In Vivo Probe of Lipid II‐Interacting Proteins

β‐Lactams represent one of the most important classes of antibiotics discovered to date. These agents block Lipid II processing and cell wall biosynthesis through inactivation of penicillin‐binding proteins (PBPs). PBPs enzymatically load cell wall building blocks from Lipid II carrier molecules onto the growing cell wall scaffold during growth and division. Lipid II, a bottleneck in cell wall biosynthesis, is the target of some of the most potent antibiotics in clinical use. Despite the immense therapeutic value of this biosynthetic pathway, the PBP–Lipid II association has not been established in live cells. To determine this key interaction, we designed an unnatural d ‐amino acid dipeptide that is metabolically incorporated into Lipid II molecules. By hijacking the peptidoglycan biosynthetic machinery, photoaffinity probes were installed in combination with click partners within Lipid II, thereby allowing, for the first time, demonstration of PBP interactions in vivo with Lipid II.     

Synthetic peptidoglycan substrates for penicillin-binding protein 5 of Gram-negative bacteria

The major constituent of the bacterial cell wall, peptidoglycan, is comprised of repeating units of N-acetylglucosamine (NAG) and N-acetylmuramic acid (NAM) with an appended peptide. Penicillin-binding proteins (PBPs) are involved in the final stages of bacterial cell wall assembly. Two activities for PBPs are the cross-linking of the cell wall, carried out by dd-transpeptidases, and the dd-peptidase activity, that removes the terminal d-Ala residue from peptidoglycan. The dd-peptidase activity moderates the extent of the cell wall cross-linking. There exists a balance between the two activities that is critical for the well-being of bacterial cells. We have cloned and purified PBP5 of Escherichia coli. The membrane anchor of this protein was removed, and the enzyme was obtained as a soluble protein. Two fragments of the polymeric cell wall of Gram-negative bacteria (compounds 5 and 6) were synthesized. These molecules served as substrates for PBP5. The products of the reactions of PBP5 and compounds 5 and 6 were isolated and were shown to be d-Ala and the fragments of the substrates minus the terminal d-Ala. The kinetic parameters for these enzymic reactions were evaluated. PBP5 would appear to have the potential for turnover of as many as 1.4 million peptidoglycan strands within a single doubling time (i.e., generation) of E. coli.     

A mechanism-based inhibitor targeting the DD-transpeptidase activity of bacterial penicillin-binding proteins

Penicillin-binding proteins (PBPs) are responsible for the final stages of bacterial cell wall assembly. These enzymes are targets of beta-lactam antibiotics. Two of the PBP activities include dd-transpeptidase and DD-carboxypeptidase activities, which carry out the cross-linking of the cell wall and trimming of the peptidoglycan, the major constituent of the cell wall, by an amino acid, respectively. The activity of the latter enzyme moderates the degree of cross-linking of the cell wall, which is carried out by the former. Both these enzymes go through an acyl-enzyme species in the course of their catalytic events. Compound 6, a cephalosporin derivative incorporated with structural features of the peptidoglycan was conceived as an inhibitor specific for DD-transpeptidases. On acylation of the active sites of dd-transpeptidases, the molecule would organize itself in the two active site subsites such that it mimics the two sequestered strands of the bacterial peptidoglycan en route to their cross-linking. Hence, compound 6 is the first inhibitor conceived and designed specifically for inhibition of DD-transpeptidases. The compound was synthesized in 13 steps and was tested with recombinant PBP1b and PBP5 of Escherichia coli, a dd-transpeptidase and a dd-carboxypeptidase, respectively. Compound 6 was a time-dependent and irreversible inhibitor of PBP1b. On the other hand, compound 6 did not interact with PBP5, neither as an inhibitor (reversible or irreversible) nor as a substrate.     

Fluorescent Bocillins: synthesis and application in the detection of penicillin-binding proteins

Novel fluorescent analogs of penicillin V were synthesized and evaluated for efficacy in the detection of penicillin binding proteins (PBPs). These molecules include the full structure of penicillin V, with the potent Bodipy fluorophore attached to the para-position of the penicillin V phenyl group. The green fluorescent Bocillin FL and the near-infrared (IR) fluorescent Bocillin 650/665 probes were shown to bind to PBPs, both purified and from membrane preparations, with high affinity and specificity. These reagents allow for facile detection of 2-4 ng of purified PBP with the aid of a fluorescent scanner.     

