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Query: UMLS:C0004134 (
ataxia
)
15,886
document(s) hit in 31,850,051 MEDLINE articles (0.00 seconds)
Atp2b2 encodes the plasma membrane Ca(2+)-ATPase type 2 (
PMCA2
) expressed in various tissues, including stereocilia of cochlear and vestibular hair cells, cerebellar Purkinje cells, and lactating mammary epithelia. Mutations of the gene lead to deafness,
ataxia
, and reduced Ca(2+) levels in milk. Heterozygous mutants also have abnormal hearing, suggesting that precise regulation of Atp2b2 is required for normal function. In this study, we describe Atp2b2 5'-untranslated region genomic structure and transcript usage in mice. Using 5'-rapid amplification of cDNA ends, we observed four transcripts: types alpha, beta, mu and delta, each splicing into a common ATG-containing exon. Types alpha and beta correspond to previously published mammalian cDNA sequences. Types mu and delta constitute novel 5'-untranslated region sequences, and were observed at high levels only in lactating mammary gland. Using real-time reverse transcriptase polymerase chain reaction, we quantified relative transcript usage across several tissues. We show that alpha and beta are abundant throughout the CNS, as well as the cochlea. When we microdissected the cochlea into hair cell and spiral ganglion containing fractions, we found that cochlear hair cell expression is mediated through the type alpha transcript. In situ hybridization studies in cerebellum using exon-specific probes revealed that alpha dominates in Purkinje neurons, while beta is enriched in cerebellar granule neurons. We compared 5'-untranslated region sequence across multiple species, and found high conservation around the first exons for alpha and beta in mammals, but not other species. The regions around the mu and delta first exons are highly conserved between rat and mouse, but less so with other species. Our results show that expression of Atp2b2 is highly regulated, using four different transcriptional start regions, two of which are differentially expressed in neuronal tissue. This suggests that unique regulatory mechanisms are used to control Atp2b2 expression in different types of cells.
...
PMID:Atp2b2, encoding plasma membrane Ca2+-ATPase type 2, (PMCA2) exhibits tissue-specific first exon usage in hair cells, neurons, and mammary glands of mice. 1667 32
PMCA2
, a major calcium pump, is expressed at particularly high levels in Purkinje neurons. Accordingly,
PMCA2
-null mice exhibit
ataxia
suggesting cerebellar pathology. It is not yet known how changes in
PMCA2
expression or activity affect molecular pathways in Purkinje neurons. We now report that the levels of metabotropic glutamate receptor 1 (mGluR1), which plays essential roles in motor coordination, synaptic plasticity, and associative learning, are reduced in the cerebellum of
PMCA2
-null mice as compared to wild type littermates. The levels of inositol 1,4,5-triphosphate receptor type 1 (IP3R1), an effector downstream to mGluR1, which mediates intracellular calcium signaling, and the expression of Homer 1b/c and Homer 3, scaffold proteins that couple mGluR1 to IP3R1, are also reduced in somata and dendrites of some Purkinje cell subpopulations. In contrast, no alterations occur in the levels of mGluR1 and its downstream effectors in the hippocampus, indicating that the changes are region specific. The reduction in cerebellar mGluR1, IP3R1 and Homer 3 levels are neither due to a generic decrease in Purkinje proteins nor extensive dendritic loss as immunoreactivity to total and non-phosphorylated neurofilament H (NFH) is increased in Purkinje dendrites and microtubule associated protein 2 (MAP2) staining reveals a dense dendritic network in the molecular layer of the
PMCA2
-null mouse cerebellum.
PMCA2
coimmunoprecipitates with mGluR1, Homer 3 and IP3R1, suggesting that the calcium pump is a constituent of the mGluR1 signaling complex. Our results suggest that the decrease in the expression of mGluR1 and its downstream effectors and perturbations in the mGluR1 signaling complex in the absence of
PMCA2
may cumulatively result in aberrant metabotropic glutamate receptor signaling in Purkinje neurons leading to cerebellar deficits in the
PMCA2
-null mouse.
...
PMID:Molecular alterations in the cerebellum of the plasma membrane calcium ATPase 2 (PMCA2)-null mouse indicate abnormalities in Purkinje neurons. 1715 Mar 72
The plasma membrane calcium ATPase (PMCA) uses energy to pump calcium (Ca2+) ions out of the cytosol into the extracellular milieu, usually against a strong chemical gradient. This energy expenditure is necessary to maintain a relatively low intracellular net Ca2+ load. Mammals have four genes (ATP2B1-ATP2B4), encoding the proteins PMCA1 through PMCA4. Transcripts from each of these genes are alternatively spliced to generate several variant proteins that are in turn post-translationally modified in a variety of ways. Expressed ubiquitously and with some level of functional redundancy in most vital tissues, only one of the four genes--Atp2b2--has been causally linked through naturally occuring mutations to disease in mammals: specifically to deafness and
ataxia
in spontaneous mouse mutants. In humans, a missense amino acid substitution in
PMCA2
modifies the severity of hearing loss. Targeted null mutations of the Atp2b1 and Atp2b4 genes in mouse are embryonic lethal and cause a sperm motility defect, respectively. These phenotypes point to complex human diseases like hearing loss, cardiac function and infertility. Changes in PMCA expression are associated with other diseases including cataract formation, carciniogenesis, diabetes, and cardiac hypertension and hypertrophy. Severity of these diseases may be affected by subtle changes in expression of the PMCA isoforms expressed in those tissues.
