Chapter 41 Animal
Nutrition
Lecture Outline
Overview: The Need to Feed
·
All
animals eat other organisms—dead or alive, whole or by the piece (including
parasites).
·
In
general, animals fit into one of three dietary categories.
1. Herbivores, such as gorillas, cows, hares, and many snails,
eat mainly autotrophs (plants and algae).
2. Carnivores, such as sharks, hawks, spiders, and snakes, eat
other animals.
3. Omnivores, such as cockroaches, bears, raccoons, and humans, consume
animal and plant or algal matter.
°
Humans
evolved as hunters, scavengers, and gatherers.
·
While
the terms herbivore, carnivore, and omnivore represent the kinds of food
that an animal usually eats, most animals are opportunistic, eating foods that
are outside their main dietary category when these foods are available.
°
For
example, cattle and deer, which are herbivores, may occasionally eat small
animals or bird eggs.
°
Most
carnivores obtain some nutrients from plant materials that remain in the
digestive tract of the prey that they eat.
°
All
animals consume bacteria along with other types of food.
·
For
any animal, a nutritionally adequate diet must satisfy three nutritional needs:
1. A balanced diet must
provide fuel for cellular work.
2. It must supply the organic
raw materials needed to construct organic molecules.
3. Essential nutrients that
the animal cannot make from raw materials must be provided in its food.
Concept 41.1 Homeostatic mechanisms manage an
animal’s energy budget
·
The
flow of food energy into and out of an animal can be viewed as a “budget,” with
the production of ATP accounting for the largest fraction by far of the energy
budget of most animals.
°
ATP
powers basal or resting metabolism, as well as activity and, in endothermic
animals, thermoregulation.
·
Nearly
all ATP generation is based on the oxidation of organic fuel
molecules—carbohydrates, proteins, and fats—in cellular respiration.
°
The
monomers of any of these substances can be used as fuel.
°
Fats
are especially rich in energy, liberating about twice the energy liberated from
an equal amount of carbohydrate or protein during oxidation.
·
When
an animal takes in more calories than it needs to produce ATP, the excess can
be used for biosynthesis.
°
This
biosynthesis can be used to grow in size or for reproduction, or it can be
stored in energy depots.
°
In
humans, the liver and muscle cells store energy as glycogen, a polymer made up
of many glucose units.
§
Glucose
is a major fuel molecule for cells, and its metabolism, regulated by hormone
action, is an important aspect of homeostasis.
§
If
glycogen stores are full and caloric intake still exceeds caloric expenditure,
the excess is usually stored as fat.
§
When
fewer calories are taken in than are expended—perhaps because of sustained
heavy exercise or lack of food—fuel is taken out of storage depots and
oxidized.
§
The
human body expends liver glycogen first and then draws on muscle glycogen and
fat.
°
Most
healthy people—even if they are not obese—have enough stored fat to sustain
them through several weeks of starvation.
§
The
average human’s energy needs can be fueled by the oxidation of only 0.3 kg of
fat per day.
·
Severe
problems occur if the energy budget remains out of balance for long periods.
°
If
the diet of a person or other animal is chronically deficient in calories, undernourishment results.
°
The
stores of glycogen and fat are used up, the body begins breaking down its own
proteins for fuel, muscles begin to decrease in size, and the brain can become
protein-deficient.
°
If
energy intake remains less than energy expenditure, death will eventually
result, and even if a seriously undernourished person survives, some damage may
be irreversible.
·
Because
a diet of a single staple such as rice or corn can often provide sufficient
calories, undernourishment is generally common only where drought, war, or some
other crisis has severely disrupted the food supply.
·
Another
cause of undernourishment is anorexia nervosa, an eating disorder associated
with a compulsive aversion to body fat.
Obesity is a global health problem.
·
Overnourishment, or obesity, the result of
excessive food intake, is a common problem in the
°
The
human body tends to store any excess fat molecules obtained from food instead
of using them for fuel.
§
In
contrast, when we eat an excess of carbohydrates, the body tends to increase
its rate of carbohydrate oxidation.
°
Thus,
the amount of fat in the diet can have a more direct effect on weight gain than
the amount of dietary carbohydrates.
