A quantitative competitive polymerase chain reaction assay for the oyster pathogen Perkinsus marinus.

A quantitative competitive polymerase chain reaction (QCPCR) assay was developed for the oyster parasite Perkinsus marinus. PCR primers for the rRNA gene region of P. marinus amplified DNA isolated from P. marinus but not from Perkinsus atlanticus, Crassostrea virginica, or the dinoflagellates Peridinium sp., Gymnodinium sp., or Amphidinium sp. A mutagenic primer was used to create a competitor plasmid molecule identical to the P. marinus target DNA sequence except for a 13-bp deletion. Both P. marinus and competitor DNA amplified with equivalent efficiencies. Each of 25 oysters was processed by 5 P. marinus diagnostic methods--Ray's fluid thioglycollate medium (FTM) tissue assay, FTM hemolymph assay, whole oyster body burden assay, QCPCR of combined gill and mantle (gill/mantle) tissue, and QCPCR of hemolymph. The QCPCR assay enabled detection of 0.01 fg of P. marinus DNA in 1.0 microg of oyster tissue. QCPCR of gill/mantle tissue or hemolymph as well as the body burden assay detected infections in 24 of 25 oysters. Ray's FTM tissue assay detected only 19 infections. The FTM hemolymph assay detected only 22 infections. Regression analysis of QCPCR results and FTM results indicated that the QCPCR assays were effective in quantitating P. marinus infections in oyster tissues.

Requirement for genes with homology to ABC transport systems for attachment and virulence of Agrobacterium tumefaciens.

Transposon mutants of Agrobacterium tumefaciens which were avirulent and unable to attach to plant cells were isolated and described previously. A clone from a library of Agrobacterium tumefaciens DNA which was able to complement these chromosomal att mutants was identified. Tn3HoHo1 insertions in this clone were made and used to replace the wild-type genes in the bacterial chromosome by marker exchange. The resulting mutants were avirulent and showed either no or very much reduced attachment to carrot suspension culture cells. We sequenced a 10-kb region of this clone and found a putative operon containing nine open reading frames (ORFs) (attA1A2BCDEFGH). The second and third ORFs (attA2 and attB) showed homology to genes encoding the membrane-spanning proteins (potB and potH; potC and potI) of periplasmic binding protein-dependent (ABC) transport systems from gram-negative bacteria. The homology was strongest to proteins involved in the transport of spermidine and putrescine. The first and fifth ORFs (attA1 and attE) showed homology to the genes encoding ATP-binding proteins of these systems including potA, potG, and cysT from Escherichia coli; occP from A. tumefaciens; cysA from Synechococcus spp.; and ORF-C from an operon involved in the attachment of Campylobacte jejuni. The ability of mutants in these att genes to bind to host cells was restored by addition of conditioned medium during incubation of the bacteria with host cells.