Early Development I & II Lecture Notes PDF

Summary

These notes cover several topics on early human development, including the stages of prenatal development, gametogenesis, and the pre-embryonic and early embryonic periods. Key topics include fertilization, cleavage, blastocyst formation, implantation, the development of the bilaminar embryonic disc, extraembryonic membranes, and gastrulation. The notes also touch on the role of teratogens and the formation of primary germ layers.

Full Transcript

L22 & L23
Early
Development

Dr. Erin Stephenson
email: [email protected]
Learning objectives
Define the three major stages of prenatal development
Define gametogenesis
Describe the process of fertilization
Describe the process of cleavage
Describe how a blastocyst is formed
Describe the process of implantation
Describe how a bilaminar embryonic disc forms and identify any associated structures/cavities
Identify the extraembryonic membranes observed during week two and describe how each forms
Discuss the process of gastrulation
List the three primary germ layers and describe the major structures derived from each layer
Describe the structures formed during neurulation
Identify the structures formed during intraembryonic mesoderm differentiation
Describe the structures formed during embryonic folding
Describe the period of embryonic development when an embryo is most susceptible to teratogens
Lecture outline
Stages of prenatal development
Gametogenesis
Pre-embryonic period
Week 1
Week 2
Early embryonic period
Teratogens
 Key terminology

Conceptus = developing human
Primordial = earliest stage of development
Blast = embryonic cell
Cyto = cell
Cyst = bladder (fluid-filled sac)
Epi = above
Hypo = below
Endo = inner
Extra = outside
Intra = within
Meso = middle
Ecto = outer
Coelom = cavity
Lecture outline
Stages of prenatal development
Gametogenesis
Pre-embryonic period
Week 1
Week 2
Early embryonic period
Week 3
Week 4
Teratogens
Learning objective(s):
Define the three major stages of prenatal development
Stages of prenatal Pre-embryonic
Weeks 1-2

development
Three key periods
 Pre-embryonic
 Embryonic
 Fetal Embryonic
Most visible development occurs Weeks 3-8
during the embryonic period

Fetal
Weeks 9-38
Lecture outline
Stages of prenatal development
Gametogenesis
Pre-embryonic period
Week 1
Week 2
Early embryonic period
Week 3
Week 4
Teratogens
Learning objective(s):
Discuss the key stages of gametogenesis
 Gametogenesis DNA condenses into
chromosomes
Duplicated sister chromatids
unite at centromere & undergo
recombination

Chromosomes align at
 Gametogenesis = germ cells → gametes equator
 Meiosis
Anaphase I
Gametes = sex cells capable of reproduction
 Male = sperms/spermatozoa
 Female = oocytes Telophase I & cytokinesis
Chromosome number is halved
 46 (diploid) → 23 sister chromatids → 23 (haploid)
 Requires two meiotic divisions

Diploid = cells have two closely similar versions of each chromosome
Sister chromatids = twin copies of replicated chromosomes that are physically linked
Homologs = versions of chromosomes that are similar but not identical
Haploid = cells have one version of each chromosome
 Spermatogenesis

Spermatogonia → primary spermatocytes
 Occurs during puberty
 Diploid germ cells
First meiotic division
 Two haploid secondary spermatocytes
Second meiotic division
 Four haploid spermatids
Spermatids → sperms via spermiogenesis
 Spermatids elongate & mature into sperms
 Oogenesis

Prior to birth

Ovulation
Oogonia → Primary oocytes Oocyte begins
second meiotic
 Occurs prior to birth division then arrests

Puberty
 Diploid cell surrounded by a follicular layer
First meiotic division
 Begins prior to birth – arrests at prophase

Fertilization
 Completed monthly beginning at puberty
 One secondary oocyte, one polar body
Second meiotic division

Just before ovulation
 Begins at ovulation – arrests at metaphase
 Complete upon penetration by a sperm
 One fertilized oocyte, one polar body
 Ovarian cycle
No fertilization?

