Resuscitation-promoting factors as lytic enzymes for bacterial growth and signaling

Resuscitation-promoting factor (Rpf) is a muralytic enzyme that increases the culturability of dormant bacteria. Recently, considerable progress has been made in understanding the structure, function and physiological role of Rpfs in different organisms, most notably the major human pathogen, Mycobacterium tuberculosis , which encodes multiple rpf -like genes. A key unresolved question, however, concerns the relationship between the predicted biochemical activity of Rpfs – cleavage of the β-1,4 glycosidic bond in the glycan backbone of peptidoglycan – and their effect on culturability. In M. tuberculosis , the interaction between RpfB and the d,l -endopeptidase, Rpf interacting protein A (RipA), enables these proteins to synergistically degrade peptidoglycan to facilitate growth. Furthermore, the combined action of Rpfs with RipA and other peptidoglycan hydrolases might produce muropeptides that could exert diverse biological effects through host and/or bacterial signaling, the latter involving serine/threonine protein kinases. Here, we explore these possibilities in the context of the structure and composition of mycobacterial peptidoglycan. Clearly, a deeper understanding of the role of Rpfs and associated peptidoglycan remodeling enzymes in bacterial growth and culturability is necessary to establish the significance of dormancy and resuscitation in diseases such as tuberculosis, which are associated with long-term persistence of viable bacterial populations recalcitrant to antibiotic and immune clearance.     

A mycobacterial enzyme essential for cell division synergizes with resuscitation-promoting factor

The final stage of bacterial cell division requires the activity of one or more enzymes capable of degrading the layers of peptidoglycan connecting two recently developed daughter cells. Although this is a key step in cell division and is required by all peptidoglycan-containing bacteria, little is known about how these potentially lethal enzymes are regulated. It is likely that regulation is mediated, at least partly, through protein-protein interactions. Two lytic transglycosylases of mycobacteria, known as resuscitation-promoting factor B and E (RpfB and RpfE), have previously been shown to interact with the peptidoglycan-hydrolyzing endopeptidase, Rpf-interacting protein A (RipA). These proteins may form a complex at the septum of dividing bacteria. To investigate the function of this potential complex, we generated depletion strains in M. smegmatis. Here we show that, while depletion of rpfB has no effect on viability or morphology, ripA depletion results in a marked decrease in growth and formation of long, branched chains. These growth and morphological defects could be functionally complemented by the M. tuberculosis ripA orthologue (rv1477), but not by another ripA-like orthologue (rv1478). Depletion of ripA also resulted in increased susceptibility to the cell wall-targeting beta-lactams. Furthermore, we demonstrate that RipA has hydrolytic activity towards several cell wall substrates and synergizes with RpfB. These data reveal the unusual essentiality of a peptidoglycan hydrolase and suggest a novel protein-protein interaction as one way of regulating its activity.     

Crystal structure of the resuscitation-promoting factor (DeltaDUF)RpfB from M. tuberculosis

Mycobacterium tuberculosis is able to establish a non-replicating state and survive in an intracellular habitat for years. Resuscitation of dormant M. tuberculosis bacteria is promoted by resuscitation-promoting factors (Rpfs), which are secreted from slowly replicating bacteria close to dormant bacteria. Here we report the crystal structure of a truncated form of RpfB (residues 194-362), the sole indispensable Rpf of the five Rpfs encoded in this bacterium genome. The structure, denoted as (DeltaDUF)RpfB, exhibits a comma-like shape formed by a lysozyme-like globular catalytic domain and an elongated G5 domain, which is widespread among cell surface binding proteins. The G5 domain, whose structure was previously uncharacterised, presents some peculiar features. The basic structural motif of this domain, which represents the tail of the comma-like structure, is a novel super-secondary-structure element, made of two beta-sheets interconnected by a pseudo-triple helix. This intricate organisation leads to the exposure of several backbone hydrogen-bond donors/acceptors. Mutagenesis analyses and solution studies indicate that this protein construct as well as the full-length form are elongated monomeric proteins. Although (DeltaDUF)RpfB does not self-associate, the exposure of structural elements (backbone H-bond donors/acceptors and hydrophobic side chains) that are usually buried in globular proteins is typically associated with adhesive properties. This suggests that the RpfB G5 domain has a cell-wall adhesive function, which allows the catalytic domain to be properly oriented for the cleavage reaction. Interestingly, sequence comparisons indicate that these structural features are also shared by G5 domains involved in biofilm formation.     

