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Query: UNIPROT:Q00604 (
X-linked
)
16,883
document(s) hit in 31,850,051 MEDLINE articles (0.00 seconds)
The
Wiskott-Aldrich syndrome
(
WAS
) is an
X-linked
disease characterized by eczema, thrombocytopenia, and profound immunodeficiency in affected males. While the etiology of the syndrome is currently unknown, abnormalities of CD43 have been described as a biochemical marker of the disease. Several investigators have demonstrated alterations in the expression of the CD43 surface antigen on
WAS
hematopoietic cells, noting either absence, decreased levels or changes in the characteristic molecular weight of the protein on the lymphocytes of affected patients. Biochemical studies have further indicated that glycosylating activity of specific enzymes which may post-translationally modify CD43 is altered in both T cells and Epstein-Barr-virus (EBV)-transformed B cells in
WAS
patients when compared to unaffected controls. Here we present data on cells derived from two males with a clinical diagnosis of
WAS
. Analysis of genomic DNA from the mothers of each of these patients (obligate carriers) showed a nonrandom X-chromosome inactivation pattern of nucleated blood cells, confirming the diagnosis of the
X-linked
syndrome. CD43 was characterized on peripheral blood lymphocytes and long-term EBV-transformed B cell lines, both to further analyze the molecular defects of
WAS
, as well as to attempt to generate a reproducible method for disease detection. Surprisingly, surface expression, molecular weight and two-dimensional gel analysis failed to demonstrated any reproducible differences in the CD43 expression, whether from disease or normal lymphocytes. Such results suggest possible heterogeneity of this syndrome.
...
PMID:CD43 is expressed normally on Wiskott-Aldrich-derived lymphocytes. 133 89
Seven forms of
X-linked
(XL) immunodeficiency have been described (XL agammaglobulinemia, XL severe combined immunodeficiency [SCID],
Wiskott-Aldrich syndrome
, XL chronic granulomatous disease, XL hyper-IgM syndrome with low IgG and IgA, and XL lymphoproliferative syndrome), and properdine deficiency. Although there are (some) phenotypic variants, diagnosis is relatively simple on the basis of clinical, immunological, and genetic characteristics. We studied a family in which several males were affected by severe infections and whose pedigree suggested recessive XL inheritance of an immunodeficiency. Immunologic and genetic studies (X inactivation patterns in females and restriction fragment length polymorphism [RFLP] segregation) were performed in order to characterize the immunodeficiency. The propositus, a 5-yr-old boy, was found to have a severe and progressive T- and B-cell functional immunodeficiency characterized by defective antigen-specific responses. No lymphocyte subsets or membrane anomalies were detected and the immunodeficiency did not correspond to usual XL forms. Studies of DNA from two of the informative females, the mother and one sister revealed nonrandom X chromosome inactivation of T cells and, partially, B cells but not PMN, a pattern similar to that observed in XL SCID carriers. RFLP studies identified a haplotype segregating with the abnormal locus that may be localized in the proximal part of the long arm of the X chromosome. We thus report the characterization of a new XL immunodeficiency that may correspond either to another XL locus or to an attenuated phenotype of XL SCID.
...
PMID:Genetic study of a new X-linked recessive immunodeficiency syndrome. 134 96
Whole-blood cells of obligate carriers of the
X-linked
Wiskott-Aldrich syndrome
(
WAS
) exhibit nonrandom inactivation of the X-chromosomes. However, because of the limited polymorphism of the probes available, the X-methylation pattern can only be determined in a restricted proportion of females. We thus analysed a large set of normal females and members of
WAS
families, using the recently described marker M27 beta, which detects the hyperpolymorphic locus DXS255. The probe was used to detect differences in methylation between the active and inactive X-chromosome, and the findings were compared with the pattern obtained using the well-documented probes from the 5' end of the PGK and HPRT genes. All the normal females were found to use either X-chromosome randomly, and there was complete correlation between the three probes in the populations studied. Segregation analysis performed with M27 beta and other related markers in the
WAS
families was fully in accordance with the X-inactivation data. The use of M27 beta, for both X-inactivation and segregation analysis of
WAS
kindreds, provides a basis for genetic counselling in the majority of families, including those with no surviving males.
...
