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ARS Home » Southeast Area » Auburn, Alabama » Aquatic Animal Health Research » Research » Publications at this Location » Publication #285835

Title: Biochemical and molecular characterization of the novobiocin and rifampicin resistant Aeromonas hydrophila vaccine strain AL09-71 N+R compared to its virulent parent strain AL90-71

Author
item Wei Pridgeon, Yuping
item MU, XINGJIANG - Auburn University
item Klesius, Phillip

Submitted to: Veterinary Microbiology
Publication Type: Peer Reviewed Journal
Publication Acceptance Date: 3/20/2013
Publication Date: 4/4/2013
Citation: Wei Pridgeon, Y., Mu, X., Klesius, P.H. 2013. Biochemical and molecular characterization of the novobiocin and rifampicin resistant Aeromonas hydrophila vaccine strain AL09-71 N+R compared to its virulent parent strain AL90-71. Veterinary Microbiology. 165:349-357.

Interpretive Summary: To understand the fitness cost of novobiocin- and rifampicin- resistance in an attenuated Aeromonas hydrophiila vaccine strain AL09-71 N+R, this study was performed. Our results revealed that the cell size, colony size, cell proliferation rate, chemotactic response, and invasion ability of the vaccine strain AL09-71 N+R was significantly smaller than that of its virulent parent strain AL09-71. Five mutations at novobiocin’s target site DNA gyrase subunit B gyrB and rifampicin’s target site RNA polymerase subunit B rpoB were found between the two strains. No unique DNA sequences were found to be present in AL09-71 but absent in AL09-71 N+R. However, at transcription level, 29 genes were found to be expressed greater than 10 fold in AL09-71 N+R compared to that in AL09-71.

Technical Abstract: To understand the fitness cost of novobiocin- and rifampicin- resistance in an attenuated Aeromonas hydrophiila vaccine strain AL09-71 N+R compared to its virulent parent strain AL09-71, colony size, cell size, cell proliferation rate, chemotactic response, and the ability to invade catfish gill cells of the two strains were compared. Our results revealed that: 1) the cell size and the colony size of AL09-71 N+R was significantly (P<0.05) smaller than that of AL09-71; 2) the proliferation rate of AL09-71 N+R was significantly (P<0.05) slower than that of AL09-71; 3) AL09-71 N+R had a significantly (P<0.05) lower chemotactic response to catfish mucus than that of AL09-71; 4) the ability of AL09-71 N+R to invade catfish gill cells was significantly (P<0.05) lower than that of AL09-71. To understand whether target site mutation might play a role in antibiotic resistance, novobiocin’s target site DNA gyrase subunit B gyrB and rifampicin’s target site RNA polymerase subunit B rpoB were sequenced from the two strains. Our results revealed the following five mutations: 1) two missense mutations (CGC to ATC resulting in arginine/R to serine/S; TAC to TGC resulting in tyrosine/Y to cysteine/C) between AL09-71 gyrB and AL09-71 N+R gyrB; 2) three missense mutations (GAC to AAC resulting in aspartic acid/D to asparagine/N; CTG to CCG resulting in leucine/L to proline/P; CTG to CCG resulting in leucine/L to proline/P) between AL09-71 rpoB and AL09-71 N+R rpoB. To determine whether any unique DNA sequences were present in AL09-71 but absent in AL09-71 N+R, PCR-select bacterial genome subtractive hybridization was performed. Of 96 clones selected from the subtractive genomic DNA library, 32 sequences were found. None of the 32 sequences was confirmed to be present in AL09-71 but absent in AL09-71 N+R. At the transcription level, 29 of the 32 genes were found to be expressed greater than 10 fold in AL09-71 N+R compared to that in AL09-71.