Sadler_T_W_ - _Langman_39_s_medical_embryology-17-78.pdf

Full Transcript

Sadler_Chap01.indd 1 8/25/2011 3:23:38 PM
Sadler_Chap01.indd 2 8/25/2011 3:23:44 PM
 Chapter 1
Introduction to Molecular
Regulation and Signaling

M
olecular biology has opened the doors to string of DNA and is referred to as heterochro-
new ways to study embryology and to matin. For transcription to occur, this DNA
enhance our understanding of normal and must be uncoiled from the beads. In this uncoiled
abnormal development. Sequencing the human state, chromatin is referred to as euchromatin.
genome, together with creating techniques to Genes reside within the DNA strand and
investigate gene regulation at many levels of com- contain regions called exons, which can be
plexity, has taken embryology to the next level. translated into proteins, and introns, which are
Thus, from the anatomical to the biochemical to interspersed between exons and which are not
the molecular level, the story of embryology has transcribed into proteins (Fig. 1.2). In addition
progressed, and each chapter has enhanced our to exons and introns, a typical gene includes the
knowledge. following: a promoter region that binds RNA
There are approximately 23,000 genes in polymerase for the initiation of transcrip-
the human genome, which represents only one tion; a transcription initiation site; a transla-
fifth of the number predicted prior to comple- tion initiation site to designate the first amino
tion of the Human Genome Project. Because acid in the protein; a translation termination
of various levels of regulation, however, the codon; and a 3′ untranslated region that includes
number of proteins derived from these genes is a sequence (the poly A addition site) that assists
closer to the original predicted number of genes. with stabilizing the mRNA, allows it to exit the
What has been disproved is the one-gene–one- nucleus, and permits it to be translated into pro-
protein hypothesis. Thus, through a variety of tein (Fig. 1.2). By convention, the 5′ and the 3′
mechanisms, a single gene may give rise to many regions of a gene are specified in relation to the
proteins. RNA transcribed from the gene. Thus, DNA is
Gene expression can be regulated at several transcribed from the 5′ to the 3′ end, and the
levels: (1) different genes may be transcribed, (2) promoter region is upstream from the tran-
nuclear deoxyribonucleic acid (DNA) transcribed scription initiation site (Fig. 1.2). The promoter
from a gene may be selectively processed to regu- region, where the RNA polymerase binds, usu-
late which RNAs reach the cytoplasm to become ally contains the sequence TATA, and this site
messenger RNAs (mRNAs), (3) mRNAs may be
selectively translated, and (4) proteins made from
the mRNAs may be differentially modified. Histone complex

DNA
GENE TRANSCRIPTION
Genes are contained in a complex of DNA and
proteins (mostly histones) called chromatin, and
Nucleosome
its basic unit of structure is the nucleosome
(Fig. 1.1). Each nucleosome is composed of an H1
octamer of histone proteins and approximately histones Linker
140 base pairs of DNA. Nucleosomes themselves DNA
are joined into clusters by binding of DNA exist-
ing between nucleosomes (linker DNA) with Figure 1.1 Drawing showing nucleosomes that form the
other histone proteins (H1 histones; Fig. 1.1). basic unit of chromatin. Each nucleosome consists of an
Nucleosomes keep the DNA tightly coiled, such octamer of histone proteins and approximately 140 base
that it cannot be transcribed. In this inactive state, pairs of DNA. Nucleosomes are joined into clusters by
chromatin appears as beads of nucleosomes on a linker DNA and other histone proteins.

3

Sadler_Chap01.indd 3 8/25/2011 3:23:44 PM
 4 Part 1 General Embryology

Promoter
region Exon 1 Intron 1 Exon 2 Intron 2 Exon 3 Intron 3 Exon 4

3' untranslated region

TATA Translation Enhancer Translation Transcription
box initiation sequence termination termination
codon Poly A site
addition site
Figure 1.2 Drawing of a “typical” gene showing the promoter region containing the TATA box; exons that contain DNA
sequences that are translated into proteins; introns; the transcription initiation site; the translation initiation site that
designates the code for the first amino acid in a protein; and the 3′ untranslated region that includes the poly A addition site
that participates in stabilizing the mRNA, allows it to exit the nucleus, and permits its translation into a protein.

is called the TATA box (Fig. 1.2). In order to appropriate tissue. Enhancers act by altering
bind to this site, however, the polymerase requires chromatin to expose the promoter or by facilitat-
additional proteins called transcription factors ing binding of the RNA polymerase. Sometimes,
(Fig. 1.3).Transcription factors also have a specific enhancers can inhibit transcription and are called
DNA-binding domain plus a transactivat- silencers. This phenomenon allows a transcrip-
ing domain that activates or inhibits transcrip- tion factor to activate one gene while silencing
tion of the gene whose promoter or enhancer it another by binding to different enhancers. Thus,
has bound. In combination with other proteins, transcription factors themselves have a DNA-
transcription factors activate gene expression binding domain specific to a region of DNA plus
by causing the DNA nucleosome complex to a transactivating domain that binds to a promoter
unwind, by releasing the polymerase so that it or an enhancer and activates or inhibits the gene
can transcribe the DNA template, and by pre- regulated by these elements.
venting new nucleosomes from forming.
Enhancers are regulatory elements of DNA DNA Methylation Represses
that activate utilization of promoters to control Transcription
their efficiency and the rate of transcription from Methylation of cytosine bases in the promoter
the promoter. Enhancers can reside anywhere regions of genes represses transcription of those
along the DNA strand and do not have to reside genes. Thus, some genes are silenced by this
close to a promoter. Like promoters, enhancers mechanism. For example, one of the X chro-
bind transcription factors (through the transcrip- mosomes in each cell of a female is inactivated
tion factor’s transactivating domain) and are used (X chromosome inactivation) by this meth-
to regulate the timing of a gene’s expression and ylation mechanism. Similarly, genes in different
its cell-specific location. For example, separate types of cells are repressed by methylation, such
enhancers in a gene can be used to direct the that muscle cells make muscle proteins (their
same gene to be expressed in different tissues. promoter DNA is mostly unmethylated), but not
The PAX6 transcription factor, which partici- blood proteins (their DNA is highly methylated).
pates in pancreas, eye, and neural tube develop- In this manner, each cell can maintain its char-
ment, contains three separate enhancers, each acteristic differentiated state. DNA methylation
of which regulates the gene’s expression in the is also responsible for genomic imprinting in

RNA Polymerase II RNA Polymerase II DNA

TATA

Transcription Transcription RNA transcript
factor protein initiation site
complex
Figure 1.3 Drawing showing binding of RNA polymerase II to the TATA box site of the promoter region of a gene. This
binding requires a complex of proteins plus an additional protein called a transcription factor. Transcription factors have their
own specific DNA-binding domain and function to regulate gene expression.

