Experience Human Development 15th Edition PDF

Summary

This textbook, Experience Human Development 15th edition, explores human development, covering genetics, hereditary mechanisms, and sex determination. It explains the genetic code, the role of DNA, and how chromosomes determine sex. The text also discusses the influence of environmental factors on gene expression.

Full Transcript

type, varies (Smits & Monden, 2011). For example, multiple birth rates in
West African women have been reported at 1 in 40, while rates in Japan are
T A
far lower at 1 in 200 (Blencowe et al., 2013). Influences on multiple births
DNA is the genetic A T are (1) the trend toward delayed childbearing and (2) the increased use of
material in all living cells.
It consists of four fertility drugs, which spur ovulation, and of assisted reproductive techniques
chemical units, called such as in vitro fertilization, which tend to be used by older women (Marti-
bases. These bases are G C net al., 2009).
the letters of the DNA
alphabet. A (adenine) T A
pairs with T (thymine) C G

Mechanisms of Heredity
and C (cytosine) pairs T A
with G (guanine). There
are 3 billion base pairs in
human DNA. The science of genetics is the study of heredity, the genetic transmission of
Letters of the DNA C G heritable characteristics from biological parents to offspring.
alphabet C G
T = Thymine T A
A = Adenine T A THE GENETIC CODE
G = Guanine
C = Cytosine The “stuff” of heredity is a chemical called deoxyribonucleic acid (DNA). The
double-helix structure of a DNA molecule resembles a long, spiraling ladder whose
C G steps are made of pairs of chemical units called bases (Figure 1). The bases—
T A adenine (A), thymine (T), cytosine (C), and guanine (G)—are the “letters” of the
genetic code, which cellular machinery “reads.”
FIGURE 1 Chromosomes are coils of DNA that consist of smaller segments called
DNA: The Genetic Code genes, the functional units of heredity. Each gene is located in a specific posi-
Source: Adapted from Ritter (1999). tion on its chromosome and contains thousands of bases. The sequence of
bases in a gene tells the cell how to make the proteins that enable it to carry
out specific functions. The complete sequence of genes in the human body
constitutes the human genome. Of course, every human has a unique genome.
The human genome is not meant to be a recipe for making a particular human.
Rather, the human genome is a reference point, or representative genome, that
shows the location of all human genes.
(a) A useful analogy is to consider the DNA of an individual as a series of
books in a library. Until those books are “read” by an enzyme called RNA
polymerase and transcribed into a readable copy of messenger RNA (m-RNA),
the knowledge contained within the books is not actualized. And what books
will be pulled down from the shelf and read is in part determined by environ-
mental factors turning genes on and off at different points in development
(Champagne & Mashoodh, 2009).
Every cell in the normal human body except the sex cells (sperm and
ova) has 23 pairs of chromosomes—46 in all. Through a type of cell division
(b)
called meiosis, which the sex cells undergo when they are developing, each
sex cell ends up with only 23 chromosomes—one from each pair. When sperm
and ovum fuse at conception, they produce a zygote with 46 chromosomes,
23 from the father and 23 from the mother (Figure 2).
Ovum Sperm

FIGURE 2
Hereditary Composition of the Zygote
(c) (a) Body cells of women and men contain 23 pairs of chromosomes, which carry
the genes, the basic units of inheritance. (b) Each sex cell (ovum and sperm) has
only 23 single chromosomes because of a special kind of cell division (meiosis).
(c) At fertilization, the 23 chromosomes from the sperm join the 23 from the ovum
Zygote so that the zygote receives 46 chromosomes, or 23 pairs.

50 EXPERIENCE HUMAN DEVELOPMENT CHAPTER 3 Forming a New Life
 At conception, then, the single-celled zygote has all the bio-
logical information needed to guide its development into a
unique individual. Through mitosis, a process by which the non-
sex cells divide in half over and over again, the DNA replicates Mother Father
itself, so that each newly formed cell has the same DNA struc-
ture as all the others. Each cell division creates a genetic dupli-
cate of the original cell, with the same hereditary information.
Sometimes a mistake in copying is made, and a mutation may Father has an X
chromosome and a Y
result. Mutations are permanent alterations in genetic material. chromosome. Mother
When development is normal, each cell (except the sex cells) has two X chromosomes.
continues to have 46 chromosomes identical to those in the Male baby receives an X
original zygote. As the cells divide, they differentiate, special- chromosome from
the mother and a Y
izing in a variety of complex bodily functions that enable the chromosome from X X X Y
child to grow and develop. the father. Female
Genes spring into action when they are turned on or off, baby receives X
either by external environmental factors such as nutrition or chromosomes from both
mother and father.
stress, or by internal factors such as hormone levels in the mother
or fetus. Thus, from the start, heredity and environment are inter-
twined. X X X X
X Y

Baby boy
SEX DETERMINATION Baby girl

Twenty-two pairs of our 23 pairs of chromosomes are autosomes, FIGURE 3
chromosomes that are not related to sexual expression. The twenty- Genetic Determination of Sex
third pair are sex chromosomes—one from the father and one from Because all babies receive an X chromosome from
the mother—that govern the baby’s sex. the mother, sex is determined by whether an X or a
Sex chromosomes are either X chromosomes or Y chromo- Y chromosome is received from the father.
somes. The sex chromosome of every ovum is an X chromosome,
but the sperm may contain either an X or a Y chromosome. The deoxyribonucleic acid (DNA)
Chemical that carries inherited instruc-
Y chromosome contains the gene for maleness, called the SRY gene. When an ovum tions for the development of all cellular
(X) is fertilized by an X-carrying sperm, the zygote formed is XX, a genetic female. forms of life.
When an ovum (X) is fertilized by a Y-carrying sperm, the resulting zygote is XY,
genetic code
a genetic male (Figure 3). Sequence of bases within the DNA mol-
Sexual differentiation is a more complex process than simple gene determination. ecule; governs the formation of proteins
Early in development, the embryo’s rudimentary reproductive system appears almost that determine the structure and func-
identical in males and in females. Research with mice has found that once hormones tions of living cells.
signal the SRY gene on the Y chromosome to turn on, cell differentiation and for- chromosomes
mation of the testes are triggered. At 6 to 8 weeks after conception, the testes start Coils of DNA that consist of genes.
to produce the male hormone testosterone. Exposure of a genetically male embryo genes
to steady, high levels of testoster- Small segments of DNA located in defi-
one ordinarily results in the devel- nite positions on particular chromo-
somes; functional units of heredity.
opment of a male body with male
sexual organs (Arnold, 2017). With- The Neanderthal genome
human genome
out this hormonal influence, a Complete sequence of genes in the hu-
was sequenced in 2013, man body.
genetically male mouse will develop
and analysis of the commonalities mutations
genitals that appear female rather
than male. between Neanderthal and human Permanent alterations in genes or chro-
genes suggests that we engaged in mosomes that may produce harmful
The development of the female characteristics.
reproductive system is equally com- limited interbreeding. In other words,
some of their genes live on in us. autosomes
plex and depends on a number of In humans, the 22 pairs of chromo-
genetic variants. These variants pro- Indeed, estimates are that only 1.5 to somes not related to sexual expression.
mote ovarian development and 7 percent of the human genome is
sex chromosomes
inhibit testicular development (Ono uniquely human (Schaefer et al., Pair of chromosomes that determines
& Harley, 2013). This includes the 2021). sex: XX in the normal human female,
HOX genes (Taylor, 2000) and a XY in the normal human male.

