Fitness cost, gyrB mutation, and absence of phosphotransferase system fructose specific IIABC component in novobiocin-resistant Streptococcus iniae vaccine strain ISNO.

To understand the fitness cost of novobiocin-resistance in an attenuated Streptococcus iniae vaccine strain ISNO compared to its virulent parent strain ISET0901, cell proliferation rate of the two strains were compared to each other. Our results revealed that the cell proliferation rates of ISNO were significantly (P<0.05) smaller than that of ISET0901. To understand whether there was any mutation at the target site of novobiocin, DNA gyrase subunit B (gyrB) was sequenced from both strains. Sequencing results revealed a point mutation of AGA to AGC, resulting in a deduced amino acid substitution of R635S. To determine whether any unique DNA sequence was present in ISET0901 but absent in ISNO, PCR-select bacterial genome subtractive hybridization was performed. A phosphotransferase system fructose specific IIABC component sequence was confirmed to be present in ISET0901 but absent in ISNO. Using genomic DNAs from ten field-strains of S. iniae as templates, the phosphotransferase system fructose specific IIABC component sequence was found to be present in five highly virulent strains, but absent in five avirulent strains. Taken together, our results suggest that: (1) As fitness cost of novobicin resistance, ISNO had significantly smaller cell proliferation rate; (2) point mutation at target site gyrB resulting in R635S substitution was associated with novobiocin resistance in ISNO; and (3) phosphotransferase system fructose specific IIABC component was associated with virulence of S. iniae.

Identification and expression profiles of multiple genes in Nile tilapia in response to bacterial infections.

To understand the molecular mechanisms involved in response of Nile tilapia (Oreochromis niloticus) to bacterial infection, suppression subtractive cDNA hybridization technique was used to identify upregulated genes in the posterior kidney of Nile tilapia at 6h post infection with Aeromonas hydrophila. A total of 31 unique expressed sequence tags (ESTs) were identified from 192 clones of the subtractive cDNA library. Quantitative PCR revealed that nine of the 31 ESTs were significantly (p<0.05) upregulated in Nile tilapia at 6h post infection with A. hydrophila at an injection dose of 10(5)CFU per fish (≈ 20% mortality). Of the nine upregulated genes, four were also significantly (p<0.05) induced in Nile tilapia at 6h post infection with A. hydrophila at an injection dose of 10(6)CFU per fish (≈ 60% mortality). Of the four genes induced by A. hydrophila at both injection doses, three were also significantly (p<0.05) upregulated in Nile tilapia at 6h post infection with Streptococcus iniae at doses of 10(6) and at 10(5)CFU per fish (≈ 70% and ≈ 30% mortality, respectively). The three genes induced by both bacteria included EST 2A05 (similar to adenylate kinase domain containing protein 1), EST 2G11 (unknown protein, shared similarity with Salmo salar IgH locus B genomic sequence with e value of 0.02), and EST 2H04 (unknown protein). Significant upregulation of these genes in Nile tilapia following bacterial infections suggested that they might play important roles in host response to infections of A. hydrophila and S. iniae.

Identification of unique DNA sequences present in highly virulent 2009 Alabama isolates of Aeromonas hydrophila.

In 2009, a disease outbreak caused by Aeromonas hydrophila occurred in 48 catfish farms in West Alabama, causing an estimated loss of more than 3 million pounds of food size channel catfish. Virulence studies have revealed that the 2009 isolates of A. hydrophila are at least 200-fold more virulent than a 1998 Alabama isolate AL98-C1B. However, up to now, no molecular markers have been identified to differentiate the highly virulent 2009 isolates from other isolates of A. hydrophila. To understand the genetic differences between the highly virulent 2009 isolates and the less virulent AL98-C1B at molecular level, PCR-select bacterial genome subtractive hybridization was used in this study. A total of 96 clones were selected from the subtractive genomic DNA library. Sequencing results revealed that the 96 clones represented 64 unique A. hydrophila sequences. Of the 64 sequences, three (hypothetical protein XAUC_13870, structural toxin protein RtxA, and putative methyltransferase) were confirmed to be present in the three virulent 2009 Alabama isolates but absent in the less virulent AL98-C1B. Using genomic DNAs from nine field isolates of A. hydrophila with different virulence as templates, two sequences (hypothetical protein XAUC_13870 and putative methyltransferase) were found to be only present in highly virulent A. hydrophila isolates, but absent in avirulent isolates.