Bone sialoprotein (BSP) and osteopontin (OPN) are two major non-collagenous proteins in bone that have similar biochemical properties and can mediate cell attachment through an RGD (Arg-Gly-Asp) motif that recognizes the vitronectin receptor. To facilitate evaluations of the biological functions of BSP and OPN in bone formation, affinity-purified rabbit polyclonal antibodies against porcine BSP and OPN were used, together with a high-resolution protein A-gold immunocytochemical technique to reveal the ultrastructural localization of these proteins in undermineralized sections of 50-day fetal porcine calvarial bone. In addition, 35S-labelled antisense riboprobes were prepared to demonstrate the cellular expression of BSP and OPN in the same tissues using in situ hybridization. Immunolocalization for both BSP and OPN revealed the highest density of gold particles associated with electron-dense organic material found at the mineralization front and in 'cement lines'. Labelling was also observed in the mineralized matrix over electron-dense material between collagen fibrils. In the osteoid of newly-formed bone, immunogold labelling for BSP and OPN was associated with loci of mineralization, which were often characterized by feathery clusters of fine needle-like crystals. Results of in situ hybridization on the same tissues demonstrated that BSP mRNA expression was restricted to differentiated osteoblasts with particularly strong signals evident at sites of de novo bone formation. More moderate expression of BSP was observed in 'older' osteoblasts and in some of the newly-entrapped osteocytes. Although expression of OPN mRNA was also observed in osteoblasts and osteocytes, the level of hybridization was similar for most bone cells and not markedly stronger than the signal observed in some stromal cells. While it is evident from these and other studies that both BSP and OPN are associated with bone formation, the differences observed in cellular expression indicate distinct roles for these proteins in bone formation.
Degenerate primers for RT-PCR were designed and used to amplify genome fragments ( c. 750 nt in the coat protein-ORF6 region) of allexiviruses from a total of 28 garlic samples from 24 provinces in China. Many samples contained more than one distinct sequence. A total of 60 different sequences were obtained. Phylogenetic analysis and two-way comparisons were used to assess the status of the sequences and to re-examine the criteria for distinguishing species within the genus. Most of the sequences could be allocated to either Garlic virus D or Garlic virus X on the basis of sequence similarity but some appeared to be intermediate between existing species. There were no sequences of Garlic virus C or Shallot virus X. A comparison with the related genera Carlavirus, Foveavirus and Potexvirus suggests that the published allexivirus species demarcation criteria may have been drawn too tightly and should be re-examined.
Degenerate primers were used to amplify virus sequences from imported lilies in Zhejiang province, China. Two viruses, Lily mottle virus (LMoV, genus Potyvirus) and Lily symptomless virus (LSV, genus Carlavirus) were detected, purified and completely sequenced from a mixed infection in a plant raised from bulbs imported from the Netherlands. The sequence of LMoV was 9644 nt long and encoded a polyprotein of 3095 amino acids with a calculated M(r) of 351.0 kDa that had only 45.1-54.4% identity to other completely sequenced potyviruses. Phylogenetic analysis of the complete polyproteins of members of the genus demonstrated that LMoV was distantly grouped with LYSV, BYMV and ClYVV. Two partial LMoV sequences from different cultivars were identical to one another and very similar (98.3% identical nucleotides) to the corresponding region of the complete sequence. Analysis of the coat protein sequences of LMoV isolates revealed two subgroups, corresponding to the earlier "Tulip breaking virus lily strain" and "Tulip band breaking virus" isolates. Our newly-determined isolates showed an extremely close relationship to the first of these. The LSV sequence was 8393 nucleotides long and had the typical carlavirus genome organization. The ORF1 protein was most closely related to that of Blueberry scorch virus (57.2% identical amino acids). Sequences of 1796 nt at the 3'-end of three additional LSV isolates from different cultivars were very similar (>98% identical nucleotides) to the corresponding region of the complete sequence. This is the first report of complete sequences for LMoV and LSV.
A potyvirus isolated from Pinellia ternata in China was characterised and shown to be related to Soybean mosaic virus (SMV). The virus was pathogenic on P. ternata and some soybean cultivars, whereas the local soybean SMV isolate HH5 did not infect P. ternata. Western blot experiments demonstrated a serological relationship between the virus from Pinellia, SMV and Watermelon mosaic virus (WMV). The complete nucleotide sequences of the Pinellia virus (isolate P-1, 9735 nt) and of the Chinese soybean SMV isolates HH5 (9585 nt) and HZ (9588 nt) were determined. A 1733 nt sequence at the 3'-terminus of a second isolate from Pinellia (isolate P-2) was also determined. The predicted polyprotein of isolate P-1 has 83% amino acid (aa) identity with those of published SMV sequences. In many parts of the genome, aa identity was about 90% but it was much lower in the P1 protein region (24-29%), where it more closely resembled Dasheen mosaic virus (62%). The partial sequence of isolate P-2 had 91% nt identity to P-1 and both isolates resembled a recent sequence in the public databases (AF469171) wrongly named Zantedeschia mosaic virus. The two complete SMV soybean sequences had 93-95% nt identity with those of the previously sequenced isolates and >97% amino acid identity. Phylogenetic analysis and comparisons of coat proteins suggest that the Pinellia, WMV and SMV potyviruses should probably be treated as strains of the same species.
The '6K1' protein of the Pinellia isolate of Soybean mosaic virus was cloned into a prokaryotic expression vector and a polyclonal antiserum raised to the expressed fusion protein. In immunogold labeling of thin sections of infected leaves of Pinellia ternata, specific labeling occurred at the cell periphery. This might suggest that the potyvirus '6K1' protein plays some role in viral cell-to-cell movement but the lack of transmembrane domains suggests that it does not conform to currently-recognized patterns of viral movement proteins.
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