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Animal Development

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Title: Animal Development


1
Animal Development
A photo of a human embryo six to eight weeks
after conception. Brain formation (upper left)
and heart developing (red shape in the center)
Table of Content Overview Concept 47.1 Concept
47.2 Concept 47.3
  • Sapphira Tsang
  • April 14, 2012
  • Biology/ Period 1

2
Overview
  • Question How does a zygote become an egg?
  • Theories
  • 18th centurypeople believed that the answer was
    preformation
  • Preformation was the idea that the egg or sperm
    already had a mini human (called a homunculus)
    that grows and develops into a larger adult
    version
  • Aristotle proposed his theory of epigenesis
  • Epigenesis was the belief that an animals
    conformation is formed from a shapeless egg
  • Answer
  • Genome of the zygote and differences between
    early embryonic cells are factors that change the
    way an organism develops
  • Cell differentiation differences between the
    functions, structures, and roles of cells
  • Morphogenesis a process wherein an animal takes
    shape and the location of the cells are already
    determined

3
Concept 47.1 Fertilization and three body
structuring stages
  • Regulation of development occurs during
    fertilization
  • Three stages occur that starts building animals
    body
  • Cleavage cell divides from the zygote creates a
    hollow ball of cells called a blastula
  • Gastrulation production of a three-layered
    embryo called the gastrula
  • Organogenesis basic organs are forming which
    eventually grows into adult structures

4
Fertilization
  • Fertilization is when the sperm and egg, the
    gametes, unite
  • Fertilization combines the haploid sets of
    chromosomes into a diploid cell (called the
    zygote)
  • When the sperm comes in contact with the eggs
    surface, metabolic reactions are triggered within
    the egg which activates the development of the
    embryo
  • Scientists study fertilization using sea urchins
  • Two reactions occur during fertilization
  • Acrosomal reaction
  • Cortical reaction

5
Acrosomal Reaction during sea urchin fertilization
  1. Head of the sperm, acrosome, comes in contact
    with the egg, activating acrosomal reaction.
  2. Acrosome releases hydrolytic enzymes?digest the
    jelly coat surrounding the egg.
  3. Sperm to elongates a structure called the
    acrosomal process, made up of actin filaments,
    which will fully penetrate through the jelly
    coat. The acrosomal process contains molecules
    which bind to receptor proteins that are rooted
    into the vitelline layer.
  4. The hole in the vitelline layer allows sperm
    membrane to fuse with egg membrane. The combined
    membranes are depolarized which provides a fast
    block to polyspermy. Polyspermy (fertilization of
    egg by more than one sperm) can lead to an
    abnormal number of chromosomes in the zygote.
  5. Sperm enters and travels to cells nucleus.
  6. Cortical reaction occurs.

4
5
3
2
1
6
6
Cortical Reaction during sea urchin fertilization
  • When sperm binds to eggs surface, signal
    transduction pathway activates? calcium is
    released into cytosol.
  • High concentration of calcium initiates cortical
    reaction wherein fusion with the eggs plasma
    membrane of vesicles located in the eggs cortex
    (area beneath the cells membrane) occurs
  • Cortical granules are formed during oogenesis
  • Cortical granules release their contents into
    periveritelline space (area between the vitilline
    layer and the plasma membrane)
  • Vitelline layer detaches from plasma membrane an
    osmotic gradient forces water into the
    perivitelline space, pushing it away from the
    membrane
  • The vitelline layer becomes a fertilization
    envelope, preventing other sperms from entering
    by a slow block to polyspermy

A picture of calcium spreading out over the cell.
7
Events of fertilization/ activation of a sea
urchin egg
  • The rate of cell respiration and protein
    synthesis may increase as a result of the rise of
    calcium

8
Fertilization in mammals
  • Fertilization in mammals is internal but it is
    external for sea urchins
  • Mammalian eggs are surrounded by follicle cells
  • Follicle cells and the egg are released during
    ovulation
  • Sperm travels through follicle cells in order to
    get to the zona pellucida, the eggs
    extracellular matrix?sperm binds to receptor
    molecules in the zona pellucida.
  • Binding stimulates acrosomal reaction sperm
    release hydrolytic enzymes
  • Zona pellucida is broken down by enzymes sperm
    membrane can fuse with the plasma membrane of egg
    by receptors.
  • Sperm nucleus enters egg

