Regeneration in animals
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Apr 11, 2020
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About This Presentation
This invloves the regeneration in animals All three types of regeneration are included
Slide Content
Tuhar Mukherjee
We have seen that tail of house lizards,
legs of spiders to be of normal size after
they are shed by the organism when
they try to escape from a danger.
The shedding of own body part is called
autotomy
legs of spiders to be of normal size after
they are shed by the organism when
they try to escape from a danger.
The shedding of own body part is called
autotomy
What is regeneration?
Regenerationisthereactivationof
developmentinpostembryoniclifeto
restoremissingtissue.
Inanimalkingdomregenerationis
presentinseveralanimalgroups.
Regenerationismarkedinloweranimal
groupslikePorifera,Cnidaria.
Regenerationisthereactivationof
developmentinpostembryoniclifeto
restoremissingtissue.
Inanimalkingdomregenerationis
presentinseveralanimalgroups.
Regenerationismarkedinloweranimal
groupslikePorifera,Cnidaria.
Porifera include those animals that are
called sponges. They multicellular
animals without tissue grade
organization.
Cnidaria includes animals like jelly fish,
sea anemone and corals. They have
nematocysts lodged in cnidoblast cells.
Regeneration whether minor wound
healing or regeneration of a leg takes
place in all organisms
called sponges. They multicellular
animals without tissue grade
organization.
Cnidaria includes animals like jelly fish,
sea anemone and corals. They have
nematocysts lodged in cnidoblast cells.
Regeneration whether minor wound
healing or regeneration of a leg takes
place in all organisms
Regeneration experiments
Tremblay 1741 (Hydra)
Réaumur 1712 (Crustaceans)
Spallanzani (Salamanders)
Tremblay 1741 (Hydra)
Réaumur 1712 (Crustaceans)
Spallanzani (Salamanders)
Crustaceans are arthropods that include
crabs, prawns. They predominantly
aquatic except Oniscus (wood louse)
which is a terrestrial crustaceans.
Salamanders are amphibians that
belong to the Order Caudata. Their body
is lizard-like.
crabs, prawns. They predominantly
aquatic except Oniscus (wood louse)
which is a terrestrial crustaceans.
Salamanders are amphibians that
belong to the Order Caudata. Their body
is lizard-like.
Types of regeneration
Stem-cell mediated regeneration
Epimorphosis
Morphallactic regeneration
Compensatory regeneration
Stem-cell mediated regeneration
Epimorphosis
Morphallactic regeneration
Compensatory regeneration
Epimorphosis
Adult structure can undergo
dedifferentiation to form a relatively
undifferentiated mass of cells that then
redifferentiates to form the new
structures.
This type of regeneration is found during
regeneration amphibian limb
Adult structure can undergo
dedifferentiation to form a relatively
undifferentiated mass of cells that then
redifferentiates to form the new
structures.
This type of regeneration is found during
regeneration amphibian limb
Anatomy of the Fore-limbs
Regeneration of Salamander
limbs
1.The skin and muscle retract from the tip
of the humerus after 2 days of
amputation.
2.Thin accumulation of blastema calls is
seen behind a thickened cap-like
epithelial layer or epidermis (Apical
Ectodermal Cap), 5 day stage
3.Large population of mitotically active
blastema cells lie distal to the humerus,
7 day stage
limbs
1.The skin and muscle retract from the tip
of the humerus after 2 days of
amputation.
2.Thin accumulation of blastema calls is
seen behind a thickened cap-like
epithelial layer or epidermis (Apical
Ectodermal Cap), 5 day stage
3.Large population of mitotically active
blastema cells lie distal to the humerus,
7 day stage
4.Blastema enlarge mitotically,
dedifferentiation occurs, 8 day
5.Early redifferentiation begins with
chondrogenesis begins in the proximal
part of the humerus and radius-ulna, 9
day
6.Pre cartilaginous condensation in the
carpal bones and digits
dedifferentiation occurs, 8 day
5.Early redifferentiation begins with
chondrogenesis begins in the proximal
part of the humerus and radius-ulna, 9
day
6.Pre cartilaginous condensation in the
carpal bones and digits
Molecular mechanism
Experiments have been done by
transplantation and immuno-blocking.
The growth of the regeneration blastema
depend on Apical ectodermal cap and
the surrounding nerve tissue.
AEC secretes Fgf8 which stimulates the
growth of the blastema.
The presence of nerves are essential for
the development of the regeneration
blastema (Mullen et al 1996).
Experiments have been done by
transplantation and immuno-blocking.
The growth of the regeneration blastema
depend on Apical ectodermal cap and
the surrounding nerve tissue.
AEC secretes Fgf8 which stimulates the
growth of the blastema.
The presence of nerves are essential for
the development of the regeneration
blastema (Mullen et al 1996).
The nerve cells secrete release factors like the new
anterior gradient protein (nAG) necessary for the
proliferation of the blastema cells.
Maintenance of ion current is also important
The field is maintained by V-ATPase proton pump in
Xenopus laevis.
