lecture 9.pdf

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Lecture 9: Pertubations of the
gastrointestinal tract

Explain how the liver and pancreas bud develop from the gut
tube, including molecular regulation.
Development of the gut tube

The gut tube forms from the endoderm

As the gut tube develops, it differentiates into various regions of the
digestive system, including the oesophagus, stomach, small intestine,
large intestine, liver, and pancreas.

Development of these regions involves specific patterns of gene
expression, which are represented in diagrams with different colours
and patterns.

The development of the GI tract follows an anterior (front) to posterior
(back) direction.

Various signalling processes regulate this development, including the
role of Hox genes and other homeobox-related transcription factors,

Lecture 9: Pertubations of the gastrointestinal tract 1
 which are crucial in controlling gene expression during this process.

Regional specification of gut endoderm through interactions with
surrounding tissues

Why study its development?

Understanding how the intestinal tract normally develops can provide
insight into the basis of birth defects.

Developing therapies for intestinal diseases depends on developing a
knowledge of how these tissues normally develop.

Regenerative and stem cell therapies aim to recapitulate the normal
steps in tissue development in order to produce the desired cell type.
Eg Pancreatic beta cells

Formation of the gut tube lining from endoderm

The gut tube is initially formed by both longitudinal and transverse folding
of the embryo

Lecture 9: Pertubations of the gastrointestinal tract 2
 Longitudinal folding

Occurs between days 21 and 24 of human development

Bending of the embryo along its length, which brings the head and tail
of the embryo closer together

The amniotic cavity pushes in at the cranial and caudal ends

As the head and tail ends move toward each other, causing the
opening to the yolk sac to narrow - this narrowing results in the
vitelline (yolk sac) duct becoming smaller and more localised to the
midgut.

Initially, the gut is divided into three regions: the foregut, midgut, and
hindgut. These regions are connected to the yolk sac, a structure that
provides nutrients to the developing embryo.

Transverse folding

This folding is influenced by the growth of somites (blocks of
mesoderm that will develop into muscles and vertebrae) and the
movement of the amniotic cavity, which pushes the sides of the
embryo inward

Lecture 9: Pertubations of the gastrointestinal tract 3
 Transverse folding occurs as a consequence of the enlargement of the
somites

The combination of transverse and lateral folding results in the
formation of the gut tube

Early establishment of the primitive gut tube

Adult derivatives

FOREGUT

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 Pharynx
Oesophagus
Stomach
Upper duodenum
Liver, gall bladder, pancreas

MIDGUT

Lower duodenum
Jejunum and ileum
Caecum and appendix
Ascending colon
Cranial half of transverse colon

HINDGUT

Caudal half of the transverse colon
Descending colon
Rectum

Pancreas and liver development

The endoderm forms the lining of 3 organs that develop caudal to the
stomach: liver, gallbladder and pancreas.

These organs originate as buds from the duodenum

Liver development:

Liver development can be induced in any part of the endoderm if
exposed to signals from the cardiac mesoderm (the tissue that will
form the heart) → these signals direct the endoderm to become liver
tissue.

However, the notochord (a structure that provides signals and support
during early development) inhibits liver formation

This is why the liver only forms in the region of the gut endoderm
closest to the cardiac mesoderm and far enough from the
notochord to avoid its inhibitory effects.

Pancreas development:

Lecture 9: Pertubations of the gastrointestinal tract 5
 Dorsal pancreas development is activated by the notochord through
activin and Fgf from the notochord repressing expression of sonic
hedgehog (shh) in the dorsal endoderm.

Additional signals from blood vessels (particularly the aorta and
vitelline veins) around the developing pancreas

Ie. the blood vessel endothelium (the inner lining of the blood
vessels) releases molecular signals that promote the expression of
key pancreatic genes such as PDX1 and PTF1A.

Pancreas has both exocrine (producing digestive enzymes) and
endocrine (producing hormones like insulin) components. The
development of the endocrine part, specifically the islets of
Langerhans, which secrete insulin, is heavily influenced by blood
vessels.