°
While
fat hoarding can be a liability today, it probably provided a fitness advantage
for our hunting-and-gathering ancestors, enabling individuals with genes
promoting the storage of high-energy molecules during feasts to survive the
eventual famines.
·
The
World Health Organization now recognizes obesity as a major global health problem.
°
The
increased availability of fattening foods in many countries combines with more
sedentary lifestyles to put excess weight on bodies.
°
In
the
·
Obesity
contributes to health problems, including diabetes, cancer of the colon and
breast, and cardiovascular disease.
·
Research
on the causes and possible treatments for weight-control problems continues.
°
Over
the long term, feedback circuits control the body’s storage and metabolism of
fat.
°
Several
hormones regulate long-term and short-term appetite by affecting a “satiety
center” in the brain.
·
Inheritance
is a major factor in obesity.
°
Most
of the weight-regulating hormones are polypeptides.
°
Dozens
of genes that code for these hormones have been identified.
·
In
mammals, a hormone called leptin, produced by adipose cells, is a key player in
a complex feedback mechanism regulating fat storage and use.
°
As
adipose tissue increases, high leptin levels cue the brain to depress appetite
and to increase energy-consuming muscular activity and body-heat production.
°
Conversely,
loss of body fat decreases leptin levels in the blood, signaling the brain to
increase appetite and weight gain.
°
Mice
that inherit a defective gene for leptin become very obese.
§
These
mice can be treated by injection with leptin.
°
However,
very few obese people have defective leptin production.
§
In
fact, most obese humans have abnormally high
leptin levels, due to their large amounts of adipose tissue.
°
For
some reason, the brain’s satiety center does not respond to the high leptin
levels in many obese people.
°
One
hypothesis is that in humans, in contrast to other mammals, the leptin system
functions to stimulate appetite and prevent weight loss rather than to prevent
weight gain.
·
Most
humans crave fatty foods. Although fat hoarding is a health liability today, it
may have been advantageous in our evolutionary past.
·
Our
ancestors on the African savanna were hunter-gatherers who probably survived
mainly on plant materials, occasionally supplemented by meat.
°
Natural
selection may have favored those individuals with a physiology that induced
them to gorge on fatty foods on the rare occasions that they were available.
°
Perhaps
these individuals were more likely to survive famine.
·
Obesity
may be beneficial in certain species.
°
Small
seabirds called petrels fly long distances to find food that is rich in lipids.
°
By
bringing lipid-rich food to their chicks, the parents minimize the weight of
food that they must carry.
°
However,
because these foods are low in protein, young petrels have to consume more
calories than they burn in metabolism—and consequently they become obese.
°
In
some petrel species, chicks at the end of the growth period weigh much more
their parents, are too heavy to fly, and need to starve for several days to
fly.
°
The
fat reserves help growing chicks to survive periods when parents are unable to
find food.
Concept 41.2 An animal’s diet must supply carbon
skeletons and essential nutrients
·
In
addition to fuel for ATP production, an animal’s diet must supply all the raw
materials for biosynthesis.
°
This
requires organic precursors (carbon skeletons) from its food.
°
Given
a source of organic carbon (such as sugar) and a source of organic nitrogen
(usually in amino acids from the digestion of proteins), animals can fabricate
a great variety of organic molecules—carbohydrates, proteins, and lipids.
·
Besides
fuel and carbon skeletons, an animal’s diet must also supply essential nutrients.
°
These
are materials that must be obtained in preassembled form because the animal’s
cells cannot make them from any raw
material.
°
Some
materials are essential for all animals, but others are needed only by certain
species.
§
For
example, ascorbic acid (vitamin C) is an essential nutrient for humans and
other primates, guinea pigs, and some birds and snakes, but not for most other
animals.
·
An
animal whose diet is missing one or more essential nutrients is said to be malnourished.
°
For
example, many herbivores living where soils and plants are deficient in
phosphorus eat bones to obtain this essential nutrient.
°
Malnutrition
is much more common than undernourishment in human populations, and it is even
possible for an overnourished individual to be malnourished.
