Aspartase/fumarase superfamily: a common catalytic strategy involving general base-catalyzed formation of a highly stabilized aci-carboxylate intermediate.

Members of the aspartase/fumarase superfamily share a common tertiary and quaternary fold, as well as a similar active site architecture; the superfamily includes aspartase, fumarase, argininosuccinate lyase, adenylosuccinate lyase, δ-crystallin, and 3-carboxy-cis,cis-muconate lactonizing enzyme (CMLE). These enzymes all process succinyl-containing substrates, leading to the formation of fumarate as the common product (except for the CMLE-catalyzed reaction, which results in the formation of a lactone). In the past few years, X-ray crystallographic analysis of several superfamily members in complex with substrate, product, or substrate analogues has provided detailed insights into their substrate binding modes and catalytic mechanisms. This structural work, combined with earlier mechanistic studies, revealed that members of the aspartase/fumarase superfamily use a common catalytic strategy, which involves general base-catalyzed formation of a stabilized aci-carboxylate (or enediolate) intermediate and the participation of a highly flexible loop, containing the signature sequence GSSxxPxKxN (named the SS loop), in substrate binding and catalysis.

Delta-crystallin enhancer binding factor 1 controls the epithelial to mesenchymal transition phenotype and resistance to the epidermal growth factor receptor inhibitor erlotinib in human head and neck squamous cell carcinoma lines.

PURPOSE: Although the epidermal growth factor receptor (EGFR) is overexpressed in a majority of head and neck squamous cell carcinomas (HNSCC), only a minority of patients derive substantial clinical benefit from EGFR inhibitors. We initiated the present study to identify the mechanisms underlying erlotinib resistance in a panel of HNSCC cell lines. METHODS: We used [(3)H]thymidine incorporation to characterize the heterogeneity of responsiveness to erlotinib-mediated growth inhibition in a panel of 27 human HNSCC cells. We characterized the molecular mechanisms involved in resistance using a representative subset of six erlotinib-sensitive and erlotinib-resistant HNSCC lines. RESULTS: Erlotinib had heterogeneous effects on DNA synthesis in HNSCC cells that correlated closely with molecular markers of epithelial to mesenchymal transition (EMT). Specifically, the drug-sensitive lines expressed high levels of E-cadherin and showed limited invasion and migration capabilities. In contrast, the erlotinib-resistant HNSCC lines expressed high levels of the E-cadherin repressor delta-crystallin enhancer binding factor 1 (deltaEF1; Zeb-1) and other mesenchymal markers and low levels of E-cadherin, and they were highly invasive and migratory. Small interfering RNA-mediated knockdown of deltaEF1 in the erlotinib-resistant cell lines (1386LN and UMSCC1) resulted in up-regulation of E-cadherin and increased sensitivity to erlotinib in an E-cadherin-dependent manner. CONCLUSIONS: DeltaEF1 controls the mesenchymal phenotype and drives erlotinib resistance in HNSCC cells. E-cadherin and deltaEF1 may prove to be useful markers in predicting EGFR inhibitor responsiveness.

The interaction of Glu294 at the subunit interface is important for the activity and stability of goose delta-crystallin.

PURPOSE: delta-Crystallin is a soluble structural protein in found in avian eye lenses; it shares high amino acid sequence identity with argininosuccinate lyase. E294 is the only residue located at the double dimer interface and it performs hydrogen bonding with the active site residues of H160 and K323 in the neighboring and diagonal subunits, respectively. H160 is reported to play an important role in catalysis due to its H-bond interaction with the fumarate moiety of the substrate. In order to clarify the function of E294 in either stabilization of the quaternary structure or in catalysis, we carried out site-directed mutagenesis and functional analysis. METHODS: The structure of both wild-type and mutant proteins were analyzed by circular dichroism (CD) spectroscopy, fluorescence spectra, and analytical ultracentrifugation. Structural stability was measured by CD and tryptophan fluorescence. A modeled structure of the E294L mutant was built and optimized with energy minimization. RESULTS: No gross structural changes were observed when E294 was substituted with leucine, as judged by circular dichroism, tryptophan fluorescence, ANS fluorescence, and sedimentation velocity analyses. However, this mutant enzyme had only about 10% of the activity of a wild-type enzyme and its secondary structure was more easily denatured by increased temperature than that of a wild-type enzyme. The mutant protein also underwent its first unfolding transition at a lower concentration of guanidinium-hydrochloride than the wild-type protein. CONCLUSIONS: These results indicate that the interactions offered by E294 in the dimer-dimer interface of delta-crystallin are required to maintain the hydrogen bonding network in the active site for catalysis. Disruption of the interaction had no significant effect on the conformation and quaternary structure of delta-crystallin but it did lead to instability in the double dimer structure.