...
PMID:The plasma membrane calcium ATPase and disease. 1819 44
Plasma membrane Ca(2+)-ATPases (PMCAs) are high-affinity calcium pumps that contribute to the maintenance of intracellular Ca(2+) homeostasis by exporting Ca(2+) from the cytosol to the extracellular environment. Mammals have four genes encoding the proteins PMCA1 through PMCA4. Each gene transcript is alternatively spliced to generate several variants. Their distribution is tissue- and cell-specific and undergoes regulation during cell development and differentiation. Traditionally, these pumps have been considered to play a housekeeping role in controlling basal Ca(2+) levels, but more recently, it became clear that the presence (and the co-expression) of different isoforms must be related to a more specialized function. Only one of the four genes (encoding
PMCA2
) has been causally linked to disease in mammals: Several spontaneous mutations are responsible for deafness and
ataxia
. Other complex human disease phenotype like hearing loss, cardiac function, and infertility are likely to be associated with PMCA function, but no spontaneous mutations in other PMCA genes than
PMCA2
are so far identified. The evidence of their involvement in disease phenotypes comes from studies on isoform-specific knockout mice. In this review, I will discuss briefly the general role of PMCA as essential component of Ca(2+) homeostasis machinery and focus on its emerging role as signaling molecule with particular attention on the diseases caused by PMCA dysfunction.
...
PMID:Plasma membrane Ca(2+)-ATPase: from a housekeeping function to a versatile signaling role. 1854 70
The Ca(2+) ATPases of the plasma membrane (PMCA pumps) export Ca(2+) from all eukaryotic cells. In mammals they are the products of four separate genes. PMCA types 1 and 4 are distributed ubiquitously; PMCA types 2 and 3 are restricted to some tissues, the most important being the nervous system. Alternative splicing at two sites greatly increases the number of pump isoforms. The two ubiquitous isoforms are no longer considered as only housekeeping pumps as they also perform tissue-specific functions. The PMCAs are classical P-type pumps, their reaction cycle repeating that of all other pumps of the family. Their 3D structure has not been solved, but molecular modeling on SERCA pump templates shows the essential structural pattern of the latter. PMCAs are regulated by calmodulin, which interacts with high affinity with their cytosolic C-terminal tail. A second calmodulin-binding domain with lower affinity is present in some splicing variants of the pump. The PMCAs are essential to the regulation of cellular Ca(2+), but the all-important Ca(2+) signal is ambivalent: defects in its control generate various pathologies, the most thoroughly studied being those of genetic origin. Genetic defects of PMCA function produce disease phenotypes: the best characterized is a form of deafness in mice and in humans linked to
PMCA2
mutations. A cerebellar X-linked human
ataxia
has recently been found to be caused by a mutation in the calmodulin-binding domain of PMCA3.
...
PMID:The plasma membrane calcium pump in health and disease. 2341 90
Mice with genetic deletion of a calcium extrusion pump, the plasma membrane calcium ATPase isoform 2,
PMCA2
, exhibit overt cerebellar ataxia, but the cellular mechanisms are only partially understood. Here, we report an enhanced synaptic GABAergic inhibition within the molecular layer of cerebellar cortex slices from
PMCA2
knockout (
PMCA2
(-/-)) mice, a finding that could contribute to the observed
ataxia
. Purkinje neurons from
PMCA2
(-/-) mice exhibited an increased frequency and amplitude of spontaneous inhibitory post-synaptic currents that was accompanied by an enhanced spontaneous firing frequency of molecular layer interneurons (both basket cells and stellate cells). The elevated inhibition was sufficient to reduce the frequency and regularity of spike firing by
PMCA2
(-/-) Purkinje neurons. Acute pharmacological inhibition of PMCA recapitulated some of these features in wild-type mice indicating that the changes were in part a direct result of
PMCA2
removal. However, additional compensatory mechanisms within the
PMCA2
(-/-) mouse were also a major factor. Indeed, morphological studies revealed an abnormally large number of molecular layer interneurons (basket cells and stellate cells) and GABAergic synapses within the
PMCA2
(-/-) cerebellar cortex. We conclude that loss of
PMCA2
adversely influences the function and organisation of Purkinje neuron synaptic inhibition as a major contributory mechanism to the ataxic phenotype of the
PMCA2
(-/-) mouse.
...
PMID:Enhanced synaptic inhibition in the cerebellar cortex of the ataxic PMCA2(-/-) knockout mouse. 2356 8
