An Alternate and Facile Method for the Synthesis of Precursors of 3- and 6- Aminosugar Donors and a One-Pot Glycosylation Approach

Pandey, Uddav

01 December 2019

The synthesis of 3- and 6- aminosugars from the old route requires many synthetic steps and is challenging. An alternative approach is to utilize acid-catalyzed hydrolysis of kanamycin derivatives. The 3-and 6 aminosugar donor was synthesized in just two steps with excellent yield and cost-effective. The acidic hydrolysis of these aminoglycosides provided not only the 3-and 6-aminosugars, but the direct chemical glycosylation of these aminosugars was proven feasible using isopropanol and octanol as the acceptor.

3-aminosugar

6- aminosugar

Kanamycin-hydrolysis

Glycosylation

Synthesis of neotrehalose; kinetics and mutagenesis of NtdC

Langill, David Mitchell

27 September 2010

3,3'-Neotrehalosadiamine (NTD) is a diaminosugar that possesses a rare alpha,beta-1,1'-linked glycosidic bond and has been reported to possess antimicrobial activity against Staphylococcus aureus. The ntdABC operon contains three structural genes that are necessary for the production of NTD in certain mutants of Bacillus subtilis. The gene predicted to be the first in the NTD biosynthetic pathway, ntdC, was subcloned into pET-28b as the hexa-histidine tagged fusion. The gene product was expressed, purified to homogeneity, and found to be an NAD+-dependent glucose 6-phosphate 3-dehydrogenase, likely operating according to a ternary complex mechanism and possessing a catalytic dyad composed by D176 and H180. The advent of this knowledge suggests that additional genes are required for the biosynthesis of NTD aside from the three encoded by the ntdABC operon.

Dehydrogenase

Antibiotic

Neotrehalosadiamine

NtdC

Biochemistry

Enzymology

Peptidoglycan recycling in the Gram-positive bacterium Staphylococcus aureus and its role in host-pathogen interaction

Dorling, Jack

January 2018

Bacteria are enclosed by a peptidoglycan sacculus, an exoskeleton-like polymer composed of glycan strands cross-linked by short peptides. The sacculus surrounds the cell in a closed bag-like structure and forms the main structural component of the bacterial cell wall. As bacteria grow and divide, cell wall remodelling by peptidoglycan hydrolases results in the release of peptidoglycan fragments from the sacculus. In Gram-negative bacteria, these fragments are efficiently trapped and recycled. Gram-positive bacteria however shed large quantities of peptidoglycan fragments into the environment. For nearly five decades, Gram-positive bacteria were thus assumed not to recycle peptidoglycan and this process has remained enigmatic until recently. In this thesis, the occurrence and physiological role of peptidoglycan recycling in the Gram-positive pathogen Staphylococcus aureus was investigated. S. aureus is an important pathogen, and is becoming increasingly resistant to many antibiotics. Through bioinformatic and experimental means it was determined that S. aureus may potentially recycle components of peptidoglycan and novel peptidoglycan recycling components were identified and characterised. Though disruption of putative peptidoglycan recycling in S. aureus appears not affect growth or gross morphology of this bacterium, potential roles for peptidoglycan recycling in cell wall homeostasis and in virulence were identified. This is to my knowledge the first demonstration of a potential role of peptidoglycan recycling in either of these aspects of bacterial physiology in any Gram-positive bacterium. This is an important step forward in understanding the basic biology of Gram-positive bacteria, and in understanding the mechanisms of virulence in S. aureus. Future study of this process in S. aureus and other Gram-positive bacteria promises to reveal yet further facets of this process and its functions, potentially leading to the identification of novel therapeutic approaches to combat infections.