Gene/Protein Disease Symptom Drug Enzyme Compound
Pivot Concepts:   Target Concepts:
Query: EC:3.6.1.3 (ATPase)
 65,361 document(s) hit in 31,850,051 MEDLINE articles (0.00 seconds)

Although the gene defects for several mouse mutants with severe osteopetrosis are known, the genes underlying human infantile malignant recessive osteopetrosis remain elusive. Osteopetrosis is thought to be caused by a defect in osteoclast function. These cells degrade bone material in a tightly sealed extracellular compartment that is acidified by a vacuolar (V)-type H(+)-ATPase. Genes encoding components of the acidification machinery are candidate genes for osteopetrosis. In five of ten patients with infantile malignant osteopetrosis, we now demonstrate five different mutations in OC116, the gene encoding the a3 subunit of the V-ATPase from osteoclasts. Two independent patients were homozygous for mutations that predict a total loss of function by severely truncating the protein. By affecting a splice site, another homozygous mutation deletes 14 amino acids within the N-terminus, which interacts with other subunits of the proton pump. On the other hand, in four patients no mutations were found, and one patient from a consanguineous family did not show homozygosity at the OC116 locus, suggesting that mutations in at least one different gene may underlie osteopetrosis. Our work shows that mutations in the gene encoding the a3 subunit of the proton pump are a rather common cause of infantile osteopetrosis and suggests that this disease is genetically heterogeneous.
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PMID:Mutations in the a3 subunit of the vacuolar H(+)-ATPase cause infantile malignant osteopetrosis. 1094 35

Solubilization of bone mineral by osteoclasts depends on the formation of an acidic extracellular compartment through the action of a V-type ATPase. We previously cloned a gene encoding a putative osteoclast-specific proton pump subunit, termed OC-116 kDa, approved mouse Atp6i (ATPase, H+ transporting, [vacuolar proton pump] member I). The function of Atp6i as osteoclast-specific proton pump subunit was confirmed in our mouse knockout study. However, the transcription regulation of Atp6i remains largely unknown. In this study, the gene encoding mouse Atp6i and the promoter have been isolated and completely sequenced. In addition, the temporal and spatial expressions of Atp6i have been characterized. Intrachromosomal mapping studies revealed that the gene contains 20 exons and 19 introns spanning approximately 11 kilobases (kb) of genomic DNA. Alignment of the mouse Atp6i gene exon sequence and predicted amino acid sequence to that of the human reveals a strong homology at both the nucleotide (82%) and the amino acid (80%) levels. Primer extension assay indicates that there is one transcription start site at 48 base pairs (bp) upstream of the initiator Met codon. Analysis of 4 kb of the putative promoter region indicates that this gene lacks canonical TATA and CAAT boxes and contains multiple putative transcription regulatory elements. Northern blot analysis of RNAs from a number of mouse tissues reveals that Atp6i is expressed predominantly in osteoclasts, and this predominant expression was confirmed by reverse-transcription polymerase chain reaction (RT-PCR) assay and immunohistochemical analysis. Whole-mount in situ hybridization shows that Atp6i expression is detected initially in the headfold region and posterior region in the somite stage of mouse embryonic development (E8.5) and becomes progressively restricted to anterior regions and the limb bud by E9.5. The expression level of Atp6i is largely reduced after E10.5. This is the first report of the characterizations of Atp6i gene, its promoter, and its gene expression patterns during mouse development. This study may provide valuable insights into the function of Atp6i, its osteoclast-selective expression, regulation, and the molecular mechanisms responsible for osteoclast activation.
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PMID:Characterization of mouse Atp6i gene, the gene promoter, and the gene expression. 1139 91

A case of infantile malignant osteopetrosis is described. The patient died from respiratory hemorrhage at 7 months of age despite treatment that included high doses of active vitamin D and administration of interferon-gamma. A postmortem examination revealed the presence of many osteoclasts in the bone, which lacked ruffled borders. This observation was consistent with the histology of bone reported in Atp6i-knockout mice, which lack the gene encoding the a3 subunit of vacuolar-type H(+)-adenosine triphosphatase (ATPase). Sequence analysis of the TCIRG1 gene encoding the a3 subunit revealed two novel mutations: a deletion/insertion mutation in exon 9 and a T-to-C transition at the splice donor site of intron 19. The former mutation caused a frame shift and premature stop codon. The latter was associated with abnormal splicing, which was confirmed by sequencing the products amplified by reverse transcription-polymerase chain reaction (RT-PCR), using total RNA from the liver specimen as template. Although several mutations in the TCIRG1 gene in infantile malignant osteopetrosis have been reported in other populations, this is the first case of a Japanese patient with a mutation identified in this gene. These results support the important role of the subunit in the function of the proton pump.
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PMID:Novel mutations in the a3 subunit of vacuolar H(+)-adenosine triphosphatase in a Japanese patient with infantile malignant osteopetrosis. 1185 54