Co-opting the cell wall in fighting methicillin-resistant Staphylococcus aureus: potent inhibition of PBP 2a by two anti-MRSA beta-lactam antibiotics

Methicillin-resistant Staphylococcus aureus (MRSA) is a global bacterial scourge that has become resistant to many classes of antibiotics, and treatment options for MRSA infections are limited. The cause of MRSA resistance to all commercially available beta-lactam antibiotics is the acquisition of the gene mecA, which encodes penicillin-binding protein 2a (PBP 2a). PBP 2a is a transpeptidase, which in contrast to the other transpeptidases of S. aureus does not experience inhibition by beta-lactam antibiotics. The lack of inhibition is due to a closed conformation for the active site for PBP 2a, which opens up only in the course of the catalytic function of the protein. Here we show that two new anti-MRSA antibiotics now undergoing clinical trials, ceftaroline and ME1036, are able to inhibit PBP 2a effectively, a process that is enhanced in the presence of a cell wall structural surrogate. It is likely that in the course of bacterial growth the occupancy of the allosteric site for the cell wall is co-opted by these antibiotics, and under these conditions the second-order rate constant for the encounter of the antibiotic and PBP 2a approaches the clinically useful value of 10(4)-10(5) M-1 s-1. These compounds are potent inhibitors of PBP 2a as well as PBPs from other species, and have potential as therapeutic agents for treatment of serious infections by MRSA and other resistant bacterial pathogens.     

12‐ to 22‐Membered Bridged β‐Lactams as Potential Penicillin‐Binding Protein Inhibitors

As potential inhibitors of penicillin‐binding proteins (PBPs), we focused our research on the synthesis of non‐traditional 1,3‐bridged β‐lactams embedded into macrocycles. We synthesized 12‐ to 22‐membered bicyclic β‐lactams by the ring‐closing metathesis (RCM) of bis‐ω‐alkenyl‐3(S)‐aminoazetidinone precursors. The reactivity of 1,3‐bridged β‐lactams was estimated by the determination of the energy barrier of a concerted nucleophilic attack and lactam ring‐opening process by using ab initio calculations. The results predicted that 16‐membered cycles should be more reactive. Biochemical evaluations against R39 DD‐peptidase and two resistant PBPs, namely, PBP2a and PBP5, revealed the inhibition effect of compound 4d , which featured a 16‐membered bridge and the N‐tert‐butyloxycarbonyl chain at the C3 position of the β‐lactam ring. Surprisingly, the corresponding bicycle, 12d , with the PhOCH₂CO side chain at C3 was inactive. Reaction models of the R39 active site gave a new insight into the geometric requirements of the conformation of potential ligands and their steric hindrance; this could help in the design of new compounds.     

Transpeptidase-mediated incorporation of D-amino acids into bacterial peptidoglycan

The β-lactams are the most important class of antibiotics in clinical use. Their lethal targets are the transpeptidase domains of penicillin binding proteins (PBPs), which catalyze the cross-linking of bacterial peptidoglycan (PG) during cell wall synthesis. The transpeptidation reaction occurs in two steps, the first being formation of a covalent enzyme intermediate and the second involving attack of an amine on this intermediate. Here we use defined PG substrates to dissect the individual steps catalyzed by a purified E. coli transpeptidase. We demonstrate that this transpeptidase accepts a set of structurally diverse D-amino acid substrates and incorporates them into PG fragments. These results provide new information on donor and acceptor requirements as well as a mechanistic basis for previous observations that noncanonical D-amino acids can be introduced into the bacterial cell wall.     

Lipid II: total synthesis of the bacterial cell wall precursor and utilization as a substrate for glycosyltransfer and transpeptidation by penicillin binding protein (PBP) 1b of Escherichia coli.

An essential feature in the life cycle of both gram positive and gram negative bacteria is the production of new cell wall. Also known as murein, the cell wall is a two-dimensional polymer, consisting of a linear, repeating N-acetylmuramic acid (MurNAc) and N-acetylglucosamine (GlcNAc) motif, cross-linked via peptides appended to MurNAc. The final steps in the maturation of murein are catalyzed by a single, bifunctional enzyme, known as a high MW, class A penicillin binding protein (PBP). PBPs catalyze polymerization of the sugar units (glycosyltransfer), as well as peptide cross-linking (transpeptidation) utilizing Lipid II as substrate. Detailed enzymology on this enzyme has been limited, due to difficulties in obtaining sufficient amounts of Lipid II, as well as the availability of a convenient and informative assay. We report the total chemical synthesis of Lipid II, as well as the development of an appropriate assay system and the observation of both catalytic transformations.     