Sadler_Chap01.indd 4 8/25/2011 3:23:53 PM
 Chapter 1 Introduction to Molecular Regulation and Signaling 5

which only a gene inherited from the father or have to be cleaved to become active, or they
the mother is expressed, while the other gene might have to be phosphorylated. Others need
is silenced. Approximately 40 to 60 human to combine with other proteins or be released
genes are imprinted and their methylation pat- from sequestered sites or be targeted to specific
terns are established during spermatogenesis and cell regions. Thus, there are many regulatory lev-
oogenesis. Methylation silences DNA by inhib- els for synthesizing and activating proteins, such
iting binding of transcription factors or by alter- that although only 23,000 genes exist, the poten-
ing histone binding resulting in stabilization of tial number of proteins that can be synthesized is
nucleosomes and tightly coiled DNA that cannot probably closer to five times the number of genes.
be transcribed.
INDUCTION AND ORGAN
OTHER REGULATORS OF GENE FORMATION
EXPRESSION
Organs are formed by interactions between cells
The initial transcript of a gene is called nuclear and tissues. Most often, one group of cells or tissues
RNA (nRNA) or sometimes premessenger RNA. causes another set of cells or tissues to change
nRNA is longer than mRNA because it con- their fate, a process called induction. In each such
tains introns that are removed (spliced out) as interaction, one cell type or tissue is the inducer
the nRNA moves from the nucleus to the cyto- that produces a signal, and one is the responder
plasm. In fact, this splicing process provides a to that signal. The capacity to respond to such
means for cells to produce different proteins from a signal is called competence, and competence
a single gene. For example, by removing different requires activation of the responding tissue by a
introns, exons are “spliced” in different patterns, competence factor. Many inductive interac-
a process called alternative splicing (Fig. 1.4). tions occur between epithelial and mesenchymal
The process is carried out by spliceosomes, cells and are called epithelial–mesenchymal
which are complexes of small nuclear RNAs interactions (Fig. 1.5). Epithelial cells are joined
(snRNAs) and proteins that recognize specific together in tubes or sheets, whereas mesenchymal
splice sites at the 5′ or the 3′ ends of the nRNA. cells are fibroblastic in appearance and dispersed
Proteins derived from the same gene are called in extracellular matrices (Fig. 1.5). Examples of
splicing isoforms (also called splice vari- epithelial–mesenchymal interactions include the
ants or alternative splice forms), and these following: gut endoderm and surrounding mes-
afford the opportunity for different cells to use enchyme to produce gut-derived organs, includ-
the same gene to make proteins specific for that ing the liver and pancreas; limb mesenchyme
cell type. For example, isoforms of the WT1 gene with overlying ectoderm (epithelium) to pro-
have different functions in gonadal versus kidney duce limb outgrowth and differentiation; and
development. endoderm of the ureteric bud and mesenchyme
Even after a protein is made (translated), there from the metanephric blastema to produce
may be post-translational modifications that nephrons in the kidney. Inductive interactions
affect its function. For example, some proteins can also occur between two epithelial tissues,

5' untranslated Tissue specific 3' untranslated
region Exons Exon (bone) Introns region

Hypothetical
gene

Protein I

Protein II
(bone)

Protein III
Figure 1.4 Drawing of a hypothetical gene illustrating the process of alternative splicing to form different proteins from
the same gene. Spliceosomes recognize specific sites on the initial transcript of nRNA from a gene. Based on these sites,
different introns are “spliced out” to create more than one protein from a single gene. Proteins derived from the same gene
are called splicing isoforms.

Sadler_Chap01.indd 5 8/25/2011 3:23:53 PM
 6 Part 1 General Embryology

to interact with other cells, or by juxtacrine
interactions, which do not involve diffusable
Mesenchyme
proteins. The diffusable proteins responsible for
paracrine signaling are called paracrine fac-
tors or growth and differentiation factors
Epithelium
(GDFs).

Signal Transduction Pathways
Paracrine Signaling
Figure 1.5 Drawing illustrating an epithelial–mesenchymal Paracrine factors act by signal transduction
interaction. Following an initial signal from one tissue, a pathways either by activating a pathway directly
second tissue is induced to differentiate into a specific or by blocking the activity of an inhibitor of a
structure. The first tissue constitutes the inducer, and the pathway (inhibiting an inhibitor, as is the case
second is the responder. Once the induction process is with hedgehog signaling). Signal transduction
initiated, signals (arrows) are transmitted in both directions pathways include a signaling molecule (the
to complete the differentiation process. ligand) and a receptor (Fig. 1.6). The receptor
spans the cell membrane and has an extracel-
such as induction of the lens by epithelium of lular domain (the ligand-binding region), a
the optic cup. Although an initial signal by the transmembrane domain, and a cytoplasmic
inducer to the responder initiates the inductive domain. When a ligand binds its receptor, it
event, crosstalk between the two tissues or cell induces a conformational change in the recep-
types is essential for differentiation to continue tor that activates its cytoplasmic domain. Usually,
(Fig. 1.5, arrows). the result of this activation is to confer enzy-
matic activity to the receptor, and most often
CELL SIGNALING this activity is a kinase that can phosphorylate
other proteins using ATP as a substrate. In turn,
Cell-to-cell signaling is essential for induction, phosphorylation activates these proteins to phos-
for conference of competency to respond, and for phorylate additional proteins, and thus a cascade
crosstalk between inducing and responding cells. of protein interactions is established that ulti-
These lines of communication are established by mately activates a transcription factor. This
paracrine interactions, whereby proteins syn- transcription factor then activates or inhibits
thesized by one cell diffuse over short distances gene expression. The pathways are numerous and

Ligand
Receptor complex
Cell membrane

P P Activated
P P (kinase) region

P Activated protein
Nuclear
Cytoplasm
pores
P Activated protein
complex

Activated protein
P
complex acts as a
transcription factor

Nucleus

Figure 1.6 Drawing of a typical signal transduction pathway involving a ligand and its receptor. Activation of the receptor
is conferred by binding to the ligand. Typically, the activation is enzymatic involving a tyrosine kinase, although other enzymes
may be employed. Ultimately, kinase activity results in a phosphorylation cascade of several proteins that activates a
transcription factor for regulating gene expression.

Sadler_Chap01.indd 6 8/25/2011 3:23:53 PM
 Chapter 1 Introduction to Molecular Regulation and Signaling 7

