The role of quarternary structure in fluorescent protein stability

The stability of fluorescent proteins (FPs) is of great importance for their use as reporters in studies of gene expression, protein dynamics and localization in cell. A comparative analysis of conformational stability of fluorescent proteins, having different association state was done. The list of studied proteins includes EGFP (monomer of green fluorescent protein, GFP), zFP506 (tetramer GFP), mRFP1 and "dimer2" (monomer and dimmer of red fluorescent protein), DsRed1 (red tetramer). The character of fluorescence intensity changes induced by guanidine hydrochloride (GdnHCl) of these proteins differs significantly. Green tetramer zFP506 has been shown to be more stable than green monomer EGFP, red dimmer "dimer2" has been shown to be less stable than red tetramer DsRed1, while red monomer mRFP1 has been shown to be practically as stable as tetramer DsRedl. It is concluded that the quaternary structure, being an important stabilizing factor, does not represent the only circumstance dictating the dramatic variations between fluorescent proteins in their conformational stability.     

Stability of the glycerol facilitator in detergent solutions

Understanding membrane protein folding and stability is required for a molecular explanation of function and for the development of interventions in membrane protein folding diseases. Stable aqueous detergent solutions of the Escherichia coli glycerol facilitator in its native oligomeric state have been difficult to prepare as the protein readily unfolds and forms nonspecific aggregates. Here, we report a study of the structure and stability of the glycerol facilitator in several detergent solutions by Blue Native and sodium dodecyl sulfate (SDS)-polyacrylamide gel electrophoresis (PAGE), circular dichroism (CD), and fluorescence. Protein tetramers were prepared in neutral dodecyl maltoside (DDM) and in zwitterionic lysomyristoylphosphatidylcholine (LMPC) detergent solutions that are stable during SDS-PAGE. Thermal unfolding experiments show that the protein is more stable in LMPC than in DDM. Tertiary structure unfolds before quaternary and some secondary structure in LMPC, whereas unfolding is more cooperative in DDM. The high stability of the protein in DDM is evident from the unfolding half-life of 8 days in 8 M urea, suggesting that hydrophobic interactions contribute to the stability. The protein unfolds readily in LMPC below pH 6, whereas the tetramer remains intact at pH 4 in DDM. At pH 4 in DDM, the protein is more sensitive than at neutral pH to unfolding by SDS and the effect is reversible. At pH 3 in DDM, the tetramer unfolds, losing its tertiary structure but retaining native helical structure which melts at significantly lower temperatures than in the native tetramer. The glycerol facilitator prepared in SDS is mainly monomeric and has ~10% less alpha-helix than the native protein. CD suggests that it forms a condensed structure with non-native tertiary contacts highly similar to the state observed in LMPC at low pH. The implications of the results for in vitro and in vivo folding of the protein are discussed.     

Crystal structure of T state aspartate carbamoyltransferase of the hyperthermophilic archaeon Sulfolobus acidocaldarius

Aspartate carbamoyltransferase (ATCase) is a model enzyme for understanding allosteric effects. The dodecameric complex exists in two main states (T and R) that differ substantially in their quaternary structure and their affinity for various ligands. Many hypotheses have resulted from the structure of the Escherichia coli ATCase, but so far other crystal structures to test these have been lacking. Here, we present the tertiary and quaternary structure of the T state ATCase of the hyperthermophilic archaeon Sulfolobus acidocaldarius (SaATC(T)), determined by X-ray crystallography to 2.6A resolution. The quaternary structure differs from the E.coli ATCase, by having altered interfaces between the catalytic (C) and regulatory (R) subunits, and the presence of a novel C1-R2 type interface. Conformational differences in the 240 s loop region of the C chain and the C-terminal region of the R chain affect intersubunit and interdomain interfaces implicated previously in the allosteric behavior of E.coli ATCase. The allosteric-zinc binding domain interface is strengthened at the expense of a weakened R1-C4 type interface. The increased hydrophobicity of the C1-R1 type interface may stabilize the quaternary structure. Catalytic trimers of the S.acidocaldarius ATCase are unstable due to a drastic weakening of the C1-C2 interface. The hyperthermophilic ATCase presents an interesting example of how an allosteric enzyme can adapt to higher temperatures. The structural rearrangement of this thermophilic ATCase may well promote its thermal stability at the expense of changes in the allosteric behavior.     

