Structure and catalytic mechanism of the β-carbonic anhydrases

The β-carbonic anhydrases (β-CAs) are a diverse but structurally related group of zinc-metalloenzymes found in eubacteria, plant chloroplasts, red and green algae, and in the Archaea. The enzyme catalyzes the rapid interconversion of CO₂ and H₂O to HCO₃⁻ and H⁺, and is believed to be associated with metabolic enzymes that consume or produce CO₂ or HCO₃⁻. For many organisms, β-CA is essential for growth at atmospheric concentrations of CO₂. Of the five evolutionarily distinct classes of carbonic anhydrase, β-CA is the only one known to exhibit allosterism. Here we review the structure and catalytic mechanism of β-CA, including the structural basis for allosteric regulation.     

Contribution of the γ-secretase subunits to the formation of catalytic pore of presenilin 1 protein

γ-Secretase is an intramembrane-cleaving protease related to the etiology of Alzheimer disease. γ-Secretase is a membrane protein complex composed of presenilin (PS) and three indispensable subunits: nicastrin, Aph-1, and Pen-2. PS functions as a protease subunit forming a hydrophilic catalytic pore structure within the lipid bilayer. However, it remains unclear how other subunits are involved in the pore formation. Here, we show that the hydrophilic pore adopted with an open conformation has already been formed by PS within the immature γ-secretase complex. The binding of the subunits induces the close proximity between transmembrane domains facing the catalytic pore. We propose a model in which the γ-secretase subunits restrict the arrangement of the transmembrane domains of PS during the formation of the functional structure of the catalytic pore.     

How does the push/pull effect of the axial ligand influence the catalytic properties of Compound I of catalase and cytochrome P450?

Density functional theory (DFT) calculations on the chemoselective epoxidation versus hydroxylation reactions of propene by oxoiron porphyrin models mimicking the active sites of catalase, cytochrome P450 (P450) and horseradish peroxidase Compound I (CpdI) are presented. The catalase reactions are concerted and proceed via two-state reactivity patterns on competing doublet and quartet spin state surfaces, but the lowest barrier is the one leading to epoxide products on the doublet spin surface. The results are compared with earlier DFT studies of models of cytochrome P450, horseradish peroxide (HRP), taurine/alpha-ketoglutarate dioxygenase and some synthetic oxoiron catalysts. The catalase barriers are midway in between those obtained for HRP and P450 models, so that tyrosinate ligated heme systems should be able to catalyze C-H hydroxylation and C=C epoxidation reactions. We show that for heme systems the barrier height of epoxidation linearly correlates with the electron affinity of Compound I as expected from the electron transfer mechanism of the rate determining step. Our studies show that the axial ligand does not influence the chemoselectivity of a reaction but that it does regulate the barrier heights and rate constants. Finally, we estimated the effect of the axial ligand on the oxoiron group and derived that it contributes from a field effect due to the charge of the ligand and a quantum mechanical effect as a result of orbital mixing. In catalase, the major component is the field effect, while the quantum mechanical effect is negligible. This is in contrast to P450 CpdI, where both effects are of similar order of magnitude.     

In silico identification of catalytic residues and domain fold of the family GH119 sharing the catalytic machinery with the α-amylase family GH57

The glycoside hydrolase family 119 (GH119) contains the α-amylase from Bacillus circulans and five other hypothetical proteins. Until now, nothing has been reported on the catalytic residues and catalytic-domain fold of GH119. Based on a detailed in silico analysis involving sequence comparison in combination with BLAST searches and structural modelling, an unambiguous relationship was revealed between the families GH119 and GH57. This includes sharing the catalytic residues, i.e. Glu231 and Asp373 as catalytic nucleophile and proton donor, respectively, in the predicted catalytic (β/α)₇-barrel domain of GH119 B. circulans α-amylase. The GH57 and GH119 families may thus define a new CAZy clan.     