complex and in some cases are characterized by a channel, and these channels are “connected”
one protein inhibiting another that in turn acti- between adjacent cells.
vates another protein (much like the situation It is important to note that there is a great
with hedgehog signaling). amount of redundancy built into the process of
signal transduction. For example, paracrine sig-
Juxtacrine Signaling
naling molecules often have many family mem-
Juxtacrine signaling is mediated through sig-
bers such that other genes in the family may
nal transduction pathways as well but does not
compensate for the loss of one of their coun-
involve diffusable factors. Instead, there are three
terparts. Thus, the loss of function of a signaling
ways juxtacrine signaling occurs: (1) A protein
protein through a gene mutation does not neces-
on one cell surface interacts with a receptor on
sarily result in abnormal development or death.
an adjacent cell in a process analogous to para-
In addition, there is crosstalk between pathways,
crine signaling (Fig. 1.6). The Notch pathway
such that they are intimately interconnected.
represents an example of this type of signal-
These connections provide numerous additional
ing. The Notch receptor protein extends across
sites to regulate signaling.
the cell membrane and binds to cells that have
Delta, Serrate, or Jagged proteins in their
cell membranes. Binding of one of these pro- Paracrine Signaling Factors
teins to Notch causes a conformational change There are a large number of paracrine signaling
in the Notch protein such that part of it on the factors acting as ligands, which are also called
cytoplasmic side of the membrane is cleaved.The GDFs. Most are grouped into four families, and
cleaved portion then binds to a transcription fac- members of these same families are used repeat-
tor to activate gene expression. Notch signaling edly to regulate development and differentiation
is especially important in neuronal differentia- of organ systems. Furthermore, the same GDFs
tion, blood vessel specification, and somite seg- regulate organ development throughout the ani-
mentation. (2) Ligands in the extracellular matrix mal kingdom from Drosophila to humans. The
secreted by one cell interact with their receptors four groups of GDFs include the fibroblast
on neighboring cells. The extracellular matrix growth factor (FGF), WNT, hedgehog, and
is the milieu in which cells reside. This milieu transforming growth factor-b (TGF-b)
consists of large molecules secreted by cells families. Each family of GDFs interacts with its
including collagen, proteoglycans (chondroi- own family of receptors, and these receptors are
tin sulfates, hyaluronic acid, etc.), and gly- as important as the signal molecules themselves
coproteins, such as fibronectin and laminin. in determining the outcome of a signal.
These molecules provide a substrate for cells on Fibroblast Growth Factors
which they can anchor or migrate. For example, Originally named because they stimulate the
laminin and type IV collagen are components growth of fibroblasts in culture, there are now
of the basal lamina for epithelial cell attach- approximately two dozen FGF genes that have
ment, and fibronectin molecules form scaffolds been identified, and they can produce hundreds
for cell migration. Receptors that link extracellu- of protein isoforms by altering their RNA splic-
lar molecules such as fibronectin and laminin to ing or their initiation codons. FGF proteins
cells are called integrins. These receptors “inte- produced by these genes activate a collection
grate” matrix molecules with a cell’s cytoskel- of tyrosine receptor kinases called fibro-
etal machinery (e.g., actin microfilaments) blast growth factor receptors (FGFRs). In
thereby creating the ability to migrate along turn, these receptors activate various signaling
matrix scaffolding by using contractile proteins, pathways. FGFs are particularly important for
such as actin. Also, integrins can induce gene angiogenesis, axon growth, and mesoderm dif-
expression and regulate differentiation as in the ferentiation. Although there is redundancy in
case of chondrocytes that must be linked to the the family, such that FGFs can sometimes sub-
matrix to form cartilage. (3) There is direct trans- stitute for one another, individual FGFs may be
mission of signals from one cell to another by responsible for specific developmental events. For
gap junctions. These junctions occur as chan- example, FGF8 is important for development of
nels between cells through which small mol- the limbs and parts of the brain.
ecules and ions can pass. Such communication is
important in tightly connected cells like epithelia Hedgehog Proteins
of the gut and neural tube because they allow The hedgehog gene was named because it coded
these cells to act in concert. The junctions them- for a pattern of bristles on the leg of Drosophila
selves are made of connexin proteins that form that resembled the shape of a hedgehog. In

Sadler_Chap01.indd 7 8/25/2011 3:23:54 PM
 8 Part 1 General Embryology

mammals, there are three hedgehog genes, apoptosis (programmed cell death) in the
Desert, Indian, and sonic hedgehog. Sonic hedgehog interdigital spaces and in other cell types.
is involved in a number of developmental events
including limb patterning, neural tube induc-
tion and patterning, somite differentiation, gut Summary
regionalization, and others. The receptor for the
hedgehog family is Patched, which binds to a During the past century, embryology has pro-
protein called Smoothened. The Smoothened gressed from an observational science to one
protein transduces the hedgehog signal, but it involving sophisticated technological and molec-
is inhibited by Patched until the hedgehog pro- ular advances. Together, observations and mod-
tein binds to this receptor. Thus, the role of the ern techniques provide a clearer understanding
paracrine factor hedgehog in this example is to of the origins of normal and abnormal develop-
bind to its receptor to remove the inhibition of a ment and, in turn, suggest ways to prevent and
transducer that would normally be active, not to treat birth defects. In this regard, knowledge of
activate the transducer directly. gene function has created entire new approaches
to the subject.
WNT Proteins There are approximately 23,000 genes in
There are at least 15 different WNT genes that the human genome, but these genes code for
are related to the segment polarity gene, wingless approximately 100,000 proteins. Genes are
in Drosophilia.Their receptors are members of the contained in a complex of DNA and proteins
frizzled family of proteins. WNT proteins are called chromatin, and its basic unit of structure
involved in regulating limb patterning, midbrain is the nucleosome. Chromatin appears tightly
development, and some aspects of somite and coiled as beads of nucleosomes on a string and
urogenital differentiation among other actions. is called heterochromatin. For transcription to
occur, DNA must be uncoiled from the beads
The TGF-b Superfamily as euchromatin. Genes reside within strands
The TGF-b superfamily has more than 30 mem- of DNA and contain regions that can be trans-
bers and includes the TGF-bs, the bone mor- lated into proteins, called exons, and untranslat-
phogenetic proteins, the activin family, the able regions, called introns. A typical gene also
Müllerian inhibiting factor (MIF, anti-Mül- contains a promoter region that binds RNA
lerian hormone), and others. The first member polymerase for the initiation of transcription; a
of the family, TGF-b1, was isolated from virally transcription initiation site, to designate the
transformed cells.TGF-b members are important first amino acid in the protein; a translation ter-
for extracellular matrix formation and epithelial mination codon; and a 3′ untranslated region
branching that occurs in lung, kidney, and salivary that includes a sequence (the poly A addition
gland development. The BMP family induces site) that assists with stabilization of the mRNA.
bone formation and is involved in regulating cell The RNA polymerase binds to the promoter
division, cell death (apoptosis), and cell migration region that usually contains the sequence TATA,
among other functions. the TATA box. Binding requires additional pro-
teins called transcription factors. Methylation
Other Paracrine Signaling Molecules of cytosine bases in the promoter region silences
Another group of paracrine signaling molecules genes and prevents transcription. This process is
important during development are neurotrans- responsible for X chromosome inactivation
mitters, including serotonin and norepinephrine, whereby the expression of genes on one of the X
that act as ligands and bind to receptors just as pro- chromosomes in females is silenced and also for
teins do.These molecules are not just transmitters genomic imprinting in which either a paternal
for neurons, but also provide important signals for or a maternal gene’s expression is repressed.
embryological development. For example, sero- Different proteins can be produced from a
tonin (5HT) acts as a ligand for a large number of single gene by the process of alternative splicing
receptors, most of which are G protein–coupled that removes different introns using spliceo-
receptors. Acting through these receptors, 5HT somes. Proteins derived in this manner are called
regulates a variety of cellular functions, including splicing isoforms or splice variants. Also,
cell proliferation and migration, and is impor- proteins may be altered by post-translational
tant for establishing laterality, gastrulation, heart modifications, such as phosphorylation or
development, and other processes during early cleavage.
stages of differentiation. Norepinephrine also acts Induction is the process whereby one group
through receptors and appears to play a role in of cells or tissues (the inducer) causes another

