The cyclic dinucleotide c-di-AMP is an allosteric regulator of metabolic enzyme function.

Cyclic di-adenosine monophosphate (c-di-AMP) is a broadly conserved second messenger required for bacterial growth and infection. However, the molecular mechanisms of c-di-AMP signaling are still poorly understood. Using a chemical proteomics screen for c-di-AMP-interacting proteins in the pathogen Listeria monocytogenes, we identified several broadly conserved protein receptors, including the central metabolic enzyme pyruvate carboxylase (LmPC). Biochemical and crystallographic studies of the LmPC-c-di-AMP interaction revealed a previously unrecognized allosteric regulatory site 25 Å from the active site. Mutations in this site disrupted c-di-AMP binding and affected catalytic activity of LmPC as well as PC from pathogenic Enterococcus faecalis. C-di-AMP depletion resulted in altered metabolic activity in L. monocytogenes. Correction of this metabolic imbalance rescued bacterial growth, reduced bacterial lysis, and resulted in enhanced bacterial burdens during infection. These findings greatly expand the c-di-AMP signaling repertoire and reveal a central metabolic regulatory role for a cyclic dinucleotide.

Cyclic di-AMP targets the cystathionine beta-synthase domain of the osmolyte transporter OpuC.

Cellular turgor is of fundamental importance to bacterial growth and survival. Changes in external osmolarity as a consequence of fluctuating environmental conditions and colonization of diverse environments can significantly impact cytoplasmic water content, resulting in cellular lysis or plasmolysis. To ensure maintenance of appropriate cellular turgor, bacteria import ions and small organic osmolytes, deemed compatible solutes, to equilibrate cytoplasmic osmolarity with the extracellular environment. Here, we show that elevated levels of c-di-AMP, a ubiquitous second messenger among bacteria, result in significant susceptibility to elevated osmotic stress in the bacterial pathogen Listeria monocytogenes. We found that levels of import of the compatible solute carnitine show an inverse correlation with intracellular c-di-AMP content and that c-di-AMP directly binds to the CBS domain of the ATPase subunit of the carnitine importer OpuC. Biochemical and structural studies identify conserved residues required for this interaction and transport activity in bacterial cells. Overall, these studies reveal a role for c-di-AMP mediated regulation of compatible solute import and provide new insight into the molecular mechanisms by which this essential second messenger impacts bacterial physiology and adaptation to changing environmental conditions.

RseA, the SigE specific anti-sigma factor of Mycobacterium tuberculosis, is inactivated by phosphorylation-dependent ClpC1P2 proteolysis.

Central to the response of Mycobacterium tuberculosis to environmental stress is the regulation of genes under the control of alternative sigma factors. Sigma E of M. tuberculosis plays an important role in the intracellular life of the bacterium and regulates several genes which are important for maintaining the integrity of the cell envelope stress. This makes it important to understand how SigE is activated under stress. Here we elucidate the mechanisms regulating interaction of SigE with its cognate anti-sigma factor RseA. Cysteines 70 and 73 are required for redox-dependent interaction of RseA with SigE. Under surface stress, PknB-dependent phosphorylation of RseA on T39 is required for its cleavage by ClpC1P2 thereby activating the SigE regulon. Rv2745c (MSMEG_2694), a transcriptional regulator, activates the clp regulon in response to vancomycin-induced stress. Taken together with the previous report that Rv2745c is activated by SigE, our study uncovers a positive feedback loop that activates the sigE regulon under envelope stress.

Spike protein mutational landscape in India during the complete lockdown phase: Could Muller's ratchet be a future game-changer for COVID-19?

