Phosphoproteomics for the identification of new mechanisms of cryodamage: the role of SPATA18 in the control of stallion sperm function

Abstract Although recent research has addressed the impact of cryopreservation on the stallion sperm proteome, studies addressing the stallion sperm phosphoproteome are lacking. In the present study, the data set of proteomes of fresh and cryopreserved spermatozoa were reanalyzed, showing that cryopreservation caused significant changes in the phosphoproteome. The phosphoproteins reduced most significantly by cryopreservation were Ca2+ binding tyrosine phosphorylation regulated, protein kinase cAMP-activated catalytic subunit beta (CABYR), mitochondria eating protein (SPATA18), A kinase anchoring protein 4 (AKAP4), A-kinase anchoring protein 3 (AKAP3) and the Family with sequence similarity 71 member B (FAM71B). These proteins belong to the gene ontology (GO) terms sperm fibrous sheath (GO: 0035686), and sperm principal piece (GO: 0097228). The regulatory interactions between kinases and phosphorylation sites on the proteins that were affected most were also investigated, and the potential kinases (based on human orthologs) involved in the regulation of these phosphoproteins identified were: PKCß for SPATA18 and GSK3ß for CABYR. Kinase inhibition assays were also conducted showing that kinases phosphorylating the above-mentioned proteins play an important role in their activity and thus, phosphorylation controls the activity of these proteins and their role in the regulation of the functionality and viability of stallion spermatozoa. In conclusion, the data reported here contribute to the understanding of the fact that the dephosphorylation of certain proteins is a molecular lesion induced by cryopreservation in the stallion spermatozoa. Graphical Abstract

[1]  M. C. Gil,et al.  The stallion spermatozoa: A valuable model to help understand the interplay between metabolism and redox (de)regulation in sperm cells. , 2022, Antioxidants & redox signaling.

[2]  R. Aitken,et al.  Proteomic analysis of spermatozoa reveals caseins play a pivotal role in preventing short-term periods of subfertility in stallions , 2022, Biology of Reproduction.

[3]  C. O’Flaherty,et al.  Redox Regulation to Modulate Phosphorylation Events in Human Spermatozoa. , 2021, Antioxidants & redox signaling.

[4]  M. C. Gil,et al.  Seminal plasma proteins as potential biomarkers for sperm motility and velocities. , 2021, Theriogenology.

[5]  Shanshan Tang,et al.  Quantitative phosphoproteomics reveals GSK3A substrate network is involved in the cryodamage of sperm motility , 2021, Bioscience reports.

[6]  A. Saxena,et al.  Curcumin in a tris‐based semen extender improves cryosurvival of Hariana bull spermatozoa , 2021, Andrologia.

[7]  T. Mendes,et al.  Prepubertal arsenic exposure alters phosphoproteins profile, quality, and fertility of epididymal spermatozoa in sexually mature rats. , 2021, Toxicology.

[8]  P. Visconti,et al.  Activation of cAMP‐dependent phosphorylation pathways is independent of ROS production during mouse sperm capacitation , 2021, Molecular reproduction and development.

[9]  Chaofeng Ma,et al.  Comparative Proteomics and Phosphoproteomics Analysis Reveal the Possible Breed Difference in Yorkshire and Duroc Boar Spermatozoa , 2021, Frontiers in Cell and Developmental Biology.

[10]  M. C. Gil,et al.  In Stallion Spermatozoa, Superoxide Dismutase (Cu–Zn) (SOD1) and the Aldo-Keto-Reductase Family 1 Member b (AKR1B1) Are the Proteins Most Significantly Reduced by Cryopreservation , 2021, Journal of proteome research.

[11]  Kazuhiro Yoshida,et al.  p53/Mieap-regulated mitochondrial quality control plays an important role as a tumor suppressor in gastric and esophageal cancers. , 2020, Biochemical and biophysical research communications.

[12]  H. Rodríguez-Martínez,et al.  Seminal plasma AnnexinA2 protein is a relevant biomarker for stallions which require removal of seminal plasma for sperm survival upon refrigeration† , 2020, Biology of Reproduction.

