Alzheimer's risk associated with human apolipoprotein E, alpha-2 macroglobulin and lipoprotein receptor related protein polymorphisms: absence of genetic interactions, and modulation by gender.

Apolipoprotein E (apoE), the lipoprotein receptor related protein (LRP) and alpha-2 macroglobulin (alpha2M) have been proposed as a functional complex involved in amyloid clearance, a crucial event for Alzheimer's disease development. In this work, we present an epidemiological approach aimed to study the interactions among these genes, age and gender. This approach did not reveal significant associations between the genes; however, the present study indicated that the risk associated with APOE promoter and LRP gene polymorphisms is modulated by gender.

A polymorphism in the tau gene associated with risk for Alzheimer's disease.

Searching for tau genetic variations which could be associated with risk for Alzheimer's disease (AD), we have performed a mutational analysis of a region containing the whole exon 11 of the tau gene, which encodes a microtubule binding region critical for tau self-assembly, and we have found a biallelic polymorphism at position +34 of intron 11 (IVS11 + 34G/A). We have analyzed the allelic frequencies of this polymorphism in a case-control sample (167 clinically diagnosed AD and 194 controls) and found that the presence of any G allele (genotypes AG + GG) is associated with a five-fold AD risk in individuals carrying the apolipoprotein E4 allele, strongly suggesting that the combined effect of tau and apoE is relevant in relation with AD pathogenesis.

DGGE method for the mutational analysis of the coding and proximal promoter regions of the Alzheimer's disease presenilin-1 gene: two novel mutations.

Many different mutations that cause Alzheimer's disease (AD) have been found in the presenilin-1 gene (PSEN1) and are associated with the most aggressive forms of the disease. With the aim of screening for PSEN1 genetic variations, we developed a method based on denaturing gradient gel electrophoresis (DGGE) that allows the mutational analysis of all the coding exons and the proximal promoter of PSEN1 using only four DGGE gels. The analysis by this methodology of a sample of 58 early-onset AD (EOAD) patients nonselected for family history resulted in finding four genetic variants within the PSEN1 coding region, two of which are novel mutations (M233L and A409T), whereas the other two have been reported previously (L282R and E318G). We also found a novel mutation within the PSEN1 proximal promoter (-280 C-->G) that, interestingly, provokes significant changes in the transcriptional activity of the gene in cell lines of neuronal and astrocytic, but not hepatic origin. These data strongly suggest that the region around -280 of PSEN1 promoter contains a regulatory element that controls its transcription specifically in neural cells.

Identification of a novel mutation (Leu282Arg) of the human presenilin 1 gene in Alzheimer's disease.

Many different mutations, causative of Alzheimer's disease, have been found in the presenilin-1 gene (PS-1). We have developed a screening method based on denaturing gradient gel electrophoresis (DGGE), which allows the mutational analysis of the whole exon 9 of PS-1. Upon the screening of a Spanish sample of early onset familial Alzheimer disease cases, we have found a novel mutation in the PS-1 gene. The mutation (a T to G transition) results in a change of the amino acid at position 282 of the presenilin protein from leucine to arginine. This mutation is located in the hydrophobic domain number 7 (exon 9) close to the site of physiological cleavage processing. The average of onset of the affected members of this family is 43+/-5 years, and the average age of exitus of affected members is 56+/-3 years. The possibility to determine the specific pathologic mechanisms of this mutation is now open.

Allelic polymorphisms in the transcriptional regulatory region of apolipoprotein E gene.

In this work, we explored the existence of genetic variants within the apolipoprotein E gene transcriptional regulatory region, using a denaturing gradient gel electrophoresis screening of a region comprising nucleotides -1017 to +406. Upon a population study, three new polymorphic sites (-491, -427 and -219) and two mutations were found. Functional effects of the polymorphisms, assayed by transient transfection and electrophoretic mobility shift assays in a human hepatoma cell line, showed that polymorphisms at sites -491 and -219 of the APOE promoter produce variations in the transcriptional activity of the gene, most probably through differential binding of nuclear proteins.

A polymorphism in the regulatory region of APOE associated with risk for Alzheimer's dementia.

The epsilon4 allele of the apolipoprotein E gene (APOE) has been associated with an increased risk of developing Alzheimer's disease (AD; refs 1,2). However, it is apparent that the APOEepsilon4 allele alone is neither necessary nor sufficient to cause the disease. We have recently found three new polymorphisms within the APOE transcriptional regulatory region (M.J.A. et al., manuscript submitted) and now establish an association between one of these polymorphisms (-491A/T) and dementia as observed in Alzheimer's disease, in two independent clinical populations. The results suggest that homozygosity of a common variant (-491A) is associated with increased risk for AD, and that this association is independent of APOEepsilon4 status. In vitro studies suggest that the -491A/T polymorphism may increase risk for AD by altering the level of ApoE protein expression.

Proteolysis of Alzheimer's disease beta-amyloid precursor protein by factor Xa.

Amyloid beta-protein is a 4-kDa peptide which originates from proteolysis of a larger protein precursor (APP) and accumulates in senile plaques in brains of Alzheimer's disease (AD) patients. Since secreted APP inhibits factors IXa, Xa and XIa, and thrombin appears to play a role in APP secretion and proteolysis, a relationship between hemostasis system and APP metabolism seems to exist. In this work we investigate the susceptibility to proteolytic cleavage by factor Xa of a fusion construct containing full-length APP prepared in bacteria, and demonstrate that both APP695 and APP770 are substrates for this protease. Factor Xa was found to cleave APP after arginines 102, 268, 510, 573 and 601 (APP695 numeration); most of these sites appear to be common for different coagulation factors. In addition, APP incubation with factor Xa generates an array of six potentially amyloidogenic fragments. Comparative kinetic analysis of APP695 and APP770 cleavage by factor Xa suggests that Kunitz-type inhibitor-containing isoforms exert an inhibitory effect on the protease. However, this inhibition is far from complete even at a 5-fold molar excess of inhibitor. Our results raise the possibility that proteases from the coagulation cascade may contribute to APP proteolysis, and support the notion that these proteases play a role in AD pathogenesis.

Location of an epitope shared by Alzheimer's amyloid peptide and brain creatine kinase using a newly developed monoclonal antibody.

Amyloid plaques, composed mainly by a peptide termed A4-amyloid, derived by proteolytic processing from the amyloid precursor protein (APP), are a hallmark in the brain of Alzheimer's disease patients. We have prepared a collection of monoclonal antibodies as tools to study APP expression and proteolysis in different systems. One of these, 5AH10, raised against residues 9-22 of A4-peptide, was selected for its ability to recognize only A4 subpeptides having the intact APP-secretase target sequence, as well as whole recombinant APP. By using synthetic subpeptides, we have located 5AH10 epitope between amino acids 15 and 22 of A4. In addition, 5AH10 showed a strong immunoreactivity to a 47 kDa protein present in rat brain extracts, that was identified as the B (brain specific) subunit of creatine kinase by immunochemical data and direct N-terminal sequencing. The cross-reaction observed is most probably due to a high degree of sequence identity between amino acids 15 to 22 of A4 peptide and amino acids 9 to 16 of rat B creatine kinase. 5AH10 did not recognize the muscle specific isoform (M subunit) of rat creatine kinase, nor the B subunit of human and rabbit creatine kinase, suggesting that glutamine at first position of the epitope is essential for antigen recognition by 5AH10.