A gene from the Xp22.3 region shares homology with voltage-gated chloride channels

In the framework of constructing a comprehensive transcript map of the human Xp22.3 region, we identified an evolutionary conserved CpG island and cloned the corresponding gene. The predicted 760 amino acid protein encoded by this gene contains 12 hydrophobic domains and shares significant sequence and structural similarities with all the previously isolated members of a recently identified family of voltage-gated chloride channels (the 'CIC family'). This gene, termed CICN4 (Chloride Channel 4), contains at least 10 exons spanning 60 to 80 kb on the X chromosome. In contrast to most genes isolated from the human Xp22.3 region, the CICN4 gene does not share homology with the Y chromosome and it is conserved in mouse and hamster. Expression studies revealed the presence of a 7.5 kb transcript which is particularly abundant in skeletal muscle and is also detectable in brain and heart. These data suggest that we have identified a new voltage-gated chloride channel which is encoded by a gene located in the distal short arm of the X chromosome.

Deletion spanning the 5' ends of both the COL4A5 and COL4A6 genes in a patient with Alport's syndrome and leiomyomatosis

Alport's syndrome is characterized clinically by a nonimmune glomerulopathy, often accompanied by sensorineural hearing loss and lens abnormalities, frequently due to mutations in the COL4A5 gene. The association of AS with diffuse leiomyomatosis, a benign proliferation of smooth muscle that occurs most often in the esophagus, trachea, and female genitalia, has been reported. Recently, a deletion involving both the COL4A5 and COL4A6 genes has been reported in four unrelated families. We report an additional case with Alport's syndrome associated with leiomyomatosis carrying a deletion of both COL4A5 and COL4A6 genes. A detailed characterization of the genomic region involved in the deletion event has been performed. Our results demonstrate that the deletion removed exon 1 of COL4A5 and exons 1 and 2 of COL4A6.

The genes for X-linked ocular albinism (OA1) and microphthalmia with linear skin defects (MLS): cloning and characterization of the critical regions

We have used cell lines from patients with deletions and translocations involving the Xp22 region to map the genes for two X-linked disorders, ocular albinism type 1 (OA1) and microphthalmia with linear skin defects (MLS). Using existing and newly isolated DNA markers, the map position within Xp22 of key patient breakpoints, defining the boundaries of the genomic regions involved in these disorders (the critical regions), has been precisely determined. A 2.6 Mb yeast artificial chromosome (YAC) contig, spanning the critical regions for these two disorders, was assembled. Detailed long-range restriction analysis of the contig established the sizes of the critical regions to be 200 kb for OA1 and 800 - 925 kb for MLS. Ten potential CpG-islands, representing candidate sites for genes, have been mapped within the 2.6 Mb region. Our data should greatly facilitate efforts aimed at cloning the genes for these developmental defects.

A high resolution deletion map of human chromosome Xp22

We have developed a 32-interval deletion panel for human chromosome Xp22 spanning about 30 megabases of genomic DNA. DNA samples from 50 patients with chromosomal rearrangements involving Xp22 were tested with 60 markers using a polymerase chain reaction strategy. The ensuing deletion map allowed us to confirm and refine the order of previously isolated and newly developed markers. Our mapping panel will provide the framework for mapping new sequences, for orienting chromosome walks in the region and for projects aimed at isolating genes responsible for diseases mapping to Xp22.

Human hnRNP protein A1 gene expression. Structural and functional characterization of the promoter

hnRNP protein A1 (34 kDa, pl 9.5) is a prominent member of the family of proteins (hnRNP proteins) that associate with the nascent transcripts of RNA polymerase II and that accompany the hnRNA through the maturation process and the export to the cytoplasm. New evidence suggests an active and specific role for some of these proteins, including protein A1, in splicing and transport. Contrary to the other hnRNP proteins, the intracellular level of protein A1 was reported to change as a function of proliferation state and cell type. In this work we analyse the A1 gene expression in different cells under different growth and differentiation conditions. Proliferation dependent expression was observed in lymphocytes and fibroblasts while purified neurons express high A1 mRNA levels both in the proliferative (before birth) and in the quiescent (after birth) state. Transformed cell lines exhibit very high (proliferation independent) A1 mRNA levels compared to differentiated tissues. A structural and functional characterization of the A1 gene promoter was carried out by means of DNase I footprinting and CAT assays. The observed promoter features can account for both elevated and regulated mRNA transcription. At least 12 control elements are contained in the 734 nucleotides upstream of the transcription start site. Assays with the deleted and/or mutated promoter indicate a co-operation of multiple transcriptional elements, distributed over the entire promoter, in determining the overall activity and the response to proliferative stimuli (serum).