Sadler_Chap01.indd 8 8/25/2011 3:23:54 PM
 Chapter 1 Introduction to Molecular Regulation and Signaling 9

group (the responder) to change their fate. The neurotransmitters, such as serotonin (5HT)
capacity to respond is called competence and and norepinephrine, also act through para-
must be conferred by a competence factor. crine signaling, serving as ligands and binding to
Many inductive phenomena involve epithelial– receptors to produce specific cellular responses.
mesenchymal interactions. Juxtacrine factors may include products of the
Signal transduction pathways include a extracellular matrix, ligands bound to a cell’s
signaling molecule (the ligand) and a recep- surface, and direct cell-to-cell communications.
tor. The receptor usually spans the cell mem-
brane and is activated by binding with its specific
ligand. Activation usually involves the capacity Problems to Solve
to phosphorylate other proteins, most often as
a kinase. This activation establishes a cascade of 1. What is meant by “competence to respond”
enzyme activity among proteins that ultimately as part of the process of induction? What
activates a transcription factor for initiation of tissues are most often involved in induction?
gene expression. Give two examples.
Cell-to-cell signaling may be paracrine, 2. Under normal conditions, FGFs and their
involving diffusable factors, or juxtacrine, receptors (FGFRs) are responsible for growth
involving a variety of nondiffusable factors. of the skull and development of the cranial
Proteins responsible for paracrine signaling are sutures. How might these signaling pathways
called paracrine factors or growth and dif- be disrupted? Do these pathways involve
ferentiation factors (GDFs). There are four paracrine or juxtacrine signaling? Can you
major families of GDFs: FGFs, WNTs, hedge- think of a way that loss of expression of one
hogs, and TGF-bs. In addition to proteins, FGF might be circumvented?

Sadler_Chap01.indd 9 8/25/2011 3:23:54 PM
 Amniotic cavity
Head end
of embryo Tail end
Future
umbilical
cord

Heart Allantois
Primordial
germ cells
in wall of
yolk sac
Yolk sac

Sadler_Chap02.indd 10 8/25/2011 8:21:41 PM
 Chapter 2 Gametogenesis: Conversion of Germ Cells into Male and Female Gametes 11

THE CHROMOSOME THEORY OF chromosomes are extremely long, they are spread
INHERITANCE diffusely through the nucleus, and they cannot
be recognized with the light microscope. With
Traits of a new individual are determined by spe- the onset of mitosis, the chromosomes begin to
cific genes on chromosomes inherited from the coil, contract, and condense; these events mark
father and the mother. Humans have approxi- the beginning of prophase. Each chromosome
mately 23,000 genes on 46 chromosomes. Genes now consists of two parallel subunits, chroma-
on the same chromosome tend to be inherited tids, that are joined at a narrow region common
together and so are known as linked genes. to both called the centromere. Throughout
In somatic cells, chromosomes appear as 23 prophase, the chromosomes continue to con-
homologous pairs to form the diploid num- dense, shorten, and thicken (Fig. 2.3A), but only
ber of 46. There are 22 pairs of matching chro- at prometaphase do the chromatids become dis-
mosomes, the autosomes, and one pair of sex tinguishable (Fig. 2.3B). During metaphase, the
chromosomes. If the sex pair is XX, the indi- chromosomes line up in the equatorial plane,
vidual is genetically female; if the pair is XY, the and their doubled structure is clearly visible
individual is genetically male. One chromosome (Fig. 2.3C). Each is attached by microtubules
of each pair is derived from the maternal gamete, extending from the centromere to the centriole,
the oocyte, and one from the paternal gamete, forming the mitotic spindle. Soon, the centro-
the sperm. Thus, each gamete contains a hap- mere of each chromosome divides, marking the
loid number of 23 chromosomes, and the union beginning of anaphase, followed by migration
of the gametes at fertilization restores the dip- of chromatids to opposite poles of the spindle.
loid number of 46. Finally, during telophase, chromosomes uncoil
and lengthen, the nuclear envelope reforms,
Mitosis and the cytoplasm divides (Fig. 2.3D–F ). Each
Mitosis is the process whereby one cell divides, daughter cell receives half of all doubled chromo-
giving rise to two daughter cells that are geneti- some material and thus maintains the same num-
cally identical to the parent cell (Fig. 2.3). Each ber of chromosomes as the mother cell.
daughter cell receives the complete complement
of 46 chromosomes. Before a cell enters mitosis, Meiosis
each chromosome replicates its deoxyribonu- Meiosis is the cell division that takes place in the
cleic acid (DNA). During this replication phase, germ cells to generate male and female gametes,

Chromosome Double-structured
Centriole
chromosome

A B C
Prophase Prometaphase Metaphase

D E F
Anaphase Telophase Daughter cells
Figure 2.3 Various stages of mitosis. In prophase, chromosomes are visible as slender threads. Doubled chromatids
become clearly visible as individual units during metaphase. At no time during division do members of a chromosome pair
unite. Blue, paternal chromosomes; red, maternal chromosomes.

Sadler_Chap02.indd 11 8/25/2011 8:21:45 PM
 12 Part 1 General Embryology

sperm and egg cells, respectively. Meiosis requires paired homologous chromosomes (Fig. 2.4C).
two cell divisions, meiosis I and meiosis II, Segments of chromatids break and are exchanged
to reduce the number of chromosomes to the as homologous chromosomes separate. As separa-
haploid number of 23 (Fig. 2.4). As in mitosis, tion occurs, points of interchange are temporarily
male and female germ cells (spermatocytes united and form an X-like structure, a chiasma
and primary oocytes) at the beginning of (Fig. 2.4C). The approximately 30 to 40 cross-
meiosis I replicate their DNA so that each of overs (one or two per chromosome) with each
the 46 chromosomes is duplicated into sister meiotic I division are most frequent between
chromatids. In contrast to mitosis, however, genes that are far apart on a chromosome.
homologous chromosomes then align them- As a result of meiotic divisions:
selves in pairs, a process called synapsis. The Genetic variability is enhanced through
pairing is exact and point for point except for crossover, which redistributes genetic
the XY combination. Homologous pairs then material
separate into two daughter cells, thereby reduc- random distribution of homologous chro-
ing the chromosome number from diploid to mosomes to the daughter cells
haploid. Shortly thereafter, meiosis II separates Each germ cell contains a haploid number
sister chromatids. Each gamete then contains of chromosomes, so that at fertilization the
23 chromosomes. diploid number of 46 is restored.
Crossover Polar Bodies
Crossovers, critical events in meiosis I, are the Also during meiosis, one primary oocyte gives
interchange of chromatid segments between rise to four daughter cells, each with 22 plus

A B C D
Pairing begins Pairing of Chiasma Pulling apart of
chromosomes formation double-structured
chromosomes

Anaphase of 1st
meiotic division

E

Cells contain 23 Cells resulting
double-structured from 1st
chromosomes meiotic division

F

Cells contain 23 Cells resulting
single chromosomes from 2nd
meiotic division
G
Figure 2.4 First and second meiotic divisions. A. Homologous chromosomes approach each other. B. Homologous
chromosomes pair, and each member of the pair consists of two chromatids. C. Intimately paired homologous chromosomes
interchange chromatid fragments (crossover). Note the chiasma. D. Double-structured chromosomes pull apart. E. Anaphase
of the first meiotic division. F,G. During the second meiotic division, the double-structured chromosomes split at the
centromere. At completion of division, chromosomes in each of the four daughter cells are different from each other.

