Endocrinology_TEXT1 PDF

Summary

This document provides a summary of the endocrine system, including concepts like homeostasis and the interactions between various hormones and glands. It also covers different types of intercellular signals, hormonal secretion, and their roles in the body.

Full Transcript

Homeostasis
Nervous System
Acts Rapidly (in milliseconds), but Short-lived
Messenger = Electrical Signals → Neurotransmitters
Very Specific receptor organs at the end of each neuron
May Stim/Inh release of Hormones
Primarily cause Musc. Ctx & secretion of fluids from glands

Endocrine System
Acts Slowly (seconds to hours), but Long-lived
Messenger = Hormones (Chemicals)
Less Specific via Blood Stream to all Body cells
Some hormones may Stim/Inh Nerve impulses
Some hormones (Epi./NE) may be Neurotransmitters also and act in
other target cells
 Basic Concepts of
Endocrine System
Functions to keep the body in Homeostasis

A state of equilibrium

Keeps the body in a steady & balanced state so that
the body systems can function optimally

Involves:
Body fluids
Acid-base balance
Temperature
Metabolism
Other factors
 Endocrine Organs
Hypothalamus Thymus

Pineal Gland Pancreas

Pituitary Gland Adrenal (Suprarenal) Glands
Posterior Pituitary Adrenal Cortex
Anterior Pituitary Adrenal Medulla

Thyroid Gland Ovaries

Parathyroid Glands Testes
Hypothalamic-Pituitary-Target gland
Axis
Hypothalamus
Produces Releasing and Inhibiting Hormones
Stimulates Anterior Pituitary Gland

Anterior Pituitary Gland
Produces Stimulating Hormones
Stimulates different “Target Organs”

“Target Organs”
Release their own Hormones
 Intercellular Chemical Signals
Hormones
Released by endocrine glands
Enter circulatory system
Affect distant cells
Ex.: Estrogen

Autocrine
Released by cells and have a local effect on same cell type from
which chemical signals released
Do NOT enter the blood
Ex.: Prostaglandin

Paracrine
Released by cells and affect other neighborly cell types locally
without being transported in blood
Ex.: Somatostatin
 Pheromones
Secreted into environment and modify behavior and physiology
Ex.: Sex pheromones

Neurohormone
Produced by neurons and function like hormones
Mostly from Post. Pituitary Gland
Ex.: Oxytocin & ADH

Neurotransmitter or Neuromodulator
Produced by neurons
Secreted into extracellular spaces by presynaptic nerve terminals
Travels short distances
Influences postsynaptic cells
Ex.: Acetylcholine.
Locally-acting Chemicals
– Do NOT enter the Blood
Paracrine (“Para” = near)
– Act upon cells next to secreting cells
Autocrine (“Auto” = self)
– Act upon the cell that secreted it

In contrast…
Other hormones may circulate for hrs & their
effect being lost once inactivated or secreted
 Hormonal Secretion

3 Patterns of Regulation of Hormone Secretion

1. Neural
via Autonomic Nervous System (Ex.: Stress)

2. Non-Hormonal
via concentration of a substance (Ex.: Glucose)

3. Hormonal
via concentration of a hormone (Ex.: Thyroid hormones)
 1. Nervous System Regulation
Stimuli such as stress or
exercise activate the
sympathetic division of the
autonomic nervous system

Sympathetic neurons stimulate
the release of epinephrine and
smaller amounts of
norepinephrine from the
adrenal medulla. Epinephrine
and norepinephrine prepare the
body to respond to stressful
conditions.

Once the stressful stimuli are
removed, less epinephrine is
released as a result of
decreased stimulation from the
autonomic nervous system.
2. Action of Substance Other Than Hormone
An increased blood
glucose concentration
stimulates increased
insulin secretion from
the pancreas

Insulin increases
glucose uptake by
tissues, which
decreases blood
glucose levels.

