Thermodynamic study of transthyretin association (wild-type and senile forms) with heparan sulfate proteoglycan: pH effect and implication of the reactive histidine residue.

The tetramer destabilization of transthyretin into monomers and its fibrillation are phenomena leading to amyloid deposition. Heparan sulfate proteoglycan (HSPG) has been found in all amyloid deposits. A chromatographic approach was developed to compare binding parameters between wild-type transthyretin (wtTTR) and an amyloidogenic transthyretin (sTTR). Results showed a greater affinity of sTTR for HSPG at pH 7.4 compared with wtTTR owing to the monomeric form of sTTR. Analysis of the thermodynamic parameters showed that van der Waals interactions were involved at the complex interface for both transthyretin forms. For sTTR, results from the plot representing the number of protons exchanged vs pH showed that the binding mechanism was pH-dependent with a critical value at a pH 6.5. This observation was due to the protonation of a histidine residue as an imidazolium cation, which was not accessible when TTR was in its tetrameric structure. At pH >6.5, dehydration at the binding interface and several contacts between nonpolar groups of sTTR and HSPG were also coupled to binding for an optimal hydrogen-bond network. At pH <6.5, the protonation of the His residue from sTTR monomer when pH decreased broke the hydrogen-bond network, leading to its destabilization and thus producing slight conformational changes in the sTTR monomer structure.

The protease activity of transthyretin reverses the effect of pH on the amyloid-ß protein/heparan sulfate proteoglycan interaction: a biochromatographic study.

Patients suffering of Alzheimer's disease (AD) are characterized by a low transthyretin (TTR) level in the brain. The effect of pH and TTR concentration in the medium on the ß-amyloid protein (Aß)/heparan sulfate proteoglycan (HSPG) association mechanism were studied using a biochromatographic approach. For this purpose, HSPG was immobilized via amino groups onto the amino propyl silica pre-packed column, activated with glutaraldehyde, by using the Schiff base method. Using an equilibrium perturbation method, it was clearly shown that Aß can be bound with HSPG. This approach allowed the determination of the thermodynamic data of this binding mechanism. The role of the pH was also analyzed. Results from enthalpy-entropy compensation and the plot of the number of protons exchanged versus pH showed that the binding mechanism was dependent on pH with a critical value at pH=6.5. This value agreed with a histidine protonation as an imidazolium cation. Moreover, the corresponding thermodynamical data showed that at pH>6.5, van der Waals and hydrogen bonds due to aromatic amino acids as tyrosine or phenylalanine present in the N-terminal (NT) part governed the Aß/HSPG association. Aß remained in its physiological structure in a random coil form (i.e. the non-amyloidogenic structure) because van der Waals interactions and hydrogen bonds were preponderant. At acidic pH (pH<6.5), ionic and hydrophobic interactions, created by histidine protonation and hydrophobic amino acids, appeared in the Aß/HSPG binding. These hydrophobic and ionic interactions led to the conversion of the random coil form of Aß into a ß-sheet structure which was the amyloidogenic folding. When TTR was incubated with Aß, the Aß/HSPG association mechanism was enthalpy driven at all pH values. The affinity of Aß for HSPG decreased when TTR concentration increased due to the complexation of Aß with TTR. Also, the decrease of the peak area with the increase of TTR concentration demonstrated that this Aß/TTR association led to the cleavage of Aß full length to a smaller fragment. For acidic pH (pH<6.5), it was shown that the importance of the hydrophobic and ionic interactions decreased when TTR concentration increased. This result confirmed that Aß was cleaved by TTR in a part containing only the NT part. Our results demonstrated clearly that TTR reversed the effect of acidic pH and thus played a protective role in AD.

Synthesis of new pyrrolo[1,2-a]quinoxaline derivatives as potential inhibitors of Akt kinase.

Akt kinases are attractive targets for small molecule drug discovery because of their key role in tumor cell survival/proliferation and their overexpression/activation in many human cancers. Recent efforts in the development and biological evaluation of small molecule inhibitors of Akt have led to the identification of novel Akt kinase inhibitors, based on a quinoxaline or pyrazinone scaffold. A series of new substituted pyrrolo[1,2-a]quinoxaline derivatives, structural analogues of these active quinoxaline or pyrazinone pharmacophores, was synthesized from various substituted 2-nitroanilines or 1,2-phenylenediamine via multistep heterocyclization process. These new compounds were tested for their in vitro ability to inhibit the proliferation of the human leukemic cell lines K562, U937 and HL60, and the breast cancer cell line MCF7. Three of these human cell lines (K562, U937 and MCF7) exhibited an active phosphorylated Akt form. The most promising active pyrroloquinoxalines were found to be 1a that inhibited K562 cell line proliferation with an IC(50) of 4.5 microM, and 1h that inhibited U937 and MCF7 cell lines with IC(50) of 5 and 8 microM, respectively. These two candidates exhibited more potent activities than the reference inhibitor A6730.