The effect of N-terminal truncation on double-dimer assembly of goose delta-crystallin.

Delta-crystallin is a soluble structural protein in avian eye lenses that confers special refractive properties. In the presence of GdmCl (guanidinium chloride), tetrameric delta-crystallin undergoes dissociation via a dimeric state to a monomeric molten globule intermediate state. The latter are denatured at higher GdmCl concentrations in a multi-state manner. In the present study, the X-ray structure of goose delta-crystallin was determined to 2.8 A (1 A=0.1 nm). In this structure the first 25 N-terminal residues interact with a hydrophobic cavity in a neighbouring molecule, stabilizing the quaternary structure of this protein. When these 25 residues were deleted this did not produce any gross structural changes, as judged by CD analysis, but slightly altered tryptophan fluorescence and ANS (8-anilino-1-naphthalenesulphonic acid) spectra. The dimeric form was significantly identified as judged by sedimentation velocity and nondenaturing gradient gel electrophoresis. This mutant had increased sensitivity to temperature denaturation and GdmCl concentrations of 0.3-1.0 M. This protein was destabilized about 3.3 kcal/mol (1 kcal=4.184 kJ) due to N-terminal truncation. After incubation at 37 degrees C N-terminal truncated proteins were prone to aggregation, suggesting the presence of the unstable dimeric conformation. An important role for the N-terminus in dimer assembly of goose delta-crystallin is proposed.

Lys-315 at the Interfaces of Diagonal Subunits of δ-Crystallin Plays a Critical Role in the Reversibility of Folding and Subunit Assembly.

δ-Crystallin is the major structural protein in avian eye lenses and is homologous to the urea cycle enzyme argininosuccinate lyase. This protein is structurally assembled as double dimers. Lys-315 is the only residue which is arranged symmetrically at the diagonal subunit interfaces to interact with each other. This study found that wild-type protein had both dimers and monomers present in 2-4 M urea whilst only monomers of the K315A mutant were observed under the same conditions, as judged by sedimentation velocity analysis. The assembly of monomeric K315A mutant was reversible in contrast to wild-type protein. Molecular dynamics simulations showed that the dissociation of primary dimers is prior to the diagonal dimers in wild-type protein. These results suggest the critical role of Lys-315 in stabilization of the diagonal dimer structure. Guanidinium hydrochloride (GdmCl) denatured wild-type or K315A mutant protein did not fold into functional protein. However, the urea dissociated monomers of K315A mutant protein in GdmCl were reversible folding through a multiple steps mechanism as measured by tryptophan and ANS fluorescence. Two partly unfolded intermediates were detected in the pathway. Refolding of the intermediates resulted in a conformation with greater amounts of hydrophobic regions exposed which was prone to the formation of protein aggregates. The formation of aggregates was not prevented by the addition of α-crystallin. These results highlight that the conformational status of the monomers is critical for determining whether reversible oligomerization or aggregate formation occurs.

Structural studies of duck delta2 crystallin mutants provide insight into the role of Thr161 and the 280s loop in catalysis.

Delta crystallin, a taxon-specific crystallin present in avian eye lenses, is homologous to the urea cycle enzyme ASL (argininosuccinate lyase). Although there are two delta crystallin isoforms in duck lenses, ddeltac1 (duck delta1 crystallin) and ddeltac2 (duck delta2 crystallin), only ddeltac2 is catalytically active. Previous structural studies have suggested that residues Ser283 and His162 in the multi-subunit active site of ddeltac2/ASL are the putative catalytic acid/base, while the highly conserved, positively charged Lys289 is thought to help stabilize the carbanion intermediate. The strict conservation of a small hydroxy-containing residue (Thr or Ser) at position 161 adjacent to the putative catalytic base, as well as its proximity to the substrate in the S283A ddeltac2 enzyme-substrate complex, prompted us to investigate further the role this residue. Structures of the active T161S and inactive T161D ddeltac2 mutants, as well as T161D complexed with argininosuccinate, have been determined to 2.0 A resolution. The structures suggest that a hydroxy group is required at position 161 to help correctly position the side chain of Lys289 and the fumarate moiety of the substrate. Threonine is probably favoured over serine, because the interaction of its methyl group with Leu206 would restrict its conformational flexibility. Residues larger than Thr or Ser interfere with substrate binding, supporting previous suggestions that correct positioning of the substrate's fumarate moiety is essential for catalysis to occur. The presence of the 280s loop (i.e. a loop formed by residues 270-290) in the 'open' conformation suggests that loop closure, thought to be essential for sequestration of the substrate, may be triggered by the formation of the carbanion or aci-carboxylate intermediates, whose charge distribution more closely mimics that of the sulphate ion found in the active-site region of the inactive ddeltac1. The 280s loop in ddeltac1 is in the closed conformation.

