Characterization of the PLP-dependent aminotransferase NikK from Streptomyces tendae and its putative role in nikkomycin biosynthesis

As inhibitors of chitin synthase, nikkomycins have attracted interest as potential antibiotics. The biosynthetic pathway to these peptide nucleosides in Streptomyces tendae is only partially known. In order to elucidate the last step of the biosynthesis of the aminohexuronic building block, we have heterologously expressed a predicted aminotransferase encoded by the gene nikK from S. tendae in Escherichia coli. The purified protein, which is essential for nikkomycin biosynthesis, has a pyridoxal-5'-phosphate cofactor bound as a Schiff base to lysine 221. The enzyme possesses aminotransferase activity and uses several standard amino acids as amino group donors with a preference for glutamate (Glu > Phe > Trp > Ala > His > Met > Leu). Therefore, we propose that NikK catalyses the introduction of the amino group into the ketohexuronic acid precursor of nikkomycins. At neutral pH, the UV-visible absorbance spectrum of NikK has two absorbance maxima at 357 and 425 nm indicative of the presence of the deprotonated and protonated aldimine with an estimated pK(a) of 8.3. The rate of donor substrate deamination is faster at higher pH, indicating that an alkaline environment favours the deamination reaction.     

Mechanism of action of nikkomycin and the peptide transport system of Candida albicans

Nikkomycin was found to be a potent growth inhibitor of Candida albicans through competitive inhibition of chitin synthase [Ki = 0.16 microM (0.1 microgram ml-1)]. The activity of the peptide-nucleoside drug was antagonized by both peptone and defined peptides. Transported dipeptides were effective antagonists while transported oligopeptides were not. A mutant of C. albicans resistant to the effects of nikkomycin through a transport defect was unable to transport dipeptides, while oligopeptide uptake was apparently unaffected. At least two peptide permeases are operational in this organism.     

A comparison of the chitin synthase-inhibitory and antifungal efficacy of nucleoside-peptide antibiotics: structure-activity relationships

Abstract Using Mucor rouxii , the chitin synthase (ChS)-inhibitory and antifungal activity was determined of 6 nucleoside-peptide antibiotics (NPAs) representing pairs of structural analogues, each consisting of a dipeptide (DP) and a corresponding tripeptide (TP). These were the nikkomycins X and I (X, I), the nikkomycins Z and J (Z, J), and the polyoxins D and A (D, A). Although all were very good ChS-inhibitors (X and A being best, with K _i approx. 0.5 μM), only X and Z elicited a strong response in vivo as determined by the degree of inhibition exerted on N -acetylglucosamine (GlcNAc) incorporation into the chitin fraction, the survival rate, and the minimum inhibitory concentration (MIC). The MIC values were about 2 μM (for X and Z) and 100 μM (for I, J, D and A). Certain DPs and TPs reduced the antifungal activity of X, the effect being much more pronounced with DPs. It is suggested that uptake of NPAs involves the transpeptidase reaction of the γ-glutamyl cycle, the observed antagonism thus resulting from competition for a common carrier.     

Hybrid antibiotics with the nikkomycin nucleoside and polyoxin peptidyl moieties

Acting as competitive inhibitors of chitin synthase, nikkomycins and polyoxins are potent antibiotics against pathogenic fungi. Taking advantage of the structural similarities between these two peptidyl nucleoside antibiotics, genes required for the biosynthesis of the dipeptidyl moiety of polyoxin from Streptomyces cacaoi were introduced into a Streptomyces ansochromogenes mutant producing the nucleoside moiety of nikkomycin X. Two hybrid antibiotics were generated. One of them was identified as polyoxin N, and the other, a novel compound, was named polynik A. The hybrid antibiotics exhibited merits from both parents: they had better inhibitory activity against phytopathogenic fungi than polyoxin B, and were more stable under different pH and temperature conditions than nikkomycin X. This study demonstrates the use of the combinatorial biosynthetic approach to produce valuable and novel hybrid antibiotics with improved properties.     

Participation of the tryptophan synthase inactivating system from yeast in the activation of chitin synthase

The previously described tryptophan synthase “inactivase II”, a proteolytic enzyme from yeast, exhibits high activity in the activation of chitin synthase. Tryptophan synthase inactivase I shows essentially no activity.The purified, heat-stable inhibitor of the tryptophan synthase inactivating enzymes also inhibits the activation of chitin synthase. We take these results to mean that the proteolytic inactivation of tryptophan synthase and the proteolytic activation of chitin synthase are catalyzed and regulated by the same protease/inhibitor system     

Chs1p and Chs3p, two proteins involved in chitin synthesis, populate a compartment of the Saccharomyces cerevisiae endocytic pathway.

