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Cellular Mechanisms of Development

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Meristematic development and morphogenesis -Apical meristems at the root and shoot tips generate a large numbers of cells -Form leaves, ... – PowerPoint PPT presentation

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Title: Cellular Mechanisms of Development


1
Cellular Mechanismsof Development
  • Chapter 19

2
Overview of Development
  • Development is the successive process of
    systematic gene-directed changes throughout an
    organisms life cycle
  • -Can be divided into four subprocesses
  • -Growth (cell division)
  • -Differentiation
  • -Pattern formation
  • -Morphogenesis

3
Cell Division
  • After fertilization, the diploid zygote undergoes
    a period of rapid mitotic divisions
  • -In animals, this period is called cleavage
  • -Controlled by cyclins and cyclin- dependent
    kinases (Cdks)
  • During cleavage, the zygote is divided into
    smaller smaller cells called blastomeres
  • -Moreover, the G1 and G2 phases are shortened or
    eliminated

4
Cell Division
5
Cell Division
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Cell Division
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Cell Division
8
Cell Division
  • Caenorhabditis elegans
  • -One of the best developmental models
  • -Adult worm consists of 959 somatic cells
  • -Transparent, so cell division can be followed
  • -Researchers have mapped out the lineage of all
    cells derived from the fertilized egg

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Cell Division
  • Blastomeres are nondifferentiated and can give
    rise to any tissue
  • Stem cells are set aside and will continue to
    divide while remaining undifferentiated
  • -Tissue-specific can give rise to only one
    tissue
  • -Pluripotent can give rise to multiple
    different cell types
  • -Totipotent can give rise to any cell type

12
Cell Division
  • Cleave in mammals continues for 5-6 days
  • producing a ball of cells, the blastocyst
  • -Consists of
  • -Outer layer Forms the placenta
  • -Inner cell mass Forms the embryo
  • -Source of embryonic stem cells (ES cells)

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Cell Division
  • A plant develops by building its body outward
  • -Creates new parts from stem cells contained in
    structures called meristems
  • -Meristematic stem cells continually divide
  • -Produce cells that can differentiate into the
    various plant tissues
  • -Leaves, roots, branches, and flowers
  • The plant cell cycle is also regulated by cyclins
    and cyclin-dependent kinases

16
Cell Differentiation
  • A human body contains more than 210 major types
    of differentiated cells
  • Cell determination commits a cell to a particular
    developmental pathway
  • -Can only be seen by experiment
  • -Cells are moved to a different location in
    the embryo
  • -If they develop according to their new
    position, they are not determined

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Cell Differentiation
  • Cells initiate developmental changes by using
    transcriptional factors to change patterns of
    gene expression
  • Cells become committed to follow a particular
    developmental pathway in one of two ways
  • 1) via differential inheritance of cytoplasmic
    determinants
  • 2) via cell-cell interactions

19
Cell Differentiation
  • Cytoplasmic determinants
  • -Tunicates are marine invertebrates
  • -Tadpoles have tails, which are lost during
    metamorphosis into the adult
  • -Egg contains yellow pigment granules
  • -Become asymmetrically localized following
    fertilization
  • -Cells that inherit them form muscles

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Cell Differentiation
  • Cytoplasmic determinants
  • -Female parent provides egg with macho-1 mRNA
  • -Encodes a transcription factor that can
    activate expression of muscle- specific genes

22
Cell Differentiation
  • Induction is the change in the fate of a cell due
    to interaction with an adjacent cell
  • If cells of a frog embryo are separated
  • -One pole (animal pole) forms ectoderm
  • -Other pole (vegetal pole) forms endoderm
  • -No mesoderm is formed
  • If the two pole cells are placed side-by-side,
    some animal-pole cells form the mesoderm

23
Cell Differentiation
  • Another example of induction is the formation of
    notochord and mesenchyme in tunicates
  • -Arise from mesodermal cells that form at the
    vegetal margin of 32-cell stage embryo
  • -Cells receive a chemical signal from underlying
    endodermal cells
  • -Anterior cells differentiate into notochord
  • -Posterior cells differentiate into mesenchyme

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Cell Differentiation
  • The chemical signal is a fibroblast growth factor
    (FGF) molecule
  • -The FGF receptor is a tyrosine kinase that
    activates a MAP kinase cascade
  • -Produces a transcription factor that triggers
    differentiation
  • Thus, the combination of macho-1 and FGF
    signaling leads to four different cell types

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Cell Differentiation
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Cell Differentiation
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Cell Differentiation
30
Cloning
  • Until very recently, biologists thought that
    determination and cell differentiation were
    irreversible in animals
  • Nuclear transplant experiments in mammals were
    attempted without success
  • -Finally, in 1996 a breakthrough
  • Geneticists at the Roslin Institute in Scotland
    performed the following procedure