Comparison of the kinetic parameters of the truncated catalytic subunit and holoenzyme of human DNA polymerase ɛ

Numerous genetic studies have provided compelling evidence to establish DNA polymerase ɛ (Polɛ) as the primary DNA polymerase responsible for leading strand synthesis during eukaryotic nuclear genome replication. Polɛ is a heterotetramer consisting of a large catalytic subunit that contains the conserved polymerase core domain as well as a 3′ → 5′ exonuclease domain common to many replicative polymerases. In addition, Polɛ possesses three small subunits that lack a known catalytic activity but associate with components involved in a variety of DNA replication and maintenance processes. Previous enzymatic characterization of the Polɛ heterotetramer from budding yeast suggested that the small subunits slightly enhance DNA synthesis by Polɛ in vitro. However, similar studies of the human Polɛ heterotetramer (hPolɛ) have been limited by the difficulty of obtaining hPolɛ in quantities suitable for thorough investigation of its catalytic activity. Utilization of a baculovirus expression system for overexpression and purification of hPolɛ from insect host cells has allowed for isolation of greater amounts of active hPolɛ, thus enabling a more detailed kinetic comparison between hPolɛ and an active N-terminal fragment of the hPolɛ catalytic subunit (p261N), which is readily overexpressed in Escherichia coli. Here, we report the first pre-steady-state studies of fully-assembled hPolɛ. We observe that the small subunits increase DNA binding by hPolɛ relative to p261N, but do not increase processivity during DNA synthesis on a single-stranded M13 template. Interestingly, the 3′ → 5′ exonuclease activity of hPolɛ is reduced relative to p261N on matched and mismatched DNA substrates, indicating that the presence of the small subunits may regulate the proofreading activity of hPolɛ and sway hPolɛ toward DNA synthesis rather than proofreading.     

An inserted α/β subdomain shapes the catalytic pocket of Lactobacillus johnsonii cinnamoyl esterase

Background

Microbial enzymes produced in the gastrointestinal tract are primarily responsible for the release and biochemical transformation of absorbable bioactive monophenols. In the present work we described the crystal structure of LJ0536, a serine cinnamoyl esterase produced by the probiotic bacterium Lactobacillus johnsonii N6.2.

Methodology/Principal Findings

We crystallized LJ0536 in the apo form and in three substrate-bound complexes. The structure showed a canonical α/β fold characteristic of esterases, and the enzyme is dimeric. Two classical serine esterase motifs (GlyXSerXGly) can be recognized from the amino acid sequence, and the structure revealed that the catalytic triad of the enzyme is formed by Ser₁₀₆, His₂₂₅, and Asp₁₉₇, while the other motif is non-functional. In all substrate-bound complexes, the aromatic acyl group of the ester compound was bound in the deepest part of the catalytic pocket. The binding pocket also contained an unoccupied area that could accommodate larger ligands. The structure revealed a prominent inserted α/β subdomain of 54 amino acids, from which multiple contacts to the aromatic acyl groups of the substrates are made. Inserts of this size are seen in other esterases, but the secondary structure topology of this subdomain of LJ0536 is unique to this enzyme and its closest homolog (Est1E) in the Protein Databank.

Conclusions

The binding mechanism characterized (involving the inserted α/β subdomain) clearly differentiates LJ0536 from enzymes with similar activity of a fungal origin. The structural features herein described together with the activity profile of LJ0536 suggest that this enzyme should be clustered in a new group of bacterial cinnamoyl esterases.     

Stoichiometric and catalytic hydrogenation of the [Co2(CO)6(μ2-η2-alkyne)] complexes

The [Co₂(CO)₆(RC₂R′)] complexes (R, R′ = H, Me, Et, Prⁿ) react with molecular hydrogen under mild conditions of temperature and pressure, at low but appreciable rates. The effect of the steric hindrance of the substituents and the strength of the metalcarbon bonds are discussed. The kinetic data measured for [Co₂(CO)₆(HC₂H)], suggest that both H₂-coordination and CO-dissociation are involved in the rate-determining step of the overall hydrogenation process.The catalytic activity of [Co₂(CO)₆(HC₂H)] in the homogeneous hydrogenation of acetylene is described. At low substrate/catalyst ratio the initial hydrogenation rate is equal, within experimental error, to that found for the stoichiometric reaction; on increasing the acetylene concentration, cyclotrimerization to benzene becomes the dominant process. Interestingly C₄ hydrocarbons (mainly butadiene and 1-butene) are produced in measurable yield (?8%). The formation of these products is interpreted as the result of the hydrogenation of the elusive [Co₂(CO)₅(HC₂H)₂] complex, an unstable intermediate in the cyclotrimerization chain.     