4
3
2
1
9
Cleavage
  • After fertilization, cell division occurs
  • Process of cleavage takes place cells undergo S
    (DNA synthesis) and M (mitosis) phase
  • Skip over G1 and G2 phases (no protein synthesis
    is occurring)
  • Embryo doesnt enlarge cytoplasm divides into
    smaller cells called blastomeres
  • Each has its own nucleus
  • First 5-7 divisions cluster of cells is known as
    a morula
  • Blastocoel (fluid filled cavity) begins to form
    within morula
  • it is fully formed in the blastula (a hollow ball
    of cells)
  • In animals, the distribution of yolk (stored
    nutrients) affects pattern of cleavage
  • Vegetal pole one pole of the egg where yolk is
    most abundant
  • Animal pole opposite end of the egg where yolk
    concentration is significantly less
  • Gray crescent a light gray area of the cytoplasm
    that helps the cell mark the dorsal side
  • Many zygotes and eggs of animals have a definite
    polarity. However, mammals do not.
  • Polarity distribution of yolk to the vegetal
    pole, having most yolk, and animal pole, having
    less yolk

10
Cleavage in echinoderm embryo
The egg is fertilized and this photo shows the
zygote prior to cleavage division.
This is a picture of post-second cleavage
division. The cell has divided and is at the four
cell stage.
The morula has formed and the blastocoel is
beginning to form.
A fully formed blastula is present and the embryo
will later hatch from the fertilization envelope.
11
Polarity determines body axes in an amphibian
A picture of the body axes of a fully developed
tadpole embryo.
  • Polarity of the egg helps with the determination
    of the anterior and posterior ends of an animal.
  • 2. Gray crescent on the cytoplasm marks the
    future dorsal site of the organism.
  • 3. Cleavage division begins left-right axis
    is defined after the dorsal-ventral and
    anterior-posterior ends are defined.

12
Cleavage in a chick embryo
Cleavage in a frog embryo
  • Zygote- cell is mostly made out of yolk. A small
    disk is located on the area of the animal pole.
    Egg white provides extra nutrients.
  • Four cell stage- early cell divisions are
    meroblastic (or incomplete). Holoblastic cleavage
    occurs when eggs containing very little yolk
    divides completely. The cleavage furrow forms
    through the cytoplasm and not through the yolk.
  • Blastoderm- cleavage divisions occur a
    blastoderm is produced which is a group of cells
    covering the top of the yolk.
  • Blastoderm cells make up two layers the epiblast
    and hypoblast, which enfold the blastocoel.

13
Gastrulation
  • Cells of blastula rearranges
  • Gastrulation produces embryonic tissues/
    embryonic germ layers.
  • Gastrula is the three layered embryo
  • Process is determined by
  • Changes in cell motility
  • Changes in cell shape
  • Changes in cellular adhesion to other cells
  • Cells near the blastula surface will move into
    the interior regions and start forming three cell
    layers

14
Gastrulation in sea urchin embryo
  • Gastrulation starts at vegetal pole?Cells from
    blastula wall travels into blastocoel they are
    referred to as mesenchyme cells in the
    blastocoel the cells still in blastula wall make
    up the vegetal plate.
  • Vegetal plate folds into itself, a process called
    invagination? starts to form an archenteron, a
    primitive gut. The open end of archenteron
    becomes the anus.
  • Endoderm cells make up archenteron. The
    mesenchyme cells send thin extensions called
    filopodia towards the ectoderm cells of the
    blastocoel wall.
  • Filopodia contracts and pulls archenteron across
    the blastocoel space.
  • Archenteron combines with the blastocoel wall,
    forming digestive tube.

15
Gastrulation in frog embryo
  1. Gastrulation starts on dorsal side of blastula.
    Invagination starts at gray crescent region, and
    becomes the dorsal lip. Involution process that
    occurs when cells roll over the lip of the
    blastospore and goes into the embryo?forms the
    endoderm and mesoderm. In the animal pole,
    ectoderm transforms and covers entire surface.
  2. Blastopore lip grows and invagination is still
    taking place. Once lips meet on either side,
    blastopore transforms into a circle which shrinks
    when the ectoderm starts covering
    surface?archenteron forms, endoderm and mesoderm
    continues to expand by involution and blastocoel
    shrinks.
  3. Archenteron is replaced by blastocoel all three
    germ layers are formed the blastospore
    encompasses a group of yolk-filled cells.

