The intracellular pathogen Mycobacterium tuberculosis (Mtb) causes tuberculosis. Enhanced intracellular survival (Eis) protein, secreted by Mtb, enhances survival of Mycobacterium smegmatis (Msm) in macrophages. Mtb Eis was shown to suppress host immune defenses by negatively modulating autophagy, inflammation, and cell death through JNK-dependent inhibition of reactive oxygen species (ROS) generation. Mtb Eis was recently demonstrated to contribute to drug resistance by acetylating multiple amines of aminoglycosides. However, the mechanism of enhanced intracellular survival by Mtb Eis remains unanswered. Therefore, we have characterized both Mtb and Msm Eis proteins biochemically and structurally. We have discovered that Mtb Eis is an efficient N ɛ -acetyltransferase, rapidly acetylating Lys55 of dualspecificity protein phosphatase 16 (DUSP16)/mitogen-activated protein kinase phosphatase-7 (MKP-7), a JNK-specific phosphatase. In contrast, Msm Eis is more efficient as an N α -acetyltransferase. We also show that Msm Eis acetylates aminoglycosides as readily as Mtb Eis. Furthermore, Mtb Eis, but not Msm Eis, inhibits LPSinduced JNK phosphorylation. This functional difference against DUSP16/MKP-7 can be understood by comparing the structures of two Eis proteins. The active site of Mtb Eis with a narrow channel seems more suitable for sequence-specific recognition of the protein substrate than the pocket-shaped active site of Msm Eis. We propose that Mtb Eis initiates the inhibition of JNK-dependent autophagy, phagosome maturation, and ROS generation by acetylating DUSP16/MKP-7. Our work thus provides insight into the mechanism of suppressing host immune responses and enhancing mycobacterial survival within macrophages by Mtb Eis.Rv2416c | lysine acetylation | antituberculosis drug N early one-third of the world's population is infected with Mycobacterium tuberculosis (Mtb). This pathogenic bacterium causes tuberculosis, which claims the lives of millions of people every year (1). Tuberculosis has also become a global health issue owing to the increased incidences of multidrug-resistant and extensively drug-resistant strains of Mtb (2). This makes a search for targets of new antituberculosis drugs urgent. Mtb is a highly successful human pathogen, surviving and multiplying within the human macrophage cells of the infected people (3). Therefore, treatment of tuberculosis is difficult, requiring many months of taking a combination of antibiotics. Mtb has the ability to persist in the form of a long-term asymptomatic infection, referred to as latent tuberculosis (4). Latent tuberculosis becomes activated when the body's immune system is weakened. As a result, tuberculosis is the major cause of death among immuno-compromised AIDS patients (5).In mycobacterial infection, host innate immune responses may play a crucial role in early protection against Mtb infection, leading to establishment of effective adaptive immunity to tuberculosis (6). Additionally, MAPK pathways are activated by Mtb or its components and play an e...
The crystal structure of M. tuberculosis l,d-transpeptidase (LdtMt2; Rv2518c) has been determined in both ligand-free and meropenem-bound forms. The detailed view of the interactions between meropenem and LdtMt2 will be useful in structure-guided discovery of new antituberculosis drugs.
Serine protease inhibitors (serpins) are metastable in their native state. This strain, which is released upon binding to target proteases, is essential for the inhibitory activity of serpins. To understand the structural basis of the native strain, we previously characterized stabilizing mutations of ␣ 1 -antitrypsin, a prototypical inhibitory serpin, in regions such as the hydrophobic core. The present study evaluates the effects of single point mutations throughout the molecule on stability and protease inhibitory activity. We identified stabilizing mutations in most secondary structures, suggesting that the native strain is distributed throughout the molecule. Examination of the substitution patterns and the structures of the mutation sites revealed surface hydrophobic pockets as a component of the native strain in ␣ 1 -antitrypsin, in addition to the previously identified unusual interactions such as side chain overpacking and cavities. Interestingly, many of the stabilizing substitutions did not affect the inhibitory activity significantly. Those that affected the activity were confined in the regions that are mobilized during the complex formation with a target enzyme. The results of our study should be useful for designing proteins with strain and for regulating the stability and functions of serpins.1 is a prototype of the serpin (serine protease inhibitor) superfamily that shares a common tertiary structure composed of three -sheets and several ␣-helices (1). Serpins include protease inhibitors in blood plasma such as ␣ 1 AT, ␣ 1 -antichymotrypsin, antithrombin III, plasminogen activator inhibitor-I, C1 inhibitor, and ␣ 2 -antiplasmin, as well as non-inhibitory members such as ovalbumin and angiotensinogen (1, 2). One salient feature of the inhibitory serpin structure is the strain in the native conformation (3-7), which is necessary for biological functions such as protease inhibition and ligand binding (1,2,8,9). The inhibition process of serpins can be described as a suicide substrate mechanism (10 -12) in which serpins, upon binding proteases, partition between cleaved serpins and stable serpin-enzyme complexes. The stoichiometry of inhibition (SI; the number of moles of inhibitor required to completely inhibit 1 mol of a target protease) is designated as 1 ϩ k substrate /k inhibition , in which k substrate is the rate constant for the substrate pathway toward the cleaved serpin and k inhibition is the rate constant for the inhibitory pathway toward the complex formation. For cognate target proteases, most serpin molecules partition into the complex formation, bringing the SI values close to 1. During the complex formation, the reactive center loop (RCL) of inhibitory serpins is cleaved (13-15) and inserted into the major -sheet, A sheet, forming a stable complex between the serpin and the protease (11,12,(15)(16)(17). It has been suggested that the rate of loop insertion is critical for inhibitory function; retardation of the loop insertion would alter the partitioning between the inhibitory and...
Background: Csd6 is one of the cell shape-determining proteins in H. pylori.Results: The active site of Csd6 is tailored to function as an l,d-carboxypeptidase in the peptidoglycan-trimming process.Conclusion: Csd6 constitutes a new family of l,d-carboxypeptidase.Significance: The substrate limitation of Csd6 is a strategy that H. pylori uses to regulate its helical cell shape and motility.
For successful infection of their hosts, pathogenic bacteria recognize host-derived signals that induce the expression of virulence factors in a spatiotemporal manner. The fulminating food-borne pathogen Vibrio vulnificus produces a cytolysin/hemolysin protein encoded by the vvhBA operon, which is a virulence factor preferentially expressed upon exposure to murine blood and macrophages. The Fe-S cluster containing transcriptional regulator IscR activates the vvhBA operon in response to nitrosative stress and iron starvation, during which the cellular IscR protein level increases. Here, electrophoretic mobility shift and DNase I protection assays revealed that IscR directly binds downstream of the vvhBA promoter PvvhBA, which is unusual for a positive regulator. We found that in addition to IscR, the transcriptional regulator HlyU activates vvhBA transcription by directly binding upstream of PvvhBA, whereas the histone-like nucleoid-structuring protein (H-NS) represses vvhBA by extensively binding to both downstream and upstream regions of its promoter. Of note, the binding sites of IscR and HlyU overlapped with those of H-NS. We further substantiated that IscR and HlyU outcompete H-NS for binding to the PvvhBA regulatory region, resulting in the release of H-NS repression and vvhBA induction. We conclude that concurrent antirepression by IscR and HlyU at regions both downstream and upstream of PvvhBA provides V. vulnificus with the means of integrating host-derived signal(s) such as nitrosative stress and iron starvation for precise regulation of vvhBA transcription, thereby enabling successful host infection.
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