Plasma Membrane Calcium Pump Isoform 4a Has a Longer Calmodulin-Binding Domain Than 4b (original) (raw)
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Proceedings of the National Academy of Sciences, 1989
cDNA clones coding for human plasma membrane Ca2+ pump isoforms have been isolated from a fetal skeletal muscle cDNA library. Compared with the sequence of a teratoma cDNA-encoded pump these clones specify isoforms that contain either 29- or 38-amino acid insertions within the calmodulin-binding region. Replacement of two basic arginine residues by an aspartic acid and a glutamine residue could influence the binding of calmodulin to these isoforms. RNase mapping shows that RNA species containing the 29-residue-encoding insertion are particularly abundant in skeletal muscles. The sequences coding for the insertions are present on a single 154-base-pair exon, as demonstrated by an analysis of the corresponding genomic region, and they are included in their respective mRNAs by alternative splicing involving the differential usage of two internal "cryptic" donor splice sites in the presence of a nearby canonical one. Inclusion of the complete 154-base-pair exon results in an m...
Journal of Biological Chemistry, 1999
A reconstitution system allowed us to measure the ATPase activity of specific isoforms of the plasma membrane Ca 2؉ pump continuously, and to measure the effects of adding or removing calmodulin. The rate of activation by calmodulin of isoform 4b was found to be very slow, with a half-time (at 235 nM calmodulin and 0.5 M free Ca 2؉ ) of about 1 min. The rate of inactivation of isoform 4b when calmodulin was removed was even slower, with a half-time of about 20 min. Isoform 4a has a lower apparent affinity for calmodulin than 4b, but its activation rate was surprisingly faster (half time about 20 s). This was coupled with a much faster inactivation rate, consistent with its low affinity. A truncated mutant of isoform 4b also had a more rapid activation rate, indicating that the downstream inhibitory region of fulllength 4b contributed to its slow activation. The results indicate that the slow activation is due to occlusion of the calmodulin-binding domain of 4b, caused by its strong interaction with the catalytic core. Since the activation of 4b occurs on a time scale comparable to that of many Ca 2؉ spikes, this phenomenon is important to the function of the pump in living cells. The slow response of 4b indicates that this isoform may be the appropriate one for cells which respond slowly to Ca 2؉ signals.
The Ca2+ affinity of the plasma membrane Ca2+ pump is controlled by alternative splicing
The Journal of biological chemistry, 1994
The plasma membrane Ca2+ pump is a calmodulin-regulated P-type ATPase that is an essential element in controlling intracellular Ca2+ concentration. Studies on the gene structure of this pump have revealed an alternate splice option that changes the structure of the calmodulin-binding domain. This change in the structure of the enzyme results in a reduced calmodulin affinity. Tests of the enzyme's activity in the presence of a high calmodulin concentration, approximating that found inside living cells, show that this reduced calmodulin affinity causes a reduced apparent affinity of the enzyme for Ca2+. This shift in the Ca2+ activation occurs in a Ca2+ concentration range crucial to cellular function and is probably the physiologically important consequence of the alternate splice.
Plasma Membrane Ca2+ Pump Isoforms 2a and 2b Are Unusually Responsive to Calmodulin and Ca2+
Journal of Biological Chemistry, 1997
The full-length a and b variants of the rat plasma membrane calcium pump, isoform 2 (rPMCA2a and rPMCA2b), were constructed and expressed in COS-7 cells. To characterize these isoforms, calcium transport was determined in a microsomal fraction. Both rPMCA2a and rPMCA2b had a much higher affinity for calmodulin than the corresponding forms of hPMCA4, and rPMCA2b had the highest affinity among the isoforms that have been tested so far. When analyzed at a relatively high calmodulin concentration, rPMCA2b and, to a lesser extent, rPMCA2a showed higher apparent calcium affinity; i.e. they were more active at lower Ca 2؉ concentrations than hPMCA4b. This indicates that these two variants of rat isoform 2 will tend to maintain a lower free cytosolic Ca 2؉ level in cells where they are expressed. Both variants also showed a higher level of basal activity (in the complete absence of calmodulin) than hPMCA4b, a property which would reinforce their ability to maintain a low free cytosolic Ca 2؉ concentration. Experiments designed to determine the source of the higher apparent Ca 2؉ affinity of rPMCA2b showed that it came from the properties of the carboxyl terminus, rather than from any difference in the catalytic core.