Mechanisms of Heredity  EXPERIENCE HUMAN DEVELOPMENT 51
 signaling molecule called Wnt-4, a variant form of which can masculinize a geneti-
cally female fetus (Bouty et al., 2020).
checkpoint
can you...
Describe the structure of DNA PATTERNS OF GENETIC TRANSMISSION
and its role in the inheritance During the 1860s, Gregor Mendel, an Austrian monk, laid the foundation for our
of characteristics? understanding of patterns of inheritance. By crossbreeding strains of peas, he discov-
ered two fundamental principles of genetics. First, traits could be either dominant or
Distinguish between meiosis recessive. Dominant traits are always expressed, whereas recessive traits are expressed
and mitosis? only if both copies of the gene are recessive. Second, traits are passed down indepen-
dently of each other. For example, the color of your hair and your height are both
Explain why the sperm nor-
hereditable traits that are not linked.
mally determines a baby’s sex?
Although some human traits are inherited via simple dominant transmission, most
human traits fall along a continuous spectrum and result from the actions of many genes
in concert. Nonetheless, Mendel’s groundbreaking work laid the foundations for our
modern understanding of genetics.

Dominant and Recessive Inheritance Genes that can produce alternative expres-
alleles sions of a characteristic (such as the presence or absence of dimples) are called alleles.
Two or more alternative forms of a gene Alleles are alternate versions of the same gene. Every person receives one maternal and
that occupy the same position on paired one paternal allele for any given trait. When both alleles are the same, the person is
chromosomes and affect the same trait.
homozygous for the characteristic; when they are different, the person is heterozygous.
homozygous In dominant inheritance, the dominant allele is always expressed, or shows up as a trait
Possessing two identical alleles for a trait. in that person. The person will look the same whether or not he or she is heterozygous
heterozygous
or homozygous because the recessive allele doesn’t show. For the trait to be expressed
Possessing differing alleles for a trait. in recessive inheritance, the person must have two recessive alleles, one from each parent.
If a recessive trait is expressed, that person cannot have a dominant allele.
dominant inheritance Let’s take red hair as an example. Because red hair is a recessive trait, you must
Pattern of inheritance in which, when a
child receives different alleles, only the
receive two recessive copies (r) of the gene—one from each parent—in order to express
dominant one is expressed. red hair. Having hair that is not red (R; brown in this example) is a dominant trait, so
you will have brown hair if you receive at least one copy (R) from either parent (Rr or
recessive inheritance RR) (Figure 4). If you receive one copy of the red hair allele (r) and one copy of an
Pattern of inheritance in which a child
receives identical recessive alleles,
allele for brown hair (R), you are heterozygous (Rr or rR); if you have two copies of the
resulting in expression of a nondominant allele for brown hair, you are homozygous dominant (RR). In both cases, you will have
trait. brown hair. If you inherited one allele for red hair from each parent, you are homozygous

FIGURE 4 Mother Father
Dominant and
Recessive
Inheritance
Because of dominant
inheritance, the same
observable phenotype
(in this case, brown hair)
can result from two different Rr Rr
genotypes (RR and Rr).
A phenotype expressing
a recessive characteristic
(such as red hair) must have
a homozygous recessive
genotype (rr).
(Left to Right) Dougal Waters/Photodisc/Getty
Images; Ioannis Pantzi/Shutterstock;
Ed-Imaging; Ed-Imaging; BDLM/Cultura/Getty
Images; Pete Pahham/Shutterstock
RR Rr rR rr

52 EXPERIENCE HUMAN DEVELOPMENT CHAPTER 3 Forming a New Life
recessive for this trait (rr) and will have red hair. Thus, the only situation in which you polygenic inheritance
would have red hair is if you received two recessive copies (r), one from each parent. Pattern of inheritance in which multiple
genes at different sites on chromo-
Relatively few traits are determined in this simple fashion. Most traits result from
somes affect a complex trait.
polygenic inheritance, the interaction of several genes. For example, there is not an
“­intelligence” gene that determines whether or not you are smart. Rather, a large number phenotype
of genes work in concert to determine your intellectual potential. Like intelligence, most Observable characteristics of a person.
individual variations in complex behaviors or traits are governed by the additive influ- genotype
ences of many genes with small but identifiable effects. Although single genes often Genetic makeup of a person, containing
determine abnormal traits, there is no single gene that by itself significantly accounts both expressed and unexpressed
for individual differences in any complex behavior. characteristics.

Multifactorial Transmission If you have brown hair, that is part of your phenotype,
the observable characteristics through which your genotype, or underlying genetic
makeup, is expressed. The phenotype is the product of the genotype and any relevant Your genotype is
environmental influences. The difference between genotype and phenotype helps explain the recipe for making you.
why a clone (a genetic copy of an individual) or even an identical twin can never be an Your phenotype is how you
exact duplicate of another person. actually turn out.
As Figure 4 illustrates, people with different genotypes may exhibit the same phe-
notype. For example, a child who is homozygous for a dominant brown hair allele will
have brown hair, but so will a child who is heterozygous for that same allele. Because
it is dominant, the brown hair is expressed, and the recessive red hair allele is hidden.
Environmental experience modifies the expression of the genotype for most traits—
a phenomenon called multifactorial transmission. Multifactorial transmission illustrates multifactorial transmission
the interaction of nature and nurture and how they affect outcomes. Imagine that Rio Combination of genetic and environ-
has inherited athletic talent and comes from a family of avid athletes. If his family mental factors to produce certain com-
plex traits.
nurtures his talent and he practices regularly, he may become a skilled athlete. How-
ever, if he is not encouraged or not motivated to engage in athletics, his genotype for epigenesis
athletic ability may not be expressed (or may be expressed to a lesser extent) in his Mechanism that turns genes on or off
phenotype. Some physical characteristics (including height and weight) and most psy- and determines functions of body cells.
chological characteristics (such as intelligence and musical ability) are products of
multifactorial transmission. Many disorders (such as attention-deficit/hyperactivity dis-
order) arise when an inherited predisposition (an abnormal variant of a normal gene)
interacts with an environmental factor, either before or after birth (Yang et al., 2013).

Epigenetic Influences on Gene Expression Have you ever wondered why identical
twins—who share 100 percent of their genetic code— look and act slightly different? Epi-
genetic variation can help explain this. The field of epigenetics includes the study of
biochemical modifications of genetic expression “above the genome”—without altering
DNA sequence. The differences arise as certain genes are turned off or on as they are
needed by the developing body or when triggered by the environment. This phenomenon
is called epigenesis, or epigenetics.
Epigenesis works via chemical molecules, or “tags,” attached to a gene that affect
the way a cell “reads” the gene’s DNA. Because every cell in the body inherits the same
DNA sequence, the function of the chemical tags is to differentiate various types of
Identical twins can
body cells, such as brain cells, skin cells, and liver cells—somewhat like placing sticky
usually open each other’s
notes in your textbook to tell you where to look for information. These tags work by
switching particular genes on or off during embryonic formation. phones with facial
Environmental factors, such as nutrition, smoking, sleep habits, stress, and physical recognition. However,
activity, can cause epigenetic changes (Wong et al., 2014). In turn these epigenetic changes because every person—
can contribute to such common ailments as cancer, diabetes, and heart disease (Biswas even identical twins—has
& Rao, 2018; Ling & Rönn, 2019; Prasher et al., 2020). It may explain why one mono- unique fingerprints (Tao et
zygotic twin is susceptible to a disease such as schizophrenia whereas the other twin is al., 2012), they cannot open
not and why some twins get the same disease but at different ages (Demir & Demir, each other’s phones with a
2018). Environmental influences can also be social in nature. For example, ­childhood fingerprint scanner.
adversity can lead to a variety of health vulnerabilities, including cardiovascular disease,

Mechanisms of Heredity  EXPERIENCE HUMAN DEVELOPMENT 53
 decreased immune responses, and an increased risk of psycho-
logical disorders (Pierce et al., 2020; Berens et al., 2017).
Cells are particularly susceptible to epigenetic modification
during critical periods such as pregnancy (Naffee et al., 2008).
Furthermore, epigenetic modifications, especially those that occur
early in life, may be heritable. For example, the granddaughters of
women and the grandsons of men who experienced famine while
in the womb lived shorter lives on average (Pembrey et al., 2014).

