High yield fermentation and purification of Tendamistat disulphide analogues secreted by Streptomyces lividans

The high resolution NMR structure of parvulustat (Z-2685) from Streptomyces parvulus FH-1641: comparison with tendamistat from Streptomyces tendae 4158

The protein parvulustat (Z-2685) from Streptomyces parvulus comprises 78 amino acids and functions as a highly efficient alpha-amylase inhibitor. Parvulustat shares 29.6 % overall amino acid sequence identity to the well-known alpha-amylase inhibitor tendamistat. Among the conserved residues are the two disulfide bridges (C9-C25, C43-C70) and the active-site motif (W16, R17, Y18). Here, we report the high-resolution NMR structure of parvulustat based on NOEs, J couplings, chemical shifts and hydrogen-exchange data. In addition, we studied the dynamical properties of parvulustat by heteronuclear relaxation measurements. We compare the structure of parvulustat with the structure of tendamistat in terms of secondary structure elements, charges and hydrophobicity. The overall structural composition is very similar, but there are distinct differences including the active-site region. These structural and dynamical differences indicate that for parvulustat an induced-fit mechanism for binding to alpha-amylase might take place, since the structure of tendamistat does not change upon binding to alpha-amylase.

Shape of the Free Energy Barriers for Protein Folding Probed by Multiple Perturbation Analysis

The characterization of the free energy barriers has been a major goal in studies on the mechanism of protein folding. Testing the effect of mutations or denaturants on protein folding reactions revealed that transition state movement is rare, suggesting that folding barriers are robust and narrow maxima on the free energy landscape. Here we demonstrate that the application of multiple perturbations allows the observation of small transition state movements that escape detection in single perturbation experiments. We used tendamistat as a model protein to test the broadness of the free energy barriers. Tendamistat folds over two consecutive transition states and through a high-energy intermediate. Measuring the combined effect of temperature and denaturant on the position of the transition state in the wild-type protein and in several mutants revealed that the early transition state shows significant transition state movement. Its accessible surface area state becomes more native-like with destabilization of the native state by temperature. To the same extent, the entropy of the early transition state becomes more native-like with increasing denaturant concentration, in accordance with Hammond behavior. The position of the late transition state, in contrast, is much less sensitive to the applied perturbations. These results suggest that the barriers in protein folding become increasingly narrow as the folding polypeptide chain approaches the native state.

Kinetic mechanism and catalysis of a native-state prolyl isomerization reaction

Folding of tendamistat is a rapid two-state process for the majority of the unfolded molecules. In fluorescence-monitored refolding kinetics about 8% of the unfolded molecules fold slowly (lambda=0.083s(-1)), limited by peptidyl-prolyl cis-trans isomerization. This is significantly less than expected from the presence of three trans prolyl-peptide bonds in the native state. In interrupted refolding experiments we detected an additional very slow folding reaction (lambda=0.008s(-1) at pH 2) with an amplitude of about 12%. This reaction is caused by the interconversion of a highly structured intermediate to native tendamistat. The intermediate has essentially native spectroscopic properties and about 2% of it remain populated in equilibrium after folding is complete. Catalysis by human cyclophilin 18 identifies this very slow reaction as a prolyl isomerization reaction. This shows that prolyl-isomerases are able to efficiently catalyze native state isomerization reactions, which allows them to influence biologically important regulatory conformational transitions. Folding kinetics of the proline variants P7A, P9A, P50A and P7A/P9A show that the very slow reaction is due to isomerization of the Glu6-Pro7 and Ala8-Pro9 peptide bonds, which are located in a region that makes strong backbone and side-chain interactions to both beta-sheets. In the P50A variant the very slow isomerization reaction is still present but native state heterogeneity is not observed any more, indicating a long-range destabilizing effect on the alternative native state relative to N. These results enable us to include all prolyl and non-prolyl peptide bond isomerization reactions in the folding mechanism of tendamistat and to characterize the kinetic mechanism and the energetics of a native-state prolyl isomerization reaction.

Apparent two-state tendamistat folding is a sequential process along a defined route

The small all-beta-sheet protein tendamistat folds and unfolds rapidly in apparent two-state reactions. Kinetic measurements of two tendamistat variants under various solvent conditions reveal, however, that folding occurs in at least two sequential steps through a metastable obligatory intermediate. Depending on the solvent conditions either step can become rate limiting. The activation parameters indicate that the first step represents an enthalpic barrier whereas the second step is an entropic barrier at 25 degrees C. Our results suggest that initial non-specific collapse precedes formation of native secondary and tertiary structure in tendamistat folding. This points at a distinct route in tendamistat folding and indicates that partially folded metastable intermediates might play an important role in the mechanism of apparent two-state folding.