PMID:Wiskott-Aldrich syndrome carrier detection with the hypervariable marker M27 beta. 135 Feb 64
The
Wiskott-Aldrich syndrome
(
WAS
) is a severe immunodeficiency and platelet deficiency disease arising from an
X-linked
defect. The disease is correctable by transplantation of hematopoietic stem cells, but the product of the defective gene is unidentified and the number of defects in patient blood cells is large. The current hurdle is the need to identify the early pathogenic event(s) that are the cause of other defects. As a step toward this goal, we have generated and examined a panel of interleukin 2-dependent allospecific T cell lines from peripheral lymphocytes of seven
WAS
patients and five normal individuals.
WAS
cell lines, like normal lines, undergo vigorous proliferation when challenged with specific allostimulant or with phorbol myristate acetate and ionomycin. Both normal and
WAS
T cell lines express cell surface molecules CD2, CD3, T cell receptor-alpha/beta, human histocompatibility leukocyte antigen class I, CD45 and CD11a, and varying ratios of CD4 and CD8, and are negative for natural killer cell and monocyte surface molecules.
WAS
T cell lines express CD43 (sialophorin/leukosialin) with molecular weight and in an amount comparable with normal T cell lines.
WAS
T cell lines thus do not express defects in CD43 (decreased amount, abnormal molecular weight), previously documented in
WAS
circulating lymphocytes. On the other hand, as detected by scanning electron microscopy,
WAS
cell lines exhibit severe morphological abnormalities, including decreased size and density of the microvillus surface projections. The morphological abnormalities of
WAS
T cell lines are similar to, or more extensive than, those previously reported for
WAS
peripheral lymphocytes, indicating that the generation of morphological (cytoarchitectural) defects is an early pathogenic event in this disease. The findings suggest that the gene that is defective in the
WAS
encodes a protein that normally functions to maintain or regulate the cytoskeletal structure of blood cells.
...
PMID:T cell lines characterize events in the pathogenesis of the Wiskott-Aldrich syndrome. 151 49
The molecular bases of the
X-linked
immunodeficiency diseases remain largely undetermined. Two of the genes involved in these diseases have been isolated, namely the genes for
X-linked
chronic granulomatous disease and properdin deficiency, and substantial progress has now been made in identifying the genes which are defective in the other five diseases,
Wiskott-Aldrich syndrome
, X-linked severe combined immunodeficiency, X-linked agammaglobulinaemia,
X-linked
hyper-IgM and X-linked lymphoproliferative syndrome. We review here the nature of the diseases, progress made in identifying and isolating the genes involved and the prospects for improved prenatal detection, carrier status determination and treatment of these life-threatening conditions.
...
PMID:The molecular basis of X-linked immunodeficiency disease. 152 25
The
Wiskott-Aldrich syndrome
(
WAS
) is an inherited disease involving defects of platelets (small size, severe thrombocytopenia due to accelerated destruction) and T lymphocytes (progressive immunodeficiency, lymphopenia). The best-characterized molecular defect is the deficiency and, in some cases, abnormal forms of the T-lymphocyte surface mucin molecule CD43; deficiency of the platelet surface mucin GPIb was observed previously in two of four patients. Neither of these defects is primary, since CD43 and GPIb are encoded by autosomal genes and the disease is
X-linked
. This study uses cellular biological approaches to explore the possibility that destruction of structurally defective
WAS
platelets, mimicked experimentally by sonication of normal platelets, plays a role by releasing protease and generating other cellular defects. We show that a protease of normal platelets, identified as Ca(2+)-dependent neutral protease (calpain), which is known to cleave platelet GPIb, also specifically cleaves CD43 on the surface of neighboring desialylated T lymphocytes. The identification of the CD43 cleaving protease was based on its requirement for Ca2+ and inhibition by leupeptin, but not by diisopropylfluorophosphate (DFP). The approximate site of CD43 cleavage was identified by the use of a rabbit antibody. Sensitivity of GPIb to calpain is shown to be sialylation-independent and that of CD43 to be sialylation-dependent, and these findings are explained in terms of molecular structures. These and previous findings are incorporated into a putative mechanism, which explains most of the defects in the
WAS
. The mechanism suggests that the primary defective molecule in the
WAS
is unlikely to be a surface glycoprotein, but rather a cytoplasmic molecule with a function in cytoskeletal interactions and/or calcium ion regulation and calpain activation.
...
