Arndt Schnuchel scite author profile

The cold-shock domain (CSD) is found in many eukaryotic transcriptional factors and is responsible for the specific binding to DNA of a cis-element called the Y-box. The same domain exists in the sequence of the Xenopus RNA-binding proteins FRG Y1 and FRG Y2 (refs 1, 3). The major cold-shock proteins of Escherichia coli (CS7.4) and B. subtilis (CspB) have sequences that are more than 40 per cent identical to the cold-shock domain. We present here the three-dimensional structure of CspB determined by nuclear magnetic resonance spectroscopy. The 67-residue protein consists of an antiparallel five-stranded beta-barrel with strands connected by turns and loops. The structure resembles that of staphylococcal nuclease and the gene-5 single-stranded-DNA-binding protein. A three-stranded beta-sheet, which contains the conserved RNA-binding motif RNP1 as well as a motif similar to RNP2 in two neighbouring antiparallel beta-strands, has basic and aromatic residues at its surface which could serve as a binding site for single-stranded DNA. CspB binds to single-stranded DNA in gel retardation experiments.

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NMR Structure and Mutagenesis of the N-Terminal Dbl Homology Domain of the Nucleotide Exchange Factor Trio

Liu

Wang

Eberstadt

et al. 1998

Cell

168

162

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Guanine nucleotide exchange factors for the Rho family of GTPases contain a Dbl homology (DH) domain responsible for catalysis and a pleckstrin homology (PH) domain whose function is unknown. Here we describe the solution structure of the N-terminal DH domain of Trio that catalyzes nucleotide exchange for Rac1. The all-alpha-helical protein has a very different structure compared to other exchange factors. Based on site-directed mutagenesis, functionally important residues of the DH domain were identified. They are all highly conserved and reside in close proximity on two a helices. In addition, we have discovered a unique capability of the PH domain to enhance nucleotide exchange in DH domain-containing proteins.

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Mutational analysis of the putative nucleic acid‐binding surface of the cold‐shock domain, CspB, revealed an essential role of aromatic and basic residues in binding of single‐stranded DNA containing the Y‐box motif

Schröder

Graumann

Schnuchel

et al. 1995

Molecular Microbiology

138

163

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The major cold-shock protein of Bacillus subtilis, CspB, is a member of a protein family widespread among prokaryotes and eukaryotes that share the highly conserved cold-shock domain (CSD). The CSD domain is involved in transcriptional and translational regulation and was shown to bind the Y-box motif, a cis-element that contains the core sequence ATTGG, with high affinity. The three-dimensional structure of CspB, a prototype of this protein family, revealed that this hydrophilic CSD domain creates a surface rich in aromatic and basic amino acids that may act as the nucleic acid-binding site. We have analysed the potential role of conserved aromatic and basic residues in nucleic acid binding by site-directed mutagenesis. In gel retardation and ultraviolet cross-linking experiments, the ability of CspB mutants to bind single-stranded oligonucleotides (ssDNA) that contain the Y-box motif was investigated. Single substitutions of three highly conserved phenylalanine residues (Phe-15, Phe-17, Phe-27) by alanine and substitution of one histidine (His-29) by glutamine, all located within the putative RNA-binding sites RNP-1 and RNP-2, abolished the nucleic acid-binding activity of CspB. Conservative substitutions of Phe-15 to tyrosine (F15Y) showed a small increase in binding affinity, whereas separate replacement of Phe-17 and Phe-27 by tyrosine caused a reduction in binding activity. These and other substitutions including the conserved basic residues Lys-7, Lys-13 and Arg-56 as well as the aromatic residues Trp-8 and Phe-30 strongly suggest that CspB uses the side-chains of these amino acids for specific interaction with nucleic acids. Ultraviolet cross-linking experiments for CspB mutants with ssDNA supported the idea of specific CspB/nucleic acid interaction and indicated an essential role for the aromatic and basic residues in this binding. In addition, two-dimensional nuclear magnetic resonance studies with F17A, K13Q, F15Y and F27Y revealed that the mutants have the same overall structure as the wild-type CspB protein.

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Solution structure of an rRNA methyltransferase (ErmAM) that confers macrolide-lincosamide-streptogramin antibiotic resistance

Petros

Schnuchel

et al. 1997

Nat Struct Mol Biol

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The Erm family of methyltransferases is responsible for the development of resistance to the macrolide-lincosamide-streptogramin type B (MLS) antibiotics. These enzymes methylate an adenine of 23S ribosomal RNA that prevents the MLS antibiotics from binding to the ribosome and exhibiting their antibacterial activity. Here we describe the three-dimensional structure of an Erm family member, ErmAM, as determined by NMR spectroscopy. The catalytic domain of ErmAM is structurally similar to that found in other methyltransferases and consists of a seven-stranded beta-sheet flanked by alpha-helices and a small two-stranded beta-sheet. In contrast to the catalytic domain, the substrate binding domain is different from other methyltransferases and adopts a novel fold that consists of four alpha-helices.

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Arndt Schnuchel

Structure in solution of the major cold-shock protein from Bacillus subtilis

NMR Structure and Mutagenesis of the N-Terminal Dbl Homology Domain of the Nucleotide Exchange Factor Trio

Mutational analysis of the putative nucleic acid‐binding surface of the cold‐shock domain, CspB, revealed an essential role of aromatic and basic residues in binding of single‐stranded DNA containing the Y‐box motif

Solution structure of an rRNA methyltransferase (ErmAM) that confers macrolide-lincosamide-streptogramin antibiotic resistance

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