31
Cloning
  • 1. Differentiated mammary cells were removed from
    the udder of a six-year old sheep
  • 2. Eggs obtained from a ewe were enucleated
  • 3. Cells were synchronized to a resting state
  • 4. The mammary and egg cells were combined by
    somatic cell nuclear transfer (SCNT)
  • 5. Successful embryos (29/277) were placed in
    surrogate mother sheep
  • 6. On July 5, 1996, Dolly was born

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Cloning
  • Dolly proved that determination in animals is
    reversible
  • -Nucleus of a differentiated cell can be
    reprogrammed to be totipotent
  • Reproductive cloning refers to the use of SCNT to
    create an animal that is genetically identical to
    another
  • -Scientists have cloned cats, rabbits, rats,
    mice, goats and pigs

35
Cloning
  • Reproductive cloning has inherent problems
  • 1. Low success rate
  • 2. Age-associated diseases
  • Normal mammalian development requires precise
    genomic imprinting
  • -The differential expression of genes based on
    parental origin
  • Cloning fails because there is not enough time to
    reprogram the genome properly

36
Cloning
  • In therapeutic cloning, stem cells are cloned
    from a persons own tissues and so the body
    readily accepts them
  • Initial stages are the same as those of
    reproductive cloning
  • -Embryo is broken apart and its embryonic stem
    cells extracted
  • -Grown in culture and then used to replace
    diseased or injured tissue

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Cloning
38
Cloning
39
Cloning
  • Human embryonic stem cells have enormous promise
    for treating a wide range of diseases
  • -However, stem cell research has raised profound
    ethical issues
  • Very few countries have permissive policy towards
    human reproductive cloning
  • -However, many permit embryonic stem cell
    research

40
Cloning
  • Early reports on a variety of adult stem cells
    indicated that they may be pluripotent

-Since then these results have been challenged
41
Pattern Formation
  • In the early stages of pattern formation, two
    perpendicular axes are established
  • -Anterior/posterior (A/P, head-to-tail) axis
  • -Dorsal/ventral (D/V, back-to-front) axis
  • Polarity refers to the acquisition of axial
    differences in developing structures
  • Position information leads to changes in gene
    activity, and thus cells adopt a fate appropriate
    for their location

42
Drosophila Embryogenesis
  • Drosophila produces two body forms
  • -Larva Tubular eating machine
  • -Adult Flying sex machine axes are
    established
  • Metamorphosis is the passage from one body form
    to another
  • Embryogenesis is the formation of a larva from a
    fertilized egg

43
Drosophila Embryogenesis
  • Before fertilization, specialized nurse cells
    move maternal mRNAs into maturing oocyte
  • -These mRNA will initiate a cascade of gene
    activations following fertilization
  • Embryonic nuclei do not begin to function until
    approximately 10 nuclear divisions later

44
Drosophila Embryogenesis
  • After fertilization, 12 rounds of nuclear
    division without cytokinesis produces a syncytial
    blastoderm
  • -4000 nuclei in a single cytoplasm
  • Membranes grow between the nuclei forming the
    cellular blastoderm
  • Within a day of fertilization, a segmented,
    tubular body is formed

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Drosophila Embryogenesis
  • Nüsslein-Volhard and Wieschaus elucidated how the
    segmentation pattern is formed
  • -Earned the 1995 Nobel Prize
  • Two different genetic pathways control the
    establishment of the A/P and D/V polarity
  • -Both involve gradients of morphogens
  • -Soluble signal molecules that can specify
    different cell fates along an axis

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Establishment of the A/P axis
  • Nurse cells secrete maternally produced bicoid
    and nanos mRNAs into the oocyte
  • -Differentially transported by microtubules to
    opposite poles of the oocyte
  • -bicoid mRNA to the future anterior pole
  • -nanos mRNA to the future posterior pole
  • -After fertilization, translation will create
    opposing gradients of Bicoid and Nanos proteins

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Establishment of the A/P axis
  • Bicoid and Nanos control translation of two other
    maternal mRNAs, hunchback and caudal, that encode
    transcription factors
  • -Hunchback activates anterior structures
  • -Caudal activates posterior structures
  • The two mRNAs are not evenly distributed
  • -Bicoid inhibits caudal mRNA translation
  • -Nanos inhibits hunchback mRNA translation

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Establishment of the D/V axis
  • Maternally produced dorsal mRNA is placed into
    the oocyte
  • -Not asymmetrically localized
  • Oocyte nucleus synthesizes gurken mRNA
  • -Accumulates in a crescent on the future dorsal
    side of embryo
  • After fertilization, a series of steps results in
    selected transport of Dorsal into ventral nuclei,
    thus forming a D/V gradient

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Production of Body Plan
  • The body plan is produced by sequential
    activation of three classes of segmentation genes
  • 1. Gap genes
  • -Map out the coarsest subdivision along the
    A/P axis
  • -All 9 genes encode transcription factors that
    activate the next gene class

