Detection of a Single Viable Cryptosporidium parvum Oocyst in Environmental Water Concentrates by Reverse Transcription-PCR.

Volume 62, no. 9, p. 3386, column 1, last line: "(specific gravity, 2.10) and centrifuging the mixture at 2,000 x g for 10 min" should read "(specific gravity, 1.10) and centrifuging the mixture at 1,050 x g for 10 min." Page 3387, column 1, line 16: "25 cycles at 90(deg)C for 5 min" should read "25 cycles at 90(deg)C for 5 s." [This corrects the article on p. 3385 in vol. 62.].

Detection of a single viable Cryptosporidium parvum oocyst in environmental water concentrates by reverse transcription-PCR.

Current methods for detection of Cryptosporidium parvum oocysts in water are time-consuming and difficult. We have developed a reverse transcription (RT)-PCR which can detect the presence of a single viable oocyst spiked into concentrated environmental water samples. The test is based on the detection of mRNA from a C. parvum heat shock protein (hsp). The synthesis of hsp was induced by a short 45 degrees C incubation followed by oocyst lysis by a freeze-thaw process. Hsp70 mRNA, produced only from viable oocysts, was then isolated by hybridization to oligo(dT)25-coated magnetic beads. Detection was achieved by RT-PCR amplification of a 590-bp region of hsp70 mRNA specific for C. parvum. To test the method, samples of reticulated, reservoir, bore, and river water were concentrated by chemical flocculation and Percoll-sucrose gradient centrifugation and then spiked with dilutions of oocysts. In all four of the water types examined, the detection of single oocysts was possible by RT-PCR combined with Southern hybridization. RT-PCR products were not obtained from formalin-inactivated oocysts. An RNA internal positive control fragment was synthesized that was included with each reaction to guard against RT-PCR false-negative results that may be caused by the presence of inhibitory substances. However, when the magnetic beads were used to extract and concentrate mRNA, no inhibition was observed. The technique is versatile, straightforward, and rapid (1 day) and provides a sensitive and economic means of screening concentrated water samples for the presence of C. parvum.

Detection of pathogenic Yersinia enterocolitica in environmental waters by PCR.

The isolation of pathogenic strains of Yersinia enterocolitica from food and water samples by culture is time-consuming and unreliable. A two-step PCR procedure has been developed which, after a period of bacterial enrichment, can detect and confirm the presence of pathogenic Y. enterocolitica within a single day. This PCR method works effectively for a range of environmental water types, including reticulated waters, reservoirs and creeks. A survey of environmental waters in Victoria, Australia, showed that the PCR method detected pathogenic Y. enterocolitica in water sampled from four separate sites (two creeks and two reservoirs). Repeat samplings of the two reservoirs yielded PCR-positive results on all but one occasion. Culture analysis of the same samples detected pathogenic Y. enterocolitica in only one sample, indicating that the PCR can detect pathogenic Y. enterocolitica which are undetectable by culture. Results from this study confirm that potentially pathogenic strains of Y. enterocolitica can exist in environmental waters.

Random amplified polymorphic DNA (RAPD) profiling of Legionella pneumophila.

DNA (RAPD) profiling of Legionella pneumophila by PCR can be used to provide a simple and efficient comparison of clinical and environmental isolates. RAPD profiling is quicker and cheaper to perform than restriction fragment length polymorphism (RFLP) typing, eliminating the need for blotting, hybridization and detection. For some isolates, RAPD profiling is more discriminatory than RFLP typing, being able to distinguish between isolates with identical RFLP types.

Identification of the E3900 family, a second family of rye B chromosome specific repeated sequences.

A second family of highly repeated sequences has been identified on the B chromosome of rye (Secale cereale). The E3900 family was detected as a variant band in EcoRI digests of +B DNA. A clone of the basic repeat of the family was obtained, and the organization of the family was investigated by genomic hybridization. The E3900 family has no apparent homology to the A chromosome sequences of rye or other members of the Gramineae. The family has been localized by in situ hybridization to the end of the long arm of the rye B chromosome. The previously characterized E1100 sequence shows in situ hybridization to the same location as the E3900 family. These results are discussed in light of current theories of the origin of B chromosomes.