Development and characterization of rifampicin-resistant mutants from high virulent strains of Flavobacterium columnare.

Flavobacterium columnare is divided into three genetic groups or genomovars, genomovar II being highly virulent for channel catfish. A modified live vaccine is currently available to prevent columnaris disease under the licensed name Aquavac-Col(®) . The strain of F. columnare used to generate the avirulent rifampicin-resistant mutant used in Aquavac-Col(®) belonged to genomovar I, the less virulent group towards channel catfish. In this study, we describe the generation and characterization of rifampicin-resistant mutants from genomovar II strains. A total of 13 new mutants were obtained, and eight of them (two from each parent strain) were genetically and phenotypically characterized. Highly conserved regions within the ribosomal operons were identical between parent and mutant strains. Genetic differences between mutants and their parent strains were revealed by amplified fragment length polymorphism (AFLP). Genetic changes were distinctive among different mutants. Analysis of the lipopolysaccharide (LPS) showed that while some mutants lacked a few molecular bands of the LPS, some exhibited the same LPS profiles as their parent strains. Comparison between immunogenic proteins from mutants and parents was carried out by immunoblot analysis and further confirmed the uniqueness of individual mutants. A complete set of rifampicin-resistant mutants with different genetic and immunogenic properties from the highly virulent genomovar II has been created. These mutants may have the potential of becoming vaccine candidates against columnaris disease.

Use of suppressive subtractive hybridization to identify Flavobacterium columnare DNA sequences not shared with Flavobacterium johnsoniae.

AIMS: To identify specific sequences in the fish pathogen Flavobacterium columnare not shared by Flavobacterium johnsoniae. METHODS AND RESULTS: Suppressive subtractive hybridization (SSH) was used to selectively amplify and clone F. columnare-specific sequences. A highly virulent strain of F. columnare was used as tester and the type strain of F. johnsoniae was used as driver. After library construction, 192 clones were selected and sequenced. From those, 110 clones contained unique F. columnare-specific sequences that were verified using dot blot hybridization. Sequence sizes ranged from 55 to 872 bp with 45,363 bp sequenced in total. CONCLUSIONS: Specific F. columnare sequences representing all but one (motility related) functional categories were annotated. Several putative virulence factors were identified in F. columnare such as a collagenase, a chondroitinase, proteases, as well as drug resistance and iron transport-related genes. SIGNIFICANCE AND IMPACT OF THE STUDY: Suppressive subtractive hybridization is a cost-effective method for identifying genetic differences between Flavobacterium spp. The number of sequences available from F. columnare has been doubled.

Molecular typing of Streptococcus agalactiae isolates from fish.

The genetic variability among Streptococcus agalactiae isolates recovered from fish was characterized using single-stranded conformation polymorphism (SSCP) analysis of the intergenic spacer region (ISR), and amplified fragment length polymorphism (AFLP) fingerprinting. A total of 46 S. agalactiae cultures isolated from different fish species and geographic origins as well as related reference strains were included in the study. ISR-SSCP divided the S. agalactiae isolates analysed into five distinct genotypes. Genotype 1 grouped all Kuwait isolates while genotype 4 clustered the majority of non-Kuwait isolates (USA, Brazil and Honduras). AFLP analysis offered a higher resolution level by dividing the isolates into 13 different genotypes. Two different AFLP profiles were identified within the Kuwait isolates. When data from both ISR-SSCP and AFLP were combined through a multidimensional analysis (MDS), a good correlation between geographical origin and genotypes was observed. Both AFLP and ISR-SSCP revealed genetic differences between S. agalactiae isolates from fish. While AFLP offered a higher resolution, ISR-SSCP also provided valid information being a simpler and faster method.

Flavobacterium columnare genomovar influences mortality in channel catfish (Ictalurus punctatus).

Flavobacterium columnare, causal agent of columnaris disease, is pathogenic to many species of freshwater fish throughout the world. The United States channel catfish (Ictalurus punctatus) aquaculture industry is severely impacted by columnaris disease. The majority of the F. columnare isolates recovered from diseased channel catfish belonged to either genomovars I or II. The objective of the present study was to determine if differences existed in the ability of these genomovars to induce mortality in channel catfish. Single strand conformation polymorphism analysis (SSCP) was used to ascribe the isolates used in this study to the appropriate genomovar. Immersion challenge experiments (15min immersion exposure to approximately 5x10(5) to 1x10(6) CFU/mL) were carried out to assess virulence of genomovar I and II isolates to channel catfish. The results demonstrated that genomovar II (n=4) isolates were significantly (P<0.05) more virulent to channel catfish fry (92-100% mortality) than genomovar I (n=3) isolates (0-46% mortality). In vivo adhesion of the genetically characterized F. columnare also correlated (r2=0.73) to increased mortality in the challenged fry. In fingerling channel catfish, significantly higher mortality (P<0.05) resulted with genomovar II isolates ALM-05-182 and ALG-00-530 as compared to all the genomovar I isolates (n=3). Mortality of genomovar II isolate BGFS-27 with similar to genomovar II isolate (ALG-00-530) and two genomovar I isolates (ALM-05-53 and 140). The results suggest that although both genomovars are present in the aquatic environment, genomovar II appears to be more pathogenic for channel catfish.

Electrochemical protoplast fusion in citrus.

We report here the development of a novel protoplast fusion method for citrus somatic hybridization. This new procedure, which we have named electrochemical protoplast fusion, is based on chemically induced protoplast aggregation, using a low concentration of polyethylene glycol, and DC pulse-promoted membrane fusion. Based on the results of nucleus and mitochondria molecular analyses, we were successful in using this method to regenerate both symmetric somatic hybrids and cybrids. Various parameters, including pulse intensity, pulse length, and composition of the fusion media, were tested, and the optimum fusion condition selected consisted of two 100-micros pulses of 1,500 V cm(-1). Our conclusion is that electrochemical fusion is a reliable and reproducible method that combines the best features of both the chemical and electrical methods, thereby promoting cell division and high embryogenesis rates of the fused cells. It represents a new approach to citrus somatic hybridization. Various interesting features of this new approach are presented and discussed.

Green fluorescent protein as a visual marker in somatic hybridization.

Using a transgenic citrus plant expressing Green Fluorescent Protein (GFP) as a parent in somatic fusion experiments, we investigated the suitability of GFP as an in vivo marker to follow the processes of protoplast fusion, regeneration and selection of hybrid plants. A high level of GFP expression was detected in transgenic citrus protoplasts, hybrid callus, embryos and plants. It is demonstrated that GFP can be used for the continuous monitoring of the fusion process, localization of hybrid colonies and callus, and selection of somatic hybrid embryos and plants.