·
There
are four classes of essential nutrients: essential amino acids, essential fatty
acids, vitamins, and minerals.
·
Animals
require 20 amino acids to make proteins.
°
Most
animals can synthesize half of these if their diet includes organic nitrogen.
·
The
remaining essential amino acids must
be obtained from food in prefabricated form.
°
Eight
amino acids are essential in the adult human with a ninth, histidine, being
essential for infants.
°
The
same amino acids are essential for most animals.
·
A
diet that provides insufficient amounts of one or more essential amino acids
causes a form of malnutrition known as protein deficiency.
°
This
is the most common type of malnutrition among humans.
°
The
victims are usually children, who, if they survive infancy, are likely to be retarded
in physical and perhaps mental development.
·
In
one variation of protein malnutrition, called kwashiorkor, the diet provides enough calories but is severely
deficient in protein.
·
The
protein in animal products, such as meat, eggs, and cheese, are “complete,”
which means that they provide all the essential amino acids in their proper
proportions.
·
Most
plant proteins are “incomplete,” being deficient in one or more essential amino
acid.
°
For
example, corn is deficient in the amino acid lysine.
°
Individuals
who are forced by economic necessity or other circumstances to obtain nearly
all their calories from corn would show symptoms of protein deficiency.
§
This
is true from any diet limited to a single plant source, including rice, wheat,
and potatoes.
·
Protein
deficiency from a vegetarian diet can be avoided by eating a combination of
plant foods that complement one another to supply all essential amino acids.
°
For
example, beans supply the lysine that is missing in corn, and corn provides the
methionine that is deficient in beans.
·
Because
the body cannot easily store amino acids, a diet with all essential amino acids
must be eaten each day, or protein synthesis is retarded.
·
Some
animals have special adaptations that get them through periods where their
bodies demand extraordinary amounts of protein.
°
For
example, penguins use muscle proteins as a source of amino acids to make new
proteins during molting.
·
While
animals can synthesize most of the fatty acids they need, they cannot
synthesize essential fatty acids.
°
These
are certain unsaturated fatty acids, including linoleic acids, which are
required by humans.
°
Most
diets furnish ample quantities of essential fatty acids, and thus deficiencies
are rare.
·
Vitamins are organic molecules
required in the diet in quantities that are quite small compared with the
relatively large quantities of essential amino acids and fatty acids animals
need.
°
While
vitamins are required in tiny amounts—from about 0.01 mg to 100 mg per
day—depending on the vitamin, vitamin deficiency (or overdose in some cases)
can cause serious problems.
·
So
far, 13 vitamins essential to humans have been identified.
°
These
can be grouped into water-soluble vitamins and fat-soluble vitamins, with
extremely diverse physiological functions.
·
The
water-soluble vitamins include the B complex, which consists of several
compounds that function as coenzymes in key metabolic processes.
°
Vitamin
C, also water soluble, is required for the production of connective tissue.
°
Excessive
amounts of water-soluble vitamins are excreted in urine, and moderate overdoses
are probably harmless.
·
The
fat-soluble vitamins are A, D, E, and K.
°
They
have a wide variety of functions.
°
Vitamin
A is incorporated in the visual pigments of the eye.
°
Vitamin
D aids in calcium absorption and bone formation.
°
Vitamin
E seems to protect membrane phospholipids from oxidation.
°
Vitamin
K is required for blood clotting.
°
Excess
amounts of fat-soluble vitamins are not excreted but are deposited in body fat.
§
Overconsumption
may lead to toxic accumulations of these compounds.
·
The
subject of vitamin dosage has aroused heated scientific and popular debate.
°
Some
believe that it is sufficient to meet recommended daily allowances (RDAs), the
nutrient intake proposed by nutritionists to maintain health.
°
Others
argue that RDAs are set too low for some vitamins, and a fraction of these
people believe, probably mistakenly, that massive
doses of vitamins confer health benefits.
°
Debate
centers on the optimal doses of vitamins C and E.
°
While
research is ongoing, all that can be said with any certainty is that people who
eat a balanced diet are not likely to develop symptoms of vitamin deficiency.
·
Minerals are simple inorganic
nutrients, usually required in small amounts—from less than 1 mg to about 2,500
mg per day.
