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14 results on '"Mazzitelli, Luciana R."'

10. Reduction of the P5A-ATPase Spf1p phosphoenzyme by a Ca2+-dependent phosphatase

Author

Corradi, Gerardo R., Mazzitelli, Luciana R., Petrovich, Guido D., Grenon, Paula, Sørensen, Danny M., Palmgren, Michael, De Tezanos Pinto, Felicitas, Adamo, Hugo P., Corradi, Gerardo R., Mazzitelli, Luciana R., Petrovich, Guido D., Grenon, Paula, Sørensen, Danny M., Palmgren, Michael, De Tezanos Pinto, Felicitas, and Adamo, Hugo P.

Abstract

P5 ATPases are eukaryotic pumps important for cellular metal ion, lipid and protein homeostasis; however, their transported substrate, if any, remains to be identified. Ca2+ was proposed to act as a ligand of P5 ATPases because it decreases the level of phosphoenzyme of the Spf1p P5A ATPase from Saccharomyces cerevisiae. Repeating previous purification protocols, we obtained a purified preparation of Spf1p that was close to homogeneity and exhibited ATP hydrolytic activity that was stimulated by the addition of CaCl2. Strikingly, a preparation of a catalytically dead mutant Spf1p (D487N) also exhibited Ca2+-dependent ATP hydrolytic activity. These results indicated that the Spf1p preparation contained a co-purifying protein capable of hydrolyzing ATP at a high rate. The activity was likely due to a phosphatase, since the protein i) was highly active when pNPP was used as substrate, ii) required Ca2+ or Zn2+ for activity, and iii) was strongly inhibited by molybdate, beryllium and other phosphatase substrates. Mass spectrometry identified the phosphatase Pho8p as a contaminant of the Spf1p preparation. Modification of the purification procedure led to a contaminant-free Spf1p preparation that was neither stimulated by Ca2+ nor inhibited by EGTA or molybdate. The phosphoenzyme levels of a contaminant-free Spf1p preparation were not affected by Ca2+. These results indicate that the reported effects of Ca2+ on Spf1p do not reflect the intrinsic properties of Spf1p but are mediated by the activity of the accompanying phosphatase.

Published
2020

11. Plasma Membrane Ca2+ Pump PMCA4z Is More Active Than Splicing Variant PMCA4x.

Author

Corradi, Gerardo R., Mazzitelli, Luciana R., Petrovich, Guido D., de Tezanos Pinto, Felicitas, Rochi, Lucia, and Adamo, Hugo P.

Subjects
CELL membranes, KNOTS & splices, MYOCARDIUM, EUKARYOTIC cells, HOMEOSTASIS, RNA splicing
Abstract

The plasma membrane Ca2+ pumps (PMCA) are P-ATPases that control Ca2+ signaling and homeostasis by transporting Ca2+ out of the eukaryotic cell. Humans have four genes that code for PMCA isoforms (PMCA1-4). A large diversity of PMCA isoforms is generated by alternative mRNA splicing at sites A and C. The different PMCA isoforms are expressed in a cell-type and developmental-specific manner and exhibit differential sensitivity to a great number of regulatory mechanisms. PMCA4 has two A splice variants, the forms "x" and "z". While PMCA4x is ubiquitously expressed and relatively well-studied, PMCA4z is less characterized and its expression is restricted to some tissues such as the brain and heart muscle. PMCA4z lacks a stretch of 12 amino acids in the so-called A-M3 linker, a conformation-sensitive region of the molecule connecting the actuator domain (A) with the third transmembrane segment (M3). We expressed in yeast PMCA4 variants "x" and "z", maintaining constant the most frequent splice variant "b" at the C-terminal end, and obtained purified preparations of both proteins. In the basal autoinhibited state, PMCA4zb showed a higher ATPase activity and a higher apparent Ca2+ affinity than PMCA4xb. Both isoforms were stimulated by calmodulin but PMCA4zb was more strongly activated by acidic lipids than PMCA4xb. The results indicate that a PMCA4 intrinsically more active and more responsive to acidic lipids is produced by the variant "z" of the splicing site A. [ABSTRACT FROM AUTHOR]

Published
2021
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12. Reduction of the P5A-ATPase Spf1p phosphoenzyme by a Ca2+-dependent phosphatase.