GENETIC AND CHROMOSOMAL
ABNORMALITIES
Most birth disorders are fairly rare (see Table 1), affecting only
about 3 percent of live births (Centers for Disease Control and
Epigenetic changes can explain why identical twins look Prevention, 2020). Nevertheless, they are the leading cause
increasingly divergent with age. of infant death in the United States, accounting for 21 percent of
LPETTET/E+/Getty Images infant deaths (Ely & Driscoll, 2020). The most prevalent defects
are clubfoot, cleft palate, Down syndrome, and heart defects, in that order (Mai et al., 2019).
Rates of disorders vary with race and ethnicity. For example, Asian/Pacific Islander
infants have the lowest prevalence of anencephaly, a variety of heart and aortal defects,
clubfoot, gastrointestinal abnormalities, limb defects, and spina bifida. Hispanic and
American Indian/Alaska native infants, by contrast, have among the highest rates of
these defects. Non-Hispanic Black infants have higher rates of omphalocele (a birth
defect in the abdominal wall) and trisomy-13 (Mai et al., 2019). Survival rates also differ
by ethnicity. In particular, African American and Hispanic infants are at higher risk than
White, non-Hispanic infants (Wang et al., 2015).
Not all genetic or chromosomal abnormalities are apparent at birth. Tay-Sachs, a
fatal degenerative disease of the central nervous system, and sickle-cell anemia, a blood
disorder, do not generally appear until at least 6 months of age. Likewise, cystic fibrosis,
a condition in which excess mucus accumulates in the lungs and digestive tract, may not
checkpoint appear until age 4. Some diseases show an even later onset, such as glaucoma, a disease
can you... in which fluid pressure builds up in the eyes, and Huntington’s disease, a progressive
degeneration of the nervous system, which do not typically appear before middle age.
Explain how epigenesis and It is in genetic defects and diseases that we see most clearly the operation of domi-
genome imprinting occur, and nant and recessive transmission, as well as of a variation, sex-linked inheritance, dis-
give examples? cussed in the the section on Sex-Linked Inheritance of Defects.

Dominant or Recessive Inheritance of Defects Most of the time, typical genes are
dominant over those carrying abnormal traits, but sometimes the gene for an abnormal
trait is dominant. When this is the case, even one copy of the “bad” gene will result in
a child expressing the disorder. Among the 1,800 disorders known to be transmitted by
dominant inheritance are achondroplasia (a type of dwarfism) and Huntington’s disease.
Defects transmitted by dominant inheritance are less likely to be lethal at an early age
than those transmitted by recessive inheritance because any affected children would be
likely to die before reproducing. Therefore, that gene would not be passed on to the next
generation and would soon disappear from the population.
Recessive defects are expressed only if the child is homozygous for that gene; in
other words, a child must inherit a copy of the recessive gene from each parent. Because
recessive genes are not expressed if the parent is heterozygous for that trait, it may not
always be apparent that a child is at risk for receiving two alleles of a recessive gene.
Defects transmitted by recessive genes tend to be lethal at an earlier age, in contrast to
those transmitted by dominant genes, because recessive genes can be transmitted by
heterozygous carriers who do not themselves have the disorder. Thus, they are able to
reproduce and pass the genes down to the next generation.
Normally the presence of a dominant/recessive gene pair results in the full
­expression of the dominant gene and the masking of the recessive gene. However, in

54 EXPERIENCE HUMAN DEVELOPMENT CHAPTER 3 Forming a New Life
 TABLE 1 Some Birth Defects and Genetic Disorders
Problem Characteristics of Condition Who Is at Risk What Can Be Done
Alpha thalassemia Severe anemia that reduces ability of the Primarily families of Frequent blood
blood to carry oxygen; nearly all affected Malaysian, African, transfusions
infants are stillborn or die soon after birth and Southeast Asian
descent

Beta thalassemia Severe anemia resulting in weakness, Primarily families of Frequent blood
(Cooley’s anemia) fatigue, and frequent illness; usually fatal in Mediterranean transfusions
adolescence or young adulthood descent

Cystic fibrosis Overproduction of mucus, which collects in 1 in 2,000 White Physical therapy to
the lung and digestive tract; children do not births loosen mucus; antibiotics
grow normally; short life span; the most for lung infections;
common inherited lethal defect among enzymes to improve
White people digestion; lung transplant

Duchenne Fatal disease usually found in males, marked 1 in 3,000 to 5,000 No treatment
muscular by muscle weakness and minor intellectual male births
dystrophy disability; respiratory failure and death
usually occur in young adulthood

Hemophilia Excessive bleeding, usually affecting males; 1 in 10,000 families Frequent transfusions of
in its most severe form, can lead to crippling with a history of blood with clotting
arthritis in adulthood hemophilia factors

Anencephaly Absence of brain tissues; infants are stillborn 1 in 1,000 No treatment
or die soon after birth

Spina bifida Incompletely closed spinal canal, muscle 1 in 1,000 Surgery prevents further
weakness or paralysis, and loss of bladder injury; shunt placed in
and bowel control; often accompanied by brain drains excess fluid.
hydrocephalus, an accumulation of spinal
fluid in the brain, and intellectual disability

Phenylketonuria Metabolic disorder resulting in intellectual 1 in 15,000 births Special diet can prevent
(PKU) disability intellectual disability

Polycystic kidney Infantile form: enlarged kidneys, leading to 1 in 1,000 Kidney transplants
disease respiratory problems and congestive heart
failure.
Adult form: kidney pain, kidney stones, and
hypertension resulting in chronic kidney failure

Sickle-cell anemia Deformed red blood cells that clog blood 1 in 500 African Painkillers, transfusions
vessels, depriving the body of oxygen; Americans for anemia and to
symptoms include severe pain, stunted prevent stroke,
growth, infections, leg ulcers, gallstones, antibiotics for infections
pneumonia, and stroke

Tay-Sachs disease Degenerative disease of the brain and Primarily found in No treatment
nerve cells, resulting in death before age 5 Eastern European
Jewish families

Sources: Adapted from Centers for Disease Control and Prevention (2021) and Ross et al. (2013).

incomplete dominance, the resulting phenotype is a combination of both genes. For incomplete dominance
example, people with only one sickle-cell allele and one “good” allele do not have Pattern of inheritance in which a child
receives two different alleles, resulting
sickle-cell anemia with its distinctive, abnormally shaped blood cells. Their blood cells in partial expression of a trait.
are not the typical round shape either. They are an intermediate shape, which shows
that the sickle-cell gene for these people is incompletely dominant.