Pocket analysis of the full-length cholix toxin. An assessment of the structure–dynamics of the apo catalytic domain

Cholix toxin from Vibrio cholerae is the third member of the diphtheria toxin (DT) group of mono-ADP-ribosyltransferase (mART) bacterial toxins. It shares structural and functional properties with Pseudomonas aeruginosa exotoxin A and Corynebacterium diphtheriae DT. Cholix toxin is an important model for the development of antivirulence approaches and therapeutics against these toxins from pathogenic bacteria. Herein, we have used the high-resolution X-ray structure of full-length cholix complexed with NAD⁺ to describe the properties of the NAD⁺-binding pocket at the residue level, including the role of crystallographic water molecules in the NAD⁺ substrate interaction. The full-length apo cholix structure is used to describe the putative NAD⁺-binding site(s) and to correlate biochemical with crystallographic data to study the stoichiometry and orientation of bound NAD⁺ molecules. We quantitatively describe the NAD⁺ substrate interactions on a residue basis for the main 22 pocket residues in cholix_f, a glycerol and 5 contact water molecules as part of the recognition surface by the substrate according to the conditions of crystallization. In addition, the dynamic properties of an in silico version of the catalytic domain were investigated in order to understand the lack of electronic density for one of the main flexible loops (R-loop) in the pocket of X-ray complexes. Implications for a rational drug design approach for mART toxins are derived.     

Expression of the catalytic subunits of pol α and pol δ from fission yeast Schizosaccharomyces pombe

This paper reports on expression and posttranslational modifications of the catalytic subunits of pol α and pol δ from fission yeastSchizosaccharomyces pombe. Okadaic acid treatment ofS. pombe spheroplasts in amounts known to inhibit phosphatases, 1 and 2A resulted in decreased proteolysis of both pol α and pol δ. Computer analysis of pol α and pol δ sequences confirmed the presence of consensus motifs for protein phosphorylation. Indirect immunofluorescence microscopy ofS. pombe cells showed nuclear location of both proteins in wild type cells. However, whereas cells transformed with a vector expressing pol α produced a clear increase of the nuclear signal no increase was detectable in cells transformed with pol δ. This observation suggests the existence of a mechanism limiting thecell concentration of pol δ in the cell. Constitutive expression ofS. pombe pol δ inE. coli was possible only with vectors containing truncated forms of its gene, indicating a toxic effect of pol δ onE. coli growth.     

Comparison of the effects of prostaglandins D2, F2α and E1 on spontaneous contractions of rabbit oviduct

The effects of PGD₂, PGF_2α and PGE₁ were studied on the circular muscle of post-ovulatory rabbit oviducts $\text{in vitro}$. PGE₁ inhibited spontaneous contractile activity. Lower concentrations of PGD₂ and PGF_2α were stimulatory and higher concentrations were inhibitory. Since PGD₂ may be produced in the oviduct, any hypothesis concerning the role of prostaglandins in the control of oviductal motility and ovum transport should include PGD₂ as well as PGFs and PGEs.     

QM/MM investigation on the catalytic mechanism of Bacteroides thetaiotaomicron α-glucosidase BtGH97a

Bacteroides thetaiotaomicron α-glucosidase BtGH97a is an inverting enzyme. In this paper, the hydrolysis mechanism of p-nitro-phenyl α-d-glucopyranoside (pNP-Glc) catalyzed by BtGH97a was firstly studied by using quantum mechanical/molecular mechanical (QM/MM) approach. Two possible reaction pathways were considered. In the first pathway, a water molecule deprotonated by a nucleophilic base (here E439 or E508) attacks firstly on the anomeric carbon of pNP-Glc, then a proton from an acid residue (E532) attacks on the glycosidic oxygen to finish the hydrolysis reaction (named as nucleophilic attack-first pathway). In the second pathway, the proton from E532 attacks firstly on the glycosidic oxygen, then the water deprotonated by the nucleophilic base attacks on the anomeric carbon of pNP-Glc (named as proton attack-first pathway). Our calculation results indicate that the nucleophilic attack-first pathway is favorable in energy, in which the nucleophilic attack process is the rate-determining step with an energy barrier of 15.4 kcal/mol in the case of residue E508 as nucleophilic base. In this rate-determining step, the deprotonation of water and the attack on the anomeric carbon are concerted. In the proton attack-first pathway, the proton attack on the glycosidic oxygen is the rate-determining step, and the energy barrier is 24.1 kcal/mol. We conclude that the hydrolysis mechanism would follow nucleophilic attack-first pathway.     