°
Mineral
requirements vary with animal species.
°
Humans
and other vertebrates require relatively large quantities of calcium and
phosphorus for the construction and maintenance of bone.
§
Calcium
is also necessary for the normal functioning of nerves and muscles.
§
Phosphorus
is a component of the cytochromes that function in cellular respiration.
°
Iron
is a component of the cytochromes that function in cellular respiration and of
hemoglobin, the oxygen-binding protein of red blood cells.
°
Magnesium,
iron, zinc, copper, manganese, selenium, and molybdenum are cofactors built
into the structure of certain enzymes.
§
Magnesium,
for example, is present in enzymes that split ATP.
°
Iodine
is required for thyroid hormones, which regulate metabolic rate.
·
Sodium,
potassium, and chloride are important in nerve function and have a major
influence on the osmotic balance between cells and the interstitial fluids.
·
Excess
consumption of salt (sodium chloride) is harmful.
°
The
average
°
Excess
consumption of salt or several other minerals can upset homeostatic balance and
cause toxic side effects.
°
For
example, too much sodium is associated with high blood pressure, and excess
iron causes liver damage.
Concept 41.3 The main stages of food processing
are ingestion, digestion, absorption, and elimination
·
Ingestion, the act of eating, is
only the first stage of food processing.
°
Food
is “packaged” in bulk form and contains very complex arrays of molecules,
including large polymers and various substances that may be difficult to
process or even toxic.
·
Animals
cannot use macromolecules like proteins, fats, and carbohydrates in the form of
starch or other polysaccharides.
°
First,
polymers are too large to pass through membranes and enter the cells of the
animal.
°
Second,
the macromolecules that make up an animal are not identical to those of its
food.
§
In
building their macromolecules, however, all organisms use common monomers.
§
For
example, soybeans, fruit flies, and humans all assemble their proteins from the
same 20 amino acids.
·
Digestion, the second stage of food
processing, is the process of breaking food down into molecules small enough
for the body to absorb.
°
Digestion
cleaves macromolecules into their component monomers, which the animal then
uses to make its own molecules or as fuel for ATP production.
§
Polysaccharides
and disaccharides are split into simple sugars.
§
Fats
are digested to glycerol and fatty acids.
§
Proteins
are broken down into amino acids.
§
Nucleic
acids are cleaved into nucleotides.
·
Digestion
reverses the process that a cell uses to link together monomers to form
macromolecules.
°
Rather
than removing a molecule of water for each new covalent bond formed, digestion
breaks bonds with the addition of water via enzymatic hydrolysis.
°
A
variety of hydrolytic enzymes catalyze the digestion of each of the classes of
macromolecules found in food.
·
Chemical
digestion is usually preceded by mechanical fragmentation of the food—by
chewing, for instance.
°
Breaking
food into smaller pieces increases the surface area exposed to digestive juices
containing hydrolytic enzymes.
·
After
the food is digested, the animal’s cells take up small molecules such as amino
acids and simple sugars from the digestive compartment, a process called absorption.
·
During
elimination, undigested material
passes out of the digestive compartment.
Digestion occurs in specialized compartments.
·
To
avoid digesting their own cells and tissues, most organisms conduct digestion
in specialized compartments.
·
The
simplest digestive compartments are food vacuoles, organelles in which
hydrolytic enzymes break down food without digesting the cell’s own cytoplasm,
a process termed intracellular
digestion.
·
This
process begins after a cell has engulfed food by phagocytosis or pinocytosis.
·
Newly
formed food vacuoles fuse with lysosomes, which are organelles containing
hydrolytic enzymes.
·
Later
the vacuole fuses with an anal pore, and its contents are eliminated.
·
In
most animals, at least some hydrolysis occurs by extracellular digestion, the breakdown of food outside cells.
°
Extracellular
digestion occurs within compartments that are continuous with the outside of
the animal’s body.
°
This
enables organisms to devour much larger prey than can be ingested by
phagocytosis and digested intracellularly.
·
Many
animals with simple body plans, such as cnidarians and flatworms, have
digestive sacs with single openings, called gastrovascular cavities.
