Microbiology and Infectious Disease

Staphylococcus aureus counters organic acid anion-mediated inhibition of peptidoglycan cross-linking through robust alanine racemase activity

Sasmita Panda
Yahani P Jayasinghe
Dhananjay D Shinde
Emilio Bueno
Amanda Stastny
Blake P Bertrand
Sujata S Chaudhari
Tammy Kielian
Felipe Cava
Donald R Ronning
Vinai C Thomas author has email address

Center for Staphylococcal Research, Department of Pathology and Microbiology, University of Nebraska Medical Center, Omaha, USA
Department of Pharmaceutical Sciences, University of Nebraska Medical Center, Omaha, USA
Laboratory for Molecular Infection Medicine Sweden (MIMS), Umeå Center for Microbial Research (UCMR), Department of Molecular Biology, Umeå University, Umea, Sweden

https://doi.org/10.7554/eLife.95389.2

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Figures and data

Alanine racemase activity counters acetate intoxication
(A) The Nebraska Transposon Mutant library was screened against 20 mM acetic acid, pH 6.0 to identify mutants with altered growth phenotypes. The WT strain and transposon mutants were grown for 24 h in TSB ± 20 mM acetic acid. The bacterial growth at 24 h was measured spectrophotometrically (OD₆₀₀) and normalized to WT growth. The X and Y-axis on the plot represent normalized growth values for each mutant in the presence or absence of acetate. (B) The growth of the WT, alr1 mutant, and alr1 complemented strain (alr1C) in TSB supplemented with 20 mM acetic acid. (C) The tolerance of strains to various acetate concentrations was assessed by monitoring growth (OD₆₀₀) following a previously published method (58). To maintain a transmembrane pH gradient of ∼1.5, the culture media was adjusted to pH 6, prior to challenging with subinhibitory acetate concentrations (40 mM-1.25 mM; two-fold dilutions). The relative growth (fractional area) of both the WT, alr1 and alr1C mutant was calculated by comparing the area under the growth curves at subinhibitory concentrations of acetate to their corresponding controls (no acetate) and plotted against acetate concentrations. (D) Aerobic growth of WT, alr1, citZ, citZalr1 mutants in TSB media lacking glucose, but supplemented with 20 mM acetic acid. (E) LC-MS/MS analysis was performed to quantify the intracellular D-Ala-D-Ala pool in strains cultured for 3 h (exponential phase) in TSB ± 20 mM acetic acid. (F) The growth of strains was monitored following D-Ala supplementation (5 mM) in TSB + 20 mM acetate, (n=3, mean ± SD). Ac, acetate. ***, P value <0.001; ****, P value <0.0001.

Translational coupling of dat to pepV limits the alr1 mutant from countering acetate intoxication
(A) Schematic representation of various engineered mutations in the pepV- dat locus.SD, Shine-Dalgarno motif; TSS, transcriptional start site. (B)-(D) Growth of engineered mutants was monitored spectrophotometrically (OD₆₀₀) in TSB supplemented with 20 mM acetate (n=3, mean ± SD). (E) RT-qPCR to determine dat transcription in various mutants relative to the WT strain.

Reaction orientation and fluxes through Alr1 and Dat
(A) Schematic representation of various isotopologues of D-Ala-D-Ala and D-Glu generated from ¹³C3¹⁵N1 labeled L-Ala. Metabolites in blue mainly arise from Alr1, red, through the Ald1/2-Dat pathway and yellow are unlabeled intermediates within cells. The mass isotopologue distribution of (B) D-Ala-D-Ala and (C) D-Glu were determined by LC-MS/MS following the growth of S. aureus in chemically defined media supplemented with ¹³C3¹⁵N1 L-Ala (n=3, mean ± SD). Isotopologues of D-Ala-D-Ala shown in grey color are minor species and are noted in Table S9.

Acetate intoxication impacts soluble PG precursor pools and cell wall cross- linking.
(A) The intracellular pool of PG intermediates in exponential phase cultures of S. aureus was estimated using LC-MS/MS analysis. cps, counts per second (B) ddl and murF transcription in the exponential growth phase was determined by RT-qPCR analysis (n=3, mean ± SD). (C) Cell wall muropeptide analysis of the WT, alr1 and dat mutants was determined following growth in TSB ± 20 mM acetate for 3 h. Cell wall cross-linking was estimated as previously described (53). Ac, acetate. *, P value <0.05; **, P value <0.01; ***, P value <0.001; ****, P value <0.0001.

Acetate anion inhibits Ddl activity.
(A) The intracellular D-Ala was determined by LC- MS/MS analysis. (B) The ddl gene was overexpressed in S. aureus using a cadmium inducible expression system (pSP36). CdCl2, 0.312 µM. (C) Inhibition of recombinant His-tagged Ddl activity in the presence of 300 mM sodium acetate (D) IC50 curve of the inhibition of rDdl by acetate. Michaelis-Menten kinetics of rDdl in varying concentrations of (E) D-Ala, and (F) ATP in the presence of acetate to assess the inhibition mechanism. (G) Structure of the acetate bound Ddl (PDB:8FFF). (H) Acetate bound to the ATP binding site of Ddl (I) Acetate bound to the second D-Ala binding site of Ddl. The calculated Fo-Fc omit maps are contoured to 3σ and the mesh is shown in blue. (J) Superimposed structure of acetate bound Ddl (slate blue) with StaDdl apo structure (PDB:2I87, beige) and StaDdl-ADP complex structure (PDB:2I8C, grey) showing a shift of ω loop (red) to ATP binding site. The D-Ala-D-Ala was modeled at the D-Ala binding site using Thermos thermophius HB8 Ddl structure (PDB:2ZDQ). The bound ADP (grey) of PDB:2I87 and modeled D-Ala-D-Ala (light blue) indicates the positioning of Ac at ATP and second D-Ala binding sites respectively. Ac, acetate; V, velocity; *, P value <0.05; ****, P value <0.0001.

Biologically relevant weak acids inhibit growth of the alr1 mutant.
Molecular docking of (A) lactate (B) propionate and (C) itaconate to the ATP binding site of Ddl. (D) The relative positions and poise of different organic anions in relation to acetate in the D-Ala binding site of Ddl was determined using Schrödinger Glide. The growth (OD₆₀₀) of the WT and alr1 mutant in TSB containing (E) lactic acid (40 mM) (F) propionic acid (20 mM) and (G) itaconic acid (20 mM) in the presence or absence of 5 mM D-Ala.

Model depicting the role of Alr1 in countering organic acid anion-mediated inhibition of Ddl.
During its growth, S. aureus (WT) maintains a substantial intracellular pool of D-Ala through the activity of Alr1. Any excess D-Ala is subsequently converted into D-Glu by the action of the Dat enzyme. The high concentration of D-Ala is crucial for the optimal functioning of Ddl and serves to prevent the inhibition of Ddl by acetate (Ac^-) and other organic acid anions. This process generates sufficient D-Ala-D-Ala, which is rapidly incorporated into the PG tripeptide precursor UDP-NAM-AEKAA to form UDP-NAM-AEKAA, which ultimately contributes to a robust cross-linked PG (murein) sacculus. In the alr1 mutant, the Dat reaction orientation is switched to preserve intracellular D-Ala. Nevertheless, this change is inadequate to maintain sufficient D-Ala pool to shield Ddl from inhibition by Ac^-, due to tight control of dat translation. This results in an excess of UDP-NAM-AEK, which competes effectively with UDP-NAM-AEKAA for PG incorporation. The absence of a terminal D-Ala-D-Ala in the PG hinders crosslinking and leads to impaired growth following acetate intoxication.

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