Gene regulation of Wiskott-Aldrich syndrome protein and the human homolog of the Drosophila Su(var)3-9: WASP and SUV39H1, two adjacent genes at Xp11.23.

The region Xp11.23 is a gene-rich, light giemsa-staining segment on the short arm of the X chromosome. In this study, we have characterized the transcriptional regulatory elements in this interval for two adjacent genes: SUV39H1, a regulator of chromatin organization, and the Wiskott-Aldrich syndrome protein (WASP). The WASP gene exhibits two alternate promoters, both of which demonstrate transcription factor binding elements specific to blood cell lineages. Reporter gene expression analyses indicate that both WASP promoters show high levels of expression in different hematopoietic cell lines. The human homolog of the Drosophila Su(var)3-9 gene was identified by sequence analysis of the region downstream from WASP. SUV39H1 is ubiquitously expressed, and the promoter sequence consists mostly of general transcription factors. The presence of putative binding sites for GAGA and Adf1 transcription factors may indicate a cross regulatory mechanism with other chromatin regulators.

The identification and characterization of two promoters and the complete genomic sequence for the Wiskott-Aldrich syndrome gene.

The Wiskott-Aldrich syndrome (WAS) is an X-linked disorder characterized by immunodeficiency, eczema and thrombocytopenia. The gene responsible for WAS was identified through positional cloning, and the function of the encoded protein (WASP) is still the subject of much speculation. WASP is currently thought to be involved in the regulation of actin polymerization in hematopoietic cells. To study the elements that regulate the WASP gene, we have identified the sites for transcription initiation. We found that two promoters were responsible for controlling WASP expression. Multiple transcription initiation sites were found immediately adjacent to the translation start site, however an alternate exon with a second promoter region was identified 6 kb upstream. Examination of the 5' sequence adjacent to the initiation sites in both promoters failed to reveal a TATA or CCAAT box, but numerous putative transcription factor binding sites including Sp1, Ets, c-Myb and PU.1 were apparent. Reporter constructs generated from each promoter showed functional activity in the Jurkat T-cell and HEL erythro-megakaryocytic cell lines. Although the alternate exon sequence was extremely GC rich and contained several potential binding elements, the primary promoter was stronger than the upstream promoter in the cell lines assayed. The transcription factor binding site profiles within each promoter suggested that they may play different roles in regulating WASP expression depending on the stage of differentiation and development, and the cell lineage. In this study we have also reported the complete nucleotide sequence of the coding and intervening sequences for the WASP gene. A comprehensive knowledge of the genomic structure and the further characterization of WASP gene expression will facilitate the continued investigation of mutations in WAS patients, and the eventual prospect of gene therapy.

ABI sequencing analysis. Manipulation of sequence data from the ABI DNA sequencer.

The ABI Sequencing Analysis application is designed specifically for the analysis of data produced by the ABI DNA Sequencer. The ABI sequencer is a laser-based instrument that utilizes fluorescent labels to analyze the products of a sequencing reaction as they migrate through a gel. After the data are collected from a sequencing run, the Analysis program identifies and tracks the sample lanes of the gel and subsequently normalizes and integrates the raw data into a chromatogram of the final sequence. For the user, there are basically two types of files that can be manipulated to potentially improve the analysis results. The Gel File consists of a computer generated image of the sequencing gel with the fluorescent DNA banding patterns. This image allows the user to view and edit the tracking lines generated and used by Analysis to collect data points for each sample. Individual Sample Files are stored for each of the samples analyzed and include the chromatogram, raw data, and annotations and information regarding the sample and sequence run. Generally, the products of a sequencing reaction are easily resolved and the Analysis software interprets the correct nucleotide sequence. Ambiguous base calls tend to occur near the end of the sequence and may be either edited or deleted by the user before exporting the data for further comparisons or alignments. Occasionally the tracking lines within the gel image may need to be adjusted or moved. The sample data are then reextracted from the Gel File and analyzed again. This review explains the general operation of Analysis in terms of viewing and editing a chromatogram, retracking the lanes of a Gel File, and analyzing the final sample data. The three versions 1.2.1, 2.1.2, and 3.3 are discussed.

