Structural basis for the specificity of PPM1H phosphatase for Rab GTPases

LRRK2 serine/threonine kinase is associated with inherited Parkinson’s disease. LRRK2 phosphorylates a subset of Rab GTPases within their switch 2 motif to control their interactions with effectors. Recent work has shown that the metal‐dependent protein phosphatase PPM1H counteracts LRRK2 by dephosphorylating Rabs. PPM1H is highly selective for LRRK2 phosphorylated Rabs, and closely related PPM1J exhibits no activity towards substrates such as Rab8a phosphorylated at Thr72 (pThr72). Here, we have identified the molecular determinant of PPM1H specificity for Rabs. The crystal structure of PPM1H reveals a structurally conserved phosphatase fold that strikingly has evolved a 110‐residue flap domain adjacent to the active site. The flap domain distantly resembles tudor domains that interact with histones in the context of epigenetics. Cellular assays, crosslinking and 3‐D modelling suggest that the flap domain encodes the docking motif for phosphorylated Rabs. Consistent with this hypothesis, a PPM1J chimaera with the PPM1H flap domain dephosphorylates pThr72 of Rab8a both in vitro and in cellular assays. Therefore, PPM1H has acquired a Rab‐specific interaction domain within a conserved phosphatase fold.     

Substrate-dependent metal preference of PPM1H, a cancer-associated protein phosphatase 2C: comparison with other family members

Protein phosphatase 2C (PP2C) family is characterized by requirement of metal cation for phosphatase activity. We previously established that PPM1H is a cancer-associated member of the PP2C family. Here we further characterized the phosphatase activity of PPM1H, focusing on its dependence on metal cation. PPM1H possesses the potential to dephosphorylate p-nitrophenyl phosphate (pNPP), casein and phosphopeptides. Interestingly, PPM1H shows the metal preference that is varied depending on the substrate (substrate-dependent metal preference); PPM1H prefers Mn²⁺ when pNPP or phosphopeptides is used as a substrate. Meanwhile, a preference for Mg²⁺ is displayed by PPM1H with casein as a substrate. When both cations are added to the reaction, the degree of the effect is always closer to that with Mn²⁺ alone, irrespective of the substrate. This preponderance of Mn²⁺ is explained by its greater affinity for PPM1H than Mg²⁺. From the literature the substrate-dependent metal preference appears to be shared by other PP2Cs. According to the crystal structure, a binuclear metal center of PP2C plays an important role for coordinating the substrate and nucleophilic waters in the active site. Therefore, the differences in the size, preferred geometry and coordination requirements between two metals, in relation to the substrate, may be responsible for this intriguing property.     

PPM1D regulates p21 expression via dephoshporylation at serine 123

The cyclin-dependent kinase inhibitor p21 plays a critical role in regulating cell cycle and cell proliferation. We previously cloned the dog p21 gene and found that unlike human p21, dog p21 is expressed as 2 isoforms due to the proline-directed phosphorylation at serine 123 (S123). Here, we identified that PPM1D, also called Wip1 and a Mg²⁺-dependent phosphatase, dephosphorylates dog p21 protein at serine 123. Specifically, we showed that the level of S123-phosphorylated dog p21 is increased by a PPM1D inhibitor in a dose-dependent manner. We also showed that over-expression of PPM1D decreases, whereas knockdown of PPM1D increases, the level of S123-phosphorylated dog p21 regardless of p53. Additionally, in vitro phosphatase assay was performed and showed that phosphorylated S123 in dog p21 is dephosphorylated by recombinant rPPM1D, which contains the catalytic domain of human PPM1D (residue 1–420), but not by the phosphatase dead rPPM1D (D314A). Furthermore, dephosphorylation of S123 by rPPM1D can be abrogated by PPM1D inhibitor or by withdrawal of Mg²⁺. Finally, we showed that upon PPM1D inhibition, the level of S123-phosphorylated dog p21 was increased, concomitantly with decreased expression of cyclin A, cyclin B, Rb, and PCNA. Together, our results indicate that PPM1D functions as a phosphatase of dog p21 at serine 123 and plays a role in cell cycle control via p21.     

