Title: Principles%20of%20Development
1Principles of Development
2Key Events in Development
- Development describes the changes in an organism
from its earliest beginnings through maturity. - Search for commonalities.
3Key Events in Development
- Specialization of cell types occurs as a
hierarchy of developmental decisions. - Cell types arise from conditions created in
preceding stages. - Interactions become increasingly restrictive.
- With each new stage
- Each stage limits developmental fate.
- Cells lose option to become something different
- Said to be determined.
4Key Events in Development
- The two basic processes responsible for this
progressive subdivision - Cytoplasmic localization
- Induction
5Fertilization
- Fertilization is the initial event in development
in sexual reproduction. - Union of male and female gametes
- Provides for recombination of paternal and
maternal genes. - Restores the diploid number.
- Activates the egg to begin development.
6Fertilization
- Oocyte Maturation
- Egg grows in size by accumulating yolk.
- Contains much mRNA, ribosomes, tRNA and elements
for protein synthesis. - Morphogenetic determinants direct the activation
and repression of specific genes later in
post-fertilization development. - Egg nucleus grows in size, bloated with RNA.
- Now called the germinal vesicle.
7Fertilization
- Most of these preparations in the egg occur
during the prolonged prophase I. - In mammals
- Oocyte now has a highly structured system.
- After fertilization it will support nutritional
requirements of the embryo and direct its
development through cleavage. - After meiosis resumes, the egg is ready to fuse
its nucleus with the sperm nucleus.
8Fertilization
- A century of research has been conducted on
marine invertebrates. - Especially sea urchins
9Contact Between Sperm Egg
- Broadcast spawners often release a chemotactic
factor that attracts sperm to eggs. - Species specific
- Sperm enter the jelly layer.
- Egg-recognition proteins on the acrosomal process
bind to species-specific sperm receptors on the
vitelline envelope.
10Fertilization in Sea Urchins
- Prevention of polyspermy only one sperm can
enter. - Fast block
- Depolarization of membrane
- Slow block
- Cortical reaction resulting in fertilization
membrane
11Fertilization in Sea Urchins
- The cortical reaction follows the fusion of
thousands of enzyme-rich cortical granules with
the egg membrane. - Cortical granules release contents between the
membrane and vitelline envelope. - Creates an osmotic gradient
- Water rushes into space
- Elevates the envelope
- Lifts away all bound sperm except the one sperm
that has successfully fused with the egg plasma
membrane.
12Fertilization in Sea Urchins
13Fertilization in Sea Urchins
- One cortical granule enzyme causes the vitelline
envelope to harden. - Now called the fertilization membrane.
- Block to polyspermy is now complete.
- Similar process occurs in mammals.
14Fertilization in Sea Urchins
- The increased Ca2 concentration in the egg after
the cortical reaction results in an increase in
the rates of cellular respiration and protein
synthesis. - The egg is activated.
15Fusion of Pronuclei
- After sperm and egg membranes fuse, the sperm
loses its flagellum. - Fusion of male and female pronuclei forms a
diploid zygote nucleus.
16Cleavage
- Cleavage rapid cell divisions following
fertilization. - Very little growth occurs.
- Each cell called a blastomere.
- Morula solid ball of cells. First 5-7 divisions.
17Polarity
- The eggs and zygotes of many animals (not
mammals) have a definite polarity. - The polarity is defined by the distribution of
yolk. - The vegetal pole has the most yolk and the animal
pole has the least.
18Body Axes
- The development of body axes in frogs is
influenced by the polarity of the egg.
The polarity of the egg determines the
anterior-posterior axis before fertilization.
At fertilization, the pigmented cortex slides
over the underlying cytoplasm toward the point of
sperm entry. This rotation (red arrow) exposes a
region of lighter-colored cytoplasm, the gray
crescent, which is a marker of the dorsal side.
The first cleavage division bisects the gray
crescent. Once the anterior-posterior and
dorsal-ventral axes are defined, so is the
left-right axis.
19Amount of Yolk
- Different types of animals have different amounts
of yolk in their eggs. - Isolecithal very little yolk, even
distribution. - Mesolecithal moderate amount of yolk
concentrated at vegetal pole. - Telolecithal Lots of yolk at vegetal pole.
- Centrolecithal lots of yolk, centrally located.
20Cleavage in Frogs
- Cleavage planes usually follow a specific pattern
that is relative to the animal and vegetal poles
of the zygote. - Animal pole blastomeres are smaller.
- Blastocoel in animal hemisphere.
- Little yolk, cleavage furrows complete.