Wiskott-Aldrich syndrome protein-deficient mice reveal a role for WASP in T but not B cell activation.

The Wiskott-Aldrich syndrome (WAS) is a human X-linked immunodeficiency resulting from mutations in a gene (WASP) encoding a cytoplasmic protein implicated in regulating the actin cytoskeleton. To elucidate WASP function, we disrupted the WASP gene in mice by gene-targeted mutation. WASP-deficient mice showed apparently normal lymphocyte development, normal serum immunoglobulin levels, and the capacity to respond to both T-dependent and T-independent type II antigens. However, these mice did have decreased peripheral blood lymphocyte and platelet numbers and developed chronic colitis. Moreover, purified WASP-deficient T cells showed markedly impaired proliferation and antigen receptor cap formation in response to anti-CD3epsilon stimulation. Yet, purified WASP-deficient B cells showed normal responses to anti-Ig stimulation. We discuss the implications of our findings regarding WASP function in receptor signaling and cytoskeletal reorganization in T and B cells and compare the effects of WASP deficiency in mice and humans.

Variable expression of WASP in B cell lines of Wiskott-Aldrich syndrome patients.

The Wiskott-Aldrich syndrome (WAS) arises from defects of the X-chromosome gene WASP. Severe platelet defects, thrombocytopenia with small platelets, are a hallmark of the disease, but clinical immunodeficiency based in lymphocyte dysfunction varies from negligible to life threatening among WAS patients. To address the connection between WASP mutations and clinical outcomes, we generated and characterized a panel of patient B cell lines. Three cell lines from patients with exon 2 missense mutations and mild immune dysfunction were found to express substantial levels of WASP mRNA and protein. On the other hand, 8 of 10 cell lines from patients with moderate or severe immune dysfunction lack detectable WASP protein. The findings suggest that the clinical variability of the WAS can partially be explained by the level of WASP protein in the patient's cells.

Mutation analysis of the gene encoding Bruton's tyrosine kinase in a family with a sporadic case of X-linked agammaglobulinemia reveals three female carriers.

Bruton's tyrosine kinase (Btk) has been identified as the protein responsible for the primary immunodeficiency X-linked agammaglobulinemia (XLA). We and others have cloned the gene for Btk and recently reported the genomic organization. Nineteen exons were positioned within the 37 kb gene. With the sequence data derived from our genomic map, we have designed a PCR based assay to directly identify mutations of the Btk gene in germline DNA of patients with XLA. In this report, the assay was used to analyze a family with a sporadic case of XLA to determine if other female relatives carry the disease. A four base-pair deletion was found in the DNA of the affected boy and was further traced through three generations. With the direct identification of the mutations responsible for XLA, we can now diagnose conclusively the disease and identify the immunologically normal female carriers. This same technique can easily be applied to prenatal diagnosis in families where the mutation can be identified.

A high-resolution map of genes, microsatellite markers, and new dinucleotide repeats from UBE1 to the GATA locus in the region Xp11.23.

Several new genes and markers have recently been identified on the proximal short arm of the human X chromosome in the area of Xp11.23. We had previously generated a YAC contig in this region extending from UBE1 to the OATL1 locus. In this report two polymorphic dinucleotide repeats, DXS6949 and DXS6950, were isolated and characterized from the OATL1 locus. A panel of YAC deletion derivatives from the distal portion of the contig was used in conjunction with the rest of the YAC map to position the new microsatellites and order other markers localizing to this interval. The marker order was determined to be DXS1367-ZNF81-DXS6849-ZNF21-DXS6616-DXS 6950-DXS6949. In the proximal region below OATL1, we have isolated a pair of YACs from the GATA locus, B1026 and C01160. Mapping within these YACs indicates the orientation of DXS1126 and DXS1240, while a cosmid near the OATL1 region reveals the overlap between the YAC contigs from the two loci. This cosmid contains the gene responsible for Wiskott-Aldrich syndrome (WAS) and localizes the disease gene between OATL1 and GATA. These data enable the expansion of the present physical map of the X chromosome from UBE1 to the GATA locus, covering a large portion of the Xp11.23 region. Genetic cross-overs in Xp11.23 support the marker orientation and the position of WAS, contrary to previous reports. With the integration of both physical and genetic maps we have predicted the following marker order: Xpter-UBE1-SYN1/ARAF1/ TIMP1-DXS1367-ZNF81-DXS.6849-ZNF21-DXSy6616++ +-(OATL1, DXS6950-DXS6949)- WAS-(GATA, DXS1126)-DXS1240-Xcen.(ABSTRACT TRUNCATED AT 250 WORDS)

