Serine proteases and their natural protein inhibitors are among the most intensively studied protein complexes. About 20 structurally diverse inhibitor families have been identified, comprising alpha-helical, beta sheet, and alpha/beta proteins, and different folds of small disulfide-rich proteins. Three different types of inhibitors can be distinguished based on their mechanism of action: canonical (standard mechanism) and non-canonical inhibitors, and serpins. The canonical inhibitors bind to the enzyme through an exposed convex binding loop, which is complementary to the active site of the enzyme. The mechanism of inhibition in this group is always very similar and resembles that of an ideal substrate. The non-canonical inhibitors interact through their N-terminal segment. There are also extensive secondary interactions outside the active site, contributing significantly to the strength, speed, and specificity of recognition. Serpins, similarly to the canonical inhibitors, interact with their target proteases in a substrate-like manner; however, cleavage of a single peptide bond in the binding loop leads to dramatic structural changes.
The doublecortin-like domains (DCX), which typically occur in tandem, are novel microtubule-binding modules. DCX tandems are found in doublecortin, a 360-residue protein expressed in migrating neurons; the doublecortin-like kinase (DCLK); the product of the RP1 gene that is responsible for a form of inherited blindness; and several other proteins. Mutations in the gene encoding doublecortin cause lissencephaly in males and the 'double-cortex syndrome' in females. We here report a solution structure of the N-terminal DCX domain of human doublecortin and a 1.5 A resolution crystal structure of the equivalent domain from human DCLK. Both show a stable, ubiquitin-like tertiary fold with distinct structural similarities to GTPase-binding domains. We also show that the C-terminal DCX domains of both proteins are only partially folded. In functional assays, the N-terminal DCX domain of doublecortin binds only to assembled microtubules, whereas the C-terminal domain binds to both microtubules and unpolymerized tubulin.
We describe the expression, purification, and biochemical characterization of two homologous enzymes, with amidohydrolase activities, of plant (Lupinus luteus potassiumindependent asparaginase, LlA) and bacterial (Escherichia coli, ybiK/spt/iaaA gene product, EcAIII) origin. Both enzymes were expressed in E. coli cells, with (LlA) or without (EcAIII) a His-tag sequence. The proteins were purified, yielding 6 or 30 mgAEL )1 of culture, respectively. The enzymes are heat-stable up to 60°C and show both isoaspartyl dipeptidase and L-asparaginase activities. Kinetic parameters for both enzymatic reactions have been determined, showing that the isoaspartyl peptidase activity is the dominating one.Despite sequence similarity to aspartylglucosaminidases, no aspartylglucosaminidase activity could be detected. Phylogenetic analysis demonstrated the relationship of these proteins to other asparaginases and aspartylglucosaminidases and suggested their classification as N-terminal nucleophile hydrolases. This is consistent with the observed autocatalytic breakdown of the immature proteins into two subunits, with liberation of an N-terminal threonine as a potential catalytic residue.
It is hypothesized that surface residues with high conformational entropy, speci®cally lysines and glutamates, impede protein crystallization. In a previous study using a model system of Rho-speci®c guanine nucleotide dissociation inhibitor (RhoGDI), it was shown that mutating Lys residues to Ala results in enhanced crystallizability, particularly when clusters of lysines are targeted. It was also shown that one of these mutants formed crystals that yielded diffraction to 2.0 A Ê , a signi®cant improvement on the wild-type protein crystals. In the current paper, an analysis of the impact of surface mutations replacing Glu residues with Ala or Asp on the stability and crystallization properties of RhoGDI is presented. The Glu3Ala (Asp) mutants are generally more likely to produce crystals of the protein than the wild-type and in one case the resulting crystals yielded a diffraction pattern to 1.2 A Ê resolution. This occurs in spite of the fact that mutating surface Glu residues almost invariably affects the protein's stability, as illustrated by the reduced ÁG between folded and unfolded forms measured by isothermal equilibrium denaturation. The present study strongly supports the notion that rational surface mutagenesis can be an effective tool in overcoming problems stemming from the protein's recalcitrance to crystallization and may also yield dramatic improvements in crystal quality.
Fibroblast growth factor 1 is a powerful mitogen playing an important role in morphogenesis, angiogenesis and wound healing and is therefore of potential medical interest. Using homologous sequence and structure comparisons, we designed and constructed 16 mutants of FGF-1 with increased thermodynamic stability, as determined by chemical and heat denaturation. For multiple mutants, additive effects on stability were observed, providing mutants up to 7.8 degrees C more stable than the wild-type. None of the introduced mutations affected any FGF-1 biological activities, such as stimulation of DNA synthesis, MAP kinase activation and binding to the FGF receptor on the cell surface. Our study provides a good starting point to improve the stability of FGF-1 in the context of its wide potential therapeutic applications. We showed that a homology approach is an effective method to change the thermodynamic properties of the protein without altering its function.
The potential of rational surface mutagenesis for enhanced protein crystallization is being probed in an ongoing effort. In previous work, it was hypothesized that residues with high conformational entropy such as Glu and Lys are suitable targets for surface mutagenesis, as they are rarely incorporated in crystal contacts or protein-protein interfaces. Previous experiments using Lys-->Ala, Glu-->Ala and Glu-->Asp mutants confirmed that mutated proteins were more likely to crystallize. In the present paper, the usefulness of Lys-->Arg mutations is studied. Several mutations of the globular domain of human RhoGDI were generated, including the single mutants K105R, K113R, K127R, K138R and K141R, the double mutants K(98,99)R and K(199,200)R and the triple mutants K(98,99,105)R and K(135,138,141)R. It is shown that Lys-->Arg mutants are more likely to crystallize than the wild-type protein, although not as likely as Lys-->Ala mutants. Out of the nine mutants tested, five produced diffracting crystals, including the K(199,200)R double mutant, which crystallized in a new space group and exceeded by approximately 1.0 A the resolution of the diffraction of the wild-type crystal. Major crystal contacts in the new lattice were created by the mutated epitope.
scite is a Brooklyn-based organization that helps researchers better discover and understand research articles through Smart Citations–citations that display the context of the citation and describe whether the article provides supporting or contrasting evidence. scite is used by students and researchers from around the world and is funded in part by the National Science Foundation and the National Institute on Drug Abuse of the National Institutes of Health.