The dire need of effective preventive measures and treatment approaches against SARS-CoV-2 virus, causing COVID-19 pandemic, calls for an in-depth understanding of its evolutionary dynamics with attention to specific geographic locations, since lockdown and social distancing to prevent the virus spread could lead to distinct localized dynamics of virus evolution within and between countries owing to different environmental and host-specific selection pressures. To decipher any correlation between SARS-CoV-2 evolution and its epidemiology in India, we studied the mutational diversity of spike glycoprotein, the key player for the attachment, fusion and entry of virus to the host cell. For this, we analyzed the sequences of 630 Indian isolates as available in GISAID database till June 07, 2020 (during the time-period before the start of Unlock 1.0 in India on and from June 08, 2020), and detected the spike protein variants to emerge from two major ancestors - Wuhan-Hu-1/2019 and its D614G variant. Average stability of the docked spike protein - host receptor (S-R) complexes for these variants correlated strongly (R2 = 0.96) with the fatality rates across Indian states. However, while more than half of the variants were found unique to India, 67% of all variants showed lower stability of S-R complex than the respective ancestral variants, indicating a possible fitness loss in recently emerged variants, despite a continuous increase in mutation rate. These results conform to the sharply declining fatality rate countrywide (>7-fold during April 11 - June 28, 2020). Altogether, while we propose the potential of S-R complex stability to track disease severity, we urge an immediate need to explore if SARS-CoV-2 is approaching mutational meltdown in India.

Polyphosphate kinase 2: a modulator of nucleoside diphosphate kinase activity in mycobacteria.

Mycobacteria encode putative class II polyphosphate kinases (PPKs). We report that recombinant PPK2 of Mycobacterium tuberculosis catalyses the synthesis of GTP from GDP using polyphosphate rather than ATP as phosphate donor. Unlike that of PPK1, this is the favoured reaction of PPK2. The sites of autophosphorylation, H115 and H247, as well as G74 were critical for GTP-synthesizing activity. Compromised survival of a ppk2 knockout (PPK2-KO) of Mycobacterium smegmatis under heat or acid stress or hypoxia, and the ability of ppk2 of M. tuberculosis to complement this, confirmed that PPK2 plays a role in mycobacterial survival under stress. Intracellular ATP : GTP ratio was higher in PPK2-KO compared with the wild-type M. smegmatis, bringing to light a role of PPK2 in regulating the intracellular nucleotide pool. We present evidence that PPK2 does so by interacting with nucleoside diphosphate kinase (Ndk). Pull-down assays and analysis by surface plasmon resonance demonstrated that the interaction requires G74 of PPK2(MTB) and (109)LET(111) of Ndk(MTB). In summary, we unravel a novel mechanism of regulation of nucleotide pools in mycobacteria. Downregulation of ppk2 impairs survival of M. tuberculosis in macrophages, suggesting that PPK2 plays an important role in the physiology of the bacteria residing within macrophages.

Novel role of Wag31 in protection of mycobacteria under oxidative stress.

Wag31 of Mycobacterium tuberculosis belongs to the DivIVA family of proteins known to regulate cell morphology in Gram-positive bacteria. Here we demonstrate an unrecognized, novel role of Wag31 in oxidatively stressed mycobacteria. We report the cleavage of penicillin-binding protein 3 (PBP3) by the intramembrane metalloprotease Rv2869c (MSMEG_2579) in oxidatively stressed cells. Amino acids (102)A and (103)A of PBP3 are required for Rv2869c-mediated cleavage. Wag31(MTB), by virtue of its interaction with PBP3 through amino acid residues (46)NSD(48), protects it from oxidative stress-induced cleavage. PBP3 undergoes cleavage in Mycobacterium smegmatis (strain PM2) harbouring wag31(Delta(46)NSD(48)) instead of the wild type, with concomitant reduction in ability to withstand oxidative stress. Overexpression of Wag31(Delta(46)NSD(48)) attenuates the survival of M. tuberculosis in macrophages with concomitant cleavage of PBP3, and renders the organism more susceptible towards hydrogen peroxide as well as drugs which generate reactive oxygen species, namely isoniazid and ofloxacin. We propose that targeting Wag31 could enhance the activity of mycobactericidal drugs which are known to generate reactive oxygen species.

Molecular basis for the recognition of cyclic-di-AMP by PstA, a PII-like signal transduction protein.

