L,D-Transpeptidase Specific Probe Reveals Spatial Activity of Peptidoglycan Cross-Linking.
Sean E PidgeonAlexis J ApostolosJulia M NelsonMoagi ShakuBinayak RimalM Nurul IslamDean C CrickSung Joon KimMartin S PavelkaBavesh D KanaMarcos M PiresPublished in: ACS chemical biology (2019)
Peptidoglycan (PG) is a cross-linked, meshlike scaffold endowed with the strength to withstand the internal pressure of bacteria. Bacteria are known to heavily remodel their peptidoglycan stem peptides, yet little is known about the physiological impact of these chemical variations on peptidoglycan cross-linking. Furthermore, there are limited tools to study these structural variations, which can also have important implications on cell wall integrity and host immunity. Cross-linking of peptide chains within PG is an essential process, and its disruption thereof underpins the potency of several classes of antibiotics. Two primary cross-linking modes have been identified that are carried out by D,D-transpeptidases and L,D-transpeptidases (Ldts). The nascent PG from each enzymatic class is structurally unique, which results in different cross-linking configurations. Recent advances in PG cellular probes have been powerful in advancing the understanding of D,D-transpeptidation by Penicillin Binding Proteins (PBPs). In contrast, no cellular probes have been previously described to directly interrogate Ldt function in live cells. Herein, we describe a new class of Ldt-specific probes composed of structural analogs of nascent PG, which are metabolically incorporated into the PG scaffold by Ldts. With a panel of tetrapeptide PG stem mimics, we demonstrated that subtle modifications such as amidation of iso-Glu can control PG cross-linking. Ldt probes were applied to quantify and track the localization of Ldt activity in Enterococcus faecium, Mycobacterium smegmatis, and Mycobacterium tuberculosis. These results confirm that our Ldt probes are specific and suggest that the primary sequence of the stem peptide can control Ldt cross-linking levels. We anticipate that unraveling the interplay between Ldts and other cross-linking modalities may reveal the organization of the PG structure in relation to the spatial localization of cross-linking machineries.
Keyphrases
- cell wall
- small molecule
- mycobacterium tuberculosis
- living cells
- fluorescence imaging
- magnetic resonance
- magnetic resonance imaging
- oxidative stress
- induced apoptosis
- cystic fibrosis
- quantum dots
- computed tomography
- cell death
- bacillus subtilis
- tissue engineering
- molecular dynamics simulations
- escherichia coli
- cell proliferation
- molecular docking
- cell cycle arrest