Sadler_Chap02.indd 12 8/25/2011 8:21:45 PM
 Primary oocyte
after DNA These cells contain
replication 46 double-structured Primary spermatocyte
chromosomes after DNA replication

First Maturation Division

Secondary 23 double-structured
oocyte chromosomes Secondary
spermatocyte
Second Maturation
Division
Mature
oocyte 23 single
(22 + X) chromosomes (22 + X) (22 + Y)

A Polar bodies B Spermatids
(22 + X)

Sadler_Chap02.indd 13 8/25/2011 8:21:45 PM
 Primary oocyte or spermatocyte
after DNA duplication
46 double-structured
chromosomes

Normal meiotic Nondisjunction Nondisjunction
division 1st meiotic division 2nd meiotic division

2nd meiotic 2nd meiotic 2nd meiotic
division division division

24 22 22 24 22 24
23 single chromosomes chromosomes chromosomes
A B C

Sadler_Chap02.indd 14 8/25/2011 8:21:48 PM
 A

14 21 t(14;21)

B

Sadler_Chap02.indd 15 8/25/2011 8:21:49 PM
 1 2 3 4 5

6 7 8 9 10 11 12

13 14 15 16 17 18

19 20 21 22 X Y

A B

Sadler_Chap02.indd 16 8/25/2011 8:21:50 PM
Sadler_Chap02.indd 17 8/25/2011 8:21:53 PM
 A B

C D

Sadler_Chap02.indd 18 8/25/2011 8:21:55 PM
Sadler_Chap02.indd 19 8/25/2011 8:22:01 PM
Sadler_Chap02.indd 20 8/25/2011 8:22:03 PM
 A B

Mitotic Mitotic
division division

A B C
Primordial Oogonium Primary oocyte
germ cell in prophase

Sadler_Chap02.indd 21 8/25/2011 8:22:03 PM
 22 Part 1 General Embryology

Surface epithelium of ovary Resting primary oocyte
Primary oocyte (diplotene stage)
in prophase
Follicular cell
Flat
epithelial
cell

Oogonia

Primary
oocytes in
prophase
of 1st
meiotic
division

A B C
4th month 7th month Newborn

Figure 2.17 Segment of the ovary at different stages of development. A. Oogonia are grouped in clusters in the cortical part of
the ovary. Some show mitosis; others have differentiated into primary oocytes and entered prophase of the first meiotic division.
B. Almost all oogonia are transformed into primary oocytes in prophase of the first meiotic division. C. There are no oogonia. Each
primary oocyte is surrounded by a single layer of follicular cells, forming the primordial follicle. Oocytes have entered the diplotene
stage of prophase, in which they remain until just before ovulation. Only then do they enter metaphase of the first meiotic division.

follicular epithelial cells (Fig. 2.17B). A primary by follicular cells. The total number of primary
oocyte, together with its surrounding flat epithelial oocytes at birth is estimated to vary from 600,000 to
cells, is known as a primordial follicle (Fig. 2.18A). 800,000. During childhood, most oocytes become
atretic; only approximately 40,000 are present by the
Maturation of Oocytes Continues at Puberty beginning of puberty, and fewer than 500 will be
Near the time of birth, all primary oocytes have ovulated. Some oocytes that reach maturity late in
started prophase of meiosis I, but instead of proceed- life have been dormant in the diplotene stage of the
ing into metaphase, they enter the diplotene stage, first meiotic division for 40 years or more before
a resting stage during prophase that is character- ovulation. Whether the diplotene stage is the most
ized by a lacy network of chromatin (Fig. 2.17C). suitable phase to protect the oocyte against environ-
Primary oocytes remain arrested in prophase and do not mental influences is unknown.The fact that the risk
finish their first meiotic division before puberty is reached. of having children with chromosomal abnormalities
This arrested state is produced by oocyte matu- increases with maternal age indicates that primary
ration inhibitor (OMI), a small peptide secreted oocytes are vulnerable to damage as they age.

A B C
Figure 2.18 A. Primordial follicle consisting of a primary oocyte surrounded by a layer of flattened epithelial cells. B. Early primary or
preantral stage follicle recruited from the pool of primordial follicles.As the follicle grows, follicular cells become cuboidal and begin to
secrete the zona pellucida, which is visible in irregular patches on the surface of the oocyte. C. Mature primary (preantral) follicle with
follicular cells forming a stratified layer of granulosa cells around the oocyte and the presence of a well-defined zona pellucida.

Sadler_Chap02.indd 22 8/25/2011 8:22:06 PM
 Chapter 2 Gametogenesis: Conversion of Germ Cells into Male and Female Gametes 23

At puberty, a pool of growing follicles is As development continues, fluid-filled spaces
established and continuously maintained from appear between granulosa cells. Coalescence of
the supply of primordial follicles. Each month, these spaces forms the antrum, and the follicle is
15 to 20 follicles selected from this pool begin to termed a vesicular or an antral follicle. Initially,
mature. Some of these die, while others begin to the antrum is crescent-shaped, but with time, it
accumulate fluid in a space called the antrum, enlarges (Fig. 2.19). Granulosa cells surrounding
thereby entering the antral or vesicular stage the oocyte remain intact and form the cumulus
(Fig. 2.19A). Fluid continues to accumulate such oophorus. At maturity, the mature vesicular
that, immediately prior to ovulation, follicles are (Graafian) follicle may be 25 mm or more in
quite swollen and are called mature vesicular diameter. It is surrounded by the theca interna,
follicles or Graffian follicles (Fig. 2.19B). The which is composed of cells having characteristics
antral stage is the longest,whereas the mature vesic- of steroid secretion, rich in blood vessels, and the
ular stage encompasses approximately 37 hours theca externa, which gradually merges with the
prior to ovulation. ovarian connective tissue (Fig. 2.19).
As primordial follicles begin to grow, sur- With each ovarian cycle, a number of follicles
rounding follicular cells change from flat to begin to develop, but usually only one reaches
cuboidal and proliferate to produce a stratified full maturity. The others degenerate and become
epithelium of granulosa cells, and the unit atretic. When the secondary follicle is mature, a
is called a primary follicle (Fig. 2.18B,C). surge in luteinizing hormone (LH) induces
Granulosa cells rest on a basement membrane the preovulatory growth phase. Meiosis I is com-
separating them from surrounding ovarian con- pleted, resulting in formation of two daughter cells
nective tissue (stromal cells) that form the theca of unequal size, each with 23 double-structured
folliculi. Also, granulosa cells and the oocyte chromosomes (Fig. 2.20A,B). One cell, the sec-
secrete a layer of glycoproteins on the surface of ondary oocyte, receives most of the cytoplasm;
the oocyte, forming the zona pellucida (Fig. the other, the first polar body, receives practically
2.18C). As follicles continue to grow, cells of none. The first polar body lies between the zona
the theca folliculi organize into an inner layer of pellucida and the cell membrane of the secondary
secretory cells, the theca interna, and an outer oocyte in the perivitelline space (Fig. 2.20B). The
fibrous capsule, the theca externa. Also, small, cell then enters meiosis II but arrests in metaphase
finger-like processes of the follicular cells extend approximately 3 hours before ovulation. Meiosis
across the zona pellucida and interdigitate with II is completed only if the oocyte is fertilized;
microvilli of the plasma membrane of the oocyte. otherwise, the cell degenerates approximately 24
These processes are important for transport of hours after ovulation. The first polar body may
materials from follicular cells to the oocyte. undergo a second division (Fig. 2.20C).

