Evidence of Torque teno virus (TTV) vertical transmission in swine.

Routes of swine torque teno virus (TTV) transmission have been minimally investigated in the pig population. Current knowledge suggests the faecal-oral route as the most probable way of viral dissemination. Other transmission routes, such as mother-to-infant, have been studied in humans, but no information is available for swine. Thus, the objective of the present study was to determine the prevalence of two swine TTV genogroups, TTV1 and TTV2, in colostrum samples (n=61) and sera samples from sows (n=10) and stillborn pigs coming from them (n=30). Colostrum was fractioned into two components, milk whey and cell pellets, and 26 out of 61 milk whey samples and 30 out of 58 cell pellets analyzed contained TTV1 or TTV2 genomes, respectively, detected by specific PCR methods. Six and 3 out of 10 serum samples from sows were positive for TTV1 and TTV2 DNA, respectively. Finally, 15 out of 30 sera from stillborns were PCR positive for TTV1, but only 2 were TTV2 positive. Positive stillborns were always infected with the same TTV genogroup as their mothers. However, TTV sequence analysis determined that sequences obtained from sows and their stillborns were not identical. In conclusion, our results indicated that swine TTVs can be transmitted vertically, and suggest that different sow-to-piglet transmission routes may coexist, including transplacental/intra-uterine as well as through lactation. This study represents the first description of swine TTV presence in colostrum and stillborn piglets.

Recessive and dominant genes interfere with the vascular transport of Potato virus A in diploid potatoes.

Resistance to Potato virus A (PVA) was examined in a diploid cross involving Solanum tuberosum subsp. andigena as a resistance source. Hypersensitive resistance (HR) to PVA cosegregated with extreme resistance (ER) to Potato virus Y conferred by the dominant gene Ry(adg) on chromosome XI. Hence, HR to PVA was controlled by a novel, dominant resistance gene closely linked to Ry(adg), or Ry(adg) recognized both viruses but conferred a different type of resistance to each virus. The HR prevented systemic infection with PVA following mechanical inoculation but not following graft inoculation. Another, recessive gene, ra, that may be linked or even allelic with Ry(adg) fully blocked vascular transport of PVA in graft-inoculated plants. Hence, a possibility exists that the genes for the three types of resistance to potyviruses may reside at the same, resistance gene-rich chromosome region syntenic in solanaceous species and might be related. The gene ra acted against all of the three PVA strains tested and, therefore, the avirulence determinants could not be mapped. However, also, PVA strain-specific resistance was found in the progeny. It was overcome by mutations introduced into the viral genome-linked protein and the helper component proteinase and/or the coat protein.

Comparison of the complete sequences of five different isolates of Potato virus A (PVA), genus Potyvirus.

The complete nucleotide (nt) and deduced amino acid (aa) sequences of isolates Ali, U, Her (from potato, Solanum tuberosum) and TamMV (from tamarillo, Solanum betacea) of Potato virus A (PVA, genus Potyvirus) were determined and compared with the previously reported sequence of PVA isolate B11. Most parts (proteins) of the polyprotein showed over 95% aa sequence similarity. The cylindrical inclusion (CI) protein and the 6K 1 protein were the most conserved proteins among the five isolates. TamMV was the most different isolate. Sequence similarity between TamMV and the other isolates was the lowest in regions close to the 5'-end [5'-non-translated region (NTR) and P1 region] and 3'-end (N-terminus of coat protein) of the genome. However, the termini of the genome (the first 60 nt of the 5'-NTR and the entire 3'-NTR) were highly similar in all five isolates. A frameshift region in the replicase (NIb) was identified the PVA isolates Ali, B11, Her and U, as compared to TamMV and other potyviruses.