Molecular characterization of variants of a new 'rule-breaking' tobacco rattle virus RNA2 in potatoes.

In potato tubers showing pronounced corky ringspot symptoms, two related 'rule-breaking" tobacco rattle virus (TRV) RNA2s, named Da-2 and Db-2, were identified. Their coat protein (cp) genes are preceded on the 5' side by an additional gene for a 35 kDa protein for which no relationships with previously described TRV genes or their expression products were found. With estimated 4296 and 4247 nucleotides (nts) the two RNAs are the longest TRV RNA2s described so far. The difference in size between Da-2 and Db-2 is due to a duplication of a stretch of 49 nts in the 5' untranslated region of Da-2. An alignment of TRV coat proteins (cp) revealed that up to about amino acid (aa) 176 they form two rather uniform groups. The much shorter C-terminal parts of the cps, however, differ considerably in size and composition. With 56 aa this C-terminal part is much longer in the Da and Db sequences than in all other TRV cps. It differs in 18 positions in the two strains whereas their N-terminal 184 aa differ only in two positions. - In young potato plants developing from bud-cuttings of TRV Db-infected potato tubers which had been planted in soil free of virus and nematodes a gradual degradation of Db-2 was observed. In the newly formed rootlets already five days after planting a deletion of 80 nts was observed in the putative 2b gene which in other TRV strains encodes a protein necessary for nematode transmission. Thirty three days after planting the entire 2b gene, 119 nts at the 3'end of the cp gene and a portion of the original 3'untranslated region of Db-2 had been lost in the newly formed roots, leaves and stolons. The gene for the 35kDa protein was the only one which was not affected by deletions which seems to emphasize its importance for the virus. Fifty days after planting only TRV RNA1, but no TRV RNA2 were detectable.

Protein expression from unintegrated HIV-1 DNA introduces bias in primary in vitro post-integration latency models.

To understand the persistence of latently HIV-1 infected cells in virally suppressed infected patients, a number of in vitro models of HIV latency have been developed. In an attempt to mimic the in vivo situation as closely as possible, several models use primary cells and replication-competent viruses in combination with antiretroviral compounds to prevent ongoing replication. Latency is subsequently measured by HIV RNA and/or protein production after cellular activation. To discriminate between pre- and post-integration latency, integrase inhibitors are routinely used, preventing novel integrations upon cellular activation. Here, we show that this choice of antiretrovirals may still cause a bias of pre-integration latency in these models, as unintegrated HIV DNA can form and directly contribute to the levels of HIV RNA and protein production. We further show that the addition of reverse transcriptase inhibitors effectively suppresses the levels of episomal HIV DNA (as measured by 2-LTR circles) and decreases the levels of HIV transcription. Consequently, we show that latency levels described in models that only use integrase inhibitors may be overestimated. The inclusion of additional control conditions, such as 2-LTR quantification and the addition of reverse transcriptase inhibitors, is crucial to fully elucidate the actual levels of post-integration latency.

A Potent Anti-influenza Compound Blocks Fusion through Stabilization of the Prefusion Conformation of the Hemagglutinin Protein.

An ultrahigh-throughput screen was performed to identify novel small molecule inhibitors of influenza virus replication. The screen employed a recombinant influenza A/WSN/33 virus expressing Renilla luciferase and yielded a hit rate of 0.5%, of which the vast majority showed little cytotoxicity at the inhibitory concentration. One of the top hits from this screen, designated S20, inhibits HA-mediated membrane fusion. S20 shows potent antiviral activity (IC50 = 80 nM) and low toxicity (CC50 = 40 µM), yielding a selectivity index of 500 and functionality against all of the group 1 influenza A viruses tested in this study, including the pandemic H1N1 and avian H5N1 viruses. Mechanism of action studies proved a direct S20-HA interaction and showed that S20 inhibits fusion by stabilizing the prefusion conformation of HA. In silico docking studies were performed, and the predicted binding site in HA2 corresponds with the area where resistance mutations occurred and correlates with the known role of this region in fusion. This high-throughput screen has yielded many promising new lead compounds, including S20, which will potentially shed light on the molecular mechanisms of viral infection and serve as research tools or be developed for clinical use as antivirals.