Ppm1E is an in cellulo AMP-activated protein kinase phosphatase

Activation of 5′-AMP-activated protein kinase (AMPK) is believed to be the mechanism by which the pharmaceuticals, metformin and phenformin, exert their beneficial effects for treatment of type 2 diabetes. These biguanide drugs elevate 5′-AMP, which allosterically activates AMPK and promotes phosphorylation on Thr172 of AMPK catalytic α subunits. Although kinases phosphorylating this site have been identified, phosphatases that dephosphorylate it are unknown. The aim of this study is to identify protein phosphatase(s) that dephosphorylate AMPKα-Thr172 within cells. Our initial data indicated that members of the protein phosphatase ce:sup>/ce:sup>/Mn²⁺-dependent (PPM) family and not those of the PPP family of protein serine/threonine phosphatases may be directly or indirectly inhibited by phenformin. Using antibodies raised to individual Ppm phosphatases that facilitated the assessment of their activities, phenformin stimulation of cells was found to decrease the ce:sup>/ce:sup>/Mn²⁺-dependent protein serine/threonine phosphatase activity of Ppm1E and Ppm1F, but not that attributable to other PPM family members, including Ppm1A/PP2Cα. Depletion of Ppm1E, but not Ppm1A, using lentiviral-mediated stable gene silencing, increased AMPKα-Thr172 phosphorylation approximately three fold in HEK293 cells. In addition, incubation of cells with low concentrations of phenformin and depletion of Ppm1E increased AMPK phosphorylation synergistically. Ppm1E and the closely related Ppm1F interact weakly with AMPK and assays with lysates of cells stably depleted of Ppm1F suggests that this phosphatase contributes to dephosphorylation of AMPK. The data indicate that Ppm1E and probably PpM1F are in cellulo AMPK phosphatases and that Ppm1E is a potential anti-diabetic drug target.     

A serine/threonine protein phosphatase-like protein, CaPTC8, from Candida albicans defines a new PPM subfamily

Protein phosphatase M family (PPM; Mg²⁺-dependent protein phosphatases), which specifically dephosphorylates serine/threonine residues, consists of pyruvate dehydrogenase phosphatases, SpoIIE, adenylate cyclase and protein phosphatase type 2Cs (PP2Cs). To identify Candida albicans PP2Cs, the archetype of the PPM Ser/Thr phosphatases, we thoroughly searched the public C. albicans genome database and identified seven PP2C members. One of the PP2Cs in C. albicans, designated as CaPTC8 gene, represents a new member of PP2C genes. Northern blot analysis showed that the expression of CaPTC8 was positively responsive to high osmolarity, temperature or serum-stimulated filamentous growth. Gene disruption further demonstrated that deletion of CaPTC8 gene caused the defect of hyphal formation. Sequence analysis revealed that two conserved amino acids His and Asn in the prototypical members of the PPM family were substituted by Val and Asp in the PTC8p-like proteins. In addition, posterior analysis for site-specific profile showed that seven more sites are under the selection of functional divergence between these two groups of proteins. Three-dimensional homology modeling illustrated the signatures of the two groups in the conserved catalytic region of the protein phosphatases. Hence, CaPTC8 plays a role in stress responses and is required for the yeast-hyphal transition, and the CaPTC8-related genes are evolutionarily conserved. The phylogenetic relationships of all members of the PPM family strongly support the existence of a distinct and new subfamily of the PP2C-related proteins, PP2CR.     

Structural and binding studies of the three-metal center in two mycobacterial PPM Ser/Thr protein phosphatases

