Psychiatric genetics

Psychiatric genetics, a subfield of behavioral neurogenetics and behavioral genetics, studies the role of genetics in psychiatric conditions such as alcoholism, schizophrenia, bipolar disorder, and autism. The basic principle behind psychiatric genetics is that genetic polymorphisms, as indicated by linkage to e.g. a single nucleotide polymorphism (SNP), are part of the etiology of psychiatric disorders.[1]

Psychiatric genetics is a somewhat new name for an old question, "Are behavioral and psychological conditions and deviations inherited".[2] The goal of psychiatric genetics is to better understand the etiology of psychiatric disorders, to use that knowledge to improve treatment methods, and possibly also to develop personalized treatments based on genetic profiles (see pharmacogenomics). In other words, the goal is to transform parts of psychiatry into a neuroscience-based discipline.[3]

History

Research on psychiatric genetics began in the late nineteenth century with Francis Galton (a founder of psychiatric genetics) who was motivated by the work of Charles Darwin and his concept of desegregation. These methods of study later improved due to the development of more advanced clinical, epidemiological, and biometrical research tools. Better research tools were the precursor to the ability to perform valid family, twin, and adoption studies. Researchers learned that genes influence how these disorders manifest and that they tend to aggregate in families.[2]

[4] [5] [6] [7]

Heritability and genetics

Most psychiatric disorders are highly heritable; the estimated heritability for bipolar disorder, schizophrenia, and autism (80% or higher) is much higher than that of diseases like breast cancer and Parkinson disease.[1] Having a close family member affected by a mental illness is the largest known risk factor, to date.[8] However, linkage analysis and genome-wide association studies have found few reproducible risk factors.[1]

Heterogeneity is an important factor to consider when dealing with genetics. Two types of heterogeneity have been identified in association with psychiatric genetics: causal and clinical. Causal heterogeneity refers to a situation in which two or more causes can independently induce the same clinical syndrome. Clinical heterogeneity refers to when a single cause can lead to more than one clinical syndrome.[9]

Several genetic risk factors have been found with the endophenotypes of psychiatric disorders, rather than with the diagnoses themselves. That is, the risk factors are associated with particular symptoms, not with the overall diagnosis.[1] In psychiatry, endophenotypes are a way of objectively measuring certain internal processes in a reliable way that is often lacking the diseases with which they are associated.[10] They lie in the space between genes and disease process and allow for some understanding of the biology of psychiatric diseases.[10]

A systematic comparative analysis of shared and unique genetic factors highlighted key gene sets and molecular processes underlying six major neuropsychiatric disorders: attention deficit hyperactivity disorder, anxiety disorders, autistic spectrum disorders, bipolar disorder, major depressive disorder, and schizophrenia.[11] This may ultimately translate into improved diagnosis and treatment of these debilitating disorders.

Methodology

Linkage, association, and microarray studies generate raw material for findings in psychiatric genetics.[12] Copy number variants have also been associated with psychiatric conditions.[13]

Genetic Linkage studies attempt to find a correlation between the diagnosis and inheritance of certain alleles within families who have two or more ill relatives. An analysis of a linkage study uses a wide chromosomal region, whereas a genetic association study endeavors to identify a specific DNA polymorphism, which can be a deletion, inversion, or repletion of a sequence.[14] Case-control association studies can be used as an exploratory tool for narrowing the area of interest after preliminary mapping of a gene by a linkage study.[15]

Predictive genetic testing

There are many way in which genetics are becoming more and more important every day. One hope for future genetic testing is the ability to test for presymptomatic or prenatal illnesses. This information has the potential to improve the lives of those affected with certain illnesses, specifically those like schizophrenia. If possible to test for schizophrenia before the symptoms develop, proactive interventions could be developed, or even preventative treatments.[9] In one study, 100% of patients with bipolar disorder indicated that they would probably take a genetic test to determine if he or she were carrying a gene associated with the disorder, if such a test existed.[8]

Ethical issues

Francis Galton studied both desirable and undesirable behavioral and mental properties to better examine the world of genetics. His research led to his proposal of a eugenic program of birth control.[16] His goal was to decrease the frequency of the less desirable traits that occurred throughout the population. His ideas were pursued by psychiatrists in many countries such as the United States, Germany and Scandinavia.[2][17]