The blood vessels surrounding the pancreas are essential not only
for supplying nutrients but also for the proper development and
function of insulin-secreting cells, as these blood vessels will later
carry hormones into the bloodstream.

Vitelline ducts variation in different species

In chicken embryos, there are paired vitelline veins, which can
lead to the development of two lobes of a ventral pancreas.

In mice, however, one of the vitelline veins (the left one) is lost
during development, resulting in the formation of only a single
ventral pancreatic bud.

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 Heterotopic tissue - the presence of the tissue outside its normal location

Pieces of gastric mucosa or pancreatic tissue found in other organs → Can
cause ulcers in unexpected locations.

^^ Could be due to the inappropriate expression of genes

Eg) mice null for Hes1 (Notch signalling mediator) have ectopic
pancreas in stomach, duodenum.

Describe how a bilobed ventral pancreas could result in annular
pancreas.
Annular pancreas

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 A congenital condition where a ring of pancreatic tissue encircles the
duodenum, the first part of the small intestine

This abnormality can lead to duodenal obstruction, where the
passage of food through the duodenum is blocked, causing severe
digestive issues.

Normally, the ventral pancreas rotates to the right side and merges with the
dorsal pancreas to form a single organ

HOWEVER - it's hypothesised that a bilobed ventral pancreas could form
—meaning there are two lobes instead of one.

These two lobes could potentially wrap around both sides of the
duodenum, and as they merge with the dorsal pancreas, they could
create a ring of pancreatic tissue around the duodenum, leading to
obstruction.

In the context of annular pancreas, a lack of Shh signaling has been
associated with the development of this condition.

In humans, mutations in the Shh gene can lead to duodenal stenosis
(narrowing of the duodenum) and imperforate anus (a birth defect where
the opening to the anus is missing or blocked). Both of these conditions
are also associated with annular pancreas.

Lecture 9: Pertubations of the gastrointestinal tract 8
 Ihh is another member of the hedgehog signaling family. In mice, loss of Ihh
signaling has been linked to ectopic branching of the ventral pancreas, which
could also contribute to the development of an annular pancreas.

Explain how left-right asymmetry can affect midgut rotation, and
the spectrum of anomalies that can result from abnormal rotation.
Rotation of the midgut

The gut is suspended by the dorsal mesentery - suspending the
developing gut from the posterior abdominal wall in the embryo.

The mesentery is crucial for maintaining the proper positioning and
orientation of the gut during rotations. It helps to anchor the gut,
ensuring that it stays in place as it undergoes the complex movements
of rotation.

Two Phases of Gut Rotation:

1) First Rotation (90 Degrees Anti-clockwise):

As the midgut elongates and temporarily extends into the umbilical
cord (a process known as physiological herniation), it undergoes a
90-degree anti-clockwise rotation around the superior
mesenteric artery.

2) Second Rotation (180 Degrees Anti-clockwise):

After the midgut has elongated and rotated 90 degrees, it begins to
return from the umbilical cord back into the abdominal cavity.
During this process, the gut undergoes an additional 180-degree
anti-clockwise rotation.

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 Left-right asymmetry in rotation

The rotation of the gut is initiated and driven by several factors:

Greater Growth in the Cranial Limb: The cranial (upper) limb of the
developing midgut grows more rapidly than the caudal (lower) limb,
contributing to the rotation process.

Left-Right Asymmetry: Another significant factor is left-right
asymmetry, which is the developmental process where the left and
right sides of the body exhibit different gene expression patterns and
structures.

Although the gut tube itself is a singular structure, the mesentery is
derived from both the left and right sides of the embryo, which merge
together.

This merging results in the mesentery having distinct left and right
components, each with different structural and molecular
characteristics.

Left side has:

Lecture 9: Pertubations of the gastrointestinal tract 10
 Express Pitx2 - a gene that plays a key role in establishing left-right
asymmetry → leads to changes in gene expression and cellular
structures on the left side

Pitx2 drives the formation of a thicker columnar epithelium

Expression of N-cadherin

Mesenchymal condensation (a process where mesenchymal cells
aggregate and form denser tissue).