Mechanisms of Heredity  EXPERIENCE HUMAN DEVELOPMENT 55
sex-linked inheritance Sex-Linked Inheritance of Defects In sex-linked inheritance (Figure 5), certain reces-
Pattern of inheritance in which certain sive disorders affect male and female children differently. This is due to the fact that
characteristics carried on the X chromo-
males are XY and females are XX. In humans, the Y chromosome is smaller and carries
some inherited from the mother are
transmitted differently to her male and far fewer genes than the X chromosome. One outcome of this is that males receive only
female offspring. one copy of any gene that happens to be carried on the sex chromosomes, whereas
females receive two copies. So, if a woman has a “bad” copy of a particular gene, she
has a backup copy. However, if a male has a “bad” copy of a particular gene, that gene
will be expressed.
Heterozygote females who carry one “bad” copy of a recessive gene and one “good”
Children with Turner one are called carriers. If such a woman has children with an unaffected male (a man
syndrome have only who has a “good” copy of the gene), she has a 50 percent chance of passing the disor-
one X chromosome, are der on to any sons they might have. If they have a son (who is XY by virtue of being
missing the second sex male), the father contributed a Y chromosome, and the mother contributed the X chro-
chromosome, and are mosome. Because she has one “good” copy and one “bad” copy, either outcome is
equally likely. Daughters (who are XX by virtue of being female) may be protected
always girls. Because so
because the father will pass on his “good” copy to daughters, so the girls have a 50
little information is carried
percent chance either of being completely unaffected or of carrying a hidden recessive
on the Y chromosome, an copy of the gene.
embryo with only a Y Sex-linked recessive disorders are more common in males than in females. For exam-
chromosome and no X ple, red-green color blindness, hemophilia (a disorder in which blood does not clot when
chromosome is not viable. it should), and Duchenne muscular dystrophy (a disorder that results in muscle degen-
Alternatively, an embryo eration and eventually death) are all more common in males, and all result from genes
with only an X chromosome located on the X chromosome. Occasionally, a female does inherit a sex-linked condition.
but no Y often is. For this to happen, the father must have a “bad” copy, and the mother must also be a
carrier or herself have the condition.

Chromosomal Abnormalities
Chromosomal abnormalities typically occur because of errors in cell division, resulting
in an extra or missing chromosome. For example, Klinefelter syndrome is caused by an
extra female sex chromosome (shown by the pattern XXY). Turner syndrome results

FIGURE 5
Sex-Linked
Inheritance Carrier Unaffected
In the most common form, mother father
the female sex chromosome
of an unaffected mother carries
one recessive abnormal gene
and one dominant “good” one (X).
The father has one “good” male X
and Y chromosome complement.

The odds for each male child are 50-50:
1. 50% risk of inheriting the abnormal
X and the disorder
2. 50% chance of inheriting “good” X X X Y
and Y chromosomes
The odds for each female child are
50-50:
1. 50% chance of inheriting one
abnormal X, to be a carrier like
mother
2. 50% chance of inheriting no X Y X X Y X
abnormal genesa

Unaffected Unaffected Affected Carrier
male female male female

Possible hereditary results

56 EXPERIENCE HUMAN DEVELOPMENT CHAPTER 3 Forming a New Life
 TABLE 2 Sex Chromosome Abnormalities
Pattern/Name Typical Characteristics* Incidence Treatment
XYY Male; tall stature; tendency toward low IQ, 1 in 1,000 male births No special treatment
especially verbal

XXX (triple X) Female; normal appearance, menstrual irregu- 1 in 1,000 female births Special education
larities, learning disorders, intellectual disability

XXY (Klinefelter) Male; sterility, underdeveloped secondary sex 1 in 1,000 male births Hormone therapy, special
characteristics, small testes, learning disorders education

XO (Turner) Female; short stature, webbed neck, impaired 1 in 1,500 to 2,500 Hormone therapy, special
spatial abilities, no menstruation, infertility, female births education
underdeveloped sex organs

Fragile X Minor-to-severe intellectual disability more 1 in 1,200 male births; Educational and behavioral
severe in males; delayed speech and motor 1 in 2,000 female births therapies when needed
development, hyperactivity; the most common
inherited form of intellectual disability

*Not every affected person has every characteristic.

from a missing sex chromosome (XO). The likelihood of errors increase in offspring of Down syndrome
women age 35 or older. Characteristics of the most common sex chromosome disorders Chromosomal disorder characterized by
moderate-to-severe intellectual disability
are shown in Table 2. and by such physical signs as a down-
Down syndrome, the most common chromosomal abnormality, accounts for about ward-sloping skin fold at the inner cor-
40 percent of all cases of moderate-to-severe intellectual disability (Pennington et al., ners of the eyes. Also called trisomy-21.
2003). The condition is also called trisomy-21 because it is characterized
in more than 90 percent of cases by an extra 21st chromosome.
Slightly over one of every 700 live births is a child with Down syn-
drome (Mai et al., 2019). Although the risk of having a child with Down
syndrome rises with age, because of the higher birthrates of younger
women, more young mothers have children with Down syndrome (Cen-
ters for Disease Control and Prevention, 2021). Research also shows
having a father less than 20 or over 40 years old increases the risk (Fang
et al., 2020). Additionally, parents who have had one child with Down
syndrome are at increased risk for having another child with Down syn-
drome (Davidson, 2008).
Between 1979 and 2003, an increased tendency to delay child rear-
ing and thus a greater number of older mothers resulted in a corre-
sponding increase in the number of children born with Down syndrome
(Shin et al., 2009). However, this trend was offset by the development
of noninvasive prenatal screening tests in 2011, which allowed pregnant
women to test for genetic disorders without risk of miscarriage. Esti-
mates are that approximately 30 percent of pregnancies in which Down
syndrome was diagnosed were electively terminated (de Graaf et al.,
2015).
Children with Down syndrome, like other children with disabilities,
tend to benefit cognitively, socially, and emotionally when provided with
regular, intensive therapies designed to help them achieve important
skills (Smith et al., 2020; Ruiz-González et al., 2019; Lukowski et al.,
2019). As adults, many live in small group homes and support them-
selves; they tend to do well in structured job situations. Because of Although Down syndrome is a major cause of
increases in the average life span, there now exists a much wider range intellectual disability, people with this chromosomal
of ages in the US population of people with Down syndrome than used abnormality can live happy, productive lives.
to be the case (de Graaf et al., 2015). Still, a recent international meta- Disability Images/Blend Images LLC

Mechanisms of Heredity  EXPERIENCE HUMAN DEVELOPMENT 57
 analysis of 34 studies indicated that, across a variety of countries, people with Down
syndrome live about 28 fewer years than the general population (O’Leary et al., 2018).
Another common
sign of Down syndrome
involves the lines that palm GENETIC COUNSELING AND TESTING
readers use to tell your Genetic counseling can help prospective parents assess their risk of bearing children with
fortune. In children with genetic or chromosomal defects. People who have already had a child with a genetic
Down syndrome, there is a defect, who have a family history of hereditary illness, who suffer from conditions known
single horizontal line across or suspected to be inherited, or who come from ethnic groups at higher risk of passing
the palm. on genes for certain diseases can get information about the likelihood their children
being affected.
genetic counseling A genetic counselor takes a family history and gives the prospective parents and any
Clinical service that advises prospective biological children physical examinations. Laboratory investigations of blood, skin, urine,
parents of their probable risk of having
or fingerprints may be performed. Chromosomes from body tissues may be analyzed
children with hereditary defects.
and photographed, and the photographs enlarged and arranged according to size and
structure on a chart called a karyotype. This chart can show chromosomal abnormalities
and can indicate whether a person might transmit genetic defects to a child (Figure 6).
The counselor tries to help clients understand the mathematical risk of a particular
condition, explains its implications, and presents information about alternative courses
of action.
Geneticists have made great contributions to avoidance of birth defects. For example,
since so many Jewish couples have been tested for genes that carry Tay-Sachs, a fatal
disease involving degeneration of mental and physical abilities, far fewer Jewish babies
have been born with the disease (Zhang et al., 2019). Similarly, screening and counsel-
ing of women of childbearing age from Mediterranean countries, where beta thalassemia
(refer to Table 1) is common, has brought a decline in births of affected babies and
greater knowledge of the risks of being a carrier (Cao & Kan, 2013).