Osteopetrosis is a heterogeneous group of inherited disorders that includes a malignant autosomal recessive form, an intermediate autosomal recessive form and autosomal dominant forms of the disease. Most malignant osteopetroses have been ascribed to mutations in the OC116 gene encoding the human a3 subunit of vacuolar H(+)-ATPase. Few cases of autosomal recessive malignant osteopetrosis have been ascribed to mutations in the chloride channel 7 gene (CLCN7), which accounts for all autosomal dominant type II cases reported to date. Up until now, however, nothing has been known regarding the molecular basis of the intermediate form of osteopetrosis (IARO). Our study of two Portuguese IARO families shows that homozygosity for ClCN7 mutations also accounts for this form of osteopetrosis. The two patients presented with spontaneous fractures in the first years of life and generalised increase of bone density. Direct sequencing of the ClCN7 gene in both patients revealed homozygosity for two mutations (G203D and P470Q). We conclude therefore that ClCN7 mutations not only account for some dominant and malignant forms but also for intermediate forms of osteopetrosis.
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PMID:Chloride channel 7 (CLCN7) gene mutations in intermediate autosomal recessive osteopetrosis. 1252 60

Osteopetroses are a heterogeneous group of human genetic diseases characterized by generalized increase in bone density due either to a decreased osteoclast population, defect in osteoclast function, or both. Current knowledge of the pathogenesis suggests defects that may be either intrinsic to osteoclast-monocyte lineage or extrinsic to the mesenchymal cells that support osteoblast ontogeny and activation. Four clinically distinct forms of human osteopetroses currently recognized are the infantile malignant autosomal recessive form, the intermediate autosomal recessive form, the adult benign autosomal dominant osteopetrosis type I, and the autosomal dominant osteopetrosis type II. Propensity to fracture is high in all types of osteopetrosis, and other characteristic clinical problems include hematologic and metabolic abnormalities, infections of affected bone, and neurologic sequela. Among the infantile malignant clinical forms 50-60% of patients present with defects in the OC116-KDa (also refers to ATP6i, TCIRGI, a3) subunit of the osteoclast vacuolar H+-ATPase (V-H+-ATPase) proton pump. Approaches that have been applied to the treatment of osteopetrosis include those aimed at stimulating host osteoclasts. These approaches however have met with little success, and it would appear that the future for the successful treatment of osteopetrosis lies with bone marrow transplantation. Various animal models mimicking some of the clinical subtypes of osteopetrosis have been generated in efforts to elicit further understanding of the pathogenesis. This review is an update on the various phenotypic presentations of human osteopetroses alongside their known animal models. Further studies on these animal models will not only expand our basic understanding of the molecular mechanisms of osteopetroses, but will also aid our ability to develop therapeutic means of intervention in diseases involving osteopetroses.
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PMID:Human osteopetroses and the osteoclast V-H+-ATPase enzyme system. 1597 May 48

Maturation stage ameloblasts of rodents express vacuolar type-H-ATPase in the ruffled border of their plasma membrane in contact with forming dental enamel, similar to osteoclasts that resorb bone. It has been proposed that in ameloblasts this v-H-ATPase acts as proton pump to acidify the enamel space, required to complete enamel mineralization. To examine whether this v-H-ATPase in mouse ameloblasts is a proton pump, we determined whether these cells express the lysosomal, T-cell, immune regulator 1 (Tcirg1, v-H-Atp6v(0)a(3)), which is an essential part of the plasma membrane proton pump that is present in osteoclasts. Mutation of this subunit in Tcirg1 null (or oc/oc) mice leads to severe osteopetrosis. No immunohistochemically detectable Tcirg1 was seen in mouse maturation stage ameloblasts. Strong positive staining in secretory and maturation stage ameloblasts however was found for another subunit of v-H-ATPase, subunit b, brain isoform (v-H-Atp6v(1)b(2)). Mouse osteoclasts and renal tubular epithelium stained strongly for both Tcirg1 and v-H-Atp6v(1)b(2). In Tcirg1 null mice osteoclasts and renal epithelium were negative for Tcirg1 but remained positive for v-H-Atp6v(1)b(2). The bone in these mutant mice was osteopetrotic, tooth eruption was inhibited or delayed, and teeth were often morphologically disfigured. However, enamel formation in these mutant mice was normal, ameloblasts structurally unaffected and the mineral content of enamel similar to that of wild type mice. We concluded that Tcirg1, which is essential for osteoclasts to pump protons into the bone, is not appreciably expressed in maturation stage mouse ameloblasts. Our data suggest that the reported v-H-ATPase in maturation stage ameloblasts is not the typical osteoclast-type plasma membrane associated proton pump which acidifies the extracellular space, but rather a v-H-ATPase potentially involved in intracellular acidification.
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PMID:Murine ameloblasts are immunonegative for Tcirg1, the v-H-ATPase subunit essential for the osteoclast plasma proton pump. 2224 29