Right side has:

Has a thinner, more squamous-like epithelium

This asymmetry in thickness and structure between the left and right
sides contributes to the physical forces that pull and rotate the gut

Hypothesis for gut rotation → differential expression of genes like Pitx2 and
the resulting structural differences in the mesentery create a mechanical force
that pulls the gut to the left, initiating its anti-clockwise rotation

Lecture 9: Pertubations of the gastrointestinal tract 11
 Fusion to body wall

As the gut re-enters the abdominal cavity, parts of the mesentery (the
membrane that suspends and supports the gut) come into contact and
fuse with the gut wall.

The regions of the gut that remain suspended within the peritoneal cavity,
covered by the mesentery on both sides → intraperitoneal

Some regions of the gut, once intraperitoneal, become secondarily
retroperitoneal as they adhere to the posterior abdominal wall.

Eg) Ascending colon & descending colon

Abnormal rotation of the gut tube

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 Complications:

Volvulus (Gut Strangulation):

Definition: Volvulus refers to the twisting of a section of the gut
around itself, which can obstruct blood flow.

Consequences: Twisting can lead to strangulation of the blood
vessels, causing ischemia (lack of blood supply) and tissue
damage. It can also cause obstruction, resulting in pain and
inability to pass food.

Treatment: Surgical intervention is often required to resolve
volvulus and restore normal blood flow.

Non-Rotation:

Definition: Non-rotation occurs when the gut fails to complete its
normal anti-clockwise rotation. This can result in the primary
intestinal loop not rotating correctly.

Appearance: This condition can lead to the gut being positioned
on the left side of the abdomen, a situation sometimes called "left-
sided colon."

Reversed Rotation:

Definition: Reversed rotation is when the second 180-degree
rotation occurs in the opposite (clockwise) direction.

Consequences: This abnormal rotation can lead to misplacement
of the gut and potentially obstruct the normal arrangement and
function.

Sub-hepatic Cecum:

Definition: Sub-hepatic cecum occurs when the cecum (the
beginning of the large intestine) is fixed just below the stomach
(pylorus).

Consequences: This can result in the small intestine being
tethered by a narrow mesentery, increasing the risk of intestinal
obstruction.

Lecture 9: Pertubations of the gastrointestinal tract 13
 Factors affecting rotation:

Left-Right Signaling:

Role: Left-right signaling, such as through the Pitx2 gene, is crucial
for proper gut rotation. Disruptions can lead to abnormalities in
rotation.

Smooth Muscle Formation:

Importance: Proper smooth muscle formation in the gut wall is
essential for normal gut rotation.

Differential Growth:

Role: The differential growth of different parts of the gut helps
drive and regulate proper rotation.

Describe the physiological herniation of the gut during embryonic
development, and contrast the different types of abnormal
herniation (umbilical hernia, omphalocoele and gastroschisis).
Physiological Herniation:

Normal Occurrence: At 7-8 weeks of gestation, the gut temporarily
herniates into the umbilical cord. This is a normal part of development, and
the gut typically returns to the abdominal cavity by the end of this period.

Types of abnormal congenital hernias:

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 Umbilical Hernia:

Definition: A small portion of the bowel protrudes through the
umbilical ring but is covered by skin.

Severity: This type is generally less severe and often resolves
spontaneously as the child grows. Since it’s covered by skin, it usually
doesn’t pose significant issues.

Omphalocele:

Definition: In this condition, the intestines, usually the mid-gut, fail to
return to the abdominal cavity after the physiological herniation.

Covering: The protruding organs are covered by an amniotic
membrane but not by muscle or skin.

Issue: This can lead to problems because the abdominal contents are
exposed to the amniotic fluid and are not protected by the skin or
muscle.

Lecture 9: Pertubations of the gastrointestinal tract 15
 Gastroschisis:

Definition: The intestines protrude through a defect in the abdominal
wall, usually to the right of the umbilicus.

Covering: The intestines are not covered by an amniotic membrane,
skin, or muscle, making this condition more exposed than
omphalocele.

Issue: Since there’s no covering, the intestines are directly exposed to
the environment, which can lead to complications and infections.

