone its mouse homologue, with either anti-human STS antibodies or human STS cDNA probes, have failed, suggesting a substantial divergence between these genes. However, partial amino-terminal sequence from purified rat liver STS is very similar to its human counterpart, and sequence comparisons have revealed several domains that are conserved among all the sulfatases characterized to date. Thus, we used a degenerate-primer RT-PCR approach to amplify a 321-bp fragment from rat liver cDNA, which was used as a probe to clone and characterize the complete cDNA. Comparison of the protein coding region between the rat and human genes showed 66% homology both at the DNA and the protein levels. STS activity was conferred to STS(−) A9 cells upon transfection with a rat Sts expression construct, indicating the authenticity of the cloned cDNA. While Sts has been shown to be located in the mouse pseudoautosomal region, both physical and genetic mapping demonstrate that Sts is not pseudoautosomal in the rat. The overall genomic organization of rat Sts and human STS is very similar, except that the insertion site for intron 1 in the rat is 26 bp upstream from that in the human. Rat Sts is only 8.2 kb long, while the human STS spans over 146 kb. Received: 24 October 1995 / Accepted: 5 March 1996     

Molecular cloning, primary structure, and expression of the human growth factor-activatable Na+/H+ antiporter

We present the complete sequence of a cDNA encoding the human amiloride-sensitive Na+/H+ antiporter. After functional complementation of a mouse fibroblast mutant by gene transfer, we isolated a 0.8 kb genomic probe from a third-cycle mouse transformant. The probe detects gene amplification in Na+/H+ antiporter "overexpressers" and a single class of mRNA of ca. 5.6 kb in human, mouse, and hamster cells. With this probe we isolated a 4 kb cDNA from a library constructed from a mouse transformant in which the transfected human gene was amplified. This cDNA includes a noncoding leader of 407 bp, a 2682 bp open reading frame, and a 3' noncoding sequence containing a mouse B1 repeated element. The amino acid sequence predicts a protein of Mr = 99,354 with an N-terminal amphipathic domain that contains 10 putative transmembrane-spanning segments and two potential glycosylation sites, followed by a hydrophilic stretch of 395 residues, presumably cytoplasmic. Stable expression of the transfected cDNA in Na+/H+ antiporter-deficient cells restored the key functional features of this transporter: H+i-activated Na+ influx, amiloride sensitivity, and pHi regulation.     

The association between HLA-A alleles and an Alu dimorphism near HLA-G

The AluYb8 sequences are a subfamily of short interspersed Alu retroelements that have been amplified within the human genome during recent evolutionary time and are useful polymorphic markers for studies on the origin of human populations. We have identified a new member of the Yb8 subfamily, AluyHG, located between the HLA-H and -G genes and 88-kb telomeric of the highly polymorphic HLA-A gene within the alpha block of the major histocompatibility complex (MHC). The AluyHG element was characterised with a view to examining the association between AluyHG and HLA-A polymorphism and reconstructing the history of the MHC alpha block. A specific primer pair was designed for a simple PCR assay to detect the absence or presence (dimorphism) of the AluyHG element within the DNA samples prepared from a panel of 46 homozygous cell-lines containing complete or recombinant ancestral haplotypes (AH) of diverse ethnic origin and 92 Caucasoid and Asian subjects on which HLA-A typing was available. The AluyHG insertion was most strongly associated with HLA-A2 and, to a lesser degree with HLA-A1, -A3, -A11, and A-19. The gene frequency of the AluyHG insertion for 146 Caucasians and 94 Chinese-Han was 0.30 and 0.32 and there was no significant difference between the observed and expected frequencies. The results of the association studies and the phylogenetic analysis of HLA-A alleles suggest that the AluyHG sequence was integrated within the progenitor of HLA-A2, but has been transferred by recombination to other human ancestral populations. In this regard, the dimorphic AluyHG element is an important diagnostic marker for HLA association studies and could help in elucidating the evolution and functions of the MHC alpha block and polymorphism within and between ancestral haplotypes. Received: 7 December 2000 / Accepted: 28 February 2001     

Sequence analysis of pig switch μ, Cμ, and Cμm

 The complete sequence of pig switch μ (Sμ) and the various domains of Cμ, a total of ca 8 kilobases (kb) of sequence, are presented and comparatively analyzed. Sμ starts about 2.5 kb downstream of the single pig J _H gene and ends 0.4 kb upstream of Cμ; the length of Sμ is 3.2 kb. Three major pentameric repeats, gagct, gggct, and gggtt, comprise more than half of the entire Sμ sequence. The two most frequent decamers are gagctgagct and gagctgggct. The longest single repeated sequence is 93 base pairs. The frequency of the various pentamers indicates that pig Sμ is more similar to human Sμ than to mouse Sμ. Received: 23 November 1996 / Revised: 21 April 1997     

Glycation of lens MIP26 affects the permeability in reconstituted liposomes.

We studied the role of glycation of lens putative gap junctional protein, MIP26, on the permeability as well as on calmodulin mediated gating activity in reconstituted liposomes. Calf lens membranes were incubated with 0-100 mM glucose for 3 days and MIP26 was isolated. There was a glucose concentration dependent increase in the glycation of MIP26 which reached to 2.48 moles/mole of protein with 100 mM glucose. Gel electrophoresis showed that there was no degradation of MIP26 to MIP22 during incubation. Channel permeability was determined by reconstituting MIP26 into asolectin liposomes. There was a MIP26 glycation dependent decrease in the permeability to sucrose. Furthermore, proteoliposomes containing nonglycated MIP26 showed complete uncoupling of the channels with calmodulin whereas the channels containing glycated MIP26 were only partially uncoupled. These results suggest that glycation of MIP26 does interfere with the gating activity in reconstituted liposomes.     

Structure and sequence of the human α- -iduronidase gene

In humans, a deficiency of the lysosomal hydrolase α- -iduronidase (IDUA; EC 3.2.1.76) results in the lysosomal storage of the glycosaminoglycans heparan sulfate and dermatan sulfate, thereby causing the lysosomal storage disorder mucopolysaccharidosis type I. The gene for IDUA is split into 14 exons spanning approximately 19 kb. We report the sequence of two noncontiguous segments of the IDUA gene, one 1.8-kb segment containing exons 1 and 2 and surrounding sequences and a second segment of 4.5 kb containing the last 12 exons. The potential promoter for IDUA has only GC box type consensus sequences consistent with a housekeeping promoter and is bounded by an Alu repeat sequence. The first two exons of IDUA are separated by an intron of 566 bp, then there is a large intron of approximately 13 kb, and the last 12 exons are clustered within 4.5 kb. No consensus polyadenylation signal was found in the 3′ untranslated region, although two variant polyadenylation signals are proposed.