Sequential In Vitro Cyclization by Cytochrome P450 Enzymes of Glycopeptide Antibiotic Precursors Bearing the X‐Domain from Nonribosomal Peptide Biosynthesis

The biosynthesis of the glycopeptide antibiotics, which include vancomycin and teicoplanin, relies on the interplay between the peptide‐producing non‐ribosomal peptide synthetase (NRPS) and Cytochrome P450 enzymes (P450s) that catalyze side‐chain crosslinking of the peptide. We demonstrate that sequential in vitro P450‐catalyzed cyclization of peptide substrates is enabled by the use of an NRPS peptide carrier protein (PCP)‐X di‐domain as a P450 recruitment platform. This study reveals that whilst the precursor peptide sequence influences the installation of the second crosslink by the P450 OxyA_tei, activity is not restricted to the native teicoplanin peptide. Initial peptide cyclization is possible with teicoplanin and vancomycin OxyB homologues, and the latter displays excellent activity with all substrate combinations tested. By using non‐natural X‐domain substrates, bicyclization of hexapeptides was also shown, which demonstrates the utility of this method for the cyclization of varied peptide substrates in vitro.     

Effects of PAR and UV Radiation on the Structural and Functional Integrity of Phycocyanin,Phycoerythrin and Allophycocyanin Isolated from the Marine Cyanobacterium Lyngbya sp. A09DM

An in vitro analysis of the effects of photosynthetically active and ultraviolet radiations was executed to assess the photostability of biologically relevant pigments phycocyanin (PC), phycoerythrin (PE) and allophycocyanin (APC) isolated from Lyngbya sp. A09DM. Ultraviolet (UV) irradiances significantly affected the integrity of PC, PE and APC; however, PAR showed least effect. UV radiation affected the bilin chromophores covalently attached to phycobiliproteins (PBPs). Almost complete elimination of the chromophore bands associated with α‐ and β‐subunit of PE and APC occurred after 4 h of UV‐B exposure. After 5 h of UV‐B exposure, the content of PC, PE and APC decreased by 51.65%, 96.8% and 96.53%, respectively. Contrary to PAR and UV‐A radiation, a severe decrease in fluorescence of all PBPs was observed under UV‐B irradiation. The fluorescence activity of extracted PBP was gradually inhibited immediately after 15–30 min of UV‐B exposure. In comparison to the PC, the fluorescence properties of PE and APC were severely lost under UV‐B radiation. Moreover, the present study indicates that UV‐B radiation can damage the structural and functional integrity of phycobiliproteins leading to the loss of their ecological and biological functions.     

Staphylococcus aureus Penicillin‐Binding Protein 2 Can Use Depsi‐Lipid II Derived from Vancomycin‐Resistant Strains for Cell Wall Synthesis

Vancomycin‐resistant Staphylococcus aureus (S. aureus) (VRSA) uses depsipeptide‐containing modified cell‐wall precursors for the biosynthesis of peptidoglycan. Transglycosylase is responsible for the polymerization of the peptidoglycan, and the penicillin‐binding protein 2 (PBP2) plays a major role in the polymerization among several transglycosylases of wild‐type S. aureus. However, it is unclear whether VRSA processes the depsipeptide‐containing peptidoglycan precursor by using PBP2. Here, we describe the total synthesis of depsi‐lipid I, a cell‐wall precursor of VRSA. By using this chemistry, we prepared a depsi‐lipid II analogue as substrate for a cell‐free transglycosylation system. The reconstituted system revealed that the PBP2 of S. aureus is able to process a depsi‐lipid II intermediate as efficiently as its normal substrate. Moreover, the system was successfully used to demonstrate the difference in the mode of action of the two antibiotics moenomycin and vancomycin.     