Describe the consequences that can occur if remnants of the
vitelline duct remain after embryogenesis.
Vitelline duct

Initially the midgut is connected to the yolk sac → this connection
becomes the vitelline duct.

The vitelline duct normally regresses (between 5th - 8th week)

Lecture 9: Pertubations of the gastrointestinal tract 16
 Meckel's Diverticulum - a small, blind-ended pouch that remains if the
vitelline duct (or omphalomesenteric duct) doesn't regress completely during
fetal development

Mostly asymptomatic, but can be inflamed or ulcerated.

In some cases, the diverticulum remains connected to the umbilicus (belly
button) via a fibrous cord

Can create a potential for complications if the intestine twists around
this cord, leading to a condition called volvulus

Can creates a fistula (an abnormal connection) between the ileum
(part of the small intestine) and the umbilicus - called umbilicoileal
fistula

Meckel’s diverticulum is the most common congenital digestive
abnormality

Lecture 9: Pertubations of the gastrointestinal tract 17
 Explain how the urogenital sinus is separated from the rectum,
and anomalies that can occur following abnormal development of
the distal hindgut.
Primitive Cloaca:

The hindgut initially opens into the primitive cloaca, a common cavity
where the early digestive and urogenital systems are connected. This
cavity is lined with endodermal tissue

Urorectal septum then separates urogenital sinus & rectum

Urorectal Septum: A mesodermal structure known as the urorectal septum
begins to invaginate (fold inwards) and moves between the developing
rectum and the urogenital sinus (the part of the cloaca that will eventually
become the bladder and parts of the genitalia).

Separation: The urorectal septum eventually separates the cloaca into two
distinct systems: the rectum (posteriorly) and the urogenital sinus
(anteriorly). This separation creates two distinct openings—one for the
digestive system and one for the urogenital system.

Perineal Body Formation:

Perineal Body: After the separation is complete, the urorectal septum
forms a structure known as the perineal body at the cloacal membrane,
which is located between the future anus and urogenital openings.

Lecture 9: Pertubations of the gastrointestinal tract 18
 Epithelial Lining of the Gastrointestinal Tract:

Endodermal Origin: The epithelial lining of most of the gastrointestinal
tract, including the rectum, is derived from the endoderm.

Ectodermal Contribution: The lining of the very end of the anal canal is
derived from the ectoderm, forming a membrane at the base.

The anal canal initially has an endodermal and ectodermal membrane that
covers it. This membrane usually breaks down after the seventh week of
development, allowing the formation of the anal lumen (the opening of the
anus).

By about the ninth week of development, the anal lumen fully forms and
becomes a continuous tube.

The upper half of the anal canal is derived fromendoderm, while the lower
half is derived from ectoderm.

Dentate (Pectinate) Line:

Definition: The dentate line (or pectinate line) is the junction where the
endoderm-derived tissue (upper part of the anal canal) meets the
ectoderm-derived tissue (lower part of the anal canal).

Blood Supply and Innervation: Above and below the dentate line, the
tissues have different blood supplies and nerve innervations, which means

Lecture 9: Pertubations of the gastrointestinal tract 19
 they respond differently to conditions such as hemorrhoids.

Hemorrhoids: Hemorrhoids above the dentate line (internal hemorrhoids)
are generally not painful because they are innervated by visceral nerves.
In contrast, hemorrhoids below the line (external hemorrhoids) are more
painful because they are innervated by somatic nerves, which are more
sensitive.

Imperforate anus/anal atresia

Lack of an Anal Opening (Imperforate Anus):

Cause: One possible cause of this condition is the persistence of the
cloacal membrane, which is a membrane that normally breaks down
to allow the formation of the anal opening. If this membrane does not
open up, it results in an imperforate anus, where there is no external
opening for the rectum.

Visual: In a baby with an imperforate anus, there is no visible anal
opening, and this condition requires surgical intervention to create a
proper opening.

Atresia of the Rectum:

Definition: Atresia refers to a condition where a body passage is
abnormally closed or absent. In the case of rectal atresia, the rectum
does not fully develop or extend properly, resulting in a blockage
where the rectum ends in a blind pouch rather than opening externally.