Theca interna

Theca externa
Follicular antrum

Antrum

Primary
oocyte

A B
Zona pellucida Cumulus oophorus

Figure 2.19 A. Vesicular (antral) stage follicle.The oocyte, surrounded by the zona pellucida, is off center; the antrum has
developed by fluid accumulation between intercellular spaces. Note the arrangement of cells of the theca interna and the
theca externa. B. Mature vesicular (Graafian) follicle.The antrum has enlarged considerably, is filled with follicular fluid, and is
surrounded by a stratified layer of granulosa cells.The oocyte is embedded in a mound of granulosa cells, the cumulus oophorus.

Sadler_Chap02.indd 23 8/25/2011 8:22:07 PM
 24 Part 1 General Embryology

Secondary oocyte
Zona pellucida Granulosa cells in division

A B C
Primary oocyte in division Secondary oocyte and Polar body in division
polar body 1
Figure 2.20 Maturation of the oocyte. A. Primary oocyte showing the spindle of the first meiotic division. B. Secondary
oocyte and first polar body. The nuclear membrane is absent. C. Secondary oocyte showing the spindle of the second
meiotic division. The first polar body is also dividing.

Spermatogenesis Shortly before puberty, the sex cords
Maturation of Sperm Begins at Puberty acquire a lumen and become the seminif-
Spermatogenesis, which begins at puberty, erous tubules. At about the same time,
includes all of the events by which sper- PGCs give rise to spermatogonial stem cells.
matogonia are transformed into spermato- At regular intervals, cells emerge from this
zoa. At birth, germ cells in the male infant stem cell population to form type A sper-
can be recognized in the sex cords of the tes- matogonia, and their production marks
tis as large, pale cells surrounded by support- the initiation of spermatogenesis. Type
ing cells (Fig. 2.21A). Supporting cells, which A cells undergo a limited number of mitotic
are derived from the surface epithelium of the divisions to form clones of cells. The last cell
testis in the same manner as follicular cells, division produces type B spermatogonia,
become sustentacular cells, or Sertoli cells which then divide to form primary sper-
(Fig. 2.21B). matocytes (Figs. 2.21B and 2.22). Primary

Spermatozoon
Maturing
spermatids

Spermatids

Primary
spermatocyte
in prophase

Primordal Sertoli
germ cell cells
Sertoli cell

A B
Spermatogonial
division
Basement membrane Spermatogonia
Figure 2.21 A. Cross section through primitive sex cords of a newborn boy showing PGCs and supporting cells.
B. Cross section through a seminiferous tubule at puberty. Note the different stages of spermatogenesis and that
developing sperm cells are embedded in the cytoplasmic processes of a supporting Sertoli cell.

Sadler_Chap02.indd 24 8/25/2011 8:22:07 PM
 Chapter 2 Gametogenesis: Conversion of Germ Cells into Male and Female Gametes 25

Type A dark
spermatogonia

Type A pale
spermatogonia

Type A pale
spermatogonia

Type B
spermatogonia

Primary
spermatocytes

Secondary
spermatocytes

Early spermatids

Late spermatids

Residual bodies

Spermatozoa

Figure 2.22 Type A spermatogonia, derived from the spermatogonial stem cell population, represent the first cells in
the process of spermatogenesis. Clones of cells are established, and cytoplasmic bridges join cells in each succeeding divi-
sion until individual sperm are separated from residual bodies. In fact, the number of individual interconnected cells is
considerably greater than depicted in this figure.

Sadler_Chap02.indd 25 8/25/2011 8:22:08 PM
 26 Part 1 General Embryology

Resting primary Secondary
Type B spermatocyte spermatocyte
spermatogonium Spermatid

A B C D
Mitotic 1st meiotic 2nd meiotic
division division division

Figure 2.23 The products of meiosis during spermatogenesis in humans.

spermatocytes then enter a prolonged pro- binding to Sertoli cells stimulates testicular fluid
phase (22 days) followed by rapid comple- production and synthesis of intracellular andro-
tion of meiosis I and formation of secondary gen receptor proteins.
spermatocytes. During the second mei-
otic division, these cells immediately begin Spermiogenesis
to form haploid spermatids (Figs. 2.21B to The series of changes resulting in the trans-
2.23). Throughout this series of events, from formation of spermatids into spermatozoa
the time type A cells leave the stem cell popu- is spermiogenesis. These changes include
lation to formation of spermatids, cytokinesis (1) formation of the acrosome, which cov-
is incomplete, so that successive cell genera- ers half of the nuclear surface and contains
tions are joined by cytoplasmic bridges. Thus, enzymes to assist in penetration of the egg
the progeny of a single type A spermatogo- and its surrounding layers during fertilization
nium form a clone of germ cells that maintain (Fig. 2.24); (2) condensation of the nucleus;
contact throughout differentiation (Fig. 2.22). (3) formation of neck, middle piece, and tail;
Furthermore, spermatogonia and spermatids and (4) shedding of most of the cytoplasm
remain embedded in deep recesses of Sertoli as residual bodies that are phagocytized by
cells throughout their development (Fig. Sertoli cells. In humans, the time required for
2.21B). In this manner, Sertoli cells support a spermatogonium to develop into a mature
and protect the germ cells, participate in their spermatozoon is approximately 74 days, and
nutrition, and assist in the release of mature approximately 300 million sperm cells are
spermatozoa. produced daily.
Spermatogenesis is regulated by LH produc- When fully formed, spermatozoa enter the
tion by the pituitary gland. LH binds to receptors lumen of seminiferous tubules. From there, they
on Leydig cells and stimulates testosterone pro- are pushed toward the epididymis by contractile
duction, which in turn binds to Sertoli cells to elements in the wall of the seminiferous tubules.
promote spermatogenesis. Follicle-stimulating Although initially only slightly motile, spermato-
hormone (FSH) is also essential because its zoa obtain full motility in the epididymis.

