Katarzyna Markowska scite author profile

The yeast transporter Acr3p is a low affinity As(III)/H(+) and Sb(III)/H(+) antiporter located in the plasma membrane. It has been shown for bacterial Acr3 proteins that just a single cysteine residue, which is located in the middle of the fourth transmembrane region and conserved in all members of the Acr3 family, is essential for As(III) transport activity. Here, we report a systematic mutational analysis of all nine cysteine residues present in the Saccharomyces cerevisiae Acr3p. We found that mutagenesis of highly conserved Cys151 resulted in a complete loss of metalloid transport function. In addition, lack of Cys90 and Cys169, which are conserved in eukaryotic members of Acr3 family, impaired Acr3p trafficking to the plasma membrane and greatly reduced As(III) efflux, respectively. Mutagenesis of five other cysteines in Acr3p resulted in moderate reduction of As(III) transport capacities and sorting perturbations. Our data suggest that interaction of As(III) with multiple thiol groups in the yeast Acr3p may facilitate As(III) translocation across the plasma membrane.

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Transmembrane topology of the arsenite permease Acr3 from Saccharomyces cerevisiae

Wawrzycka¹,

Markowska²,

Maciaszczyk-Dziubińska³

et al. 2017

Biochimica et Biophysica Acta (BBA) - Biomembranes

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Acr3 is a plasma membrane transporter, a member of the bile/arsenite/riboflavin transporter (BART) superfamily, which confers high-level resistance to arsenicals in the yeast Saccharomyces cerevisiae. We have previously shown that the yeast Acr3 acts as a low affinity As(III)/H and Sb(III)/H antiporter. We have also identified several amino acid residues that are localized in putative transmembrane helices (TM) and appeared to be critical for the Acr3 activity. In the present study, the topology of Acr3 was investigated by insertion of glycosylation and factor Xa protease cleavage sites at predicted hydrophilic regions. The analysis of the glycosylation pattern and factor Xa cleavage products of resulting Acr3 fusion constructs provide evidence supporting a topological model of Acr3 with 10 TM segments and cytoplasmically oriented N- and C-terminal domains. Next, we investigated the role of the hydrophilic loop connecting TM8 and TM9, the large size of which is unique to members of the yeast Acr3 family of metalloid transporters. We found that a 28 amino acid deletion in this region does not affect Acr3 folding, trafficking substrate binding, or transport activity. Finally, we constructed a homology-based structural model of Acr3 using the crystal structure of the Yersinia frederiksenii homologue of the human bile acid sodium symporter ASBT.

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Mechanisms of arsenic toxicity and transport in microorganisms

Mucha

Berezowski

Markowska

2017

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Arsenic is an ubiquitous element present in the environment either through geological or anthropogenic activities. Millions of people all over the world are exposed to arsenic mainly via air, drinking water and food sources, which results in higher incidence of cancer. Several mechanisms by which arsenic compounds induce tumorigenesis have been proposed. Arsenic mediates its toxicity by generating oxidative stress, inducing protein misfolding, promoting genotoxicity, hampering DNA repair and disrupting signal transduction. Thus, all organisms have developed multiple pathways for arsenic detoxification. In this article, we review recent advances in the understanding of arsenic toxicity and its transport routes in prokaryotes and eukaryotes, including a dual role of aquaglyceroporins in the uptake and efflux, active transport out of the cell via secondary ion pumps and sequestration of metalloid-thiol conjugates into vacuoles by primary ABC transporters. We believe that such studies are of high importance due to the increasing usage of arsenic-based drugs in the treatment of certain types of cancer and diseases caused by protozoan parasites as well as for the development of bio-and phytoremediation strategies for metalloid-polluted areas. 1. Introduction. 2. The chemical properties and the presence of arsenic in the environment. 3. Pathways for arsenic uptake. 4. Mechanism of trivalent arsenic toxicity. 4.1. Oxidative stress. 4.2. Arsenic binding to proteins. 4.3. Protein aggregation. 5. Pentavalent arsenic toxicity. 6. Cellular detoxification mechanisms of arsenic compounds. 6.1. ars operons. 6.2. ACR genes. 6.3. Removal of arsenic conjugates by the ABC transporters. 6.4. Bi-directional transport of arsenic. 7. Summary

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Identification of critical residues for transport activity of Acr3p, the Saccharomyces cerevisiae As(III)/H⁺ antiporter

Markowska

Maciaszczyk-Dziubińska

Migocka

et al. 2015

Molecular Microbiology

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Summary Acr3p is an As(III)/H+ antiporter from Saccharomyces cerevisiae belonging to the bile/arsenite/riboflavin transporter superfamily. We have previously found that Cys151 located in the middle of the fourth transmembrane segment (TM4) is critical for antiport activity, suggesting that As(III) might interact with a thiol group during the translocation process. In order to identify functionally important residues involved in As(III)/H + exchange, we performed a systematic alanine-replacement analysis of charged/polar and aromatic residues that are conserved in the Acr3 family and located in putative transmembrane segments. Nine residues (Asn117, Trp130, Arg150, Trp158, Asn176, Arg230, Tyr290, Phe345, Asn351) were found to be critical for proper folding and trafficking of Acr3p to the plasma membrane. In addition, we found that replacement of highly conserved Phe266 (TM7), Phe352 (TM9), Glu353 (TM9) and Glu380 (TM10) with Ala abolished transport activity of Acr3p, while mutation of Ser349 (TM9) to Ala significantly reduced the As(III)/H + exchange, suggesting an important role of these residues in the transport mechanism. Detailed mutational analysis of Glu353 and Glu380 revealed that the negatively charged residues located in the middle of transmembrane segments TM9 and TM10 are crucial for antiport activity. We also discuss a hypothetical model of the Acr3p transport mechanism.

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ISW1a modulates cohesin distribution in centromeric and pericentromeric regions

Litwin

Nowicka

Markowska

et al. 2023

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Cohesin is a highly conserved, multiprotein complex whose canonical function is to hold sister chromatids together to ensure accurate chromosome segregation. Cohesin association with chromatin relies on the Scc2-Scc4 cohesin loading complex that enables cohesin ring opening and topological entrapment of sister DNAs. To better understand how sister chromatid cohesion is regulated, we performed a proteomic screen in budding yeast that identified the Isw1 chromatin remodeler as a cohesin binding partner. In addition, we found that Isw1 also interacts with Scc2-Scc4. Lack of Isw1 protein, the Ioc3 subunit of ISW1a or Isw1 chromatin remodeling activity resulted in increased accumulation of cohesin at centromeres and pericentromeres, suggesting that ISW1a may promote efficient translocation of cohesin from the centromeric site of loading to neighboring regions. Consistent with the role of ISW1a in the chromatin organization of centromeric regions, Isw1 was found to be recruited to centromeres. In its absence we observed changes in the nucleosomal landscape at centromeres and pericentromeres. Finally, we discovered that upon loss of RSC functionality, ISW1a activity leads to reduced cohesin binding and cohesion defect. Taken together, our results support the notion of a key role of chromatin remodelers in the regulation of cohesin distribution on chromosomes.

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