Complete nucleotide sequences of two closely related tobacco rattle virus RNA2s for which previously possibly only deletion/recombination mutants had been described.

The almost complete nucleotide (nt) sequences lacking only short primer-derived 5' and 3' terminal portions were determined for the RNA2s of two closely related tobacco rattle virus (TRV) isolates which were detected in recently infected roots of Nicotiana benthamiana bait plants (isolate HaB) or of field-grown potato plants (isolate HaW), respectively. The sequences of c. 1350 5' proximal nts in these RNA2s were almost identical to those in four previously described TRV isolates from potatoes in the Netherlands and Poland which had been propagated in tobacco leaves. The RNA2s of the earlier isolates, however, consist of only c. 2000 nts, whereas the HaW and HaB RNA2s comprise more than 4000 nts. In addition to the coat protein gene which is present in the RNA2s of all isolates, the HaW and HaB RNA2s contain two further open reading frames which in the previous isolates were apparently lost either entirely or of which small remnants only were left. The RNA2s of the previously described isolates and of our new ones have different RNA1-related 3' ends which apparently have been acquired from different supporting RNA1s. After transmission to tobacco leaves HaB RNA2 formed deletion/recombination mutants which--as in the previous isolates--consisted of only c. 2000 nts. They had acquired the 3' end from their supporting RNA1.

Sequence-modified primers for the differential RT-PCR detection of Andean potato latent and Andean potato mild mosaic viruses in quarantine tests.

To enable the differential PCR detection of Andean potato latent virus (APLV) and Andean potato mild mosaic virus (APMMV) strains, sense primers were designed that correspond to regions directly upstream of the coat protein genes. Their differentiating power was increased by A->C or T->C replacements in their 3'-terminal parts. Together with the broad-specificity antisense primer EM3, primer AL-a-mod3C detected all APLV strains tested, but none of the APMMV strains. Primer AM-a-mod4C yielded PCR products with all APMMV preparations, but also with some APLV preparations. Sequence analysis revealed that this was not due to a lack of primer specificity, but to the sensitive detection of contaminating APMMV in some of our APLV preparations.

The complete genome sequences of a Peruvian and a Colombian isolate of Andean potato latent virus and partial sequences of further isolates suggest the existence of two distinct potato-infecting tymovirus species.

The complete genomic RNA sequences of the tymovirus isolates Hu and Col from potato which originally had been considered to be strains of the same virus species, i.e. Andean potato latent virus (APLV), were determined by siRNA sequencing and assembly, and found to share only c. 65% nt sequence identity. This result together with those of serological tests and comparisons of the coat protein gene sequences of additional tymovirus isolates from potato suggest that the species Andean potato latent virus should be subdivided into two species, i.e. APLV and Andean potato mild mosaic virus (APMMV). Primers were designed for the broad specificity detection of both viruses.

New isolates of carnation Italian ringspot virus differ from the original one by having replication-associated proteins with a typical tombusvirus-like N-terminus and by inducing peroxisome- rather than mitochondrion-derived multivesicular bodies.

Five new isolates of carnation Italian ringspot virus (CIRV) from cherry trees, Gypsophila and surface water differ from the original carnation isolate (CIRV-car) and also from Pelargonium necrotic spot virus (PelNSV) by having an ORF 1/ORF1-RT with a typical tombusvirus-like 5'end and by inducing the formation of peroxisome- rather than mitochondrion-derived multivesicular bodies (MVBs). This supports with natural isolates earlier conclusions reached by others with artificially produced hybrid viruses that the 5'end of ORF 1 determines from which organelle the MBVs will be derived. CIRV-car might have resulted from a natural recombination event with genome elements of a PelNSV-like virus.