A B

1 2 3 4 5

C

6 7 8 9 10 11 12

D E

13 14 15 16 17 18

checkpoint
can you...
F G

19 20 21 22 Sex chromosomes
Explain the operation of
dominant inheritance, recessive FIGURE 6
inheritance, incomplete
dominance, sex-linked
Karyotype of a Female with Down Syndrome
A karyotype is a photograph that shows the chromosomes when they are separated and
inheritance, and mutations in
aligned for cell division. We know that this is a karyotype of a person with Down
transmission of birth defects?
syndrome because there are three chromosomes instead of the usual two on pair 21.
Explain the purposes of Because pair 23 consists of two Xs, we know that this is the karyotype of a female.
genetic counseling? Sources: Babu & Hirschhorn (1992); March of Dimes Birth Defects Foundation (1987).

58 EXPERIENCE HUMAN DEVELOPMENT CHAPTER 3 Forming a New Life
Studying the Influences of
Heredity and Environment
Today it has become clear that, although certain rare physical disorders are virtually 100
percent inherited, phenotypes for most traits, such as those having to do with intelligence
and personality, are subject to a complex array of hereditary and environmental forces.

MEASURING HERITABILITY
One approach to the study of heredity and environment is quantitative: It seeks to mea-
sure how much heredity and environment influence particular traits. This is the tradi-
tional goal of the science of behavioral genetics. behavioral genetics
Behavioral geneticists have developed a means of estimating how much of a trait is Quantitative study of relative hereditary
due to genetics and how much is the result of environmental influences by using a con- and environmental influences on
behavior.
cept known as heritability. Every trait is a consequence of genes and environment. By
looking at groups of people with known genetic relationships and assessing whether or heritability
not they are concordant, or the same, on a given trait, behavioral geneticists can estimate Statistical estimate of contribution of he-
the relative influence of genes and environment. redity to individual differences in a spe-
cific trait within a given population.
Heritability cannot be measured directly. Thus, researchers in behavioral genetics
have developed indirect methods for assessing the relationship between the expression concordant
of traits and the genetic and environmental factors influencing them. Although there are Term describing tendency of twins to
variations in the details, the underlying logic of the approaches in these types of studies share the same trait or disorder.
is the same.
If two people are unrelated, we know they are not likely to share any genes. If two
people are identical twins, we know they share all their genes. If two people are fraternal
twins, siblings, or parent and child, they share roughly 50 percent of their genes with Keep in mind that a
each other. And, if we know, on average, how many genes people share, then we can high heritability estimate
measure how similar they are on traits (that is, their concordance rate) and work back- does not mean that a trait
ward to determine the relative environmental influences. Therefore, if heredity has a cannot be influenced by
large influence on a particular trait, identical twins should be more alike on that trait environment. If the
than fraternal twins, and adopted children should be more like their biological parents environment changes, the
than their adoptive parents. Note that this can be carried out to more distant genetic heritability estimate may
relatives as well. For traits with strong genetic influences, for example, siblings should change as well.
be more similar than cousins on that trait.
We can also use the environment to estimate influences. If the environment exerts
a large influence on a trait, people who live together should be more similar than those
that live apart, and shared genes should matter less. For example, in this situation, we
might compare adopted children to their biological and adoptive parents. If adopted
children are more similar to their adoptive parents than their biological parents on a
trait, then that trait is likely influenced strongly by the environment.
Essentially, this approach boils down to comparisons of shared genes, the same or
different environments, and concordance rates. Using these three variables allows
researchers to make an estimate of the relative influence of genes and environment on
a trait. Different variations of this basic approach are used. In family studies, researchers
measure the degree to which biological relatives share certain traits and determine
whether or not the closeness of the familial relationship is associated with the degree
of similarity. Adoption studies look at similarities between adopted children and their
adoptive families and also between adopted children and their biological families. Twin
studies compare pairs of monozygotic, or identical, twins with same-sex dizygotic, or
fraternal, twins.
Heritability is expressed as a percentage ranging from 0.0 to 1.0: the higher the
number, the greater the heritability of a trait. A heritability estimate of 1.0 indicates that
genes are 100 percent responsible for variances in the trait within the population. A
heritability estimate of 0.0 percent would indicate the environment shaped a trait

Studying the Influences of Heredity and Environment  EXPERIENCE HUMAN DEVELOPMENT 59
 e­ xclusively. Note that heritability does not refer to the influences that shaped any one
particular person because those influences are virtually impossible to separate. Nor does
checkpoint
can you... heritability tell us how traits develop. It merely indicates the statistical extent to which
genes contribute to a trait at a certain time within a given population.
State the basic assumption
underlying studies of behav-
ioral genetics and how it
HOW HEREDITY AND THE ENVIRONMENT WORK TOGETHER
applies to family, twin, and Today many developmental scientists see heredity and environment as fundamentally
adoption studies?
intertwined. From conception on, throughout life, a combination of constitutional factors
(related to biological and psychological makeup) and social, economic, and cultural
factors help shape development.

Reaction Range Many characteristics vary, within limits, under varying hereditary or
environmental conditions. The concept of reaction range can help us visualize how this
happens.
reaction range Reaction range refers to a range of potential expressions of a hereditary trait. Body
Potential variability, depending on envi- size, for example, depends largely on biological processes, which are genetically regu-
ronmental conditions, in the expression
lated. Tall people have tall children, and short people have short children. Even so, a
of a hereditary trait.
range of sizes is possible. In societies in which nutrition has dramatically improved, an
canalization entire generation has grown up to tower over the generation before. The better-fed chil-
Limitation on variance of expression of dren share their parents’ genes but have responded to a healthier world. Ultimately,
certain inherited characteristics.
height has genetic limits. We don’t see typically developing people who are only 1 foot
tall or 10 feet tall.
Heredity can influence whether a reaction range is wide or narrow. In other words,
the genotype places limits on the range of possible phenotypes. For example, a child
born with a defect producing mild cognitive limitations is more able to respond to a
favorable environment than a child born with more severe limitations. Likewise, a child
IQ (phenotype) with greater native intelligence is likely to benefit more from an
160 enriched home and school environment than a child with a more
typical level of intelligence (Figure 7).
140 reaction
range 155 Canalization Some traits have an extremely narrow range of reac-
120 tion. The metaphor of canalization illustrates how heredity restricts
reaction 125 the range of development for some traits. After a heavy storm, the
range rainwater that has fallen on a pavement has to go somewhere. If the
100
reaction 100 street has potholes, the water will fill them. If deep canals have been
range
80
dug along the edges of the street, the water will flow into the canals.
Highly canalized traits, such as eye color, are analogous to the
deep canals. They are strongly programmed by genes, and there is
60 115
100 little opportunity for variance in their expression. Because of the
90 deep, genetically dug channel, it would take an extreme change in
40
environment to alter their course. The canal is too deep for the water
to easily slosh over.
20
Many highly canalized traits tend to be those necessary for sur-
vival. In the case of very important traits such as these, natural
Marcie Juan Andrea selection has designed them to develop in a predictable and reliable
(genotype A) (genotype B) (genotype C) way within a variety of environments and a multitude of influences.
Enriched environment Restricted environment
They are too important to be left to chance. Thus, traits such as
these tend to be highly canalized. With respect to motor develop-
ment, typical babies follow a predictable sequence: crawling or scoot-
FIGURE 7
ing, walking, and then running, in that order, at certain approximate
Intelligence and Reaction Range ages. This sequence is said to be canalized, in that children will
Children with different genotypes for intelligence will follow this same blueprint irrespective of many variations in the envi-
show varying reaction ranges when exposed to a ronment. A similar process occurs for language. Despite differences
restricted (blue portion of bar) or enriched (entire bar) in linguistic environments, babies the world over reach language mile-
environment. stones at approximately the same time and in the same order.

