Project description:Lysine acetylation is thought to provide a mechanism for regulating metabolism in diverse bacteria. Indeed, many studies have shown that the majority of enzymes involved in central metabolism are acetylated and that acetylation can alter enzyme activity. However, the details regarding this regulatory mechanism are still unclear, specifically with regards to the signals inducing lysine acetylation. To better understand this global regulatory mechanism, we profiled changes in lysine acetylation during growth of Escherichia coli on glucose or xylose at both high and low sugar concentrations using label-free mass spectrometry. The goal was to see whether lysine acetylation differed during growth on these two sugars. No significant differences, however, were observed. Rather, the initial sugar concentration was the principal factor governing changes in lysine acetylation, with higher sugar concentrations causing more acetylation. These results suggest that acetylation does not target specific metabolic pathways but rather simply targets with accessible lysines, which may or may not alter enzyme activity. They further suggest that lysine acetylation principally results from conditions that favor accumulation of acetyl phosphate, the principal acetate donor in E. coli.

Project description:Although protein acetylation is widely observed, it has been associated with few specific regulatory functions making it poorly understood. To interrogate its functionality, we analyzed the acetylome in Escherichia coli knockout mutants of cobB, the only known sirtuin-like deacetylase, and patZ, the best-known protein acetyltransferase. For four growth conditions, more than 2,000 unique acetylated peptides, belonging to 809 proteins, were identified and differentially quantified. Nearly 65% of these proteins are related to metabolism. The global activity of CobB contributes to the deacetylation of a large number of substrates and has a major impact on physiology. Apart from the regulation of acetyl-CoA synthetase, we found that CobB-controlled acetylation of isocitrate lyase contributes to the fine-tuning of the glyoxylate shunt. Acetylation of the transcription factor RcsB prevents DNA binding, activating flagella biosynthesis and motility, and increases acid stress susceptibility. Surprisingly, deletion of patZ increased acetylation in acetate cultures, which suggests that it regulates the levels of acetylating agents. The results presented offer new insights into functional roles of protein acetylation in metabolic fitness and global cell regulation. In this study we aimed to discover how the deregulation of protein acetylation could alter physiology in E. coli. We observed that the deletion of both cobB or patZ genes in E. coli altered gene expression, specially those genes related with motility, chemotaxis and acid stress response. We used three biological replicates in this study and each condition. The control in these experiments was E. coli BW25113

Project description:The histone-like protein HU is crucial for genome organization and the expression of many genes in Escherichia coli. HU binds DNA independent of any specific nucleotide sequence but exhibits two binding affinities; low-affinity to any B-DNA (non-specific) and high affinity to DNA with distortions like kinks and cruciforms (structure-specific). We validated and defined the three conserved lysine residues, K3, K18, and K83, in HU as critical amino acid residues for the non-specific binding and the conserved P63 together with the lysine residues critical for the structure-specific binding both in vitro and in vivo. By determining the effects of disrupting the two DNA binding modes on various HU-dependent physiological processes, we demonstrate that the DNA structure-specific binding regulates expression of many genes including those involved in DNA metabolic processes that control chromosome maintenance and partition. On the other hand, HU associates with the chromosome at numerous sites primarily through the lysines-mediated non-specific binding and control chromosome dynamics and structural maintenance. Thus, we demonstrate that two different DNA binding mode of HU plays separate roles: (i) The high-affinity DNA structure-specific binding regulates many distinct DNA metabolic processes, primarily through transcription regulation. (ii) Its low-affinity, non-specific binding directly helps general organization of the genome.

Project description:Protein lysine acetylation (Kac) is an important post-translational modification (PTM) mechanism in both eukaryotes and prokaryotes, with key roles in cellular regulation. To investigate the role of Kac in plants infected with virus, we characterized the lysine acetylome of Nicotiana benthamiana plants with or without a Chinese Wheat Mosaic Virus (CWMV) infection by using TMT labeling-based protein modification differential analysis, high-resolution liquid chromatography mass spectrometry analysis, and integrated bioinformatics analysis. Here, we identified 4803 acetylated lysine sites on 1964 proteins. A comparison of the acetylation levels of the CWMV-infected group with those of the uninfected group revealed that 747 sites were up-regulated on 422 proteins, including chloroplast localization proteins and histone H3, and 150 sites were down-regulated on 102 proteins when using a change threshold of at least 1.2 times and a t-test p-value of <0.05. Nineteen conserved motifs were extracted; 51% of the identified proteins were localized to the chloroplast. Among the acetylated proteins, 19 Kac sites were combined in core histones, including 10 Kac sites on histone 3. Bioinformatics analysis revealed that Kac occurs on a diverse range of proteins involved in a wide variety of biological processes, especially photosynthesis. Furthermore, we demonstrate that the acetylation level of chloroplast localization proteins and histone H3 are significantly increased. In summary, our results reveal the regulatory roles of Kac in response to CWMV infection.