Destabilization of the Homotetrameric Assembly of 3-Deoxy-d-Arabino-Heptulosonate-7-Phosphate Synthase from the Hyperthermophile Pyrococcus furiosus Enhances Enzymatic Activity

Many proteins adopt homomeric quaternary structures to support their biological function, including the first enzyme of the shikimate pathway that is ultimately responsible for the biosynthesis of the aromatic amino acids in plants and microorganisms. This enzyme, 3-deoxy-d-arabino-heptulosonate-7-phosphate synthase (DAH7PS), adopts a variety of different quaternary structures depending on the organism in which it is found. The DAH7PS from the hyperthermophilic archaebacterium Pyrococcus furiosus was previously shown to be tetrameric in its crystalline form, and this quaternary association is confirmed in an improved structure in a different crystal system. This tetramer is also present in solution as revealed by small-angle X-ray scattering and analytical ultracentrifugation. This homotetrameric form has two distinct interfaces, both of which bury over 10% each of the surface area of a single monomer. Substitution of Ile for Asp in the hydrophobic region of one interface gives a protein with a remarkable 4-fold higher maximum catalytic rate than the wild-type enzyme. Analytical ultracentrifugation at pH 7.5 reveals that the tetrameric form is destabilized; although the protein crystallizes as a tetramer, equilibrium exists between tetrameric and dimeric forms with a dissociation constant of 22 μM. Thus, under the conditions of kinetic assay, the enzyme is primarily dimeric, revealing that the dimeric form is a fully functional catalyst. However, in comparison to the wild-type protein, the thermal stability of the dimeric protein is significantly compromised. Thus, an unusual compromise of enzymatic activity versus stability is observed for this DAH7PS from an organism that favors a hyperthermophilic environment.     

The pathway by which the tetrameric protein transthyretin dissociates

The homotetrameric protein transthyretin (TTR) must undergo rate-limiting dissociation to its constituent monomers in order to enable partial denaturation that allows the process of amyloidogenesis associated with human pathology to ensue. The TTR quaternary structure contains two distinct dimer interfaces, one of which creates the two binding sites for the natural ligand thyroxine. Tetramer dissociation could proceed through three distinct pathways; scission into dimers along either of the two unique quaternary interfaces followed by dimer dissociation represents two possibilities. Alternatively, the tetramer could lose monomers sequentially. To elucidate the TTR dissociation pathway, we employed two different TTR constructs, each featuring covalent attachment of proximal subunits. We demonstrate that tethering the A and B subunits of TTR with a disulfide bond (as well as the symmetrically disposed C and D subunits) allows urea-mediated dissociation of the resulting (TTR-S-S-TTR)(2) construct, affording (TTR-S-S-TTR)(1) retaining a stable 16-stranded beta-sheet structure that is equivalent to the dimer not possessing a thyroid binding site. In contrast, linking the A and C subunits employing a peptide tether (TTR-L-TTR)(2) affords a kinetically stable quaternary structure that does not dissociate or denature in urea. Both tethered constructs and wild-type TTR exhibit analogous stability based on guanidine hydrochloride denaturation curves. The latter denaturant can denature the tetramer, unlike urea, which can only denature monomeric TTR; hence urea requires dissociation to monomers to function. Under native conditions, the (TTR-S-S-TTR)(2) construct is able to dissociate and incorporate subunits from labeled WT TTR homotetramers at a rate equivalent to that exhibited by WT TTR. In contrast, the (TTR-L-TTR)(2) construct is unable to exchange any subunits, even after 180 h. All of the data presented herein and elsewhere demonstrate that the pathway of TTR tetramer dissociation occurs by scission of the tetramer along the crystallographic C(2) axis affording AB and CD dimers that rapidly dissociate into monomers. Determination of the mechanism of dissociation provides an explanation for why small molecules that bind at the AB/CD dimer-dimer interface impose kinetic stabilization upon TTR and disease-associated variants thereof.     

