Advancing molecular diagnostics for trypanosomatid parasites.

This Commentary highlights the article by González-Andrade et al who investigated a conserved spliced leader RNA as an attractive new molecular target for next-generation diagnostics in diseases caused by trypanosomatids.

Diagnosis of trypanosomatid infections: targeting the spliced leader RNA.

Trypanosomatids transcribe their genes in large polycistronic clusters that are further processed into mature mRNA molecules by trans-splicing. During this maturation process, a conserved spliced leader RNA (SL-RNA) sequence of 39 bp is physically linked to the 5' end of the pre-mRNA molecules. Trypanosomatid infections cause a series of devastating diseases in man (sleeping sickness, leishmaniasis, Chagas disease) and animals (nagana, surra, dourine). Here, we investigated the SL-RNA molecule for its diagnostic potential using reverse transcription followed by real-time PCR. As a model, we used Trypanosoma brucei gambiense, which causes sleeping sickness in west and central Africa. We showed that the copy number of the SL-RNA molecule in one single parasitic cell is at least 8600. We observed a lower detection limit of the SL-RNA assay in spiked blood samples of 100 trypanosomes per milliliter of blood. We also proved that we can detect the trypanosome's SL-RNA in the blood of sleeping sickness patients with a sensitivity of 92% (95% CI, 78%-97%) and a specificity of 96% (95% CI, 86%-99%). The SL-RNA is thus an attractive new molecular target for next-generation diagnostics in diseases caused by trypanosomatids.

Affinity purification of T7 RNA transcripts with homogeneous ends using ARiBo and CRISPR tags.

Affinity purification of RNA using the ARiBo tag technology currently provides an ideal approach to quickly prepare RNA with 3' homogeneity. Here, we explored strategies to also ensure 5' homogeneity of affinity-purified RNAs. First, we systematically investigated the effect of starting nucleotides on the 5' heterogeneity of a small SLI RNA substrate from the Neurospora VS ribozyme purified from an SLI-ARiBo precursor. A series of 32 SLI RNA sequences with variations in the +1 to +3 region was produced from two T7 promoters (class III consensus and class II 2.5) using either the wild-type T7 RNA polymerase or the P266L mutant. Although the P266L mutant helps decrease the levels of 5'-sequence heterogeneity in several cases, significant levels of 5' heterogeneity (≥1.5%) remain for transcripts starting with GGG, GAG, GCG, GGC, AGG, AGA, AAA, ACA, AUA, AAC, ACC, AUC, and AAU. To provide a more general approach to purifying RNA with 5' homogeneity, we tested the suitability of using a small CRISPR RNA stem-loop at the 5' end of the SLI-ARiBo RNA. Interestingly, we found that complete cleavage of the 5'-CRISPR tag with the Cse3 endoribonuclease can be achieved quickly from CRISPR-SLI-ARiBo transcripts. With this procedure, it is possible to generate SLI-ARiBo RNAs starting with any of the four standard nucleotides (G, C, A, or U) involved in either a single- or a double-stranded structure. Moreover, the 5'-CRISPR-based strategy can be combined with affinity purification using the 3'-ARiBo tag for quick purification of RNA with both 5' and 3' homogeneity.

Rapid purification of RNA secondary structures.

A new method for rapid purification and structural analysis of oligoribonucleotides of 19 and 20 nt is applied to RNA hairpins SL3 and SL2, which are stable secondary structures present on the psi recognition element of HIV-1. This approach uses ion-pairing reversed-phase liquid chromatography (IP-RPLC) to achieve the separation of the stem-loop from the transcription mix. Evidence is presented that IP-RPLC is sensitive to the different conformers of these secondary structures. The purity of each stem-loop was confirmed by mass spectrometry and PAGE. IP-RPLC purification was found to be superior to PAGE in terms of time, safety and, most importantly, purity.

Structure of SL4 RNA from the HIV-1 packaging signal.

The NMR-based structure is described for an RNA model of stem-loop 4 (SL4) from the HIV-1 major packaging domain. The GAGA tetraloop adopts a conformation similar to the classic GNRA form, although there are differences in the details. The type II tandem G.U pairs have a combination of wobble and bifurcated hydrogen bonds where the uracil 2-carbonyl oxygen is hydrogen-bonded to both G,H1 and G,H2. There is the likelihood of a Na(+) ion coordinated to the four carbonyl oxygens in the major groove for these G.U pairs and perhaps to the N7 lone pairs of the G bases as well. A continuous stack of five bases extends over nearly the whole length of the stem to the base of the loop in the RNA 16mer: C15/U14/G13/G5/C6. There is no evidence for a terminal G.A pair; instead, G1 appears quite unrestrained, and A16 stacks on both C15 and G2. Residues G2 through G5 exhibit broadened resonances, especially G3 and U4, suggesting enhanced mobility for the 5'-side of the stem. The structure shows G2/G3/U4 stacking along the same strand, nearly isolated from interaction with the other bases. This is probably an important factor in the signal broadening and apparent mobility of these residues and the low stability of the 16mer hairpin against thermal denaturation.