An exploration of the binding site of aldolase using alkanediol monoglycolate bisphosphoric esters

Alkanediol monoglycolate bisphosphoric esters (P-O-CH2-CO-O-(CH2)n-O-P), which are analogues of the aldolase (D-fructose-1,6-bisphosphate D-glyceraldehyde-3-phosphate-lyase, EC 4.1.2.13) substrate fructose 1,6-bisphosphate, were synthesized and used for probing its active site. The Ki value was lowest when the maximum distance between the phosphorus atoms of the bisphosphate was brought close to that of fructose 1,6-bisphosphate. The binding constants estimated from difference spectra correlate well with Ki values for the substrate analogues. Propanediol monoglycolate bisphosphoric ester protected aldolase from inactivation by 1,2-cyclohexanedione, which preferentially attacks arginine-55. However, propanol phosphate had little protective effect. The synthesized phosphate compounds protected the enzyme against inactivation by trypsin, and also against spontaneous denaturation. These results suggest that the synthesized phosphate compounds bind to aldolase at the active site, which tends to keep the distance constant between the two phosphate-binding sites for the open-chain form of fructose 1,6-bisphosphate, and stabilize the natural conformation of the enzyme. Both arginine-55 and lysine-146 are shown to participate in the phosphate-binding site for the C-1-phosphate of fructose 1,6-bisphosphate.     

An exploration of the binding site of aldolase using N-(omega-hydroxyalkyl) glycolamidobisphosphoric esters

N-(omega-Hydroxyalkyl)glycolamidobisphosphoric esters (P-O-CH2-CO-NH-(CH2)n -O-P), which are analogues of the aldolase (D-fructose-1,6-bisphosphate D-glyceraldehyde-3-phosphate-lyase, EC 4.1.2.13) substrate fructose 1,6-bisphosphate, were synthesized and used for probing its active site. These phosphate compounds competitively inhibited aldolase activity. The Ki value was lowest when the maximum distance between the phosphorus atoms of the bisphosphate was brought close to that of fructose 1,6-bisphosphate. The inhibitor constants, Ki, were compared to those of alkanediol monoglycolate bisphosphoric esters and alkanediol bisphosphate compounds, which were reported previously by Ogata et al. The values of Ki for the bisphosphate compounds containing an amide group, the amide bisphosphate compounds, were smaller than those for the bisphosphate compounds containing an ester group, the ester bisphosphate compounds, and those for alkanediol bisphosphates were the largest for the same distance between phosphorus atoms in these bisphosphates. The difference spectra of aldolase caused by binding of a saturating concentration of N-(omega-hydroxypropyl)glycolamidobisphosphoric ester resembled that of butanediol monoglycolate bisphosphoric ester. However, the effects of the amide bisphosphate compounds on the absorption spectrum of aldolase were smaller than those of the ester bisphosphate compounds for the same distance between phosphorus atoms in these bisphosphate compounds. These results suggest that the synthesized phosphate compounds bind to aldolase at the active site and the -CO-NH- group of the compounds might be held more tightly than the -CO-O- group by hydrogen bonds, presumably with the amino acid residues in the active site, such as Lys-146 or -229 and Asp-33 or Glu-187. On the other hand, the -CO-O- group might be more effective in changing the environment of the Trp-147 residue in the active site of this enzyme.     

Location and primary structure of the substrate binding site peptide of aldolase C

An octadecapeptide containing the substrate-combining site of rabbit brain aldolase (aldolase C) has been isolated. This peptide has tentatively been assigned the structure: Ala-Leu-Ser(Asx,His,His,Val,Tyr)(Leu,Glx,Gly,Thr,Leu,Leu)(Lys,Pro,Asx,Met). The primary sequence of this peptide thus appears to be very similar to that of the active-site peptide of rabbit muscle aldolase (aldolase A), but it is located in a different BrCN segment, approximately 50 residues closer to the NH₂-terminus of the aldolase C subunit. A tentative sequence has also been obtained for an adjacent nonapeptide, also homologous with the corresponding structure in aldolase A. The evidence suggests that a large segment of the peptide chain in aldolase C may be translocated, as compared with aldolase A.     

Chemical modification of the actin binding site of rabbit muscle aldolase by diethylpyrocarbonate

Summary To extend the available information on the significance of the interactions between glycolytic enzymes and the actin component of the cellular ultrastructure, investigations into the compositional characteristics of the actin binding site on one of the major glycolytic enzymes, aldolase, have been undertaken. As the electrostatic nature of the association has been previously reported indicative of a cationic region on the enzyme involved in the binding, these studies have investigated the possibility of the involvement of histidine residues in this binding region. By the use of the histidine specific reagent, diethylpyrocarbonate, we have been able to establish a difference in nature of an actin binding domain and the active site domain which does contain an essential histidine. The results have been discussed in relation to the significance of this finding with respect to the binding of aldolase to subcellular structure.     

An axial binding site in the Tetrahymena precursor RNA.

