Structural Investigation of Bacterial Cell Wall Modifying and Recycling Enzymes

Abstract

Die Dissertation ist gesperrt bis zum 28. Juli 2027 !

The bacterial cell wall with its main structural component, peptidoglycan, is essential for the survival of bacteria as it maintains cell integrity by countering the internal turgor pressure and provides protection against environmental stresses as an outer defense barrier. Continuous synthesis, remodeling, and degradation of the peptidoglycan macromolecule is required during the bacteria's life cycle in order to allow growth, division, and separation. In the context of increasing antibiotic resistance in many bacterial strains, some of which are human pathogens with major implications for clinical healthcare, these processes and the peptidoglycan molecule itself have been the subject of numerous studies. In the course of peptidoglycan biosynthesis, many bacteria introduce modifications to the archetypical peptidoglycan structure to evade host defense mechanisms and to improve rigidity and stability of the peptidoglycan scaffold. One of the most common modifications is the amidation of the second amino acid residue in the peptidoglycan stem peptide, which directly influences the peptidoglycan cross-linking efficiency and contributes to antibiotic resistance. In the first project of this thesis, the MurT/GatD enzyme complex that performs this amidation in important human pathogenic bacteria such as Staphylococcus aureus, Mycobacterium tuberculosis, and Streptococcus pneumoniae was investigated. Following up on two previously determined structures, a new crystal packing for S. aureus MurT/GatD was identified that allows crystallization experiments with peptidoglycan precursor ligands. Moreover, a third homologous structure from Streptococcus pyogenes was obtained enabling a more detailed comparison of two distinct arrangements of the protein complex and confirming the conserved binding site for ATP MurT in a ligand-bound structure. The structures determined in this work in combination with enzyme activity and ligand binding assays expanded and improved our knowledge on bacterial peptidoglycan amidation by the MurT/GatD complex. Together with the structures from S. aureus and S. pneumoniae, they provide a basis for future structural studies on MurT/GatD with the long-term goal of developing specific, small molecule inhibitors for this enzyme complex in order to combat antimicrobial resistant pathogens. To preserve resources when degrading the cell wall, most bacteria recycle the individual building blocks of the peptidoglycan molecule, either for reuse in cell wall synthesis or in case of starvation as a nutrient source. Recycling pathways influence the viability of bacterial species and are often linked to antibiotic resistance mechanisms. While peptidoglycan recycling in Gram-negative bacteria has been studied in more detail, less information is available for Gram- Ipositive species. The second project of this thesis focused on two peptidases, YkfA and YkfC, from the Gram-positive model organism Bacillus subtilis that cleave amide bonds in peptidoglycan-derived peptides. Protein expression, purification, and crystallization experiments were conducted for the L,D-carboxypeptidase YkfA, that cleaves the bond between the third and fourth residue in the peptidoglycan stem peptide, with the aim of determining the first atomic structure of this enzyme. The experiments provide a starting point for further studies to elucidate the structure and mechanism of YkfA in order to generally improve the understanding of serine peptidases from the S66 family that are involved in cell wall recycling. The D,L-endopeptidase YkfC cleaves between the second and third residue in the stem peptide and belongs to the major class of NlpC/P60 cysteine peptidases. In this work, a high yield expression and purification protocol of YkfC was established followed by X-ray crystallographic experiments. To analyze substrate specificity and engagement on an atomic level and for comparison to a homologous structure from Bacillus cereus, structures of YkfC in the apo state, covalently bound to a dipeptide product, and in complex with a pentapeptide substrate were determined. Investigation of the structures revealed a conserved specificity to peptides with a free N-terminal L-alanine residue and the formation of an oxyanion hole by a tyrosine residue, which is unusual for cysteine peptidases, in the YkfC subfamily. Moreover, the structures gave insights into the orientation of important residues during catalysis and the engagement of the C-terminal residues in the peptide substrate by YkfC. Residues potentially forming contacts to the peptide substrate were additionally investigated in a mutation activity experiment. With the here laid structural foundation, further experiments including the natural mDAP-containing peptide substrate are now straightforward. Afterwards, the focus could be shifted towards related NlpC/P60 peptidases that, in contrast to B. subtilis YkfC, are essential for the bacterium. In summary, the structural studies on peptidoglycan modification and recycling enzymes presented in this work improved our understanding of important processes associated with the bacterial cell wall. The information gathered could serve as a basis for comparison in future studies on functionally related enzymes and help in the development of strategies to inhibit these enzymes and thus combat bacterial pathogens.