In Saccharomyces cerevisiae, the synthesis of chitin, a cell-wall polysaccharide, is temporally and spatially regulated with respect to the cell cycle and morphogenesis. Using immunological reagents, we found that steady-state levels of Chs1p and Chs3p, two chitin synthase enzymes, did not fluctuate during the cell cycle, indicating that they are not simply regulated by synthesis and degradation. Previous cell fractionation studies demonstrated that chitin synthase I activity (CSI) exists in a plasma membrane form and in intracellular membrane-bound particles called chitosomes. Chitosomes were proposed to act as a reservoir for regulated transport of chitin synthase enzymes to the division septum. We found that Chs1p and Chs3p resided partly in chitosomes and that this distribution was not cell cycle regulated. Pulse-chase cell fractionation experiments showed that chitosome production was blocked in an endocytosis mutant (end4-1), indicating that endocytosis is required for the formation or maintenance of chitosomes. Additionally, Ste2p, internalized by ligand-induced endocytosis, cofractionated with chitosomes, suggesting that these membrane proteins populate the same endosomal compartment. However, in contrast to Ste2p, Chs1p and Chs3p were not rapidly degraded, thus raising the possibility that the temporal and spatial regulation of chitin synthesis is mediated by the mobilization of an endosomal pool of chitin synthase enzymes.     

Cloning,reassembling and integration of the entire nikkomycin biosynthetic gene cluster into <Emphasis Type="Italic">Streptomyces ansochromogenes</Emphasis> lead to an improved nikkomycin production

Background  

Nikkomycins are a group of peptidyl nucleoside antibiotics produced by Streptomyces ansochromogenes. They are competitive inhibitors of chitin synthase and show potent fungicidal, insecticidal, and acaricidal activities. Nikkomycin X and Z are the main components produced by S. ansochromogenes. Generation of a high-producing strain is crucial to scale up nikkomycins production for further clinical trials.     

The S. cerevisiae structural gene for chitin synthase is not required for chitin synthesis in vivo

The chitin synthase of Saccharomyces is a plasma membrane-bound zymogen. Following proteolytic activation, the enzyme synthesizes insoluble chitin that has chain length and other physical properties similar to chitin found in bud scars. We isolated mutants lacking chitin synthase activity (chs1) and used these to clone CHS1. The gene has an open reading frame of 3400 bases and encodes a protein of 130 kd. The fission yeast S. pombe lacks chitin synthase and chitin. When a plasmid encoding a CHS1-lacZ fusion protein is introduced into S. pombe, both enzymatic activities are expressed in the same ratio as in S. cerevisiae, demonstrating that CHS1 encodes the structural gene of chitin synthase. Three CHS1 gene disruption experiments were performed. In all cases, strains with the disrupted gene have a recognizable phenotype, lack measurable chitin synthase activity in vitro but are viable, contain normal levels of chitin in vivo, and mate and sporulate efficiently.     

Virulence of Mycobacterium tuberculosis

Abstract Different strains of Candida albicans show varied sensitivities to the peptide analogues bacilysin, polyoxins and nikkomycins. From a sensitive strain, B2630, spontaneous mutants were selected for resistance to each analogue; certain mutants showed cross-resistance to other analogues and associated defects in peptide transport. A bacilysin-resistant mutant was cross resistant to the other analogues and to m -fluorophenylalanyl-Ala (FPA) but retained sensitivity to m -fluorophenylalanyl-Ala—Ala (FPAA). It showed defective dipeptide transport but normal oligopeptide transport. A revertant, selected for its ability to utilize Ala-Ala as sole nitrogen source, regained wild-type dipeptide transport activity and analogue sensitivity. Thus, C. albicans has distinguishable mechanisms for dipeptide and oligopeptide transport which can be exploited for uptake of peptide-drug adducts.     