Project description:Although protein acetylation is widely observed, it has been associated with few specific regulatory functions making it poorly understood. To interrogate its functionality, we analyzed the acetylome in Escherichia coli knockout mutants of cobB, the only known sirtuin-like deacetylase, and patZ, the best-known protein acetyltransferase. For four growth conditions, more than 2,000 unique acetylated peptides, belonging to 809 proteins, were identified and differentially quantified. Nearly 65% of these proteins are related to metabolism. The global activity of CobB contributes to the deacetylation of a large number of substrates and has a major impact on physiology. Apart from the regulation of acetyl-CoA synthetase, we found that CobB-controlled acetylation of isocitrate lyase contributes to the fine-tuning of the glyoxylate shunt. Acetylation of the transcription factor RcsB prevents DNA binding, activating flagella biosynthesis and motility, and increases acid stress susceptibility. Surprisingly, deletion of patZ increased acetylation in acetate cultures, which suggests that it regulates the levels of acetylating agents. The results presented offer new insights into functional roles of protein acetylation in metabolic fitness and global cell regulation. In this study we aimed to discover how the deregulation of protein acetylation could alter physiology in E. coli. We observed that the deletion of both cobB or patZ genes in E. coli altered gene expression, specially those genes related with motility, chemotaxis and acid stress response.

Project description:Lysine acetylation (Kac) plays a critical role in the regulation of a great deal of important cellular processes. However, little is known about Kac in Solenopsis invicta, which is one of the 100 most dangerous invasive species in the world. Lysine acetylome in S. invicta was evaluated for the first time in this study. Altogether, 2387 Kac sites were tested in 992 proteins. The prediction of subcellular localization indicated that most identified proteins were located in cytoplasm, mitochondria and nucleus. The enriched Kac site motifs included Kac H, Kac Y, Kac G, Kac F, Kac T, and Kac W. H, Y, F, and W were of frequent occurrence at the +1 position, whereas G, Y and T were of frequent occurrence at the –1 position. Based on cellular component, acetylated proteins were enriched in cytoplasmic part, mitochondrial matrix, and cytosolic ribosome. Furthermore, 25 pathways were detected to be significantly enriched. Interestingly, arginine and proline metabolism as well asphagosome, which were related to immunity, contained several Kac proteins. Acetylation or deacetylation of the proline and phagosome proteins may adjust the protein function, which may be why S. invicta was highly immune. As for interaction network investigation, diverse interactions were adjusted by Kac. Our study of lysine acetylome supplies abundant information for function analysis of reversible Kac in the growth and development of S. invicta and other Hymenoptera insects. Confirming the functions of Kac target proteins may be useful to design specific and effective drugs to prevent and control this dangerous invasive species.

Project description:Protein post-translational modifications (PTMs) play crucial roles in various biological processes across prokaryotes and eukaryotes. Lysine acetylation (Kac), which is observed in different bacteria species and is known to be a dynamic and reversible PTM involved in numerous physiological functions. However, limited research has been conducted to explore the connection between Kac and bacterial antibiotic resistance. In this investigation, we employed advanced 4D label-free quantitative proteomics technology to examine the differential expression of Kac-modified proteins in Staphylococcus aureus strains: one susceptible to erythromycin (Ery-S) and another induced to be resistant (Ery-R). Our systematic analysis identified a total of 1808 acetylated proteins with 6791 specific Kac sites. Notably, we quantified 1907 of these sites across 483 proteins. A total of 548 Kac sites were affected by erythromycin pressure on 316 acetylated proteins. Functional analyses uncovered a notable presence of differentially acetylated proteins (DAPs) within pathways associated with ribosome assembly, glycolysis, and lysine biosynthesis. Moreover, our findings indicate a significant acetylation of ribosomal proteins in antibiotic-resistant strains, implying a potential regulatory role of this modification in translation processes. Further investigations using polysome profiling experiments revealed that Kac modification of ribosomal and ribosome-associated proteins can maintain translation in response to antibiotic stress. Our data provides support for the link between protein lysine acetylation and bacterial antibiotic resistance, highlighting the potential involvement of ribosome translation. These findings collectively unveil a novel mechanism that enhances our understanding of bacterial antibiotic resistance and offer valuable insights for the development of antibiotic treatment strategies.

