1,721,018 research outputs found
The plasma membrane calcium pumps: focus on the role in (neuro)pathology
No full textThe plasma membrane Ca(2+) ATPase (PMCA pump) is a member of the superfamily of P-type pumps. It is organized in the plasma membrane with ten transmembrane helices and two main cytosolic loops, one of which contains the catalytic center. It also contains a long C-terminal tail that houses the binding site for calmodulin, the main regulator of the activity of the pump. The pump also contains a number of other regulators, among them acidic phospholipids, kinases, and numerous protein interactors. Separate genes code for 4 basic pump isoforms in mammals, additional isoform complexity being generated by the alternative splicing of primary transcripts. Pumps 1 and 4 are expressed ubiquitously, pumps 2 and 3 are tissue restricted, with preference for the nervous system. In essentially all cells, the pump coexists with much more powerful systems that clear Ca(2+) from the cytosol, e.g. the SERCA pump and the Na(+)/Ca(2+) exchanger. Its role in the global regulation of cellular Ca(2+) homeostasis is thus quantitatively marginal: its main function is the regulation of Ca(2+) signaling in selected sub-plasma membrane microdomains where Ca(2+) modulated interactors also reside. Malfunctions of the pump linked to genetic mutations are now described with increasing frequency, the disease phenotypes being especially severe in the nervous system where isoforms 2 and 3 predominate. The analysis of the pump defects suggests that the disease phenotypes are likely to be related to the imperfect modulation of Ca(2+) signaling in selected sub-plasma membrane microdomains, leading to the defective control of the activity of important Ca(2+) dependent interactors
Why calcium? How calcium became the best communicator.
No full textCalcium carries messages to virtually all important functions of cells. Although it was already active in unicellular organisms, its role became universally important after the transition to multicellular life. In this Minireview, we explore how calcium ended up in this privileged position. Most likely its unique coordination chemistry was a decisive factor as it makes its binding by complex molecules particularly easy even in the presence of large excesses of other cations, e.g. magnesium. Its free concentration within cells can thus be maintained at the very low levels demanded by the signaling function. A large cadre of proteins has evolved to bind or transport calcium. They all contribute to buffer it within cells, but a number of them also decode its message for the benefit of the target. The most important of these “calcium sensors” are the EF-hand proteins. Calcium is an ambivalent messenger. Although essential to the correct functioning of cell processes, if not carefully controlled spatially and temporally within cells, it generates variously severe cell dysfunctions, and even cell death
The human SLC8A3 gene and the tissue-specific Na+/Ca2+ exchanger 3 isoforms.
No full textWe have identified the human gene for member 3 of Solute Carrier family 8 (SLC8A3) by bioinformatic analysis of human genomic sequences. The gene is located on chromosome 14q24.2, and spans a region of about 150 kb. The full-length DNA complementary to RNA encoding the Na(+)/Ca(2+) exchanger isoform 3 (NCX3), amplified by reverse transcriptase-polymerase chain reaction (RT-PCR) from the human neuroblastoma SH-SY5Y RNA, includes seven exons and encodes a protein of about 100 kDa. RT-PCR analysis was performed in different tissues to determine the exon composition in the region encoding the large intracellular loop of the protein. The region underwent modifications by alternative tissue-specific splicing. NCX3.2, including exon 4 but not exon 5, was found in human brain and in the neuroblastoma cell line. In human skeletal muscle two additional isoforms were identified: NCX3.3, including exons 4 and 5, and a truncated isoform (NCX3.4) produced by the skipping of both exons 3 and 4. The skipping causes a frame shift downstream of the exon 2 sequence. The new coding sequence of 25 amino acids terminates with a stop codon in exon 6. The NCX3.4 isoform (68 kDa) is truncated in the C-terminal portion of the domain first found in Drosophila Na(+)/Ca(2+) exchanger domain (Calxbeta) and lacks the C-terminal hydrophobic segments
Control of the Na+/Ca2+ exchanger 3 promoter by cyclic adenosine monophosphate and Ca2+ in differentiating neurons
No full textThe human gene for member 3 of solute carrier family 8 (SLC8A3), encoding the Na+/Ca2+ exchanger isoform 3 (NCX3), was identified on chromosome 14q24.2. The minimal promoter region was predicted 250 bp upstream of exon 1. This was confirmed by luciferase reporter assays of pGL3-promoter constructs in transfected SH-SY5Y cells. The promoter activity was monitored during the differentiation of this cell line elicited by the sequential treatment with retinoic acid and brain-derived neurotrophic factor (BDNF). The activity was induced by cyclic AMP (cAMP) via the CRE (cAMP response element) and was stimulated by retinoic acid. The increase of intracellular Ca2+ induced by the partial depolarization of the plasma membrane with KCl down-regulated both the basal and the cAMP-stimulated transcription. The down-regulation of the latter may be mediated by the phosphorylation of the CRE-binding protein by a calmodulin-dependent kinase (CaMKII). The exposure of cells to BDNF after treatment with retinoic acid rapidly induced promoter activity during the initial five hours and phosphorylation of CRE-binding protein during the first two hours. The promoter activity was further enhanced by cAMP, but became insensitive to Ca2+. In BDNF-stimulated cells cAMP elevation caused the preferential phosphorylation of ATF1 instead of that of CRE-binding protein
The PMCA pumps in genetically determined neuronal pathologies
No full textCa2+ signals regulate most aspects of animal cell life. They are of particular importance to the nervous system, in which they regulate specific functions, from neuronal development to synaptic plasticity. The homeostasis of cell Ca2+ must thus be very precisely regulated: in all cells Ca2+ pumps transport it from the cytosol to the extracellular medium (the Plasma Membrane Ca2+ ATPases, hereafter referred to as PMCA pumps) or to the lumen of intracellular organelles (the Sarco/Endoplasmatic Reticulum Ca2+ ATPase and the Secretory Pathway Ca2+ ATPase, hereafter referred to as SERCA and SPCA pumps, respectively). In neurons and other excitable cells a powerful plasma membrane Na+/Ca2+ exchanger (NCX) also exports Ca2+ from cells. Quantitatively, the PMCA pumps are of minor importance to the bulk regulation of neuronal Ca2+. However, they are important in the regulation of Ca2+ in specific sub-plasma membrane microdomains which contain a number of enzymes that are relevant to neuronal function. The PMCA pumps (of which 4 basic isoforms are expressed in animal cells) are P-type ATPases that are characterized by a long C-terminal cytosolic tail which is the site of interaction with most of the regulatory factors of the pump, the most important being calmodulin. In resting neurons, at low intracellular Ca2+the C-terminal tail of the PMCA interacts with the main body of the protein keeping it in an autoinhibited state. Local Ca2+ increase activates calmodulin that removes the C-terminal tail from the inhibitory sites. Dysregulation of the Ca2+ signals are incompatible with healthy neuronal life. A number of genetic mutations of PMCA pumps are associated with pathological phenotypes, those of the neuron-specific PMCA 2 and PMCA 3 being the best characterized. PMCA 2 mutations are associated with deafness and PMCA 3 mutations are linked to cerebellar ataxias. Biochemical analysis of the mutated pumps overexpressed in model cells have revealed their decreased ability to export Ca2+. The defect in the bulk cytosolic Ca2+ homeostasis is minor, in keeping with the role of the PMCA pumps in the local control of Ca2+ in specialized plasma membrane microdomains
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