nonsteroid hormone
Hormone derived from
an amine, a peptide, or
a protein.
second messenger
Molecule that relays a
hormone signal inside a
target cell.
steroid hormone
Hormone derived from
cholesterol.
types of hormones and their signals
n There are two basic categories of hormones—steroids and
nonsteroids that consist of amino acids.
n Links to Steroids 2.10, Amino acids 2.11, Proteins
of the plasma membrane 3.4
Hormones come in several chemical forms
Hormones vary in their chemical structure, which affects
how they function. Steroid hormones are lipids derived
from cholesterol. Amino acids or
chains of them are the raw material
of nonsteroid hormones. In this
group are amine hormones (modi-
fied amino acids), peptide hormones
(short amino-acid chains), and pro-
tein hormones (longer amino-acid
chains). Table 15.2 lists some exam-
ples of each.
Regardless of their chemical
makeup, hormones affect cell activi-
ties by binding to protein receptors
of target cells. The signal is then converted into a form that
can work in the cell. Then the cell’s activity changes:
Some hormones cause a target cell to take in more of a
substance, such as glucose. Other hormones stimulate or
inhibit the target cell in ways that alter the rate at which it
makes new proteins or modifies existing proteins or other
structures in the cytoplasm. Sometimes a hormone may
even change a cell’s shape.
It’s important to keep in mind that only cells with recep-
tors for a given hormone will respond to it. For example,
many types of cells have receptors for the hormone cortisol,
so it has widespread effects in the body. If only a few types
signal
received
signal
converted
cell
responds
© Cengage Learning
of cells have receptors for a particular hormone, its effects
in the body will be limited to tissues and organs where
those types of cells are present.
Steroid hormones interact with cell DNA
Steroid hormones are produced by cells in the adrenal
glands and in the primary reproductive organs—ovaries
and testes. Estrogen made in the ovaries and testosterone
made in the testes are good examples.
Figure 15.2A illustrates how a steroid hormone may act.
Being lipid-soluble, it may diffuse directly across the lipid
bilayer of a target cell’s plasma membrane. Once inside the
cytoplasm, the hormone molecule usually moves into the
nucleus and binds to a receptor. In some cases it binds to a
receptor in the cytoplasm, and then the hormone–receptor
complex enters the nucleus. There the complex interacts
with a particular gene—a segment of the cell’s DNA. Genes
carry the instructions for making proteins. By turning
genes on or off, steroid hormones turn protein-making
machinery on or off. This change in a target cell’s activity
is the response to the hormone signal.
Some steroid hormones act in another way. They bind
receptors on cell membranes and change the membrane
properties in ways that affect the target cell’s function.
Thyroid hormones are not chemically the same as steroid
hormones, but they behave the same. So does vitamin D.
Vitamin D meets the definition of a hormone because it is
made in the skin and ultimately arrives via the bloodstream
in the GI tract, where it acts on target cells in ways that
increase the absorption of calcium. En route “raw” vitamin D
(called cholecalciferol) is activated by steps that occur in the
liver and kidneys. Like steroid hormones, activated vitamin
D and thyroid hormones bind with receptors in the nucleus,
so we can consider them as part of this group.
nonsteroid hormones act indirectly,
by way of second messengers
Nonsteroid hormones don’t enter a target cell. Their chemi-
cal makeup makes them water-soluble, and this property
means they can’t cross a target cell’s lipid-rich plasma
membrane. Instead, when this type of hormone binds to
receptors in the plasma membrane, the binding sets in
motion a series of reactions that activate enzymes. These
reactions lead to the target cell’s response.
For instance, consider a liver cell that has receptors for
glucagon, a peptide hormone. As sketched in Figure 15.2B,
this type of receptor spans the plasma membrane and
extends into the cytoplasm. When a receptor binds glucagon,
the cell produces a second messenger. This is a molecule
called cyclic AMP (cyclic adenosine mono phosphate) that
forms in the cytoplasm and relays the incoming hormonal
signal onward. (The hormone itself is the “first messenger.”)
15.2
Steroid Sex hormones (estrogens, progesterone,
hormones testosterone), aldosterone, cortisol
Steroidlike: Vitamin D, thyroid hormones
Amines Melatonin, epinephrine, norepinephrine,
thyroid hormone (thyroxine, triiodothyronine)
Peptides Oxytocin, antidiuretic hormone, calcitonin,
parathyroid hormone
Proteins Growth hormone (somatotropin), insulin,
prolactin, follicle-stimulating hormone,
luteinizing hormone
Table 15.2 Categories of Hormones
and a Few Examples
288 Chapter 15
Copyright 2016 Cengage Learning. All Rights Reserved. May not be copied, scanned, or duplicated, in whole or in part. Due to electronic rights, some third party content may be suppressed from the eBook and/or eChapter(s).