Centriole Mitochondria Tail piece
Golgi Golgi
material
Golgi
material
A
Acrosomic
B Ring
structure
granule Middle piece
Acrosome
C D
Nucleus
covered by
the acrosome
Figure 2.24 Important stages in transformation of the human spermatid into the spermatozoon.

Sadler_Chap02.indd 26 8/25/2011 8:22:11 PM
 A B C
Primordial follicle with Trinucleated oocyte
two oocytes

Sadler_Chap02.indd 27 8/25/2011 8:22:12 PM
 28 Part 1 General Embryology

remain surrounded by a layer of follicular cells cells give rise to primary spermatocytes, which
derived from the surface epithelium of the ovary through two successive meiotic divisions pro-
(Fig. 2.17). Together, they form the primordial duce four spermatids (Fig. 2.5). Spermatids
follicle. At puberty, a pool of growing follicles go through a series of changes (spermiogen-
is recruited and maintained from the finite sup- esis) (Fig. 2.24), including (1) formation of
ply of primordial follicles. Thus, every month, the acrosome; (2) condensation of the nucleus;
15 to 20 follicles begin to grow, and as they (3) formation of neck, middle piece, and tail;
mature, they pass through three stages: (1) pri- and (4) shedding of most of the cytoplasm.
mary or preantral, (2) vesicular or antral, and The time required for a spermatogonium to
(3) mature vesicular or Graafian follicle. The become a mature spermatozoon is approxi-
primary oocyte remains in prophase of the first mately 74 days.
meiotic division until the secondary follicle is
mature. At this point, a surge in LH stimulates
preovulatory growth: Meiosis I is completed, and Problems to Solve
a secondary oocyte and polar body are formed. 1. What is the most common cause of abnor-
Then, the secondary oocyte is arrested in meta- mal chromosome number? Give an example
phase of meiosis II approximately 3 hours before of a clinical syndrome involving abnormal
ovulation and will not complete this cell division numbers of chromosomes.
until fertilization.
In the male, primordial cells remain dor- 2. In addition to numerical abnormalities, what
mant until puberty, and only then do they types of chromosomal alterations occur?
differentiate into spermatogonia. These stem 3. What is mosaicism, and how does it occur?

Sadler_Chap02.indd 28 8/25/2011 8:22:15 PM
Sadler_Chap03.indd 29 8/25/2011 8:23:34 PM
Sadler_Chap03.indd 30
Hypothalamic
impulses

Pituitary gland
30 Part 1 General Embryology

Gonadotropins

FSH LH

Maturation of follicle Ovulation Corpus luteum Degenerating
corpus luteum
1 2 3 4

Figure 3.1 Drawing showing the role of the hypothalamus and pituitary gland in regulating the ovarian cycle. Under the influence of GnRH from the hypothalamus, the pituitary releases
the gonadotropins, FSH, and LH. Follicles are stimulated to grow by FSH and to mature by FSH and LH. Ovulation occurs when concentrations of LH surge to high levels. LH also promotes
development of the corpus luteum. 1, primordial follicle; 2, growing follicle; 3, vesicular follicle; 4, mature vesicular (graafian) follicle.

8/25/2011 8:23:37 PM
 Chapter 3 First Week of Development: Ovulation to Implantation 31

Primary oocyte Granulosa Zona pellucida Antrum
cells Theca
externa

Theca
interna

A Primordial follicle B Growing follicle C Vesicular follicle
Figure 3.2 A. Primordial follicle. B. Growing follicle. C. Vesicular follicle. Every day from the pool of primordial follicles
A, some begin to develop into growing follicles B, and this growth is independent of FSH.Then, as the cycle progresses, FSH
secretion recruits growing follicles to begin development into vesicular (antral) follicles. C. During the last few days of maturation
of vesicular follicles, estrogens, produced by follicular and thecal cells, stimulate increased production of LH by the pituitary gland
(Fig. 3.1), and this hormone causes the follicle to enter the mature vesicular (graafian) stage, to complete meiosis I, and
to enter meiosis II, where it is arrested in metaphase approximately 3 hours before ovulation.

follicle. Coincident with final development of breaks free (ovulation) and floats out of the
the vesicular follicle, there is an abrupt increase ovary (Fig. 3.3). Some of the cumulus oopho-
in LH that causes the primary oocyte to com- rus cells then rearrange themselves around the
plete meiosis I and the follicle to enter the zona pellucida to form the corona radiata
preovulatory mature vesicular stage. Meiosis II (Figs. 3.2B to 3.6).
is also initiated, but the oocyte is arrested in
metaphase approximately 3 hours before ovula- Corpus Luteum
tion. In the meantime, the surface of the ovary After ovulation, granulosa cells remaining in
begins to bulge locally, and at the apex, an avas- the wall of the ruptured follicle, together with
cular spot, the stigma, appears. The high con- cells from the theca interna, are vascularized
centration of LH increases collagenase activity, by surrounding vessels. Under the influence of
resulting in digestion of collagen fibers sur- LH, these cells develop a yellowish pigment and
rounding the follicle. Prostaglandin levels also change into lutein cells, which form the corpus
increase in response to the LH surge and cause luteum and secrete estrogens and progesterone
local muscular contractions in the ovarian wall. (Fig. 3.3C). Progesterone, together with some
Those contractions extrude the oocyte, which estrogen, causes the uterine mucosa to enter the
together with its surrounding granulosa cells progestational or secretory stage in prepara-
from the region of the cumulus oophorus tion for implantation of the embryo.

Antrum Granulosa cells Luteal cells
Ovarian stroma
Theca interna Theca
externa
Blood
vessels
1st
polar
body

Oocyte in Cumulus
2nd meiotic oophorus Fibrin
division cells
A Mature vesicular follicle B Ovulation C Corpus luteum
Figure 3.3 A. Mature vesicular follicle bulging at the ovarian surface. B. Ovulation. The oocyte, in metaphase of meiosis
II, is discharged from the ovary together with a large number of cumulus oophorus cells. Follicular cells remaining inside the
collapsed follicle differentiate into lutean cells. C. Corpus luteum. Note the large size of the corpus luteum, caused by hyper-
trophy and accumulation of lipid in granulosa and theca interna cells. The remaining cavity of the follicle is filled with fibrin.

Sadler_Chap03.indd 31 8/25/2011 8:23:38 PM
 32 Part 1 General Embryology

Figure 3.4 Relation of fimbriae and ovary. Fimbriae collect the oocyte and sweep it into the uterine tube.

