The effect of metal ions on the Spf1p P5A-ATPase. High sensitivity to irreversible inhibition by zinc.

The Spf1p protein from Saccharomyces cerevisiae belongs to the family of P5A-ATPases that have recently been shown to protect the endoplasmic reticulum by dislocating misinserted membrane proteins. The loss of function of P5A-ATPases leads to endoplasmic reticulum stress with a pleiotropic phenotype including protein, sterol and metal ion dyshomeostasis. Like other P-ATPases, Spf1p requires Mg2+. We found that free Mg2+ stimulated the Spf1p ATPase activity along a double hyperbolic curve with two components of K1/2 = 14 and 800 µM Ca2+, Mn2+ and Co2+ lowered about 50% of the Spf1p ATPase with relatively low affinity (Ki ∼75 µM) and the activity was fully recovered after metal ion chelation with EGTA. In contrast, low concentrations of Zn2+ and Cd2+decreased the activity to less than 20% and lead to slow irreversible inactivation of the enzyme. After the treatment with Zn2+, Spf1p exhibited a reduced apparent affinity for ATP and formed lower levels of the catalytic phosphoenzyme. The inactivation by Zn2+ occurred preferentially at a pH > 6 and could be prevented by adding either ATP or ADP to the inactivation media. These results suggest that Zn2+ inactivated Spf1p by binding to amino acid residues from the nucleotide binding-phosphorylation domains that are protonated at lower pH. Alternatively the binding of nucleotides may indirectly compete with a conformational change leading to the Zn2+-inactive form of the enzyme. Exposure of yeast cells to high concentrations of Zn2+ led to changes similar to the phenotype characteristic of the Spf1Δ cells. Altogether, our data, point out a possible mechanism by which the inhibition of P5A-ATPases could potentiate metal ion-induced ER stress and proteotoxicity.

The Spf1p P5A-ATPase "arm-like" domain is not essential for ATP hydrolysis but its deletion impairs autophosphorylation.

The yeast Spf1p P5A-ATPase actively translocates membrane spanning peptides of mislocalized proteins from the endoplasmic reticulum. Loss of Spf1p function causes a pleiotropic ER stress-phenotype associated with alterations of homeostasis of metal ions, lipids, protein folding, glycosylation, and membrane insertion. A unique characteristic of P5A-ATPases is the presence of an extended insertion which was called the "arm-like" domain connecting the phosphorylation domain (P) with transmembrane segment M5 near the peptidyl-substrate binding pocket. Here we have constructed and characterized a Δarm mutant of Spf1p lacking a segment of 117 amino acids of the "arm-like" domain. The Δarm mutant was capable of hydrolyzing ATP at maximal rates of 50% of that of the wild type enzyme. With the non-nucleotide substrate analog pNPP, the hydrolytic activity of the mutant dropped to 10%. The mutant showed an apparent affinity for ATP similar to the wild type. When incubated with ATP the Δarm mutant produced a lower level of the catalytic phosphoenzyme in amounts proportionate to the ATPase activity. These results indicate that the "arm-like" domain is not essential for hydrolytic activity and suggest that it is needed for the stabilization of Spf1p in a phosphorylation-ready conformation.

Polyamine Transport Assay Using Reconstituted Yeast Membranes.

ATP13A2/PARK9 is a late endo-/lysosomal P5B transport ATPase that is associated with several neurodegenerative disorders. We recently characterized ATP13A2 as a lysosomal polyamine exporter, which sheds light on the molecular identity of the unknown mammalian polyamine transport system. Here, we describe step by step a protocol to measure radiolabeled polyamine transport in reconstituted vesicles from yeast cells overexpressing human ATP13A2. This protocol was developed as part of our recent publication (van Veen et al., 2020 ) and will be useful for characterizing the transport function of other putative polyamine transporters, such as isoforms of the P5B transport ATPases.

The strategic function of the P5-ATPase ATP13A2 in toxic waste disposal.

The P-type ATPase ATP13A2 protein was originally associated with a form of Parkinson's Disease (PD) known as Kufor Rakeb Syndrome (KRS). However, in the last years it has been found to underlay variants of neuronal ceroid-lipofuscinoses and hereditary spastic paraplegia. These findings expand the clinical and genetic spectrum of ATP13A2-associated disorders, which are commonly characterized by lysosomal dysfunction. Nowadays it is well known that lysosomes are not merely related to the degradation and recycling of cellular waste, but are also involved in fundamental processes such as secretion, plasma membrane repair, signaling, energy metabolism and autophagy. The essential role of lysosomes in these cellular processes has significant implications for health and disease. ATP13A2 is localized in lysosomes and late endosomes and its mutation leads to lysosome dysfunction, diminishes the exosome secretion and impairs autophagic flux. In this review, we first describe ATP13A2-associated disorders and their relation with the endolysosomal pathway. We then describe the ATP13A2-involvement in iron homeostasis and its potential linkage with new pathologies like cancer, and finally, we consider the putative role of ATP13A2 in lipid processing and degradation, opening the interesting possibility of a broader role of this protein providing protection against a variety of disease-associated changes affecting cellular homeostasis.

Inhibition of the Formation of the Spf1p Phosphoenzyme by Ca2.

P5-ATPases are important for processes associated with the endosomal-lysosomal system of eukaryotic cells. In humans, the loss of function of P5-ATPases causes neurodegeneration. In the yeastSaccharomyces cerevisiae, deletion of P5-ATPase Spf1p gives rise to endoplasmic reticulum stress. The reaction cycle of P5-ATPases is poorly characterized. Here, we showed that the formation of the Spf1p catalytic phosphoenzyme was fast in a reaction medium containing ATP, Mg(2+), and EGTA. Low concentrations of Ca(2+)in the phosphorylation medium decreased the rate of phosphorylation and the maximal level of phosphoenzyme. Neither Mn(2+)nor Mg(2+)had an inhibitory effect on the formation of the phosphoenzyme similar to that of Ca(2+) TheKmfor ATP in the phosphorylation reaction was ∼1 µmand did not significantly change in the presence of Ca(2+) Half-maximal phosphorylation was attained at 8 µmMg(2+), but higher concentrations partially protected from Ca(2+)inhibition. In conditions similar to those used for phosphorylation, Ca(2+)had a small effect accelerating dephosphorylation and minimally affected ATPase activity, suggesting that the formation of the phosphoenzyme was not the limiting step of the ATP hydrolytic cycle.