Characterization of the chromosomal aac(6')-Ic gene from Serratia marcescens
The DNA sequence of the chromosomal aac(6')-Ic gene from Serratia marcescens, which had been previously cloned (H. M. Champion, P. M. Bennett, D. A. Lewis, and D. S. Reeves, J. Antimicrob. Chemother. 22:587-596, 1988) was determined. High-pressure liquid chromatographic analysis of extracts prepared from Escherichia coli carrying the chromosomal aac(6')-Ic gene on a plasmid confirmed the presence of 6'-N-acetyltransferase activity in this strain, which was suggested by the aminoglycoside resistance profile. DNA sequence analysis of the cloned 2,057-bp PstI fragment revealed several regions of homology to previously characterized sequences from GenBank, including the rpoD and tRNA-2 genes of E. coli. Subcloning experiments confirmed the coding sequence of the aac(6')-Ic gene to be at positions 1554 to 1992. The predicted amino acid sequence of the AAC(6')-Ic protein suggested that it was the third member of a family of AAC(6') proteins which included a coding region identified between the aadB and aadA genes of Tn4000 and an AAC(6') protein encoded by pUO490, which was isolated from Enterobacter cloacae. Primer extension analysis suggested that the -35 region of the aac(6')-Ic promoter overlapped a large palindromic sequence which may be involved in the regulation of the aac(6')-Ic gene. Hybridization experiments utilizing a restriction fragment from the aac(6')-Ic gene showed that all S. marcescens organisms carried this gene whether or not the AAC(6')-I resistance profile was expressed. Organisms other than Serratia spp. did not hybridize to this probe.
Genetic analysis of bacterial acetyltransferases: identification of amino acids determining the specificities of the aminoglycoside 6'-N-acetyltransferase Ib and IIa proteins
The aminoglycoside 6'-N-acetyltransferase [AAC(6')-I] and AAC(6')-II enzymes represent a class of bacterial proteins capable of acetylating tobramycin, netilmicin, and 2'-N-ethylnetilmicin. However, an important difference exists in their abilities to modify amikacin and gentamicin. The AAC(6')-I enzymes are capable of modifying amikacin. In contrast, the AAC(6')-II enzymes are capable of modifying gentamicin. Nucleotide sequence comparison of the aac(6')-Ib gene and the aac(6')-IIa gene showed 74% sequence identity (K. J. Shaw, C. A. Cramer, M. Rizzo, R. Mierzwa, K. Gewain, G. H. Miller, and R. S. Hare, Antimicrob. Agents Chemother. 33:2052-2062, 1989). Comparison of the deduced protein sequences showed 76% identity and 82% amino acid similarity. A genetic analysis of these two proteins was initiated to determine which amino acids were responsible for the differences in specificity. Results of domain exchanges, which created hybrid AAC(6') proteins, indicated that amino acids in the carboxy half of the proteins were largely responsible for determining specificity. Mutations shifting the specificity of the AAC(6')-Ib protein to that of the AAC(6')-IIa protein (i.e., gentamicin resistance and amikacin sensitivity) have been isolated. DNA sequence analysis of four independent isolates revealed base changes causing the same amino acid substitution, a leucine to serine, at position 119. Interestingly, this serine occurs naturally at the same position in the AAC(6')-IIa protein. Oligonucleotide-directed mutagenesis was used to construct the corresponding amino acid change, a serine to leucine, in the AAC(6')-IIa protein. This change resulted in the conversion of the AAC(6')-IIa substrate specificity to that of AAC(6')-Ib. Analysis of additional amino acid substitutions within this region of AAC(6')-Ib support the model that we have identified an aminoglycoside binding domain of these proteins.
Correlation between aminoglycoside resistance profiles and DNA hybridization of clinical isolates
DNA hybridization data and aminoglycoside resistance profiles (AGRPs) were determined for 4,088 clinical isolates from three studies (United States, Belgium, and Argentina). The correlation between susceptibility profiles and hybridization results was determined with nine DNA probes. For each of the seven aminoglycoside resistance profiles which we were able to test, the data suggested at least two distinct genes could encode enzymes which lead to identical resistance profiles. Furthermore, the DNA hybridization data showed that individual strains carried up to six unique aminoglycoside resistance genes. DNA hybridization revealed interesting differences in the frequencies of these genes by organism and by country.