- Holoblastic cleavage
21Cleavage in Birds
- Meroblastic cleavage, incomplete division of the
egg. - Occurs in species with yolk-rich eggs, such as
reptiles and birds. - Blastoderm cap of cells on top of yolk.
22Direct vs. Indirect Development
- When lots of nourishing yolk is present, embryos
develop into a miniature adult. - Direct development
- When little yolk is present, young develop into
larval stages that can feed. - Indirect development
- Mammals have little yolk, but nourish the embryo
via the placenta.
23Blastula
- A fluid filled cavity, the blastocoel, forms
within the embryo a hollow ball of cells now
called a blastula.
24Gastrulation
- The morphogenetic process called gastrulation
rearranges the cells of a blastula into a
three-layered (triploblastic) embryo, called a
gastrula, that has a primitive gut. - Diploblastic organisms have two germ layers.
25Gastrulation
- The three tissue layers produced by gastrulation
are called embryonic germ layers. - The ectoderm forms the outer layer of the
gastrula. - Outer surfaces, neural tissue
- The endoderm lines the embryonic digestive tract.
- The mesoderm partly fills the space between the
endoderm and ectoderm. - Muscles, reproductive system
26Gastrulation Sea Urchin
- Gastrulation in a sea urchin produces an embryo
with a primitive gut (archenteron) and three germ
layers. - Blastopore open end of gut, becomes anus in
deuterostomes.
27Gastrulation - Frog
- Result embryo with gut 3 germ layers.
- More complicated
- Yolk laden cells in vegetal hemisphere.
- Blastula wall more than one cell thick.
28Gastrulation - Chick
- Gastrulation in the chick is affected by the
large amounts of yolk in the egg. - Primitive streak a groove on the surface along
the future anterior-posterior axis. - Functionally equivalent to blastopore lip in
frog.
29Gastrulation - Chick
- Blastoderm consists of two layers
- Epiblast and hypoblast
- Layers separated by a blastocoel
- Epiblast forms endoderm and mesoderm.
- Cells on surface of embryo form ectoderm.
30Gastrulation - Mouse
- In mammals the blastula is called a blastocyst.
- Inner cell mass will become the embryo while
trophoblast becomes part of the placenta. - Notice that the gastrula is similar to that of
the chick.
31Suites of Developmental Characters
- Two major groups of triploblastic animals
- Protostomes
- Deuterostomes
- Differentiated by
- Spiral vs. radial cleavage
- Regulative vs. mosaic cleavage
- Blastopore becomes mouth vs. anus
- Schizocoelous vs. enterocoelous coelom formation.
32Deuterostome Development
- Deuterostomes include echinoderms (sea urchins,
sea stars etc) and chordates. - Radial cleavage
33Deuterostome Development
- Regulative development the fate of a cell
depends on its interactions with neighbors, not
what piece of cytoplasm it has. A blastomere
isolated early in cleavage is able to from a
whole individual.
34Deuterostome Development
- Deuterostome means second mouth.
- The blastopore becomes the anus and the mouth
develops as the second opening.
35Deuterostome Development
- The coelom is a body cavity completely surrounded
by mesoderm. - Mesoderm coelom form simultaneously.
- In enterocoely, the coelom forms as outpocketing
of the gut.
36Deuterostome Development
- Typical deuterostomes have coeloms that develop
by enterocoely. - Vertebrates use a modified version of
schizocoely.
37Protostome Development
- Protostomes include flatworms, annelids and
molluscs. - Spiral cleavage
38Protostome Development
- Mosaic development cell fate is determined by
the components of the cytoplasm found in each
blastomere. - Morphogenetic determinants.
- An isolated blastomere cant develop.
39Protostome Development
- Protostome means first mouth.
- Blastopore becomes the mouth.
- The second opening will become the anus.
40Protostome Development
- In protostomes, a mesodermal band of tissue forms
before the coelom is formed. - The mesoderm splits to form a coelom.
- Schizocoely
- Not all protostomes have a true coelom.
- Pseudocoelomates have a body cavity between
mesoderm and endoderm. - Acoelomates have no body cavity at all other than
the gut.
41Two Clades of Protostomes
- Lophotrochozoan protostomes include annelid
worms, molluscs, some small phyla. - Lophophore horseshoe shaped feeding structure.
- Trochophore larva
- Feature all four protostome characteristics.
42Two Clades of Protostomes
- The ecdysozoan protostomes include arthropods,
roundworms, and other taxa that molt their
exoskeletons. - Ecdysis shedding of the cuticle.
- Many do not show spiral cleavage.
43Building a Body Plan
- An organisms development is determined by the
genome of the zygote and also by differences that
arise between early embryonic cells. - Different genes will be expressed in different
cells.