60 EXPERIENCE HUMAN DEVELOPMENT CHAPTER 3 Forming a New Life
 Cognition and personality, however, are not highly canalized. They are more subject
to variations in experience. Consider reading. We are not wired to read: Natural selection
has not designed us to naturally develop this skill. The environment plays a large part. In humans, walking
Parents who play letter and word games and who read to their children are likely to and talking are canalized
have children who learn to read earlier than if these skills are not encouraged or rein- traits. Can you think of
forced. Children who are not taught to read do not learn to do so spontaneously. other human physical or
behavioral characteristics
Genotype-Environment Interaction Genotype-environment interaction usually refers
that might be highly
to the effects of similar environmental conditions on genetically different individuals,
canalized?
and a discussion of these interactions is a way to conceptualize and talk about the
different ways nature and nurture interact. To take a familiar example, many children
are exposed to pollen and dust, but those with a genetic predisposition are more likely genotype-environment interaction
The portion of phenotypic variation that
to develop allergic reactions (Sordillo et al., 2015). Interactions can work the other
results from the reactions of genetically
way as well: Genetically similar children often develop differently depending on their different individuals to similar environ-
home environments. A child born with a difficult temperament may develop adjust- mental conditions.
ment problems in one family and thrive in another, depending largely on parental
handling.

Genotype-Environment Correlation The environment often reflects or reinforces One environmental
genetic differences. This tendency is called genotype-environment correlation, and it works factor that has been
in three ways to strengthen the phenotypic expression of a genotypic tendency (Berge- identified as protective
man & Plomin, 1989). The first two ways are common among younger children, the against severe allergies
third among older children, adolescents, and adults.
in children is early
Passive correlations: You not only inherit genes from your biological parents, you exposure to animals
also inherit environments. For example, a musical parent is likely to create a home (Wegienka et al., 2011).
environment in which music is heard regularly, to give a child music lessons, and to
take the child to musical events. If the child inherited the parent’s musical talent,
genotype-environment correlation
the child’s musicality will reflect a combination of genetic and environmental Tendency of certain genetic and envi-
influences. This type of correlation is called passive because the child does not ronmental influences to reinforce each
control it. Passive correlations are most applicable to young children, whose parents other; may be passive, reactive (evoca-
have a great deal of control over their early experiences. In addition, passive tive), or active. Also called genotype-
correlations function only when a child is living with a biologically related parent. environment covariance.

Reactive, or evocative, correlations: Children with differing genetic makeups evoke
different reactions from others. For example, parents who are not musically
inclined may make a special effort to provide musical experiences for a child who
Behavioral genetics
shows interest and ability in music. This response, in turn, strengthens the child’s
research with twins and
genetic inclination toward music. This type of correlation is called reactive because
the other people react to the child’s genetic makeup. siblings shows whether we
enjoy or hate exercise is
Active correlations: As children get older and have more freedom to choose their
genetically influenced and
own activities and environments, they actively select or create experiences
shows moderate heritability
consistent with their genetic tendencies. An adolescent with a talent for music will
probably seek out musical friends, take music classes, and go to concerts if such (Schutte et al., 2017).
opportunities are available. This tendency to seek out environments compatible
with one’s genotype is called niche-picking; it helps explain why identical twins niche-picking
reared apart tend to have similar characteristics. Tendency of a person, especially after
early childhood, to seek out environ-
ments compatible with his or her
Nonshared Environmental Influences Although two children in the same family may genotype.
bear a striking physical resemblance, siblings can differ greatly in intellect and especially
in personality (Plomin & Daniels, 2011). One reason may be genetic differences, which
lead children to need different kinds of stimulation or to respond differently to a similar
home environment. For example, one child may be more affected by family discord than
another (Horowitz et al., 2010). In addition, studies in behavioral genetics suggest that
many of the experiences that strongly affect development vary for different children in
a family (Dunn & Plomin, 1991). Children may live in the same family, but that does
not mean that their experiences are identical.

Studying the Influences of Heredity and Environment  EXPERIENCE HUMAN DEVELOPMENT 61
 These nonshared environmental effects result from the unique environ-
ment in which each child in a family grows up. Children in a family have
a shared environment—the home they live in, the people in it, and the
activities family members jointly engage in—but they also, even if they
are twins, have experiences that are not shared by their brothers and
sisters. Parents and siblings may treat each child differently. Certain
events, such as illnesses and accidents, and experiences outside the home
affect one child and not another. Despite being in the same family, the
influences are not identical. Indeed, some behavioral geneticists have
concluded that although heredity accounts for most of the similarity
between siblings, the nonshared environment accounts for most of the
difference (Hetherington et al., 2013).
We can also extend the conversation about genotype-environment
correlations to explain some of the effects of the nonshared environment
on siblings’ experiences. Children’s genetic differences may lead parents
to react to them differently and treat them differently. One child may be
An adolescent with artistic talent may seek out shy and elicit more gentle behavior from parents; another may be bold
opportunities to engage in creative pursuits. and be given greater freedom and encouragement to explore. Children
This is an example of niche-picking. also mold their environments by the choices they make—what they do
Hill Street Studios/Getty Images
and with whom—and their genetic makeup influences these choices. A
child who loves to read may spend hours in solitude; an athletic and sociable child may
nonshared environmental effects prefer to be outside playing with others. Thus, not only will the child’s talents (such as
The unique environment in which each reading or athleticism) develop differently, but their social life will be different as well.
child grows up, consisting of distinctive
These differences tend to be accentuated as children grow older and have more experi-
influences or influences that affect one
child differently than another. ences outside the family (Plomin, 1996; Scarr, 1992).