Phospho-Ser/Thr protein phosphatases (PPs) are dinuclear metalloenzymes classed into two large families, PPP and PPM, on the basis of sequence similarity and metal ion dependence. The archetype of the PPM family is the α isoform of human PP2C (PP2Cα), which folds into an α/β domain similar to those of PPP enzymes. The recent structural studies of three bacterial PPM phosphatases, Mycobacterium tuberculosis MtPstP, Mycobacterium smegmatis MspP, and Streptococcus agalactiae STP, confirmed the conservation of the overall fold and dinuclear metal center in the family, but surprisingly revealed the presence of a third conserved metal-binding site in the active site. To gain insight into the roles of the three-metal center in bacterial enzymes, we report structural and metal-binding studies of MtPstP and MspP. The structure of MtPstP in a new trigonal crystal form revealed a fully active enzyme with the canonical dinuclear metal center but without the third metal ion bound to the catalytic site. The absence of metal correlates with a partially unstructured flap segment, indicating that the third manganese ion contributes to reposition the flap, but is dispensable for catalysis. Studies of metal binding to MspP using isothermal titration calorimetry revealed that the three Mn²⁺-binding sites display distinct affinities, with dissociation constants in the nano- and micromolar range for the two catalytic metal ions and a significantly lower affinity for the third metal-binding site. In agreement, the structure of inactive MspP at acidic pH was determined at atomic resolution and shown to lack the third metal ion in the active site. Structural comparisons of all bacterial phosphatases revealed positional variations in the third metal-binding site that are correlated with the presence of bound substrate and the conformation of the flap segment, supporting a role of this metal ion in assisting enzyme-substrate interactions.     

Identification of the acid/base catalyst of a glycoside hydrolase family 3 (GH3) β-glucosidase from Aspergillus niger ASKU28

Background

The commercially important glycoside hydrolase family 3 (GH3) β-glucosidases from Aspergillus niger are anomeric-configuration-retaining enzymes that operate through the canonical double-displacement glycosidase mechanism. Whereas the catalytic nucleophile is readily identified across all GH3 members by sequence alignments, the acid/base catalyst in this family is phylogenetically variable and less readily divined.

Methods

In this report, we employed three-dimensional structure homology modeling and detailed kinetic analysis of site-directed mutants to identify the catalytic acid/base of a GH3 β-glucosidase from A. niger ASKU28.

Results

In comparison to the wild-type enzyme and other mutants, the E490A variant exhibited greatly reduced k_cat and k_cat/K_m values toward the natural substrate cellobiose (67,000- and 61,000-fold, respectively). Correspondingly smaller kinetic effects were observed for artificial chromogenic substrates p-nitrophenyl β-d-glucoside and 2,4-dinitrophenyl β-d-glucoside, the aglycone leaving groups of which are less dependent on acid catalysis, although changes in the rate-determining catalytic step were revealed for both. pH-rate profile analyses also implicated E490 as the general acid/base catalyst. Addition of azide as an exogenous nucleophile partially rescued the activity of the E490A variant with the aryl β-glucosides and yielded β-glucosyl azide as a product.

Conclusions and general significance

These results strongly support the assignment of E490 as the acid/base catalyst in a β-glucosidase from A. niger ASKU28, and provide crucial experimental support for the bioinformatic identification of the homologous residue in a range of related GH3 subfamily members.     

Crystal structure of the Clostridium limosum C3 exoenzyme

C3-like toxins ADP-ribosylate and inactivate Rho GTPases. Seven C3-like ADP-ribosyltransferases produced by Clostridium botulinum, Clostridium limosum, Bacillus cereus and Staphylococcus aureus were identified and two representatives - C3bot from C. botulinum and C3stau2 from S. aureus - were crystallized. Here we present the 1.8 Å structure of C. limosum C3 transferase C3lim and compare it to the structures of other family members. In contrast to the structure of apo-C3bot, the canonical ADP-ribosylating turn turn motif is observed in a primed conformation, ready for NAD binding. This suggests an impact on the binding mode of NAD and on the transferase reaction. The crystal structure explains why auto-ADP-ribosylation of C3lim at Arg41 interferes with the ADP-ribosyltransferase activity of the toxin.     

The molecular structure of epoxide hydrolase B from Mycobacterium tuberculosis and its complex with a urea-based inhibitor

