TY - JOUR
T1 - The apolipoprotein E/CI/CII gene cluster and late-onset Alzheimer disease
AU - Yu, Chang En
AU - Payami, Haydeh
AU - Olson, Jane M.
AU - Boehnke, Michael
AU - Wijsman, Ellen M.
AU - Orr, Harry T.
AU - Kukull, Walter A.
AU - Goddard, Katrina A B
AU - Nemens, Ellen
AU - White, June A.
AU - Alonso, M. Elisa
AU - Taylor, Todd D.
AU - Ball, Melvyn J.
AU - Kaye, Jeffrey
AU - Morris, John
AU - Chui, Helena
AU - Sadovnick, Adele D.
AU - Martin, George M.
AU - Larson, Eric B.
AU - Heston, Leonard L.
AU - Bird, Thomas D.
AU - Schellenberg, Gerard D.
PY - 1994
Y1 - 1994
N2 - The chromosome 19 apolipoprotein E/CI/CII gene cluster was examined for evidence of linkage to a familial Alzheimer disease (FAD) locus. The family groups studied were Volga German (VG), early-onset non-VG (ENVG; mean age at onset <60 years), and late-onset families. A genetic association was observed between apolipoprotein E (ApoE) allele ε4 and FAD in late-onset families; the ε4 allele frequency was .51 in affected subjects, .37 in at-risk subjects, .11 in spouses, and .19 in unrelated controls. The differences between the ε4 frequencies in affected subjects versus controls and in at- risk subjects versus controls were highly significant (standard normal deviate [Z(SND)]) = 7.37, P < 10 -9; and Z(SND) = 4.07, P < .00005, respectively). No association between the ε4 allele and FAD was observed in the ENVG or VG groups. A statistically significant allelic association between ε4 and AD was also observed in a group of unrelated subjects; the ε4 frequency was .26 in affected subjects, versus .19 in controls (Z(SND) = 2.20, P < .03). Evidence of linkage of ApoE and ApoCII to FAD was examined by maximum-likelihood methods, using three models and assuming autosomal dominant inheritance: (1) age-dependent penetrance, (2) extremely low (1%) penetrance, and (3) age-dependent penetrance corrected for sporadic Alzheimer disease (AD). For ApoCII in late-onset families, results for close linkage were negative, and only small positive lod-score-statistic (Z) values were obtained (model 1, maximum Z [Z(max)] = 0.61, recombination fraction [θ] = .30; model 2, Z(max) = 0.47, θ = .20). For ApoE in late-onset kindreds, positive Z values were obtained when either allele frequencies from controls (model 1, Z(max) = 2.02, θ = .15; model 2, Z(max) = 3.42, θ = .05) or allele frequencies from the families (model 1, Z(max) = 1.43, θ = .15; model 2, Z(max) = 1.70, θ = .05) were used. When linkage disequilibrium was incorporated into the analysis, the Z values increased (model 1, Z(max) = 3.17, θ = .23; model 3, Z(max) = 1.85, θ = .20). For the ENVG group, results for ApoE and ApoCII were uniformly negative. Affected-pedigree- member analysis gave significant results for the late-onset kindreds, for ApoE (Z(SND) = 3.003, P = .003) and ApoCII (Z(SND) = 2.319, P = .016), when control allele frequencies were used but not when allele frequencies were derived from the families.
AB - The chromosome 19 apolipoprotein E/CI/CII gene cluster was examined for evidence of linkage to a familial Alzheimer disease (FAD) locus. The family groups studied were Volga German (VG), early-onset non-VG (ENVG; mean age at onset <60 years), and late-onset families. A genetic association was observed between apolipoprotein E (ApoE) allele ε4 and FAD in late-onset families; the ε4 allele frequency was .51 in affected subjects, .37 in at-risk subjects, .11 in spouses, and .19 in unrelated controls. The differences between the ε4 frequencies in affected subjects versus controls and in at- risk subjects versus controls were highly significant (standard normal deviate [Z(SND)]) = 7.37, P < 10 -9; and Z(SND) = 4.07, P < .00005, respectively). No association between the ε4 allele and FAD was observed in the ENVG or VG groups. A statistically significant allelic association between ε4 and AD was also observed in a group of unrelated subjects; the ε4 frequency was .26 in affected subjects, versus .19 in controls (Z(SND) = 2.20, P < .03). Evidence of linkage of ApoE and ApoCII to FAD was examined by maximum-likelihood methods, using three models and assuming autosomal dominant inheritance: (1) age-dependent penetrance, (2) extremely low (1%) penetrance, and (3) age-dependent penetrance corrected for sporadic Alzheimer disease (AD). For ApoCII in late-onset families, results for close linkage were negative, and only small positive lod-score-statistic (Z) values were obtained (model 1, maximum Z [Z(max)] = 0.61, recombination fraction [θ] = .30; model 2, Z(max) = 0.47, θ = .20). For ApoE in late-onset kindreds, positive Z values were obtained when either allele frequencies from controls (model 1, Z(max) = 2.02, θ = .15; model 2, Z(max) = 3.42, θ = .05) or allele frequencies from the families (model 1, Z(max) = 1.43, θ = .15; model 2, Z(max) = 1.70, θ = .05) were used. When linkage disequilibrium was incorporated into the analysis, the Z values increased (model 1, Z(max) = 3.17, θ = .23; model 3, Z(max) = 1.85, θ = .20). For the ENVG group, results for ApoE and ApoCII were uniformly negative. Affected-pedigree- member analysis gave significant results for the late-onset kindreds, for ApoE (Z(SND) = 3.003, P = .003) and ApoCII (Z(SND) = 2.319, P = .016), when control allele frequencies were used but not when allele frequencies were derived from the families.
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M3 - Article
C2 - 8128960
AN - SCOPUS:23444438235
SN - 0002-9297
VL - 54
SP - 631
EP - 642
JO - American Journal of Human Genetics
JF - American Journal of Human Genetics
IS - 4
ER -