Arsenite interferes with protein folding and triggers formation of protein aggregates in yeast

Summary Several metals and metalloids profoundly affect biological systems, but their impact on the proteome and mechanisms of toxicity are not fully understood. Here, we demonstrate that arsenite causes protein aggregation in Saccharomyces cerevisiae. Various molecular chaperones were found to be associated with arsenite-induced aggregates indicating that this metalloid promotes protein misfolding. Using in vivo and in vitro assays, we show that proteins in the process of synthesis/folding are particularly sensitive to arsenite-induced aggregation, that arsenite interferes with protein folding by acting on unfolded polypeptides, and that arsenite directly inhibits chaperone activity. Thus, folding inhibition contributes to arsenite toxicity in two ways: by aggregate formation and by chaperone inhibition. Importantly, arsenite-induced protein aggregates can act as seeds committing other, labile proteins to misfold and aggregate. Our findings describe a novel mechanism of toxicity that may explain the suggested role of this metalloid in the etiology and pathogenesis of protein folding disorders associated with arsenic poisoning.

[1]  J. Tkach,et al.  Evidence for an Unfolding/Threading Mechanism for Protein Disaggregation by Saccharomyces cerevisiae Hsp104* , 2004, Journal of Biological Chemistry.

[2]  P. Christen,et al.  d-Peptides as Inhibitors of the DnaK/DnaJ/GrpE Chaperone System* , 2003, Journal of Biological Chemistry.

[3]  B. Bukau,et al.  Protein quality control in the cytosol and the endoplasmic reticulum: brothers in arms. , 2010, Molecular cell.

[4]  A. Goffeau,et al.  Isolation of Three Contiguous Genes, ACR1, ACR2 and ACR3, Involved in Resistance to Arsenic Compounds in the Yeast Saccharomyces cerevisiae , 1997, Yeast.

[5]  C. Grant,et al.  The thioredoxin system protects ribosomes against stress-induced aggregation. , 2005, Molecular biology of the cell.

[6]  Cole M. Haynes,et al.  An arsenite-inducible 19S regulatory particle-associated protein adapts proteasomes to proteotoxicity. , 2006, Molecular cell.

[7]  R. Wysocki,et al.  The Saccharomyces cerevisiae ACR3 Gene Encodes a Putative Membrane Protein Involved in Arsenite Transport* , 1997, The Journal of Biological Chemistry.

[8]  S. O'Bryant,et al.  The Arsenic Exposure Hypothesis for Alzheimer Disease , 2010, Alzheimer disease and associated disorders.

[9]  S. Lindquist,et al.  Hsp104, Hsp70, and Hsp40 A Novel Chaperone System that Rescues Previously Aggregated Proteins , 1998, Cell.

[10]  P. Christen,et al.  Heavy metal ions are potent inhibitors of protein folding. , 2008, Biochemical and biophysical research communications.

[11]  J. Strathern,et al.  Methods in yeast genetics : a Cold Spring Harbor Laboratory course manual , 2005 .

[12]  A. Gruhler,et al.  The PRE4 gene codes for a subunit of the yeast proteasome necessary for peptidylglutamyl-peptide-hydrolyzing activity. Mutations link the proteasome to stress- and ubiquitin-dependent proteolysis. , 1993, The Journal of biological chemistry.

[13]  P. Goloubinoff,et al.  Molecular Chaperones and Associated Cellular Clearance Mechanisms against Toxic Protein Conformers in Parkinson’s Disease , 2011, Neurodegenerative Diseases.

[14]  S. Lindquist,et al.  Hsp104, Hsp70 and Hsp40 interplay regulates formation, growth and elimination of Sup35 prions , 2008, The EMBO journal.

[15]  J. Frydman Folding of newly translated proteins in vivo: the role of molecular chaperones. , 2001, Annual review of biochemistry.

[16]  H. Aposhian,et al.  Arsenic toxicology: five questions. , 2006, Chemical research in toxicology.

[17]  Markus J. Tamás,et al.  Quantitative transcriptome, proteome, and sulfur metabolite profiling of the Saccharomyces cerevisiae response to arsenite. , 2007, Physiological genomics.

[18]  Markus J. Tamás,et al.  How Saccharomyces cerevisiae copes with toxic metals and metalloids. , 2010, FEMS microbiology reviews.

[19]  T. Ideker,et al.  Integrating phenotypic and expression profiles to map arsenic-response networks , 2004, Genome Biology.

[20]  P. De Los Rios,et al.  Active Solubilization and Refolding of Stable Protein Aggregates By Cooperative Unfolding Action of Individual Hsp70 Chaperones* , 2004, Journal of Biological Chemistry.

[21]  J. Schneider,et al.  Arsenic(III) species inhibit oxidative protein folding in vitro. , 2009, Biochemistry.

[22]  Judith Frydman,et al.  In vivo newly translated polypeptides are sequestered in a protected folding environment , 1999, The EMBO journal.

[23]  Pierre R. Bushel,et al.  Global Transcriptome and Deletome Profiles of Yeast Exposed to Transition Metals , 2008, PLoS genetics.

[24]  C. Behl,et al.  HSF1-Controlled and Age-Associated Chaperone Capacity in Neurons and Muscle Cells of C. elegans , 2010, PloS one.