Lecture 9: Pertubations of the gastrointestinal tract 20
 Severity: The severity of atresia can vary, depending on how much
tissue is obstructing the pathway or how much of the rectum is
underdeveloped.

Abnormal Connections Between Urogenital and Rectal Tissues:

Cause: During normal development, the urorectal septum separates
the urogenital system from the rectal system. However, if this process
is incomplete or abnormal, there can be improper connections or
fistulas between these systems, leading to complications.

Deletion of both Hoxa13 and Hoxd13 in mice cause defects in cloacal
partitioning and anal sphincter.

Role: Hox genes are critical in the proper formation and partitioning of
the cloaca into separate urogenital and rectal regions. Mutations in
these genes can lead to defects in the urorectal septum, resulting in
improper separation of the digestive and urogenital systems, as well as
defects in the formation of the anal sphincter.

Mutations in Shh and Gli2 result in lack of anus (colon ends in blind sac)

Role: The Shh signaling pathway is crucial for the proper development
of many body structures, including the formation of the anus.
Mutations in this pathway can cause severe defects, such as a
condition where the colon ends in a blind sac, meaning there is no
connection between the rectum and the external body, leading to an
imperforate anus.

Lecture 9: Pertubations of the gastrointestinal tract 21
 Hindgut fistulas (abnormal connection between two body parts) and atresias
(absence or closure of a normal body passage)

Many cases of anal atresia have a fistula connecting portion of hindgut to
another
structure in urogenital sinus region.

Lecture 9: Pertubations of the gastrointestinal tract 22
 Explain how Hirschsprungs disease results from improper
development of the neural crest.
Enteric nervous system development

Enteric neural crest cells (ENCCs) primarily originate from the vagal
neural crest, located around the neck region (cervical area) of the
developing embryo

Migration process:

ENCCs migrate from the vagal region into the gut, beginning at the oral
(mouth) end and moving towards the anal end

As the cells migrate along the gut, they colonize it, contributing to the
formation of the enteric nervous system throughout the
gastrointestinal tract.

Stages of Migration in Mice:

Lecture 9: Pertubations of the gastrointestinal tract 23
 E9.5: The neural crest cells begin their migration into the developing
gut.

E10.5: The gut is undergoing physiological herniation (a temporary
stage where the gut protrudes into the umbilical cord due to rapid
growth), and the neural crest cells continue their migration.

As the gut returns to the abdominal cavity, ENCCs migrate further and
populate the entire length of the gut.

Contribution of Sacral Neural Crest Cells:

In addition to the vagal neural crest cells, a smaller population of sacral
neural crest cells (originating from the lower part of the spinal cord)
also contributes to the ENS.

However, the sacral neural crest cells only start contributing
significantly after the vagal neural crest cells have already migrated to
the distal (far) end of the gut. They mainly give rise to some of the
neurons and glia in the distal parts of the gut.

Enteric nervous system

Structure of the Enteric Nervous System (ENS):

The ENS forms two major networks of neurons, called plexi (or
plexuses), that run along the entire length of the gut:

Lecture 9: Pertubations of the gastrointestinal tract 24
 Myenteric Plexus (Auerbach's Plexus): Located between the two
layers of the muscularis externa, this plexus primarily controls the
gut's motility, including the rhythmic contractions known as
peristalsis.

Submucosal Plexus (Meissner's Plexus): Found in the
submucosa, this plexus regulates functions such as blood flow,
secretion of digestive enzymes, and absorption in the gut.

Fishnet Stockings Analogy:

The plexuses are described as looking like "fishnet stockings,"
meaning they consist of interconnected neuronal cell bodies and
fibers that create a net-like structure across the gut wall. This
network allows for coordinated communication and control across
different parts of the gut.

Regulation of Gut Function:

The ENS plays a crucial role in regulating several aspects of gut
function:

Peristalsis: The coordinated contraction and relaxation of gut
muscles that propels food along the digestive tract. The
myenteric plexus is primarily responsible for this process.

