CLINICAL AND PATHOGENESIS OVERVIEW OF MYROIDES SPP. INFECTION

The genus Myroides classified as Flavobacterium odoratum comprises non- motile ,aerobic, yellow –pigmented .They are non hemolytic on blood agar while it show a good growth on MacConkey and nutrient agar with salt tolerant up to 5% of NaCl also non fermented gram-negative rods .Members of the genus are cause many infectious disease in severely immunocompromised patient includes endocarditics urinary tract infection ,cuteneous infection ,and ventriculitis that behave as low grade opportunistic pathogens and widely distributed in the environment specially in water. Myroides spp. should be attribute among pathogens in hospitalized ,catheterized patients with wide resistant to antibiotic specially Minocycline is useful treating UTI caused by the genus . 16S ribosomal RNA(rRNA) sequencing can identified accurately the species level .In this reviews which description of dangerous infection duo to by Myroides in an immunocompromise host ,moreover reviewed the antibiotic resistance and pathogenesis. Many species of the genus Myroides were primarily taking from intestine of human. The genus Myroides includes five species : M. odoratus. , M. pelagicus, M. profundi , M. odoratimimus and M. marinus , by susceptibility to desferrioxamine . M. profundi has produced a protease Myroilysin ,with characterized as playing a role in hydrolysis of collagen through collagenase production and elastinolytic activity displaying by metalloprotease and playing important role with collagenase for hydrolysis of collagen that proven virulence of genus.

Chromosome-Encoded β-Lactamases TUS-1 and MUS-1 from Myroides odoratus and Myroides odoratimimus (Formerly Flavobacterium odoratum), New Members of the Lineage of Molecular Subclass B1 Metalloenzymes

ABSTRACT Myroides odoratus and Myroides odoratimimus (formerly designated in a single species as Flavobacterium odoratum) are gram-negative aerobes and sources of nosocomial infections in humans. They have variable susceptibility to β-lactams and a decreased susceptibility to carbapenems. Using genomic DNAs of M. odoratus CIP 103105 and M. odoratimimus CIP 103073 reference strains, shotgun cloning of β-lactamase genes was performed, followed by protein expression in Escherichia coli. The deduced amino acid sequences of these β-lactamase genes revealed that TUS-1 and MUS-1 from M. odoratus CIP 103105 and M. odoratimimus CIP 103073, respectively, shared 73% amino acid identity. Mature proteins TUS-1 and MUS-1, with pI values of 7.8 and 5.2, respectively, had relative molecular masses of ca. 26 kDa. These β-lactamases are members of the subclass B1 of metallo-β-lactamases and are distantly related to other metalloenzymes, being most closely related to IND-1 from Chryseobacterium indologenes (42% amino acid identity). However, phylogenic analysis showed that TUS-1 and MUS-1 belong to the same phylogenic lineage of subclass B1 enzymes that groups the subclass B1 β-lactamases of Flavobacterium species. Kinetic parameters of purified β-lactamases TUS-1 and MUS-1 detailed their hydrolysis spectra, which encompass most β-lactams except aztreonam. β-Lactamases TUS-1 and MUS-1 were classified in functional subgroup 3a of metalloenzymes. This work further characterizes chromosome-encoded metalloenzymes from Flavobacteriaceae species that explain at least part of their intrinsic resistance to β-lactams.

Expression of the Isoamylase Gene ofFlavobacterium odoratum KU in Escherichia coliand Identification of Essential Residues of the Enzyme by Site-Directed Mutagenesis

ABSTRACT The isoamylase gene from Flavobacterium odoratum KU was cloned into and expressed in Escherichia coli JM109. The promoter of the gene was successful in E. coli, and the enzyme produced was excreted into the culture medium, depending on the amount of the enzyme expressed. The enzyme found in the culture medium showed almost the same M r, heat-inactivating constant, and N-terminal sequence as those of the enzyme accumulated in the periplasmic space. This result indicated that the enzyme accumulated in an active form at the periplasm was transported out of the cell. The primary sequence of the enzyme, which was deduced from its nucleotide sequence, showed that the mature enzyme consisted of 741 amino acid residues. By changing five possible residues to Ala independently, it was found that Asp-374, Glu-422, and Asp-497 were essential. The sequences around those residues were highly conserved in isoamylases of different origins and the glycogen operon protein X, GlgX. The comparison of the distance between these essential residues with those of various amylases suggested that the bacterial and plant isoamylase but not GlgX had a longer fourth loop than the other amylases. This longer fourth loop had a possible role in accommodating the long branched chains of native glycogens and starches.

Comparative activity of trovafloxacin, alone and in combination with other agents, against gram-negative nonfermentative rods.

In the first part of this study, agar dilution MICs were used to test the activities of trovafloxacin, ciprofloxacin, ofloxacin, levofloxacin, sparfloxacin, clinafloxacin, ceftazidime, and imipenem against 458 gram-negative nonfermenters. The overall respective MICs at which 50% of isolates are inhibited (MIC50s) and MIC90s were as follows: trovafloxacin, 1.0 and 16.0 microg/ml; ciprofloxacin, 2.0 and 16.0 microg/ml; ofloxacin, 2.0 and 32.0 microg/ml; levofloxacin, 1.0 and 16.0 microg/ml; sparfloxacin, 1.0 and 16.0 microg/ml; clinafloxacin, 0.5 and 4.0 microg/ml; ceftazidime, 8.0 and 128.0 microg/ml; imipenem, 2.0 and 256.0 microg/ml. Clinafloxacin was the most active of all the quinolones tested. The MIC90s of trovafloxacin were < or = 4.0 microg/ml for Pseudomonas aeruginosa, Stenotrophomonas maltophilia, Flavobacterium odoratum, and Chryseobacterium meningosepticum; trovafloxacin MIC90s were < or = 2.0 microg/ml for Moraxella spp., Pseudomonas stutzeri, and Chryseobacterium indologenes-C. gleum. Of the other quinolones tested, the MICs of sparfloxacin and levofloxacin were lower than those of ciprofloxacin and ofloxacin. High ceftazidime MICs (> or = 32.0 microg/ml) were observed for all nonfermentative species tested. Although for the majority of strains tested imipenem MICs were < or = 8.0 microg/ml, high imipenem MICs were observed for many species, especially S. maltophilia, Burkholderia cepacia, F. odoratum, and Chryseobacterium meningosepticum. For Alcaligenes xylosoxidans strains, the MICs of all compounds were generally a few dilutions lower than those for Alcaligenes faecalis-A. odorans. Time-kill studies with five strains revealed that trovafloxacin and all quinolones yielded more rapid time-kill kinetics than ceftazidime and imipenem. Synergy testing by checkerboard titrations of 286 strains with trovafloxacin combined with ceftazidime, amikacin, and imipenem revealed fractional inhibitory concentration (FIC) indices in the range indicating synergism (< or = 0.5) for 81, 41, and 40 strains, respectively, and FIC indices indicating additivity or indifference (> 0.5 to 4.0) for 205, 245, and 246 strains, respectively. No FIC indices indicating antagonism (> 4.0) were observed. Synergy between trovafloxacin and ceftazidime was found for 32 of 36 S. maltophilia strains. Time-kill studies with 20 strains showed that for most strains for which FIC indices were in the range indicating additivity or indifference, FIC indices indicated synergy by the time-kill method. Synergy was particularly noticeable for S. maltophilia strains with combinations of ceftazidime and trovafloxacin.