44Building a Body Plan
- Uneven distribution of substances in the egg
called cytoplasmic determinants results in some
of these differences. - Position of cells in the early embryo result in
differences as well. - Induction
45Restriction of Cellular Potency
- In many species that have cytoplasmic
determinants only the zygote is totipotent,
capable of developing into all the cell types
found in the adult.
46Restriction of Cellular Potency
- Unevenly distributed cytoplasmic determinants in
the egg cell - Are important in establishing the body axes.
- Set up differences in blastomeres resulting from
cleavage.
47Restriction of Cellular Potency
- As embryonic development proceeds, the potency of
cells becomes progressively more limited in all
species.
48Cell Fate Determination and Pattern Formation by
Inductive Signals
- Once embryonic cell division creates cells that
differ from each other, - The cells begin to influence each others fates
by induction.
49Induction
- Induction is the capacity of some cells to cause
other cells to develop in a certain way. - Dorsal lip of the blastopore induces neural
development. - Primary organizer
50Spemann-Mangold Experiment
- Transplanting a piece of dorsal blastopore lip
from a salamander gastrula to a ventral or
lateral position in another gastrula developed
into a notochord somites and it induced the
host ectoderm to form a neural tube.
51Building a Body Plan
- Cell differentiation the specialization of
cells in their structure and function. - Morphogenesis the process by which an animal
takes shape and differentiated cells end up in
their appropriate locations.
52Building a Body Plan
- The sequence includes
- Cell movement
- Changes in adhesion
- Cell proliferation
- There is no hard-wired master control panel
directing development. - Sequence of local patterns in which one step in
development is a subunit of another. - Each step in the developmental hierarchy is a
necessary preliminary for the next.
53Hox Genes
- Hox genes control the subdivision of embryos into
regions of different developmental fates along
the anteroposterior axis. - Homologous in diverse organisms.
- These are master genes that control expression of
subordinate genes.
54Formation of the Vertebrate Limb
- Inductive signals play a major role in pattern
formation the development of an animals
spatial organization.
55Formation of the Vertebrate Limb
- The molecular cues that control pattern
formation, called positional information - Tell a cell where it is with respect to the
animals body axes. - Determine how the cell and its descendents
respond to future molecular signals.
56Formation of the Vertebrate Limb
- The wings and legs of chicks, like all vertebrate
limbs begin as bumps of tissue called limb buds. - The embryonic cells within a limb bud respond to
positional information indicating location along
three axes.
57Formation of the Vertebrate Limb
- One limb-bud organizer region is the apical
ectodermal ridge (AER). - A thickened area of ectoderm at the tip of the
bud. - The second major limb-bud organizer region is the
zone of polarizing activity (ZPA). - A block of mesodermal tissue located underneath
the ectoderm where the posterior side of the bud
is attached to the body.
58Morphogenesis
- Morphogenesis is a major aspect of development in
both plants and animals but only in animals does
it involve the movement of cells.
59The Cytoskeleton, Cell Motility, and Convergent
Extension
- Changes in the shape of a cell usually involve
reorganization of the cytoskeleton.
60Changes in Cell Shape
- The formation of the neural tube is affected by
microtubules and microfilaments.
61Cell Migration
- The cytoskeleton also drives cell migration, or
cell crawling. - The active movement of cells from one place to
another. - In gastrulation, tissue invagination is caused by
changes in both cell shape and cell migration.
62Evo-Devo
- Evolutionary developmental biology - evolution is
a process in which organisms become different as
a result of changes in the genetic control of
development. - Genes that control development are similar in
diverse groups of animals. - Hox genes
63Evo-Devo
- Instead of evolution proceeding by the gradual
accumulation of numerous small mutations, could
it proceed by relatively few mutations in a few
developmental genes? - The induction of legs or eyes by a mutation in
one gene suggests that these and other organs can
develop as modules.
64The Common Vertebrate Heritage
- Vertebrates share a common ancestry and a common
pattern of early development. - Vertebrate hallmarks all present briefly.
- Dorsal neural tube
- Notochord
- Pharyngeal gill pouches
- Postanal tail
65Amniotes
- The embryos of birds, reptiles, and mammals
develop within a fluid-filled sac that is
contained within a shell or the uterus. - Organisms with these adaptations form a
monophyletic group called amniotes. - Allows for embryo to develop away from water.
66Amniotes
- In these three types of organisms, the three germ
layers also give rise to the four extraembryonic
membranes that surround the developing embryo.