V-ATPase also called vacuolar ATPase are
evolutionary conserved ATPases that are found in
eukaryotic cells. They maintain low pH or acidic
environment in a wide variety of intracellular
organelles like lysosomes
Suppression the field inhibits the development of the
limb (Altizer et al 2002).
anterior gradient protein (nAG) necessary for the
proliferation of the blastema cells.
Maintenance of ion current is also important
The field is maintained by V-ATPase proton pump in
Xenopus laevis.
V-ATPase also called vacuolar ATPase are
evolutionary conserved ATPases that are found in
eukaryotic cells. They maintain low pH or acidic
environment in a wide variety of intracellular
organelles like lysosomes
Suppression the field inhibits the development of the
limb (Altizer et al 2002).
Pattern formation
The dorsal-ventral and anterior-posterior
axes between the stump and the
regenerating tissue are conserved, and
cellular and molecular studies have
confirmed that the patterning
mechanisms of developing and
regenerating limbs are very similar. The
blastema cells can respond to the limb
bud of a developing limb (Muneoka and
Bryant, 1982)
The dorsal-ventral and anterior-posterior
axes between the stump and the
regenerating tissue are conserved, and
cellular and molecular studies have
confirmed that the patterning
mechanisms of developing and
regenerating limbs are very similar. The
blastema cells can respond to the limb
bud of a developing limb (Muneoka and
Bryant, 1982)
Sonic Hedgehog is seen in the posterior
region of the blastema and the developing limb
bud.
Retinoic acid synthesized by the wound
epidermis specifies the proximal distal axis
and also the anterior posterior axis.
RA activates Hoxa gene differentially in the
that specifies the pattern in the regenerating
Limbs.
It might also establish the domain of Meis
genes (1 & 2) across the limb bud. Fgfs
suppress the Meis gene activation restricting
them to the proximal side
region of the blastema and the developing limb
bud.
Retinoic acid synthesized by the wound
epidermis specifies the proximal distal axis
and also the anterior posterior axis.
RA activates Hoxa gene differentially in the
that specifies the pattern in the regenerating
Limbs.
It might also establish the domain of Meis
genes (1 & 2) across the limb bud. Fgfs
suppress the Meis gene activation restricting
them to the proximal side
Epimorphic regeneration is also seen in
planarian flatworms.
planarian flatworms.
Morphallactic regeneration
Regeneration occurs due to repatterning
of existing tissues.
Hydra
Regeneration occurs due to repatterning
of existing tissues.
Hydra
Morphollactic regeneration in
Hydra
Body Hydra has head (hypostome region)
at the distal
Foot (basal disc) at proximal end
If the body is cut into several pieces, each
piece will regenerate a head at its apical
end and a foot at its basal end. The result
is a smaller size organism as no growth
takes place.
The polarity of Hydra is determined by a
series of morphogenetic gradients that
permit the head to form at one region and
basal disc at another.
Hydra
Body Hydra has head (hypostome region)
at the distal
Foot (basal disc) at proximal end
If the body is cut into several pieces, each
piece will regenerate a head at its apical
end and a foot at its basal end. The result
is a smaller size organism as no growth
takes place.
The polarity of Hydra is determined by a
series of morphogenetic gradients that
permit the head to form at one region and
basal disc at another.
Morphogen gradients
Head activation gradient
Head inhibition gradient
Basal disc activation gradient
Basal disc inhibition gradient
Head activation gradient
Head inhibition gradient
Basal disc activation gradient
Basal disc inhibition gradient
Head activation gradient
Gradient can be measured by implanting
rings of tissue from various levels of a
donor Hydrainto the host trunk
Wilby and Webster 1970
Herands and Bode 1974
MacWilliams 1983
Peptide gradients involved are Heady,
Head Activator and Hym301
Heady and Head Activator critical for head
formation and initiation of bud
Hym301 for number of tentacles formed
Gradient can be measured by implanting
rings of tissue from various levels of a
donor Hydrainto the host trunk
Wilby and Webster 1970
Herands and Bode 1974
MacWilliams 1983
Peptide gradients involved are Heady,
Head Activator and Hym301
Heady and Head Activator critical for head
formation and initiation of bud
Hym301 for number of tentacles formed
Head inhibition gradient
Normal regeneration of hypostome is inhibited when
an intact hypostome is grafted adjacent to the site of
amputation
If subhypostomal tissue is grafted to the same site of
amputation, no secondary axis forms. Host’s head
inhibits the formation of head and secondary axis
If subhypostomal tissue is grafted to a decapitated
host, secondary axis forms.
No head will be produced if the tissue is implanted
into the apical region of intact host
Head will be produced if implanted below the host.
Normal regeneration of hypostome is inhibited when
an intact hypostome is grafted adjacent to the site of
amputation
If subhypostomal tissue is grafted to the same site of
amputation, no secondary axis forms. Host’s head
inhibits the formation of head and secondary axis
If subhypostomal tissue is grafted to a decapitated
host, secondary axis forms.
No head will be produced if the tissue is implanted
into the apical region of intact host
Head will be produced if implanted below the host.