[13]  R. Aitken,et al.  Mass spectrometry reveals distinct proteomic profiles in high- and low-quality stallion spermatozoa. , 2020, Reproduction.

[14]  M. C. Gil,et al.  Proteomic profiling of stallion spermatozoa suggests changes in sperm metabolism and compromised redox regulation after cryopreservation. , 2020, Journal of proteomics.

[15]  M. C. Gil,et al.  Redox Regulation and Oxidative Stress: The Particular Case of the Stallion Spermatozoa , 2019, Antioxidants.

[16]  C. Ortega-Ferrusola,et al.  Rosiglitazone in the thawing medium improves mitochondrial function in stallion spermatozoa through regulating Akt phosphorylation and reduction of caspase 3 , 2019, PloS one.

[17]  J. Vilo,et al.  g:Profiler: a web server for functional enrichment analysis and conversions of gene lists (2019 update) , 2019, Nucleic Acids Res..

[18]  Olga Tanaseichuk,et al.  Metascape provides a biologist-oriented resource for the analysis of systems-level datasets , 2019, Nature Communications.

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

[20]  M. Jodar,et al.  The contribution of human sperm proteins to the development and epigenome of the preimplantation embryo. , 2018, Human reproduction update.

[21]  A. Saxena,et al.  Effect of reduced glutathione supplementation in semen extender on tyrosine phosphorylation and apoptosis like changes in frozen thawed Hariana bull spermatozoa. , 2017, Animal reproduction science.

[22]  M. Jodar,et al.  Semen proteomics and male infertility. , 2017, Journal of proteomics.

[23]  H. Arakawa,et al.  Discovery of Mieap‐regulated mitochondrial quality control as a new function of tumor suppressor p53 , 2017, Cancer science.

[24]  C. Ortega-Ferrusola,et al.  Computational flow cytometry reveals that cryopreservation induces spermptosis but subpopulations of spermatozoa may experience capacitation-like changes. , 2017, Reproduction.

[25]  R. Aitken,et al.  Electrophilic aldehyde products of lipid peroxidation selectively adduct to heat shock protein 90 and arylsulfatase A in stallion spermatozoa , 2017, Biology of Reproduction.

[26]  M. Ikawa,et al.  CABYR is essential for fibrous sheath integrity and progressive motility in mouse spermatozoa , 2016, Journal of Cell Science.

[27]  G. Salido,et al.  Autophagy-related proteins are functionally active in human spermatozoa and may be involved in the regulation of cell survival and motility , 2016, Scientific Reports.

[28]  F. Peña,et al.  Caspase 3 Activity and Lipoperoxidative Status in Raw Semen Predict the Outcome of Cryopreservation of Stallion Spermatozoa1 , 2016, Biology of reproduction.

[29]  G. Salido,et al.  The autophagy-related protein LC3 is processed in stallion spermatozoa during short-and long-term storage and the related stressful conditions. , 2016, Animal : an international journal of animal bioscience.

[30]  R. Aitken,et al.  Causes and consequences of oxidative stress in spermatozoa. , 2016, Reproduction, fertility, and development.

[31]  Sean J. Humphrey,et al.  Protein Phosphorylation: A Major Switch Mechanism for Metabolic Regulation , 2015, Trends in Endocrinology & Metabolism.

[32]  F. Peña,et al.  Depletion of Intracellular Thiols and Increased Production of 4-Hydroxynonenal that Occur During Cryopreservation of Stallion Spermatozoa Lead to Caspase Activation, Loss of Motility, and Cell Death1 , 2015, Biology of reproduction.

[33]  B. Ball,et al.  The Impact of Reproductive Technologies on Stallion Mitochondrial Function. , 2015, Reproduction in domestic animals = Zuchthygiene.

[34]  R. Aitken,et al.  Investigation of the stallion sperm proteome by mass spectrometry. , 2015, Reproduction.

[35]  Xuejiang Guo,et al.  Quantitative Phosphoproteomics Analysis Reveals a Key Role of Insulin Growth Factor 1 Receptor (IGF1R) Tyrosine Kinase in Human Sperm Capacitation* , 2015, Molecular & Cellular Proteomics.