Autonomic nervous
system also influences
insulin secretion
 3. Hormonal Regulation

Negative and Positive Feedback

At each level of the HPT Axis

Prevents Over-secretion of any hormone

Acts like a “Thermostat” of a house
Stimulation (+)
Inhibition (-)
Homeostasis

Values of variables fluctuate around a SET POINT

This determines a normal range of values

SET POINT
Desired value

What is the set point for Body Temperature?
Negative Feedback
Any deviation ( or ) from the set point is made SMALLER
(ie.: Returning to normalcy)

This occurs mostly in the body

Positive Feedback
Any deviation ( or ) from the set point is made GREATER
(ie.: Going further away from normalcy)

Not so common in the body
 Transport & Distribution

Hormones dissolve in blood

2 forms in bloodstream
1. Free Form
2. Bound to Binding Protein, reversibly

Equilibrium of 2 forms

Hormones distributed quickly thru body because
they are in the blood
Free Form
Diffuse thru Capillary wall into Interstitial Fluid
Follows concentration gradient

Lipid-soluble Hormones
Diffuse easily thru Capillary Cells
Water-soluble Hormones
Must pass thru Capillary Fenestrae

Bound Form
Reversibly bound as a “Reserve” on Binding Proteins
(In Proteinuria, the Pt will lose these binding proteins in
his urine and thus the hormone bound to them)
Hormone/Target Cell Interaction
Ligand
Anything that binds to a receptor
ie.: A Hormone is a Ligand

Binding Site
Where the Ligand binds to
ie.: A Receptor Site is a Binding Site

Ligand/Binding Site
A proper connection will elicit a response by the Target Cell
VERY SPECIFIC
ie.: GH cannot bind to an Oxytocin Receptor site
 Target Cells
Highly specific receptors (proteins or glycoproteins)

Geometry of receptors complement specific hormone
Like a “Lock & Key” fit

Up Regulation -  Sensitivity when
Low Hormone level

Down Regulation -  Sensitivity when
High Hormone level
 Receptors for Hormones

Receptors for Catecholamines & Peptide
Hormones are in the cell membranes of
target cells

Thyroid & Steroid Hormones cross the
membrane and bind to receptors in the
cytoplasm or nucleus
 Classes of Receptors
Membrane-bound Receptors
Integral proteins with receptor site at cell surface
These do NOT enter cell

Interact with ligands that cannot pass through the
plasma membrane

Involves a 2nd Messenger within the cell
a “Chain Reaction” occurs

Ligands:
– Water-soluble, Larger ligands, etc.
Protein Hormones
Polypeptide Hormones
Catecholamines (Epi/NE)
Intracellular Receptors
In cytoplasm or in the nucleus
These DO enter cell

Interact with ligands that can pass through the plasma
membrane

Ligands:
– Lipid-soluble, Smaller ligands, etc.
Steroid Hormones
Thyroid Hormones
 Membrane-bound Receptors
Ligand binds reversibly

1 of 2 Cascade of Events occurs:

1. Activation of G proteins
 cAMP, Ca2+, Diacylglycerol (DAG) or Inositol Triphosphate (IP3)

2. Receptors Alter Activity of Intracellular Enzymes Directly
 cGMP, Nitric oxide, or Ca2+
 1. Activation of G Proteins
Cascade of Events for  cAMP:
1. Hormone (1st Messenger) binds to “Surface Receptor”
2. This then binds to a G protein in the cell
3. The G protein is then activated as it binds GTP, displacing GDP
4. Adenylate Cyclase is activated
5. This produces cAMP (2nd Messenger) in cell
6. cAMP binds to Protein Kinase
7. Phosphorylation occurs on certain Proteins (requires ATP)
8. Activation of those Proteins occurs
(ie.: the protein is made in response to what hormone “told” the cell)

– 1 hormone molecule will activate a chain of cascades resulting
in millions of activated proteins which, in turn, make billions
of the substance the protein is suppose to release

This is why it responds RAPIDLY !!!!
Other 2nd Messengers:
Ca2+
Diacylglycerol (DAG)
Inositol Triphosphate (IP3)

Understand cAMP’s mechanism (illustrated in the past few slides)
Don’t worry about the mechanisms of other 2nd messengers