CHARACTERISTICS INFLUENCED BY HEREDITY
AND ENVIRONMENT
checkpoint
can you... Keeping in mind the complexity of unraveling the influences of heredity and environ-
ment, let’s look at what is known about their roles in producing certain characteristics.
Explain and give at least one
example of reaction-range Physical Health The risk of developing a wide variety of medical disorders, including
canalization and of each of the
high blood pressure, heart disease, stroke, rheumatoid arthritis, and epilepsy, has been
found to be influenced by genetics (Olczak et al., 2021; Assimes & Roberts, 2016; Dichgans
three genotype-environment
et al., 2019; Okada et al., 2019; Myers et al., 2019). Life span, too, seems to be influenced
correlations?
by genes (Melzer et al., 2020).
Differentiate the three types of Obesity is usually measured by body mass index, or BMI (comparison of weight to
genotype-environment height), and is a risk factor for many negative health outcomes. Children between the 85th
correlation? and 95th percentiles are classified as overweight, and those above the 95th percentile as
obese. The risk of obesity is 2 to 3 times higher for a child with a family history of obesity
List three kinds of influences (Bahreynian et al., 2017). Therefore, we might reasonably conclude that obesity involves
that contribute to nonshared genetic contributions.
environmental effects? Research shows that obesity is indeed affected by genetics. There is not “a” gene for
obesity; rather it is a multifactorial condition. Twin studies, adoption studies, and other
research suggest the heritability of obesity is 40 to 50 percent across the general popula-
tion. However, heritability varies across weight status. In people who are obese, heritability
estimates are 60 to 65 percent. In people who are severely obese, heritability estimates are
over 80 percent (Bouchard, 2021).
However, this increased risk is not solely genetic. Environmental experiences also con-
tribute to obesity (Willyard, 2014). The kind and amount of food eaten in a particular
home and the amount of exercise that is encouraged can increase or decrease the likelihood
that a child will become obese. Moreover, the wider social context is at play as well. Obe-
obesity
sity rates rise in countries with rapid socioeconomic growth and increases in gross domes-
Extreme overweight in relation to age,
sex, height, and body type as defined tic product (Min et al., 2013). In Western countries, obesity likely stems from the
by having a body mass index at or interaction of a genetic predisposition with overeating, supersized portions, and inadequate
above the 95th percentile. exercise (Lakerveld et al., 2017).

62 EXPERIENCE HUMAN DEVELOPMENT CHAPTER 3 Forming a New Life
Intelligence Heredity exerts a strong influence on general intelligence, as measured by
intelligence tests, and a moderate effect on specific abilities such as memory, verbal
ability, and spatial ability (Plomin & Von Stumm, 2018). Note that although specific
genes might contribute to intelligence, intelligence is best described as shaped by large
numbers of genes working together.
Indirect evidence of the role of heredity in intelligence comes from adoption and
twin studies. Adopted children’s scores on standardized intelligence tests are consistently
closer to the scores of their biological mothers than to those of their adoptive parents
and siblings; monozygotic twins are more alike in intelligence than dizygotic twins (Bri-
ley & Tucker-Drob, 2013).
Intelligence also depends in part on brain size and structure, which are under strong
genetic control (Goriounova & Mansvelder, 2019). Experience counts, too. An enriched
or impoverished environment can substantially affect the development and expression of
innate ability (Kempermann, 2019). Environmental influence is greater, and heritability
lower, among poor families than among more economically privileged families (Nisbett
et al., 2012).
The influence of genes increases sharply with age (Plomin & Dreary, 2015). This
increase is probably a result of niche-picking. The shared family environment has a strong
temperament
influence on young children but little influence on adolescents, who are more apt to find Characteristic disposition, or style of ap-
their own niche by actively selecting environments compatible with their hereditary proaching and reacting to situations.
abilities and related interests (Bouchard, 2013).
schizophrenia
Mental disorder marked by loss of
Temperament and Personality When babies are exposed to a new experience, say contact with reality; symptoms include
riding on a train or playing with a new noisy toy, some infants respond with interest and hallucinations and delusions.
excitement, and others with apprehension and withdrawal. Some babies are active, others
less so. Some babies sleep and eat at the same time every day, others have difficulty set-
tling into a consistent schedule. Right from the beginning, infants are utterly unique.
Another trait
Psychologists call babies’ unique and characteristic ways of approaching and react-
ing to environmental stimuli temperament. Temperament is largely inborn and is rela- influenced by genetics
tively consistent over the years, although it may respond to special experiences or is religiosity. Behavioral
parental handling (Goldsmith et al., 1987). In support of the role of genes, siblings— genetics research suggests
both twins and singletons—tend to be similar in temperament on such traits as positive that the tendency to believe
affect, activity level (Saudino & Micalizzi, 2015), and behavioral regulation (Gagne & strongly in a religion is
Saudino, 2010). moderately heritable;
Temperament underlies adult personality. Given the genetic contributions found for that is, at about the same
temperament, one would predict personality research should also illustrate hereditary level as intelligence (Waller
influences. This is indeed the case. Scientists have identified genes directly linked with et al., 1990).
specific aspects of personality such as neuroticism and extraversion (Vinkhuyzen et al.,
2012). Overall, the heritability of personality traits appears to be around
40 percent (Vukasović & Bratko, 2015), and there is little evidence of
shared environmental influence (Plomin, 2011). As with intelligence,
genetic influences on personality appear to become more important with
age (Briley & Tucker-Drob, 2014) and are shaped in part by active niche-
picking (Kandler & Zapko-Willmes, 2017).

Psychopathology There is evidence for a hereditary influence on such
mental disorders as schizophrenia, autism, alcoholism, and depression.
All tend to run in families and to show greater concordance between
monozygotic twins than between dizygotic twins. However, heredity alone
does not produce such disorders; an inherited tendency can be triggered
by environmental factors (Smoller et al., 2019).
Schizophrenia illustrates the interaction of heredity and genetics. Although temperamental characteristics—such as
Schizophrenia is a neurological disorder that affects about 1 percent of shyness—are genetically influenced, the environment
the US population each year (Society for Neuroscience, 2008). It is modulates the expression of these tendencies and
characterized by loss of contact with reality; hallucinations and delusions; shapes the resulting adult personality.
loss of coherent, logical thought; and inappropriate emotionality. Patricia Marks/Shutterstock

Studying the Influences of Heredity and Environment  EXPERIENCE HUMAN DEVELOPMENT 63
 ­ stimates of heritability range from 60 to 80 percent (Schwab & Wildenauer, 2013). A
E
wide array of rare gene mutations, some of which involve missing or duplicated segments
of DNA, may increase susceptibility to schizophrenia (Giegling et al., 2017). However,
monozygotic twins are not always concordant for schizophrenia, perhaps due to epigen-
etic processes (Smigielski et al., 2020).
checkpoint Researchers also have looked at possible nongenetic influences, such as a series of
can you... neurological insults in fetal life (Debnath et al., 2015), exposure to influenza or rubella
(Brown, 2012), or high stress experienced by a mother during her pregnancy (Lipner et
Discuss the evidence for
al., 2019). Infants born in urban areas or those whose mothers experienced obstetric
genetic and environmental complications or who were poor or severely deprived as a result of war or famine are
influences on physical and at higher risk (Rapoport et al., 2012), as are infants born during the winter months
physiological traits such as (Martinez-Ortega et al., 2011). Advanced paternal age is also a risk factor for schizo-
obesity, intelligence, tempera- phrenia (Lan et al., 2020), and there are indications that, at least for boys, having very
ment, and schizophrenia? young fathers may put children at elevated risk as well (Miller et al., 2010).

Prenatal Development
For many women, the first clear (though not necessarily reliable) sign of pregnancy is
gestation
a missed menstrual period. But even before that first missed period, a pregnant woman’s
Period of development between con- body undergoes subtle but noticeable changes. Table 3 lists early signs and symptoms
ception and birth. of pregnancy.
During gestation, the period between conception and birth, an unborn child under-
gestational age
Age of an unborn baby, usually dated
goes dramatic processes of development. The normal range of gestation is between 37
from the first day of an expectant moth- and 41 weeks. Gestational age is usually dated from the first day of an expectant moth-
er’s last menstrual cycle. er’s last menstrual cycle.

TABLE 3 Early Signs and Symptoms of Pregnancy
Physical Change Causes and Timing
Missed period May indicate pregnancy, although can be misleading

Tender, swollen Increased production of the female hormones estrogen and progesterone stimulates breast growth
breasts to prepare for producing milk.