"Zn-link": a metal-sharing interface that organizes the quaternary structure and catalytic site of the endoribonuclease, RNase E

Ribonuclease E is an essential hydrolytic endonuclease in Escherichia coli, and it plays a central role in maintaining the balance and composition of the messenger RNA population. The enzyme is also required for rRNA and tRNA processing. We have shown earlier that the highly conserved catalytic domain of E. coli RNase E is a homotetramer [Callaghan, A. J. et al. (2003) Biochemistry 42, 13848-13855]. Here, we report that this quaternary organization requires zinc. Two protomers share a single zinc ion, and quantitative analysis indicates that each protein contributes two cysteine thiols toward the coordination of the metal. The candidate cysteines are part of a motif that is conserved in the RNase E protein family, and mutation of these residues causes the partial loss of zinc, the complete disruption of the tetramer into dimers, and effective catalytic inactivation. However, these mutations do not affect RNA binding. The tetramer can be artificially maintained by disulfide bond formation, which fully displaces the zinc but largely preserves the catalytic activity. Thus, catalytic activity does not require zinc directly but does require the quaternary structure, for which the metal is essential. We propose that the RNase E tetramer has two nonequivalent subunit interfaces, one of which is mediated by a single, tetrathiol-zinc complex, which we refer to as a "Zn-link" motif. One or both interfaces organize the active site, which is distinct from the primary site of RNA binding.     

Structure and conformational stability of a tetrameric thermostable N‐succinylamino acid racemase

The N‐succinylamino acid racemases (NSAAR) belong to the enolase superfamily and they are large homooctameric/hexameric species that require a divalent metal ion for activity. We describe the structure and stability of NSAAR from Geobacillus kaustophilus (GkNSAAR) in the absence and in the presence of Co²⁺ by using hydrodynamic and spectroscopic techniques. The Co²⁺, among other assayed divalent ions, provides the maximal enzymatic activity at physiological pH. The protein seems to be a tetramer with a rather elongated shape, as shown by AU experiments; this is further supported by the modeled structure, which keeps intact the largest tetrameric oligomerization interfaces observed in other homooctameric members of the family, but it does not maintain the octameric oligomerization interfaces. The native functional structure is mainly formed by α‐helix, as suggested by FTIR and CD deconvoluted spectra, with similar percentages of structure to those observed in other protomers of the enolase superfamily. At low pH, the protein populates a molten‐globule‐like conformation. The GdmCl denaturation occurs through a monomeric intermediate, and thermal denaturation experiments indicate a high thermostability. The presence of the cofactor Co²⁺ did alter slightly the secondary structure, but it did not modify substantially the stability of the protein. Thus, GkNSAAR is one of the few members of the enolase family whose conformational propensities and stability have been extensively characterized. © 2009 Wiley Periodicals, Inc. Biopolymers 91: 757–772, 2009. This article was originally published online as an accepted preprint. The “Published Online” date corresponds to the preprint version. You can request a copy of the preprint by emailing the Biopolymers editorial office at biopolymers@wiley.com     

Biophysical Characterization of the Dimer and Tetramer Interface Interactions of the Human Cytosolic Malic Enzyme

The cytosolic NADP⁺-dependent malic enzyme (c-NADP-ME) has a dimer-dimer quaternary structure in which the dimer interface associates more tightly than the tetramer interface. In this study, the urea-induced unfolding process of the c-NADP-ME interface mutants was monitored using fluorescence and circular dichroism spectroscopy, analytical ultracentrifugation and enzyme activities. Here, we demonstrate the differential protein stability between dimer and tetramer interface interactions of human c-NADP-ME. Our data clearly demonstrate that the protein stability of c-NADP-ME is affected predominantly by disruptions at the dimer interface rather than at the tetramer interface. First, during thermal stability experiments, the melting temperatures of the wild-type and tetramer interface mutants are 8–10°C higher than those of the dimer interface mutants. Second, during urea denaturation experiments, the thermodynamic parameters of the wild-type and tetramer interface mutants are almost identical. However, for the dimer interface mutants, the first transition of the urea unfolding curves shift towards a lower urea concentration, and the unfolding intermediate exist at a lower urea concentration. Third, for tetrameric WT c-NADP-ME, the enzyme is first dissociated from a tetramer to dimers before the 2 M urea treatment, and the dimers then dissociated into monomers before the 2.5 M urea treatment. With a dimeric tetramer interface mutant (H142A/D568A), the dimer completely dissociated into monomers after a 2.5 M urea treatment, while for a dimeric dimer interface mutant (H51A/D90A), the dimer completely dissociated into monomers after a 1.5 M urea treatment, indicating that the interactions of c-NADP-ME at the dimer interface are truly stronger than at the tetramer interface. Thus, this study provides a reasonable explanation for why malic enzymes need to assemble as a dimer of dimers.     