[25]  S. Lindquist,et al.  Multiple effects of trehalose on protein folding in vitro and in vivo. , 1998, Molecular cell.

[26]  A. Lewandowska,et al.  Chaperones in control of protein disaggregation , 2008, The EMBO journal.

[27]  A. Udvardy,et al.  S. cerevisiae 26S protease mutants arrest cell division in G2/metaphase , 1993, Nature.

[28]  H. Iwahashi,et al.  Direct evidence for the intracellular localization of Hsp104 in Saccharomyces cerevisiae by immunoelectron microscopy. , 1999, Cell stress & chaperones.

[29]  Markus J. Tamás,et al.  Genetic basis of arsenite and cadmium tolerance in Saccharomyces cerevisiae , 2009, BMC Genomics.

[30]  A. Goldberg,et al.  Protein degradation and protection against misfolded or damaged proteins , 2003, Nature.

[31]  Markus J. Tamás,et al.  Transcriptional activation of metalloid tolerance genes in Saccharomyces cerevisiae requires the AP-1-like proteins Yap1p and Yap8p. , 2004, Molecular biology of the cell.

[32]  E. Deuerling,et al.  A dual function for chaperones SSB–RAC and the NAC nascent polypeptide–associated complex on ribosomes , 2010, The Journal of cell biology.

[33]  M. M. Bradford A rapid and sensitive method for the quantitation of microgram quantities of protein utilizing the principle of protein-dye binding. , 1976, Analytical biochemistry.

[34]  P. Christen,et al.  Non-native Proteins as Newly-Identified Targets of Heavy Metals and Metalloids , 2011 .

[35]  P. Goloubinoff,et al.  Proteinaceous Infectious Behavior in Non-pathogenic Proteins Is Controlled by Molecular Chaperones* , 2002, The Journal of Biological Chemistry.

[36]  Tajpreet Kaur,et al.  Mechanisms Pertaining to Arsenic Toxicity , 2011, Toxicology international.

[37]  M. Zulauf,et al.  Investigation of the molecular chaperone DnaJ by analytical ultracentrifugation , 1995 .

[38]  R. Parker,et al.  Polysomes, P bodies and stress granules: states and fates of eukaryotic mRNAs. , 2009, Current opinion in cell biology.

[39]  M. Schmitt,et al.  in Saccharomyces cerevisiae , 1995 .

[40]  Anders Blomberg,et al.  Automated screening in environmental arrays allows analysis of quantitative phenotypic profiles in Saccharomyces cerevisiae , 2003, Yeast.

[41]  D. E. Anderson,et al.  Identification of arsenic-binding proteins in human breast cancer cells. , 2007, Cancer letters.

[42]  Richard I. Morimoto,et al.  Progressive Disruption of Cellular Protein Folding in Models of Polyglutamine Diseases , 2006, Science.

[43]  R. Parker,et al.  Localization to, and Effects of Pbp1, Pbp4, Lsm12, Dhh1, and Pab1 on Stress Granules in Saccharomyces cerevisiae , 2010, PloS one.

[44]  S. Lindquist,et al.  Hsp104 is required for tolerance to many forms of stress. , 1992, The EMBO journal.

[45]  Daniel S. Yuan,et al.  Trivalent Arsenic Inhibits the Functions of Chaperonin Complex , 2010, Genetics.

[46]  Paolo De Los Rios,et al.  Hsp70 chaperones accelerate protein translocation and the unfolding of stable protein aggregates by entropic pulling. , 2006, Proceedings of the National Academy of Sciences of the United States of America.

[47]  S. Liebman,et al.  A translational fidelity mutation in the universally conserved sarcin/ricin domain of 25S yeast ribosomal RNA. , 1996, RNA.

[48]  P. Christen,et al.  Disaggregating chaperones: an unfolding story. , 2009, Current protein & peptide science.

[49]  D. Menzel,et al.  Arsenic binding proteins from human lymphoblastoid cells. , 1999, Toxicology letters.

[50]  B. Bukau,et al.  The DnaK Chaperone System of Escherichia coli: Quaternary Structures and Interactions of the DnaK and GrpE Components (*) , 1995, The Journal of Biological Chemistry.

[51]  A. Hartwig,et al.  Carcinogenic metal compounds: recent insight into molecular and cellular mechanisms , 2008, Archives of Toxicology.

[52]  R. Lock,et al.  Insight into the selectivity of arsenic trioxide for acute promyelocytic leukemia cells by characterizing Saccharomyces cerevisiae deletion strains that are sensitive or resistant to the metalloid. , 2008, The international journal of biochemistry & cell biology.

[53]  P. Christen,et al.  Potassium ions and the molecular-chaperone activity of DnaK. , 1996, European journal of biochemistry.

[54]  D. Hoyle,et al.  Application of the comprehensive set of heterozygous yeast deletion mutants to elucidate the molecular basis of cellular chromium toxicity , 2007, Genome Biology.

[55]  A. Macario,et al.  Sick chaperones and ageing: a perspective , 2002, Ageing Research Reviews.

[56]  Lawrence Rajendran,et al.  The Transcellular Spread of Cytosolic Amyloids, Prions, and Prionoids , 2009, Neuron.