M5 B ECTODERM - NEURULATION PDF

Summary

This document details the neurulation process, covering topics such as the formation and differentiation of the neural tube in amphibians and humans. It includes diagrams and descriptions of various stages and structures within the developing embryo.

Full Transcript

ECTODERM
Neurulation
ABI 3109 – Developmental Biology
Department of Biological Sciences
 Introduction: Organogenesis

Ectoderm the epidermis of the skin, nervous
system, sense organs and a few other cell types

Endoderm  tissues that line the digestive tract
and organs that develop as outgrowths of the
digestive tract (including the liver, pancreas, and
lungs).

Mesoderm  skeletal, muscle tissues and
circulatory, excretory and reproductive systems.
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Figure 1. A portrait of Hans Spemann and his assistant Hilde Pröscholdt Mangold.
 Spemann-Mangold Organizer

The Spemann-Mangold organizer, also known as
the Spemann organizer, is a cluster of cells in the
developing embryo of an amphibian that induces
development of the central nervous system.
Induction is the process by which the identity of
certain cells influences the developmental fate of
surrounding cells.
 The Spemann-Mangold organizer experiment

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 Transplantation Experiment
of Spemann and Mangold

Has shown that the cells in the Dorsal Lip Blastophore have an
extraordinary role in the formation of the dorsal mesoderm,
particularly the notochord and some pharyngeal endoderm
These cells have been referred to as the Spemann organizer
since the cells here induces the formation of the CNS
One important chemical that was later known to be the cause
of the induction of the CNS is chordin (encoded by the gene
chordin).
Before the CNS is induced to form, chordin is a protein that
dorsalizes early vertebrate embryonic tissues binds to bone
morphogenetic proteins (BMPs) that may be involved also in
organogenesis
o the embryonic process by which the neural plate folds to
give rise to the neural tube, which will form the central
nervous system in vertebrates.
Neurulation
Primary neurulation
 neural plate cells are directed to proliferate,
invaginate and pinch off to form hollow tube
Secondary neurulation
 neural tube arises from solid cord of cells that
sinks into the embryo
 forms the spinal cord/medullary cord and
mantle/intermediate zone
 differentiates into neurons and glia
Primary Neurulation

formation of the shaping of the
neural plate neural plate

bending of the
closure of the
neural plate –
neural groove –
neural groove
neural tube
(neural fold)
Primary Neurulation
Formation and shaping of the neural plate
 underlying dorsal mesoderm signals the
ectodermal cells to elongate
 shaping by intrinsic movement of epidermal and
neural plate regions
Primary Neurulation
Bending of the Neural Plate
 MHP – medial hinge point
 DLHP – dorsolateral hinge points
 becomes wedge shaped due to microfilaments
& microtubules inhibited by colchicine &
cytochalasin B
Primary Neurulation
Closure of Neural Tube
 paired neural folds are brought together at the
dorsal midline
 formation of neuropore
 neural tube separates from ectoderm by N-
cadherin and N-CAM
 Genetics: Pax3, Sonic hedgehog (Shh), open
brain (opb)
 Dietary: folic acid (Vit B12) and cholesterol
Differentiation of Neural Tube
neural tube & its lumen bulge & constrict to
form the brain and spinal cord chambers
cell population on neural tube rearrange to
form different regions of CNS
neuroepithelial cells differentiates into
neurons and glial cells
Neurulation of Humans
Neurulation in Humans
Neurulation in Humans
Neurulation in Humans
Neurulation in Humans
Neurulation in Humans
Neurulation in Humans
Neurulation in Humans
Neurulation in Humans
Differentiation of Neural Tube:
Cranial- Vesiculation
Differentiation of Neural
Tube
telencephalon
prosencephalon diencephalon

mesencephalon mesencephalon

rhombencephalon metencephalon

myelencephalon
 Derivatives of the Three Primary Vesicles

Primary Vesicles Secondary Vesicles Neural Derivatives Cavity Derivatives
Cerebral
Telencephalon hemispheres and Lateral ventricle
globus pallidus
Prosencephalon
Thalamus,
Diencephalon hypothalamus, and Third Ventricle
epithalamus
Mesencephalon Mesencephalon Midbrain Cerebral aqueduct
Pons and Upper part of
Metencephalon
cerebellum 4th ventricle
Rhombencephalon Lower part of
Myelencephalon Medulla 4th ventricle/central
canal
 Neurogenesis
Neural stem cell/ neuroderm cells begin to
differentiate into neurons and glial cells.
Neurons migrate throughout the brain, and once they
have reached their final destination they develop
axons and dendrites, forming synapses.
Neuronal Formation
> 1011 neurons & 1012 glial cells
CNS: oligodendrocyte
PNS: Schwann cell
 Spinal cord
the caudal end develops to form the spinal cord
Cells on the dorsal side form the alar plate, which
subsequently becomes the dorsal horn (posterior)
Cells at the ventral end form the basal plate, which
then becomes the ventral horn (anterior)
Neural Tube Defects
failure of the neural tube to close
 anencephaly, spinabifida, craniorachischisis
 Anencephaly
failure of the neural tube to close at the cranial/cephalic end, leading to the partial
absence of the brain and skull
lethal condition, and newborns with this congenital abnormality typically do not
survive longer than a few hours or days after birth
 Spina Bifida
results from incomplete closure of the neural tube at the
caudal end (most commonly in the lumbar region).
There are three main types of spina bifida, of increasing
severity: Oculta, Meningocele, Myelomeningocele
Spina bifida occulta
mildest and most common type. This type of
spina bifida results in a small separation or gap
in one or more of the bones of the spine
an incomplete closure of the vertebrae, without
protrusion of the spinal cord. Most people with
this form of spina bifida are unaware of having it,
and its discovery is often incidental
Meningocele (meningeal cyst)
a sac of fluid comes through an opening in your baby's
back, but their spinal cord isn't in the sac. There's usually
little or no nerve damage.
the meninges protrude between the vertebrae posteriorly,
but the spinal cord is undamaged.
simplest form of open neural tube defects characterized by
cystic dilatation of meninges containing cerebrospinal fluid
without any neural tissue.
Myelomeningocele(open spina bifida
most serious type
spinal canal is open along several vertebrae in the lower or middle
back
Part of the spinal cord, including the spinal cord's protective
covering and spinal nerves, push through this opening at birth,
forming a sac on the baby's back.
Tissues and nerves usually are exposed
baby prone to dangerous infections and may cause loss of
movement in the legs, and bladder and bowel dysfunction
Other ECTODERMAL
DERIVATIVES
Outer Ectoderm
 cells covering the embryo after
neurulation
 form the periderm that is shed
off and basal layer
(germinativum) – give rise to
spinous layer
Outer/Surface Ectoderm
 Outer/Surface Ectoderm

olfactory epithelium, mouth epithelium, tooth enamel, adenohypophysis,
lens, cornea, cochlear duct, semicircular ducts
Neural Crest
originates from cells located along the
margins of neural plate
break free from neural tube and lose cell to
cell adhesiveness
cranial, circumpahryngeal and trunk neural
crest
 Neural Crest
 Endocrine and
paraendocrine
derivatives
 PNS
 adrenal medulla
 dermal smooth
muscles
Neural Crest
 Pigment cells
 Anterior facial cartilage
 Connective tissue
 Corneal endothelium
 Tooth papillae
 Adipose tissue
 Connective tissue of salivary, lacrimal,
thymus, thyroid and pituitary