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Hormone Survey: Getting to Know Your Hormones

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Getting to Know Your Hormones Classification of Hormones Classification by System/Function Classification by Source Classification by Structure - Peptide Hormones – PowerPoint PPT presentation

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Title: Hormone Survey: Getting to Know Your Hormones


1
Hormone SurveyGetting to Know Your Hormones
  • Classification of Hormones
  • Classification by System/Function
  • Classification by Source
  • Classification by Structure
  • - Peptide Hormones
  • -Steroid Hormones
  • -Amino Acid Derivatives
  • Classification of Hormone Receptors

2
Some Things to Know about a Hormone
  • Source (what organ/cell produces and/or secretes
    it?)
  • What is its target cell(s)?
  • What is the effect on target cells?
  • What regulates its production/secretion?
  • What type of chemical structure?
  • Details of transport/metabolism?
  • What type of receptor/signal transduction?

3
Learning Objectives Classification of Hormones
by Function
  • Describe the various functions that the endocrine
    system regulates.
  • Become familiar with the range of hormones
    involved in these functions.
  • You are NOT responsible for specific names of
    these hormones yet.

4
Classification of Hormones by Function
  • Reproductive Hormones
  • - estrogens (estradiol), androgens
    (testosterone), progesterone
  • - luteinizing hormone, follicle-stimulating
    hormone, prolactin, oxytocin
  • - inhibin, activin, follistatin
  • - gonadotropin-releasing hormone

5
Classification of Hormones by Function
  • Growth Hormones
  • - Growth hormone (somatotropin)
  • - somatomedins (insulin-like growth factors)
  • - somatostatin, growth hormone-releasing hormone
  • - nerve growth factor, epidermal growth factor,
    fibroblast growth factor, etc.

6

Classification of Hormones by Function
  • Hormones regulating carbohydrate/energy
    metabolism
  • Insulin, glucagon, cortisol, growth hormone,
    epinephrine
  • Hormones regulating general body metabolism -
    thyroid hormone (T3, T4)
  • - thyroid stimulating hormone (TSH, or
    thyrotropin)
  • - thyrotropin-releasing hormone (TRH)

7

Classification of Hormones by Function
  • Hormones involved in stress responses
  • - norepinephrine, epinephrine
  • - cortisol
  • Hormones involved in mineral and water balance
  • - aldosterone, renin, vasopressin
  • - atrial natriuretic peptide

8
Classification of Hormones by Function
  • Regulation of Calcium Metabolism
  • parathyroid hormone, calcitonin, vitamin D,
    others.
  • Regulation of Digestion
  • cholecystokinin, gastrin, secretin, somatostatin
  • Regulation of Blood Formation
  • erythropoietin, erythrocyte differentiation
    factor

9
Classification of Hormones by Source
  • Hypothalamus (brain) acts on the pituitary to
    control the release of pituitary hormones
  • -gonadotropin-releasing hormone (GnRH)
  • -thyrotropin-releasing hormone (TRH)
  • -corticotropin-releasing hormone (CRH)
  • -prolactin-inhibiting factor (probably
    dopamine?)
  • -somatostatin
  • -growth hormone-releasing hormone (GHRH)

10
Classification of Hormones by Source
  • Anterior Pituitary (anterior lobe)
  • - luteinizing hormone (LH)
  • - follicle-stimulating hormone (FSH)
  • - thyroid-stimulating hormone (TSH)
  • - growth hormone (GH or somatotropin)
  • - prolactin (PRL)
  • - adrenal corticotropic hormone (ACTH, or
    corticotropin)

11
Classification of Hormones by Source
  • Posterior Pituitary (posterior lobe)
  • - oxytocin
  • - vasopressin (antidiuretic hormone, ADH)
  • Intermediate Lobe (absent in adult human)
  • - melanocyte-stimulating hormone

12
Classification of Hormones by Source
  • Thyroid gland
  • - thyroid hormones (T3, T4)
  • - calcitonin
  • Parathyroid gland
  • - parathyroid hormone

13
Classification of Hormones by Source
  • Ovary and testis
  • - estrogens, androgens, progesterone
  • - inhibins, activins, follistatin
  • - relaxin
  • Placenta
  • - human chorionic gonadotropin (hCG)
  • - placental lactogen
  • - steroid hormone

14

Classification of Hormones by Source
  • Adrenal cortex
  • - glucocorticoids (cortisol, corticosterone)
  • - mineralocorticoids (aldosterone)
  • - androgens (androstenedione)
  • Adrenal medulla
  • - epinephrine, norepinephrine

15

Classification of Hormones by Source
  • Pancreas (endocrine)
  • - insulin
  • - glucagon
  • Kidney
  • - erythropoietin
  • GI Tract
  • - gastrin
  • - cholecystokinin
  • - secretin
  • - somatostatin
  • Heart
  • - atrial natriuretic peptide

16
Reminder.
  • At this point, do NOT memorize the preceding
    lists of hormone sources and functions.
  • DO understand the following information on
    hormone structure.

