Quantitative proteomics analysis reveals alterations of lysine acetylation in mouse testis in response to heat shock and X-ray exposure

Environmental stresses are important factors causing male infertility which attracts broad attention. Protein acetylation is a pivotal post-translational modification and modulates diverse physiological processes including spermatogenesis. In this study, we employed quantitative proteomic techniques and bioinformatics tools to analyze the alterations of acetylome profile of mouse testis after heat shock and X-irradiation. Overall, we identified 1139 lysine acetylation sites in 587 proteins in which 1020 lysine acetylation sites were quantified. The Gene Ontology analysis showed that the major acetylated protein groups were involved in generation of precursor metabolites and metabolic processes, and were localized predominantly in cytosolic and mitochondrial. Compared to the control group, 36 sites of 28 acetylated proteins have changed after heat shock, and 49 sites of 43 acetylated proteins for X-ray exposure. Some of the differentially acetylated proteins have been reported to be associated with the progression of spermatogenesis and male fertility. We observed the up-regulated acetylation level change on testis specific histone 2B and heat shock protein upon heat treatment and a sharp decline of acetylation level on histone H2AX under X-ray treatment, suggesting their roles in male germ cells. Notably, the acetylation level on K279 of histone acetyltransferase (Kat7) was down-regulated in both heat and X-ray treatments, indicating that K279 may be a key acetylated site and affect its functions in spermatogenesis. Our results reveal that protein acetylation might add another layer of complexity to the regulation for spermatogenesis, and further functional studies of these proteins will help us elucidate the mechanisms of abnormal spermatogenesis.     

Proteome-wide lysine acetylation profiling of the human pathogen Mycobacterium tuberculosis

N^ɛ-Acetylation of lysine residues represents a pivotal post-translational modification used by both eukaryotes and prokaryotes to modulate diverse biological processes. Mycobacterium tuberculosis is the causative agent of tuberculosis, one of the most formidable public health threats. Many aspects of the biology of M. tuberculosis remain elusive, in particular the extent and function of N^ɛ-lysine acetylation. With a combination of anti-acetyllysine antibody-based immunoaffinity enrichment with high-resolution mass spectrometry, we identified 1128 acetylation sites on 658 acetylated M. tuberculosis proteins. GO analysis of the acetylome showed that acetylated proteins are involved in the regulation of diverse cellular processes including metabolism and protein synthesis. Six types of acetylated peptide sequence motif were revealed from the acetylome. Twenty lysine-acetylated proteins showed homology with acetylated proteins previously identified from Escherichia coli, Salmonella enterica, Bacillus subtilis and Streptomyces roseosporus, with several acetylation sites highly conserved among four or five bacteria, suggesting that acetylated proteins are more conserved. Notably, several proteins including isocitrate lyase involved in the persistence, virulence and antibiotic resistance are acetylated, and site-directed mutagenesis of isocitrate lyase acetylation site to glutamine led to a decrease of the enzyme activity, indicating major roles of KAc in these proteins engaged cellular processes. Our data firstly provides a global survey of M. tuberculosis acetylation, and implicates extensive regulatory role of acetylation in this pathogen. This may serve as an important basis to address the roles of lysine acetylation in M. tuberculosis metabolism, persistence and virulence.     

Proteome-wide lysine acetylation identification in developing rice (Oryza sativa) seeds and protein co-modification by acetylation,succinylation, ubiquitination,and phosphorylation

Protein lysine acetylation is a highly conserved post-translational modification with various biological functions. However, only a limited number of acetylation sites have been reported in plants, especially in cereals, and the function of non-histone protein acetylation is still largely unknown. In this report, we identified 1003 lysine acetylation sites in 692 proteins of developing rice seeds, which greatly extended the number of known acetylated sites in plants. Seven distinguished motifs were detected flanking acetylated lysines. Functional annotation analyses indicated diverse biological processes and pathways engaged in lysine acetylation. Remarkably, we found that several key enzymes in storage starch synthesis pathway and the main storage proteins were heavily acetylated. A comprehensive comparison of the rice acetylome, succinylome, ubiquitome and phosphorylome with available published data was conducted. A large number of proteins carrying multiple kinds of modifications were identified and many of these proteins are known to be key enzymes of vital metabolic pathways. Our study provides extending knowledge of protein acetylation. It will have critical reference value for understanding the mechanisms underlying PTM mediated multiple signal integration in the regulation of metabolism and development in plants.     