CAL1, a gene required for activity of chitin synthase 3 in Saccharomyces cerevisiae

The CAL1 gene was cloned by complementation of the defect in Calcofluor-resistant calR1 mutants of Saccharomyces cerevisiae. Transformation of the mutants with a plasmid carrying the appropriate insert restored Calcofluor sensitivity, wild-type chitin levels and normal spore maturation. Southern blots using the DNA fragment as a probe showed hybridization to a single locus. Allelic tests indicated that the cloned gene corresponded to the calR1 locus. The DNA insert contains a single open-reading frame encoding a protein of 1,099 amino acids with a molecular mass of 124 kD. The predicted amino acid sequence shows several regions of homology with those of chitin synthases 1 and 2 from S. cerevisiae and chitin synthase 1 from Candida albicans. calR1 mutants have been found to be defective in chitin synthase 3, a trypsin-independent synthase. Transformation of the mutants with a plasmid carrying CAL1 restored chitin synthase 3 activity; however, overexpression of the enzyme was not achieved even with a high copy number plasmid. Since Calcofluor-resistance mutations different from calR1 also result in reduced levels of chitin synthase 3, it is postulated that the products of some of these CAL genes may be limiting for expression of the enzymatic activity. Disruption of the CAL1 gene was not lethal, indicating that chitin synthase 3 is not an essential enzyme for S. cerevisiae.     

Two chitin synthases in Saccharomyces cerevisiae

Disruption of the yeast CHS1 gene, which encodes trypsin-activable chitin synthase I, yielded strains that apparently lacked chitin synthase activity in vitro, yet contained normal levels of chitin (Bulawa, C. E., Slater, M., Cabib, E., Au-Young, J., Sburlati, A., Adair, W. L., and Robbins, P. W. (1986) Cell 46, 213-225). It is shown here that disrupted (chs1 :: URA3) strains have a particulate chitin synthetic activity, chitin synthase II, and that wild type strains, in addition to chitin synthase I, have this second activity. Chitin synthase II is measured in wild type strains without preincubation with trypsin, the condition under which highest chitin synthase II activities are obtained in extracts from the chs1 :: URA3 strain. Chitin synthase II, like chitin synthase I, uses UDP-GlcNAc as substrate and synthesizes alkali-insoluble chitin (with a chain length of about 170 residues). The enzymes are equally sensitive to the competitive inhibitor Polyoxin D. The two chitin synthases are distinct in their pH and temperature optima, and in their responses to trypsin, digitonin, N-acetyl-D-glucosamine, and Co2+. In contrast to the report by Sburlati and Cabib (Sburlati, A., and Cabib, E. (1986) Fed. Proc. 45, 1909), chitin synthase II activity in vitro is usually lowered on treatment with trypsin, indicating that chitin synthase II is not activated by proteolysis. Chitin synthase II shows highest specific activities in extracts from logarithmically growing cultures, whereas chitin synthase I, whether from growing or stationary phase cultures, is only measurable after trypsin treatment, and levels of the zymogen do not change. Chitin synthase I is not required for alpha-mating pheromone-induced chitin synthesis in MATa cells, yet levels of chitin synthase I zymogen double in alpha factor-treated cultures. Specific chitin synthase II activities do not change in pheromone-treated cultures. It is proposed that of yeast's two chitin synthases, chitin synthase II is responsible for chitin synthesis in vivo, whereas nonessential chitin synthase I, detectable in vitro only after trypsin treatment, may not normally be active in vivo.     

Molecular characterization of co-transcribed genes from Streptomyces tendae Tü901 involved in the biosynthesis of the peptidyl moiety and assembly of the peptidyl nucleoside antibiotic nikkomycin

Six genes (nikP1, nikP2, nikS, nikT, nikU, and nikV) from Streptomyces tendae Tu901 were identified by analysis of the nucleotide sequence of the nikkomycin gene cluster. These genes, together with the previously described nikQ and nikR, span 9.39 kb and are transcribed as a polycistronic mRNA in a growth-phase-dependent manner. The nikP1 gene encodes a non-ribosomal peptide synthase consisting of an adenylation domain, a thiolation domain, and an N-terminal 70-residue segment of unknown function. The amino acid sequence encoded by the nikP2 gene displays similarity to the sequences of thioesterases, and the nikS product belongs to a superfamily of proteins characterized by a specific ATP-binding fold. The N-terminal 70 amino acids of the predicted nikT gene product show significant sequence similarity to acyl carrier proteins, and the C-terminal 330 amino acids to aminotransferases. The sequences of the deduced proteins NikU and NikV exhibit similarity to components S and E, respectively, of glutamate mutase from Clostridium. Disruption of the nikP1, nikS, nikT, or nikV gene by insertion of a kanamycin resistance cassette abolished formation of nikkomycins I, J, X, and Z, all of which contain hydroxypyridylhomothreonine as the peptidyl moiety. The nikP1 mutants, and the nikS and nikT mutants accumulated the nucleoside moieties nikkomycin Cz, and nikkomycins Cx and Cz, respectively. The nikV mutants formed nikkomycins Ox and Oz, which contain 2-amino-4-hydroxy-4-(3'-hydroxy-6'-pyridyl) butanoic acid as the peptidyl moiety. The nikP2 mutants synthesized nikkomycins I, J, X, and Z, but amounts of nikkomycins I and X, which contain formylimidazolone as the base, were lower. Feeding formylimidazolone to nikP2 mutants restored the ability to form nikkomycins I and X. Our results indicate that nikU and nikV are required for the synthesis of hydroxypyridylhomothreonine, the genes nikP1, nikP2 and nikS are required for the assembly of nikkomycins, and nikT is required for both pathways. The putative activities of each of their products are discussed.     