17
Classification by Structure
  • Hormones can be classified based on their
    structure as steroid hormones, peptide hormones,
    or amino acid derivatives.
  • The structure of the hormone determines
  • How it is made (gene product cholesterol
    derivative amino acid derivative)
  • How it is transported (binding protein?)
  • How it interacts with receptors on target cells
    (hormone-receptor interactions)

18
Hormone-Receptor Interactions
  • Hormones and receptors bind due to noncovalent
    bonding between them.
  • This also involves a three-dimensional lock and
    key conformation
  • BUT, there is a caveat this analogy breaks
    down
  • Receptor Affinity
  • Receptor Number

19
Hormone-Receptor Interactions
  • Only specific regions of the hormone and receptor
    interact.
  • Some regions determine hormone binding
  • Other regions allow signal transduction
  • Small changes in hormone or receptor structure
    can prevent hormone binding and/or hormone
    activity

20
Peptide Hormones Water Soluble Gene Products
  • Recall that proteins are gene products
  • gene (DNA)
  • transcription
  • mRNA
  • translation
  • protein

21
Structure of Peptide Hormones
  • Proteins are made up of amino acids, connected to
    each other by peptide bonds.
  • Peptide hormones may be very short (three amino
    acids) to very long (over one hundred amino
    acids) in length.
  • They typically have an amino terminus (NH2) and a
    carboxyl terminus (-COOH).

NH2
COOH
22
Structure of Peptide Hormones
  • Peptides have primary, secondary, tertiary, and
    quaternary structure

23

Peptide Hormones Subunit Structure
  • Peptide hormones may consist of two subunits
    joined together, usually by disulfide bonds at
    cysteine residues.
  • Example LH, FSH and TSH are composed of a
    common alpha subunit, and distinct beta subunits

24
Peptide Hormones
  • The shape of peptide hormones may be influenced
    by and strengthened by disulfide bridges.
  • Peptides may also form ring structures, such as
    oxytocin.

25

Peptide Hormones Glycosylation
  • Peptide hormones may be glycosylated (have
    carbohydrate side chains).
  • This glycosylation can affect
  • - assembly of hormone subunits
  • - secretion from the endocrine cell
  • - clearance of the hormone from the circulation
  • - biological activity (receptor binding and
    biological response of the target cell)

26

Peptide Hormones Species Homology
  • The primary amino acid sequence of peptide
    hormones may differ slightly from species to
    species. Hormones obtained from one species may
    not necessarily interact with receptors for
    hormones of a different species.
  • Example The human FSH receptor does not
    respond well to FSH from other species.

27
Endocrine Bioinformatics
  • Bioinformatics The utilization of information
    (ie, databases) to solve biological problems.
  • Example Suppose you were studying the hormone
    prolactin, and wanted to see what chromosome it
    was located on, and if there were any
    undiscovered hormones which were similar in
    structure.
  • Approach Compare the human prolactin sequence to
    the human genome database at
  • http//www.ncbi.nlm.nih.gov/genome/seq/HsBlast.htm
    l

28
Actions of Peptide Hormones
  • The effects of peptide hormones are relatively
    quick, but short-lived.

29
Half-life of Peptide Hormones
  • The half-life of peptide hormones in the
    circulation is relatively short (water soluble,
    no binding proteins).

- Fares et al., 1992
30
Steroid Hormones
  • Steroid hormones are NOT made up of amino acids.
    They have a characteristic four ring structure,
    derived from cholesterol

Examples estrogens, androgens, progesterone,
cortisol, aldosterone
31

Characteristics of Steroid Hormones
  • Steroid hormones are not glycosylated.
  • The structure of steroid hormones is the same in
    all species (estradiol in rats is the same as
    estradiol in humans).
  • Is there a gene for testosterone? How is
    testosterone made? How is its production
    regulated?

32
Characteristics of Steroid Hormones
  • Steroid hormones have more gradual and
    long-lasting effects than peptide hormones (in
    general).

33
Characteristics of Steroid Hormones
  • Steroid hormones have a relatively longer half
    life in the circulation (in general, compared
    with peptide hormones) reflects plasma binding
    proteins.

34
Amino Acid Derivatives (Amines)
  • There are other hormones which are not steroids
    and not peptides, but are derived from amino acid
    precursors.
  • Epinephrine (adrenaline) Derived from tyrosine.