Characterization of monomeric dihydrodipicolinate synthase variant reveals the importance of substrate binding in optimizing oligomerization

To gain insights into the role of quaternary structure in the TIM-barrel family of enzymes, we introduced mutations to the DHDPS enzyme of Thermotoga maritima, which we have previously shown to be a stable tetramer in solution. These mutations were aimed at reducing the number of salt bridges at one of the two tetramerization interface of the enzyme, which contains many more interactions than the well characterized equivalent interface of the mesophilic Escherichia coli DHDPS enzyme. The resulting variants had altered quaternary structure, as shown by analytical ultracentrifugation, gel filtration liquid chromatography, and small angle X-ray scattering, and X-ray crystallographic studies confirmed that one variant existed as an independent monomer, but with few changes to the secondary and tertiary structure. Reduction of higher order assembly resulted in a loss of thermal stability, as measured by a variety of methods, and impaired catalytic function. Binding of pyruvate increased the oligomeric status of the variants, with a concomitant increase in thermal stability, suggesting a role for substrate binding in optimizing stable, higher order structures. The results of this work show that the salt bridges located at the tetramerization interface of DHDPS play a significant role in maintaining higher order structures, and demonstrate the importance of quaternary structure in determining protein stability and in the optimization of enzyme catalysis.     

NMR studies on the monomer–tetramer transition of melittin in an aqueous solution at high and low temperatures

Melittin, a peptide of 26 amino acid residues, has been used as a model peptide for protein folding and unfolding, and extensive research has been done into its structure and conformational stability. Circular dichroism (CD) studies have demonstrated that melittin in an aqueous solution undergoes a transition from a helical tetramer to a random coil monomer not only by heating but also by cooling from room temperature (i.e., heat- and cold-denaturation, respectively). The heat-denaturation has been also examined by nuclear magnetic resonance (NMR) experiments, however, no NMR data have been presented on the cold-denaturation. In this paper, using proton ((1)H) NMR spectroscopy, we show that melittin undergoes conformational transitions from the monomer to the tetramer to the monomer by elevating temperature from 2 to 70 °C. Only melittin including a trans proline peptide bond participates in the transitions, whereas melittin including a cis proline one does not. The tetramer has maximum conformation stability at around 20 °C, and cooperativity of the heat-denaturation is extremely low.     

Energetics of quasiequivalence: computational analysis of protein-protein interactions in icosahedral viruses.

Quaternary structure polymorphism found in quasiequivalent virus capsids provides a static framework for studying the dynamics of protein interactions. The same protein subunits are found in different structural environments within these particles, and in some cases, the molecular switching required for the polymorphic quaternary interactions is obvious from high-resolution crystallographic studies. Employing atomic resolution structures, molecular mechanics, and continuum electrostatic methods, we have computed association energies for unique subunit interfaces of three icosahedral viruses, black beetle virus, southern bean virus, and human rhinovirus 14. To quantify the chemical determinants of quasiequivalence, the energetic contributions of individual residues forming quasiequivalent interfaces were calculated and compared. The potential significance of the differences in stabilities at quasiequivalent interfaces was then explored with the combinatorial assembly approach. The analysis shows that the unique association energies computed for each virus serve as a sensitive basis set that may determine distinct intermediates and pathways of virus capsid assembly. The pathways for the quasiequivalent viruses displayed isoenergetic oligomers at specific points, suggesting that these may determine the quaternary structure polymorphism required for the assembly of a quasiequivalent particle.     