Design,synthesis and biological evaluation of hetaryl-nucleoside derivatives as inhibitors of chitin synthase

We report here the design, synthesis and biological evaluation of new models of sugar analogues for chitin synthase. These UDP-GlcNAc mimetics associate a sugar-mimicking hetaryl group and uridine, linked with different pyrophosphate bioisosteres. The compounds displayed weak inhibition activity on chitin synthase and their antifungal potencies have been assayed against a large variety of pathogenic fungi.     

Chemical synthesis of UDP-4-O-methyl-GlcNAc, a potential chain terminator of chitin synthesis

Chitin synthase converts uridine diphosphoryl-N-acetylglucosamine (UDP-GlcNAc) to chitin (poly-beta-(1-->4)-GlcNAc). During polymerization, elongation occurs at the 4-OH (nonreducing) terminus of the growing chitin chain. Blockage of the 4-OH via incorporation of UDP-N-acetyl-4-O-methylglucosamine (UDP-4-OMe-GlcNAc, 3) can potentially terminate chitin polymerization, and represents a novel strategy for chitin synthase inhibition. The chemical synthesis of 3 and preliminary evaluation of its possible incorporation by chitin synthase are reported herein.     

Proper ascospore maturation requires the chs1+ chitin synthase gene in Schizosaccharomyces pombe

We have cloned chs1+, a Schizosaccharomyces pombe gene with similarity to class II chitin synthases, and have shown that it is responsible for chitin synthase activity present in cell extracts from this organism. Analysis of this activity reveals that it behaves like chitin synthases from other fungi, although with specific biochemical characteristics. Deletion or overexpression of this gene does not lead to any apparent defect during vegetative growth. In contrast, chs1+ expression increases significantly during sporulation, and this is accompanied by an increase in chitin synthase activity. In addition, spore formation is severely affected when both parental strains carry a chs1 deletion, as a result of a defect in the synthesis of the ascospore cell wall. Finally, we show that wild-type, but not chs1-/chs1-, ascospore cell walls bind wheatgerm agglutinin. Our results clearly suggest the existence of a relationship between chs1+, chitin synthesis and ascospore maturation in S. pombe.     

Relationship between the nitrogenase activity and dark respiration rate of Synechococcus RF-1

Growth of three different anaerobic rumen fungi Neocallimastix frontalis, Piromonas communis and Sphaeromonas communis was assessed in vitro at regular intervals by measurements of protein and chitin content and of chitin synthase activity of the cell free extracts. Similar trends and a comparable amount of protein and chitin were observed in the three species. However, chitin synthase activity was higher in S. communis and contrary to the activity of the other two strains did not decrease after maximum enzyme activity was reached. There were positive correlations between chitin content, protein content and chitin synthase activity during the active growth phase of the fungi indicating that they could be confidently used to determine in vitro growth phase and biomass concentration.     

A nonradioactive,high throughput assay for chitin synthase activity

Wheat germ agglutinin (WGA) binds with high affinity and specificity to several sites on chitin polymers. Based on these properties we have modified and adapted a previously patented (U.S. patent 5,888,757) nonradioactive, high throughput screening assay for antimicrobial agents, making it suitable as a quantitative enzymatic assay for the activity of individual chitin synthase isozymes in yeast. The procedure involves binding of synthesized chitin to a WGA-coated surface followed by detection of the polymer with a horseradish peroxidase-WGA conjugate. Horseradish peroxidase activity is then determined as an increment in absorbance at 600 nm. Absorbance values are converted to amounts of chitin using acid-solubilized chitin as a standard. The high sensitivity (lower limit of detection about 50 ng chitin), low dispersion (lower than 10%), and high throughput (96-well microtiter plate format) make this assay an excellent substitute for the conventional radioactive chitin synthase assay in cell-free extracts. We have applied this method to the differential assay of chitin synthase activities (Chs1, Chs2, and Chs3) in cell-free extracts of Saccharomyces cerevisiae. Analysis of Chs3 activity in chitosomal and plasma membrane fractions revealed that Chs3 in the plasma membrane fraction is about sixfold more active than in the chitosome.     