Mycobacterium tuberculosis (Mtb), the intracellular pathogen that infects macrophages primarily, is the causative agent of the infectious disease tuberculosis in humans. The Mtb genome encodes at least six epoxide hydrolases (EHs A to F). EHs convert epoxides to trans-dihydrodiols and have roles in drug metabolism as well as in the processing of signaling molecules. Herein, we report the crystal structures of unbound Mtb EHB and Mtb EHB bound to a potent, low-nanomolar (IC₅₀ ≈ 19 nM) urea-based inhibitor at 2.1 and 2.4 Å resolution, respectively. The enzyme is a homodimer; each monomer adopts the classical α/β hydrolase fold that composes the catalytic domain; there is a cap domain that regulates access to the active site. The catalytic triad, comprising Asp104, His333 and Asp302, protrudes from the catalytic domain into the substrate binding cavity between the two domains. The urea portion of the inhibitor is bound in the catalytic cavity, mimicking, in part, the substrate binding; the two urea nitrogen atoms donate hydrogen bonds to the nucleophilic carboxylate of Asp104, and the carbonyl oxygen of the urea moiety receives hydrogen bonds from the phenolic oxygen atoms of Tyr164 and Tyr272. The phenolic oxygen groups of these two residues provide electrophilic assistance during the epoxide hydrolytic cleavage. Upon inhibitor binding, the binding-site residues undergo subtle structural rearrangement. In particular, the side chain of Ile137 exhibits a rotation of around 120° about its C^α-C^β bond in order to accommodate the inhibitor. These findings have not only shed light on the enzyme mechanism but also have opened a path for the development of potent inhibitors with good pharmacokinetic profiles against all Mtb EHs of the α/β type.     

PPM1D regulates p21 expression via dephoshporylation at serine 123

The cyclin-dependent kinase inhibitor p21 plays a critical role in regulating cell cycle and cell proliferation. We previously cloned the dog p21 gene and found that unlike human p21, dog p21 is expressed as 2 isoforms due to the proline-directed phosphorylation at serine 123 (S123). Here, we identified that PPM1D, also called Wip1 and a Mg²⁺-dependent phosphatase, dephosphorylates dog p21 protein at serine 123. Specifically, we showed that the level of S123-phosphorylated dog p21 is increased by a PPM1D inhibitor in a dose-dependent manner. We also showed that over-expression of PPM1D decreases, whereas knockdown of PPM1D increases, the level of S123-phosphorylated dog p21 regardless of p53. Additionally, in vitro phosphatase assay was performed and showed that phosphorylated S123 in dog p21 is dephosphorylated by recombinant rPPM1D, which contains the catalytic domain of human PPM1D (residue 1–420), but not by the phosphatase dead rPPM1D (D314A). Furthermore, dephosphorylation of S123 by rPPM1D can be abrogated by PPM1D inhibitor or by withdrawal of Mg²⁺. Finally, we showed that upon PPM1D inhibition, the level of S123-phosphorylated dog p21 was increased, concomitantly with decreased expression of cyclin A, cyclin B, Rb, and PCNA. Together, our results indicate that PPM1D functions as a phosphatase of dog p21 at serine 123 and plays a role in cell cycle control via p21.     

Enhanced catalytic site thermal stability of cold-adapted esterase EstK by a W208Y mutation

Hydrophobic interactions are known to play an important role for cold-adaptation of proteins; however, the role of amino acid residue, Trp, has not been systematically investigated. The extracellular esterase, EstK, which was isolated from the cold-adapted bacterium Pseudomonas mandelii, has 5 Trp residues. In this study, the effects of Trp mutation on thermal stability, catalytic activity, and conformational change of EstK were investigated. Among the 5 Trp residues, W²⁰⁸ was the most crucial in maintaining structural conformation and thermal stability of the enzyme. Surprisingly, mutation of W²⁰⁸ to Tyr (W²⁰⁸Y) showed an increased catalytic site thermal stability at ambient temperatures with a 13-fold increase in the activity at 40 °C compared to wild-type EstK. The structure model of W²⁰⁸Y suggested that Y²⁰⁸ could form a hydrogen bond with D³⁰⁸, which is located next to catalytic residue H³⁰⁷, stabilizing the catalytic domain. Interestingly, Tyr was conserved in the corresponding position of hyper-thermophilic esterases EstE1 and AFEST, which are active at high temperatures. Our study provides a novel insight into the engineering of the catalytic site of cold-adapted enzymes with increased thermal stability and catalytic activity at ambient temperatures.     