Chemical shift mapping of γδ resolvase dimer and activated tetramer: Mechanistic implications for DNA strand exchange

Several static structural models exist for γδ resolvase, a self-coded DNA recombinase of the γδ transposon. While these reports are invaluable to formulation of a mechanistic hypothesis for DNA strand exchange, several questions remain. Foremost among them concerns the protomer structural dynamics within the protein/DNA synaptosome. Solution NMR chemical shift assignments have been made for truncated variants of the natural wild-type dimer, which is inactive without the full synaptosome structure, and a mutationally activated tetramer. Of the 134 residues, backbone ¹H, ¹⁵N, and ¹³Cα assignments are made for 121–124 residues in the dimer, but only 76–80 residues of the tetramer. These assignment differences are interpreted by comparison to X-ray diffraction models of the recombinase dimer and tetramer. Inspection of intramolecular and intermolecular structural variation between these models suggests a correspondence between sequence regions at subunit interfaces unique to tetramer, and the regions that can be sequentially assigned in the dimer but not the tetramer. The loss of sequential context for assignment is suggestive of stochastic fluctuation between structural states involving protomer–protomer interactions exclusive to the activated tetrameric state, and may be indicative of dynamics which pertain to the recombinase mechanism.     

Change in the crystal packing of soybean beta-amylase mutants substituted at a few surface amino acid residues

In spite of the high similarity of amino acid sequence and three-dimensional structure between soybean beta-amylase (SBA) and sweet potato beta-amylase (SPB), their quaternary structure is quite different, being a monomer in SBA and a tetramer in SPB. Because most of the differences in amino acid sequences are found in the surface region, we tested the tetramerization of SBA by examining mutations of residues located at the surface. We designed the SBA tetramer using the SPB tetramer structure as a model and calculating the change of accessible surface area (DeltaASA) for each residue in order to select sites for the mutation. Two different mutant genes encoding SB3 (D374Y/L481R/P487D) and SB4 (K462S added to SB3), were constructed for expression in Escherichia coli and the recombinant proteins were purified. They existed as a monomer in solution, but gave completely different crystals from the native SBA. The asymmetric unit of the mutants contains four molecules, while that of native SBA contains one. The interactions of the created interfaces revealed that there were more intermolecular interactions in the SB3 than in the SB4 tetramer. The substituted charged residues on the surface are involved in interactions with adjacent molecules in a different way, forming a new crystal packing pattern.     

Amadori rearrangement potential of hemoglobin at its glycation sites is dependent on the three-dimensional structure of protein.

The site selectivity of nonenzymic glycation of proteins has been suggested to be a consequence of the Amadori rearrangement activity of the protein at the respective glycation sites [Acharya, A. S., Roy, R. P., & Dorai, B. (1991) J. Protein Chem. 10, 345-358]. The catalytic activity that determines the potential of a site for nonenzymic glycation is the propensity of its microenvironment to isomerize the protein bound aldose (aldimine) to a protein bound ketose (ketoamine). The catalytic power of the microenvironment of the glycation sites could be endowed to them either by the amino acid sequence (nearest-neighbor linear effects) or by the higher order structure (tertiary/quarternary) of the protein (nearest-neighbor three-dimensional effect). In an attempt to resolve between these two structural concepts, the glycation potential of Val-1(alpha) and Lys-16(alpha), the residues of hemoglobin A exhibiting the least and the highest isomerization activity in the tetramer, respectively, has been compared in the segment alpha 1-30, isolated alpha-chain, and the tetramer. When alpha-chain is used as the substrate for the nonenzymic glycation, the influence of the quaternary structure of the tetramer will be absent. Similarly, the contribution of the tertiary and quaternary structure of the protein will be absent when alpha 1-30 is used as the substrate. The microenvironment of Lys-16(alpha) exhibited hardly any Amadori rearrangement activity in the segment alpha 1-30. The tertiary structure of the alpha-chain induces a considerable degree of catalytic activity to the microenvironment of Lys-16(alpha) to isomerize the aldimine adduct at this site.(ABSTRACT TRUNCATED AT 250 WORDS)     

Thermodynamic analysis of the dissociation of the aldolase tetramer substituted at one or both of the subunit interfaces

