ATP13A2 (PARK9) is a late endo-lysosomal transporter of unknown function that is genetically implicated in a spectrum of neurodegenerative disorders, including Kufor-Rakeb syndrome, a parkinsonism with dementia 1 and early-onset Parkinson's disease (PD) 2. ATP13A2 offers protection against genetic and environmental risk factors of PD, whereas loss of ATP13A2 compromises lysosomal function 3. The lysosomal transport function of ATP13A2 remained unclear, but here, we establish ATP13A2 as a lysosomal polyamine exporter with highest affinity for spermine. Polyamines stimulate the activity of purified ATP13A2, while disease mutants are functionally impaired to a degree that correlates with the disease phenotype. ATP13A2 promotes cellular polyamine uptake via endocytosis and transports polyamines into the cytosol, which highlights a role for endo-lysosomes in cellular polyamine uptake. At high concentrations, polyamines induce cell toxicity, which is exacerbated by ATP13A2 loss due to lysosomal dysfunction, lysosomal rupture and cathepsin B activation. This phenotype is recapitulated in neurons and nematodes with loss of ATP13A2 or its orthologues. Thus, defective lysosomal polyamine export is a new mechanism for lysosome-dependent cell death that may be implicated in neurodegeneration. Our findings further shed light on the molecular identity of the elusive mammalian polyamine transport system. ATP13A2 is a P5B-ATPase belonging to the family of P-type ATPases, which couple ATP hydrolysis to substrate transport while transiently forming a catalytic phospho-intermediate 4. ATP13A2 is generally described as a heavy metal transporter 5 , but Ca 2+ 6 and the polyamine spermidine (SPD) 7,8 were also proposed. To screen for the transported substrate(s) of ATP13A2, we measured ATPase activity in the presence of various candidate substrates in solubilized microsomal membrane fractions of SH-SY5Y cells that overexpress human ATP13A2 wild type (WT) (WT-OE) or comparable levels of the catalytically dead D508N mutant (D508N-OE) 9,10. ATPase activity of ATP13A2 WT was significantly stimulated by the polyamines SPD and spermine (SPM) (Fig. 1a), whereas SPM had no effect on the D508N mutant (Extended Data Fig. 1a). MnCl2, ZnCl2, FeCl3, CaCl2, diamines, monoamines and amino acids exerted no effect (Extended Data Fig. 1a-3 d). The polyamines SPM, N 1-acetylspermine and SPD were able to stimulate ATPase activity in a concentration-dependent manner (Fig. 1b, Extended Data Fig. 1e) with the highest apparent affinity for SPM (Extended Data Table 1). The catalytic auto-phosphorylation and/or dephosphorylation reactions of P-type ATPases occur in response to binding of the transported substrate 4. ATP13A2 forms a phospho-intermediate on the D508 residue in the absence of SPM supplementation 9,10 , whereas SPM leads to a dose-dependent reduction in ATP13A2 phospho-enzyme levels (Fig. 1c), which is not seen with ornithine (Extended Data Fig. 1f). The dephosphorylation rate following a chase with non-radioactive ATP increased in the presence of...
Polyamines, such as putrescine, spermidine, and spermine, are physiologically important polycations, but the transporters responsible for their uptake in mammalian cells remain poorly characterized. Here, we reveal a new component of the mammalian polyamine transport system using CHO-MG cells, a widely used model to study alternative polyamine uptake routes and characterize polyamine transport inhibitors for therapy. CHO-MG cells present polyamine uptake deficiency and resistance to a toxic polyamine biosynthesis inhibitor methylglyoxal bis-(guanylhydrazone) (MGBG), but the molecular defects responsible for these cellular characteristics remain unknown. By genome sequencing of CHO-MG cells, we identified mutations in an unexplored gene, ATP13A3 , and found disturbed mRNA and protein expression. ATP13A3 encodes for an orphan P5B-ATPase (ATP13A3), a P-type transport ATPase that represents a candidate polyamine transporter. Interestingly, ATP13A3 complemented the putrescine transport deficiency and MGBG resistance of CHO-MG cells, whereas its knockdown in WT cells induced a CHO-MG phenotype demonstrated as a decrease in putrescine uptake and MGBG sensitivity. Taken together, our findings identify ATP13A3, which has been previously genetically linked with pulmonary arterial hypertension, as a major component of the mammalian polyamine transport system that confers sensitivity to MGBG.
The activity of proteases is tightly regulated, and dysregulation is linked to a variety of human diseases. For this reason, ABPP is a well-suited method to study protease biology and the design of protease probes has pushed the boundaries of ABPP. The development of highly selective protease probes is still a challenging task. After an introduction, the first section of this chapter discusses several strategies to enable detection of a single active protease species. These range from the usage of non-natural amino acids, combination of probes with antibodies, and engineering of the target proteases. A next section describes the different types of detection tags that facilitate the read-out possibilities including various types of imaging methods and mass spectrometry-based target identification. The power of protease ABPP is illustrated by examples for a selected number of proteases. It is expected that some protease probes that have been evaluated in animal models of human disease will find translation into clinical application in the near future.
Polyamines are essential for cell growth and differentiation, but their trafficking by the polyamine transport system is not fully understood. Herein, the synthesis of several azido‐derivatized polyamines for easy conjugation by click chemistry is described. Attachment of a 4,4‐difluoro‐4‐bora‐3a,4a‐diaza‐s‐indacene (BODIPY) dye gave fluorescent polyamine probes, which were tested in cell culture. The linear probe series showed superior cellular uptake compared with that of probes in which the dye was attached to a branch on one of the central amines. Interestingly, the linear probes accumulated rapidly in cancer cells (MCF‐7), but not in nontumorigenic cells (MCF‐10A). The fluorescent polyamine probes are therefore applicable to the study of polyamine trafficking, whereas the azido polyamines may be further utilized to transport cargo into cancer cells by exploiting the polyamine transport system.
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