抗结核分枝杆菌RpfB结构域单克隆抗体的制备及鉴定

目的:制备抗结核分枝杆菌Rpf B结构域单克隆抗体。方法:将p PRO-EXHT-Rpf B domain原核表达载体接种于大肠杆菌DH5中,用IPTG诱导表达Rpf B结构域蛋白,以纯化的Rpf B结构域蛋白作为免疫原,皮下包埋免疫小鼠3次,每次间隔2周;分离小鼠的脾细胞,与Sp2/0细胞融合,克隆化制备抗Rpf B结构域单抗,ELISA检测其效价,鉴定其特异性和相对亲和力,观察制备的抗Rpf B结构域单抗对Rpf家族其他蛋白的识别能力及其对结核分枝杆菌和藤黄微球菌的生长抑制作用。结果:制备了3株抗Rpf B结构域单抗,特异性高,亲和力较强,均能特异性识别Rpf B结构域。经小鼠腹腔注射制备腹水并纯化,获得了较高纯度的单抗,所制备的抗Rpf B结构域多肽的单克隆抗体可以识别多种Rpf样蛋白及其结构域蛋白。在抗体滴度为1∶1000时可有效抑制Rpf B结构域对结核分枝杆菌H37Ra和藤黄微球菌的生长促进作用,提示抗Rpf B结构域单抗可能会抑制进入机体内生长停滞或潜伏感染的结核分枝杆菌的再次激活,可能具有预防隐性感染复发的作用。结论:抗Rpf B结构域单抗的制备为进一步研究Rpf B结构域的生物学和免疫特性提供了实验工具。     

Mycobacterium tuberculosis RpfE crystal structure reveals a positively charged catalytic cleft

Resuscitation promoting factor (Rpf) proteins, which hydrolyze the sugar chains in cell‐wall peptidoglycan (PG), play key roles in prokaryotic cell elongation, division, and escape from dormancy to vegetative growth. Like other bacteria, Mycobacterium tuberculosis (Mtb) expresses multiple Rpfs, none of which is individually essential. This redundancy has left unclear the distinct functions of the different Rpfs. To explore the distinguishing characteristics of the five Mtb Rpfs, we determined the crystal structure of the RpfE catalytic domain. The protein adopts the characteristic Rpf fold, but the catalytic cleft is narrower compared to Mtb RpfB. Also in contrast to RpfB, in which the substrate‐binding surfaces are negatively charged, the corresponding RpfE catalytic pocket and predicted peptide‐binding sites are more positively charged at neutral pH. The complete reversal of the electrostatic potential of the substrate‐binding site suggests that the different Rpfs function optimally at different pHs or most efficiently hydrolyze different micro‐domains of PG. These studies provide insights into the molecular determinants of the evolution of functional specialization in Rpfs.     

Resuscitation Promoting Factors: a Family of Microbial Proteins in Survival and Resuscitation of Dormant Mycobacteria

Mycobacterium tuberculosis, the causative agent of tuberculosis (TB), is an extraordinarily successful pathogen of humankind. It has been estimated that up to one-third of the world’s population is infected with M. tuberculosis, and this population is an important reservoir for disease reactivation. Resuscitation promoting factor (Rpf) is a secretory protein, which was first reported in Micrococcus luteus. There are five functionally redundant Rpf-like proteins found in M. tuberculosis. Rpf promotes the resuscitation of dormant bacilli to yield normal, viable colony forming bacteria. All Rpfs share a conserved domain of about 70 amino acids and possess a lysozyme-like activity. The structural studies of the conserved domain suggest that Rpfs could be considered as a c-type lysozyme and lytic transglycosylases. Recently a novel class of nitrophenylthiocyanates (NPT) inhibitors of the muralytic activity of Rpf were reported which opens a new approach in the study of cell-wall hydrolyzing enzymes. This review describes molecular and structural studies conducted on Rpf proteins, their role in the resuscitation of dormant bacteria, in the reactivation of latent infection and identification of low molecular weight inhibitors of resuscitation promoting factors.     

