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Transcript
Chapter Five Genetics and the Development of the Human Brain CHAPTER 5 GENETICS AND DEVELOPMENT OF THE HUMAN BRAIN Genetics and Behavior • Genotype – set of genetic instructions – 23 pairs of chromosomes made up of DNA • Phenotype – observable traits • Gene Expression – genetic instructions converted into a feature of a living cell • Mitochondrial DNA (mDNA) originates from mother • Alleles – alternative versions of particular gene Figure 5.1 Mitochondrial DNA Allows Researchers to Trace Population History Figure 5.2 Three Alleles Give Rise to Four Types of Blood Genetics and Behavior • From Genes to Proteins – Constructed from adenine, cytosine, guanine, thymine – Human gene activity in the brain very high – Proteome – proteins encoded and expressed by genome • Sources of Genetic Diversity – Meiosis and crossing over – Mutations – chromosome replication errors – The Special Case of the Sex Chromosomes • Sex-linked characteristics • X chromosome inactivation – Single Nucleotide Polymorphisms (SNPs) Figure 5.3 The Process of Gene Expression Figure 5.4 Cell Division by Meiosis Figure 5.5 Crossing Over Contributes to Genetic Diversity Figure 5.7 Probabilities of Hemophilia Figure 5.9 SNPs and Disease Genetics and Behavior • The Roles of Heredity and Environment – Heritability always refers to a population not to individuals – Heritability cannot be assessed without taking the environment into account – Twin and adoption studies • Minnesota Study of Twins Reared Apart Figure 5.10 Heritability Interacts with Environment Figure 5.11 Similarities in Identical Twins Development • Growth and Differentiation of the Nervous System – Early differentiation • Cell germ layers – ectoderm, mesoderm, and endoderm • Neural plate, neural groove, neural tube – Formation of neurons and glia • Originate from cells in the ventricular zone • Progenitor cells divide by mitosis – Cell migration • Guided by radial glia • Cells in cerebral cortex arrive in an inside-out fashion Figure 5.14 The Closing of the Neural Tube Figure 5.15 Neurogenesis Figure 5.16 Radial Glia Guide the Migration of New Cells Development • Differentiation – Differentiation of the dorsal and ventral halves of neural tube – Differentiation of the neural tube along the rostral-caudal axis • Growth of Axons and Dendrites – Developing axons and dendrites end in growth cones – Filapodia and lamellipodia Figure 5.17 Growth Cones Guide Axons to Their Targets Figure 5.18 Growth Cones Respond to a Variety of Cues Development • Formation of Synapses – Interaction with target cells influences the type of neurotransmitter released by the presynaptic cell – Movement of receptors to the synaptic site guided by chemical release by presynaptic and postsynaptic structures • Cell Death – Apoptosis = programmed cell death – Neurotrophins influence the survival of a neuron Figure 5.19 Steps in the Formation of a Synapse at the Neuromuscular Junction Figure 5.20 Growing Axons Compete for Nerve Growth Factor Development • Synaptic Pruning – Number of functional synapses is reduced • Myelination – Occurs in rostral direction starting with the spinal cord, then hindbrain, midbrain, and forebrain – Burst in myelination around the time of birth – Prefrontal cortex not completely myelinated until early adulthood Figure 5.21 Synaptic Rearrangement over the Lifespan Effect of Experience on Development • Plasticity • Experience and the Visual System – Early in development cells of LGN and primary visual cortex receive input from both eyes – Experience with sensory information influences segregation of ocular dominance Figure 5.22 Input Influences the Development of the Optic Tectum Figure 5.23 Input from Both Eyes Competes for the Control of Target Cells in the LGN Figure 5.24 Early Experiences Affect the Organization of Ocular Dominance Columns Effect of Experience on Development • Experience and Social Behavior – Lorenz demonstrated imprinting in several species of birds – Romanian children and social deprivation • Ending a Critical Period – Conclusion of growth spurt in myelin coincides with reduced abilities to learn additional languages – Presence or absence of neurotrophins may influence timing of critical periods Disorders of Brain Development • Neural Tube Defects – Anencephaly – Spinal bifida • Genetic Disorders – Down syndrome – Fragile-X syndrome – PKU • Environmental Toxins – Fetal alcohol syndrome Redevelopment in Response to Damage • Anterograde degeneration, retrograde degeneration, and transneuronal degeneration • Genetic therapy and Nogo inhibitors as possible treatments The Adult Nervous System • Fully mature at 25; weight of brain starts to decrease at 45 • Neurogenesis in Adulthood • Alzheimer’s Disease – neurofibrillary tangles – amyloid Figure 5.27 Neuronal Responses to Damage Figure 5.28 Alzheimer’s Disease Produces Structural Abnormalities in Neurons