35

Amino Acid Derivatives
  • Thyroid hormones (triiodothyronine, thyroxine)
    are also produced from tyrosine.
  • In this case, get lipid soluble hormones (not
    water soluble)

36
Water soluble hormones
Lipid soluble hormones
gene mRNA peptide hormones
synthesis
synthesis
stimulus
amino acid derivatives (epinephrine, norepinephrin
e)
cholesterol steroid hormone
amino acid derivative (thyroid hormone)
secretion
storage
diffusion
secretion
free hormone
free hormone
binding protein
Hormone Level
Hormone Level
Time
Time
plasma membrane receptors
ion flux
target DNA
second messengers (cAMP, cGMP)
phosphorylation
mRNA
protein
cellular response
cellular response
37
Types of receptors
  • Receptors for the water soluble hormones are
    found on the surface of the target cell, on the
    plasma membrane.
  • These types of receptors are coupled to various
    second messenger systems which mediate the action
    of the hormone in the target cell.
  • Receptors for the lipid soluble hormones reside
    in the nucleus (and sometimes the cytoplasm) of
    the target cell.
  • Because these hormones can diffuse through the
    lipid bilayer of the plasma membrane, their
    receptors are located on the interior of the
    target cell

38
Hormones and their receptors
39
Second messenger systems
  • Receptors for the water soluble hormones are
    found on the surface of the target cell, on the
    plasma membrane. These types of receptors are
    coupled to various second messenger systems which
    mediate the action of the hormone in the target
    cell

40
Second messengers for cell-surface receptors
  • Second messenger systems include
  • Adenylate cyclase which catalyzes the conversion
    of ATP to cyclic AMP
  • Guanylate cyclase which catalyzes the conversion
    of GMP to cyclic GMP (cyclic AMP and cyclic GMP
    are known collectively as cyclic nucleotides)
  • Calcium and calmodulin phospholipase C which
    catalyzes phosphoinositide turnover producing
    inositol phosphates and diacyl glycerol.

41
Types of receptors
42
Second messenger systems
  • Each of these second messenger systems activates
    a specific protein kinase enzyme.
  • These include cyclic nucleotide-dependent protein
    kinases
  • Calcium/calmodulin-dependent protein kinase, and
    protein kinase C which depends on diacyl glycerol
    binding for activation.
  • Protein kinase C activity is further increased by
    calcium which is released by the action of
    inositol phosphates.

43
Second messenger systems
  • The generation of second messengers and
    activation of specific protein kinases results in
    changes in the activity of the target cell which
    characterizes the response that the hormone
    evokes.
  • Changes evoked by the actions of second
    messengers are usually rapid

44
Signal transduction mechanisms of hormones
45
Cell surface receptor action
46
G-protein coupled receptors
Adenylate cyclase, cAMP and PKA
47
Amplification via 2nd messenger
48
Transmembrane kinase-linked receptors
  • Certain receptors have intrinsic kinase activity.
    These include receptors for growth factors,
    insulin etc. Receptors for growth factors
    usually have intrinsic tyrosine kinase activity
  • Other tyrosine-kinase associated receptor, such
    as those for Growth Hormone, Prolactin and the
    cytokines, do not have intrinsic kinase activity,
    but activate soluble, intracellular kinases such
    as the Jak kinases.
  • In addition, a newly described class of receptors
    have intrinsic serine/threonine kinase
    activitythis class includes receptors for
    inhibin, activin, TGFb, and Mullerian Inhibitory
    Factor (MIF).

49
Protein tyrosine kinase receptors
50
Receptors for lipid-soluble hormones reside
within the cell
  • Because these hormones can diffuse through the
    lipid bilayer of the plasma membrane, their
    receptors are located on the interior of the
    target cell.
  • The lipid soluble hormone diffuses into the cell
    and binds to the receptor which undergoes a
    conformational change. The receptor-hormone
    complex is then binds to specific DNA sequences
    called response elements.
  • These DNA sequences are in the regulatory regions
    of genes.

51
Receptors for lipid-soluble hormones reside
within the cell
  • The receptor-hormone complex binds to the
    regulatory region of the gene and changes the
    expression of that gene.
  • In most cases binding of receptor-hormone
    complex to the gene stimulating the transcription
    of messenger RNA.
  • The messenger RNA travels to the cytoplasm where
    it is translated into protein. The translated
    proteins that are produced participate in the
    response that is evoked by the hormone in the
    target cell
  • Responses evoked by lipid soluble hormones are
    usually SLOW, requiring transcription/translation
    to evoke physiological responses.

52
Mechanism of lipid soluble hormone action
53
Receptor control mechanisms
  • Hormonally induced negative regulation of
    receptors is referred to as homologous-desensitiza
    tion
  • This homeostatic mechanism protects from toxic
    effects of hormone excess.
  • Heterologous desensitization occurs when exposure
    of the cell to one agonist reduces the
    responsiveness of the cell any other agonist that
    acts through a different receptor.
  • This most commonly occurs through receptors that
    act through the adenylyl cyclase system.
  • Heterologous desensitization results in a broad
    pattern of refractoriness with slower onset than
    homologous desensitization
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