Assignment of the human heterogeneous nuclear ribonucleoprotein A1 gene (HNRPA1) to chromosome 12q13.1 by cDNA competitive in situ hybridization

Heterogeneous nuclear ribonucleoprotein (HNRP) core protein A1 is a major component of mammalian HNRP particles. The human HNRP A1 protein was shown to be encoded by a 4.6-kb gene, split into 10 exons, belonging to a multigene family of about 30 A1-specific sequences per haploid genome, many of which correspond to pseudogenes of the processed type. Here we report the mapping of the human HNRPA1 gene to band 12q13.1. Localization was performed by nonisotopic in situ hybridization using a phage genomic clone that contains the active HNRPA1 gene as well as 13.5-kb flanking sequences. To suppress hybridization to pseudogene sequences, unlabeled HNRPA1 cDNA was added in excess over the probe to the hybridization mixture.

Alternative splicing in the human gene for the core protein A1 generates another hnRNP protein

The human hnRNP core protein A1 (34 kd) is encoded by a 4.6 kb gene split into 10 exons. Here we show that the A1 gene can be differentially spliced by the addition of an extra exon. The new transcript encodes a minor protein of the hnRNP complex, here defined A1B protein, with a calculated mol. wt of 38 kd, that coincides with a protein previously designated as B2 by some authors. In vitro translation of the mRNAs selected by hybridization with A1 cDNA produced two proteins of 34 and 38 kd; Northern blot analysis of poly(A)+ RNA from HeLa cells revealed that the abundance of the A1B mRNA was approximately 5% that of A1. The A1B protein was detected by Western blotting with an anti-A1 monoclonal antibody both in enriched preparations of basic hnRNP proteins and in 40S hnRNP particles. The A1B protein exhibits a significantly higher affinity than A1 for ssDNA. The recombinant A1B protein, expressed in Escherichia coli, shows the same electrophoretic mobility and charge as the cellular one.

Isolation of an active gene encoding human hnRNP protein A1. Evidence for alternative splicing

Heterogeneous nuclear ribonucleoprotein (hnRNP) core protein A1 is a major component of mammalian hnRNP 40 S particles. We describe the structure of an active A1 gene and report on the partial characterization of the A1 gene family. About 30 A1-specific sequences are present per haploid human genome: 15 such sequences were isolated from a human genomic DNA library. Many corresponded to pseudogenes of the processed type but by applying a selection for actively transcribed regions we isolated an active A1 gene. The gene spans a region of 4.6 x 10(3) base-pairs and it is split into ten exons that encode the 320 amino acid residues of the protein. The amino acid sequence derived from the exon sequences is identical with that deduced from cDNA and reported for the protein. One intron exactly separates the two structural domains that constitute the protein. Each of the two RNA-binding domains in protein A1 is encoded by one exon. Experimental evidence indicates that the A1 gene can encode for more than one protein by alternative splicing. The gene is preceded by a strong promoter that contains at least two CCAAT boxes and two possible Sp1 binding sites, but it lacks a TATA box.

cDNA cloning of human hnRNP protein A1 reveals the existence of multiple mRNA isoforms

Protein A1 is one of the major component of mammalian ribonucleoprotein particles (hnRNP). Human protein A1 cDNA cloning and sequencing revealed the existence of at least two protein isoforms. Among the cDNAs examined, sequence differences were found both in the structural portion, leading to aminoacid changes (Tyr to Phe or Arg to Lys) and in the non translated 3'-region where two T-stretches of different length were observed. Interestingly one of the aminoacid substitutions falls into a consensus sequence common to many RNA binding proteins. Northern blot analysis of poly A+ RNAs from five human tissues revealed two mRNA forms of 1500 and 1900 n due to alternative polyadenylation. Analysis of genomic DNA showed at least 30 A1-specific sequences, some of which correspond to processed pseudogenes. These results suggest that protein A1 is encoded by a multigene family.

Molecular cloning of Bacillus subtilis genes involved in DNA metabolism

Different clones carrying a chromosomal DNA fragment able to transform Bacillus subtilis mutants dnaA13, dnaB19, dnaG5, recG40 and polA42 to a wild-type phenotype were isolated from a library constructed in plasmid pJH101. A lambda recombinant clone carrying a chromosomal fragment able to transform dnaC mutants was obtained from a lambda Charon 4A library. A restriction map of the cloned DNA fragments was constructed. The 11.3 kb cloned DNA fragment of plasmid pMP60-13 containing the wild-type sequence of dnaG5 was shown to transform a recF33 mutant as well.