You can view the next 3 Diagrams to see how other 2nd
messenger mechanisms occur……
Notice the chain of events BEFORE the 2nd messenger begins are the
same as with cAMP’s mechanism
2. Receptors that Directly Alter the
Activity of Intracellular Enzymes
(Simpler Cascade as G-Protein is NOT involved)

Cascade of Events for  cGMP
1. Hormone (1st Messenger) binds to “Surface Receptor”
2. The inner portion of this receptor activates Guanylate cyclase
3. This converts GTP to cGMP (2nd Messenger)
4. cGMP acts on certain Proteins
5. Activation of those Proteins occurs

Phosphodiesterase inactivates cGMP to GMP

This Pathway also responds RAPIDLY !!!!
 Intracellular Receptors
Thyroid & Steroid Hormones
> 90% are bound to proteins in blood

These hormones diffuse into target cells

Binds to DNA in Nucleus
A specific mRNA is made and synthesizes a certain protein that the
hormone “tells” the target cell to make

There is no amplification
(ie.: 1 structure does not tell 4 structures what to do at the same time)

This is why it responds SLOWLY !!!
 Hypothalamus

(Neural Functions)
Coordinates HR, BP & Resp. rate from:
Pons
Medulla oblongata
Regulates:
Temperature
Hunger / Thirst
Sleep

Endocrine Functions………
Where the Nervous & Endocrine Systems interact

Releasing & Inhibiting Hormones
7 Major Hormones
(Ex. TRH, GnRH, PIH, etc.)
Synthesized, Stored AND Secreted by Hypothalamus
Target Organ is Anterior Pituitary Gland

ADH & Oxytocin
Synthesized by Hypothalamus
Stored & Secreted by Posterior Pituitary Gland
May still find their way into the bloodstream if the Posterior Pituitary
Gland is compromised since they are still both synthesized
 Pineal Gland (Body)

Circadium Rhythm
Biological Clock
“Jet Lag” issue

Releases Melatonin (NOT Melanin)
Daylight (-) / Darkness (+)
May control Onset of Puberty??
Melatonin ’s during puberty
Pituitary Gland (Hypophysis)

“The Master Gland”

Sits in Sella Turcica
Bony “cup” in the sphenoid bone
Actually Two (2) Glands:

1. Anterior Pituitary Gland (Adenohypophysis)
– Synthesizes, Stores & Secretes 7 Major Hormones from itself
into bloodstream
– 75% of Pituitary
– Evolved from floor of mouth (Rathke’s Pouch)

2. Posterior Pituitary Gland (Neurohypophysis)
– Stores and Secretes 2 hormones
(*** These are actually synthesized in Hypothalamus)
– Evolved from base of brain
An “Extension” of the Hypothalamus via Infundibulum
 Anterior Pituitary Gland
(Histology)
Acidophils (Pinkish)
Cells that contain Polypeptide Hormones
Somatotropes which produce GH
Lactotropes which produce PRL

Basophils (Bluish)
Cells that contain Glycoprotein Hormones
Thyrotropes which produce TSH
Gonadotropes which produce LH or FSH
Corticotropes which produce ACTH

Chromophobes (Colorless)
These are cells that have minimal or no hormonal content
Anterior Pituitary Gland Hormones
Thyroid Stimulating Hormone (TSH)
Stimulates thyroid gland to secrete thyroid hormones (T 3 & T4)

Growth Hormone (GH)
Stimulates most tissues to grow

Adrenocorticotropic Hormone (ACTH)
Stimulates adrenal (cortex) gland to secrete its hormones (mostly Cortisol)

Follicle Stimulating Hormone (FSH)
Stimulates follicles (egg sacs) to grow in ovaries
Stimulates sperm production in testicles

Luteinizing Hormone (LH)
Releases progesterone from ovaries AND Triggers ovulation (release of egg from ovary)
Releases testosterone from testicles

Prolactin (PRL)
Stimulates breasts to make milk

Melanocyte Stimulating Hormone (MSH)
Stimulates melanocytes to secrete melanin
 Posterior Pituitary Gland
(Histology)

Neuroglia
Pituicytes

Nerve fibers (Axons)

