The archaeon Sulfolobus solfataricus expresses large amounts of a small basic protein, Sso7d, which was previously identified as a DNA-binding protein possibly involved in compaction of DNA. We have determined the solution structure of Sso7d. The protein consists of a triple-stranded anti-parallel beta-sheet onto which an orthogonal double-stranded beta-sheet is packed. This topology is very similar to that found in eukaryotic Src homology-3 (SH3) domains. Sso7d binds strongly (Kd < 10 microM) to double-stranded DNA and protects it from thermal denaturation. In addition, we note that epsilon-mono-methylation of lysine side chains of Sso7d is governed by cell growth temperatures, suggesting that methylation is related to the heat-shock response.
The capsule of Bacteroides fragilis is unusual in that it consists of two distinct capsular polysaccharides. Using a combination of high-resolution NMR spectroscopy, theoretical calculations, and as few chemical procedures as required, the structure of both polysaccharide antigens (polysaccharides A and B) was elucidated. Using the above procedures, it was possible to obtain the complete structures using minimal quantities of polysaccharides A and B (8 and 5 mg, respectively). Only small amounts of each subjected to chemical analysis were not recoverable. Polysaccharide A is composed of the following repeating unit: [----3)alpha-D-AATp(1----4)[beta-D-Galf(1----3)]alpha-D- GalpNAc(1----3)beta-D-Galp(1----], where AAT is 2-acetamido-4-amino-2,4,6-trideoxygalactose. A pyruvate substituent having the R configuration spans O-4 and O-6 of the beta-D-galactopyranosyl residue. Polysaccharide B is composed of the following repeating unit: [----4)alpha-L-QuipNAc(1----3)beta-D-QuipNAc(1----4)[alpha-L - Fucp(1----2)beta-D-GalpA(1----3)beta-D-GlcpNAc(1----3)]alpha -D-Galp(1----]. A 2-aminoethylphosphonate substituent is situated on O-4 of the N-acetyl-beta-D-glucopyranosyl residue.
A 58-amino acid polypeptide containing the functional core region, the x1 core, of the major transactivation domain of the human glucocorticoid receptor has been expressed in Escherichia coli and purified to homogeneity. The polypeptide retains 60-701% ofthe activity ofthe intact domain when assayed in vivo or in vitro. This report describes a structural characterization of the T1 core peptide fragment. Circular dichroism spectroscopy shows that the T1 core and a larger fragment encompassing the intact Tl domain are largely unstructured in water solution under a variety of pH conditions. The T1 core, however, acquires a significant a-helical structure when analyzed in the presence of trifluoroethanol, an agent that favors secondary structure formation in regions that have propensity for a-helical conformation.Two-and three-dimensional NMR spectroscopy of 1-N-labeled T1 core, in the presence of trifluoroethanol, has allowed sequential assignment of 'H and 15N resonances and identification of three protein segments with a-helical character.
The immunological properties of the group B meningococcal alpha(2-8)-linked sialic acid polysaccharide have been rationalized in terms of a model where the random coil nature of the polymer can be described by the presence of local helices. The conformational versatility of the alpha NeuAc(2-8)alpha NeuAc linkage has been explored by NMR studies at 600 MHz in conjunction with potential energy calculations for colominic acid, an alpha(2-8)NeuAc polymer, and the trisaccharide alpha NeuAc(2-8)alpha NeuAc(2-8)beta NeuAc. Potential energy calculations were used to estimate the energetically favorable conformers and to describe the wide range of helices which the polymer can adopt. No unique conformer was found to satisfy all NMR constraints, and only ensemble averaged nuclear Overhauser enhancements could correctly simulate the experimental data. Conformational differences between the polymer and the trisaccharide could be best explained in terms of slight changes in the relative distribution of conformers in solution. Similar helical parameters for the alpha(2-8)NeuAc polymer and poly(A) were proposed as the basis for their cross-reactivity to a monoclonal antibody IgMNOV. The unusual length dependency for binding of oligosaccharide to group B specific antibodies was postulated to arise from the recognition of a high-order local helix with an extended conformation which was not highly populated in solution.
Many biochemical processes, including DNA packing, maintenance and control, rely on non-sequence specific protein-DNA interactions. Nonspecific DNA-binding proteins have evolved to tolerate a wide range of DNA sequences, yet bind with a respectable affinity. The nonspecific binding requirement is in contrast to that imposed on, for example, transcription factors and implies a different structural basis for the biomolecular recognition process. To address this issue, and the mechanism for archaeal DNA packing, we determined the structure of the Sso7d protein from Sulfolobus solfataricus in complex with DNA. Sso7d binds DNA by placing a triple-stranded beta-sheet across the DNA minor groove. The protein is anchored in this position by the insertion of hydrogen bond-donating side chains into the groove and additionally stabilized by electrostatic and non-polar interactions with the DNA backbone. This structure explains how strong binding can be achieved independent of DNA sequence. Sso7d binding also distorts the DNA conformation and introduces significant unwinding of the helix. This effect suggests a mechanism for DNA packing in Sulfolobus based on negative DNA supercoiling.
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