Cyclic-di-AMP (c-di-AMP) is a broadly conserved bacterial second messenger that is of importance in bacterial physiology. The molecular receptors mediating the cellular responses to the c-di-AMP signal are just beginning to be discovered. PstA is a previously uncharacterized PII -like protein which has been identified as a c-di-AMP receptor. PstA is widely distributed and conserved among Gram-positive bacteria in the phylum Firmicutes. Here, we report the biochemical, structural, and functional characterization of PstA from Listeria monocytogenes. We have determined the crystal structures of PstA in the c-di-AMP-bound and apo forms at 1.6 and 2.9 Å resolution, respectively, which provide the molecular basis for its specific recognition of c-di-AMP. PstA forms a homotrimer structure that has overall similarity to the PII protein family which binds ATP. However, PstA is markedly different from PII proteins in the loop regions, and these structural differences mediate the specific recognition of their respective nucleotide ligand. The residues composing the c-di-AMP binding pocket are conserved, suggesting that c-di-AMP recognition by PstA is of functional importance. Disruption of pstA in L. monocytogenes affected c-di-AMP-mediated alterations in bacterial growth and lysis. Overall, we have defined the PstA family as a conserved and specific c-di-AMP receptor in bacteria.

Phenotypic heterogeneity in mycobacterial stringent response.

BACKGROUND: A common survival strategy of microorganisms subjected to stress involves the generation of phenotypic heterogeneity in the isogenic microbial population enabling a subset of the population to survive under stress. In a recent study, a mycobacterial population of M. smegmatis was shown to develop phenotypic heterogeneity under nutrient depletion. The observed heterogeneity is in the form of a bimodal distribution of the expression levels of the Green Fluorescent Protein (GFP) as reporter with the gfp fused to the promoter of the rel gene. The stringent response pathway is initiated in the subpopulation with high rel activity. RESULTS: In the present study, we characterise quantitatively the single cell promoter activity of the three key genes, namely, mprA, sigE and rel, in the stringent response pathway with gfp as the reporter. The origin of bimodality in the GFP distribution lies in two stable expression states, i.e., bistability. We develop a theoretical model to study the dynamics of the stringent response pathway. The model incorporates a recently proposed mechanism of bistability based on positive feedback and cell growth retardation due to protein synthesis. Based on flow cytometry data, we establish that the distribution of GFP levels in the mycobacterial population at any point of time is a linear superposition of two invariant distributions, one Gaussian and the other lognormal, with only the coefficients in the linear combination depending on time. This allows us to use a binning algorithm and determine the time variation of the mean protein level, the fraction of cells in a subpopulation and also the coefficient of variation, a measure of gene expression noise. CONCLUSIONS: The results of the theoretical model along with a comprehensive analysis of the flow cytometry data provide definitive evidence for the coexistence of two subpopulations with overlapping protein distributions.

Novel role of phosphorylation-dependent interaction between FtsZ and FipA in mycobacterial cell division.

The bacterial divisome is a multiprotein complex. Specific protein-protein interactions specify whether cell division occurs optimally, or whether division is arrested. Little is known about these protein-protein interactions and their regulation in mycobacteria. We have investigated the interrelationship between the products of the Mycobacterium tuberculosis gene cluster Rv0014c-Rv0019c, namely PknA (encoded by Rv0014c) and FtsZ-interacting protein A, FipA (encoded by Rv0019c) and the products of the division cell wall (dcw) cluster, namely FtsZ and FtsQ. M. smegmatis strains depleted in components of the two gene clusters have been complemented with orthologs of the respective genes of M. tuberculosis. Here we identify FipA as an interacting partner of FtsZ and FtsQ and establish that PknA-dependent phosphorylation of FipA on T77 and FtsZ on T343 is required for cell division under oxidative stress. A fipA knockout strain of M. smegmatis is less capable of withstanding oxidative stress than the wild type and showed elongation of cells due to a defect in septum formation. Localization of FtsQ, FtsZ and FipA at mid-cell was also compromised. Growth and survival defects under oxidative stress could be functionally complemented by fipA of M. tuberculosis but not its T77A mutant. Merodiploid strains of M. smegmatis expressing the FtsZ(T343A) showed inhibition of FtsZ-FipA interaction and Z ring formation under oxidative stress. Knockdown of FipA led to elongation of M. tuberculosis cells grown in macrophages and reduced intramacrophage growth. These data reveal a novel role of phosphorylation-dependent protein-protein interactions involving FipA, in the sustenance of mycobacterial cell division under oxidative stress.

An oligopeptide transporter of Mycobacterium tuberculosis regulates cytokine release and apoptosis of infected macrophages.

