Human Biology Course Unit 9 PDF

Summary

This document is a course unit on human biology, focusing on the endocrine system and body defense mechanisms. It covers the functions of hormones, different endocrine glands and their roles, and interactions between the endocrine and nervous systems. The course unit also touches upon the related biological processes such as the hormonal regulation in the body.

Full Transcript

BACHELOR OF SCIENCE IN COMPUTER SCIENCE:
HUMAN BIOLOGY
COURSE MODULE COURSE UNIT WEEK
2 9 10

Endocrine System and Body Defense Mechanisms

✓ Read course and unit objectives
✓ Read study guide prior to class attendance
✓ Read required learning resources; refer to unit
terminologies for jargons
✓ Proactively participate in classroom discussions
✓ Participate in weekly discussion board (Canvas)
✓ Answer and submit course unit tasks

At the end of this unit, the students are expected to:

Cognitive:
1. Identify the major endocrine organs and the hormones that they secrete
2. Understand how hormones initiate both short-term and long-term body changes
3. Describe how the body reacts to the invasion of disease-causing organisms and substances
4. Explain how the body can acquire long-lasting resistance to microbes
Affective:
1. Listen attentively during class discussions
2. Challenge ideas and opinions raised by the classmates and instructors with tact and
respect.
 3. Appreciate how the endocrine system controls bodily processes and the growth and
development of an individual
Psychomotor:
1. Participate actively during online and face-to-face discussions

Goodenough, J. and McGuire, B. A. 2011. Human Biology. Majority of the modules are based on
the book Biology of Humans (4th Edition): Concepts, Application, and Issues (pp. 173-191, 238-
257). San Francisco, CA: Pearson

Endocrine System

Function and Mechanisms of Hormones

Endocrine glands release their hormones into the spaces just outside cells, instead of moving their
secretions through ducts as observed in other glands. After being released into spaces between
cells, the hormones then diffuse into the bloodstream.

Endocrine glands and organs that have some endocrine tissue constitute the endocrine system.
The endocrine system regulates and coordinates other organ systems and helps maintain
homeostasis.

Hormones serve as the chemical messengers of the endocrine system and these hormones
contact virtually all cells within the body. However, hormones affect only target cells that have
receptors for specific hormones. These receptors recognize and bind specific hormones. The
hormones can be categorized based on their chemical constitution, and they can be recognized as
steroid hormones or peptide hormones

Steroid hormones. Image from here

Steroid hormones are lipid-soluble, allowing them to cross through the plasma membrane of target
cells. Once it enters the cell, these hormones combine with a receptor molecule inside the cell,
forming a hormone–receptor complex. In the nucleus, the complex directs synthesis of specific
proteins, including enzymes that stimulate or inhibit metabolic pathways.

Water-soluble hormones. Image from here
Meanwhile, due to their composition, water-soluble hormones, like those made up of peptides and
proteins, cannot pass through the lipid bilayer of the plasma membrane. These hormones need to
activate second messenger systems in order to perform its function. The hormone binds to a
receptor on the plasma membrane. Once the hormone binds to a receptor, it will activate a
molecule in the cytoplasm, considered the second messenger. The secondary messenger changes
the activity of enzymes and chemical reactions.
A common difference in function between the two types of hormones is the kind of process
activated. Lipid-soluble hormones prompt the synthesis of proteins, while water-soluble hormones
activate existing proteins.

Endocrine glands are stimulated to manufacture and release hormones by chemical changes in the
blood, hormones released by other endocrine glands, and messages from the nervous system.

Hormone secretion is usually regulated by negative feedback mechanisms. However, there are
occasions that hormone secretion is made possible by positive feedback mechanisms. Hormones
also interact with each other, and the action may either be antagonistic, synergistic, or permissive.

Glands of the Endocrine System

Different Endocrine Glands in the human body. Image from here

Hypothalamus and the Pituitary Gland
Both the hypothalamus and the pituitary gland are found in the, or near the, brain. The pituitary
gland is divided into two parts, namely an anterior lobe and a posterior lobe. The function of the
anterior lobe is influenced by the hypothalamus through a circulatory connection (connection of
blood vessels). Neurosecretory cells (nerve cells that release chemical messengers) found in the
hypothalamus release hormones that travel by way of the bloodstream to the anterior lobe. These
hormones stimulate or inhibit release of hormones produced by the anterior lobe.

The anterior pituitary releases six hormones
o growth hormone, GH;
o prolactin, PRL;
o thyroid-stimulating hormone, TSH;
o adrenocorticotropic hormone,
o ACTH; follicle-stimulating hormone, FSH; and
o luteinizing hormone, LH.
Four (TSH, ACTH, FSH, LH) of the six hormones are tropic hormones, meaning they influence
other endocrine glands.

