Specificity in legume-Rhizobium symbiosis depends on plant and rhizobial genes. As our objective was to study broad host-range determinants of rhizobia, we sought a legume and a Rhizobium with the lowest possible specificity. By inoculating 12 different legumes with a heterogenous collection of 35 fast-growing rhizobia, we found Rhizobium sp. NGR234 to be the Rhizobium and Vigna unguiculata to be the plant with the lowest specificities. Transfer of cloned fragments of the Sym-plasmid pNGR234a into heterologous rhizobia, screening for extension of host-range of the transconjugants to include V. unguiculata, and restriction mapping of the Hsn- and overlapping clones, proved that there were at least three distinct Hsn-regions (HsnI, II, and III) on pNGR234a. HsnI is located next to nodD, HsnII is linked to nifKDH and HsnIII to nodC. In addition to nodulation of Vigna, HsnI conferred upon the transconjugants the ability to nodulate Glycine max, Macroptilium atropurpureum and Psophocarpus tetragonolobus. All three Hsn-regions, when transferred to the appropriate recipients, induced root-hair-curling on M. atropurpureum. Hsn-region III was able to complement a mutation in the host-range gene nodH of R. meliloti strain 2011. Homology to "nod-box"-sequences could be shown only for the sub-clones containing HsnII and HsnIII, thus suggesting different regulation mechanisms for HsnI and HsnII/III.
We show that overexpression of Sub2p, a multifunctional Saccharomyces cerevisiae helicase family member that is involved in mRNA elongation and transport, also suppresses heterochromatic silencing at telomeres. Genetic assays show cells that overexpress SUB2 from a high copy plasmid exhibit increased survival rates when selecting for a telomere-silenced URA3 reporter. Two temperature-sensitive sub2 mutations that affect different helicase domains were also examined at the permissive temperature; these mutants also overcome silencing of the URA3 reporter. The degree to which silencing is suppressed correlates with SUB2 RNA and protein levels. Additionally, we find that Sub2p localizes to the telomeres, as determined by chromatin immunoprecipitation assays, suggesting that Sub2p has a direct effect at telomeres. Genome-wide analysis of transcripts was used to assess whether Sub2p overproduction affects only the silenced URA3 reporter gene, or whether other subtelomeric genes are also affected. Of the 70 RNA transcripts elevated in the Sub2p overexpressing cells, 28% are encoded by subtelomeric genes that are located within 5 Kbp of a core X or Y repeat. The remainder of the transcripts clustered into several functional groups, including the iron homeostasis pathway, purine nucleotide metabolism, and miscellaneous transport genes, among others. These results suggest a targeted effect of Sub2p on transcription. Our results also confirm that Sub2p affects heterochromatic gene expression, similar to that observed with the Drosophila Hel25E homologue. The above observations imply that Sub2p affects chromatin structure in addition to, or in parallel with, its functions in transcription elongation, splicing and mRNA transport.
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