Oocyte Transport syncytiotrophoblast of the developing embryo.
Shortly before ovulation, fimbriae of the uter- The corpus luteum continues to grow and forms
ine tube sweep over the surface of the ovary, and the corpus luteum of pregnancy (corpus
the tube itself begins to contract rhythmically. It luteum graviditatis). By the end of the third
is thought that the oocyte, surrounded by some month, this structure may be one third to one
granulosa cells (Figs. 3.3B and 3.4), is carried into half of the total size of the ovary.Yellowish luteal
the tube by these sweeping movements of the cells continue to secrete progesterone until the
fimbriae and by motion of cilia on the epithelial end of the fourth month; thereafter, they regress
lining. Once in the tube, cumulus cells withdraw slowly as secretion of progesterone by the tro-
their cytoplasmic processes from the zona pellu- phoblastic component of the placenta becomes
cida and lose contact with the oocyte. adequate for maintenance of pregnancy. Removal
Once the oocyte is in the uterine tube, it is of the corpus luteum of pregnancy before the
propelled by peristaltic muscular contractions of fourth month usually leads to abortion.
the tube and by cilia in the tubal mucosa with
the rate of transport regulated by the endocrine FERTILIZATION
status during and after ovulation. In humans, the
fertilized oocyte reaches the uterine lumen in Fertilization, the process by which male and
approximately 3 to 4 days. female gametes fuse, occurs in the ampullary
region of the uterine tube. This is the wid-
Corpus Albicans est part of the tube and is close to the ovary
If fertilization does not occur, the corpus luteum (Fig. 3.4). Spermatozoa may remain viable in the
reaches maximum development approximately female reproductive tract for several days.
9 days after ovulation. It can easily be recognized as Only 1% of sperm deposited in the vagina
a yellowish projection on the surface of the ovary. enter the cervix, where they may survive for
Subsequently, the corpus luteum shrinks because many hours. Movement of sperm from the
of degeneration of lutean cells (luteolysis) and cervix to the uterine tube occurs by muscular
forms a mass of fibrotic scar tissue, the corpus contractions of the uterus and uterine tube and
albicans. Simultaneously, progesterone produc- very little by their own propulsion. The trip
tion decreases, precipitating menstrual bleeding. from cervix to oviduct can occur as rapidly as
If the oocyte is fertilized, degeneration of the 30 minutes or as slow as 6 days. After reach-
corpus luteum is prevented by human chori- ing the isthmus, sperm become less motile and
onic gonadotropin, a hormone secreted by the cease their migration. At ovulation, sperm again

Sadler_Chap03.indd 32 8/25/2011 8:23:39 PM
 Chapter 3 First Week of Development: Ovulation to Implantation 33

become motile, perhaps because of chemoat- ampulla is not an advantage, since capacitation has
tractants produced by cumulus cells surrounding not yet occurred and such sperm are not capable
the egg, and swim to the ampulla, where fertil- of fertilizing the egg. Much of this conditioning
ization usually occurs. Spermatozoa are not able during capacitation occurs in the uterine tube and
to fertilize the oocyte immediately upon arrival involves epithelial interactions between the sperm
in the female genital tract but must undergo and the mucosal surface of the tube. During this
(1) capacitation and (2) the acrosome reac- time, a glycoprotein coat and seminal plasma pro-
tion to acquire this capability. teins are removed from the plasma membrane that
Capacitation is a period of conditioning in overlies the acrosomal region of the spermato-
the female reproductive tract that in the human zoa. Only capacitated sperm can pass through the
lasts approximately 7 hours. Thus, speeding to the corona cells and undergo the acrosome reaction.

A

Corona radiata cells
Phase 1 Phase 2

Polor body
in division

Acrosome Inner acrosomal
membrane dissolves

Sperm nucleus Secondary oocyte in
Plasma 2nd meiotic division
membrane

Fusion oocyte and
sperm cell membranes
B
Phase 3

Figure 3.5 A. Scanning electron micrograph of sperm binding to the zona pellucida. B. The three phases of oocyte pen-
etration. In phase 1, spermatozoa pass through the corona radiata barrier; in phase 2, one or more spermatozoa penetrate
the zona pellucida; in phase 3, one spermatozoon penetrates the oocyte membrane while losing its own plasma membrane.
Inset shows normal spermatocyte with acrosomal head cap.

Sadler_Chap03.indd 33 8/25/2011 8:23:40 PM
 34 Part 1 General Embryology

Figure 3.6 A. Oocyte immediately after ovulation, showing the spindle of the second meiotic division. B. A spermatozoon
has penetrated the oocyte, which has finished its second meiotic division. Chromosomes of the oocyte are arranged in a
vesicular nucleus, the female pronucleus. Heads of several sperm are stuck in the zona pellucida. C. Male and female pronuclei.
D,E. Chromosomes become arranged on the spindle, split longitudinally, and move to opposite poles. F. Two-cell stage.

The acrosome reaction, which occurs after enzymes (acrosin) allows sperm to penetrate the
binding to the zona pellucida, is induced by zona zona, thereby coming in contact with the plasma
proteins.This reaction culminates in the release of membrane of the oocyte (Fig. 3.5). Permeability of
enzymes needed to penetrate the zona pellucida, the zona pellucida changes when the head of the
including acrosin- and trypsin-like substances sperm comes in contact with the oocyte surface.
(Fig. 3.5). This contact results in release of lysosomal enzymes
The phases of fertilization include from cortical granules lining the plasma mem-
Phase 1, penetration of the corona radiata brane of the oocyte. In turn, these enzymes alter
Phase 2, penetration of the zona pellucida properties of the zona pellucida (zona reaction)
Phase 3, fusion of the oocyte and sperm cell
to prevent sperm penetration and inactivate spe-
membranes cies-specific receptor sites for spermatozoa on the
zona surface. Other spermatozoa have been found
Phase 1: Penetration of the Corona embedded in the zona pellucida, but only one
Radiata seems to be able to penetrate the oocyte (Fig. 3.6).
Of the 200 to 300 million spermatozoa normally
deposited in the female genital tract, only 300 Phase 3: Fusion of the Oocyte and
to 500 reach the site of fertilization. Only one Sperm Cell Membranes
of these fertilizes the egg. It is thought that the The initial adhesion of sperm to the oocyte is
others aid the fertilizing sperm in penetrating the mediated in part by the interaction of integrins
barriers protecting the female gamete. Capacitated on the oocyte and their ligands, disintegrins, on
sperm pass freely through corona cells (Fig. 3.5). sperm. After adhesion, the plasma membranes of
the sperm and egg fuse (Fig. 3.5). Because the
Phase 2: Penetration of the Zona plasma membrane covering the acrosomal head
Pellucida cap disappears during the acrosome reaction,
The zona is a glycoprotein shell surrounding the actual fusion is accomplished between the oocyte
egg that facilitates and maintains sperm binding membrane and the membrane that covers the
and induces the acrosome reaction. Both binding posterior region of the sperm head (Fig. 3.5). In
and the acrosome reaction are mediated by the the human, both the head and the tail of the sper-
ligand ZP3, a zona protein. Release of acrosomal matozoon enter the cytoplasm of the oocyte, but

Sadler_Chap03.indd 34 8/25/2011 8:23:42 PM
 A B

Sadler_Chap03.indd 35 8/25/2011 8:23:43 PM
Sadler_Chap03.indd 36 8/25/2011 8:23:46 PM
 Chapter 3 First Week of Development: Ovulation to Implantation 37

Figure 3.8 Development of the zygote from the two-cell stage to the late morula stage. The two-cell stage is reached
approximately 30 hours after fertilization; the four-cell stage is reach