Resuscitation-Promoting Factors Are Cell Wall-Lytic Enzymes with Important Roles in the Germination and Growth of Streptomyces coelicolor

Dormancy is a common strategy adopted by bacterial cells as a means of surviving adverse environmental conditions. For Streptomyces bacteria, this involves developing chains of dormant exospores that extend away from the colony surface. Both spore formation and subsequent spore germination are tightly controlled processes, and while significant progress has been made in understanding the underlying regulatory and enzymatic bases for these, there are still significant gaps in our understanding. One class of proteins with a potential role in spore-associated processes are the so-called resuscitation-promoting factors, or Rpfs, which in other actinobacteria are needed to restore active growth to dormant cell populations. The model species Streptomyces coelicolor encodes five Rpf proteins (RpfA to RfpE), and here we show that these proteins have overlapping functions during growth. Collectively, the S. coelicolor Rpfs promote spore germination and are critical for growth under nutrient-limiting conditions. Previous studies have revealed structural similarities between the Rpf domain and lysozyme, and our in vitro biochemical assays revealed various levels of peptidoglycan cleavage capabilities for each of these five Streptomyces enzymes. Peptidoglycan remodeling by enzymes such as these must be stringently governed so as to retain the structural integrity of the cell wall. Our results suggest that one of the Rpfs, RpfB, is subject to a unique mode of enzymatic autoregulation, mediated by a domain of previously unknown function (DUF348) located within the N terminus of the protein; removal of this domain led to significantly enhanced peptidoglycan cleavage.     

复苏促进因子研究进展

复苏促进因子是一类广泛存在于结核分枝杆菌等革兰阳性菌中的蛋白质,能促进休眠菌复苏。复苏促进因子的作用机制目前仍然是未知的,然而对此类蛋白的结构域预测及核磁共振分析显示其保守区具有溶菌酶样折叠。我们简要综述了国外对此类蛋白作用机制的研究进展。     

Crystal Structure of the Resuscitation-Promoting Factor ΔDUFRpfB from M. tuberculosis

Mycobacterium tuberculosis is able to establish a non-replicating state and survive in an intracellular habitat for years. Resuscitation of dormant M. tuberculosis bacteria is promoted by resuscitation-promoting factors (Rpfs), which are secreted from slowly replicating bacteria close to dormant bacteria. Here we report the crystal structure of a truncated form of RpfB (residues 194-362), the sole indispensable Rpf of the five Rpfs encoded in this bacterium genome. The structure, denoted as _ΔDUFRpfB, exhibits a comma-like shape formed by a lysozyme-like globular catalytic domain and an elongated G5 domain, which is widespread among cell surface binding proteins. The G5 domain, whose structure was previously uncharacterised, presents some peculiar features. The basic structural motif of this domain, which represents the tail of the comma-like structure, is a novel super-secondary-structure element, made of two β-sheets interconnected by a pseudo-triple helix. This intricate organisation leads to the exposure of several backbone hydrogen-bond donors/acceptors. Mutagenesis analyses and solution studies indicate that this protein construct as well as the full-length form are elongated monomeric proteins. Although _ΔDUFRpfB does not self-associate, the exposure of structural elements (backbone H-bond donors/acceptors and hydrophobic side chains) that are usually buried in globular proteins is typically associated with adhesive properties. This suggests that the RpfB G5 domain has a cell-wall adhesive function, which allows the catalytic domain to be properly oriented for the cleavage reaction. Interestingly, sequence comparisons indicate that these structural features are also shared by G5 domains involved in biofilm formation.     

Rpf proteins are the factors of reactivation of the dormant forms of actinobacteria

As the response to unfavorable growth conditions, nonsporulating mycobacteria transform into the dormant state with the concomitant formation of the specialized dormant forms characterized by low metabolic activity and resistance to antibiotics. Such dormant cells can be reactivated under the influence of several factors including proteins of Rpf (Resuscitation promoting factor) family, which possess peptidoglycan hydrolase activity and were considered to belong to the group of the autocrine growth factors of the bacteria. Remarkable interest toward Rpf family is determined by its par-ticipation in resuscitation of the dormant forms of Mycobacterium tuberculosis, what in turn is the key element in resuscitation of the latent tuberculosis – an infectious disease that affects one third of the World’s population. Experiments with Rpf mutant forms and with strains deleted in these proteins revealed a relationship between the enzymatic activity of this protein and its ability to resuscitate mycobacteria both in vitro and in vivo. This review discusses possible mechanisms of Rpf action including those related to possible participation of the products of mycobacterial Rpf-mediated cell wall hydrolysis (muropeptides) as signaling molecules. The unique ability of Rpf proteins to resuscitate the dormant forms of mycobacteria and to stimulate their proliferation would allow these proteins to occupy their niche in medicine–in diagnostics and in creation of antituberculosis subunit vaccines.     

