DISCOVERY OF NOVEL MURAYMYCIN ANTIBIOTICS AND INSIGHT INTO THE BIOSYNTHETIC PATHWAY

Cui, Zheng

01 January 2018

New antibiotics with novel targets or mechanisms of action are needed to counter the steady emergence of bacterial pathogens that are resistant to antibiotics used in the clinic. MraY, a promising novel target for antibiotic development, initiates the lipid cycle for the biosynthesis of peptidoglycan cell wall, which is essential for the survival of most, if-not-all, bacteria. MraY is an enzyme that catalyzes the transfer and attachment of phospho-MurNAc-pentapeptide to a lipid carrier, undecaprenylphosphate. Muraymycins are recently discovered lipopeptidyl nucleoside antibiotics that exhibit remarkable antibiotic activity against Gram-positive as well as Gram-negative bacteria by inhibiting MraY. We conducted a thorough examination of the metabolic profile of Streptomyces sp. strain NRRL 30473, a known producer of muraymycins. Eight muraymycins were isolated and characterized by a suite of spectroscopic methods, including three new members of muraymycin family named B8, B9 and C5. Muraymycins B8 and B9, which differ from other muraymycins by having an elongated fatty acid side chain, showed potent antibacterial activity against Escherichia coli ∆tolC mutant and pM IC50 against Staphylococcus aureus MraY. Muraymycin C5, which is characterized by an N-acetyl modification of the disaccharide’s primary amine, greatly reduced its antibacterial activity, which possibly indicates this modification is used for self-resistance. In addition to the discovery of new muraymycins, eleven enzymes from the biosynthetic pathway were functionally assigned and characterized in vitro. Six enzymes involved in the biosynthesis of amino ribofuranosylated uronic acid moiety of muraymycin were characterized: Mur16, a non-heme, Fe(II)-dependent α-ketoglutarate: UMP dioxygenase; Mur17, an L-threonine: uridine-5′-aldehyde transaldolase; Mur20, an L-methionine:1-aminotransferase; Mur26, a low specificity pyrimidine nucleoside phosphorylase; Mur18, a primary amine-requiring nucleotidylyltransferase; Mur19, a 5-amino-5-deoxyribosyltransferase. A one-pot enzyme reaction was utilized to produce this disaccharide moiety and its 2′′-deoxy analogue. Two muraymycin-modifying enzymes that confer self-resistance were functionally assigned and characterized: Mur28, a TmrB-like ATP-dependent muraymycin phosphotransferase, and Mur29, a muraymycin nucleotidyltransferase. Notably, Mur28 preferentially phosphorylates the intermediate, aminoribofuranosylated uronic acid, in the muraymycin biosynthetic pathway to produce a cryptic phosphorylated-dissacharide intermediate. Mur23 and Mur24 were assigned as two enzymes that modify the cryptic phosphorylated intermediate by attachment of an aminopropyl group. Mur24 catalyzes the incorporation of butyric acid into the phosphorylated-disaccharide. Following the incorporation, Mur23 catalyzes a PLP-dependent decarboxylation. Finally, Mur15, which belongs to the cupin family, is functionally assigned as a non-heme, Fe(II)-dependent α-ketoglutarate dioxygenase that catalyzes the β-hydroxylation of a leucine moiety in muraymycin D1 to form muraymycin C1. Mur15 can also hydroxylate the γ-position of leucine moiety to muraymycins with fatty acid chain in β-position.

nucleoside antibiotics

muraymycin

translocase I (MraY)

antibiotic resistance

biosynthesis

Biochemistry

ELUCIDATING THE MECHANISM OF LIPL: A NON-HEME FE(II), α -KETOGLUTARATE: URIDINE-5’-MONOPHOSPHATE DIOXYGENASE

Goswami, Anwesha

01 January 2015

Several nucleoside natural product antibiotics from Streptomyces sp. and actinomycetes have recently been shown to target bacterial peptidoglycan cell wall biosynthesis by inhibiting the bacterial translocase I (MraY). The biosynthetic gene clusters for A-90289, liposidomycins and caprazamycins revealed a protein with sequence similarity to proteins annotated as α-KG:taurine dioxygenases (TauD). This enzyme (LipL) is a mononuclear, non-heme, Fe(II) dependent α-keto glutarate (α-KG) :uridine monophosphate (UMP) dioxygenase responsible for the net dephosphorylation and two electron oxidation of UMP to uridine-5’-aldehyde. The postulated reaction coordinates involving the activation of the C-5’ center in UMP and the corresponding formation of uridine-5’-aldehyde are modeled on extensive spectroscopic and structural characterizations of TauD. In this dissertation, the postulated radical mechanism for LipL involving the formation of an unstable hydroxylated intermediate is investigated via the characterization of a key product obtained from the reaction of LipL (and its homolog Cpr19) with a synthetically modified surrogate substrate where the bridging phosphoester oxygen in UMP is replaced with a 5’ C-P bond. We further validate our hypothesis by analyzing the reactions of both LipL and Cpr19 with specifically 2H1 – labeled UMP substrate and confirming the expected products via mass spectrometry. In addition, we explore substrate promiscuity of the enzymes and utilize a set of site specific mutants of Cpr19 as means of gaining better insight into the active site residues. Predictive models for Cpr19 and LipL structures are developed by the combination of experimental results and chemical logic.

nucleoside antibiotics

peptidoglycan cell wall

dioxygenases

iron-dependent enzymes

BIOSYNTHETIC PATHWAY OF THE AMINORIBOSYL COMPONENT OF LIPOPEPTIDYL NUCLEOSIDE ANTIBIOTICS

Chi, Xiuling

01 January 2013

Several lipopeptidyl nucleoside antibiotics that inhibit bacterial translocase I (MraY) involved in peptidoglycan cell wall biosynthesis contain an aminoribosyl moiety, an unusual sugar appendage in natural products. A-90289 and muraminomicin are the two representative antibiotics that belong to this family. Bioinformatic analysis of the biosynthetic A-90289 gene clusters revealed that five enzymes are likely involved in the assembly and attachment of the aminoribosyl unit. These enzymes of A-90289 are functionally assigned by in vitro characterization. The results reveal a unique ribosylation pathway that highlighted by uridine-5′-monophosphate as the source of the sugar, a phosphorylase strategy to generate a sugar-1-phosphate, and a primary amine-requiring nucleotidylyltransferase that generates the NDP-sugar donor. Muraminomicin, which has a structure similar to A-90289, holds the distinction in that both ribose units are 2-deoxy sugars. The biosynthetic gene cluster of muraminomicin has been identified, cloned and sequenced, and bioinformatic analysis revealed a minimum of 24 open reading frames putatively involved in the biosynthesis, resistance, and regulation of muraminomicin. Similar to the A-90289 pathway, fives enzymes are still likely involved in the assembly of the 2,5-dideoxy-5-aminoribose saccharide unit, and two are now functionally assigned and characterized: Mra20, a 5′-amino-2′,5′-dideoxyuridine phosphorylase and Mra23, a UTP:5-amino-2,5-dideoxy-α-D-ribose-1-phosphate uridylyltransferase. The cumulative results are consistent with the incorporation of the ribosyl appendage of muraminomicin via the archetypical sugar biosynthetic pathway that parallels A-90289 biosynthesis

Aminoribosyl unit

lipopeptidyl nucleoside antibiotics

peptidoglycan cell wall

biosynthetic gene cluster

ORF enzymes

Amino Acids, Peptides, and Proteins

Enzymes and Coenzymes