Synthesis of a new type of core–shell particle from hyperbranched polyglycerol

Based on hyperbranched polyglycerol (PG), a route to prepare particles with a novel topology was developed. The hydroxyls of PG were converted to trithiocarbonates, and the latter were used to mediate the surface graft polymerization of N,N‐dimethylaminoethyl acrylate. The poly(N,N‐dimethylaminoethyl acrylate) shell was crosslinked by 1,6‐dibromohexane and then parted from the core by the cleavage of trithiocarbonates with sodium borohydride. Novel particles with thiol groups located on the interface between the PG core and poly(N,N‐dimethylaminoethyl acrylate) shell were thus formed. The shell crosslinking could be performed at very high solid contents (2–4%). These polymer particles showed pH‐ and temperature‐dependent solubility. © 2005 Wiley Periodicals, Inc. J Polym Sci Part A: Polym Chem 43: 5458–5464, 2005     

A computational evaluation of the mechanism of penicillin-binding protein-catalyzed cross-linking of the bacterial cell wall

Penicillin-binding protein 1b (PBP 1b) of the gram-positive bacterium Streptococcus pneumoniae catalyzes the cross-linking of adjacent peptidoglycan strands, as a critical event in the biosynthesis of its cell wall. This enzyme is representative of the biosynthetic PBP structures of the β-lactam-recognizing enzyme superfamily and is the target of the β-lactam antibiotics. In the cross-linking reaction, the amide between the -D-Ala-D-Ala dipeptide at the terminus of a peptide stem acts as an acyl donor toward the ε-amino group of a lysine found on an adjacent stem. The mechanism of this transpeptidation was evaluated using explicit-solvent molecular dynamics simulations and ONIOM quantum mechanics/molecular mechanics calculations. Sequential acyl transfer occurs to, and then from, the active site serine. The resulting cross-link is predicted to have a cis-amide configuration. The ensuing and energetically favorable cis- to trans-amide isomerization, within the active site, may represent the key event driving product release to complete enzymatic turnover.     

A Crystal Structure of a Functional RNA Molecule Containing an Artificial Nucleobase Pair

As one of its goals, synthetic biology seeks to increase the number of building blocks in nucleic acids. While efforts towards this goal are well advanced for DNA, they have hardly begun for RNA. Herein, we present a crystal structure for an RNA riboswitch where a stem C:G pair has been replaced by a pair between two components of an artificially expanded genetic‐information system (AEGIS), Z and P , (6‐amino‐5‐nitro‐2(1H)‐pyridone and 2‐amino‐imidazo[1,2‐a]‐1,3,5‐triazin‐4‐(8H)‐one). The structure shows that the Z : P pair does not greatly change the conformation of the RNA molecule nor the details of its interaction with a hypoxanthine ligand. This was confirmed in solution by in‐line probing, which also measured a 3.7 nM affinity of the riboswitch for guanine. These data show that the Z : P pair mimics the natural Watson–Crick geometry in RNA in the first example of a crystal structure of an RNA molecule that contains an orthogonal added nucleobase pair.     

Synthesis of lipidated green fluorescent protein and its incorporation in supported lipid bilayers

Herein we report a semisynthetic method of producing membrane-anchored proteins. Ligation of synthetic lipids with designed anchor structures to proteins was performed using native chemical ligation (NCL) of a C-terminal peptide thioester and an N-terminal cysteine lipid. This strategy mimics the natural glycosylphosphatidylinositol (GPI) linkage found in many natural membrane-associated proteins; however, the synthetic method utilizes simple lipid anchors without glycans. Synthetically lipidated recombinant green fluorescent protein (GFP) was shown to be stably anchored to the membrane, and its lateral fluidity was quantitatively characterized by direct fluorescence imaging in supported membranes. Circumventing the steps of purification from native cell membranes, this methodology facilitates the reconstitution of membrane-associated proteins.     

Monitoring Endocytic Trafficking of Anthrax Lethal Factor by Precise and Quantitative Protein Labeling

Coupling the genetic code expansion technique with bioorthogonal reactions enables precise control over the conjugation site as well as the choice of fluorescent probes during protein labeling. However, the advantages of this strategy over bulky and rigid fluorescent proteins (FPs) remain to be fully explored. Here we applied site‐specific bioorthogonal labeling on anthrax lethal factor (LF) to visualize its membrane translocation inside live cells. In contrast to the previously reported FP tags that significantly perturbed LF’s membrane trafficking, our precisely and quantitatively labeled LF exhibited an endocytic activity comparable to wild‐type LF. This allowed time‐lapse imaging of LF’s natural translocation process from host cell membrane to cytosol, which revealed molecular details of its virulence mechanism. Our strategy is generally applicable for monitoring intracellular protein membrane translocation that is difficult to access using conventional protein labeling methodologies.     

