Warning: Undefined array key "mm" in /www/wwwroot/www.ai-bt.com/si.php on line 10 Deprecated: trim(): Passing null to parameter #1 ($string) of type string is deprecated in /www/wwwroot/www.ai-bt.com/si.php on line 10 Quantitative genetic analysis of brain size variation in sticklebacks: support for the mosaic model of brain evolution.

Literature DB >> 26108633

Quantitative genetic analysis of brain size variation in sticklebacks: support for the mosaic model of brain evolution.

Kristina Noreikiene¹, Gábor Herczeg², Abigél Gonda¹, Gergely Balázs³, Arild Husby⁴, Juha Merilä⁵.

Abstract

The mosaic model of brain evolution postulates that different brain regions are relatively free to evolve independently from each other. Such independent evolution is possible only if genetic correlations among the different brain regions are less than unity. We estimated heritabilities, evolvabilities and genetic correlations of relative size of the brain, and its different regions in the three-spined stickleback (Gasterosteus aculeatus). We found that heritabilities were low (average h(2) = 0.24), suggesting a large plastic component to brain architecture. However, evolvabilities of different brain parts were moderate, suggesting the presence of additive genetic variance to sustain a response to selection in the long term. Genetic correlations among different brain regions were low (average rG = 0.40) and significantly less than unity. These results, along with those from analyses of phenotypic and genetic integration, indicate a high degree of independence between different brain regions, suggesting that responses to selection are unlikely to be severely constrained by genetic and phenotypic correlations. Hence, the results give strong support for the mosaic model of brain evolution. However, the genetic correlation between brain and body size was high (rG = 0.89), suggesting a constraint for independent evolution of brain and body size in sticklebacks.

Entities: Species

Keywords: brain size; evolvability; genetic correlation; heritability; integration

Mesh：

Year: 2015 PMID： 26108633 PMCID： PMC4590490 DOI： 10.1098/rspb.2015.1008

Source DB: PubMed Journal: Proc Biol Sci ISSN： 0962-8452 Impact factor: 5.349

37 in total

1. Evolutionary radiations and convergences in the structural organization of mammalian brains.

Authors: W de Winter; C E Oxnard
Journal: Nature Date: 2001-02-08 Impact factor: 49.962

2. Variation in the volume of zebra finch song control nuclei is heritable: developmental and evolutionary implications.

Authors: D C Airey; H Castillo-Juarez; G Casella; E J Pollak; T J DeVoogd
Journal: Proc Biol Sci Date: 2000-10-22 Impact factor: 5.349

3. The master sex-determination locus in threespine sticklebacks is on a nascent Y chromosome.

Authors: Catherine L Peichel; Joseph A Ross; Clinton K Matson; Mark Dickson; Jane Grimwood; Jeremy Schmutz; Richard M Myers; Seiichi Mori; Dolph Schluter; David M Kingsley
Journal: Curr Biol Date: 2004-08-24 Impact factor: 10.834

4. Early rearing environment impacts cerebellar growth in juvenile salmon.

Authors: Rebecca L Kihslinger; Gabrielle A Nevitt
Journal: J Exp Biol Date: 2006-02 Impact factor: 3.312

5. Genetics of growth predict patterns of brain-size evolution.

Authors: B Riska; W R Atchley
Journal: Science Date: 1985-08-16 Impact factor: 47.728

6. Postembryonic development of the cerebellum in gymnotiform fish.

Authors: G K Zupanc; I Horschke; R Ott; G B Rascher
Journal: J Comp Neurol Date: 1996-07-08 Impact factor: 3.215

7. Comparing evolvabilities: common errors surrounding the calculation and use of coefficients of additive genetic variation.

Authors: Francisco Garcia-Gonzalez; Leigh W Simmons; Joseph L Tomkins; Janne S Kotiaho; Jonathan P Evans
Journal: Evolution Date: 2012-02-06 Impact factor: 3.694

8. Genetic and phenotypic variation in weight of brain and spinal cord between inbred strains of mice.

Authors: T H Roderick; R E Wimer; C C Wimer; P A Schwartzkroin
Journal: Brain Res Date: 1973-12-21 Impact factor: 3.252

9. Artificial selection on relative brain size in the guppy reveals costs and benefits of evolving a larger brain.

Authors: Alexander Kotrschal; Björn Rogell; Andreas Bundsen; Beatrice Svensson; Susanne Zajitschek; Ioana Brännström; Simone Immler; Alexei A Maklakov; Niclas Kolm
Journal: Curr Biol Date: 2013-01-03 Impact factor: 10.834

10. Genetic architecture supports mosaic brain evolution and independent brain-body size regulation.

Authors: Reinmar Hager; Lu Lu; Glenn D Rosen; Robert W Williams
Journal: Nat Commun Date: 2012 Impact factor: 14.919

20 in total

1. Genetics of Cerebellar and Neocortical Expansion in Anthropoid Primates: A Comparative Approach.

Authors: Peter W Harrison; Stephen H Montgomery
Journal: Brain Behav Evol Date: 2017-07-06 Impact factor: 1.808

2. Intraspecific brain size variation between coexisting sunfish ecotypes.

Authors: Caleb J Axelrod; Frédéric Laberge; Beren W Robinson
Journal: Proc Biol Sci Date: 2018-11-07 Impact factor: 5.349

3. Environmentally induced changes to brain morphology predict cognitive performance.

Authors: Thomas W Pike; Michael Ramsey; Anna Wilkinson
Journal: Philos Trans R Soc Lond B Biol Sci Date: 2018-09-26 Impact factor: 6.237

Review 4. Brain evolution and development: adaptation, allometry and constraint.

Authors: Stephen H Montgomery; Nicholas I Mundy; Robert A Barton
Journal: Proc Biol Sci Date: 2016-09-14 Impact factor: 5.349

5. Maternal stress has divergent effects on gene expression patterns in the brains of male and female threespine stickleback.

Authors: David C H Metzger; Patricia M Schulte
Journal: Proc Biol Sci Date: 2016-09-28 Impact factor: 5.349