The effect of divalent cations on the catalytic activity of the human plasma 3′-exonuclease

The 3′-exonuclease from human plasma is a soluble form of nucleotide pyrophosphatase/phosphodiesterase 1 (NPP1) (EC 3.1.4.1/EC 3.6.1.9). Here, the possibility of divalent cation influence for the 3′-exonuclease activity was investigated using the phosphorothioate congener of oligonucleotide containing all phosphorothioate internucleotide linkages of the [R_P]-configuration ([R_P-PS]-d[T₁₂]) as the substrate for this enzyme. It was found that the 3′-exonuclease is a metalloenzyme, i.e. its phosphodiesterase activity was completely abolished at 0.8 mM concentration EDTA and, in turn, it was restored in the presence of Mg²⁺ or Mn²⁺ ions. In addition, Mg²⁺ can be replaced effectively by Ca²⁺, Mn²⁺, or Co²⁺, but not by Ni²⁺ and Cd²⁺ during the hydrolysis of the phosphorothioate substrate in human plasma. In addition, the mechanism is postulated, by which a single internucleotide phosphorothioate bond of the S_P-configuration at the 3′-end of unmodified phosphodiesters (PO-oligos), or their phosporothioate analogs (PS-oligos) protects these compounds against degradation in blood.     

Substrate recognition of the catalytic α-subunit of glucosidase II from Schizosaccharomyces pombe

The recombinant catalytic α-subunit of N-glycan processing glucosidase II from Schizosaccharomyces pombe (SpGIIα) was produced in Escherichia coli. The recombinant SpGIIα exhibited quite low stability, with a reduction in activity to <40% after 2-days preservation at 4 °C, but the presence of 10% (v/v) glycerol prevented this loss of activity. SpGIIα, a member of the glycoside hydrolase family 31 (GH31), displayed the typical substrate specificity of GH31 α-glucosidases. The enzyme hydrolyzed not only α-(1→3)- but also α-(1→2)-, α-(1→4)-, and α-(1→6)-glucosidic linkages, and p-nitrophenyl α-glucoside. SpGIIα displayed most catalytic properties of glucosidase II. Hydrolytic activity of the terminal α-glucosidic residue of Glc₂Man₃-Dansyl was faster than that of Glc₁Man₃-Dansyl. This catalytic α-subunit also removed terminal glucose residues from native N-glycans (Glc₂Man₉GlcNAc₂ and Glc₁Man₉GlcNAc₂) although the activity was low.     

Structural and functional analysis of the flexible regions of the catalytic α-subunit of protein kinase CK2

CK2 is a Ser/Thr protein kinase essential for cell viability. Its activity is anomalously high in several solid (prostate, mammary gland, lung, kidney and head and neck) and haematological tumours (AML, CML and PML), creating conditions favouring the onset of cancer. Cancer cells become addicted to high levels of CK2 activity and therefore this kinase is a remarkable example of "non-oncogene addiction". CK2 is a validated target for cancer therapy with one inhibitor in phase I clinical trials. Several crystal structures of CK2 are available, many in complex with ATP-competitive inhibitors, showing the presence of regions with remarkable flexibility. We present the structural characterisation of these regions by means of seven new crystal structures, in the apo form and in complex with inhibitors. We confirm previous findings about the unique flexibility of the CK2α catalytic subunit in the hinge/αD region, the p-loop and the β4β5 loop, and show here that there is no clear-cut correlation between the conformations of these flexible zones. Our findings challenge some of the current interpretations on the functional role of these regions and dispute the hypothesis that small ligands stabilize an inactive state. The mobility of the hinge/αD region in the human enzyme is unique among protein kinases, and this can be exploited for the development of more selective ATP-competitive inhibitors. The identification of different ligand binding modes to a secondary site can provide hints for the design of non-ATP-competitive inhibitors targeting the interaction between the α catalytic and the β regulatory subunits.     