°
These
cavities function in both digestion and distribution of nutrients throughout the
body.
°
For
example, the cnidarians called hydras capture their prey with nematocysts and
use tentacles to stuff the prey through the mouth into the gastrovascular
cavity.
§
The
prey is then partially digested by enzymes secreted by specialized gland cells of
the gastrodermis.
°
Nutritive
muscular cells in the gastrodermis engulf the food particles.
§
Most
of the actual hydrolysis of macromolecules occurs intracellularly.
°
Undigested
materials are eliminated through the mouth.
·
In
contrast to cnidarians and flatworms, most animals have digestive tubes
extending between a mouth and anus.
·
These
tubes are called complete digestive tracts or alimentary canals.
°
Because
food moves in one direction, the tube can be organized into specialized regions
that carry out digestion and nutrient absorption in a stepwise fashion.
°
In
addition, animals with alimentary canals can eat more food before the earlier
meal is completely digested.
Concept 41.4 Each organ of the mammalian digestive system has
specialized food-processing functions
·
The
general principles of food processing are similar for a diversity of animals,
including the mammalian system that we will use as a representative example.
·
The
mammalian digestive system consists of the alimentary canal and various
accessory glands that secrete digestive juices into the canal through ducts.
°
Peristalsis, rhythmic waves of
contraction by smooth muscles in the walls of the canal, pushes food along.
°
Sphincters, muscular ring-like
valves, regulate the passage of material between specialized chambers of the
canal.
°
The
accessory glands include the salivary
glands, the pancreas, the liver, and the gallbladder.
·
After
chewing and swallowing, it takes 5 to 10 seconds for food to pass down the
esophagus to the stomach, where it spends 2 to 6 hours being partially
digested.
·
Final
digestion and nutrient absorption occur in the small intestine over a period of
5 to 6 hours.
·
In
12 to 24 hours, any undigested material passes through the large intestine, and
feces are expelled through the anus.
The oral cavity, pharynx, and esophagus
initiate food processing.
·
Both
physical and chemical digestion of food begins in the mouth.
°
During
chewing, teeth of various shapes cut, smash, and grind food, making it easier
to swallow and increasing its surface area.
°
The
presence of food in the oral cavity
triggers a nervous reflex that causes the salivary glands to deliver saliva
through ducts to the oral cavity.
°
Salivation
may occur in anticipation because of learned associations between eating and
the time of day, cooking odors, or other stimuli.
·
Saliva
contains a slippery glycoprotein called mucin, which protects the soft lining
of the mouth from abrasion and lubricates the food for easier swallowing.
°
Saliva
also contains buffers that help prevent tooth decay by neutralizing acid in the
mouth.
°
Antibacterial
agents in saliva kill many bacteria that enter the mouth with food.
·
Chemical
digestion of carbohydrates, a main source of chemical energy, begins in the
oral cavity.
°
Saliva
contains salivary amylase, an enzyme
that hydrolyzes starch and glycogen into smaller polysaccharides and the
disaccharide maltose.
·
The
tongue tastes food, manipulates it during chewing, and helps shape the food
into a ball called a bolus.
°
During
swallowing, the tongue pushes a bolus back into the oral cavity and into the
pharynx.
·
The
pharynx, also called the throat, is
a junction that opens to both the esophagus and the trachea (windpipe).
°
When
we swallow, the top of the windpipe moves up so that its opening, the glottis,
is blocked by a cartilaginous flap, the epiglottis.
°
This
mechanism normally ensures that a bolus will be guided into the entrance of the
esophagus and not directed down the windpipe.
°
When
not swallowing, the esophageal sphincter muscles are contracted, the epiglottis
is up, and the glottis is open, allowing airflow to the lungs.
°
When
a food bolus reaches the pharynx, the larynx moves upward and the epiglottis
tips over the glottis, closing off the trachea.
°
The
esophageal sphincter relaxes and the bolus enters the esophagus.
°
In
the meantime, the larynx moves downward and the trachea is opened, and
peristalsis moves the bolus down the esophagus to the stomach.
·
The
esophagus conducts food from the
pharynx down to the stomach by peristalsis.
