Table 1.
Examples of fluorescent d-amino acid (FDAA) applications in recent studies. The subheadings classify the use of FDAAs in the experimental designs of these studies
| Article Title | Article Citation |
|---|---|
| Developing d-amino acid–based probes for peptidoglycan study | |
| In situ probing of newly synthesized peptidoglycan in live bacteria with fluorescent d-amino acids. | Kuru et al. (15) |
| d-Amino acid chemical reporters reveal peptidoglycan dynamics of an intracellular pathogen. | Siegrist et al. (97) |
| Reconstitution of peptidoglycan cross-linking leads to improved fluorescent probes of cell wall synthesis. | Lebar et al. (98) |
| Synthesis of fluorescent d-amino acids and their use for probing peptidoglycan synthesis and bacterial growth in situ. | Kuru et al. (54) |
| d-Amino acid probes for penicillin binding protein-based bacterial surface labeling. | Fura et al. (99) |
| Metabolic profiling of bacteria by unnatural C-terminated d-amino acids. | Pidgeon et al. (100) |
| Metabolic remodeling of bacterial surfaces via tetrazine ligations. | Pidgeon & Pires (101) |
| Full color palette of fluorescent d-amino acids for in situ labeling of bacterial cell walls. | Hsu et al. (62) |
| Identifying the formation and/or structure of peptidoglycan | |
| Discovery of chlamydial peptidoglycan reveals bacteria with murein sacculi but without FtsZ. | Pilhofer et al. (102) |
| De novo morphogenesis in L-forms via geometric control of cell growth. | Billings et al. (103) |
| A new metabolic cell-wall labelling method reveals peptidoglycan in Chlamydia trachomatis. | Liechti et al. (73) |
| Anammox planctomycetes have a peptidoglycan cell wall. | van Teeseling et al. (104) |
| Pathogenic Chlamydia lack a classical sacculus but synthesize a narrow, mid-cell peptidoglycan ring, regulated by MreB, for cell division. | Liechti et al. (105) |
| Studying bacterial morphogenesis and peptidoglycan growth pattern | |
| Peptidoglycan transformations during Bacillus subtilis sporulation. | Tocheva et al. (106) |
| Site-directed fluorescence labeling reveals a revised N-terminal membrane topology and functional periplasmic residues in the Escherichia coli cell division protein FtsK. | Berezuk et al. (107) |
| Salinity-dependent impacts of ProQ, Prc, and Spr deficiencies on E. coli cell structure. | Kerr et al. (108) |
| Cell separation in Vibrio cholerae is mediated by a single amidase whose action is modulated by two nonredundant activators. | Möll et al. (109) |
| Rod-like bacterial shape is maintained by feedback between cell curvature and cytoskeletal localization. | Ursell et al. (52) |
| Cell shape dynamics during the staphylococcal cell cycle. | Monteiro et al. (110) |
| Molecular modeling, simulation, and virtual screening of MurD ligase protein from salmonella typhimurium LT2. | Samal et al. (111) |
| Short-stalked Prosthecomicrobium hirschii cells have a Caulobacter-like cell cycle. | Williams et al. (112) |
| Treadmilling by FtsZ filaments drives peptidoglycan synthesis and bacterial cell division. | Bisson-Filho et al. (5) |
| Dynamics of the peptidoglycan biosynthetic machinery in the stalked budding bacterium Hyphomonas neptunium. | Cserti et al. (63) |
| Hydrolysis of peptidoglycan is modulated by amidation of meso-diaminopimelic acid and Mg2+ in B. subtilis. | Dajkovic et al. (113) |
| Staphylococcus aureus requires at least one FtsK/SpoIIIE protein for correct chromosome segregation. | Veiga & Pinho (114) |
| GTPase activity–coupled treadmilling of the bacterial tubulin FtsZ organizes septal cell wall synthesis. | Yang et al. (66) |
| Short FtsZ filaments can drive asymmetric cell envelope constriction at the onset of bacterial cytokinesis. | Yao et al. (115) |
| Determining peptidoglycan synthesis activity and sites | |
| Divin: a small molecule inhibitor of bacterial divisome assembly. | Eun et al. (116) |
| Peptidoglycan synthesis machinery in Agrobacterium tumefaciens during unipolar growth and cell division. | Cameron et al. (117) |
| Interplay of the serine/threonine-kinase StkP and the paralogs DivIVA and GpsB in pneumococcal cell elongation and division. | Fleurie et al. (118) |
| MapZ marks the division sites and positions FtsZ rings in Streptococcus pneumoniae. | Fleurie et al. (119) |
| Sequential evolution of bacterial morphology by co-option of a developmental regulator. | Jiang et al. (81) |
| Pbp2x localizes separately from Pbp2b and other peptidoglycan synthesis proteins during later stages of cell division of S. pneumoniae D39. | Tsui et al. (120) |
| Endopeptidase-mediated β-lactam tolerance. | Dörr et al. (121) |
| Roles for both FtsA and the FtsBLQ subcomplex in FtsN-stimulated cell constriction in E. coli. | Liu et al. (122) |
| A d,d-carboxypeptidase is required for Vibrio cholerae halotolerance. | Möll et al. (123) |
| The bacterial tubulin FtsZ requires its intrinsically disordered linker to direct robust cell wall construction. | Sundararajan et al. (124) |
| Lipid-linked cell wall precursors regulate membrane association of bacterial actin MreB. | Schirner et al. (125) |
| MreC and MreD proteins are not required for growth of S. aureus. | Tavares et al. (126) |
| The cell wall amidase AmiB is essential for Pseudomonas aeruginosa cell division, drug resistance and viability. | Yakhnina et al. (127) |
| Lyme disease and relapsing fever Borrelia elongate through zones of peptidoglycan synthesis that mark division sites of daughter cells. | Jutras et al. (128) |
| Structure–function analysis of the extracellular domain of the pneumococcal cell division site positioning protein MapZ. | Manuse et al. (129) |
| Roles of the essential protein FtsA in cell growth and division in S. pneumoniae. | Mura et al. (130) |
| FtsZ-dependent elongation of a coccoid bacterium. | Pereira et al. (131) |
| Colanic acid intermediates prevent de novo shape recovery of E. coli spheroplasts, calling into question biological roles previously attributed to colanic acid. | Ranjit & Young (132) |
| Subcompartmentalization by cross-membranes during early growth of Streptomyces hyphae. | Yagüe et al. (133) |
| Pentapeptide-rich peptidoglycan at the B. subtilis cell-division site. | Angeles et al. (134) |
| Mycobacterium tuberculosis protease MarP activates a peptidoglycan hydrolase during acid stress. | Botella et al. (135) |
| B. subtilis swarmer cells lead the swarm, multiply, and generate a trail of quiescent descendants. | Hamouche et al. (136) |
| Deciphering the mode of action of cell wall-inhibiting antibiotics using metabolic labeling of growing peptidoglycan in Streptococcus pyogenes. | Sugimoto et al. (137) |