Performance Evaluation of a Prototype Architect Antibody Assay for Babesia microti.

The tick-borne protozoan Babesia microti is responsible for more than 200 cases of transfusion-transmitted babesiosis (TTB) infection in the United States that have occurred over the last 30 years. Measures to mitigate the risk of TTB include nucleic acid testing (NAT) and B. microti antibody testing. A fully automated prototype B. microti antibody test was developed on the Architect instrument. The specificity was determined to be 99.98% in volunteer blood donors (n = 28,740) from areas considered to have low endemicity for B. microti The sensitivity of the prototype test was studied in experimentally infected macaques; a total of 128 samples were detected as positive whereas 125 were detected as positive with an indirect fluorescent antibody (IFA) test; additionally, 83 (89.2%) of the PCR-positive samples were detected in contrast to 81 (87.1%) using an IFA test. All PCR-positive samples that tested negative in the prototype antibody test were preseroconversion period samples. Following seroconversion, periods of intermittent parasitemia occurred; 17 PCR-negative samples drawn in between PCR-positive bleed dates tested positive both by the prototype test (robust reactivity) and IFA test (marginal reactivity) prior to the administration of therapeutic drugs, indicating that the PCR test failed to detect samples from persistently infected macaques. The prototype assay detected 56 of 58 (96.6%) human subjects diagnosed with clinical babesiosis by both PCR and IFA testing. Overall, the prototype anti-Babesia assay provides a highly sensitive and specific test for the diagnosis of B. microti infection. While PCR is preferred for detection of window-period parasitemia, antibody tests detect infected subjects during periods of low-level parasitemia.

Fluorescence and solution NMR study of the active site of a 160-kDa group II intron ribozyme.

We have reconstructed the group II intron from Pylaiella littoralis (PL) into a hydrolytic ribozyme, comprising domains 1-3 (D123) connected in cis plus domain 5 (D5) supplied in trans that efficiently cleaves spliced exon substrates. Using a novel gel-based fluorescence assay and nuclear magnetic resonance (NMR) spectroscopy, we monitored the direct binding of D5 to D123, characterized the kinetics of the spliced exon hydrolysis reaction (which is mechanistically analogous to the reverse of the second catalytic step of splicing), and identified the binding surface of D123 on D5. This PL ribozyme acts as an RNA endonuclease even at low monovalent (100 mM KCl) and divalent ion concentrations (1-10 mM MgCl(2)). This is in contrast to other group II intron ribozyme systems that require high levels of salt, making NMR analysis problematic. D5 binds tightly to D123 with a K(d) of 650 +/- 250 nM, a K(m) of approximately 300 nM, and a K(cat) of 0.02 min(-1) under single turnover conditions. Within the approximately 160-kDa D123-D5 binary complex, site-specific binding to D123 leads to dramatic chemical shift perturbation of residues localized to the tetraloop and internal bulge within D5, suggesting a structural switch model for D5-assisted splicing. This minimal ribozyme thus recapitulates the essential features of the reverse of the second catalytic step and represents a well-behaved system for ongoing high-resolution structural work to complement folding and catalytic functional studies.

High-affinity DNA binding by a Mot1p-TBP complex: implications for TAF-independent transcription.

Yeast Mot1p, an abundant conserved member of the Snf2p-ATPase family of proteins, both dissociates TBP from DNA in vitro using the energy of ATP and represses gene transcription in vivo, yet paradoxically, loss of Mot1p function also leads to decreased transcription of certain genes. We conducted experiments utilizing fluorescently labeled DNA, TBP, fluorescence anisotropy spectroscopy and native gel electrophoresis to study Mot1p action. We have made a number of observations, the most intriguing being that a stable Mot1p-TBP complex has the ability to bind TATA DNA with high affinity, albeit with dramatically altered specificity. We propose that this altered TBP-DNA recognition is integral to Mot1p's ability to regulate transcription, and further postulate that the Mot1p-TBP complex delivers TBP to TAF-independent mRNA encoding genes.