Journal of Biological Chemistry, 2007
The inhibition by the regulatory domain and the interaction with calmodulin (CaM) vary among plasma membrane calcium pump (PMCA) isoforms. To explore these differences, the kinetics of CaM effects on PMCA4a were investigated and compared with those of PMCA4b. The maximal apparent rate constant for CaM activation of PMCA4a was almost twice that for PMCA4b, whereas the rates of activation for both isoforms showed similar dependence on Ca 2؉. The inactivation of PMCA4a by CaM removal was also faster than for PMCA4b, and Ca 2؉ showed a much smaller effect (2versus 30-fold modification). The rate constants of the individual steps that determine the overall rates were obtained from stopped-flow experiments in which binding of TA-CaM was observed by changes in its fluorescence. TA-CaM binds to two conformations of PMCA4a, an "open" conformation with high activity, and a "closed" one with lower activity. Compared with PMCA4b (
European Journal of Biochemistry, 1992
cDNA species covering the entire coding sequence of the human homologue of the rat plasma membrane Ca2 +-ATPase (PMCA) isoform 2 have been isolated and characterized. The deduced amino acid sequence shows 99% identity with that of the rat protein and can be aligned with the latter without gaps except for one 14-amino-acid-residue insert in the region immediately preceding the putative phospholipid-sensitive domain in the human pump. cDNA clones isolated by anchored polymerase-chain reaction revealed additional microheterogeneity in the same N-terminal PMCA2coding region. Alternative RNA splicing involving a region of 135 nucleotides generates three types of cDNA. One does not contain any of the 135 bp, and the other two contain 42 bp or the entire 135 bp of the optional sequence. Analysis of genomic DNA indicates that this sequence is encoded by three separate exons of 33, 60 and 42 bp. Although each of these exons could be inserted into the mRNA without changing the reading frame, polymerase-chain amplifications using cDNA libraries from several human tissues show that the 33-bp and the 60-bp exons are never independently used during splicing. The unequal distribution of the splice variants suggests tissue-specific regulation of the alternative-splicing pathways and indicates a functional specialization of the encoded isoform subtypes.
Role of Alternative Splicing in Generating Isoform Diversity Among Plasma Membrane Calcium Pumps
Physiological Reviews, 2001
Calcium pumps of the plasma membrane (also known as plasma membrane Ca2+-ATPases or PMCAs) are responsible for the expulsion of Ca2+ from the cytosol of all eukaryotic cells. Together with Na+/Ca2+ exchangers, they are the major plasma membrane transport system responsible for the long-term regulation of the resting intracellular Ca2+concentration. Like the Ca2+ pumps of the sarco/endoplasmic reticulum (SERCAs), which pump Ca2+ from the cytosol into the endoplasmic reticulum, the PMCAs belong to the family of P-type primary ion transport ATPases characterized by the formation of an aspartyl phosphate intermediate during the reaction cycle. Mammalian PMCAs are encoded by four separate genes, and additional isoform variants are generated via alternative RNA splicing of the primary gene transcripts. The expression of different PMCA isoforms and splice variants is regulated in a developmental, tissue- and cell type-specific manner, suggesting that these pumps are functionally adapted to...
Journal of Biological Chemistry, 2009
Using solution NMR spectroscopy, we obtained the structure of Ca 2؉-calmodulin (holoCaM) in complex with peptide C28 from the binding domain of the plasma membrane Ca 2؉-ATPase (PMCA) pump isoform 4b. This provides the first atomic resolution insight into the binding mode of holoCaM to the full-length binding domain of PMCA. Structural comparison of the previously determined holoCaM⅐C20 complex with this holoCaM⅐C28 complex supports the idea that the initial binding step is represented by (holoCaM⅐C20) and the final bound complex by (holoCaM⅐C28). This affirms the existing multi-step kinetic model of PMCA4b activation by CaM. The complex exhibits a new binding motif in which holoCaM is wrapped around helical C28 peptide using two anchoring residues from the peptide at relative positions 18 and 1. The anchors correspond to Phe-1110 and Trp-1093, respectively, in fulllength PMCA4b, and the peptide and CaM are oriented in an anti-parallel manner. This is a greater sequence distance between anchors than in any of the known holoCaM complexes with a helical peptide. Analysis of the geometry of holoCaMpeptide binding for the cases where the target peptide adopts an ␣ D-helix with its anchors buried in the main hydrophobic pockets of the two CaM lobes establishes that only relative sequential positions of 10, 14, 17, and 18 are allowed for the second anchor. Plasma membrane Ca 2ϩ-ATPases (PMCAs) 3 are crucial components of Ca 2ϩ regulation in eukaryotic cells. In mammals, four isoforms (PMCA1-4) and numerous splice variants are involved
Journal of Biological Chemistry, 2007
The inhibition by the regulatory domain and the interaction with calmodulin (CaM) vary among plasma membrane calcium pump (PMCA) isoforms. To explore these differences, the kinetics of CaM effects on PMCA4a were investigated and compared with those of PMCA4b. The maximal apparent rate constant for CaM activation of PMCA4a was almost twice that for PMCA4b, whereas the rates of activation for both isoforms showed similar dependence on Ca 2؉. The inactivation of PMCA4a by CaM removal was also faster than for PMCA4b, and Ca 2؉ showed a much smaller effect (2versus 30-fold modification). The rate constants of the individual steps that determine the overall rates were obtained from stopped-flow experiments in which binding of TA-CaM was observed by changes in its fluorescence. TA-CaM binds to two conformations of PMCA4a, an "open" conformation with high activity, and a "closed" one with lower activity. Compared with PMCA4b (