Identification of mutations in the Wiskott-Aldrich syndrome gene and characterization of a polymorphic dinucleotide repeat at DXS6940, adjacent to the disease gene.

The Wiskott-Aldrich syndrome (WAS) is an X-chromosome-linked recessive disease characterized by eczema, thrombocytopenia, and immunodeficiency. The disease gene has been localized to the proximal short arm of the X chromosome and recently isolated through positional cloning. The function of the encoded protein remains undetermined. In this study we have characterized mutations in 12 unrelated patients to confirm the identity of the disease gene. We have also revised the coding sequence and genomic structure for the WAS gene. To analyze further the transmittance of the disease gene, we have characterized a polymorphic microsatellite at the DXS6940 locus within 30 kb of the gene and demonstrate the inheritance of the affected alleles in families with a history of WAS.

Characterization of germline mutations of the gene encoding Bruton's tyrosine kinase in families with X-linked agammaglobulinemia.

Bruton's tyrosine kinase (Btk) has been identified as the protein responsible for the primary immunodeficiency X-linked agammaglobulinemia (XLA) and has been described as a new member of Src-related cytoplasmic protein tyrosine kinases. We have recently characterized the structure of the entire gene encoding Btk and developed a polymerase chain reaction (PCR)-based assay to detect germline mutations within it. In this report we describe six mutations, five of which are novel, of the Btk gene in patients with XLA and demonstrate the inheritance pattern of the defect within the families of the affected individuals. The mutations found include two nonsense and two missense mutations, a single base deletion at an intron acceptor splice site, and a 16-bp insertion. A single strand conformation polymorphism was also found in the 5' end of intron 8 with the same assay. This technique has provided a powerful tool for direct analysis of the Btk gene for the diagnosis of XLA and carrier detection. The identification of new mutations may eventually reveal the role of Btk in the signaling pathways involved in B-cell development.

Genomic organization of the Btk gene and exon scanning for mutations in patients with X-linked agammaglobulinemia.

The defective gene responsible for the recessively inherited immunodeficiency X-linked agammaglobulinemia (XLA) has been shown to encode a cytoplasmic protein tyrosine kinase of the Src family designated Btk (Bruton's tyrosine kinase). To facilitate the search for germline mutations of the Btk gene, we have characterized its genomic structure. Eighteen introns were positioned within the approximately 37 kb gene. Each of the exon/intron boundaries were defined and sequenced, and all but two conform to consensus sequences. We have utilized the genomic organization of Btk and the intervening sequence data to design an assay for amplifying each of the 19 exons from XLA patient DNA for single strand conformation polymorphism (SSCP) analysis. By using this method we have identified mutations in 12 of 14 unrelated affected males: seven different base substitutions and two small deletions. Two of the mutations described in exon 15 of the kinase domain were found in more than one patient and may represent a mutation hot spot. Exon scanning has proven to be a valuable method for identifying the patient mutations in genomic DNA without the use of cDNA. The mutations are easily confirmed with direct sequencing of the amplified exons. This approach will greatly benefit XLA family studies involving carrier detection and prenatal diagnosis. In addition, the mutations identified may reveal residues involved in the specific protein interactions necessary in the B-cell developmental pathway, of which Btk is an integral component.