Genotyping and its implications are still seen as ethically controversial by many people. The ELSI (Ethical, Legal, and Social Initiative), which is part of the Human Genome Project, was created with the aim of "foster[ing] basic and applied research on the ethical, legal and social implications of genetic and genomic research for individuals, families and communities.".[18]

See also

References

  1. 1 2 3 4 Burmeister M, McInnis MG, Zöllner S (2008). "Psychiatric genetics: progress amid controversy". Nat Rev Genet. 9 (7): 527–40. doi:10.1038/nrg2381. PMID 18560438.
  2. 1 2 3 Maier, Wolfgang (2003). "Psychiatric genetics: overview on achievements, problems, perspectives". In Leboyer, M, Bellivier, F. Psychiatric genetics: methods and reviews. Humana Press. pp. 1–20.
  3. Züchner S, Roberts ST, Speer MC, Beckham JC (2007). "Update on psychiatric genetics". Genet Med. 9 (6): 332–40. doi:10.1097/GIM.0b013e318065a9fa. PMID 17575499.
  4. Owen, MJ; Cardno, AG.; O'Donovan, MC. (2000). "Psychiatric genetics: back to the future". Molecular Psychiatry. 5 (1): 22–31. doi:10.1038/sj.mp.4000702.
  5. Sebat, J.; et al. (2007). "Strong association of de novo copy number mutations with autism". Science. 316 (5823): 445–9. doi:10.1126/science.1138659. PMC 2993504Freely accessible. PMID 17363630.
  6. Stefansson, H.; et al. (2008). "Large recurrent microdeletions associated with schizophrenia". Nature. 455 (7210): 232–6. doi:10.1038/nature07229. PMC 2687075Freely accessible. PMID 18668039.
  7. Knight, S.; et al. (1999). "Subtle chromosomal rearrangements in children with unexplained mental retardation". The Lancet. 354 (9191): 1676–81. doi:10.1016/S0140-6736(99)03070-6. PMID 10568569.
  8. 1 2 Blacker, D., Racette, S. R., Sklar, P., & Smoller, J. W. (2005). Psychiatric genetics: a survey of psychiatrists’ knowledge, opinions, and practice patterns. J Clin Psychiatry, 66(7), 821-830.
  9. 1 2 Tsuang, M., Taylor, L., Faraone, S. (2003). "Psychiatric genetics: future and prospects". In Leboyer, M, Bellivier, F. Psychiatric genetics: methods and reviews. Humana Press. pp. 251–265.
  10. 1 2 Flint, J., Munafo, M (February 2001). "The endophenotype concept in psychiatric genetics". Psychological Medicine 37 (2): 163–180.
  11. Lotan, Amit; Fenckova, Michaela; Bralten, Janita; Alttoa, Aet; Dixson, Luanna; Williams, Robert W.; van der Voet, Monique (2014-01-01). "Neuroinformatic analyses of common and distinct genetic components associated with major neuropsychiatric disorders". Neurogenomics. 8: 331. doi:10.3389/fnins.2014.00331.
  12. Konneker T, Barnes T, Furberg H, Losh M, Bulik CM, Sullivan PF (2008). "A searchable database of genetic evidence for psychiatric disorders". Am J Med Genet B Neuropsychiatr Genet. 147b (6): 671–5. doi:10.1002/ajmg.b.30802. PMC 2574546Freely accessible. PMID 18548508.
  13. Bourgeron, T., Giros, B.,(2003). " Genetic Markers in Psychiatric Genetics". In Leboyer, M, Bellivier, F. Psychiatric genetics: methods and reviews. Humana Press. pp. 63–98.
  14. Levinson, D. F. (2005). Meta-analysis in psychiatric genetics. Current psychiatry reports, 7(2), 143-152.
  15. Bellivier, F. (2003). "Genetic association studies: definition of cases and controls". In Leboyer, M, Bellivier, F. Psychiatric genetics: methods and reviews. Humana Press. pp. 127–141.
  16. "The Possible Improvement of the Human Breed Under the Existing Conditions of Law and Sentiment". Nature. 64 (1670): 659–665. doi:10.1038/064659b0.
  17. Eugenics and the Welfare State: Norway, Sweden, Denmark, and Finland. Michigan State University Press. 2005. ISBN 978-0870137587.
  18. "ELSI Research Program Overview". Retrieved 2016-05-31.
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