Pyridyl derivatives of benzaldehyde as potential antisickling agents.

Compounds that bind to sickle hemoglobin (Hb S) producing an allosteric shift to the high-affinity Hb S that does not polymerize are being developed to treat sickle cell anemia (SCA). In this study, three series of pyridyl derivatives of substituted benzaldehydes (Classes I-III) that combine structural features of two previously determined potent antisickling agents, vanillin and pyridoxal, were synthesized. When analyzed with normal human whole blood, the compounds form Schiff-base adducts with Hb and left shift the oxygen equilibrium curve (OEC) to the more soluble high-affinity Hb, more than vanillin or pyridoxal. Generally, Class-I compounds with an aromatic aldehyde located ortho to the pyridyl substituent are the most potent, followed by the Class-II compounds with the aldehyde at the meta-position. Class-III compounds with the aldehyde at the para position show the weakest activity. The structure-activity studies of these pyridyl derivatives of substituted benzaldehydes demonstrate significant allosteric potency that may be useful for treating SCA.

Identification of novel allosteric regulators of human-erythrocyte pyruvate kinase.

Erythrocyte pyruvate kinase (PK) is an important glycolytic enzyme, and manipulation of its regulatory behavior by allosteric modifiers is of interest for medicinal purposes. Human-erythrocyte PK was expressed in Rosetta cells and purified on an Ni-NTA column. A search of the small-molecules database of the National Cancer Institute (NCI), using the UNITY software, led to the identification of several compounds with similar pharmacophores as fructose-1,6-bisphosphate (FBP), the natural allosteric activator of the human kinases. The compounds were subsequently docked into the FBP binding site using the programs FlexX and GOLD, and their interactions with the protein were analyzed with the energy-scoring function of HINT. Seven promising candidates, compounds 1-7, were obtained from the NCI, and subjected to kinetics analysis, which revealed both activators and inhibitors of the R-isozyme of PK (R-PK). The allosteric effectors discovered in this study could prove to be lead compounds for developing medications for the treatment of hemolytic anemia, sickle-cell anemia, hypoxia-related diseases, and other disorders arising from erythrocyte PK malfunction.

Structural basis for the potent antisickling effect of a novel class of five-membered heterocyclic aldehydic compounds.

Naturally occurring five-membered heterocyclic aldehydes, including 5-hydroxymethyl-2-furfural, increase the oxygen affinity of hemoglobin (Hb) and strongly inhibit the sickling of homozygous sickle red blood (SS) cells. X-ray studies of Hb complexed with these compounds indicate that they form Schiff base adducts in a symmetrical fashion with the N-terminal alphaVal1 nitrogens of Hb. Interestingly, two cocrystal types were isolated during crystallization experiments with deoxygenated Hb (deoxyHb): one crystal type was composed of the low-affinity or tense (T) state Hb quaternary structure; the other crystal type was composed of high-affinity or relaxed state Hb (with a R2 quaternary structure). The R2 crystal appears to be formed as a result of the aldehydes binding to fully or partially ligated Hb in the deoxyHb solution. Repeated attempts to crystallize the compounds with liganded Hb failed, except on rare occasions when very few R state crystals were obtained. Oxygen equilibrium, high performance liquid chromatography (HPLC), antisickling, and X-ray studies suggest that the examined heterocyclic aldehydes may be acting to prevent polymerization of sickle hemoglobin (HbS) by binding to and stabilizing liganded Hb in the form of R2 and/or various relaxed state Hbs, as well as binding to and destabilizing unliganded T state Hb. The proposed mechanism may provide a general model for the antisickling effects of aldehyde containing small molecules that bind to N-terminal alphaVal1 nitrogens of Hb. The examined compounds also represent a new class of potentially therapeutic agents for treating sickle cell disease (SCD).

Synthesis and X-ray studies of chiral allosteric modifiers of hemoglobin.

This study was designed to investigate the effect of chirality on the allosteric activity of a series of Hb allosteric modifiers. The chiral analogues were based on the lead compound (4), JP7, [1-[4-(((3,5-dimethylanilino)carbonyl)methyl)phenoxy]cyclopentanecarboxylic acid] with different D- and L-amino acids conjugated to the JP7 acid moiety. The D-isomers were the most potent in vitro effectors in Hb solutions as well as with whole blood. In general, this study demonstrated that the chirality of extended amino acid side chains in JP7 conjugates plays an important role in observed degree of allosteric activity. The binding site interactions for four analogues were determined by single crystallographic diffraction studies. Conclusions show that the chiral configuration of some of the D-isomers enable the effectors to bind with a greater number of interactions with the protein residues. D- and L-isomers with equivalent or near equivalent allosteric activity did not show any significant differences or interactions between their amino acid side chains and the protein. The most potent effectors, in vitro, were compounds 15 and 19, D-isomers of leucine and phenylalanine, respectively. Compounds 21, 22, 30, and32 were more potent in vitro in Hb solutions than JP7.

X-ray crystallographic analyses of symmetrical allosteric effectors of hemoglobin: compounds designed to link primary and secondary binding sites.

The rational design and X-ray crystallographic analyses of two symmetrical allosteric effectors of hemoglobin (Hb) are reported. Compound design was directed by the previously solved co-crystal structure of one of the most potent allosteric effectors of Hb, 2-[4-[(3,5-dichlorophenylcarbamoyl)-methyl]-phenoxy]-2-methylpropionic acid (RSR4), which revealed two distinct binding sites for this compound in the Hb central water cavity. The primary binding site has been observed for all compounds of this structural class, which stabilize deoxy Hb by engaging in inter-dimer contacts with three of the four protein subunits. Interactions at the secondary binding site of RSR4 occur primarily between the beta(1) and beta(2) subunits and serve to further constrain the deoxy state. Based on these observations, it was hypothesized that compounds with the ability to simultaneously span and link both of these sites would possess increased potency, but at a lower molar concentration than RSR4. Two symmetrical compounds were designed and synthesized based on this hypothesis. The symmetrical effector approach was taken to minimize the number of compound orientations needed to successfully bind at either of the distinct allosteric sites. X-ray crystallographic analyses of these two effectors in complex with Hb revealed that they successfully spanned the RSR4 primary and secondary binding sites. However, the designed compounds interacted with the secondary binding site in such a way that intra-dimer, as opposed to inter-dimer, interactions were generated. In agreement with these observations, in vitro evaluation of the symmetrical effectors in Hb solution indicated that neither compound possessed the potency of RSR4. A detailed analysis of symmetrical effector-Hb contacts and comparisons with the binding contacts of RSR4 are discussed.