Deck 2: Heredity, Environment, and the Brain

A) occur during the process of meiosis.
B) reflect differences in genotype.
C) reveal differences in genetic code.
D) show differences in phenotype.
E) occur during the process of mitosis.

A) Color blindness is dominant and dominant genes affect males more than females.
B) Color blindness is a sex-linked trait associated with the X chromosome.
C) Color blindness only affects males as it is associated with a dominant gene on the Y chromosome.
D) Color blindness is only passed on to males through their mother.
E) Color blindness is only passed on to males through their father.

A) negative mutation.
B) neutral mutation.
C) positive mutation.
D) fixed-region mutation.
E) mixed mutation.

A) mixed mutations are not always positive.
B) random negative mutations can occur.
C) mutations are always linked to sex-linked chromosomes.
D) mutations are typically passed on by the mother.
E) environment has little effect on most genes.

A) the study of genetic mutations.
B) adoption studies.
C) twin studies.
D) the Human Genome Project.
E) the gene therapy project.

A) phenotype
B) genotype
C) microbiome
D) gamete
E) chromosomal link

A) Twins who reach different heights in adulthood
B) A boy born with blue eyes who now has brown eyes in adulthood
C) A son who grows to be nearly 5 inches taller than either parent
D) A daughter who reaches the same height as her biological mother
E) A girl with hazel eyes who still has hazel eyes in adulthood

A) eye color; height
B) skin color; weight
C) height; weight
D) diet; weight
E) weight; eye color

A) Gene therapy
B) Genetic transmission
C) Epigenetics
D) Evocative expression
E) Passive expression

A) evocative effects.
B) proactive limitations.
C) epigenetics.
D) gene-environment matching.
E) systematic effects.

A) animals and humans have similar gene-environment interactions on a few traits.
B) humans experience a stronger gene-environment interaction than animals.
C) animals' genetic contribution is higher for nearly every trait in comparison with humans.
D) the same principles of gene-environment interactions observed in animals apply to humans.
E) animals' genetic contribution is lower for nearly every trait in comparison with humans.

A) caregiving is genetically hard-wired into all species.
B) animals and humans have differences in genetic transmission.
C) early experience may alter gene expression.
D) genes alter our environment.
E) only the strongest genetic traits persist.

A) ladder metaphor
B) library metaphor
C) computer metaphor
D) animalistic analogy
E) evolutionary analogy

A) Vision
B) Attention
C) Smell and taste
D) Motor control
E) Memory

A) responsible for regulating heart rate and breathing.
B) the smallest and lightest portion of the brain.
C) nearly fully developed shortly after birth.
D) responsible for higher functions such as language and memory.
E) a dense tract of nerve fibers.

A) Temporal lobe
B) Forebrain
C) Thalamus
D) Amygdala
E) Right hemisphere

A) hindbrain.
B) midbrain.
C) brain stem.
D) medulla.
E) cerebral cortex.

A) It is responsible for complex thinking and planning.
B) It is responsible for regulating many basic life functions such as heart rate and digestion.
C) It is only found in humans, not animals.
D) It is responsible for communication between hemispheres.
E) It is the last portion of the brain to fully develop.

A) dendrites
B) cell wall
C) neurons
D) axon terminals
E) glial cells

A) cell body.
B) axon.
C) glial cell.
D) dendrite.
E) myelin.

A) Cell bodies
B) Suppressed neurons
C) Myelin
D) Glial cells
E) Dendrites

A) fMRI
B) EEG
C) EKG
D) PET
E) MRI

A) migration.
B) myelination.
C) synaptogenesis.
D) neurogenesis.
E) pruning.

A) neurogenesis.
B) synaptogenesis.
C) pruning.
D) myelination
E) migration.

A) development of synaptic connections.
B) pruning of unnecessary and unused neural connections.
C) improvement in the conductivity of the nerve impulses.
D) growth of the neural tube.
E) increase in the number of dendrites.

A) after three years of age.
B) after the first year.
C) before adolescence.
D) before and after birth.
E) before a child's third birthday.

A) Yes, infants have billions of neurons and now is the time to maintain them.
B) Yes, infants crave stimulation, and this is the critical period for brain growth.
C) No, pruning away excess neurons will improve the child's neural communication.
D) No, synaptogenesis must be allowed to occur naturally without a structured environment.
E) Yes, early brain growth leads to better synaptic connections later in childhood.

A) germination.
B) maturation.
C) synaptogenesis.
D) migration.
E) regeneration.

A) Synapses are pruned in early childhood as a response to the environment but grow back in adolescence as the child matures.
B) Synapses that are unused are pruned while myelination of the axon increases the efficiency of communication between childhood and adolescence.
C) Dendrite and axon communication becomes less efficient as the child moves into adolescence.
D) Axons and dendrites expand in the number of connections they make during the adolescent years.
E) Axons and dendrites become thinner and more sparse throughout childhood and adolescence.

A) synaptogenesis.
B) experience-expectant plasticity.
C) experience-dependent plasticity.
D) neurogenesis.
E) synaptic pruning

A) Take no action until Jess is at least 5 years of age. The brain is highly adaptive and no significant impact to the brain will occur.
B) Take action at 2 to 3 years of age, after monitoring the effect of the cataracts on vision over time, but before preschool begins.
C) Take no action, as the brain will adapt to the cataracts and can disrupt the specialized fine-tuning of neural connections.
D) Remove the cataracts after age 3 years and provide specialized brain exercises to improve functioning.
E) Remove the cataracts during infancy, as removing them after infancy increases the chance of visual impairments.

A) A deaf child's auditory processing areas become specialized for visual processing.
B) An older child's hindbrain takes over many of the tasks once attributed to the cerebral cortex.
C) Specialized brain stimulation programs mimic auditory stimuli, prompting growth of auditory processing areas.
D) A deaf child's cerebral cortex increases in gray matter, compensating for lack of auditory stimuli.
E) A young child's cerebral cortex decreases in white matter, compensating for lack of auditory stimuli.

A) expectant
B) resilient
C) neuro-typical
D) experience-expectant
E) sensitive

A) A school-age child's pre-frontal cortex grows naturally.
B) A child raised in a high-stress environment shows increases in surface area of the brain relative to children without such an experience.
C) A child raised in a highly enriched environment shows increases in surface area of the brain relative to children without such an experience.
D) A child raised in a high SES household shows decreases in specific areas of the brain relative to children in low SES households.
E) A child raised in poverty shows resilience despite the impoverished environment.

A) experimental studies with twins.
B) experimental studies with adopted children and families.
C) correlational studies of children in various home environments.
D) brain imaging research in large-scale, controlled-experiments.
E) correlational studies exclusively in rats.

A) There are times in development when then the brain expects to develop certain skills.
B) There are times in development when the brain is most susceptible to experiences.
C) The brain is more susceptible to certain experiences than others across development.
D) The brain is hard-wired to learn particular skills.
E) The brain is no longer thought of as being hard-wired for brain growth.

A) critical periods.
B) sensitive periods.
C) niche-picking.
D) brain lateralization.
E) myelination.

A) Critical periods
B) Experience-expectant brain growth
C) Canalization
D) Brain plasticity
E) Neurogenesis

A) BRAIN initiative
B) Neurological Society of America
C) Brain-Based Project
D) Frontiers of Science Foundation
E) Brain Balance Study