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Health Psychology and Aging. Health Psychology. Also, “behavioural medicine” Role of behaviour in promoting health, preventing and treating disease New Relatively little behavioural genetics work. Body Weight. Genetic factors account for majority of variance in weight
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Health Psychology • Also, “behavioural medicine” • Role of behaviour in promoting health, preventing and treating disease • New • Relatively little behavioural genetics work
Body Weight • Genetic factors account for majority of variance in weight • MZ, reared together = 0.8 • MZ, reared apart = 0.72 • DZ, reared together = 0.43 • Biological parents & offspring = 0.26 • Biological parents & adopted away offspring = 0.23 • Adoptive parents & adopted offspring = 0.01 • Heritability about 70% • Shared environment effects low
Obesity • Natural energy reserves (fatty tissue) exceeds healthy limits • Absolute or relative terms • Body mass index • Weight/height2 • Exceeds 30kg/m2
Co-morbidity • Osteoarthritis • Obstructive sleep apnea • Diabetes • Cancer • Cardiovascular disease
Environmental Factors • Overeating • High caloric, “energy-dense” foods • Fast food consumption tripled and calorie intake quadrupled between 1977-1995 in North America • Sedentary lifestyle
Genetics • Prader-Willi syndrome • 7 gene deletion, chromosome 15q • Bardet-Biedl syndrome • 12 genes, chromosome 11 or 16 • BBS proteins • MOMO syndrome • Extremely rare (1 in 100 million births); seems to be autosomal dominant mutation • Leptin receptor mutations • Regulates adipose-tissue mass • Melanocortin receptor mutations • G-protein coupled receptors; account for 6% of early-onset obesity • Single-locus mutations only account for 7% of all cases of obesity
Neurobiological Mechanisms • Leptin • Produced by adipose tissue • Signals fat storage reserves in body • Mediates long-term appetite controls (eat more when fat stores low, less when stores are high) • Ghrelin • Produced by stomach • Modulates short-term appetite control (eat when empty, stop when stretched) • Both produced peripherally, but act on CNS, primarily hypothalamus
Hypothalamus • Several circuits contribute to hypothalamus’ involvement in appetite • Melanocortin pathway • Arcuate nucleus (AN) --> lateral hypothalamus (LH) and ventromedial hypothalamus (VMH) • LH = brain’s feeding centre VMH = brain’s satiety centre • When AN neurons activated --> appetite • Neurons inhibited by circulating leptin and ghrelin
Leptin • Leptin originally discovered 1950s; homozygous mutation --> obese mice • But, not the primary cause of obesity in humans • Over 240 other mouse genes identified in weight <wikipedia.org/wiki/Image:Fatmouse.jpg>
FTO • Obesity risk allele • 10 SNPs in first intron of FTO; chromosome 16 • About 39,000 Europeans studied (Frayling et al. (2007)) • Versus individuals with no variant copy: • One copy, average 1.2kg heavier; 30% increased risk of obesity • Two copies (16% of subjects), average 3kg heavier, 70% increased risk of obesity • Ethnic differences in copy variant frequencies • 45% West/Central Europeans; 52% West African; 14% Chinese and Japanese
Addictions • Typically, some form of chemical use • Substance alters body physiology and/or neurochemistry • Recurring compulsion • Questions about other addictions • E.g., food, gambling, sex • Suggestions that these may be components of obsessive compulsive disorder, not addictions, per se
Alcoholism • Runs in families • 40% and 20% risk for first degree male and female relatives of alcoholic proband, respectively • 20% and 5% for general male and female population, respectively • Assortative mating for alcohol use high (0.38) • Could be inflating shared environment estimates
Male Twin Studies • Moderate heritability for males, modest for females • E.g., Concordances: MZ ~ 50%, DZ ~35% • Heritability ~0.6 • Early onset and more severe alcoholism is more heritable
Female Twin Studies • Inconsistent results • Heritability figures range from 0.25 to 0.55
Shared Environment • Related to initial alcohol use in teens and young adults, but not to later alcohol abuse • Effect on siblings, not parents and offspring • Correlation for alcohol abuse in parents and biological teens 0.3, but only 0.04 for adopted teens • Correlation for alcohol abuse in unrelated adopted siblings 0.24 (0.45 for same sex, 0.01 for opposite sex) • Sibling and/or peer effects more important than parent effects in adolescence
Genotype-Environment Interaction • Genetic risk for alcoholism greater in more permissive environments • Heritability lower for: • Married individuals • People with strong religious upbringing • People from stricter and closer families • Regions with lower alcohol sales
Animal Models • Long sleep (LS) and short sleep (SS) mice • Inbred strain • After 18 generations LS mice “slept” for average of 2 hours post alcohol; SS mice only for about 10 minutes • Lot of variation in LS (1.2 - 4.4 hours); less in SS (0 - 0.65 hours)
Alcohol Response Polygenic • Suggests many genes involved • Steady divergence over 18 generations (1 or 2 genes would have stabilized much sooner) • Variability in sleep times for LS and SS • Different responses by LS & SS strains to other drugs (e.g., cocaine, morphine) • QTL mapping and knockout studies identify 5 genes for dopamine D2 receptor • Each gene accounts for 20 minutes of sleep; five about 130 minutes of total 170 minute difference between LS and SS mice
Dopamine D4 receptor knockout --> supersensitivity to alcohol, cocaine, methamphetamine • Serotonin receptor knockout --> increased alcohol consumption
Humans • Ethnic differences • Mutant ALDH2 allele • Inactivates key enzyme in alcohol metabolism • 25% Chinese, 40% Japanese, almost no Caucasians • But, this and other genes don’t show consistent effects even within ethnic groups
Smoking • MZ concordance, 75% • DZ concordance, 63% • Heritability about 60% with some shared environmental effects • Like alcohol, less parents, more peers and siblings
Aging • Tricky • Older individuals vary greatly biologically and psychologically • So, grouping into “elderly” for analysis not very effective • Relatively little behavioural genetics work on second half of lifespan • Traditional nurturist/behaviourist carry-over?
Effects • Specific types (e.g., Alzheimer’s) • General cognitive decline • Various tests, e.g., Informant Questionnaire on Cognitive Decline in the Elderly (IQCODE) • Differences in abilities • Fluid abilities decline (e.g., spatial) • Crystallized abilities improve (e.g., vocabulary) • Both equally heritable
Personality traits remarkably stable across adult lifespan; large genetic effect here • Heritabilities of late life psychopathology and personality disorders very similar to younger rates • Longevity only has modest genetic effects (heritability about 25%)