Structural and Functional Analysis of Human SIRT1

SIRT1 is a NAD⁺-dependent deacetylase that plays important roles in many cellular processes. SIRT1 activity is uniquely controlled by a C-terminal regulatory segment (CTR). Here we present crystal structures of the catalytic domain of human SIRT1 in complex with the CTR in an open apo form and a closed conformation in complex with a cofactor and a pseudo-substrate peptide. The catalytic domain adopts the canonical sirtuin fold. The CTR forms a β hairpin structure that complements the β sheet of the NAD⁺-binding domain, covering an essentially invariant hydrophobic surface. The apo form adopts a distinct open conformation, in which the smaller subdomain of SIRT1 undergoes a rotation with respect to the larger NAD⁺-binding subdomain. A biochemical analysis identifies key residues in the active site, an inhibitory role for the CTR, and distinct structural features of the CTR that mediate binding and inhibition of the SIRT1 catalytic domain.     

The X-ray Crystal Structure of an Arthrobacter protophormiae Endo-β-N-Acetylglucosaminidase Reveals a (β/α)8 Catalytic Domain, Two Ancillary Domains and Active Site Residues Key for Transglycosylation Activity

Glycoside hydrolase family GH85 is a family of endo-β-N-acetylglucosaminidases that is responsible for the hydrolysis of β-1,4 linkage in the N,N-diacetylchitobiose core of N-linked glycans. The endo-β-N-acetylglucosaminidase from Arthrobacter protophormiae (Endo-A) is of particular interest, given its increasing use for the chemoenzymatic synthesis of bespoke N-glycans using N-glycan oxazolines as glycosyl donors. The E173Q variant of Endo-A is especially attractive for synthesis, as it is hydrolytically impaired but still able to catalyze N-glycan synthesis by transglycosylation using activated oxazoline donors. Here we present the three-dimensional structure of the A. protophormiae Endo-A E173Q variant, solved by multiple-wavelength anomalous scattering methods and refined at 1.8 Å resolution. The structure reveals that GH85 enzymes display a trimodular architecture in which a (β/α)₈ catalytic domain occurs with two ancillary β-sheet modules. The active centre is fully consistent with the known neighboring-group catalytic mechanism in which E173 acts as the catalytic acid/base for reaction via an oxazoline intermediate. Of note is the presence of an asparagine in the active centre, in a position likely to interact with the acetyl NH group that, in all other known families of glycosidase using this mechanism, is an aspartate or glutamate residue. The substrate-binding surface reveals an open topography, consistent with the ability to accept a large range of glycoprotein substrates and the ability to transglycosylate other acceptors. The three-dimensional structure of this important biocatalyst reveals that residues implicated in the enhancement of transglycosylation and synthetic capacity are proximal to the active centre, where they may act to favor binding of acceptor substrates.     

Molecular characterization of a thermostable L-fucose isomerase from Dictyoglomus turgidum that isomerizes L-fucose and D-arabinose

A recombinant thermostable l-fucose isomerase from Dictyoglomus turgidum was purified with a specific activity of 93 U/mg by heat treatment and His-trap affinity chromatography. The native enzyme existed as a 410 kDa hexamer. The maximum activity for l-fucose isomerization was observed at pH 7.0 and 80 °C with a half-life of 5 h in the presence of 1 mM Mn²⁺ that was present one molecular per monomer. The isomerization activity of the enzyme with aldose substrates was highest for l-fucose (with a k_cat of 15,500 min⁻¹ and a K_m of 72 mM), followed by d-arabinose, d-altrose, and l-galactose. The 15 putative active-site residues within 5 Å of the substrate l-fucose in the homology model were individually replaced with other amino acids. The analysis of metal-binding capacities of these alanine-substituted variants revealed that Glu349, Asp373, and His539 were metal-binding residues, and His539 was the most influential residue for metal binding. The activities of all variants at 349 and 373 positions except for a dramatically decreased k_cat of D373A were completely abolished, suggesting that Glu349 and Asp373 were catalytic residues. Alanine substitutions at Val131, Met197, Ile199, Gln314, Ser405, Tyr451, and Asn538 resulted in substantial increases in K_m, suggesting that these amino acids are substrate-binding residues. Alanine substitutions at Arg30, Trp102, Asn404, Phe452, and Trp510 resulted in decreases in k_cat, but had little effect on K_m.     