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Production of Body Plan
  • 2. Pair-rule genes
  • -Divide the embryo into seven zones
  • -The 8 or more genes encode transcription
    factors that regulate each other, and activate
    the next gene class
  • 3. Segment polarity genes
  • -Finish defining the embryonic segments

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Production of Body Plan
  • Segment identity arises from the action of
    homeotic genes
  • -Mutations in them lead to the appearance of
    normal body parts in unusual places

-Ultrabithorax mutants producean extra pair of
wings
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Production of Body Plan
  • Homeotic gene complexes
  • -The HOM complex genes of Drosophila are grouped
    into two clusters
  • -Antennapedia complex, which governs the
    anterior end of the fly
  • -Bithorax complex, which governs the posterior
    end of the fly
  • -Interestingly, the order of genes mirrors the
    order of the body parts they control

62
Production of Body Plan
  • Homeotic gene complexes
  • -All of these genes contain a conserved 180-base
    sequence, the homeobox
  • -Encodes a 60-amino acid DNA-binding domain,
    the homeodomain
  • -Homeobox-containing genes are termed Hox genes
  • -Vertebrates have 4 Hox gene clusters

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Production of Body Plan
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Production of Body Plan
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Pattern Formation in Plants
  • The predominant homeotic gene family in plants is
    the MADS-box genes
  • -Found in most eukaryotic organisms, although in
    much higher numbers in plants
  • MADS-box genes encode transcriptional regulators,
    which control various processes
  • -Transition from vegetative to reproductive
    growth, root development and floral organ identity

66
Morphogenesis
  • Morphogenesis is the formation of ordered form
    and structure
  • -Animals achieve it through changes in
  • -Cell division
  • -Cell shape and size
  • -Cell death
  • -Cell migration
  • -Plants use these except for cell migration

67
Morphogenesis
  • Cell division
  • -The orientation of the mitotic spindle
    determines the plane of cell division in
    eukaryotic cells
  • -If spindle is centrally located, two
    equal-sized daughter cells will result
  • -If spindle is off to one side, two unequal
    daughter cells will result

68
Morphogenesis
  • Cell shape and size
  • -In animals, cell differentiation is
    accomplished by profound changes in cell size and
    shape
  • -Nerve cells develop long processes called
    axons
  • -Skeletal muscles cells are large and
    multinucleated

69
Morphogenesis
  • Cell death
  • -Necrosis is accidental cell death
  • -Apoptosis is programmed cell death
  • -Is required for normal development in all
    animals
  • -Death program pathway consists of
  • -Activator, inhibitor and apoptotic
    protease

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Morphogenesis
  • Cell migration
  • -Cell movement involves both adhesion and loss
    of adhesion between cells and substrate
  • -Cell-to-cell interactions are often mediated
    through cadherins
  • -Cell-to-substrate interactions often involve
    complexes between integrins and the extracellular
    matrix (ECM)

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Development of Seed Plants
  • Plant development occurs in five main stages
  • 1. Early embryonic cell division
  • -First division is off-center
  • -Smaller cell divides to form the embryo
  • -Larger cell divides to form suspensor
  • -Cells near it ultimately form the root
  • -Cells on the other end, form the shoot

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Development of Seed Plants
  • 2. Embryonic tissue formation
  • -Three basic tissues differentiate
  • -Epidermal, ground and vascular
  • 3. Seed formation
  • -1-2 cotyledons form
  • -Development is arrested
  • 4. Seed germination
  • -Development resumes
  • -Roots extend down, and shoots up

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Development of Seed Plants
  • 5. Meristematic development and morphogenesis
  • -Apical meristems at the root and shoot tips
    generate a large numbers of cells
  • -Form leaves, flowers and all other components
    of the mature plant

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Environmental Effects
  • Both plant and animal development are affected by
    environmental factors
  • -Germination of a dormant seed proceeds only
    under favorable soil and day conditions
  • -Reptiles have a temperature-dependent sex
    determination (TSD) mechanism
  • -The water flea Daphnia changes its shape after
    encountering a predatory fly larva

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Environmental Effects
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Environmental Effects
  • In mammals, embryonic and fetal development have
    a longer time course
  • -Thus they are more subject to the effects of
    environmental contaminants, and blood-borne
    agents in the mother
  • -Thalidomide, a sedative drug
  • -Many pregnant women who took it
    had children with limb defects

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Environmental Effects
  • Endocrine disrupting chemicals (EDCs)
  • -Interfere with synthesis, transport or
    receptor-binding of endogenous hormones
  • -Derived from three main sources
  • -Industrial wastes (polychlorinated biphenyls
    or PCBs)
  • -Agricultural practices (DDT)
  • -Effluent of sewage-treatment plants
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