Posaconazole Is a Potent Inhibitor of Sterol 14α-Demethylation in Yeasts and Molds
Posaconazole (POS; SCH 56592) is a novel triazole that is active against a wide variety of fungi, including fluconazole-resistant Candida albicans isolates and fungi that are inherently less susceptible to approved azoles, such as Candida glabrata. In this study, we compared the effects of POS, itraconazole (ITZ), fluconazole (FLZ), and voriconazole (VOR) on sterol biosynthesis in strains of C. albicans (both azole-sensitive and azole-resistant strains), C. glabrata, Aspergillus fumigatus, and Aspergillus flavus. Following exposure to azoles, nonsaponifiable sterols were extracted and resolved by liquid chromatography and sterol identity was confirmed by mass spectroscopy. Ergosterol was the major sterol in all but one of the strains; C. glabrata strain C110 synthesized an unusual sterol in place of ergosterol. Exposure to POS led to a decrease in the total sterol content of all the strains tested. The decrease was accompanied by the accumulation of 14␣-methylated sterols, supporting the contention that POS inhibits the cytochrome P450 14␣-demethylase enzyme. The degree of sterol inhibition was dependent on both dose and the susceptibility of the strain tested. POS retained activity against C. albicans isolates with mutated forms of the 14␣-demethylase that rendered these strains resistant to FLZ, ITZ, and VOR. In addition, POS was a more potent inhibitor of sterol synthesis in A. fumigatus and A. flavus than either ITZ or VOR.Fungal infections are a significant cause of morbidity and mortality among immunocompromised patients. The mortality rate for bone marrow transplant patients infected with Aspergillus fumigatus is approaching 90% (7). Similarly, Candida species are the fourth most common nosocomial bloodstream pathogen in the Unites States and in pediatric patients have a crude mortality rate of 20% (21). The current antifungal armamentarium, amphotericin B (AMB), fluconazole (FLZ), and itraconazole (ITZ), and the newer agents, caspofungin and voriconazole (VOR), have not satisfactorily met therapeutic needs, particularly in the case of mold infections. Consequently, there is an urgent need to develop new antifungal drugs.Posaconazole (POS; SCH 56592) is a potent new triazole antifungal compound with broad-spectrum activity both in vitro and in vivo (1, 15). Although POS is fungistatic against yeasts, it is fungicidal against A. fumigatus (8). Prior work had determined that triazoles inhibit the lanosterol 14␣-demethylase enzyme, resulting in a block in synthesis of ergosterol, the major sterol of the fungal cell membrane (3). Ergosterol is required for both membrane integrity (14) and for the function of some membrane-associated proteins (20). In addition to its role in maintaining membrane integrity, trace amounts of ergosterol are also thought to be required for the cell to progress through the cell cycle (5).Previously, we demonstrated that POS inhibited ergosterol synthesis in an azole-susceptible Candida albicans isolate (4).Here we extend these studies to compare the effect of POS, FLZ, ITZ, and VOR...
Mechanism of azole antifungal activity as determined by liquid chromatographic/mass spectrometric monitoring of ergosterol biosynthesis
A liquid chromatography/mass spectrometry (LC/MS) method for separation and characterization of ergosterol biosynthetic precursors was developed to study the effect of Posaconazole on sterol biosynthesis in fungi. Ergosterol biosynthetic precursors were characterized from their electron ionization mass spectra acquired by a normal-phase chromatography, particle beam LC/MS method. Fragment ions resulting from cleavage across the D-ring and an abundant M - 15 fragment ion were diagnostic for methyl substitution at C-4 and C-14. Comparison of the sterol profile in control and treated Candida albicans incubations showed depletion of ergosterol and accumulation of C-4 and C-14 methyl-substituted sterols following treatment with Posaconazole. These C-4 and C-14 methyl sterols are known to be incapable of sustaining cell growth. The results demonstrate that Posaconazole exerts its antifungal activity by inhibition of ergosterol biosynthesis. Furthermore, Posaconazole appears to disrupt ergosterol biosynthesis by inhibition of lanosterol 14alpha-demethylase.
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