Eukaryotic ssDNA viruses encode a rolling-circle replication (RCR) initiation protein, Rep, which binds to iterated DNA elements functioning as essential elements for virus-specific replication. By using the iterons of all known circoviruses, nanoviruses and nanovirus-like satellites as heuristic devices, we have identified certain amino acid residues that presumably determine the DNA-binding specificity of their Rep proteins. These putative "specificity determinants" (SPDs) cluster in two discrete protein regions, which are adjacent to distinct conserved motifs. A comparable distribution of SPDs was uncovered in the Rep protein of geminiviruses. Modeling of the tertiary structure of diverse Rep proteins showed that SPD regions interact to form a small beta-sheet element that has been proposed to be critical for high-affinity DNA-binding of Rep. Our findings indicate that eukaryotic circular ssDNA viruses have a common ancestor and suggest that SPDs present in replication initiators from a huge variety of viral and plasmid RCR systems are associated with the same conserved motifs.
We study the folding of small proteins inside confining potentials. Proteins are described using an effective potential model that contains the Ramachandran angles as degrees of freedom and does not need any a priori information about the native state. Hydrogen bonds, dipole-dipole-, and hydrophobic interactions are taken explicitly into account. An interesting feature displayed by this potential is the presence of metastable intermediates between the unfolded and native states. We consider different types of confining potentials to describe proteins folding inside cages with repulsive or attractive walls. Using the Wang-Landau algorithm, we determine the density of states and analyze in detail the thermodynamical properties of the confined proteins for different sizes of the cages. We show that confinement dramatically reduces the phase space available to the protein and that the presence of intermediate states can be controlled by varying the properties of the confining potential. Cages with strongly attractive walls destabilize the intermediate states and lead to a two-state folding into a configuration that is less stable than the native structure. However, cages with slightly attractive walls enhance the stability of native structure and induce a folding process, which occurs through intermediate configurations.
A tospovirus was identified in tomato plants from two counties in Florida by reverse transcription-PCR and sequencing of portions of the S, M and L genomic segments. The predicted amino-acid sequences of the N protein of PCR products from four plant samples were >96% identical to those of TCSV. Partial nucleic acid sequences of the L and M RNA were >97% identical to those reported for TCSV isolates. Extracts from field samples infected test plants and produced symptoms similar to those reported for TCSV. This is the first report of an isolate of TCSV in Florida and in the USA.
The complete genome of a variant of the multi-segmented (+) RNA virus blueberry necrotic ring blotch virus (BNRBV), which has not been assigned to a genus, was obtained from foliar red lesions on southern highbush blueberries grown in Alachua Co., Florida. The genome organization of this variant, BNRBV-RL, is the same as that of BNRBV: four genomic segments and seven ORFs (one ORF on each of RNA 1, RNA 2, and RNA 4 and as many as four ORFs on RNA 3). BLAST analysis revealed nucleic acid sequence identities of 89 %, 90 %, 90 % and 86 % to BNRBV RNA 1, RNA 2, RNA 3 and RNA 4, respectively. Phylogenetic analysis of the amino acid sequence of the putative RdRp domain indicated that BNRBV-RL was closely related to BNRBV and less related to citrus leprosis virus type C and three other mite-transmitted viruses. The nucleotide and amino acid sequence differences between BNRBV-RL and BNRBV combined with differences in symptom expression in blueberry would suggest that BNRBV-RL is a strain of BNRBV.
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