Exolytic and endolytic turnover of peptidoglycan by lytic transglycosylase Slt of
            <i>Pseudomonas aeruginosa</i>

Lee, Mijoon; Batuecas, M.T.; Tomoshige, Shusuke; Dominguez-Gil, T.; Mahasenan, Kiran V.; Dik, David A.; Hesek, Dušan; Millán, Claudia; Usón, Isabel; Lastochkin, Elena; Hermoso, J.A.; Mobashery, Shahriar

doi:10.1073/pnas.1801298115

Cited by 36 publications

(54 citation statements)

References 32 publications

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“…Notably, it is only after the binding of substrates that contain pentapeptide stems that it can exhibit endolytic activity due to a conformational change of the protein on substrate binding. A movie of this rearrangement is available in the supplementary material of reference [23]. Additional studies suggest protein-protein interactions with inner membrane PBPs are also important [26].…”

Section: Structural Studies Of the Soluble Lts Slt Sltb1 And Sltb3 mentioning

confidence: 98%

“…Recently, lytic transglycosylases of P. aeruginosa have been extensively characterized [21][22][23][24][25][26][27]. These cell wall proteins are found in many other pathogenic bacteria and are classified according to amino acid sequence and function [28].…”

Section: Lytic Transglycosylases Of P Aeruginosamentioning

confidence: 99%

“…X-ray crystal structures of Slt in its apo form as well as in complex with various synthetic PG substrates and reaction products demonstrated that this Lt has both exolytic and endolytic activity [23]. It is a donut shaped protein like Slt of E. coli.…”

Section: Structural Studies Of the Soluble Lts Slt Sltb1 And Sltb3 mentioning

confidence: 99%

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Bulgecins as β-Lactam Enhancers Against Multidrug Resistant (MDR) Pseudomonas aeruginosa

Skalweit¹

2019

Pseudomonas Aeruginosa - An Armory Within

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Antibiotic resistance in non-lactose fermenting pathogens such as Pseudomonas aeruginosa (P. aeruginosa) is increasing, making these clinical pathogens more difficult to treat. Multiple resistance mechanisms exist within P. aeruginosa that affect all classes of antibiotics used in the clinic. New strategies and treatment targets within these MDR pathogens must be exploited. One heretofore untapped target is the family of cell wall enzymes known as lytic transglycosylases (Lts). Lts work in concert with penicillin binding proteins (PBPs) and other cell wall proteins such as amidases and peptidoglycan hydrolases to affect normal cell division, and during stress and programmed cell death. Lts are inhibited by natural products called bulgecins, produced by non-pathogenic Paraburkholderia and Burkholderia spp. New research describing the ability of Lt inhibition to restore susceptibility to β-lactams in MDR P. aeruginosa, as well as the structural biologic basis for the activity of bulgecins will be reviewed. Other targets and applications of bulgecins will also be discussed.

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Section: Structural Studies Of the Soluble Lts Slt Sltb1 And Sltb3 mentioning

confidence: 98%

Section: Lytic Transglycosylases Of P Aeruginosamentioning

confidence: 99%

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Bulgecins as β-Lactam Enhancers Against Multidrug Resistant (MDR) Pseudomonas aeruginosa

Skalweit¹

2019

Pseudomonas Aeruginosa - An Armory Within

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“…283,284 Accordingly, we have undertaken extensive mechanistic and structural studies of this family. These efforts have led us to the discovery that an ABC-transporter-like regulatory module is present in the structure of the P. aeruginosa MltF LT 285 ; that the P. aeruginosa SltB1 LT has a catenane dimer structure; that the P. aeruginosa Slt LT 286 has the same compelling doughnut-shape as is seen in other Slt LTs whose catalytic activity is governed by important conformational changes 234,[287][288][289] ; and to a computational mechanism for the smallest LT of E. coli, MltE, 233 based on our crystallographic analyses. 290,291 The assertion of an intimate relationship between the LT family and β-lactam antibiotic efficacy has irrefutable support.…”

Section: Abetting the β-Lactam Antibiotics Against Gram-negative Bamentioning

confidence: 99%

“…303 F I G U R E 3 The stereo image of the structure of the complex of the E503Q catalytic-impaired mutant of the P. aeruginosa Slt LT bound to bulgecin A (bottom structure) (PDB 6FCQ). 286 Bulgecin A (depicted in sphere representation; color by atom types) is bound at the active site of this LT. This active site is located on the threshold of the central opening of this doughnutshaped protein…”