Hypostome
Broun and Bode 2002
Hypostome can induce secondary axis in host tissue
Produces both head activation and head inhibition signals
Self-differentiating region
head inhibition signals inhibit the formation of new
organizing centers
Signaling through the canonical Wnt pathway form the
head organizer.
Inhibition of GSK3 leads to ectopic tentacles at all levels
and each piece of the trunk has the ability to stimulate the
outgrowth of new buds.
Goosecoid (vertebrate organizer molecule) and
Brachyury(induces formation of mesoderm in vertebrates)
are also found
Broun and Bode 2002
Hypostome can induce secondary axis in host tissue
Produces both head activation and head inhibition signals
Self-differentiating region
head inhibition signals inhibit the formation of new
organizing centers
Signaling through the canonical Wnt pathway form the
head organizer.
Inhibition of GSK3 leads to ectopic tentacles at all levels
and each piece of the trunk has the ability to stimulate the
outgrowth of new buds.
Goosecoid (vertebrate organizer molecule) and
Brachyury(induces formation of mesoderm in vertebrates)
are also found
Basal disc
Source foot activation and foot inhibition
gradients.
Gradients of head and foot inhibitors
appear to block bud formation
mannacle might activate shineguard in
the basal disc ectoderm
shineguard, a tyrosine kinase extends in
a gradient from the ectoderm just above
the basal disc through the lower region.
Bud form where this gradient fades.
Source foot activation and foot inhibition
gradients.
Gradients of head and foot inhibitors
appear to block bud formation
mannacle might activate shineguard in
the basal disc ectoderm
shineguard, a tyrosine kinase extends in
a gradient from the ectoderm just above
the basal disc through the lower region.
Bud form where this gradient fades.
Bud location is a function of both the
head and foot inhibitors.
When the head is removed the head
inhibitor is not made. The region with the
highest head activator forms the head.
After the head is formed, head inhibitor
generates.
head and foot inhibitors.
When the head is removed the head
inhibitor is not made. The region with the
highest head activator forms the head.
After the head is formed, head inhibitor
generates.
Compensatory regeneration
the differentiated cells divide and
maintain their differentiated function.
Cells do not come from stem cells or
dedifferentiated cells.
Found in mammalian liver, heart of
zebra fish
the differentiated cells divide and
maintain their differentiated function.
Cells do not come from stem cells or
dedifferentiated cells.
Found in mammalian liver, heart of
zebra fish
Histology of liver
Regeneration of liver cells
Loss of liver cells is sensed by the absence
of some liver specific factors and increase
of bile salts and gut lipopolysaccharides
Lipopolysaccharides activate the non-
hepatocyte cells (Kupffer’s cells and
stellate cells) to secrete paracrine factors
like IL6. These factors induce the
hepatocytes to reenter cell cycle.
Kupffer cells secrete IL6 and TNF alpha
Stellate cells secrete TGF beta and
hepatocyte growth factor.
Loss of liver cells is sensed by the absence
of some liver specific factors and increase
of bile salts and gut lipopolysaccharides
Lipopolysaccharides activate the non-
hepatocyte cells (Kupffer’s cells and
stellate cells) to secrete paracrine factors
like IL6. These factors induce the
hepatocytes to reenter cell cycle.
Kupffer cells secrete IL6 and TNF alpha
Stellate cells secrete TGF beta and
hepatocyte growth factor.
Hepatocytes activate cMet.
cMet is the receptor for HGF.
Blocking of cMet blocks liver regeneration
Trauma of partial hepatectomy releases
metalloproteinases that digests the extracellular
matrix and permit the hepatocyte to separate
and proliferate.
Enzymes may also activate HGF by proteolysis
cleavage.
All these factors promote cell division by
activating cyclin D and E, repressing cyclin
inhibitors like p27 and preventing apoptosis
Fxr transcription factor activated by bile is
necessary for liver regeneration
Oval cells are small progenitor cells that can
produce hepatocytes and bile duct cells
cMet is the receptor for HGF.
Blocking of cMet blocks liver regeneration
Trauma of partial hepatectomy releases
metalloproteinases that digests the extracellular
matrix and permit the hepatocyte to separate
and proliferate.
Enzymes may also activate HGF by proteolysis
cleavage.
All these factors promote cell division by
activating cyclin D and E, repressing cyclin
inhibitors like p27 and preventing apoptosis
Fxr transcription factor activated by bile is
necessary for liver regeneration
Oval cells are small progenitor cells that can
produce hepatocytes and bile duct cells
Regeneration in other animals
Polypoid stage of cnidarians
Earthworms can regenerate their lost
body parts if they are cut antero-
posteriorly
Arthropod limb
Echinoderms like star fish can
regenerate arms.
Holothurians can regenerate parts of
alimentary canal and respiration tree.
Polypoid stage of cnidarians
Earthworms can regenerate their lost
body parts if they are cut antero-
posteriorly
Arthropod limb
Echinoderms like star fish can
regenerate arms.
Holothurians can regenerate parts of
alimentary canal and respiration tree.
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