Activation for catalysis of penicillin-binding protein 2a from methicillin-resistant Staphylococcus aureus by bacterial cell wall

Methicillin-resistant Staphylococcus aureus (MRSA) has acquired a unique penicillin-binding protein (PBP), PBP 2a, which has rendered the organism resistant to the action of all available beta-lactam antibiotics. The X-ray structure of PBP 2a shows the active site in a closed conformation, consistent with resistance to inhibition by beta-lactam antibiotics. However, it is known that PBP 2a avidly cross-links the S. aureus cell wall, which is its physiological function. It is shown herein that synthetic fragments of the bacterial cell wall bind in a saturable manner to PBP 2a and cause a conformational change in the protein that makes the active site more accessible to binding to a beta-lactam antibiotic. These observations and measurements point to a novel strategy by nature to keep the active site of PBP 2a sheltered from the inhibitory activity of the antibiotics, yet it becomes available to the polymeric cell wall by a requisite conformational change for the critical cell wall cross-linking reaction.     

Designing Visible Light‐Cured Thiol‐Acrylate Hydrogels for Studying the HIPPO Pathway Activation in Hepatocellular Carcinoma Cells

Various polymerization mechanisms have been developed to prepare peptide‐immobilized poly(ethylene glycol) (PEG) hydrogels, a class of biomaterials suitable for studying cell biology in vitro. Here, a visible light mediated thiol‐acrylate photopolymerization scheme is reported to synthesize dually degradable PEG‐peptide hydrogels with controllable crosslinking and degradability. The influence of immobilized monothiol pendant peptide is systematically evaluated on the crosslinking of these hydrogels. Further, methods are proposed to modulate hydrogel crosslinking, including adjusting concentration of comonomer or altering the design of multifunctional peptide crosslinker. Due to the formation of thioether ester bonds, these hydrogels are hydrolytically degradable. If the dithiol peptide linkers used are susceptible to protease cleavage, these thiol‐acrylate hydrogels can be designed to undergo partial proteolysis. The differences between linear and multiarm PEG‐acrylate (i.e., PEGDA vs PEG4A) are also evaluated. Finally, the use of the mixed‐mode thiol‐acrylate PEG4A‐peptide hydrogels is explored for in situ encapsulation of hepatocellular carcinoma cells (Huh7). The effects of matrix stiffness and integrin binding motif (e.g., RGDS) on Huh7 cell growth and HIPPO pathway activation are studied using PEG4A‐peptide hydrogels. This visible light poly­merized thiol‐acrylate hydrogel system represents an alternative to existing light‐cured hydrogel platforms and shall be useful in many biomedical applications.     

Protein Organic Chemistry and Applications for Labeling and Engineering in Live‐Cell Systems

The modification of proteins with synthetic probes is a powerful means of elucidating and engineering the functions of proteins both in vitro and in live cells or in vivo. Herein we review recent progress in chemistry‐based protein modification methods and their application in protein engineering, with particular emphasis on the following four strategies: 1) the bioconjugation reactions of amino acids on the surfaces of natural proteins, mainly applied in test‐tube settings; 2) the bioorthogonal reactions of proteins with non‐natural functional groups; 3) the coupling of recognition and reactive sites using an enzyme or short peptide tag–probe pair for labeling natural amino acids; and 4) ligand‐directed labeling chemistries for the selective labeling of endogenous proteins in living systems. Overall, these techniques represent a useful set of tools for application in chemical biology, with the methods 2–4 in particular being applicable to crude (living) habitats. Although still in its infancy, the use of organic chemistry for the manipulation of endogenous proteins, with subsequent applications in living systems, represents a worthy challenge for many chemists.     

Tuning the Inter‐nanofibril Interaction To Regulate the Morphology and Function of Peptide/DNA Co‐assembled Viral Mimics

The ability to tune the inter‐subunit interaction within the virus capsid may be critical to assembly and biological function. This process was extended here with peptide/DNA co‐assembled viral mimics. The resulting co‐assemblies, formed and stabilized by both peptide nanofibril–DNA and peptide nanofibril–nanofibril interactions, were tuned through hydrophobic packing interactions of the peptide sequences. By strengthening peptide side‐chain complementarity and/or elongating the peptide chain (from 4 to 8 residues), we report strengthening the inter‐nanofibril interaction to create stable nanococoons that give high gene‐transfection efficacy.