Longitudinal follow-up of late-onset Alzheimer disease families.

Historically, data for genetic studies are collected at one time point. However, for diseases with late onset or with complex phenotypes, such as Alzheimer disease (AD), restricting diagnosis to a single ascertainment contact may not be sufficient. Affection status may change over time and some initial diagnoses may be inconclusive. Follow-up provides the opportunity to resolve these complications. However, to date, previous studies have not formally demonstrated that longitudinally re-contacting families is practical or productive. To update data initially collected for linkage analysis of late-onset Alzheimer disease (LOAD), we successfully re-contacted 63 of 81 (78%) multiplex families (two to 17 years after ascertainment). Clinical status changed for 73 of the 230 (32%) non-affected participants. Additionally, expanded family history identified 20 additional affected individuals to supplement the data set. Furthermore, fostering ongoing relationships with participating families helped recruit 101 affected participants into an autopsy and tissue donation program. Despite similar presentations, discordance between clinical diagnosis and neuropathologic diagnosis was observed in 28% of those with tissue diagnoses. Most of the families were successfully re-contacted, and significant refinement and supplementation of the data was achieved. We concluded that serial contact with longitudinal evaluation of families has significant implications for genetic analyses.

Lack of association between UBQLN1 and Alzheimer disease.

Alzheimer disease (AD) is heterogeneous and complex with a strong genetic diathesis. It is the most common cause of dementia affecting the elderly. Linkage studies [Kehoe et al., 1999; Hum Mol Genet 8: 237-245]; [Pericak-Vance et al., 2000; Exp Gerontol 35: 1343-1352]; [Myers et al., 2002; Am J Med Genet 114: 235-244]; [Blacker et al., 2003; Hum Mol Genet 12: 23-32] identified chromosome 9q as a region containing a possible AD candidate gene. Functional protein studies [Mah et al., 2000; J Cell Biol 151: 847-862]; [Ko et al., 2002; J Biol Chem 277: 35386-35392] identified the UBQLN1 gene on chromosome 9q that encodes ubiquilin as a likely candidate for a role in late-onset AD pathogenesis. A recent family-based study by [Bertram et al., 2005; N Engl J 352: 884-894] reported genetic association and expression evidence for a putative AD risk allele of an intronic single nucleotide polymorphism (SNP) within the UBQLN1 gene. In this study, we comprehensively assessed whether any of seven polymorphisms located across the UBQLN1 gene are associated with AD in another large family-based data set and an independent case-control data set. We found no significant association of AD risk with any of the seven SNPs genotyped (including those SNPs previously reported by Bertram et al.) in either the family-based or case-control data set. Age-specific analyses and analyses conditional on Apolipoprotein E (ApoE) genotype and sex also revealed no significant associations to AD risk in either data set. Using age at onset (AAO) as a quantitative trait revealed a modest age modifying association; however, the results were inconsistent between the data sets. Our results suggest that UBQLN1 variants do not increase risk for AD in these data.

A genetic linkage map of the baboon (Papio hamadryas) genome based on human microsatellite polymorphisms.

A first-generation genetic linkage map of the baboon (Papio hamadryas) genome was developed for use in biomedical and evolutionary genetics. Pedigreed baboons (n = 694) were selected from the breeding colony maintained by the Southwest Foundation for Biomedical Research. To facilitate comparison with the human genome, the baboon linkage map consists primarily of human microsatellite loci amplified using published human PCR primers. Genotypes for 325 human microsatellites and 6 novel baboon microsatellites were used in linkage analyses performed with the MultiMap expert system. The resulting sex-averaged meiotic recombination map covers all 20 baboon autosomes, with average spacing among loci of 7.2 cM. Direct comparison among homologous (orthologous) loci reveals that, for 7 human autosomes, locus order is conserved between humans and baboons. For the other 15 autosomes, one or more rearrangements distinguish the two genomes. The total centimorgan distances among homologous markers are 28.0% longer in the human genome than in the baboon, suggesting that rates of recombination may be higher in humans. This baboon linkage map is the first reported for any nonhuman primate species and creates opportunities for mapping quantitative trait loci in baboons, as well as for comparative evolutionary analyses of genome structure.