Begins at puberty, terminates at menopause
Hypothalamus stimulates release of
gonadotropins from the pituitary gland
 Follicle stimulating hormone (FSH)
 Stimulates follicular maturation
 Luteinizing hormone (LH)
 Stimulates production of estrogens
 More estrogen = more LH = ovulation
Ovulation
 Follicle becomes corpus luteum
 Secretes estrogen & progesterone
 Endometrium of uterus thickens
Lecture outline
Stages of prenatal development
Gametogenesis
Pre-embryonic period
Week 1
Week 2
Early embryonic period
Week
Learning 3
objective(s):
Weeksthe
Describe 4-8
process of fertilization
Teratogens
Describe the process of cleavage
Describe how a blastocyst is formed
Describe the process of implantation
 Pre-embryonic period

Ovarian Cycle
Week 1
 Fertilization
 Cleavage
 Blastocyst formation
 Implantation
Week 2
 Bilaminar disc forms
 Lacunae form
 Extraembryonic mesoderm
develops
 hCG secretion begins
Week 1

Blastocyst
Fertilization Cleavage formation Implantation
 Fertilization
Union of genetic material
Begins when a capacitated sperm penetrates
a secondary oocyte
 Secondary oocyte completes second meiosis
Pronuclei of ovum & sperm combine
Formation of a diploid zygote
46 chromosomes
 Cleavage
Repeated mitotic divisions of the zygote
Increases the number of blastomeres
Results in formation of a morula
 12-32 blastomeres in a solid mass
Begins ~30 h after fertilization as the
zygote moves along the uterine tube
 Blastocyst formation

Development of a fluid-filled cavity within the morula
 Pushes the inner-cell mass to one side
The blastomere divides into two structures –
 Inner cell mass/embryoblast
 Trophoblast
Begins ~4 d after fertilization
 Implantation

Blastocyst embeds in the uterine endometrium
Begins ~6 d & continues into Week 2
The trophoblast differentiates into two layers
 Cytotrophoblast Day 6
 Syncytiotrophoblast
The syncytiotrophoblast erodes the uterine tissues to
facilitate implantation

Day 12

Day 7
 Summary of Week 1
Cleavage

Zygote
formation
Blastocyst
formation
Implantation
Lecture outline
Stages of prenatal development
Gametogenesis
Pre-embryonic period
Week 1
Week 2
Early embryonic period
Week 3
Learning objective(s):
Weeks 4-8
Describe the process of implantation
Teratogens
Describe how a bilaminar embryonic disc forms and identify any associated structures/cavities
Identify the extraembryonic membranes observed during week two and describe how each forms
Week 2
Bilaminar
embryonic
disc & Extraembryonic
cavities Lacunae mesoderm

Implantation continues

“Week of twos”
 Bilaminar
embryonic disc
Embryoblast changes morphology during implantation
 Forms a bilaminar disc
Epiblast
 Dorsal surface
Hypoblast
 Ventral surface

Day 8
Bilaminar
embryonic disc
 Amnionic cavity
~ Week 7, 17 mm embryo
Forms within the epiblast
Amnioblasts separate from the epiblast &
surround the amniotic cavity
 Amnion
Will eventually surround the conceptus

Day 8
 Primary umbilical
vesicle

Cells continuous with the hypoblast line the
cytotrophoblast, forming a vesicle
 Primary umbilical/exocoelomic vesicle/yolk sac

Day 8
 Lacunar network

Syncytiotrophoblast erodes uterine blood vessels
 Lacunae
Lacunar network allows diffusion of
nutrients/gasses via maternal blood

Day 9
Extraembryonic mesoderm
Extraembryonic mesoderm

Cells migrate between the exocoelomic membrane &
cytotrophoblast
 Extraembryonic mesoderm
Spaces form & coalesce
 Future chorionic cavity/gestational sac

Day 12
Extraembryonic mesoderm

Extraembryonic somatic mesoderm
 Lines the trophoblast & amnion
 Forms the connecting stalk – primitive umbilical cord
 Fuses with the trophoblast to form the chorion
Extraembryonic splanchnic mesoderm
 Surrounds the primary umbilical vesical

Day 14
Prechordal plate

Localized thickening of the hypoblast
Organizing center for structures of the head
from which the oropharyngeal membrane
will arise Day 14
 Future mouth
Human chorionic gonadotropin
(hCG)