67Amniotes
- Amnion fluid filled membranous sac that
encloses the embryo. Protects embryo from shock. - Yolk sac stores yolk and pre-dates the amniotes
by millions of years.
68Amniotes
- Allantois - storage of metabolic wastes during
development. - Chorion - lies beneath the eggshell and encloses
the embryo and other extraembryonic membrane. - As embryo grows, the need for oxygen increases.
- Allantois and chorion fuse to form a respiratory
surface, the chorioallantoic membrane. - Evolution of the shelled amniotic egg made
internal fertilization a requirement.
69The Mammalian Placenta and Early Mammalian
Development
- Most mammalian embryos do not develop within an
egg shell. - Develop within the mothers body.
- Most retained in the mothers body.
- Monotremes
- Primitive mammals that lay eggs.
- Large yolky eggs resembling bird eggs.
- Duck-billed platypus and spiny anteater.
70The Mammalian Placenta and Early Mammalian
Development
- Marsupials
- Embryos born at an early stage of development and
continue development in abdominal pouch of
mother. - Placental Mammals
- Represent 94 of the class Mammalia.
- Evolution of the placenta required
- Reconstruction of extraembryonic membranes.
- Modification of oviduct - expanded region formed
a uterus.
71Mammalian Development
- The eggs of placental mammals
- Are small and store few nutrients.
- Exhibit holoblastic cleavage.
- Show no obvious polarity.
72Mammalian Development
- Gastrulation and organogenesis resemble the
processes in birds and other reptiles.
73Mammalian Development
- Early embryonic development in a human proceeds
through four stages - Blastocyst reaches uterus.
- Blastocyst implants.
- Extraembryonic membranes start to form and
gastrulation begins. - Gastrulation has produced a 3-layered embryo.
74Mammalian Development
- The extraembryonic membranes in mammals are
homologous to those of birds and other reptiles
and have similar functions.
75Mammalian Development
- Amnion
- Surrounds embryo
- Secretes fluid in which embryo floats
- Yolk sac
- Contains no yolk
- Source of stem cells that give rise to blood and
lymphoid cells - Stem cells migrate to into the developing embryo
- Allantois
- Not needed to store wastes
- Contributes to the formation of the umbilical
cord - Chorion
- Forms most of the placenta
76Organogenesis
- Various regions of the three embryonic germ
layers develop into the rudiments of organs
during the process of organogenesis.
77Organogenesis
- Many different structures are derived from the
three embryonic germ layers during organogenesis.
78Derivatives of Ectoderm Nervous System and Nerve
Growth
- Just above the notochord (mesoderm), the ectoderm
thickens to form a neural plate. - Edges of the neural plate fold up to create an
elongated, hollow neural tube. - Anterior end of neural tube enlarges to form the
brain and cranial nerves. - Posterior end forms the spinal cord and spinal
motor nerves.
79Derivatives of Ectoderm Nervous System and Nerve
Growth
- Neural crest cells pinch off from the neural
tube. - Give rise to
- Portions of cranial nerves
- Pigment cells
- Cartilage
- Bone
- Ganglia of the autonomic system
- Medulla of the adrenal gland
- Parts of other endocrine glands
- Neural crest cells are unique to vertebrates.
- Important in evolution of the vertebrate head and
jaws.
80Derivatives of Endoderm Digestive Tube and
Survival of Gill Arches
- During gastrulation, the archenteron forms as the
primitive gut. - This endodermal cavity eventually produces
- Digestive tract
- Lining of pharynx and lungs
- Most of the liver and pancreas
- Thyroid, parathyroid glands and thymus
81Derivatives of Endoderm Digestive Tube and
Survival of Gill Arches
- Pharyngeal pouches are derivatives of the
digestive tract. - Arise in early embryonic development of all
vertebrates. - During development, endodermally-lined pharyngeal
pouches interact with overlying ectoderm to form
gill arches. - In fish, gill arches develop into gills.
- In terrestrial vertebrates
- No respiratory function
- 1st arch and endoderm-lined pouch form upper and
lower jaws, and inner ear. - 2nd, 3rd, and 4th gill pouches form tonsils,
parathyroid gland and thymus.
82Derivatives of Mesoderm Support, Movement and
the Beating Heart
- Most muscles arise from mesoderm along each side
of the neural tube. - The mesoderm divides into a linear series of
somites (38 in humans).
83Derivatives of Mesoderm Support, Movement and
the Beating Heart
- The splitting, fusion and migration of somites
produce the - Axial skeleton
- Dermis of dorsal skin
- Muscles of the back, body wall, and limbs
- Heart
- Lateral to the somites the mesoderm splits to
form the coelom.