In contrast, the connection between the hypothalamus and the posterior lobe is neural, or by direct
connection of nerve cells. Neurosecretory cells in the hypothalamus make oxytocin (OT) and
antidiuretic hormone (ADH). These two hormones travel down the axons of the cells to axon
terminals found in the posterior lobe. These hormones are then stored in the posterior lobe and
released when needed.

Thyroid Glands

Thyroid gland produces two hormones, namely the thyroid hormone and the calcitonin. The thyroid
hormone is responsible for regulating metabolic rate, heat production, and blood pressure, and
there are two types of thyroid hormones, which are Thyroxine (T 4) and Triiodothyronine (T3).
Meanwhile, Calcitonin maintains low levels of calcium in the bloodstream
Parathyroid Glands

The parathyroid glands are located at back of the thyroid gland and appears as four small masses
of tissues. The parathyroid gland secretes parathyroid hormone (PTH), which has an opposite
function to calcitonin. The action of PTH raises blood levels of calcium through the movement of
calcium from bone and urine to the blood.

Adrenal Glands

Each of two adrenal glands are found on top of a kidney and has two regions, identified as adrenal
cortex and adrenal medulla. The adrenal cortex (outer region) releases gonadocorticoids,
mineralocorticoids, and glucocorticoids. The adrenal medulla (inner region) produces epinephrine
(adrenaline) and norepinephrine (noradrenaline). These two hormones are responsible for initiating
the fight-or-flight response.

Pancreas

The pancreas secretes the hormones that help control the sugar levels in the blood. Glucagon
increases glucose in the blood while insulin decreases glucose in the blood. The inability to control
the blood sugar levels could result in diabetes mellitus. Diabetes mellitus is a group of disorders
characterized by problems with insulin production or function.

Thymus Gland

The thymus gland lies on top of the heart and plays an important role in immunity since its
hormones play an important role in the maturation of white blood cells called T lymphocytes.

Pineal Gland

The pineal gland is located at the center of the brain. This hormone secretes the hormone
melatonin, which appears to be responsible for establishing biological rhythms and triggering
sleep.

Locally Acting Chemical Messengers

Some local chemical messengers transfer information between adjacent cells. These kinds of
receptors elicit rapid responses in target cells. Examples of local signaling molecules include
neurotransmitters, prostaglandins, growth factors, and nitric oxide.

Body Defense Mechanisms

The Body's Defense System

The body’s defense system attempts to attack substances or structures identified to be not part of
the body, which may include disease-causing organisms called pathogens as well as cancerous
cells.

Three Lines of Defense

The body has three lines of defense. These lines of defense activate at different periods and each
of these defenses perform different functions
Image from: Li, Xia & Xiupeng, Wang & Ito, Atsuo. (2018). Tailoring inorganic nanoadjuvants
towards next-generation vaccines. Chemical Society Reviews. 47. 10.1039/C8CS00028J.

The first line of defense includes both nonspecific physical barriers and chemical barriers.
Nonspecific physical barriers include the skin and mucous membranes while chemical barriers
include sweat, oil, tears, and saliva. Both physical and chemical barriers which prevent entry of
pathogens.

The second line of innate defense includes defensive cells and proteins, inflammation, and fever.
Phagocytes, eosinophils, and natural killer cells are defensive cells of the second line of defense.
Meanwhile, antiviral interferons and complement are proteins that cause cells to burst.

The inflammatory response is another part of the second line of defense and it occurs as a result of
tissue injury or invasion by foreign microbes.

Mast cells in the injured area release histamine. The histamine increases blood flow by dilating
blood vessels to the region. Dilating blood vessels increases the permeability of capillaries in the
region. Increased blood flow results in the redness and warmth in the region, while the release of
fluids from the capillaries causes swelling.
Fever is described as an abnormally high body temperature. Fever helps the body fight invading
microbes by increasing several body defense mechanisms. The increase in temperature also
slows down the growth of many pathogens.

The third line of defense, the adaptive immune response, targets specific pathogens, and this line
of defense takes advantage of memory of the immune system.

Distinguishing Self from Nonself

Self markers are present in all body cells. Self markers are proteins that are also called as the
major histocompatibility complex (MHC) proteins. Without these markers, cells are considered
nonself and are attacked by the immune system. An antigen is a substance that triggers the
immune system and are found in nonself cells.

Lymphocytes are white blood cells that are responsible for immune responses, and two types of
cells (B lymphocytes and T lymphocytes) develop in the bone marrow. However, both cells mature
in different places. The B cells stay and mature in the bone marrow, while the T cells migrate and
mature in the thymus gland. B cells and T cells have receptors on their respective cell surfaces.
These receptors allow each of those cells to recognize an antigen that features a different shape.

When an antigen is detected, B cells and T cells with receptors that detect the antigen, causing
these cells to replicate repeatedly. These cells form effector cells that destroy the antigen. Once
the antigen is destroyed, the cells then form memory cells that remain in the body over years or
even decades. These memory cells supply a rapid response on following exposure to the antigen.

