Raghuvir K. Arni scite author profile

Snake venoms are cocktails of enzymes and non‐enzymatic proteins used for both the immobilization and digestion of prey. The most common snake venom enzymes include acetylcholinesterases, l‐amino acid oxidases, serine proteinases, metalloproteinases and phospholipases A2. Higher catalytic efficiency, thermal stability and resistance to proteolysis make these enzymes attractive models for biochemists, enzymologists and structural biologists. Here, we review the structures of these enzymes and describe their structure‐based mechanisms of catalysis and inhibition. Some of the enzymes exist as protein complexes in the venom. Thus we also discuss the functional role of non‐enzymatic subunits and the pharmacological effects of such protein complexes. The structures of inhibitor–enzyme complexes provide ideal platforms for the design of potent inhibitors which are useful in the development of prototypes and lead compounds with potential therapeutic applications.

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Recent advances in the understanding of brown spider venoms: From the biology of spiders to the molecular mechanisms of toxins

Gremski

Trevisan-Silva

Ferrer

et al. 2014

Toxicon

132

134

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Structures of the noncovalent complexes of human and bovine prothrombin fragment 2 with human PPACK-thrombin

Arni¹,

Padmanabhan²,

Wu³

et al. 1993

Biochemistry

107

118

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Both human and bovine prothrombin fragment 2 (the second kringle) have been cocrystallized separately with human PPACK (D-Phe-Pro-Arg)-thrombin, and the structures of these noncovalent complexes have been determined and refined (R = 0.155 and 0.157, respectively) at 3.3-A resolution using X-ray crystallographic methods. The kringles interact with thrombin at a site that has previously been proposed to be the heparin binding region. The latter is a highly electropositive surface near the C-terminal helix of thrombin abundant in arginine and lysine residues. These form salt bridges with acidic side chains of kringle 2. Somewhat unexpectedly, the negative groups of the kringle correspond to an enlarged anionic center of the lysine binding site of lysine binding kringles such as plasminogens K1 and K4 and TPA K2. The anionic motif is DGDEE in prothrombin kringle 2. The corresponding cationic center of the lysine binding site region has an unfavorable Arg70Asp substitution, but Lys35 is conserved. However, the folding of fragment 2 is different from that of prothrombin kringle 1 and other kringles: the second outer loop possesses a distorted two-turn helix, and the hairpin beta-turn of the second inner loop pivots at Val64 and Asp70 by 60 degrees. Lys35 is located on a turn of the helix, which causes it to project into solvent space in the fragment 2-thrombin complex, thereby devastating any vestige of the cationic center of the lysine binding site. Since fragment 2 has not been reported to bind lysine, it most likely has a different inherent folding conformation for the second outer loop, as has also been observed to be the case with TPA K2 and the urokinase kringle. The movement of the Val64-Asp70 beta-turn is most likely a conformational change accompanying complexation, which reveals a new heretofore unsuspected flexibility in kringles. The fragment 2-thrombin complex is only the second cassette module-catalytic domain structure to be determined for a multidomain blood protein and only the third domain-domain interaction to be described among such proteins, the others being factor Xa without a Gla domain and Ca2+ prothrombin fragment 1 with a Gla domain and a kringle.

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The X-ray Crystallographic Structure ofEscherichia coli Branching Enzyme

Abad¹,

Binderup²,

Rios-Steiner³

et al. 2002

Journal of Biological Chemistry

116

110

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Branching enzyme catalyzes the formation of ␣-1,6 branch points in either glycogen or starch. We report the 2.3-Å crystal structure of glycogen branching enzyme from Escherichia coli. The enzyme consists of three major domains, an NH 2 -terminal seven-stranded ␤-sandwich domain, a COOH-terminal domain, and a central ␣/␤-barrel domain containing the enzyme active site. While the central domain is similar to that of all the other amylase family enzymes, branching enzyme shares the structure of all three domains only with isoamylase. Oligosaccharide binding was modeled for branching enzyme using the enzyme-oligosaccharide complex structures of various ␣-amylases and cyclodextrin glucanotransferase and residues were implicated in oligosaccharide binding. While most of the oligosaccharides modeled well in the branching enzyme structure, an approximate 50°rotation between two of the glucose units was required to avoid steric clashes with Trp 298 of branching enzyme. A similar rotation was observed in the mammalian ␣-amylase structure caused by an equivalent tryptophan residue in this structure. It appears that there are two binding modes for oligosaccharides in these structures depending on the identity and location of this aromatic residue.

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Structural Basis for Metal Ion Coordination and the Catalytic Mechanism of Sphingomyelinases D

Murakami

Fernandes-Pedrosa

Tambourgi

et al. 2005

Journal of Biological Chemistry

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Sphingomyelinases D (SMases D) fromLoxosceles spider venom are the principal toxins responsible for the manifestation of dermonecrosis, intravascular hemolysis, and acute renal failure, which can result in death. These enzymes catalyze the hydrolysis of sphingomyelin, resulting in the formation of ceramide 1-phosphate and choline or the hydrolysis of lysophosphatidyl choline, generating the lipid mediator lysophosphatidic acid. This report represents the first crystal structure of a member of the sphingomyelinase D family from Loxosceles laeta (SMase I), which has been determined at 1.75-Å resolution using the "quick cryo-soaking" technique and phases obtained from a single iodine derivative and data collected from a conventional rotating anode x-ray source. SMase I folds as an (␣/␤) 8 barrel, the interfacial and catalytic sites encompass hydrophobic loops and a negatively charged surface. Substrate binding and/or the transition state are stabilized by a Mg 2؉

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Raghuvir K. Arni

Enzymatic toxins from snake venom: structural characterization and mechanism of catalysis

Recent advances in the understanding of brown spider venoms: From the biology of spiders to the molecular mechanisms of toxins

Structures of the noncovalent complexes of human and bovine prothrombin fragment 2 with human PPACK-thrombin

The X-ray Crystallographic Structure ofEscherichia coli Branching Enzyme

Structural Basis for Metal Ion Coordination and the Catalytic Mechanism of Sphingomyelinases D

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