Extensive lysine acetylation occurs in evolutionarily conserved metabolic pathways and parasite‐specific functions during Plasmodium falciparum intraerythrocytic development

Lysine acetylation has emerged as a major post‐translational modification involved in diverse cellular functions. Using a combination of immunoisolation and liquid chromatography coupled to accurate mass spectrometry, we determined the first acetylome of the human malaria parasite Plasmodium falciparum during its active proliferation in erythrocytes with 421 acetylation sites identified in 230 proteins. Lysine‐acetylated proteins are distributed in the nucleus, cytoplasm, mitochondrion and apicoplast. Whereas occurrence of lysine acetylation in a similarly wide range of cellular functions suggests conservation of lysine acetylation through evolution, the Plasmodium acetylome also revealed significant divergence from those of other eukaryotes and even the closely related parasite Toxoplasma. This divergence is reflected in the acetylation of a large number of Plasmodium‐specific proteins and different acetylation sites in evolutionarily conserved acetylated proteins. A prominent example is the abundant acetylation of proteins in the glycolysis pathway but relatively deficient acetylation of enzymes in the citrate cycle. Using specific transgenic lines and inhibitors, we determined that the acetyltransferase PfMYST and lysine deacetylases play important roles in regulating the dynamics of cytoplasmic protein acetylation. The Plasmodium acetylome provides an exciting start point for further exploration of functions of acetylation in the biology of malaria parasites.     

Étude électrophorétique de l'hybride expérimental entre Papio anubis et P. cynocephalus

Hybrids between Papio anubis and P. cynocephalus occur in nature. We have studied laboratory bred hybrids, together with their backcrossed offspring. Electrophoretic experiments on the proteins, serum enzymes and erythrocytes obtained from both hybrids and parents lead to three conclusions. First, both parents and hybrids possess proteins having identical mobilities; this case is the most frequent in the 23 loci studied. Second, individual polymorphism caused by, for example, carbonic anhydrase I or transferrin in one or both parents results in the appearance of a codominant phenotype in the hybrid, when the parental components are distinguishable. Third, when other enzymes such as albumin, alkaline phosphatase, haemoglobin and the serum esterases have particular electrophoretic mobilities in the parents, then the hybrid is again codominant; a particularly interesting case among the esterases is that of pseudocholinesterase, where the paternal component is partially repressed in the hybrid. The hybrid than exhibits the phenomenon of allelic repression of at least one gene, which confirms the taxonomic position of species of the two forms of Papio studied.     

Characterization and prediction of lysine (K)-acetyl-transferase specific acetylation sites

Lysine acetylation is a well-studied post-translational modification on both histone and nonhistone proteins. More than 2000 acetylated proteins and 4000 lysine acetylation sites have been identified by large scale mass spectrometry or traditional experimental methods. Although over 20 lysine (K)-acetyl-transferases (KATs) have been characterized, which KAT is responsible for a given protein or lysine site acetylation is mostly unknown. In this work, we collected KAT-specific acetylation sites manually and analyzed sequence features surrounding the acetylated lysine of substrates from three main KAT families (CBP/p300, GCN5/PCAF, and the MYST family). We found that each of the three KAT families acetylates lysines with different sequence features. Based on these differences, we developed a computer program, Acetylation Set Enrichment Based method to predict which KAT-families are responsible for acetylation of a given protein or lysine site. Finally, we evaluated the efficiency of our method, and experimentally detected four proteins that were predicted to be acetylated by two KAT families when one representative member of the KAT family is over expressed. We conclude that our approach, combined with more traditional experimental methods, may be useful for identifying KAT families responsible for acetylated substrates proteome-wide.     