Produced by the syncytiotrophoblast at
the end of Week 2
Maintains the corpus luteum of the ovary
 Progesterone, estrogen
Summary of Week 2
Implantation continues
The embryoblast differentiates into a bilaminar embryonic disc
 Epiblast & hypoblast
The amniotic cavity appears in the epiblast
The primary umbilical vesicle & extraembryonic mesoderm develop
Lacunar networks & chorionic villi form
The extraembryonic coelom forms from spaces that develop in the extraembryonic mesoderm
 Future chorionic cavity
The primary umbilical vesicle becomes smaller & gradually disappears
 Secondary umbilical vesicle develops
The prechordal plate develops as a localized thickening of the hypoblast
The syncytiotrophoblast begins secreting hCG
Lecture outline
Stages of prenatal development
Gametogenesis
Pre-embryonic period
Week 1
Week 2
L23: Early Development II
Early embryonic period
Week 3
Week 4
Learning objective(s):
Teratogens
Discuss the process of gastrulation
List the three primary germ layers and describe the major structures derived from each layer
Describe the structures formed during neurulation
Identify the structures formed during intraembryonic mesoderm differentiation
Embryonic
period
Early
embryonic
period
Week 3
Differentiation of
intraembryonic
Gastrulation Neurulation mesoderm
Gastrulation

Bilaminar disc → trilaminar disc
 Primary germ layers
Establishment of body plan
Cranial – caudal axis
Left – right sides
Begins with appearance of primitive streak
Primitive streak

Epiblast cells migrate to median plane
Primitive node appears
 Marks cranial side of primitive streak
 Streak elongates caudal → cranial
Invagination of cells creates primitive groove
 Trilaminar disc

Mesenchymal cells migrate through the primitive streak
 Epiblast converted to ECTODERM
 Epithelial tissues
Cells that displace/replace the hypoblast
 Forms the ENDODERM
 Epithelial tissues
Cells that migrate between the ectoderm & endoderm
 Intraembryonic MESODERM
 Mesenchymal or epithelial tissues
 Notochord formation

Migrating mesenchymal cells form the notochord process
 Cellular cord between primitive node & prechordal plate
 Binds underlying endoderm
 Fused layers degenerate leaving the notochord plate
Notochord plate folds inward to form the notochord
 Signaling hub
 Forms longitudinal axis of axial skeleton

Notochord formation in 3 mouse embryos
Foxa2-eGFP and T-mCherry are fluorescent proteins that mark the paraxial
mesoderm Credit: HHMI News
 Neurulation

Notochord signaling induces the neural plate
 Thickening of overlying ectoderm – neuroectoderm
The neural plate invaginates
 Forms the neural groove & neural folds
Neural folds meet in the midline
 Forms the neural tube
 Future central nervous system
 Formation of the neural plate
Ectoderm overlying the notochord
begins to thicken

Formation of the neural groove
Invagination of the neural plate
begins

Formation of the neural folds
Invagination of the neural plate
continues

Deepening of the neural groove &
formation of neural crest cells
Neural folds migrate toward one another
whereas neural crest cells migrate away
from the developing neural tube

Closure of the neural tube
Neural folds unite in the midline
& the tube closes
 Closure of the neural tube

Begins in cervical region & occurs bidirectionally
Complete by end of Week 4
Incomplete closure is problematic
 Cranial end – anencephaly (lethal)
 Caudal end – spina bifida (loss of function)

Link to video
 Neural crest cells

Undergo epithelial → mesenchymal transition
Migrate away from the neural folds
 Separate into right & left divisions
 Widely distributed along predefined pathways
 Form ganglia, Schwann cells, pharyngeal arches
& their derivatives, leptomeninges,
melanocytes, odontoblasts, suprarenal medulla
 Ectoderm summary

Ectoderm is derived from the epiblast
Neuroectoderm is a thickened region over the
notochord that becomes the neural tube & neural crest
Surface ectoderm becomes the epidermis
 Intraembryonic mesoderm
Germ layer between the ectoderm & endoderm
Derived from the epiblast
Differentiates into three parallel columns
 Paraxial mesoderm
 Intermediate mesoderm
 Lateral plate mesoderm

Anterior Posterior

Link to video
cells cells
migrate to migrating
paraxial laterally
mesoderm
Mesoderm differentiation in a chick embryo. Sweetman D, Wagstaff L, Cooper O, Weijer C & Münsterberg A. (2008). The migration of paraxial and
lateral plate mesoderm cells emerging from the late primitive streak is controlled by different Wnt signals. BMC Dev. Biol. , 8, 63. PMID: 18541012 DOI.
 Paraxial mesoderm

Paired columns either side of the notochord
Columns condense & segment into somites ~Day 22, 2.5 mm

 38-39 somites develop craniocaudally from days 26-32
 Form the sclerotome, myotome, & dermatome
 Vertebrae, ribs, posterior skull
 Skeletal muscles of the limbs & trunk
 Skin over the back & limbs