The resuscitation-promoting factors of Mycobacterium tuberculosis are required for virulence and resuscitation from dormancy but are collectively dispensable for growth in vitro

Mycobacterium tuberculosis contains five resuscitation-promoting factor (Rpf)-like proteins, RpfA-E, that are implicated in resuscitation of this organism from dormancy via a mechanism involving hydrolysis of the peptidoglycan by Rpfs and partnering proteins. In this study, the rpfA-E genes were shown to be collectively dispensable for growth of M. tuberculosis in broth culture. The defect in resuscitation of multiple mutants from a 'non-culturable' state induced by starvation under anoxia was reversed by genetic complementation or addition of culture filtrate from wild-type organisms confirming that the phenotype was associated with rpf-like gene loss and that the 'non-culturable' cells of the mutant strains were viable. Other phenotypes uncovered by sequential deletion mutagenesis revealed a functional differentiation within this protein family. The quintuple mutant and its parent that retained only rpfD displayed delayed colony formation and hypersensitivity to detergent, effects not observed for mutants retaining only rpfE or rpfB. Furthermore, mutants retaining rpfD or rpfE were highly attenuated for growth in mice with the latter persisting better than the former in late-stage infection. In conjunction, these results are indicative of a hierarchy in terms of function and/or potency with the Rpf family, with RpfB and RpfE ranking above RpfD.     

Proteins of the Rpf (resuscitation promoting factor) family are peptidoglycan hydrolases

The secreted Micrococcus luteus protein, Rpf, is required for successful resuscitation of dormant "non-culturable" M. luteus cells and for growth stimulation in poor media. The biochemical mechanism of Rpf action remained unknown. Theoretical predictions of Rpf domain architecture and organization, together with a recent NMR analysis of the protein structure, indicate that the conserved Rpf domain has a lysozyme-like fold. In the present study, we found that both the secreted native protein and the recombinant protein lyse crude preparations of M. luteus cell walls. They also hydrolyze 4-methylumbelliferyl-beta-D-N,N',N'-triacetylchitotrioside, a synthetic substrate for peptidoglycan muramidases, with optimum activity at pH 6. The Rpf protein also has weak proteolytic activity against N-CBZ-Gly-Gly-Arg-beta-naphthylamide, a substrate for trypsin-like enzymes. Rpf activity towards 4-methylumbelliferyl-beta-D-N,N',N'-triacetylchitotrioside was reduced when the glutamate residue at position 54, invariant for all Rpf family proteins and presumably involved in catalysis, was altered. The same amino acid substitution resulted in impaired resuscitation activity of Rpf. The data indicate that Rpf is a peptidoglycan-hydrolyzing enzyme, and strongly suggest that this specific activity is responsible for its growth promotion and resuscitation activity. A possible mechanism of Rpf-mediated resuscitation is discussed.     

Structure and dynamics of the multi-domain resuscitation promoting factor RpfB from Mycobacterium tuberculosis

RpfB is multidomain protein that is crucial for Mycobacterium tuberculosis resuscitation from dormancy. This protein cleaves cell wall peptidoglycan, an essential bacterial cell wall polymer formed by glycan chains of β-(1-4)-linked-N-acetylglucosamine (GlcNAc) and N-acetylmuramic acid (MurNAc) cross-linked by short peptide stems. RpfB is structurally complex being composed of five distinct domains, namely a catalytic, a G5 and three DUF348 domains. Here, we have undertaken a combined experimental and computation structural investigations on the entire protein to gain insights into its structure–function relationships. CD spectroscopy and light scattering experiments have provided insights into the protein fold stability and into its oligomeric state. Using the available structure information, we modeled the entire protein structure, which includes the two DUF348 domains whose structure is experimentally unknown, and we analyzed the dynamic behavior of RpfB using molecular dynamics simulations. Present results highlight an intricate mutual influence of the dynamics of the different protein domains. These data provide interesting clues on the functional role of non-catalytic domains of RpfB and on the mechanism of peptidoglycan degradation necessary to resuscitation of M. tuberculosis.     