Author

Corradi, Gerardo R., Mazzitelli, Luciana R., Petrovich, Guido D., Grenon, Paula, Sørensen, Danny M., Palmgren, Michael, de Tezanos Pinto, Felicitas, and Adamo, Hugo P.

Subjects
*MASS spectrometry, *SACCHAROMYCES cerevisiae, *METAL ions, *ADENOSINE triphosphatase, *BERYLLIUM
Abstract

P5 ATPases are eukaryotic pumps important for cellular metal ion, lipid and protein homeostasis; however, their transported substrate, if any, remains to be identified. Ca2+ was proposed to act as a ligand of P5 ATPases because it decreases the level of phosphoenzyme of the Spf1p P5A ATPase from Saccharomyces cerevisiae. Repeating previous purification protocols, we obtained a purified preparation of Spf1p that was close to homogeneity and exhibited ATP hydrolytic activity that was stimulated by the addition of CaCl2. Strikingly, a preparation of a catalytically dead mutant Spf1p (D487N) also exhibited Ca2+-dependent ATP hydrolytic activity. These results indicated that the Spf1p preparation contained a co-purifying protein capable of hydrolyzing ATP at a high rate. The activity was likely due to a phosphatase, since the protein i) was highly active when pNPP was used as substrate, ii) required Ca2+ or Zn2+ for activity, and iii) was strongly inhibited by molybdate, beryllium and other phosphatase substrates. Mass spectrometry identified the phosphatase Pho8p as a contaminant of the Spf1p preparation. Modification of the purification procedure led to a contaminant-free Spf1p preparation that was neither stimulated by Ca2+ nor inhibited by EGTA or molybdate. The phosphoenzyme levels of a contaminant-free Spf1p preparation were not affected by Ca2+. These results indicate that the reported effects of Ca2+ on Spf1p do not reflect the intrinsic properties of Spf1p but are mediated by the activity of the accompanying phosphatase. [ABSTRACT FROM AUTHOR]

Published
2020
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14. Plasma Membrane Ca 2+ Pump PMCA4z Is More Active Than Splicing Variant PMCA4x.

Author

Corradi GR, Mazzitelli LR, Petrovich GD, de Tezanos Pinto F, Rochi L, and Adamo HP

Abstract

The plasma membrane Ca 2+ pumps (PMCA) are P-ATPases that control Ca 2+ signaling and homeostasis by transporting Ca 2+ out of the eukaryotic cell. Humans have four genes that code for PMCA isoforms (PMCA1-4). A large diversity of PMCA isoforms is generated by alternative mRNA splicing at sites A and C. The different PMCA isoforms are expressed in a cell-type and developmental-specific manner and exhibit differential sensitivity to a great number of regulatory mechanisms. PMCA4 has two A splice variants, the forms "x" and "z". While PMCA4x is ubiquitously expressed and relatively well-studied, PMCA4z is less characterized and its expression is restricted to some tissues such as the brain and heart muscle. PMCA4z lacks a stretch of 12 amino acids in the so-called A-M3 linker, a conformation-sensitive region of the molecule connecting the actuator domain (A) with the third transmembrane segment (M3). We expressed in yeast PMCA4 variants "x" and "z", maintaining constant the most frequent splice variant "b" at the C-terminal end, and obtained purified preparations of both proteins. In the basal autoinhibited state, PMCA4zb showed a higher ATPase activity and a higher apparent Ca 2+ affinity than PMCA4xb. Both isoforms were stimulated by calmodulin but PMCA4zb was more strongly activated by acidic lipids than PMCA4xb. The results indicate that a PMCA4 intrinsically more active and more responsive to acidic lipids is produced by the variant "z" of the splicing site A., Competing Interests: The authors declare that the research was conducted in the absence of any commercial or financial relationships that could be construed as a potential conflict of interest., (Copyright © 2021 Corradi, Mazzitelli, Petrovich, de Tezanos Pinto, Rochi and Adamo.)

Published
2021
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