Fenestrated Capillaries
“Little holes” to allow the hormones to enter blood
Posterior Pituitary Gland Hormones

Anti-Diuretic Hormone (ADH)

 Urine →  Blood volume →  BP

Oxytocin (OXY)

Ejects milk from breasts
Contracts uterus during labor
 ANTERIOR Pituitary Gland

Tropic Hormones (Tropins)

All Anterior Pituitary Hormones are tropins

Regulate hormone secretions of target endocrine tissues
 ANTERIOR Pituitary Gland

1. Growth Hormone (GH)
(a.k.a. Somatotropin)

*** Stimulates Cell Growth in all body cells

(Increases Height & Weight in Puberty)
Excess
– (Symptoms differ if Growth plates are fused or not)

Gigantism
– (In Children)
– Symmetrical growth of long bones
Growth plates are NOT fused yet

Acromegaly
– (In Adults)
– Facial features become wider & enlarged
Growth plates are already fused
– Enlarged Hands, Face & Jaw
– HTN
– Death due to Heart Failure
Pituitary Gland lies adjacent to
Optic Chiasm

Large Pituitary Tumor can
press against Optic Chiasm

Causes “Tunnel Vision”
(Bitemporal Hemianopsia)

(Inferior View)
 Deficiency
– Pituitary Dwarfism
(In Children)
Short stature, but with normal body proportions
Growth plates are NOT fused yet

NOTE: Not all causes of Dwarfism are due to GH deficiency.
 Dwarfism
ACHONDROPLASIA
– (m.c. form of Dwarfism (70%))

Long bones stop growing in childhood
Normal torso, short limbs

Failure of cartilage growth in Epiphyseal Plate

Spontaneous mutation produces mutant dominant allele

PITUITARY DWARFISM
Lack of Growth Hormone (GH)

Normal proportions with short stature
2. Thyroid Stimulating Hormone (TSH)
(a.k.a. Thyrotropin)

Stimulates Thyroid gland to secrete Thyroid Hormones

T3
T4
3. Adrenocorticotropic Hormone (ACTH)

Stimulates Adrenal (Cortex) gland to secrete 3 Hormones:

Aldosterone
Cortisol
Androgens (Sex Steroids (Testosterone & Estrogen))

Binds directly to Melanocytes and releases Melanin
4. Follicle Stimulating Hormone (FSH)

In Females (acts on Ovaries)
Develops Follicles
Produces Mature Ova
Secretes Estrogen

In Males (acts on Testes)
Stimulates Production of Sperm
5. Luteinizing Hormone (LH)

In Females (acts on Ovaries)
Triggers Ovulation
Stimulates Corpus Luteum to secrete Progesterone
(Corpus Luteum → ruptured site where egg was released)

In Males (acts on Testes)
Secretes Testosterone
6. Prolactin (PRL)

Stimulates the Development of Milk Glands
(During Puberty)

Stimulates the Production of Milk
(During Pregnancy)
7. Melanocyte Stimulating Hormone (MSH)

Not truly a significant hormone

NOT produced in adults

In Pregnancy:
Stimulates Melanocytes in skin to release Melanin
(Produces Pigmentation in face & Abdomen)

ACTH also stimulates Melanocytes
 POSTERIOR Pituitary Gland

1. Antidiuretic Hormone (ADH, Vasopressin)

Reabsorbs H2O from Kidneys

 Urine Volume →  Blood volume →  BP

 Vasoconstriction →  BV Diameter →  BP
Excess
Syndrome of Inappropriate ADH (SIADH)

– Lung Cancer (m.c.c.) → Produces an ADH-like hormone

   Urine →    Blood volume → HTN
   Vasoconstriction →    BV Diameter → HTN

Deficiency
Diabetes Insipidus (DI)

   Urine →    Blood volume → HYPOtension
VERY Rare

POLYDIPSIA = Increase in Thirst
POLYURIA = Increase in Urine output
2. Oxytocin

Stimulates Uterus to contract
Begins labor

Stimulates the Release of Milk (Lactation)
When baby cries or sucks