Alterations of hemorheological parameters and tubulin content in erythrocytes from diabetic subjects

Treatment of human erythrocytes with high glucose concentrations altered the content and distributions of three tubulin isotypes, with consequent reduction of erythrocyte deformability and osmotic resistance. In erythrocytes from diabetic subjects (D erythrocytes), (i) tubulin in the membrane-associated fraction (Mem-Tub) was increased and tubulin in the sedimentable fraction (Sed-Tub) was decreased, (ii) deformability was lower than in erythrocytes from normal subjects (N erythrocytes), and (iii) detyrosinated/acetylated tubulin content was higher in the Mem-Tub fraction and tyrosinated/acetylated tubulin content was higher in the Sed-Tub fraction, in comparison with N erythrocytes. Similar properties were observed for human N erythrocytes treated with high glucose concentrations, and for erythrocytes from rats with streptozotocin-induced diabetes. In N erythrocytes, high-glucose treatment caused translocation of tubulin from the Sed-Tub to Mem-Tub fraction, thereby reducing deformability and inducing acetylation/tyrosination in the Sed-Tub fraction. The increased tubulin acetylation in these cells resulted from inhibition of deacetylase enzymes. Increased tubulin acetylation and translocation of this acetylated tubulin to the Mem-Tub fraction were both correlated with reduced osmotic resistance. Our findings suggest that (i) high glucose concentrations promote tubulin acetylation and translocation of this tubulin to the membrane, and (ii) this tubulin is involved in regulation of erythrocyte deformability and osmotic fragility.     

Positional proteomics: preparation of amino-terminal peptides as a strategy for proteome simplification and characterization

We describe a protocol for selective extraction of the amino (N)-terminal-most peptide of a protein or a mixture of proteins after proteolysis. The first stage of the protocol blocks the free amino groups alpha and epsilon (the latter being lysyl residues) on the intact proteins by acetylation. In the second stage, proteolysis of the acetylated proteins yields a mixture of N-terminally acetylated (true N-terminal) and non-acetylated (internal and carboxy-terminal) peptides. Affinity capture of peptides bearing free amino groups using an immobilized amine-reactive reagent removes internal peptides from the mixture. The unbound fraction is highly enriched in N-terminal peptides, which can be analyzed without further treatment. This method is compatible with a range of proteolytic enzymes and fragmentation methods, and should take 2 d to complete. The N-terminal peptides can then be analyzed by mass spectrometry. This low cost, rapid method is readily adopted using off the shelf reagents.     

Histone methylation. Its occurrence in different cell types and relation to histone H4 metabolism in developing trout testis.

Histone methylation in developing trout testis has been observed in the diploid stem cells and primary spermatocytes, which actively synthesize DNA and histones. In spermatids, histone methylation is minimal and so probably plays no role in the replacement of histones by protamine which is characteristic of this cell type. No turnover of histone methyl groups could be detected over several hours, so that unlike acetylation or phosphorylation of histones, methylation in this tissue appears to be a stable, irreversible modification. When histone H4, labeled with [14C]methyl groups, is separated on starch gels into acetylated and phosphorylated derivatives, [14C]methyl label does not appear in positions characteristic of newly synthesized histone H4, i.e. the highly acetylated (di-, tri-, and tetra-acetylated), unphosphorylated species. [14C]Methyl label appears rather in the unphosphorylated, and unacetylated or monoacetylated species, shifting with time to the monophosphorylated form of histone H4. These data suggest a temporal sequence of events for histone H4: synthesis, then acetylation and deacetylation, followed by methylation and phosphorylation. Occurring late after histone synthesis and assembly into chromatin, histone methylation might then be necessary for histone interactions with other molecules (e.g. histone phosphokinase) prior to mitosis.     

Modification of histone binding in calf thymus chromatin and in the chromatin-protamine complex by acetic anhydride.

A relationship between side-chain modification of histones and their displaceability from DNA has been investigated using calf thymus chromatin which was chemically acetylated with acetic anhydride. When the chromatin is treated with increasingly higher concentrations of the reagent, histones become acetylated to an increasingly greater extent, attaining the modification at 23-24 sites for histone I, 5-6 for IIb1, 9-10 for IIb2, 5-6 for III and 3-4 for IV. As the chromatin becomes more acetylated, NaCl concentrations required for histone removal are lowered. Saturation binding of protamine does not bring about either an increase in the number of acetylation sites of histones in chromatin or a decrease of the NaCl requirement for dissociation of the acetylated chromatins. A comparison of the present results with the extents of histone acetylation known to occur enzymatically in vivo indicates that the complete removal of somatic histones during transformation of chromatin in spermiogenesis cannot be explained on the basis of decreased binding of the histone to DNA by acetylation or by a combination of acetylation and protamine binding, suggesting that the displacement process may require some additional processes.     