Distinct interactions of αA-crystallin with homologous substrate proteins, δ-crystallin and argininosuccinate lyase, under thermal stress.

δ-Crystallin is a taxon-specific eye lens protein that was recruited from argininosuccinate lyase (ASL) through gene sharing. ASL is a metabolic enzyme that catalyzes the reversible conversion of argininosuccinate into arginine and fumarate and shares about 70% sequence identity and similar overall topology with δ-crystallin. ASL has a lower thermal stability than δ-crystallin. In this study, we show that the small heat shock protein, αA-crystallin, functions as a molecular chaperone, and enhanced thermal stability of both δ-crystallin and ASL. The stoichiometry for efficient protection of the two substrate proteins by αA-crystallin was determined by slowly increasing the temperature. N- or C-terminal truncated mutants of δ-crystallin co-incubated with αA-crystallin showed higher thermal stability than wild-type enzyme, and the stoichiometry for efficient protection was the same. Thermal unfolding of δ-crystallin or ASL in the presence of αA-crystallin followed a similar three-state model, as determined by circular dichroism analyses. A stable intermediate which retained about 30% α-helical structure was observed. Protection from thermal denaturation by αA-crystallin was by interaction with partly unfolded ASL or δ-crystallin to form high molecular weight heteroligomers, as judged by size-exclusive chromatography and SDS-PAGE analyses. Aggregate formation of ASL was significantly reduced in the presence of αA-crystallin. The extent of protection of ASL and δ-crystallin at different ratios of αA-crystallin were described by hyperbolic and sigmoidal curves, respectively. These results suggest the preferential recognition of partly unfolded ASL by αA-crystallin. In contrast, unstable δ-crystallin might trigger a cooperative interaction by higher stoichiometries of αA-crystallin leading to fuller protection. The different interactions of αA-crystallin with the two homologous but functionally different substrate proteins show its behavior as a chaperone is variable.

Substitution of residues at the double dimer interface affects the stability and oligomerization of goose delta-crystallin.

Delta-crystallin is the major structural protein in avian and reptilian eye lenses, and confers special refractive properties. The protein is a homotetramer arranged as a dimer of dimers. In the present study, the roles of the side chains of Glu267, Lys315, and Glu327, which provide hydrogen bonds at the double dimer interface, were investigated. Hydrophobic side chain substitution led to all mutant proteins having an unstable dimer interface. The E267L/E327L mutant had the greatest sensitivity to temperature, urea and guanidinium hydrochloride denaturation, and the most extensive exposure of hydrophobic patches, as judged by 1-anilinonaphthalene-8-sulfonic acid fluorescence, CD, and tryptophan fluorescence. In contrast, the E267L/K315L/E327L mutant showed higher stability than the E267L/E327L mutant. Some level of the dissociated dimeric form was observed in the K315L mutant, but it was not observed for the K315A and E267L/K315L mutants. The E327L mutant was partially in the dissociated dimeric form, whereas the E267/E327L mutant was predominantly dissociated into dimers. In contrast, the triple mutant of E267L/K315L/E327L retained a tetrameric structure. In the presence of urea, a stable monomeric intermediate with higher stability than the wild type was identified for the K315A mutant. Disruption of interfacial interactions at Glu267 led to polymerization of partly unfolded intermediates in the presence of 3 m urea. However, these polymeric forms were not observed with combinations of the E267L mutation with other mutations. These results indicate that these hydrogen bonds, which are present at different contact surfaces in the dimer-dimer interface, perform distinct functions in double dimer assembly. The coordination of these interactions is critical for the stability and tetramer formation of delta-crystallin.

