C-terminal effect of Thermoanaerobacter tengcongensis ribosome recycling factor on its activity and conformation changes.

The in vivo activities and conformational changes of ribosome recycling factor from Thermoanaerobacter tengcongensis (TteRRF) with 12 successive C-terminal deletions were compared. The results showed that TteRRF mutants lacking one to four amino acid residues are inactive, those lacking five to nine are reactivated to a similar or a little higher level than wild-type TteRRF, and those lacking ten to twelve are inactivated again gradually. Conformational studies indicated that only the ANS binding fluorescence change is correlated well with the RRF in vivo activity change, while the secondary structure and local structure at the aromatic residues are not changed significantly. Trypsin cleavage site identification and protein stability measurement suggested that mutation only induced subtle conformation change and increased flexibility of the protein. Our results indicated that the ANS-detected local conformation changes of TteRRF and mutants are one verified direct reason of the in vivo inactivation and reactivation in Escherichia coli.

Cooperative unfolding of Escherichia coli ribosome recycling factor originating from its domain-domain interaction and its implication for function.

Cooperative unfolding of Escherichia coli ribosome recycling factor (RRF) and its implication for function were investigated by comparing the in vitro unfolding and the in vivo activity of wild-type E. coli RRF and its temperature-sensitive mutant RRF(V117D). The experiments show that mutation V117D at domain I could perturb the domain II structure as evidenced in the near-UV CD and tyrosine fluorescence spectra though no significant globular conformation change occurred. Both equilibrium unfolding induced by heat or denaturant and kinetic unfolding induced by denaturant obey the two-state transition model, indicating V117D mutation does not perturb the efficient interdomain interaction, which results in cooperative unfolding of the RRF protein. However, the mutation significantly destabilizes the E. coli RRF protein, moving the thermal unfolding transition temperature range from 50-65 to 35-50 degrees C, which spans the non-permissive temperature for the growth of E. coli LJ14 strain (frr(ts)). The in vivo activity assays showed that although V117D mutation results in a temperature sensitive phenotype of E. coli LJ14 strain (frr(ts)), over-expression of mutant RRF(V117D) can eliminate the temperature sensitive phenotype at the non-permissive temperature (42 degrees C). Taking all the results into consideration, it can be suggested that the mechanism of the temperature sensitive phenotype of the E. coli LJ14 cells is due to inactivation of mutant RRF(V117D) caused by unfolding at the non-permissive temperatures.

Domain II plays a crucial role in the function of ribosome recycling factor.

RRF (ribosome recycling factor) consists of two domains, and in concert with EF-G (elongation factor-G), triggers dissociation of the post-termination ribosomal complex. However, the function of the individual domains of RRF remains unclear. To clarify this, two RRF chimaeras, EcoDI/TteDII and TteDI/EcoDII, were created by domain swaps between the proteins from Escherichia coli and Thermoanaerobacter tengcongensis. The ribosome recycling activity of the RRF chimaeras was compared with their wild-type RRFs by using in vivo and in vitro activity assays. Like wild-type TteRRF (T. tengcongensis RRF), the EcoDI/TteDII chimaera is non-functional in E. coli, but both wild-type TteRRF, and EcoDI/TteDII can be activated by coexpression of T. tengcongensis EF-G in E. coli. By contrast, like wild-type E. coli RRF (EcoRRF), TteDI/EcoDII is fully functional in E. coli. These findings suggest that domain II of RRF plays a crucial role in the concerted action of RRF and EF-G for the post-termination complex disassembly, and the specific interaction between RRF and EF-G on ribosomes mainly depends on the interaction between domain II of RRF and EF-G. This study provides direct genetic and biochemical evidence for the function of the individual domains of RRF.

Effect of N-terminal deletions on the foldability, stability, and activity of staphylococcal nuclease.

The effect of N-terminally successive deletions on the foldability, stability, and activity of staphylococcal nuclease was examined. The structural changes in the nuclease caused by the deletions follow a hierarchical pattern: N-terminal truncation of the nuclease by up to nine residues clearly perturbs the conformation of the N-terminal beta-subdomain but does not affect the C-terminal alpha-subdomain; deletion of 11 or 12 residues perturbs the C-terminal alpha-subdomain, resulting in formation of a molten globule state; deletion of 13 residues causes the nuclease to become highly unfolded. N-terminally deleted nuclease delta11 retains the ability to fold but delta12 is not able to fold into an enzymatically active conformation, suggesting that 11 residues is the maximum length that can be deleted from the N-terminus while still retaining the folding competence of the nuclease. Further, the results suggest that proper folding of the C-terminal alpha-subdomain probably relies on the integrity of the N-terminal beta-subdomain.

Expression in Escherichia coli, purification and characterization of Thermoanaerobacter tengcongensis ribosome recycling factor.

A very promising approach to understanding the mechanism of protein thermostability is to investigate the structure-function relationship of homologous proteins with different thermostabilities. Ribosome recycling factor (RRF), which is an essential factor for protein synthesis in bacteria, may be a good candidate for such study. In this report, a ribosome recycling factor from Thermoanaerobacter tengcongensis was expressed and characterized. This protein contains 184 residues, shows 51.4% identity to that of Escherichia coli RRF, and has very strong antigenic cross-reactivity with antibody to E. coli RRF. In vivo activity assay shows that weak residual activity may remain in TteRRF in E. coli cells. Circular dichroism spectral analysis shows that TteRRF has a very similar secondary structure to that of E. coli RRF, implying that they have similar tertiary structures. However, their thermostabilities are significantly different. To find which domain of RRF is mainly responsible for maintaining stability, TteDI/EcoDII and EcoDI/TteDII RRF chimeras were created. Their domain I and domain II are from E. coli and T. tengcongensis RRFs, respectively. The results of GdnHCl and heat induced denaturation of the chimeric RRFs suggest that the domain I plays a major role in maintaining the stability of the RRF molecule.