Secretion: The submucosal plexus controls the secretion of
digestive enzymes and fluids, which are essential for breaking
down food

Autonomous Functioning:

The ENS is sometimes referred to as the "second brain" because it
contains a vast number of neurons—almost as many as in the
spinal cord—and can operate independently of the central nervous
system (CNS).

Although it is modulated by the sympathetic and parasympathetic
branches of the autonomic nervous system (which can speed up
or slow down digestive processes), the ENS itself can control
digestion autonomously. This independence allows the digestive

Lecture 9: Pertubations of the gastrointestinal tract 25
 system to function without conscious thought, ensuring that the
body efficiently processes and absorbs nutrients.

Hirschsprung’s Disease

Hirschsprung's disease occurs when neural crest cells fail to migrate all
the way to the end of the gut during development.

Neural crest cells are essential for forming the ENS, which controls
peristalsis—the rhythmic contractions that move food through the
digestive tract. In Hirschsprung's disease, there is a region of the gut
without an ENS (aganglionic region), meaning this area cannot
regulate muscle contractions properly.

Effect on the Gut:

The absence of the ENS in a section of the gut results in that area
being constantly constricted. The muscles in this section cannot
relax, causing a blockage.

Food can enter the gut but cannot pass through the constricted area,
leading to a build-up of food and waste above the blockage.

Symptoms and Physical Manifestation:

Lecture 9: Pertubations of the gastrointestinal tract 26
 The constricted region with no ENS leads to a condition known as
megacolon. The section of the gut above the constriction becomes
swollen because food and waste accumulate there.

This swollen area, however, contains normal enteric neurons and is
not the source of the problem. The actual issue lies in the constricted
segment at the end of the gut, where there is a lack of enteric
neurons.

Complications:

If left untreated, the build-up of waste in the megacolon can lead to
dangerous complications. The gut may swell to the point where it tears
or leaks, causing sepsis, a life-threatening infection that can spread
throughout the body.

Lecture 9: Pertubations of the gastrointestinal tract 27
 Hirschsprungs disease – role of GDNF pathway

GDNF (Glial Cell-Derived Neurotrophic Factor) is crucial for the
development of the enteric nervous system (ENS). It is responsible for:

Survival of enteric neural crest cells.

Migration of these cells along the gut.

Proliferation (increasing the number of cells).

Lecture 9: Pertubations of the gastrointestinal tract 28
 Differentiation (cells becoming specialized).

The pathway involves GDNF forming a dimer (a molecule made up of two
identical subunits). This dimer binds to a receptor called GFRα1 (GDNF
family receptor alpha 1), which must pair with another receptor, RET (a
receptor tyrosine kinase), to activate downstream signaling that is crucial
for ENS development.

Mice study:

Knockout Mice (Mice without GDNF or RET genes):

Mice lacking the GDNF or RET gene completely fail to develop
enteric neurons, indicating the essential role of these genes in ENS
development.

Heterozygous Mice (Mice with one functional and one non-
functional RET gene):

These mice appear normal and do not show defects in the ENS,
indicating that in mice, one functional RET gene is sufficient for
normal ENS development.

Differences Between Mice and Humans:

In humans, individuals who are heterozygous for a mutation in RET
(having one normal and one mutated RET gene) can develop
Hirschsprung's disease. This suggests that humans may require a
higher level of RET function than mice.

The difference might be due to the fact that humans have a longer gut
than mice, meaning that the process of neural crest cells migrating
along the gut takes longer and might require more RET signaling for
proper development.

Threshold of RET Function:

In mice, if RET levels are reduced to about 30-40%, they develop
Hirschsprung's disease. This highlights the importance of maintaining
a certain threshold level of RET for the proper migration of neural crest
cells and the formation of the ENS.

Hirschsprung’s disease – complex multigenic disorder

Lecture 9: Pertubations of the gastrointestinal tract 29
 Hirschsprung's disease occurs more frequently in males than in females

There is a 4:1 male:female sex bias

The disease is influenced by both genetic mutations and environmental
factors

Incomplete Penetrance - refers to the fact that not everyone with a
genetic mutation associated with Hirschsprung's disease will actually
develop the disease.