~Day 23, 3.0 mm

~Day 24, 3.5 mm
 Intermediate mesoderm

Continuous laterally with the paraxial mesoderm
Precursor to parts of the urinary & reproductive systems
 Kidneys & ureters
 Gonads, reproductive ducts, glands
 Uterus
 Lateral plate mesoderm
Continuous laterally with the extraembryonic mesoderm
 Covers the umbilical vesicle & amnion
Divides into somatic (parietal) & splanchnic (visceral) layers
Transverse folding fuses right & left sides in the midline
 Intraembryonic coelom – future thoracic & abdominopelvic cavities
Mesoderm summary

Mesoderm is derived from the epiblast
Paraxial mesoderm
Somites
Intermediate mesoderm
Urogenital structures
Lateral plate mesoderm
Somatic (parietal) mesoderm
Splanchnic (visceral) mesoderm
 Endoderm
Germ layer surrounding the umbilical vesicle
Derived from the epiblast
Will form the lining of the gut tube
 Most internal organs will bud from the gut tube
Foregut – oropharyngeal membrane
Midgut – secondary umbilical vesicle
Hindgut – cloacal membrane
 Oropharyngeal & cloacal membranes

Sites where ectoderm fuses directly with endoderm
Oropharyngeal membrane is at the cranial end
 Future mouth
 Foregut
Cloacal membrane is at the caudal end
 Future anal & urogenital openings
 Hind gut
Summary of
germ layer
derivatives
Lecture outline
Stages of prenatal development
Gametogenesis
Pre-embryonic period
Week 1
Week 2
Early embryonic period
Week 3
Week 4
Learning
Teratogens
objective(s):
Describe the structures formed during embryonic folding
Week 4

Embryonic
Neural tube closure folding
 Embryonic folding

Conversion of elongating disc into curved cylinder
Caused by differential growth along longitudinal
axis & lateral parts of disc
Craniocaudal folding & transverse folding occur
simultaneously
 Craniocaudal folding

Caused by rapid growth of the neural tube
Oropharyngeal & cloacal membranes move to ventral surface
Endoderm of umbilical vesicle is internalized
 Foregut, midgut, hind gut established

Link to video
 Transverse folding
Caused by rapid growth of the somites
Bilateral edges of conceptus fuse in the midline
Gut tube formed as splanchnic mesoderm & endoderm fuse
Body wall formed as somatic mesoderm & surface ectoderm fuse
 Except at the vitelline duct (stalk of umbilical vesicle)
Summary of Weeks 3 & 4
Gastrulation establishes body planes & generates the primary germ layers from the epiblast
 Ectoderm, mesoderm, endoderm

The notochord is established as a signaling hub that initiates neurulation
Neurulation establishes the nervous system & neural crest cells
The intraembryonic mesoderm differentiates into three paired columns
 Paraxial, intermediate, lateral plate

The endoderm forms the lining of the gut tube
The oropharyngeal & cloacal membranes are established
The conceptus converts from disc to tube via folding in the craniocaudal & transverse axes
 Craniocaudal folding internalizes future thoracoabdominal structures
 Transverse folding forms the gut tube, body wall, & surrounds the conceptus with the amnionic cavity
Lecture outline
Stages of prenatal development
Gametogenesis
Pre-embryonic period
Week 1
Week 2
Early embryonic period
Week 3
Week 4
Teratogens
Learning objective(s):
Describe the period of embryonic development when an embryo is most susceptible to teratogens
 Teratogens

Most deaths during infancy are caused by birth defects
 Genetic factors, environmental factors, a combination
Teratogens are substances/organisms/physical agents
that can interfere with normal development
 Slowed growth, loss of function, malformations, death
Learning objectives
 We defined the three major stages of prenatal development
 We discussed the process of gametogenesis
 We described the process of fertilization
 We described the process of cleavage
 We described how a blastocyst is formed
 We described the process of implantation
 We described how a bilaminar embryonic disc forms and identified the associated structures/cavities
 We identified the extraembryonic membranes observed during week two and described how each forms
 We discussed the process of gastrulation
 We identified the three primary germ layers & described the major structures derived from each
 We described the structures formed during neurulation
 We identified the structures formed during intraembryonic mesoderm differentiation
 We described the structures formed during embryonic folding
 We described the period of embryonic development when an embryo is most susceptible to teratogens
Links to summary videos
Gastrulation https://youtu.be/ADlYn0ImTNg

Neurulation https://youtu.be/lGLexQR9xGs

Folding https://youtu.be/yXUv4MPuNTA