Probing the subtle conformational state of N138ND2-Q106O hydrogen bonding deletion mutant (Asn138Asp) of staphylococcal nuclease using time of flight mass spectrometry with limited proteolysis.

Recent studies indicate that the N138ND2-Q106O hydrogen bonding deletion in staphylococcal nuclease significantly alters the conformational integrity and stability of the nuclease. To find out the structural basis of the changes, mass spectrometry and limited proteolysis methods were combined to probe the subtle conformational changes in the SNaseN138D mutant and SNaseN138D-Ca2+-pdTp complex. The results reveal that the N138ND2-Q106O hydrogen bonding deletion makes the C-terminal part of alpha-helix 1 and alpha-helix 2 in the C-terminal subdomain of SNaseN138D unfold to some extent, but does not have much effect on the N-terminal part of alpha-helix 1, alpha-helix 3, and the N-terminal beta-barrel subdomain of SNaseN138D. Binding of ligands makes the alpha-helices 1 and 2 more resistant to protease Glu-C attack and converts the partially unfolded state to a native-like state. This study also demonstrates how mass spectrometry can be combined with limited proteolysis to observe conformational changes induced by ligand binding.

The effects of amino acid replacements of glycine 20 on conformational stability and catalysis of staphylococcal nuclease.

Staphylococcal nuclease (SNase) is a well-established model for protein folding studies. Its three-dimensional structure has been determined. The enzyme, Ca2+, and DNA or RNA substrate form a ternary complex. Glycine 20 is the second position of the first beta-turn of SNase, which may serve as the folding initiation site for the SNase polypeptide. To study the role of Gly20 in the conformational stability and catalysis of SNase, three mutants, in which Gly20 was replaced by alanine, valine, or isoleucine, were constructed and studied by using circular dichroism spectra, intrinsic and ANS-binding fluorescence spectra, stability and activity assays. The mutations have little effect on the conformational integrity of the mutants. However, the catalytic activity is reduced drastically by the mutations, and the stability of the protein is progressively decreased in the order G20A

Effect of a specific hydrogen bond (N138ND2-Q106O) on conformational integrity, stability, and activity of staphylococcal nuclease.

There are two hydrogen bonding interactions (N138ND2-Q106O and Y54OH-S141OG) between the C-terminal region and the main body of staphylococcal nuclease (SNase). To examine the role of these hydrogen bonds, SNase(141) and its three mutants, SNase(141)N138D, SNase(141)S141A, and SNase(141)N138D/S141A, were created. The N138D mutation has the N138ND2-Q106O interaction deleted and the S141A mutation has the Y54OH-S141OG and S141OG-N138O interactions deleted. The conformational features, stability, and activity of the proteins have been compared by using circular dichroism, intrinsic and ANS-binding fluorescence, GdnHCl-induced denaturation, and activity assay. The results clearly show that the N138D mutation significantly alters the secondary and tertiary structures of the protein, producing a partially unfolding state; in contrast, the S141A mutation has no such effect on structure. These results strongly suggest that the specific hydrogen bond, N138ND2-Q106O, plays an important role in maintaining the conformational integrity and stability of the nuclease.

A vector with the downstream box of the initiation codon can highly enhance protein expression in Escherichia coli.

An expression vector, pET-DB, with a perfectly matching downstream box of the initiation codon has been constructed on the basis of the pET system. Any gene of interest can then be inserted into the vector. Four genes were used to test the expression efficiency of the vector. The results show that the vector pET-DB can further increase protein expression level at least up to 35-70% as compared with the initial T7 expression system, indicating that the downstream box can enhance protein expression in Escherichia coli.

An efficient fusion expression system for protein and peptide overexpression in Escherichia coli and NMR sample preparation.

An efficient fusion expression system with a small fusion partner, His6-tagged N-terminal fragment of staphylococcal nuclease R, has been constructed and tested with two genes. The results show that the system is not only suitable for overexpression of small proteins and peptides but simplifies purification of target proteins and peptides. The study also provides a practical method for preparation of isotope-labeled protein sample for NMR analysis.

Soluble expression in Escherichia coli, purification and characterization of a human TF-1 cell apoptosis-related protein TFAR19.

A novel human TF-1 cell apoptosis-related protein, TFAR19, cloned from a human leukemia cell line, TF-1, was first overexpressed in Escherichia coli with the sequence Met-Gly-His(6)-Gly-Thr-Asn-Gly, a hexahistidine sequence followed by a hydroxylamine cleavage site attached to its amino terminus. The resulting protein was soluble and single-step purified to homogeneity by metal chelating affinity chromatography. After cleavage of the purified His(6)-tagged TFAR19 sample with hydroxylamine, highly purified untagged TFAR19 protein was then obtained through an FPLC Resource Q column. The structural characteristics and function of the His(6)-tagged and untagged TFAR19 proteins were studied using circular dichroism, intrinsic fluorescence, and ANS-binding fluorescence spectra and apoptosis activity assay. The results show that alpha-helix is the main secondary structure of the proteins and the two forms of TFAR19 protein fold properly, which correspond well to their apoptosis activity expression. The results also indicate that the extra sequence including the His(6)-tag fused to the N-terminus of TFAR19 protein has a minimal effect on its structure and function, suggesting that the His(6)-tagged TFAR19 protein could be further used as an immobilized target for finding potential proteins which interact with TFAR19 from a cDNA library using in vitro ribosome display technique.