Structure and dynamic properties of the single disulfide-deficient alpha-amylase inhibitor [C45A/C73A]tendamistat: an NMR study

Covalent linkages such as disulfide bonds are important for the stabilization of proteins. In the present NMR study we compare the structure and the dynamics of the single disulfide-deficient variant C45A/C73A of the alpha-amylase inhibitor tendamistat and the wild-type protein, which contains two disulfide bonds (C11-C27 and C45-C73). Complete proton assignment was achieved by standard homonuclear 2D techniques for the variant. Chemical shift differences, intra-strand NOE effects and protected amide proton were used to compare the connectivity of the secondary structure elements of variant and wild-type. Dynamic properties of the wild-type protein were studied by 13C(alpha) heteronuclear NOE experiments with carbon in natural abundance. 15N isotope labeling was necessary to obtain the relaxation parameters of the variant, because of sample degradation. The 15N resonance assignment was achieved by a 15N 3D-NOESY-HMQC. Removal of the C45-C73 bond by the C45A/C73A mutation has no influence upon the beta-barrel structure of tendamistat beside very local changes at the mutation site. The relaxation data revealed only subtle differences between variant and wild-type on a subnanosecond time scale. Only the N-terminus and G62 in the connecting loop between the anti-parallel beta-sheets showed an increased mobility. The results are discussed in respect to thermodynamic stability and the secretion efficiency of tendamistat.

Characterization of the secA gene of Streptomyces lividans encoding a protein translocase which complements and Escherichia coli mutant defective in the ATPase activity of SecA

The secA gene of Streptomyces lividans was cloned using as probe a 57-mer oligonucleotide based on conserved sequences of the Escherichia coli secA and the Bacillus subtilis div genes. It encodes a protein of 946 amino acids (aa) with a deduced M(r) of 106,079, with high similarity to all known SecA proteins. All the previously described conserved motifs of SecA proteins were conserved in the S. lividans protein. The secA gene of S. lividans restored sensitivity to sodium azide in E. coli SecA4 (AzR) a mutant with an azide-resistant (ATPase defective) SecA protein. However, it did not complement the temperature-sensitive mutation in E. coli MM52 (SecAts) (a conditional lethal mutant defective in protein translocation) allowing only poor growth at the nonpermissive temperature. secA homologous sequences were present in 11 different species of Streptomyces and Nocardia.

Production and secretion of proteins by streptomycetes

Streptomycetes produce a large number of extracellular enzymes as part of their saprophytic mode of life. Their ability to synthesize enzymes as products of their primary metabolism could lead to the production of many proteins of industrial importance. The development of high-yielding expression systems for both homologous and heterologous gene products is of considerable interest. In this article, we review the current knowledge on the various factors that affect the production and secretion of proteins by streptomycetes and try to evaluate the suitability of these bacteria for the large-scale production of proteins of industrial importance.

Efficient secretion of biologically active mouse tumor necrosis factor alpha by Streptomyces lividans

We have studied the production of mouse tumor necrosis factor alpha (mTNF) with Streptomyces lividans as host. mTNF cDNA was fused to the alpha-amylase-encoding gene (aml) of Streptomyces venezuelae ATCC15068 at 12 amino acids (aa) downstream from the signal-peptidase cleavage site so that the aa surrounding this processing site were conserved. S. lividans containing this construct secreted mTNF at moderately high levels (1-10 micrograms/ml) as a biologically active compound of high specific activity (1 x 10(8) units/mg protein). No unprocessed pre-protein and virtually no processed protein could be detected in the cell lysates. N-terminal aa sequence analysis indicated microheterogeneity (-3 to -6 forms) at the N-terminal site of secreted mTNF. It was demonstrated that this microheterogeneity was due to aminopeptidase activity.

The nuclear-magnetic-resonance solution structure of the mutant alpha-amylase inhibitor [R19L] Tendamistat and comparison with wild-type Tendamistat

The recombinant mutant alpha-amylase inhibitor [R19L]Tendamistat, with Arg19 replaced by Leu, was prepared and its NMR solution structure determined. Based on complete sequence-specific 1H-NMR assignments, 845 nuclear Overhauser effect upper-distance constraints and 156 dihedral angle constraints were collected using two-dimensional homonuclear 1H-NMR experiments. The structure was calculated with the program DIANA, using the redundant dihedral angle constraints strategy for improved convergence. For restrained energy minimization, the programs FANTOM and AMBER were used. The wild-type NMR solution structure was similarly recalculated from the previously published input of conformational constraints [Kline, A., Braun, W. & Wüthrich, K. (1988) J. Mol. Biol. 204, 675-724]. For each protein a group of 20 conformers represents a well-defined solution structure, with average root-mean-square-distance values for the backbone atoms of the individual conformers relative to the mean coordinates of 50 pm. The two structures are nearly identical to each other and to the previously published Tendamistat structures in solution and in crystals. The only significant difference is strictly localized near the single amino acid substitution in the presumed active site -Trp18-Arg(Leu)-Tyr-, i.e. Leu19 and Tyr20 are more precisely defined in the solution structure of [R19L]Tendamistat than the corresponding residues Arg19 and Tyr20 in wild-type Tendamistat.

Developments in high cell density and high productivity microbial fermentation

In the past year, new approaches to control high cell density fermentations, molecular strategies coupled with fermentation technology, and updated traditional strategies have been used to overproduce important biological products. The most significant advances include new implementation of control strategies for feeding high cell density fermentations as well as the continued development of alternative Gram-positive bacterial expression systems.

Streptomyces lividans as host for heterologous protein production

Streptomycetes are Gram-positive soil bacteria with a well differentiated morphology. They are considered interesting candidates for the production of heterologous proteins for several reasons, including their efficient secretion mechanism by which the secreted proteins are localized into the culture supernatant. In view of this potential, this review article describes different aspects of gene expression and regulation in Streptomyces, and summarizes and discusses results obtained using Streptomyces lividans as host for secretion of heterologous proteins of prokaryotic and eukaryotic origin.