Evidence that E. coli ribosomal protein S13 has two separable functional domains involved in 16S RNA recognition and protein S19 binding.

We have found that E. coli ribosomal protein S13 recognizes multiple sites on 16S RNA. However, when protein S19 is included with a mixture of proteins S4, S7, S8, S16/S17 and S20, the S13 binds to the complex with measurably greater strength and with a stoichiometry of 1.5 copies per particle. This suggests that the protein may have two functional domains. We have tested this idea by cleaving the protein into two polypeptides. It was found that one of the fragments, composed of amino acid residues 84-117, retained the capacity to bind 16S RNA at multiple sites. Protein S19 had no affect on the strength or stoichiometry of the binding of this fragment. These data suggest that S13 has a C-terminal domain primarily responsible for RNA recognition and possibly that the N-terminal region is important for association with protein S19.     

Rous sarcoma virus direct repeat cis elements exert effects at several points in the virus life cycle.

Two approximately 135-nucleotide (nt) direct repeats flank the Rous sarcoma virus (RSV) oncogene src and are composed of two smaller repeats, dr1 (approximately 100 nt) and dr2 (approximately 36 nt). These sequences have been reported to contain cis-acting signals necessary for RNA packaging and elements that allow cytoplasmic accumulation of unspliced RNA (cytoplasmic transport elements). In this report, we show that avian fibroblasts infected with the Prague A strain of RSV with precise deletions of both dr1 elements express src and are transformed by this mutant virus but production of virus particles is very low and virus spread throughout the culture requires several weeks. We show that the replication defect is due to complex effects on viral RNA transport, viral RNA half-life, and virus particle assembly. The dr1 elements may contain binding sites for a permissive cell-specific factor(s) that facilitates efficient nuclear-cytoplasmic transport, RNA stability, and cytoplasmic utilization of unspliced viral RNA. The implications of these results for understanding the defects of nonpermissive virus infections in mammalian cells are discussed.     

Substantial Metabolic Activity of Human Brown Adipose Tissue during Warm Conditions and Cold-Induced Lipolysis of Local Triglycerides

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Some parameters relevant to affinity chromatography on immobilized nucleotides

1. The suitability of cellulose and Sepharose as supports for affinity chromatography of two groups of cofactor-linked enzymes, dehydrogenases and kinases, was examined. Sepharose was found to be superior. 2. The selective capacities of the columns were measured by frontal analysis and are discussed in relation to the nucleotide contents. 3. The effect of various concentrations of enzyme and of non-specific protein on the performance of the affinity columns, and the effects of equilibration time, flow rate, sample volume and dilution of the nucleotide were examined. 4. The effect of interposing polymethylene and polyglycine extension arms between the matrix backbone and the nucleotide was investigated for several cofactor-dependent enzymes. Maximum binding was observed with an extension arm 0.8-1nm long.     

Anastomosis is required for virulence of the fungal necrotroph Alternaria brassicicola

A fungal mycelium is typically composed of radially extending hyphal filaments interconnected by bridges created through anastomoses. These bridges facilitate the dissemination of nutrients, water, and signaling molecules throughout the colony. In this study, we used targeted gene deletion and nitrate utilization mutants of the cruciferous pathogen Alternaria brassicicola and two closely related species to investigate hyphal fusion (anastomosis) and its role in the ability of fungi to cause disease. All eight of the A. brassicicola isolates tested, as well as A. mimicula and A. japonica, were capable of self-fusion, with two isolates of A. brassicicola being capable of non-self-fusion. Disruption of the anastomosis gene homolog (Aso1) in A. brassicicola resulted in both the loss of self-anastomosis and pathogenicity on cabbage. This finding, combined with our discovery that a previously described nonpathogenic A. brassicicola mutant defective for a mitogen-activated protein kinase gene (amk1) also lacked the capacity for self-anastomosis, suggests that self-anastomosis is associated with pathogenicity in A. brassicicola.     

Similarity queries for temporal toxicogenomic expression profiles

We present an approach for answering similarity queries about gene expression time series that is motivated by the task of characterizing the potential toxicity of various chemicals. Our approach involves two key aspects. First, our method employs a novel alignment algorithm based on time warping. Our time warping algorithm has several advantages over previous approaches. It allows the user to impose fairly strong biases on the form that the alignments can take, and it permits a type of local alignment in which the entirety of only one series has to be aligned. Second, our method employs a relaxed spline interpolation to predict expression responses for unmeasured time points, such that the spline does not necessarily exactly fit every observed point. We evaluate our approach using expression time series from the Edge toxicology database. Our experiments show the value of using spline representations for sparse time series. More significantly, they show that our time warping method provides more accurate alignments and classifications than previous standard alignment methods for time series.     

Labyrinthulomycetes phylogeny and its implications for the evolutionary loss of chloroplasts and gain of ectoplasmic gliding

The labyrinthulomycetes, also known as the 'Labyrinthulomycota' are saprotrophic or less frequently parasitic stramenopilan protists, usually in marine ecosystems. Their distinguishing feature is an 'ectoplasmic net,' an external cytoplasmic network secreted by a specialized organelle that attaches the cell to its substrate and secretes digestive enzymes for absorptive nutrition. In this study, one of our aims was to infer the phylogenetic position of the labyrinthulomycetes relative to the non-photosynthetic bicoeceans and oomycetes and the photosynthetic ochrophytes and thereby evaluate patterns of change from photosynthesis to saprotrophism among the stramenopiles. For the labyrinthulomycetes, we determined sequences of the actin, beta-tubulin, and elongation factor 1-alpha gene fragments and where necessary, ribosomal small subunit (SSU) genes. Multilocus analysis using standard tree construction techniques not only strongly supported the oomycetes as the sister group to the phototrophic stramenopiles, but also, for the first time with moderate statistical support, showed that the labyrinthulomycetes and the bicoecean as sister groups. The paraphyly of the non-photosynthetic groups was consistent with independent loss of photosynthesis in labyrinthulomycetes and oomycetes. We also wished to develop a phylogenetically based hypothesis for the origin of the gliding cell bodies and the ectoplasmic net found in some labyrinthulomycetes. The cells of species in Labyrinthula and Aplanochytrium share a specialized form of motility involving gliding on ectoplasmic tracks. Before our study, only ribosomal DNA genes had been determined for these genera and their phylogenetic position in the labyrinthulomycetes was equivocal. Multilocus phylogenies applying our newly determined protein-coding sequences divided the labyrinthulomycetes between sister clades 'A' and 'B' and showed that the monophyletic group containing all of the gliding species was nested among non-gliding species in clade B. This phylogeny suggested that species that glide via an ectoplasm evolved from species that had used the ectoplasm mainly for anchorage and assimilation rather than motility.