16
Gastrulation in chick embryo
  • Some cells of the epiblast travel towards the
    inside of the embryo producing a primitive streak
    (a bunch of moving into the middle of the
    blastoderm).
  • Some cells form the endoderm some form the
    mesoderm.
  • The cells that stay on the embryos surface
    becomes the ectoderm.

17
Organogenesis
  • the three germ layers develop into basic organs

Organogenesis in frog embryo
  • Somites-
  • neural tube formed
  • lateral mesoderm separates, making the coelom
  • mesoderm forms the somites
  • somites form axial skeleton muscles
  • Neural plate forms-
  • notochord grows from dorsal mesoderm
  • notochord signals for dorsal ectoderm to form
    neural plate

Neural tube forms- neural plate folds into itself
and detaches itself, resulting in neural
tube?neural tube becomes the central nervous
system.
18
Organogenesis in chick
  • Organogenesis in a chick is similar to
    organogenesis in a frog

19
Structures formed from the three embryonic germ
layers in vertebrates
  • Ectoderm
  • Mesoderm

Endoderm
  • Notochord
  • Skeletal system
  • Muscular system
  • Muscle that make up the stomach, intestines, etc
  • Excretory system
  • Circulatory and lymphatic system
  • Reproductive system (except for germ cells)
  • Dermis of skin
  • Body cavity lining
  • Adrenal cortex
  • Sweat glands
  • Hair follicles
  • Epidermis of skin
  • Lining of mouth and rectum
  • Sensory receptors
  • Eye cornea and lens
  • Nervous system
  • Adrenal medulla (part of the adrenal gland which
    secrete hormones)
  • Tooth enamel
  • Epithelium of pineal and pituitary glands
  • Digestive tract lining
  • Respiratory system lining
  • Urethra, urinary bladder, and reproductive system
    lining
  • Liver
  • Pancreas
  • Thymus
  • Thyroid and parathyroid glands

20
Developmental adaptations of amniotes
Amnion
Allantois
  • Terms to know
  • Amnion serves as protection and cushion for
    embryo prevents dehydration
  • Allantois basically a garbage can?stores
    embryos waste functions with chorion as a
    lung
  • Chorion exchange gases with allantois provide
    embryo with oxygen and carbon dioxide
  • Yolk Sac stores nutrients and feeds the embryo
  • Amniotes animals that develop as embryos in
    fluid-filled sacs in eggs or a uterus

Chorion
Yolk sac
  • All vertebrates develop in aqueous environments
  • Evolution of animal movement onto land requires
  • Shelled eggs
  • Uterus of marsupial and placental mammales

21
Mammalian Development
  • Mammalian egg cell and zygote
  • Do not contain polarity in their cytoplasm
    contents
  • Have yolk-lacking, holoblastic zygote cleavages
  • Have small eggs
  • Gastrulation and organogensis are similar to
    those processes in birds and reptiles
  • Embryo development in early stages
  • Cleavage formed
  • Embryo traveled down oviduct to the uterus
  • Inner cell mass a group of cells at one end of
    the cavity
  • Inner cell mass develops into embryo proper and
    add to all extra embryonic membranes
  • Implantation occurs
  • Trophoblast (outer epithelium of blastocyst)
    initiates implantation when it secretes enzymes
    that break down endometrium molecules (uterus
    lining)
  • Blastocyst can then enter the endometrium
  • Trophoblast thickens and it extends fingerlike
    projections into maternal tissues rich in blood
    vessels
  • Invasion by trophoblast results in erosion of
    capillaries in endometrium? the blood spills out
    and covers trophoblast tissue
  • Gastrulation starts
  • Implantation completed
  • Cells from epiblast move inward through the
    primitive streak, forming the mesoderm and
    endoderm
  • Germ layers are formed

22
Concept 47.2 Morphogenesis in animals involves
specific changes in cell shape, position, and
adhesion
  • Only in animals, morphogenesis involves movement
    of cells
  • Movement can determine cell shape or allow cells
    to travel within embryo
  • When the cytoskeleton changes, so does the cell
    shape