°
The
muscles at the very top of the esophagus are striated and, therefore, under
voluntary control.
°
Involuntary
waves of contraction by smooth muscles in the rest of the esophagus then take
over.
The stomach stores food and performs
preliminary digestion.
·
The
stomach is located in the upper
abdominal cavity, just below the diaphragm.
°
With
accordion-like folds and a very elastic wall, the stomach can stretch to
accommodate about 2 L of food and fluid, storing an entire meal.
°
The
stomach also secretes a digestive fluid called gastric juice and mixes this secretion with the food by the
churning action of the smooth muscles in the stomach wall.
·
Gastric
juice is secreted by the epithelium lining numerous deep pits in the stomach
wall.
°
With
a high concentration of hydrochloric acid, the pH of the gastric juice is about
2—acidic enough to digest iron nails.
§
This
acid disrupts the extracellular matrix that binds cells together.
§
It
kills most bacteria that are swallowed with food.
°
Also
present in gastric juice is pepsin,
an enzyme that begins the hydrolysis of proteins.
§
Pepsin,
which works well in strongly acidic environments, breaks peptide bonds adjacent
to specific amino acids, producing smaller polypeptides.
§
Pepsin
is secreted in an inactive form
called pepsinogen by specialized
chief cells in gastric pits.
°
Parietal
cells, also in the pits, secrete hydrochloric acid that converts pepsinogen to
the active pepsin only when both reach the lumen of the stomach, minimizing
self-digestion.
§
In
a positive-feedback system, activated pepsin can activate more pepsinogen
molecules.
·
The
stomach’s second line of defense against self-digestion is a coating of mucus,
secreted by epithelial cells, that protects the stomach lining.
°
Still,
the epithelium is continually eroded, and the epithelium is completely replaced
by mitosis every three days.
°
Gastric
ulcers, lesions in the stomach lining, are caused by the acid-tolerant
bacterium Heliobacter pylori.
§
Ulcers
are often treated with antibiotics.
·
About
every 20 seconds, the stomach contents are mixed by the churning action of smooth
muscles.
°
You
may feel hunger pangs when your empty stomach churns.
§
Sensations
of hunger are also associated with brain centers that monitor the blood’s
nutritional status and the levels of appetite-controlling hormones.
°
As
a result of mixing and enzyme action, what begins in the stomach as a recently
swallowed meal becomes a nutrient-rich broth known as acid chyme.
·
Most
of the time the stomach is closed off at either end.
°
The
opening from the esophagus to the stomach, the cardiac orifice, normally dilates
only when a bolus driven by peristalsis arrives.
§
The
occasional backflow of acid chyme from the stomach into the lower esophagus
causes heartburn.
°
At
the opening from the stomach to the small intestine is the pyloric sphincter, which helps regulate the passage of chyme into
the intestine.
§
A
squirt at a time, it takes about 2 to 6 hours after a meal for the stomach to
empty.
The small intestine is the major organ of
digestion and absorption.
·
With
a length of more than 6 m in humans, the small
intestine is the longest section of the alimentary canal.
·
Most
of the enzymatic hydrolysis of food macromolecules and most of the absorption
of nutrients into the blood occurs in the small intestine.
·
In
the first 25 cm or so of the small intestine, the duodenum, acid chyme from the stomach mixes with digestive juices
from the pancreas, liver, gall bladder, and gland cells of the intestinal wall.
°
The
pancreas produces several hydrolytic enzymes and an alkaline solution rich in
bicarbonate that buffers the acidity of the chyme from the stomach.
°
Pancreatic
enzymes include protein-digesting enzymes (proteases) that are secreted into
the duodenum in inactive form.
§
The
pancreatic proteases are activated once they are in the extracellular space
within the duodenum.
·
The
liver performs a wide variety of important functions in the body, including the
production of bile.
°
Bile
is stored in the gallbladder until needed.
°
It
contains bile salts that act as detergents that aid in the digestion and
absorption of fats.
°
Bile
also contains pigments that are by-products of red blood cell destruction in
the liver.
§
These
bile pigments are eliminated from the body with the feces.
·
The
brush border of the epithelial lining of the duodenum produces several
digestive enzymes.