Project description:Protein lysine acetylation, a dynamic and reversible posttranslational modification, plays a crucial role in several cellular processes including cell cycle regulation, metabolic pathways, enzymatic activities and protein interactions. Brenneria nigrifluens is the pathogen of shallow bark canker of walnut trees and can cause serious disease on walnut trees. Up to now, it is little known about the roles of lysine acetylation in the plant pathogenic bacteria. In the present study, the lysine acetylome of B. nigrifluens was determined by high-resolution LC-MS/MS analysis. In total, we identified 1,866 lysine acetylation sites distributed in 737 acetylated proteins. Bioinformatics results indicate that acetylated proteins participate in many different biological functions in B. nigrifluens. Four conserved motifs, namely, LKac, Kac*F, I*Kac and L*Kac, were identified in this bacterium. Protein interaction network analysis indicates that all kinds of interactions are modulated by protein lysine acetylation. Overall, 14 acetylated proteins are related to the virulence of B. nigrifluens.

Project description:Acetylation modifies protein subcellular localization, stability, enzymatic activity, and protein-protein and protein-DNA interactions, playing a crucial role in mediating protein function. However, research on non-histone acetylation remains limited. This study investigates changes in lysine acetylation (Kac) in proteins in response to drought using 4D label-free quantitative lys-acetylproteome analysis. We identified a total of 15,064 acetylated peptides across 4,393 proteins, with 2,486 Kac sites exhibiting significant changes: 246 proteins showed increased Kac levels, while 1,406 displayed reductions. Notably, proteins associated with metabolic pathways, such as nucleotide sugar biosynthesis, proteasome, glutamate decarboxylase and the tricarboxylic acid (TCA) cycle, were significantly impacted. The alterations in Kac levels correlated with various KEGG pathways, suggesting that acetylation plays a regulatory role in drought response mechanisms. Furthermore, we identified specific acetylation sites in transcription factors (TFs), highlighting their involvement in this process. Functional validation demonstrated that mutations in Kac sites of five randomly selected TFs resulted in significant changes in drought tolerance, emphasizing the critical role of lysine acetylation in modulating stress responses. Overall, our findings indicate that Kac modification serves as a key regulatory mechanism in birch adaptation to drought stress, influencing both metabolic processes and transcriptional regulation.

Project description:Candida albicans is an opportunistic fungal pathogen capable of causing superficial mucosal and systemic infections, sometimes leading to life-threatening conditions. The increasing resistance of C. albicans to azole antifungals has become a significant challenge in clinical treatment. Lysine acetylation (Kac) is a well-studied post-translational modification that plays crucial roles in various biological processes. However, its impact on antifungal resistance in C. albicans remains poorly understood. Five strains of C. albicans isolated from the same patient, representing different stages of acquired fluconazole resistance in vivo, were used in this study to investigate the potential regulatory mechanism of Kac on the development of azole resistance in C. albicans. Quantitative proteomic analysis using tandem mass tag (TMT) labeling, acetylation enrichment, and liquid chromatography-mass spectrometry (LC-MS) was conducted on these five strains. We divided all strains into four comparison groups and identified a total of 1796 lysine acetylation sites across 938 proteins, with quantitative data available for 1314 acetylation sites in 712 proteins. Analysis of 155 significantly differentially modified sites revealed that the acetylation levels of key proteins involved in the conversion of pyruvate to acetyl-CoA for entry into the tricarboxylic acid (TCA) cycle for energy production were initially downregulated and then upregulated during the acquisition of fluconazole resistance. Additionally, the acetylation levels of proteins involved in ribosome synthesis, translation processes, and amino acid synthesis were found to increase. Therefore, lysine acetylation in C. albicans may contribute to azole resistance by regulating energy metabolism and protein synthesis.