The influence of supplemental components in nutrient medium on chitosan formation by the fungus Absidia orchidis

Chitosan, a derivative of chitin, is a natural component of some fungus cell walls. It is formed by the complex action of chitin synthase and chitin deacetylase. The in vitro activity of these two enzymes is known to be influenced by several factors. We investigated the influence of ferrous ions, manganese ions, cobalt ions, trypsin, and chitin, as individual supplements to the nutrient medium, on the in vivo activity of chitin synthase and chitin deacetylase to form chitosan in the fungus Absidia orchidis. Manganese and ferrous ions gave the most significant results. These ions increase chitosan yields through an increase in biomass production rather than an increase of chitosan content in cell walls. Manganese and ferrous ions lowered the activity of chitin deacetylase; however, their influence on the activity of chitin synthase was more complex. The effects of trypsin and chitin on biomass and cell wall chitosan content were negligible, while cobalt ions completely inhibited the growth of fungi.     

The Myosin Motor Domain of Fungal Chitin Synthase V Is Dispensable for Vesicle Motility but Required for Virulence of the Maize Pathogen Ustilago maydis

Class V chitin synthases are fungal virulence factors required for plant infection. They consist of a myosin motor domain fused to a membrane-spanning chitin synthase region that participates in fungal cell wall formation. The function of the motor domain is unknown, but it might deliver the myosin chitin synthase-attached vesicles to the growth region. Here, we analyze the importance of both domains in Mcs1, the chitin synthase V of the maize smut fungus Ustilago maydis. By quantitative analysis of disease symptoms, tissue colonization, and single-cell morphogenic parameters, we demonstrate that both domains are required for fungal virulence. Fungi carrying mutations in the chitin synthase domain are rapidly recognized and killed by the plant, whereas fungi carrying a deletion of the motor domain show alterations in cell wall composition but can invade host tissue and cause a moderate plant response. We also show that Mcs1-bound vesicles exhibit long-range movement for up to 20 μm at a velocity of ~1.75 μm/s. Apical Mcs1 localization depends on F-actin and the motor domain, whereas Mcs1 motility requires microtubules and persists when the Mcs1 motor domain is deleted. Our results suggest that the myosin motor domain of ChsV supports exocytosis but not long-range delivery of transport vesicles.     

Isolation of a chitin synthase gene (CHS1) from Candida albicans by expression in Saccharomyces cerevisiae

Chitin synthase activity was studied in yeast and hyphal forms of Candida albicans. pH-activity profiles showed that yeast and hyphae contain a protease-dependent activity that has an optimum at pH 6.8. In addition, there is an activity that is not activated by proteolysis in vitro and which shows a peak at pH 8.0. This suggests there are two distinct chitin synthases in C. albicans. A gene for chitin synthase from C. albicans (CHS1) was cloned by heterologous expression in a Saccharomyces cerevisiae chs1 mutant. Proof that the cloned chitin synthase is a C. albicans membrane-bound zymogen capable of chitin biosynthesis in vitro was based on several criteria. (i) the CHS1 gene complemented the S. cerevisiae chs1 mutation and encoded enzymatic activity which was stimulated by partial proteolysis; (ii) the enzyme catalyses incorporation of [14C]-GlcNAc from the substrate, UDP[U-14C]-GlcNAc, into alkali-insoluble chitin; (iii) Southern analysis showed hybridization of a C. albicans CHS1 probe only with C. albicans DNA and not with S. cerevisiae DNA; (iv) pH profiles of the cloned enzyme showed an optimum at pH 6.8. This overlaps with the pH-activity profiles for chitin synthase measured in yeast and hyphal forms of C. albicans. Thus, CHS1 encodes only part of the chitin synthase activity in C. albicans. A gene for a second chitin synthase in C. albicans with a pH optimum at 8.0 is proposed. DNA sequencing revealed an open reading frame of 2328 nucleotides which predicts a polypeptide of Mr 88,281 with 776 amino acids. The alignment of derived amino acid sequences revealed that the CHS1 gene from C. albicans (canCHS1) is homologous (37% amino acid identity) to the CHS1 gene from S. cerevisiae (sacCHS1).