For example, within the same family, individuals with the same
missense mutation in the RET gene can have different outcomes:

One individual may have long-segment Hirschsprung's disease,
where a large portion of the gut is affected.

Two others might have short-segment Hirschsprung's disease,
with a smaller region affected.

Another might not develop the disease at all.

The variability in how Hirschsprung's disease manifests can be attributed
to several factors:

Multiple Genes: Other genes besides RET may influence the
development and severity of the disease.

Environmental Factors: Non-genetic factors, such as the prenatal
environment, could impact the development of the enteric nervous
system.

Epigenetic Factors: Changes in gene expression that do not involve
alterations to the DNA sequence (epigenetics) might play a role.

Sex Bias: As mentioned, the disease affects males more frequently,
suggesting that gender may also influence the risk and severity of the
condition.

Discuss the role of the microbiota in the development and
maturation of the gastrointestinal tract.
Microbiota

Lecture 9: Pertubations of the gastrointestinal tract 30
 The microbiota consists of bacteria that live in the gastrointestinal tract,
particularly in the colon.

These bacteria are crucial for digesting food and providing nutrients that
the human body cannot extract on its own.

Interestingly, there are more bacterial genes in the human body than
human genes.

Although the microbiota likely doesn't play a significant role in development
before birth, it becomes essential for normal functioning and immune
development after birth.

The microbiota is also involved in regulating the immune system, the nervous
system, and nutrient absorption.

Variability of Microbiota:

The composition of the microbiota varies significantly between individuals,
primarily influenced by diet.

The idea that the uterus is sterile has been challenged by recent studies
showing minimal bacterial colonization before birth. However, the majority
of microbiota colonization happens after birth.

Influence of Birth Method:

The mode of delivery during birth impacts the initial microbiota
colonization:

Vaginal birth exposes the baby to bacteria from the vaginal canal.

Caesarean birth exposes the baby to bacteria primarily from the skin.

This difference in initial exposure could potentially influence the baby's
developing microbiota and overall health.

Diet's Role in Microbiota Development:

A baby's microbiota is heavily influenced by its diet, such as whether the
baby is breastfed or bottle-fed.

The microbiota undergoes significant changes during the first two years of
life, stabilizing afterward.

Lecture 9: Pertubations of the gastrointestinal tract 31
 Germ free mice

Germ-free mice are bred and raised in an environment without any
bacteria, often delivered by caesarean section and kept in sterile
conditions.

These mice show significant differences in immune system development,
nervous system function, and nutrient absorption compared to mice with
normal bacterial exposure.

Some effects of bacteria (gut microtobia) on gut development

Increase development of small intestinal capillary networks - crucial for
proper nutrient absorption and gut function.

Development of immune system in gut

Lecture 9: Pertubations of the gastrointestinal tract 32
 Affects the presence and function of glial cells in crypt/villi - involved in
supporting neurons and maintaining gut function.

Maintenance of neural-immune interactions in ENS

Impact on brain development - Comparisons between germ-free mice
(mice without any bacteria) and those with a normal microbiota reveal
differences in brain activity and gene expression.

For instance, germ-free mice exhibit changes in brain activity and
gene expression compared to mice with a healthy, diverse microbiota.

Impact of microbiota

Effect on immune development

Effect on nervous system (enteric nervous system and brain)

Lecture 9: Pertubations of the gastrointestinal tract 33
 Behaviour

Effect on gut epithelium

Intestinal (and overall) health

An imbalance in the microbiota, known as dysbiosis, where harmful
bacteria outnumber beneficial ones, can disrupt gut function and
contribute to various health problems.

Dietary Recommendations:

Healthy Diet: A diet rich in vegetables and whole grains supports a healthy
microbiota. This is because such foods promote the growth of beneficial
bacteria.

Lecture 9: Pertubations of the gastrointestinal tract 34
 Mediterranean Diet: This diet, which emphasizes whole grains,
vegetables, fruits, nuts, and healthy fats, has been shown to improve the
diversity and health of gut bacteria.

Lecture 9: Pertubations of the gastrointestinal tract 35