Antibody-Mediated Responses and Cell-Mediated Responses

The antibody-mediated immune response and the cell-mediated immune response can occur
simultaneously with the aim to defend the body against the same antigen.

Steps of Adaptive Immune Response

Image from here

Macrophages engulf foreign material or
organism they encounter through the
process of phagocytosis. After engulfing
the material, a part of the destroyed
substance will be placed on the surface of
the macrophage to serve as an antigen.
This will alert lymphocytes to the presence
of an invader while at the same time
revealing the identity of the foreign body
looks like.
To prevent other immune cells from attacking the macrophages, these cells also have their own
molecular (MHC) markers on their membranes, allowing them to be identified as belonging in the
body.

The macrophage then presents the antigen to a helper T cell. The latter cell serves as the main
switch to the entire immune response after the macrophage secretes a chemical that activates the
helper T cell. Once it is activated, the helper T cell releases a chemical that activates the
appropriate B cells and T cells, although only the cells for the antigen will be activated.

B cells are responsible for antibody-mediated immune responses. Antibodies produced by the B-
cells allow the body to respond to antigens that are free in body fluids. These antigens including
bacteria, free virus particles, and toxins.

Once activated by the helper T cell, a B cell replicates repeatedly, and the B cells results to the
formation of two lines of descendant cells. which effector cells that transform into plasma cells and
memory B cells.

Plasma cells secrete Y-shaped proteins called antibodies into the bloodstream, and these proteins
bind to the particular antigen. Once the antigen is bound, the immune system may inactivate it or
may remove it from the body.

Cytotoxic T cells handle cell-mediated immune responses. These cells are more effective against
cellular threats. These cellular threats include infected body cells and cancer cells.

Like B cells, T cells form two lines of descendant cells upon activation, and these include effector
cells, called cytotoxic T cells, and memory T cells. Cytotoxic T cells secrete perforins, which
causes cells to burst and die by placing holes on the cell membrane.

After the first encounter with a particular antigen, the primary response is initiated, which may take
several weeks to become effective against the antigen. Meanwhile, memory T cells allows for a
quicker response in the presence of the same antigen. This response is called a secondary
response.

Last but not the least, the suppressor T cells dampen the activity of B cells and T cells when the
levels of the antigens present in the body decreases.

Active and Passive Immunity

In active immunity, the body forms memory cells that defend the body against a particular antigen.
There are two ways to develop active immunity, and these include the introduction of an antigen
that infects the body. Another way to develop active immunity is through vaccination, a procedure
that introduces a harmless form of an antigen into the body.

Meanwhile, a passive immunity results when a person receives antibodies that were produced by
another person or animal. Unlike active immunity, passive immunity only appears and works for a
short period of time.

Monoclonal Antibodies
Monoclonal antibodies are identical antibodies that bind to a specific antigen. Monoclonal
antibodies are used in research and in the diagnosis and treatment of diseases.

Problems of the Immune System

Autoimmune disorders occur when the immune system attacks the body’s own cells.

An allergy is a strong immune response against an antigen, which in this case is called an allergen.
Allergy occurs when the allergen binds to IgE antibodies on the surface of mast cells or basophils.
Once allergens are recognized by the mast cells or basophils, histamines are released. Histamine
causes redness, swelling, itching, and other symptoms that are commonly observed in an allergic
response.

Negative Feedback Mechanism – a mechanism that aims to reduce fluctuations in the output of the
system
Positive Feedback Mechanism – a mechanism that aims to increase fluctuations in the output of the
system
First Messenger – an extracellular substance that binds to a receptor at the cell surface. Examples of
first messenger include hormones and neurotransmitters.
Second Messenger – molecules within the cells that relay the signal from receptors located at the cell
surface
Pathogen – bacteria, virus, or fungi that could cause disease
Active Immunity – process of exposing the body to an antigen to generate a long-lasting immune
response.
Passive Immunity – provided when a person is given antibodies to combat pathogens present in the
body

National Institutes of Health (United States). (n.d.). Endocrine Diseases.
https://www.niddk.nih.gov/health-information/endocrine-diseases

Study Questions
Between the nervous system and the endocrine system, which of the two is responsible for
the growth spurt that occurs at puberty? Which of the two is responsible for the rapid
withdrawal of the hand once exposed to high temperature? Why?
Explain how an HIV infection can cause death in individuals even if the virus itself is not
direct cause of death of the person infected with the pathogen.
Goodenough, J. and McGuire, B. A. 2011. Human Biology. Majority
of the modules are based on the book Biology of Humans (4th
Edition): Concepts, Application, and Issues (pp. 173-191, 238-257).
San Francisco, CA: Pearson

Kerr, S and Georgia Institute of Technology. (23 November 2016).
Biology 1520: Animal Sensory Systems.
http://bio1520.biology.gatech.edu/chemical-and-electrical-
signals/sensory-systems-i/