Kinetic refolding barrier of guanidinium chloride denatured goose delta-crystallin leads to regular aggregate formation.

Delta-crystallin is the major soluble protein in avian eye lenses with a structural role in light scattering. Dissociation and unfolding of the tetrameric protein in guanidinium chloride (GdmCl) can be sensitively monitored by the intrinsic tryptophan fluorescence. In this study refolding of GdmCl-denatured delta-crystallin was investigated. A marked hysteresis was observed while refolding by dilution of the 5 M GdmCl-denatured delta-crystallin. The secondary structure of the refolded protein was largely restored. However, monitoring intrinsic fluorescence of single tryptophan mutants indicated that the microenvironment of domain 1 (W74) was not restored. The region containing W169, which is close to the dimer interface, remained exposed following refolding. During refolding of the wild-type protein, dimeric, tetrameric, and aggregate forms were identified. The ratio of tetramer to dimer increased with time, as judged by gel-filtration chromatography and nondenaturing gel electrophoresis. However the observed levels of tetramer did not return to the same levels as observed before GdmCl treatment. The proportion of tetramer was significantly decreased in the N-25 deletion mutant and it did not increase with time. These results suggest that there is a kinetic barrier for assembly of dimers into tetramers. The consequence of this is that dimers refold to form aggregates. Aggregation seems to follow a nucleation mechanism with an apparent reaction order of 4.7+/-0.2, suggesting four or five monomers constitute the core structure of nucleus, which propagate to form high molecular weight aggregates. Addition of alpha-crystallin during refolding prevents aggregation. Thioflavin T and Congo red assays indicated a regular structure for the protein aggregates, which appear as hollow tubules packed into helical bundles. Aggregate formation was protein concentration dependent that progressed via two stages with rate constants of 0.0039+/-0.0006 and 0.00043+/-0.00003 s(-1), respectively. We propose that the N-terminal segment of delta-crystallin plays a critical role in proper double dimer assembly and also in the assembly of nucleus to aggregate formation.

Recovery of argininosuccinate lyase activity in duck delta1 crystallin.

Delta-crystallin, the major soluble protein component in the avian eye lens, is homologous to argininosuccinate lyase (ASL). Two delta-crystallin isoforms exist in ducks, delta1- and delta2-crystallin, which are 94% identical in amino acid sequence. While duck delta2-crystallin (ddeltac2) has maintained ASL activity, evolution has rendered duck delta1-crystallin (ddeltac1) enzymatically inactive. Previous attempts to regenerate ASL activity in ddeltac1 by mutating the residues in the 20s (residues 22-31) and 70s (residues 74-89) loops to those found in ddeltac2 resulted in a double loop mutant (DLM) which was enzymatically inactive (Tsai, M. et al. (2004) Biochemistry 43, 11672-82). This result suggested that one or more of the remaining five amino acid substitutions in domain 1 of the DLM contributes to the loss of ASL activity in ddeltac1. In the current study, residues Met-9, Val-14, Ala-41, Ile-43, and Glu-115 were targeted for mutagenesis, either alone or in combination, to the residues found in ddeltac2. ASL activity was recovered in the DLM by changing Met-9 to Trp, and this activity is further potentiated in the DLM-M9W mutant when Glu-115 is changed to Asp. The roles of Trp-9 and Asp-115 were further investigated by site-directed mutagenesis in wild-type ddeltac2. Changing the identity of either Trp-9 or Asp-115 in ddeltac2 resulted in a dramatic drop in enzymatic activity. The loss of activity in Trp-9 mutants indicates a preference for an aromatic residue at this position. Truncation mutants of ddeltac2 in which the first 8, 9, or 14 N-terminal residues were removed displayed either decreased or no ASL activity, suggesting residues 1-14 are crucial for enzymatic activity in ddeltac2. Our kinetic studies combined with available structural data suggest that the N-terminal arm in ASL/delta2-crystallin is involved in stabilizing regions of the protein involved in substrate binding and catalysis, and in completely sequestering the substrate from the solvent.

Disruption of a salt bridge dramatically accelerates subunit exchange in duck delta2 crystallin.