Section: Abetting the β-Lactam Antibiotics Against Gram-negative Bamentioning

confidence: 99%

Constructing and deconstructing the bacterial cell wall

Fisher

Mobashery

2019

Protein Science

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The history of modern medicine cannot be written apart from the history of the antibiotics. Antibiotics are cytotoxic secondary metabolites that are isolated from Nature. The antibacterial antibiotics disproportionately target bacterial protein structure that is distinct from eukaryotic protein structure, notably within the ribosome and within the pathways for bacterial cell‐wall biosynthesis (for which there is not a eukaryotic counterpart). This review focuses on a pre‐eminent class of antibiotics—the β‐lactams, exemplified by the penicillins and cephalosporins—from the perspective of the evolving mechanisms for bacterial resistance. The mechanism of action of the β‐lactams is bacterial cell‐wall destruction. In the monoderm (single membrane, Gram‐positive staining) pathogen Staphylococcus aureus the dominant resistance mechanism is expression of a β‐lactam‐unreactive transpeptidase enzyme that functions in cell‐wall construction. In the diderm (dual membrane, Gram‐negative staining) pathogen Pseudomonas aeruginosa a dominant resistance mechanism (among several) is expression of a hydrolytic enzyme that destroys the critical β‐lactam ring of the antibiotic. The key sensing mechanism used by P. aeruginosa is monitoring the molecular difference between cell‐wall construction and cell‐wall deconstruction. In both bacteria, the resistance pathways are manifested only when the bacteria detect the presence of β‐lactams. This review summarizes how the β‐lactams are sensed and how the resistance mechanisms are manifested, with the expectation that preventing these processes will be critical to future chemotherapeutic control of multidrug resistant bacteria.

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Macromolecular Machineries in Cell‐Wall Recycling

Batuecas

Hermoso

2019

Encyclopedia of Life Sciences

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Peptidoglycan, the major constituent of bacterial cell wall, is a huge polymeric macromolecule composed of glycan strands covalently linked by interconnecting peptide stems and critical for survival of bacteria. Peptidoglycan is constantly edited, biosynthesised and degraded, during essential bacterial processes such as division, elongation or insertion of the cellular machinery (e.g. flagella, pili) into cell wall. Degradation fragments are recovered, especially in Gram‐negative bacteria, by active transport and recycled to rebuild the wall. In some important Gram‐negative pathogens, β‐lactam resistance is directly linked to peptidoglycan recycling. The recycling process requires orchestration of different lytic enzymes and transporters from periplasm, the inner membrane, to cytoplasm. Recent structural and functional studies have provided relevant insights into enzymatic regulation, substrate specificity and activity of the lytic machineries involved in recycling with relevant implications in antibiotics resistance. Key Concepts Peptidoglycan recycling is an essential process in Gram‐negative bacteria that recovers self‐degradation products of cell wall in the cytoplasm to reutilise them to rebuild the wall. PG recycling is important in cell‐wall biosynthesis and in bacterial communication in many bacteria, and in antibiotics resistance in some pathogens from Enterobacteriaceae and Pseudomonadaceae families. PG recycling involves a large number of enzymes and transporters spanning from periplasm, inner and outer membranes, and cytoplasm. Lytic transglycosylases (LTs) are periplasmic and, typically, modular enzymes that initiate PG recycling by non‐hydrolytic degradation of glycan chains. They are classified in six families. Several LTs are found in each Gram‐negative bacterium. The Slt structure reveals how, under the effect of β‐lactam antibiotics, the cell wall is repaired by degradation of aberrant nascent PG chains and how it initiates the resistance phenotype. MltF is a modular membrane‐bound LT that experiences allosteric activation triggered by muropeptides. PG amidases are present in periplasm and cytoplasm. Activity in periplasm is regulated by cellular location, protein–protein interactions and oligomeric state. An activation mechanism has been discovered for cytosolic enzymes. Anhydro‐muropeptides are the key molecules to activate the AmpR to induce AmpC β‐lactamase in response to β‐lactam challenge. Regulation (in space and time) of the catalytic processes as well as of interaction between different partners is essential in PG recycling enzymes.

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Exolytic and endolytic turnover of peptidoglycan by lytic transglycosylase Slt of Pseudomonas aeruginosa

Cited by 36 publications

References 32 publications

Bulgecins as β-Lactam Enhancers Against Multidrug Resistant (MDR) Pseudomonas aeruginosa

Bulgecins as β-Lactam Enhancers Against Multidrug Resistant (MDR) Pseudomonas aeruginosa

Constructing and deconstructing the bacterial cell wall

Macromolecular Machineries in Cell‐Wall Recycling

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