BACKGROUND: The Mycobacterium tuberculosis genome encodes two peptide transporters encoded by Rv3665c-Rv3662c and Rv1280c-Rv1283c. Both belong to the family of ABC transporters containing two nucleotide-binding subunits, two integral membrane proteins and one substrate-binding polypeptide. However, little is known about their functions in M. tuberculosis. Here we report functional characterization of the Rv1280c-Rv1283c-encoded transporter and its substrate-binding polypeptide OppA(MTB). METHODOLOGY/PRINCIPAL FINDINGS: OppA(MTB) was capable of binding the tripeptide glutathione and the nonapeptide bradykinin, indicative of a somewhat broad substrate specificity. Amino acid residues G109, N110, N230, D494 and F496, situated at the interface between domains I and III of OppA, were required for optimal peptide binding. Complementaton of an oppA knockout mutant of M. smegmatis with OppA(MTB) confirmed the role of this transporter in importing glutathione and the importance of the aforesaid amino acid residues in peptide transport. Interestingly, this transporter regulated the ability of M. tuberculosis to lower glutathione levels in infected compared to uninfected macrophages. This ability was partly offset by inactivation of oppD. Concomitantly, inactivation of oppD was associated with lowered levels of methyl glyoxal in infected macrophages and reduced apoptosis-inducing ability of the mutant. The ability to induce the production of the cytokines IL-1beta, IL-6 and TNF-alpha was also compromised after inactivation of oppD. CONCLUSIONS: Taken together, these studies uncover the novel observations that this peptide transporter modulates the innate immune response of macrophages infected with M. tuberculosis.

Positive feedback and noise activate the stringent response regulator rel in mycobacteria.

Phenotypic heterogeneity in an isogenic, microbial population enables a subset of the population to persist under stress. In mycobacteria, stresses like nutrient and oxygen deprivation activate the stress response pathway involving the two-component system MprAB and the sigma factor, SigE. SigE in turn activates the expression of the stringent response regulator, rel. The enzyme polyphosphate kinase 1 (PPK1) regulates this pathway by synthesizing polyphosphate required for the activation of MprB. The precise manner in which only a subpopulation of bacterial cells develops persistence, remains unknown. Rel is required for mycobacterial persistence. Here we show that the distribution of rel expression levels in a growing population of mycobacteria is bimodal with two distinct peaks corresponding to low (L) and high (H) expression states, and further establish that a positive feedback loop involving the mprAB operon along with stochastic gene expression are responsible for the phenotypic heterogeneity. Combining single cell analysis by flow cytometry with theoretical modeling, we observe that during growth, noise-driven transitions take a subpopulation of cells from the L to the H state within a "window of opportunity" in time preceding the stationary phase. It is these cells which adapt to nutrient depletion in the stationary phase via the stringent response. We find evidence of hysteresis in the expression of rel in response to changing concentrations of PPK1. Hysteresis promotes robustness in the maintenance of the induced state. Our results provide, for the first time, evidence that bistability and stochastic gene expression could be important for the development of "heterogeneity with an advantage" in mycobacteria and suggest strategies for tackling tuberculosis like targeting transitions from the low to the high rel expression state.

Polyphosphate kinase is involved in stress-induced mprAB-sigE-rel signalling in mycobacteria.

Polyphosphate kinase 1 (PPK1) helps bacteria to survive under stress. The ppk1 gene of Mycobacterium tuberculosis was overexpressed in Escherichia coli and characterized. Residues R230 and F176, predicted to be present in the head domain of PPK1, were identified as residues critical for polyphosphate (polyP)-synthesizing ability and dimerization of PPK1. A ppk1 knockout mutant of Mycobacterium smegmatis was compromised in its ability to survive under long-term hypoxia. The transcription of the rel gene and the synthesis of the stringent response regulator ppGpp were impaired in the mutant and restored after complementation with ppk1 of M. tuberculosis, providing evidence that PPK1 is required for the stringent response. We present evidence that PPK1 is likely required for mprAB-sigE-rel signalling. sigma(E) regulates the transcription of rel, and we hypothesize that under conditions of stress polyP acts as a preferred donor for MprB-mediated phosphorylation of MprA facilitating transcription of the sigE gene thereby leading finally to the enhancement of the transcription of rel in M. smegmatis and M. tuberculosis. Downregulation of ppk1 led to impaired survival of M. tuberculosis in macrophages. PolyP plays a central role in the stress response of mycobacteria.