Intragenic complementation is a unique property of oligomeric enzymes with which to study subunit-subunit interactions. Complementation occurs when different subunits, each possessing distinct mutations that render the individual homomutant proteins inactive, interact to form a heteromutant protein with partial recovery of activity. In this paper, complementation events between human argininosuccinate lyase (ASL) and its homolog, duck delta2 crystallin, were characterized. Different active site mutants in delta2 crystallin complement by the regeneration of native-like active sites as reported previously for ASL. The complementarity of the ASL and delta2 crystallin subunit interfaces was illustrated by the in vivo formation of active hybrid tetramers from inactive ASL and inactive delta2 crystallin mutants. Subunits of both ASL and delta2 crystallin do not dissociate and reassociate in vitro at room temperature, even after 6 days of incubation, indicating that the multimerization interface is very strong. However, disruption of a salt bridge network in the tetrameric interface of delta2 crystallin caused a drastic acceleration of subunit dissociation. Double mutants combining these interface mutants with active site mutants of delta2 crystallin were able to dissociate and reassociate to form active tetramers in vitro within hours. These results suggest that exchange of subunits may occur without unfolding of the monomer. Intragenic complementation in these interface mutants occurs by reintroducing the native salt bridge interaction upon hetero-oligomerization. Our studies demonstrate the value of intragenic complementation as a tool for investigating subunit-subunit interactions in oligomeric proteins.

Monomeric molten globule intermediate involved in the equilibrium unfolding of tetrameric duck delta2-crystallin.

Duck delta2-crystallin is a soluble tetrameric lens protein. In the presence of guanidinium hydrochloride (GdnHCl), it undergoes stepwise dissociation and unfolding. Gel-filtration chromatography and sedimentation velocity analysis has demonstrated the dissociation of the tetramer protein to a monomeric intermediate with a dissociation constant of 0.34 microM3. Dimers were also detected during the dissociation and refolding processes. The sharp enhancement of 1-anilinonaphthalene-8-sulfonic acid (ANS) fluorescence at 1 M GdnHCl strongly suggested that the dissociated monomers were in a molten globule state under these conditions. The similar binding affinity (approximately 60 microM) of ANS to protein in the presence or absence of GdnHCl suggested the potential assembly of crystallins via hydrophobic interactions, which might also produce off-pathway aggregates in higher protein concentrations. The dynamic quenching constant corresponding to GdnHCl concentration followed a multistate unfolding model implying that the solvent accessibility of tryptophans was a sensitive probe for analyzing delta2-crystallin unfolding.

A duck delta1 crystallin double loop mutant provides insight into residues important for argininosuccinate lyase activity.

Delta-crystallin is directly related to argininosuccinate lyase (ASL), and catalyzes the reversible hydrolysis of argininosuccinate to arginine and fumarate. Two delta-crystallin isoforms exist in duck lenses, delta1 and delta2, which are 94% identical in amino acid sequence. Although the sequences of duck delta2-crystallin (ddeltac2) and duck delta1-crystallin (ddeltac1) are 69 and 71% identical to that of human ASL, respectively, only ddeltac2 has maintained ASL activity. Domain exchange experiments and comparisons of various delta-crystallin structures have suggested that the amino acid substitutions in the 20's (residues 22-31) and 70's (residues 74-89) loops of ddeltac1 are responsible for the loss of enzyme activity in this isoform. To test this hypothesis, a double loop mutant (DLM) of ddeltac1 was constructed in which all the residues that differ between the two isoforms in the 20's and 70's loops were mutated to those of ddeltac2. Contrary to expectations, kinetic analysis of the DLM found that it was enzymatically inactive. Furthermore, binding of argininosuccinate by the DLM, as well as the ddeltac1, could not be detected by isothermal titration calorimetry (ITC). To examine the conformation of the 20's and 70's loops in the DLM, and to understand why the DLM is unable to bind the substrate, its structure was determined to 2.5 A resolution. Comparison of this structure with both wild-type ddeltac1 and ddeltac2 structures reveals that the conformations of the 20's and 70's loops in the DLM mutant are very similar to those of ddeltac2. This suggests that the five amino acid substitutions in domain 1 which lie outside of the two loop regions and which are different in the DLM, and ddeltac2, must be important enzymatically. The structure of the DLM in complex with sulfate was also determined to 2.2 A resolution. This structure demonstrates that the conformational changes of the 280's loop and domain 3, previously observed in ddeltac1, also occur in the DLM upon sulfate binding, reinforcing the hypothesis that these events may occur in the active ddeltac2 protein during catalysis.