The fructose-1,6-bis(phosphate) aldolase isologous tetramer tightly associates through two different subunit interfaces defined by its 222 symmetry. Both single- and double-interfacial mutant aldolases have a destabilized quaternary structure, but there is little effect on the catalytic activity. These enzymes are however thermolabile. This study demonstrates the temperature-dependent dissociation of the mutant enzymes and determines the dissociation free energies of both mutant and native aldolase. Subunit dissociation is measured by sedimentation equilibrium in the analytical ultracentrifuge. At 25 degrees C the tetramer-dimer dissociation constants for each single-mutant enzyme are similar, about 10(-6) M. For the double-mutant enzyme, sedimentation velocity experiments on sucrose density gradients support a tetramer-monomer equilibrium. Furthermore, sedimentation equilibrium experiments determined a dissociation constant of 10(-15) M3 for the double-mutant enzyme. By the same methods the upper limit for the dissociation constant of wild-type aldolase A is approximately 10(-28) M3, which indicates an extremely stable tetramer. The thermodynamic values describing monomer-tetramer and dimer-tetramer equilibria are analyzed with regard to possible cooperative interaction between the two subunit interfaces.     

Compromise and accommodation in ecotin, a dimeric macromolecular inhibitor of serine proteases

Ecotin is a dimeric serine protease inhibitor from Escherichia coli which binds proteases to form a hetero-tetramer with three distinct interfaces: an ecotin-ecotin dimer interface, a larger primary ecotin-protease interface, and a smaller secondary ecotin-protease interface. The contributions of these interfaces to binding and inhibition are unequal. To investigate the contribution and adaptability of each interface, we have solved the structure of two mutant ecotin-trypsin complexes and compared them to the structure of the previously determined wild-type ecotin-trypsin complex. Wild-type ecotin has an affinity of 1 nM for trypsin, while the optimized mutant, ecotin Y69F, D70P, which was found using phage display technologies, inhibits rat trypsin with a K(i) value of 0.08 nM. Ecotin 67-70A, M84R which has four alanine substitutions in the ecotin-trypsin secondary binding site, along with the M84R mutation at the primary site, has a K(i) value against rat trypsin of 0.2 nM. The structure of the ecotin Y69F, D70P-trypsin complex shows minor structural changes in the ecotin-trypsin tetramer. The structure of the ecotin 67-70A, M84R mutant bound to trypsin shows large deviations in the tertiary and quaternary structure of the complex. The trypsin structure shows no significant changes, but the conformation of several loop regions of ecotin are altered, resulting in the secondary site releasing its hold on trypsin. The structure of several regions previously considered to be rigid is also significantly modified. The inherent flexibility of ecotin allows it to accommodate these mutations and still maintain tight binding through the compromises of the protein-protein interfaces in the ecotin-trypsin tetramer. A comparison with two recently described ecotin-like genes from other bacteria suggests that these structural and functional features are conserved in otherwise distant bacterial lineages.     

Thermal stability and mode of oligomerization of the tetrameric peanut agglutinin: a differential scanning calorimetry study

Peanut agglutinin is a homotetrameric legume lectin. The crystal structure of peanut agglutinin shows that the four subunits associate in an unusual manner, giving rise to open quaternary structure [Banarjee, R., et al. (1994) Proc. Natl. Acad. Sci. U.S.A. 91, 227-231]. The thermal unfolding of peanut agglutinin has been characterized by differential scanning calorimetry and gel filtration to elucidate its thermal stability and its mode of oligomerization. The unfolding process is reversible and could be described by a three-state model with two transitions occurring at around 331 and 336 K. For the tetramer, the ratio of DeltaHc/DeltaHv for the first transition is close to 4 and for the second transition is close to 0.25, suggesting that 4 and 0.25 cooperative unit(s) of the tetramer are involved in the first and second transitions, respectively. The agreement between the model-independent DeltaHv(S) determined from the values of the temperatures of the peak maximum (Tp1) with the protein concentration with the values of DeltaHv obtained from the fit of the data to the transition confirms that the first peak is associated with the dissociation of peanut agglutinin tetramers (A4) to "folded" monomers (4A), whereas the second peak describes the unfolding (4U) of these monomers. The overall process for the thermal unfolding of peanut agglutinin could therefore be summarized as A4 <==> 4A <==> 4U. Gel filtration studies confirm this process, as peanut agglutinin elutes as a tetramer up to 50 degrees C, and at and above 56 degrees C (Tm of first transition), it elutes at a position commensurate with that of the folded monomer of peanut agglutinin. The unfolding behavior of peanut agglutinin in the presence of saturating amounts of carbohydrate ligands is similar to that observed for the unligated form. The temperature of maximal stability of the peanut agglutinin tetramer at pH 7.4 is calculated to be around 33 degrees C with a maximal free energy of stabilization of 8.70 kcal/mol. The results demonstrate that unfolding of peanut agglutinin goes through two distinct phases with folded monomer being the intermediate.     