Enzymatic characteristics of an ApaH-like phosphatase,PrpA, and a diadenosine tetraphosphate hydrolase,ApaH, from Myxococcus xanthus

We characterized the activities of the Myxococcus xanthus ApaH-like phosphatases PrpA and ApaH, which share homologies with both phosphoprotein phosphatases and diadenosine tetraphosphate (Ap₄A) hydrolases. PrpA exhibited a phosphatase activity towards p-nitrophenyl phosphate (pNPP), tyrosine phosphopeptide and tyrosine-phosphorylated protein, and a weak hydrolase activity towards Ap_nA and ATP. In the presence of Mn²⁺, PrpA hydrolyzed Ap₄A into AMP and ATP, whereas in the presence of Co²⁺ PrpA hydrolyzed Ap₄A into two molecules of ADP. ApaH exhibited high phosphatase activity towards pNPP, and hydrolase activity towards Ap_nA and ATP. Mn²⁺ was required for ApaH-mediated pNPP dephosphorylation and ATP hydrolysis, whereas Co²⁺ was required for Ap_nA hydrolysis. Thus, PrpA and ApaH may function mainly as a tyrosine protein phosphatase and an Ap_nA hydrolase, respectively.     

Structural analyses of Legionella LepB reveal a new GAP fold that catalytically mimics eukaryotic RasGAP

Rab GTPases are emerging targets of diverse bacterial pathogens. Here, we perform biochemical and structural analyses of LepB, a Rab GTPase-activating protein (GAP) effector from Legionella pneumophila. We map LepB GAP domain to residues 313-618 and show that the GAP domain is Rab1 specific with a catalytic activity higher than the canonical eukaryotic TBC GAP and the newly identified VirA/EspG family of bacterial RabGAP effectors. Exhaustive mutation analyses identify Arg444 as the arginine finger, but no catalytically essential glutamine residues. Crystal structures of LepB_313-618 alone and the GAP domain of Legionella drancourtii LepB in complex with Rab1-GDP-AlF₃ support the catalytic role of Arg444, and also further reveal a 3D architecture and a GTPase-binding mode distinct from all known GAPs. Glu449, structurally equivalent to TBC RabGAP glutamine finger in apo-LepB, undergoes a drastic movement upon Rab1 binding, which induces Rab1 Gln70 side-chain flipping towards GDP-AlF₃ through a strong ionic interaction. This conformationally rearranged Gln70 acts as the catalytic cis-glutamine, therefore uncovering an unexpected RasGAP-like catalytic mechanism for LepB. Our studies highlight an extraordinary structural and catalytic diversity of RabGAPs, particularly those from bacterial pathogens.     

X-ray structures of Bacillus pallidusd-arabinose isomerase and its complex with l-fucitol

d-Arabinose isomerase (d-AI), also known as l-fucose isomerase (l-FI), catalyzes the aldose–ketose isomerization of d-arabinose to d-ribulose, and l-fucose to l-fuculose. Bacillus pallidus (B. pallidus) d-AI can catalyze isomerization of d-altrose to d-psicose, as well as d-arabinose and l-fucose. Three X-ray structures of B. pallidusd-AI in complexes with 2-methyl-2,4-pentadiol, glycerol and an inhibitor, l-fucitol, were determined at resolutions of 1.77, 1.60 and 2.60 Å, respectively. B. pallidusd-AI forms a homo-hexamer, and one subunit has three domains of almost equal size; two Rossmann fold domains and a mimic of the (β/α) barrel fold domain. A catalytic metal ion (Mn²⁺) was found in the active site coordinated by Glu342, Asp366 and His532, and an additional metal ion was found at the channel for the passage of a substrate coordinated by Asp453. The X-ray structures basically supported the ene-diol mechanism for the aldose–ketose isomerization by B. pallidusd-AI, as well as Escherichia coli (E. coli) l-FI, in which Glu342 and Asp366 facing each other at the catalytic metal ion transfer a proton from C2 to C1 and O1 to O2, acting as acid/base catalysts, respectively. However, considering the ionized state of Asp366, the catalytic reaction also possibly occurs through the negatively charged ene-diolate intermediate stabilized by the catalytic metal ion. A structural comparison with E. colil-FI showed that B. pallidusd-AI possibly interconverts between “open” and “closed” forms, and that the additional metal ion found in B. pallidusd-AI may help to stabilize the channel region.     

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.