Slight bleeding or Implantation bleeding may occur about 10 to 14 days after fertilization when ovum attaches to lining
cramping of uterus. Women may also cramp as the uterus enlarges.

Nausea with or Pregnancy hormones likely play a role. Morning sickness may begin as early as 2 weeks after con-
without vomiting ception but usually around 4 to 8 weeks and may occur at any time of day.

Frequent urination Enlarging uterus during first trimester exerts pressure on the bladder.

Fatigue Heart is pumping harder and faster to carry nutrients to the fetus. Stepped-up production of hormones
takes extra effort. Progesterone depresses central nervous system and may cause sleepiness.

Mood swings Flood of hormones early in pregnancy can produce emotional highs and lows.

Constipation Increase in progesterone may slow digestion, so food passes more slowly through intestinal tract.

Food aversions Hormonal changes may alter food preferences, especially during first trimester. Heightened sense of
smell may trigger nausea in response to certain foods.

Faintness and Lightheaded feeling may be triggered by blood vessel dilation and low blood pressure or by low
dizziness blood sugar.

Raised basal body Basal body temperature (taken first thing in the morning) normally rises soon after ovulation each
temperature month and then drops during menstruation. When menstruation ceases, temperature remains elevated.

Source: Mayo Clinic (2021).

64 EXPERIENCE HUMAN DEVELOPMENT CHAPTER 3 Forming a New Life
CULTURAL BELIEFS ABOUT PRENATAL DEVELOPMENT
Although our modern understanding of pregnancy differs from traditional beliefs found
in much of the world, people from all cultures share the understanding that the prenatal
environment can profoundly shape the developing human.
Much of the research on cultural beliefs about prenatal development has been con-
ducted in Asian countries, where common practices during pregnancy include massage,
the use of traditional healers, medicines and herbs, taboos against the consumption of
hot or cold foods, behavioral taboos, and superstitions (Withers et al., 2018). For exam-
ple, in Chiang Mai, Thailand, women are sometimes cautioned against eating papaya,
pickled foods, or more than half a banana during pregnancy. Spicy food, too, is advised
against as it is thought to be associated with being born hairless, and coffee or tea is
believed to negatively affect a child’s intelligence (Liamputtong et al., 2005).
Similar taboos are found worldwide. In some areas of India, “cold” foods such as
milk, yogurt, coconut, wheat, vegetables, and rice are recommended for pregnant women
and believed to guard against miscarriage (Choudry, 1997). Alternatively, Guatemalan
mothers are warned to avoid “hot” foods such as meat and beans (Cosminsky, 1982).
The Walpiri aboriginal people of Australia warn pregnant mothers to avoid eating food
made from spiked animals such as anteaters, monitor lizards, or possums and are told Pregnancy tests
to be careful not to harm any animal associated with their developing baby’s spirit, which identify the presence of
is shaped by the geographical area in which the child is conceived (Pierroutsakos, 2000). human chorionic
Traditional beliefs for the Konya of Turkey specify mothers should eat quince if a dim-
gonadotropin, which, under
pled baby is desired or apples if they want their child to have ruddy cheeks (Okka et
normal circumstances, is
al., 2016). And, Canadian First Nations people believe it is important to eat foods such
as wild meat, fish, white carrots, potatoes, rice, and berries for the baby’s health, and produced only by embryos
also stress the importance of moderate exercise lest the baby stick to the womb and and fetuses. So there are
experience a difficult labor (Sokoloski, 1995). no false positives.
These cultural beliefs are interesting because they highlight important cultural mes- A pregnancy might not be
sages and beliefs about pregnancy. However, they are also important because traditional viable, but a positive
beliefs may clash with modern medical treatment, leading some women to forego pre- pregnancy test tells a
natal care. For example, pregnant Zambian women in one study avoided medical care woman a conception has
during pregnancy in part because they believed if they divulged their use of traditional occurred.
healers to health care providers, they would be denied service (Maimbolwa et al., 2003).

STAGES OF PRENATAL DEVELOPMENT
Prenatal development takes place in three stages: germinal, embryonic, and fetal. (Table 4
gives a month-by-month description.)
Both before and after birth, development proceeds according to two fundamental
principles: Growth and motor development occur from the top down and from the
center of the body outward. The cephalocaudal principle, from Latin, meaning “head to cephalocaudal principle
tail,” dictates that development proceeds from the head to the lower part of the trunk. Principle that development proceeds in
a head-to-tail direction; that is, that up-
An embryo’s head, brain, and eyes develop earliest and are disproportionately large until
per parts of the body develop before
the other parts catch up. According to the proximodistal principle, from Latin, meaning lower parts of the trunk.
“near to far,” development proceeds from parts near the center of the body to outer
ones. The embryo’s head and trunk develop before the limbs, and the arms and legs proximodistal principle
Principle that development proceeds
before the fingers and toes.
from within to without; that is, that parts
of the body near the center develop
Germinal Stage (Fertilization to 2 Weeks) During the germinal stage, from fertiliza- before the extremities.
tion to about 2 weeks of gestational age, the zygote divides, becomes more complex, and
germinal stage
is implanted in the wall of the uterus.
First 2 weeks of prenatal development,
Within 36 hours after fertilization, the zygote enters a period of rapid cell division characterized by rapid cell division,
and duplication (mitosis). Seventy-two hours after fertilization, it has divided first into blastocyst formation, and implantation
16 and then into 32 cells; a day later, it has 64 cells. While the fertilized ovum is divid- in the wall of the uterus.
ing, it is also making its way through the fallopian tube to the uterus, a journey of 3 or
4 days. Its form changes into a blastocyst, a fluid-filled sphere, which floats freely in the
uterus until the sixth day after fertilization, when it begins to implant itself in the uter-

Prenatal Development  EXPERIENCE HUMAN DEVELOPMENT 65
 TABLE 4 Milestones in Prenatal Development
Age Accomplishments
3 weeks Nervous system begins to form.

4 weeks Heart begins to beat.

5 weeks Head continues rapid growth.

8 weeks Almost all body parts are differentiated.
12 weeks Growth of head slows.
Formation of red blood cells by liver slows. Biophoto Associates/Science Source

14 weeks Begins to coordinate limb movement
Possible to visually determine baby’s sex
16 weeks
Ultrasound shows clearly defined bone structure.
20 weeks Possible to hear heartbeat with stethoscope
Baby covered by fine downy hair called lanugo.
Fetal movements called quickening are felt by mother.

Clouds Hill Imaging Ltd/Corbis
Documentary/Getty Images

21 weeks Rapid eye movements commence.
Substantial weight gain
24 weeks Fingernails can be seen.
28 weeks Eyes open and close.
Lungs capable of breathing
32 weeks Skin pink and smooth
Chubby appearance
38 weeks Nervous system can carry out some integrative functions.
James Stevenson/Science Source
Reacts to light
Usually assumes upside-down position as birth approaches

Sources: Leifer (2003); Moore & Persaud (2003); Olds et al. (1996).

implantation ine wall. Only about 10 to 20 percent of fertilized ova complete the task of implantation
The attachment of the blastocyst to the and continue to develop. Where the egg implants will determine the placement of the
uterine wall, occurring at about day 6. placenta.
Before implantation, as cell differentiation begins, some cells around the edge of
the blastocyst cluster on one side to form the embryonic disk, a thickened cell mass
from which the embryo begins to develop. This mass will differentiate into three layers.
The ectoderm, the upper layer, will become the outer layer of skin, the nails, hair,
teeth, sensory organs, and the nervous system, including the brain and spinal cord.