Neural tube formation in vertebrates
23
Cell Crawling
  • Cell crawling the movement of cells to other
    places
  • Convergent extension type of morphogenetic
    movement wherein tissue layer cells arrange as a
    thin, long sheet
  • Cell crawling is involved in convergent extension

24
Extracellular Matrix (ECM) and Cell Adhesion
Molecules
  • Roles of ECM fibers
  • Guide cells in morphogenetic movements
  • Function as tracks to direct migrating cells
  • Migrating cells moving along specific paths have
    receptor proteins that receive direction signals
  • Signals can direct the orientation of the
    cytoskeleton so that it can move the cell forward
  • Cell adhesion molecules (CAMs) located on cell
    surface and binds to other CAMs on neighboring
    cells
  • Help regulate movements and tissue building due
    to differences in amount of CAMs and chemical
    identity
  • Cadherins require calcium for work
  • Gene for cadherins is differentiated by their
    location at certain times during embryo
    development

25
  • Cell migration using fibronection
  • Frog blastula formation through cadherin
  • Fibronecton provides anchorage for cells

26
Concept 47.3 The developmental fate of cells
depends on their history and inductive signals
  • Two principles of differentiation during
    embryonic development
  • In early cleavage divisions, embryonic cells must
    become different from each other.
  • After asymmetries are determined, interactions
    between embryonic cells determine fate by causing
    changes in gene expression

Fate Mapping
  • Fate map territorial diagrams of embryonic
    development
  • Scientists studied fate maps while manipulating
    embryo parts to see whether a cells fate can be
    changed by moving it
  • Two conclusions were made
  • Founder cells give rise to specific tissues in
    older embryos
  • As development proceeds, cells development
    potential becomes restricted
  • Developmental potential range of structures it
    can form

27
Fate mapping
28
Establishing Cellular Asymmetries
  • In nonamniotic vertebrates, body axes
    determination are made early during oogenesis or
    fertilization
  • Example locations of melanin and yolk in the
    unfertilized egg of a frog determines the vegetal
    hemispheres
  • In amniotes, body axes are not determined until
    later
  • Environmental factors determine the axes
  • Gravity establishes anterior-posterior axis of
    chicks in the eggs
  • pH differences between blastoderm cells determine
    the dorsal-ventral axis

Restrictions of cellular potency
  • Totipotent zygote is capable of developing into
    all adult cell types
  • Only the zygote is totipotent
  • Mammalian embryo cells remain totipotent until
    16-cell stage this is when they arrange into
    precursors of trophoblast and inner cell mass of
    blastocyst
  • Location determines cell fate
  • At 8-cell stage, each blastomeres can develop an
    embryo if isolated

29
Cell Fate determination and pattern formation by
inductive signals
  • Embryonic cell division creates cells that
    differ? cells influence each others fates by
    induction
  • Inductive signals affect pattern formation
  • Pattern formation development of spatial
    organization in an animal
  • Positional information signals the cell its
    position in the animals body axes and determines
    how the cell will respond to molecular signals
  • Signal molecules
  • Affect gene expression in receiving cells
  • Result in differentiation
  • Can develop certain structures

30
Spemann and Mangolds Experiment
Spemann and Mangolds experiment concluded that
the dorsal lip of the blastopore acts as an
organizer of the embryo
31
Vertebrate Limb Development
A chicks wing and legs start off as limb buds.
  • Limp bud provides a model of pattern formation
  • Made up of a core mesodermal tissue surrounded by
    ectoderm layer
  • Two organizer regions in limp bud of vertebrate
    limbs
  • Apical ectodermal ridge (AER) thick region of
    ectoderm at tip of the bud produces secreted
    protein signals that promote limb-bud outgrowth
  • Zone of polarizing activity (ZPA) a block of
    mesodermal tissue underneath ectoderm needed for
    proper pattern formation and produces posterior
    structures

32
Tissue Tranplantation experiment
Tissue transplantation experiment supports the
idea that ZPA produces an inductive signal
message with information for posterior positions
33
Works Cited
  • www.campbellbiology.com
  • Campbell Biology textbook
  • Pictures from www.campbellbiology.com
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