°
Several
enzymes are secreted into the lumen, while others are bound to the surface of
the epithelial cells.
·
Enzymatic
digestion is completed as peristalsis moves the mixture of chyme and digestive
juices along the small intestine.
·
Most
digestion is completed while the chyme is still in the duodenum.
·
The
remaining regions of the small intestine, the jejunum and ileum,
function mainly in the absorption of nutrients and water.
·
To
enter the body, nutrients in the lumen must pass the lining of the digestive
tract.
·
A
few nutrients are absorbed in the stomach and large intestine, but most
absorption takes place in the small intestine.
°
The
small intestine has a huge surface area—300 m2, roughly the size of
a tennis court.
·
The
enormous surface of the small intestine is an adaptation that greatly increases
the rate of nutrient absorption.
°
Large
circular folds in the lining bear fingerlike projections called villi, and each epithelial cell of a
villus has many microscopic appendages called microvilli that are exposed to the intestinal lumen.
°
The
microvilli are the basis of the term “brush border” for the intestinal
epithelium.
·
Penetrating
the core of each villus is a net of microscopic blood vessels (capillaries) and
a single vessel of the lymphatic system called a lacteal.
°
Nutrients
are absorbed across the intestinal epithelium and then across the unicellular
epithelium of capillaries or lacteals.
°
Only
these two single layers of epithelial cells separate nutrients in the lumen of
the intestine from the bloodstream.
·
In
some cases, transport of nutrients across the epithelial cells is passive, as
molecules move down their concentration gradients from the lumen of the
intestine into the epithelial cells, and then into capillaries.
°
Fructose,
a simple sugar, moves by diffusion alone down its concentration gradient from
the lumen of the intestine into the epithelial cells and then into capillaries.
·
Amino
acids and sugars pass through the epithelium, enter capillaries, and are
carried away from the intestine by the bloodstream.
·
Glycerol
and fatty acids absorbed by epithelial cells are recombined into fats.
°
The
fats are mixed with cholesterol and coated with special proteins to form small
globules called chylomicrons.
°
Chylomicrons
are transported by exocytosis out of epithelial cells and into lacteals.
°
The
lacteals converge into the larger vessels of the lymphatic system, eventually
draining into large veins that return blood to the heart.
°
The
capillaries and veins that drain nutrients away from the villi converge into
the hepatic portal vein, which leads
directly to the liver.
·
Therefore,
the liver, which has the metabolic versatility to interconvert various organic
molecules, has first access to amino acids and sugars absorbed after a meal is
digested.
·
The
liver modifies and regulates this varied mix before releasing materials back
into the bloodstream.
°
For
example, the liver helps regulate the levels of glucose in the blood, ensuring
that blood exiting the liver usually has a glucose concentration very close to
0.1%, regardless of carbohydrate content of the meal.
·
From
the liver, blood travels to the heart, which pumps the blood and nutrients to
all parts of the body.
Reclaiming water is a major function of the
large intestine.
·
The
large intestine, or colon, is connected to the small
intestine at a T-shaped junction where a sphincter controls the movement of
materials.
°
One
arm of the T is a pouch called the cecum.
°
The
relatively small cecum of humans has a fingerlike extension, the appendix, which makes a minor
contribution to body defense.
°
The
main branch of the human colon is shaped like an upside-down U, about 1.5 m
long.
·
A
major function of the colon is to recover water that has entered the alimentary
canal as the solvent to various digestive juices.
°
About
7 L of fluid are secreted into the lumen of the digestive tract of a person
each day.
°
More
than 90% of the water is reabsorbed, most in the small intestine, the rest in
the colon.
°
Digestive
wastes, the feces, become more solid
as they are moved along the colon by peristalsis.
°
Movement
in the colon is sluggish, requiring 12 to 24 hours for material to travel the
length of the organ.
°
If
the lining of the colon is irritated by a bacterial infection, less water than
usual is resorbed, resulting in diarrhea.
§
If
insufficient water is absorbed because peristalsis moves the feces too slowly,
the result is constipation.
·
Living
in the large intestine is a rich flora of mostly harmless bacteria.