[36]  J. Morrell,et al.  Effect of overnight staining on the quality of flow cytometric sorted stallion sperm: comparison with tradtitional protocols. , 2014, Reproduction in domestic animals = Zuchthygiene.

[37]  J. Ballescà,et al.  Identification of proteins involved in human sperm motility using high-throughput differential proteomics. , 2014, Journal of proteome research.

[38]  H. Rodríguez-Martínez,et al.  Phosphorylated AKT preserves stallion sperm viability and motility by inhibiting caspases 3 and 7. , 2014, Reproduction.

[39]  L. Jensen,et al.  KinomeXplorer: an integrated platform for kinome biology studies , 2014, Nature Methods.

[40]  J. Ramalho-Santos,et al.  Human Sperm Tail Proteome Suggests New Endogenous Metabolic Pathways* , 2012, Molecular & Cellular Proteomics.

[41]  G. Salido,et al.  The membrane of the mammalian spermatozoa: much more than an inert envelope. , 2012, Reproduction in domestic animals = Zuchthygiene.

[42]  M. Mann,et al.  PhosphoSiteAnalyzer: a bioinformatic platform for deciphering phospho proteomes using kinase predictions retrieved from NetworKIN. , 2012, Journal of proteome research.

[43]  F. Peña,et al.  Dissecting the molecular damage to stallion spermatozoa: the way to improve current cryopreservation protocols? , 2011, Theriogenology.

[44]  Charlotte Soneson,et al.  The projection score - an evaluation criterion for variable subset selection in PCA visualization , 2011, BMC Bioinformatics.

[45]  S. Ichinose,et al.  Mieap, a p53-Inducible Protein, Controls Mitochondrial Quality by Repairing or Eliminating Unhealthy Mitochondria , 2011, PloS one.

[46]  S. Ichinose,et al.  Possible Existence of Lysosome-Like Organella within Mitochondria and Its Role in Mitochondrial Quality Control , 2011, PloS one.

[47]  F. Peña,et al.  Inhibition of the mitochondrial permeability transition pore reduces "apoptosis like" changes during cryopreservation of stallion spermatozoa. , 2010, Theriogenology.

[48]  R. Gentleman,et al.  Independent filtering increases detection power for high-throughput experiments , 2010, Proceedings of the National Academy of Sciences.

[49]  H. Rodríguez-Martínez,et al.  Identification of sperm subpopulations in stallion ejaculates: changes after cryopreservation and comparison with traditional statistics. , 2009, Reproduction in domestic animals = Zuchthygiene.

[50]  R. Aitken,et al.  The mouse sperm proteome characterized via IPG strip prefractionation and LC‐MS/MS identification , 2008, Proteomics.

[51]  Tony Pawson,et al.  NetworKIN: a resource for exploring cellular phosphorylation networks , 2007, Nucleic Acids Res..

[52]  B. Ball,et al.  Capacitation-like changes in equine spermatozoa following cryopreservation. , 2006, Theriogenology.

[53]  H. Rodríguez-Martínez,et al.  Assessment of fresh and frozen-thawed boar semen using an Annexin-V assay: a new method of evaluating sperm membrane integrity. , 2003, Theriogenology.

[54]  J. Shabanowitz,et al.  Phosphoproteome Analysis of Capacitated Human Sperm , 2003, The Journal of Biological Chemistry.

[55]  L. A. Bush,et al.  CABYR, a novel calcium-binding tyrosine phosphorylation-regulated fibrous sheath protein involved in capacitation. , 2002, Developmental biology.

[56]  Y Hochberg,et al.  Multiple test procedures for dose finding. , 1996, Biometrics.

[57]  Y. Hochberg,et al.  The antihypertensive effect of atenolol and bopindolol in the elderly. , 1989, Netherlands Journal of Medicine.

[58]  M. Buffone,et al.  Sperm Capacitation and Acrosome Reaction in Mammalian Sperm. , 2016, Advances in anatomy, embryology, and cell biology.