Structural and dynamic requirements for optimal activity of the essential bacterial enzyme dihydrodipicolinate synthase

Dihydrodipicolinate synthase (DHDPS) is an essential enzyme involved in the lysine biosynthesis pathway. DHDPS from E. coli is a homotetramer consisting of a 'dimer of dimers', with the catalytic residues found at the tight-dimer interface. Crystallographic and biophysical evidence suggest that the dimers associate to stabilise the active site configuration, and mutation of a central dimer-dimer interface residue destabilises the tetramer, thus increasing the flexibility and reducing catalytic efficiency and substrate specificity. This has led to the hypothesis that the tetramer evolved to optimise the dynamics within the tight-dimer. In order to gain insights into DHDPS flexibility and its relationship to quaternary structure and function, we performed comparative Molecular Dynamics simulation studies of native tetrameric and dimeric forms of DHDPS from E. coli and also the native dimeric form from methicillin-resistant Staphylococcus aureus (MRSA). These reveal a striking contrast between the dynamics of tetrameric and dimeric forms. Whereas the E. coli DHDPS tetramer is relatively rigid, both the E. coli and MRSA DHDPS dimers display high flexibility, resulting in monomer reorientation within the dimer and increased flexibility at the tight-dimer interface. The mutant E. coli DHDPS dimer exhibits disorder within its active site with deformation of critical catalytic residues and removal of key hydrogen bonds that render it inactive, whereas the similarly flexible MRSA DHDPS dimer maintains its catalytic geometry and is thus fully functional. Our data support the hypothesis that in both bacterial species optimal activity is achieved by fine tuning protein dynamics in different ways: E. coli DHDPS buttresses together two dimers, whereas MRSA dampens the motion using an extended tight-dimer interface.     

Partial denaturation of transthyretin is sufficient for amyloid fibril formation in vitro.

Amyloid diseases are caused by the self-assembly of a given protein into an insoluble cross-beta-sheet quaternary structural form which is pathogenic. An understanding of the biochemical mechanism of amyloid fibril formation should prove useful in understanding amyloid disease. Toward this end, a procedure for the conversion of the amyloidogenic protein transthyretin into amyloid fibrils under conditions which mimic the acidic environment of a lysosome has been developed. Association of a structured transthyretin denaturation intermediate is sufficient for amyloid fibril formation in vitro. The rate of fibril formation is pH dependent with significant rates being observed at pHs accessible within the lysosome (3.6-4.8). Far-UV CD spectroscopic studies suggest that transthyretin retains its secondary structural features at pHs where fibrils are formed. Near-UV CD studies demonstrate that transthyretin has retained the majority of its tertiary structure during fibril formation as well. Near-UV CD analysis in combination with glutaraldehyde cross-linking studies suggests that a pH-mediated tetramer to monomer transition is operative in the pH range where fibril formation occurs. The rate of fibril formation decreases markedly at pHs below pH 3.6, consistent with denaturation to a monomeric TTR intermediate which has lost its native tertiary structure and capability to form fibrils. It is difficult to specify with certainty which quaternary structural form of transthyretin is the amyloidogenic intermediate at this time. These difficulties arise because the maximal rate of fibril formation occurs at pH 3.6 where tetramer, traces of dimer, and significant amounts of monomer are observed.(ABSTRACT TRUNCATED AT 250 WORDS)