A novel zinc-binding fold in the helicase interaction domain of the Bacillus subtilis DnaI helicase loader

The helicase loader protein DnaI (the Bacillus subtilis homologue of Escherichia coli DnaC) is required to load the hexameric helicase DnaC (the B. subtilis homologue of E. coli DnaB) onto DNA at the start of replication. While the C-terminal domain of DnaI belongs to the structurally well-characterized AAA+ family of ATPases, the structure of the N-terminal domain, DnaI-N, has no homology to a known structure. Three-dimensional structure determination by nuclear magnetic resonance (NMR) spectroscopy shows that DnaI presents a novel fold containing a structurally important zinc ion. Surface plasmon resonance experiments indicate that DnaI-N is largely responsible for binding of DnaI to the hexameric helicase from B. stearothermophilus, which is a close homologue of the corresponding much less stable B. subtilis helicase

Biosynthetically directed 2 H labelling for stereospecific resonance assignments of glycine methylene groups

Stereospecific resonance assignments of the α-protons of glycine are often difficult to obtain by measurements of scalar coupling constants or nuclear Overhauser effects. Here we show that these stereospecific resonance assignments can readily be obtain

Glutarate and N-acetyl-L-glutamate buffers for cell-free synthesis of selectively 15N-labelled proteins

Cell-free protein synthesis provides rapid and economical access to selectively N-labelled proteins, greatly facilitating the assignment of N-HSQC spectra. While the best yields are usually obtained with buffers containing high concentrations of potassium L-glutamate, preparation of selectively N-Glu labelled samples requires non-standard conditions. Among many compounds tested to replace the L-Glu buffer, potassium N-acetyl-L-glutamate and potassium glutarate were found to perform best, delivering high yields for all proteins tested, with preserved selectivity of N- Glu labelling. Assessment of amino-transferase activity by combinatorial N-labelling revealed that glutarate and N-acetyl-L-glutamate suppress the transfer of the N- α-amino groups between amino acids less well than the conventional L-Glu buffer. On balance, the glutarate buffer appears most suitable for the preparation of samples containing N-L-Glu while the conventional L-Glu buffer is advantageous for all other samples

[Ln(DPA) 3 ] 3- is a convenient paramagnetic shift reagent for protein NMR studies

(Chemical Equation Presented) Paramagnetic lanthanide ions present outstanding tools for structural biology by NMR spectroscopy. Here we show that the 3:1 complexes between dipicolinic acid and lanthanides are paramagnetic reagents which can site-specifically bind to a wide range of proteins without formation of a covalent bond. The observed pseudocontact shifts can be interpreted by a single magnetic susceptibility anisotropy tensor, enabling its use for structure refinements. The resonance assignment of the paramagnetic spectrum is greatly facilitated by the rapid exchange between bound and free protein, leading to gradual chemical shift changes as the protein is titrated with the paramagnetic dipicolinic acid complex. The association with the paramagnetic lanthanide leads to weak molecular alignment in a magnetic field so that the reagents can be used for the measurement of residual dipolar couplings without the need of protein modification or anisotropic alignment media. The protein samples can be recovered by simple dialysis

Glutarate and N -acetyl-L-glutamate buffers for cell-free synthesis of selectively 15 N-labelled proteins

Cell-free protein synthesis provides rapid and economical access to selectively 15N-labelled proteins, greatly facilitating the assignment of 15N-HSQC spectra. While the best yields are usually obtained with buffers containing high concentrations of potassium L-glutamate, preparation of selectively 15N-Glu labelled samples requires non-standard conditions. Among many compounds tested to replace the L-Glu buffer, potassium N-acetyl-L-glutamate and potassium glutarate were found to perform best, delivering high yields for all proteins tested, with preserved selectivity of 15N- Glu labelling. Assessment of amino-transferase activity by combinatorial 15N-labelling revealed that glutarate and N-acetyl-L-glutamate suppress the transfer of the 15N- α-amino groups between amino acids less well than the conventional L-Glu buffer. On balance, the glutarate buffer appears most suitable for the preparation of samples containing 15N-L-Glu while the conventional L-Glu buffer is advantageous for all other samples

High-yield cell-free protein synthesis for site-specific incorporation of unnatural amino acids at two sites

Using aminoacyl-tRNA synthetase/suppressor tRNA pairs derived from Methanocaldococcus jannaschii, an Escherichia coli cell-free protein production system affords proteins with site-specifically incorporated unnatural amino acids (UAAs) in high yields through the use of optimized amber suppressor tRNACUA opt and optimization of reagent concentrations. The efficiency of the cell-free system allows the incorporation of trifluoromethyl-phenylalanine using a polyspecific synthetase evolved previously for p-cyanophenylalanine, and the incorporation of UAAs at two different sites of the same protein without any re-engineering of the E. coli cells used to make the cell-free extract

The dengue virus NS2B-NS3 protease retains the closed conformation in the complex with BPTI

The C-terminal β-hairpin of NS2B (NS2Bc) in the dengue virus NS2B-NS3 protease is required for full enzymatic activity. In crystal structures without inhibitor and in the complex with bovine pancreatic trypsin inhibitor (BPTI), NS2Bc is displaced from t

Multiple-site labeling of proteins with unnatural amino acids

A cell-free protein synthesis system from which the release factor RF1 has been selectively removed enables the facile incorporation of unnatural amino acids into proteins at difficult and multiple sites by optimized use of orthogonal tRNA/aminoacyl-tRN