Carbohydrate Recognition by RpfB from Mycobacterium tuberculosis Unveiled by Crystallographic and Molecular Dynamics Analyses

Resuscitation of Mtb is crucial to the etiology of Tuberculosis, because latent tuberculosis is estimated to affect one-third of the world population. The resuscitation-promoting factor RpfB is mainly responsible for Mtb resuscitation from dormancy. Given the impact of latent Tuberculosis, RpfB represents an interesting target for tuberculosis drug discovery. However, no molecular models of substrate binding and catalysis are hitherto available for this enzyme. Here, we identified key interactions involved in substrate binding to RpfB by combining x-ray diffraction studies and computational approaches. The crystal structure of RpfB catalytic domain in complex with N,N′,N″-triacetyl-chitotriose, as described here, provides the first, to our knowledge, atomic representation of ligand recognition by RpfB and demonstrates that the strongest interactions are established by the N-acetylglucosamine moiety in the central region of the enzyme binding cleft. Molecular dynamics analyses provided information on the dynamic behavior of protein-substrate interactions and on the role played by the solvent in RpfB function. These data combined with sequence conservation analysis suggest that Glu-292 is the sole residue crucial for catalysis, implying that RpfB acts via the formation of an oxocarbenium ion rather than a covalent intermediate. Present data represent a solid base for the design of effective drug inhibitors of RpfB. Moreover, homology models were generated for the catalytic domains of all members of the Mtb Rpf family (RpfA-E). The analysis of these models unveiled analogies and differences among the different members of the Rpf protein family.Abbreviations used: Mtb, Mycobacterium tuberculosis; RpfB, Resuscitation promoting factor B; PDB, Protein Data Bank; RpfBc, catalytic domain of RpfB; NAG3, N,N'',N"-triacetyl-chitotriose; NAG6, hexa-N- acetylchitohexaose; MD, molecular dynamics; RMSF, root mean-square fluctuation     

Finding of the Low Molecular Weight Inhibitors of Resuscitation Promoting Factor Enzymatic and Resuscitation Activity

Background

Resuscitation promoting factors (RPF) are secreted proteins involved in reactivation of dormant actinobacteria, including Mycobacterium tuberculosis. They have been considered as prospective targets for the development of new anti-tuberculosis drugs preventing reactivation of dormant tubercle bacilli, generally associated with latent tuberculosis. However, no inhibitors of Rpf activity have been reported so far. The goal of this study was to find low molecular weight compounds inhibiting the enzymatic and biological activities of Rpfs.

Methodology/Principal Findings

Here we describe a novel class of 2-nitrophenylthiocyanates (NPT) compounds that inhibit muralytic activity of Rpfs with IC₅₀ 1–7 µg/ml. Fluorescence studies revealed interaction of active NPTs with the internal regions of the Rpf molecule. Candidate inhibitors of Rpf enzymatic activity showed a bacteriostatic effect on growth of Micrococcus luteus (in which Rpf is essential for growth protein) at concentrations close to IC₅₀. The candidate compounds suppressed resuscitation of dormant (“non-culturable”) cells of M. smegmatis at 1 µg/ml or delayed resuscitation of dormant M. tuberculosis obtained in laboratory conditions at 10 µg/ml. However, they did not inhibit growth of active mycobacteria under these concentrations.

Conclusions/Significance

NPT are the first example of low molecular weight compounds that inhibit the enzymatic and biological activities of Rpf proteins.     

Structural Changes and Cellular Localization of Resuscitation-Promoting Factor in Environmental Isolates of Micrococcus luteus

Dormancy among nonsporulating actinobacteria is now a widely accepted phenomenon. In Micrococcus luteus, the resuscitation of dormant cells is caused by a small secreted protein (resuscitation-promoting factor, or Rpf) that is found in “spent culture medium.” Rpf is encoded by a single essential gene in M. luteus. Homologs of Rpf are widespread among the high G + C Gram-positive bacteria, including mycobacteria and streptomycetes, and most organisms make several functionally redundant proteins. M. luteus Rpf comprises a lysozyme-like domain that is necessary and sufficient for activity connected through a short linker region to a LysM motif, which is present in a number of cell-wall-associated enzymes. Muralytic activity is responsible for resuscitation. In this report, we characterized a number of environmental isolates of M. luteus, including several recovered from amber. There was substantial variation in the predicted rpf gene product. While the lysozyme-like and LysM domains showed little variation, the linker region was elongated from ten amino acid residues in the laboratory strains to as many as 120 residues in one isolate. The genes encoding these Rpf proteins have been characterized, and a possible role for the Rpf linker in environmental adaptation is proposed. The environmental isolates show enhanced resistance to lysozyme as compared with the laboratory strains and this correlates with increased peptidoglycan acetylation. In strains that make a protein with an elongated linker, Rpf was bound to the cell wall, rather than being released to the growth medium, as occurs in reference strains. This rpf gene was introduced into a lysozyme-sensitive reference strain. Both rpf genes were expressed in transformants which showed a slight but statistically significant increase in lysozyme resistance.     