Core histone hyperacetylation co-maps with generalized DNase I sensitivity in the chicken beta-globin chromosomal domain.

The distribution of core histone acetylation across the chicken beta-globin locus has been mapped in 15 day chicken embryo erythrocytes by immunoprecipitation of mononucleosomes with an antibody recognizing acetylated histones, followed by hybridization probing at several points in the locus. A continuum of acetylation was observed, covering both genes and intergenic regions. Using the same probes, the generalized sensitivity to DNase I was mapped by monitoring the disappearance of intact genomic restriction fragments from Southern transfers. Close correspondence between the 33 kb of sensitive chromatin and the extent of acetylation indicates that one role of the modification could be the generation and/or maintenance of the open conformation. The precision of acetylation mapping makes it a possible approach to the definition of chromosomal domain boundaries.     

The fasted/fed mouse metabolic acetylome: N6-acetylation differences suggest acetylation coordinates organ-specific fuel switching

The elucidation of extra-nuclear lysine acetylation has been of growing interest, as the cosubstrate for acetylation, acetyl CoA, is at a key metabolic intersection. Our hypothesis was that mitochondrial and cytoplasmic protein acetylation may be part of a fasted/re-fed feedback control system for the regulation of the metabolic network in fuel switching, where acetyl CoA would be provided by fatty acid oxidation, or glycolysis, respectively. To test this, we characterized the mitochondrial and cytoplasmic acetylome in various organs that have a high metabolic rate relative to their mass, and/or switch fuels, under fasted and re-fed conditions (brain, kidney, liver, skeletal muscle, heart muscle, white and brown adipose tissues). Using immunoprecipitation, coupled with LC-MS/MS label free quantification, we show there is a dramatic variation in global quantitative profiles of acetylated proteins from different organs. In total, 733 acetylated peptides from 337 proteins were identified and quantified, out of which 31 acetylated peptides from the metabolic proteins that may play organ-specific roles were analyzed in detail. Results suggest that fasted/re-fed acetylation changes coordinated by organ-specific (de)acetylases in insulin-sensitive versus -insensitive organs may underlie fuel use and switching. Characterization of the tissue-specific acetylome should increase understanding of metabolic conditions wherein normal fuel switching is disrupted, such as in Type II diabetes.     

Selective isolation of polypeptide chains bearing multiple types of postsynthetic modifications. Recovery of simultaneously acetylated and phosphorylated forms of histone H2A and high mobility group proteins 14 and 17

In order to study coordinate or simultaneous modifications of chromosomal proteins by phosphorylation and acetylation, duck erythrocytes were incubated with [32P]orthophosphate and the thiol-containing acetate analogue, 2-mercaptoacetate. Enzymatic transfer of the analogue to the epsilon-amino groups of lysine residues permits the selective recovery of the newly thio-derivatized polypeptide chains by Hg-affinity chromatography, and this acetylated subpopulation can then be analyzed for [32P]phosphate uptake. The histones and high mobility group proteins were extracted from cell nuclei, purified, and finally analyzed for incorporation of [32P]phosphate and 2-mercaptoacetate. Several of the nuclear proteins, in particular histone H2A and the high mobility group proteins HMG-14 and HMG-17, were subjected to organomercurial-agarose chromatography. Significant amounts of these cysteine-free proteins were retained on the affinity column, and by this criterion were shown to have incorporated mercaptoacetate. The mercaptoacetylated proteins were further analyzed and found to contain the 32P label as well. These observations provide incontrovertible evidence that individual molecules of chromosomal proteins can carry postsynthetic modifications in the form of phosphorylation and acetylation at the same time, and also establish that both types of modification must have occurred during the short period in which the cells were exposed to the two precursors.