°
One
of the most common inhabitants of the human colon is Escherichia coli, a favorite research organism.
°
As
a by-product of their metabolism, many colon bacteria generate gases, including
methane and hydrogen sulfide.
°
Some
bacteria produce vitamins, including biotin, folic acid, vitamin K, and several
B vitamins, which supplement our dietary intake of vitamins.
·
Feces
contain masses of bacteria and undigested materials including cellulose.
°
Although
cellulose fibers have no caloric value to humans, their presence in the diet
helps move food along the digestive tract.
·
The
terminal portion of the colon is called the rectum, where feces are stored until they can be eliminated.
°
Between
the rectum and the anus are two sphincters, one involuntary and one voluntary.
°
Once
or more each day, strong contractions of the colon create an urge to defecate.
Concept 41.5 Evolutionary adaptations of
vertebrate digestive systems are often associated with diet
·
The
digestive systems of mammals and other vertebrates are variations on a common
plan.
·
However,
there are many intriguing variations, often associated with the animal’s diet.
·
Dentition,
an animal’s assortment of teeth, is one example of structural variation
reflecting diet.
°
Particularly
in mammals, evolutionary adaptation of teeth for processing different kinds of
food is one of the major reasons that mammals have been so successful.
·
Nonmammalian
vertebrates generally have less specialized dentition, but there are
exceptions.
°
For
example, poisonous snakes, such as rattlesnakes, have fangs, modified teeth
that inject venom into prey.
§
Some
snakes have hollow fangs, like syringes, while others drip poison along grooves
in the tooth surface.
·
All
snakes have another important anatomic adaptation for feeding, the ability
swallow large prey whole.
°
The
lower jaw is loosely hinged to the skull by an elastic ligament that permits
the mouth and throat to open very wide for swallowing.
·
Large,
expandable stomachs are common in carnivores, which may go for a long time
between meals and, therefore, must eat as much as they can when they do catch
prey.
°
For
example, a 200-kg African lion can consume 40 kg of meat in one meal.
·
The
length of the vertebrate digestive system is also correlated with diet.
·
In
general, herbivores and omnivores have longer alimentary canals relative to
their body sizes than do carnivores, providing more time for digestion and more
surface areas for absorption of nutrients.
·
Vegetation
is more difficult to digest than meat because it contains cells walls.
Symbiotic microorganisms help nourish many
vertebrates.
·
Much
of the chemical energy in the diet of herbivorous animals is contained in the
cellulose of plant cell walls.
°
However,
animals do not produce enzymes that hydrolyze cellulose.
°
Many
vertebrates (and termites) solve this problem by housing large populations of
symbiotic bacteria and protists in special fermentation chambers in their
alimentary canals.
°
These
microorganisms do have enzymes that
can digest cellulose to simple sugars that the animal can absorb.
·
The
location of symbiotic microbes in herbivores’ digestive tracts varies depending
on the species.
°
The
hoatzin, an herbivorous bird that lives in South American rain forests, has a
large, muscular crop that houses symbiotic microorganisms.
°
Many
herbivorous mammals, including horses, house symbiotic microorganisms in a
large cecum, the pouch where the small and large intestines connect.
°
The
symbiotic bacteria of rabbits and some rodents live in the large intestine and
cecum.
§
Since
most nutrients are absorbed in the small intestine, these organisms recover
nutrients from fermentation in the large intestine by eating some of their feces
and passing food through a second time.
°
The
koala also has an enlarged cecum, where symbiotic bacteria ferment finely
shredded eucalyptus leaves.
·
The
most elaborate adaptations for a herbivorous diet have evolved in the ruminants, which include deer, cattle,
and sheep.
°
When
the cow first chews and swallows a mouthful of grass, boluses enter the rumen
and the reticulum.
§
Symbiotic
bacteria and protists digest this cellulose-rich meal, secreting fatty acids.
§
Periodically,
the cow regurgitates and rechews the cud, which further breaks down the
cellulose fibers.
°
The
cow then reswallows the cud to the omasum, where water is removed.
°
The
cud, with many microorganisms, passes to the abomasum for digestion by the
cow’s enzymes.