Previous studies allow the construction of three distinct models of the binding of G and arginine within the active site of the Tetrahymena self-splicing preribosomal precursor RNA. These models (base triple, axial I and axial II) are now distinguished by measurements on the specificity of RNAs with nucleotide substitutions at positions spanning the site. Because the semi-conserved unpaired nucleotide 263 has no effect on substrate or inhibitor selection by the Tetrahymena RNA we conclude that the axial I model is improbable. In contrast, data with substituted RNAs and nucleoside analogs suggest that nucleotide 265 makes a hydrogen bond with the substrate. Accordingly the active site appears axial because substrate contacts exist at more than one nucleotide on the 5' side of the P7 helix. The effects of this hydrogen bond are observable in cases where the donor or acceptor is on the RNA, whether nucleotide 265 is a purine or pyrimidine, or whether nucleotide 265 is mispaired, wobble paired or normally paired. This pattern is consistent with the axial II model. Molecular dynamics and energy minimization calculations lead to the same conclusions as these site-directed substitutions; the base triple and axial I models are unstable dynamically. Under thermal agitation, the third model site (axial II) is transformed to a related, but more stable structure, axial III. The axial III active site is characterized by the extrusion of the conserved bulged base 263 from the P7 helix, a semi-pocket for G base formed by stacking of nucleotide 262, and formation of all bonds to the G base originally proposed for both the base triple and axial II sites. Because of these hydrogen bonds the axial III site is also consistent with data on enzymatic specificity. The axial III model indicates an unforeseen capacity for pocket formation within the groove of an RNA helix, suggests that the site may be unusually flexible, and bears on a hypothesis concerning the origin of the genetic code.     

Analysis of the class I aldolase binding site architecture based on the crystal structure of 2-deoxyribose-5-phosphate aldolase at 0.99A resolution

The crystal structure of the bacterial (Escherichia coli) class I 2-deoxyribose-5-phosphate aldolase (DERA) has been determined by Se-Met multiple anomalous dispersion (MAD) methods at 0.99A resolution. This structure represents the highest-resolution X-ray structure of an aldolase determined to date and enables a true atomic view of the enzyme. The crystal structure shows the ubiquitous TIM alpha/beta barrel fold. The enzyme contains two lysine residues in the active site. Lys167 forms the Schiff base intermediate, whereas Lys201, which is in close vicinity to the reactive lysine residue, is responsible for the perturbed pK(a) of Lys167 and, hence, also a key residue in the reaction mechanism. DERA is the only known aldolase that is able to use aldehydes as both aldol donor and acceptor molecules in the aldol reaction and is, therefore, of particular interest as a biocatalyst in synthetic organic chemistry. The uncomplexed DERA structure enables a detailed comparison with the substrate complexes and highlights a conformational change in the phosphate-binding site. Knowledge of the enzyme active-site environment has been the basis for exploration of catalysis of non-natural substrates and of mutagenesis of the phosphate-binding site to expand substrate specificity. Detailed comparison with other class I aldolase enzymes and DERA enzymes from different organisms reveals a similar geometric arrangement of key residues and implies a potential role for water as a general base in the catalytic mechanism.     

The alkyl moieties in wax esters and alkyl diacyl glycerols of sharks

The alkyl moieties in wax esters and alkyl diacyl glycerols from the liver of the dogfish, soupfin shark, and silky shark are almost exclusively saturated and monounsaturated, the main alkyl moieties being the C(16) and C(18) chains in both lipid classes. However, the alkyl moieties in wax esters occur in a wider range of chain lengths. The unsaturated alkyl moieties in the two classes of lipids are mixtures of isomers. The distribution of isomeric octadecenyl moieties in wax esters and alkyl diacyl glycerols is almost the same.     

An exploration of the primary specificity site of cathepsin B

Peptidyl diazomethyl ketones inactivate cathepsin B apparently by alkylation of the active center thiol following complex formation as in the case of benzyloxycarbonyl (Cbz)-Phe-AlaCHN2. The phenylalanine contributes considerably to binding in the secondary specificity site. In order to define the topography of the active center region comprising the primary specificity site of beef spleen cathepsin B, a series of peptidyl diazomethyl ketones having the general structure Cbz-Phe-X-CHN2 has now been synthesized. The amino acid, X, has been varied in size to include rather large side chains which might reveal available binding potential or limitations. Some of the reagents, in fact, were not inhibitory even at 10(-4) M. Others, however, that did measurably inactivate cathepsin B provided a range of reactivities that extended over 5 orders of magnitude and correlated with affinity in the reversible phase of inactivation. Some large side chains, for example, that of tryptophan, were very poorly tolerated in this region of the active center, whereas others, such as O-benzyl threonine, provided remarkably active inhibitors. A topographical rationalization of the results is offered.     

An improved procedure for the preparation of alkyl sulphate esters suitable for the study of secondary alkylsulphohydrolase enzymes.

A simple, rapid and convenient method for the synthesis of secondary alkyl sulphate esters is described in which the sodium alkoxide of the parent alcohol is sulphated by using triethylamine-SO3 complex. The procedure gives relatively good yields, even for the sulphation of long-chain alcohols and those in which the hydroxy group is remote from the terminal carbon atoms. Positional isomerization, arising from the migration of the hydroxy group along the carbon chain, is absent, and resolved enantiomers of alcohols react with complete retention of configuration.