Theoretical investigation of the enzymatic phosphoryl transfer of β-phosphoglucomutase: revisiting both steps of the catalytic cycle

Enzyme catalyzed phosphate transfer is a part of almost all metabolic processes. Such reactions are of central importance for the energy balance in all organisms and play important roles in cellular control at all levels. Mutases transfer a phosphoryl group while nucleases cleave the phosphodiester linkages between two nucleotides. The subject of our present study is the Lactococcus lactis β-phosphoglucomutase (β-PGM), which effectively catalyzes the interconversion of β-D-glucose-1-phosphate (β-G1P) to β-D-glucose-6-phosphate (β-G6P) and vice versa via stabile intermediate β-D-glucose-1,6-(bis)phosphate (β-G1,6diP) in the presence of Mg(2+). In this paper we revisited the reaction mechanism of the phosphoryl transfer starting from the bisphosphate β-G1,6diP in both directions (toward β-G1P and β-G6P) combining docking techniques and QM/MM theoretical method at the DFT/PBE0 level of theory. In addition we performed NEB (nudged elastic band) and free energy calculations to optimize the path and to identify the transition states and the energies involved in the catalytic cycle. Our calculations reveal that both steps proceed via dissociative pentacoordinated phosphorane, which is not a stabile intermediate but rather a transition state. In addition to the Mg(2+) ion, Ser114 and Lys145 also play important roles in stabilizing the large negative charge on the phosphate through strong coordination with the phosphate oxygens and guiding the phosphate group throughout the catalytic process. The calculated energy barrier of the reaction for the β-G1P to β-G1,6diP step is only slightly higher than for the β-G1,6diP to β-G6P step (16.10 kcal mol(-1) versus 15.10 kcal mol(-1)) and is in excellent agreement with experimental findings (14.65 kcal mol(-1)).     

QM/MM investigation on the catalytic mechanism of Bacteroides thetaiotaomicron α-glucosidase BtGH97a

Bacteroides thetaiotaomicron α-glucosidase BtGH97a is an inverting enzyme. In this paper, the hydrolysis mechanism of p-nitro-phenyl α-d-glucopyranoside (pNP-Glc) catalyzed by BtGH97a was firstly studied by using quantum mechanical/molecular mechanical (QM/MM) approach. Two possible reaction pathways were considered. In the first pathway, a water molecule deprotonated by a nucleophilic base (here E439 or E508) attacks firstly on the anomeric carbon of pNP-Glc, then a proton from an acid residue (E532) attacks on the glycosidic oxygen to finish the hydrolysis reaction (named as nucleophilic attack-first pathway). In the second pathway, the proton from E532 attacks firstly on the glycosidic oxygen, then the water deprotonated by the nucleophilic base attacks on the anomeric carbon of pNP-Glc (named as proton attack-first pathway). Our calculation results indicate that the nucleophilic attack-first pathway is favorable in energy, in which the nucleophilic attack process is the rate-determining step with an energy barrier of 15.4kcal/mol in the case of residue E508 as nucleophilic base. In this rate-determining step, the deprotonation of water and the attack on the anomeric carbon are concerted. In the proton attack-first pathway, the proton attack on the glycosidic oxygen is the rate-determining step, and the energy barrier is 24.1kcal/mol. We conclude that the hydrolysis mechanism would follow nucleophilic attack-first pathway.     

Mutational analysis of a site-specific recombinase: characterization of the catalytic and dimerization domains of the β recombinase of pSM19035

The β recombinase encoded by the streptococcal plasmid pSM19035, which shows 28 to 34% identity with DNA resolvases and DNA invertases, can catalyze formation of deletions or inversions between properly oriented target sites. We have constructed a number of site-directed mutations at residues that are conserved between the β protein and other DNA recombinases of the resolvase/invertase family. The analysis of the recombination and DNA-binding ability of each mutant protein shows that the mutations affect the catalytic activity and, in two cases, the dimerization of the protein. The results suggest that the β protein probably mediates recombination by a catalytic mechanism similar to that proposed for the resolvase/invertase family. Since the β recombinase differs from DNA resolvases and DNA invertases in its lack of bias towards either of these reactions, the results presented support the hypothesis that its unique properties might depend on details of the architecture or assembly of the recombination complex. In addition, two β protein mutants that can no longer form dimers in solution have provided new insights into the way the protein binds to DNA