Iron Deficiency and Recovery in Yeast: A Quantitative Proteomics Approach.

Iron is an essential element for life, as it is critical for oxygen transport, cellular respiration, DNA synthesis, and metabolism. Disruptions in iron metabolism have been associated with several complex diseases like diabetes, cancer, infection susceptibility, neurodegeneration, and others; however, the molecular mechanisms linking iron metabolism with these diseases are not fully understood. A commonly used model to study iron deficiency (ID) is yeast, Saccharomyces cerevisiae. Here, we used quantitative (phospho)proteomics to explore the early (4 and 6 h) and late (12 h) response to ID. We showed that metabolic pathways like the Krebs cycle, amino acid, and ergosterol biosynthesis were affected by ID. In addition, during the late response, several proteins related to the ubiquitin-proteasome system and autophagy were upregulated. We also explored the proteomic changes during a recovery period after 12 h of ID. Several proteins recovered their steady-state levels, but some others, such as cytochromes, did not recover during the time tested. Additionally, we showed that autophagy is active during ID, and some of the degraded proteins during ID can be rescued using KO strains for several key autophagy genes. Our results highlight the complex proteome changes occurring during ID and recovery. This study constitutes a valuable data set for researchers interested in iron biology, offering a temporal proteomic data set for ID, as well as a compendium the proteomic changes associated with episodes of iron recovery.

[1]  P. Alepuz,et al.  Global translational repression induced by iron deficiency in yeast depends on the Gcn2/eIF2α pathway , 2020, Scientific Reports.

[2]  J. Dixon,et al.  Reversible phosphorylation of Rpn1 regulates 26S proteasome assembly and function , 2019, Proceedings of the National Academy of Sciences.

[3]  E. Berry,et al.  The assembly of succinate dehydrogenase: a key enzyme in bioenergetics , 2019, Cellular and Molecular Life Sciences.

[4]  P. Thomas,et al.  Protocol Update for large-scale genome and gene function analysis with the PANTHER classification system (v.14.0) , 2019, Nature Protocols.

[5]  Susan E. Abbatiello,et al.  Characterization and Optimization of Multiplexed Quantitative Analyses Using High-Field Asymmetric-Waveform Ion Mobility Mass Spectrometry. , 2019, Analytical chemistry.

[6]  Martin Eisenacher,et al.  The PRIDE database and related tools and resources in 2019: improving support for quantification data , 2018, Nucleic Acids Res..

[7]  P. Alepuz,et al.  Yeast Cth2 protein represses the translation of ARE-containing mRNAs in response to iron deficiency , 2018, PLoS genetics.

[8]  Steven P Gygi,et al.  Streamlined Tandem Mass Tag (SL-TMT) Protocol: An Efficient Strategy for Quantitative (Phospho)proteome Profiling Using Tandem Mass Tag-Synchronous Precursor Selection-MS3. , 2018, Journal of proteome research.

[9]  N. Kassebaum,et al.  Iron deficiency across chronic inflammatory conditions: International expert opinion on definition, diagnosis, and management , 2017, American journal of hematology.

[10]  L. Pillus,et al.  Phosphorylation of the 19S regulatory particle ATPase subunit, Rpt6, modifies susceptibility to proteotoxic stress and protein aggregation , 2017, PloS one.

[11]  G. Cairo,et al.  Molecular regulation of cellular iron balance , 2017, IUBMB life.

[12]  M. Martínez-Pastor,et al.  Mechanisms of iron sensing and regulation in the yeast Saccharomyces cerevisiae , 2017, World journal of microbiology & biotechnology.

[13]  M. J. Chen,et al.  Reversible phosphorylation of the 26S proteasome , 2017, Protein & Cell.

[14]  T. Deloughery Iron Deficiency Anemia. , 2017, The Medical clinics of North America.

[15]  Steven P. Gygi,et al.  A Triple Knockout (TKO) Proteomics Standard for Diagnosing Ion Interference in Isobaric Labeling Experiments , 2016, Journal of The American Society for Mass Spectrometry.

[16]  Hironobu Nakayama,et al.  Iron-depletion promotes mitophagy to maintain mitochondrial integrity in pathogenic yeast Candida glabrata , 2016, Autophagy.

[17]  Marco Y. Hein,et al.  The Perseus computational platform for comprehensive analysis of (prote)omics data , 2016, Nature Methods.

[18]  Dipendra K. Aryal,et al.  Disrupted iron homeostasis causes dopaminergic neurodegeneration in mice , 2016, Proceedings of the National Academy of Sciences.

[19]  H. Hirano,et al.  Biological significance of co- and post-translational modifications of the yeast 26S proteasome. , 2016, Journal of proteomics.

[20]  N. Andrews,et al.  Metabolic Catastrophe in Mice Lacking Transferrin Receptor in Muscle , 2015, EBioMedicine.

[21]  Nektarios Tavernarakis,et al.  Iron-Starvation-Induced Mitophagy Mediates Lifespan Extension upon Mitochondrial Stress in C. elegans , 2015, Current Biology.

[22]  H. Hirano,et al.  Receptor-mediated selective autophagy degrades the endoplasmic reticulum and the nucleus , 2015, Nature.

[23]  M. Boele van Hensbroek,et al.  Anaemia, iron deficiency and susceptibility to infections. , 2014, The Journal of infection.

[24]  Edward L. Huttlin,et al.  MultiNotch MS3 Enables Accurate, Sensitive, and Multiplexed Detection of Differential Expression across Cancer Cell Line Proteomes , 2014, Analytical chemistry.

[25]  M. Georgieff,et al.  Fetal iron deficiency alters the proteome of adult rat hippocampal synaptosomes. , 2013, American journal of physiology. Regulatory, integrative and comparative physiology.

[26]  Edward L. Huttlin,et al.  Increasing the multiplexing capacity of TMTs using reporter ion isotopologues with isobaric masses. , 2012, Analytical chemistry.

[27]  S. Gygi,et al.  MS3 eliminates ratio distortion in isobaric labeling-based multiplexed quantitative proteomics , 2011, Nature Methods.

[28]  Shmuel Pietrokovski,et al.  Atg8: an autophagy-related ubiquitin-like protein family , 2011, Genome Biology.

[29]  Edward L. Huttlin,et al.  A Tissue-Specific Atlas of Mouse Protein Phosphorylation and Expression , 2010, Cell.

[30]  L. McAlister-Henn,et al.  Disulfide bond formation in yeast NAD+-specific isocitrate dehydrogenase. , 2009, Biochemistry.

[31]  E. Susser,et al.  Maternal iron deficiency and the risk of schizophrenia in offspring. , 2008, Archives of general psychiatry.

[32]  D. Thiele,et al.  Cooperation of two mRNA-binding proteins drives metabolic adaptation to iron deficiency. , 2008, Cell metabolism.

[33]  Steven P Gygi,et al.  Target-decoy search strategy for increased confidence in large-scale protein identifications by mass spectrometry , 2007, Nature Methods.

[34]  Steven P Gygi,et al.  A probability-based approach for high-throughput protein phosphorylation analysis and site localization , 2006, Nature Biotechnology.

[35]  J. Connor,et al.  Long-lasting neural and behavioral effects of iron deficiency in infancy. , 2006, Nutrition reviews.

[36]  O. Pines,et al.  Yeast aconitase in two locations and two metabolic pathways: seeing small amounts is believing. , 2005, Molecular biology of the cell.

[37]  D. Thiele,et al.  Coordinated Remodeling of Cellular Metabolism during Iron Deficiency through Targeted mRNA Degradation , 2005, Cell.