Peptidoglycan fragments stimulate resuscitation of “non-culturable” mycobacteria

Resuscitation promoting factors (Rpfs), belonging to a family of secreted actinobacterial proteins with predicted peptidoglycan (PG) hydrolytic activities, participate in the reactivation of dormant cells. In the present study we demonstrate that a recombinant truncated form of Micrococcus luteus Rpf hydrolyzes isolated PG of Mycobacterium smegmatis and Mycobacterium tuberculosis liberating PG fragments of different size. These fragments possess stimulatory activity toward “non-culturable” dormant M. smegmatis and M. tuberculosis cells, similar to the activity of recombinant Rpf. Relatively large PG fragments (0.1–0.5 μm) obtained either by Rpf digestion or by PG ultrasonication revealed resuscitation activities when added in concentrations 0.1–0.2 μg/ml to the resuscitation medium. It is suggested that PG fragments could either directly activate the resuscitation pathway of dormant mycobacteria or serve as a substrate for endogenous Rpf, resulting in low molecular weight products with resuscitation activity. Whilst both suggestions are plausible, it was observed that PG-dependent resuscitation activity was suppressed by means of a specific Rpf inhibitor (4-benzoyl-2-nitrophenylthiocyanate), which provides additional support for the second of these possibilities.     

Cell-cell interactions during formation and reactivation of "nonculturable" mycobacteria

To date, the possible existence of "nonculturable" (NC) but potentially viable forms has been shown for some bacteria. NC mycobacteria have attracted particular interest due to the assumption that the latent form of tuberculosis is associated with the conversion of its causative agent, Mycobacterium tuberculosis, into the NC state. A number of approaches have been developed to obtain NC forms of mycobacteria, but the mechanisms of transition into or from this state have been insufficiently studied. This review considers cell-cell communications involved in the formation and reactivation of NC forms of the bacteria M. smegmatis and M. tuberculosis. Special attention has been paid to the secreted Rpf family proteins, which belong to peptidoglycan hydrolases and participate in the resuscitation of NC mycobacteria.     

Wake up! Peptidoglycan lysis and bacterial non-growth states

When stressed, bacteria can enter various non-dividing states, which are medically important. For example, dormancy is used by Mycobacterium tuberculosis to evade host responses. A major breakthrough has been the discovery of resuscitation-promoting factor (Rpf) from Micrococcus luteus, which is an extremely potent anti-dormancy factor. Mycobacteria have multiple proteins that contain this domain. Surprisingly, the highly conserved resuscitation-promoting factor domain has strong structural similarities to lysozyme and soluble lytic transglycosylases, and it has been demonstrated that resuscitation-promoting factors cleave peptidoglycan. This suggests that the activation of dormant cells requires peptidoglycan hydrolysis, which either alters the mechanical properties of the cell wall to facilitate cell division or releases lysis products that function as anti-dormancy signals.     

Interaction and Modulation of Two Antagonistic Cell Wall Enzymes of Mycobacteria

Bacterial cell growth and division require coordinated cell wall hydrolysis and synthesis, allowing for the removal and expansion of cell wall material. Without proper coordination, unchecked hydrolysis can result in cell lysis. How these opposing activities are simultaneously regulated is poorly understood. In Mycobacterium tuberculosis, the resuscitation-promoting factor B (RpfB), a lytic transglycosylase, interacts and synergizes with Rpf-interacting protein A (RipA), an endopeptidase, to hydrolyze peptidoglycan. However, it remains unclear what governs this synergy and how it is coordinated with cell wall synthesis. Here we identify the bifunctional peptidoglycan-synthesizing enzyme, penicillin binding protein 1 (PBP1), as a RipA-interacting protein. PBP1, like RipA, localizes both at the poles and septa of dividing cells. Depletion of the ponA1 gene, encoding PBP1 in M. smegmatis, results in a severe growth defect and abnormally shaped cells, indicating that PBP1 is necessary for viability and cell wall stability. Finally, PBP1 inhibits the synergistic hydrolysis of peptidoglycan by the RipA-RpfB complex in vitro. These data reveal a post-translational mechanism for regulating cell wall hydrolysis and synthesis through protein–protein interactions between enzymes with antagonistic functions.