Paul J. Romaniuk

CPA is a class of isothermal amplification reactions that is carried out by a strand displacement DNA polymerase and does not require an initial denaturation step or the addition of a nicking enzyme. At the assay temperature of 63°C, the formation of a primer-template hybrid at transient, spontaneous denaturation bubbles in the DNA template is favored over re-annealing of the template strands by the high concentration of primer relative to template DNA. Strand displacement is encouraged by the annealing of cross primers with 5' ends that are not complementary to the template strand and the binding of a displacement primer upstream of the crossing primer. The resulting exponential amplification of target DNA is highly specific and highly sensitive, producing amplicons from as few as four bacterial cells. Here we report on the basic CPA mechanism - single crossing CPA - and provide details on alternative mechanisms.

The specific interaction between R17 coat protein and its target of translational repression at the initiation site of the R17 replicase gene was studied by synthesizing variants of the RNA binding site and measuring their affinity to the coat protein by using a nitrocellulose filter binding assay. Substitution of two of the seven single-stranded residues by other nucleotides greatly reduced the Ka, indicating that they are essential for the RNA-protein interaction. In contrast, three other single-stranded residues can be substituted without altering the Ka. When several of the base-paired residues in the binding site are altered in such a way that pairing is maintained, little change in Ka is observed. However, when the base pairs are disrupted, coat protein does not bind. These data suggest that while the hairpin loop structure is essential for protein binding, the base-paired residues do not contact the protein directly. On the basis of these and previous data, a model for the structural requirements of the R17 coat protein binding site is proposed. The model was successfully tested by demonstrating that oligomers with sequences quite different from the replicase initiator were able to bind coat protein.

Helical organisms with novel ultrastructural characteristics were isolated from the intestinal mucosa of rats and mice. These bacteria were characterized by the presence of 9 to 11 periplasmic fibers which appeared as concentric helical ridges on the surface of each cell. The cells were motile with a rapid corkscrewlike motion and had bipolar tufts of 10 to 14 sheathed flagella. The bacteria were microaerophilic, nutritionally fastidious, and physiologically similar to Helicobacter species and Wolinella succinogenes but could be differentiated from these organisms by their unique cellular ultrastructure. Using 16S rRNA sequencing, we found that strain ST1T (T = type strain) was related to previously described Helicobacter species, "Flexispira rappini," and W. succinogenes. The closest relatives of strain ST1T were Helicobacter mustelae and "F. rappini" (average similarity value, 96%). On the basis of phylogenetic data, strain ST1T (= ATCC 49282T) represents a new species of the genus Helicobacter, for which we propose the name Helicobacter muridarum.

Comparison of partial 16S rRNA sequences from representative Campylobacter species indicates that the Campylobacter species form a previously undescribed basic eubacterial group, which is related to the other major groups only by very deep branching. This analysis was extended to include the spiral bacterium associated with human gastritis, Campylobacter pylori (formerly Campylobacter pyloridis). The distance between C. pylori and the other Campylobacter species is sufficient to exclude the pyloric organism from the Campylobacter genus. The results indicate that C. pylori is more closely related to Wolinella succinogenes than it is to the other Campylobacter species inspected. Another close relative of the campylobacters was found to be Thiovulum, a sulfide-dependent marine bacterium.