PMID:Effect of platelet calpain on normal T-lymphocyte CD43: hypothesis of events in the Wiskott-Aldrich syndrome. 155 70
Although the
X-linked
immunodeficiencies--X-linked agammaglobulinemia (XLA), X-linked severe combined immunodeficiency (XSCID),
Wiskott-Aldrich syndrome
(
WAS
), X-linked lymphoproliferative syndrome and
X-linked
hyper IgM syndrome--have been mapped to loci distributed throughout the X chromosome, they have several features in common that suggest that they might be members of a gene family: (i) all are maintained in the population at approximately the same gene frequency; (ii) expression of each defect is limited to the hematopoietic system; (iii) atypical forms of each disorder have been described; and (iv) obligate carriers of these disorders are normal by all immunologic criteria. The failure of carriers of XLA, XSCID, and
WAS
to show signs of their gene defects can be explained by the preferential use of the normal, nonmutant X as the active X in the cell lineages affected by the gene defects. These three disorders also share an additional feature; in boys with XLA, XSCID, or
WAS
there is asynchronous expression of cell surface markers of differentiation or activation. If some or all of the genes that are abnormal in the
X-linked
immunodeficiencies are members of a gene family, then isolation of one gene may lead to the others.
...
PMID:Molecular approaches to analysis of X-linked immunodeficiencies. 159 Sep 86
The
Wiskott-Aldrich Syndrome
(
WAS
) is a rare
X-linked
immunohematological disorder characterized by eczema, profound thrombocytopenia, and progressive immunodeficiency. Severe hemorrhage, overwhelming sepsis, or lymphoreticular malignancy usually cause death in childhood. Recently, bone marrow transplantation (BMT) has been curative in some well-established cases, but there is no general agreement about the place of BMT in infants with
WAS
before the development of significant immunological abnormalities. We describe the successful use of early histocompatible BMT in a 10-month-old infant in whom
WAS
was diagnosed on the basis of eczema, thrombocytopenia, small platelets, and raised serum immunoglobulin A (Ig) and IgE, but before the development of immunodeficiency as evidenced clinically by recurrent infections, or immunologically by low serum IgM or consistently abnormal lymphocyte responses to mitogens. After an unstable period for several weeks posttransplantation when he developed marked hepatomegaly and severe interstitial pneumonitis, he made a good recovery. His eczema and thrombocytopenia resolved and he has shown no clinical or laboratory evidence of immunodeficiency. It is now over 2 years since his BMT. Because of the poor prognosis of
WAS
, where a histocompatible donor is available, BMT at the earliest opportunity, despite the inherent risks of such a procedure, may be the best option for an infant with
WAS
.
...
PMID:Early bone marrow transplantation in an infant with Wiskott-Aldrich syndrome. 179 57
While inherited
X-linked
(XL) isolated thrombocytopenia is a mild condition, the
Wiskott-Aldrich syndrome
(
WAS
) associates severe thrombocytopenia with an immunodeficiency component and has a poor prognosis. Whether these conditions correspond to separate genetic entities or to different mutations of the same gene(s) remains unresolved. The
Wiskott-Aldrich syndrome
locus has been assigned to Xp 11.2 by means of RFLP studies. The X-inactivation pattern in female carriers has been found to follow a skewed pattern in the hematopoietic cells, thus allowing carrier detection. We studied a family with four members affected by XL thrombocytopenia and report the results of genetic segregation analysis, together with the X-inactivation pattern of hematopoietic cells from an obligate female carrier. Although the affected locus mapped to the same region as that of
WAS
, lymphocytes presented a skewed pattern of X-inactivation, whereas polymorphonuclear lymphocytes (PMN) did not. These results provide further evidence that the
Wiskott-Aldrich syndrome
and XL thrombocytopenia are different expressions of mutations within a single locus and that the severity of the disease corresponds to distinct hematopoietic cell selections in obligate carriers.
...
PMID:X-linked thrombocytopenia and Wiskott-Aldrich syndrome: similar regional assignment but distinct X-inactivation pattern in carriers. 191 30
The gene for the
Wiskott-Aldrich syndrome
, an
X-linked
immunodeficiency disease, has been mapped between the RFLP markers DXS7 and DXS14 on the short arm of the X-chromosome. Close linkage to these markers permits accurate carrier detection and prenatal diagnosis. In one family with
WAS
patients in two generations, RFLP analysis was applied to three women at risk. It could be determined with more than 98.5% accuracy that these women were not carriers.
...
PMID:[Genetic carrier detection for the Wiskott-Aldrich syndrome using restriction fragment length polymorphism analysis]. 197 11
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