22 results in An Introduction to Neuroendocrinology
5 - Neurotransmitters
- Michael Wilkinson, Dalhousie University, Nova Scotia, Richard E. Brown, Dalhousie University, Nova Scotia
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Summary
In general terms, neurons communicate with each other through chemical messengers called neurotransmitters. Given the complexity of the brain, it should not be surprising that there are more than 100 known neurotransmitters (Purves et al. 2008). Neurotransmitters are synthesized in nerve cells, sometimes using precursors from the diet (e.g. tyrosine; see Figure 5.8), and are released into the synapse where they bind to specific receptors located on the postsynaptic cell. As discussed in the present chapter, this simple view conceals the many fascinating ways in which neurons communicate with each other. This chapter focuses on the different categories of neurotransmitters, the synthesis, storage, transport and release of neurotransmitters, their action at receptors and their deactivation. The influence of drugs on neurotransmitter function will also be discussed. Chapter 6 examines the specific effects of neurotransmitters in the neuroendocrine system, and Chapter 10 covers the actions of neurotransmitters at their receptors on postsynaptic cells.
The neuron and the synapse
A typical neuron is shown in Figure 5.1. Neurons possess a cell body, which contains the nucleus, and the characteristic dendrites plus an axon. The dendrites receive messages from other cells onto their spines and shafts, while the axon transmits information to other cells. Although each nerve cell has only one axon, this axon may have a number of branches and the nerve terminals at the end of each branch can form synapses with other neurons.
Nerve cells communicate with each other by the release of neurotransmitters from the nerve terminals of the axon into the synapse, the space that separates the presynaptic and postsynaptic cells. Neurotransmitters released into the synapse then bind to their receptors on the postsynaptic cell. As shown in Figure 5.1, synapses can form between the axon of the presynaptic cell and a number of different sites on the postsynaptic cell, including the shafts and/or spines of dendrites (axodendritic synapses), the cell body (axosomatic synapses) and the axons (axoaxonic synapses).
10 - Receptors for peptide hormones, neuropeptides and neurotransmitters
- Michael Wilkinson, Dalhousie University, Nova Scotia, Richard E. Brown, Dalhousie University, Nova Scotia
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Summary
Peptide hormones, neuropeptides, neurotransmitters and other non-steroid chemical messengers regulate cellular and biochemical activity by binding to receptors located in the plasma membranes of their target cells. These chemical messengers are generally polar and water soluble and so cannot readily enter their target cells to influence the cell nucleus in the manner described for steroid and thyroid hormones (Chapter 9). In order to induce biochemical changes within the target cell, they act as first messengers to activate a second messenger, such as cAMP, within the cytoplasm of the target cell. The transduction of information from the first to the second messenger is accomplished through the activation of membrane protein transducers (G proteins) and enzymes, such as adenylate cyclase. This chapter discusses membrane receptors for peptide hormones and neurotransmitters, the mechanisms by which signal transduction across the cell membrane occurs, the role of G proteins and receptor tyrosine kinases in this signal transduction, the second messenger systems activated, and the actions of the second messengers in the target cells, with special emphasis on neural target cells.
Some of this material was introduced in Chapter 5 and we will refer to relevant figures where appropriate.
Membrane receptors
Membrane receptors are complex proteins embedded in the cell membrane. The function of these receptors is to recognize specific ligands in the blood (e.g. peptide hormones, neuropeptides) or in the synapse (e.g. neurotransmitters) and bind to them. Once this binding occurs, signal transduction across the cell membrane occurs as described in section 10.2 below. As noted in the description of steroid hormone receptors, modern techniques of immunohistochemistry (using antibodies to receptor proteins) and in situ hybridization (allowing visualization of peptide mRNA) permit the ready localization of membrane receptors in any tissue of interest. Gene cloning and sequencing techniques enabled molecular biologists to develop three-dimensional models of many membrane receptors. There are three distinct types of membrane receptor: (1) ligand-gated ion channel receptors; (2) guanine nucleotide binding protein (G-protein-) coupled receptors; and (3) transmembrane-regulated tyrosine kinases.
6 - Neurotransmitter and neuropeptide control of hypothalamic, pituitary and other hormones
- Michael Wilkinson, Dalhousie University, Nova Scotia, Richard E. Brown, Dalhousie University, Nova Scotia
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Summary
Previous chapters have discussed the endocrine glands and their hormones (Chapter 2), the hormones of the pituitary gland (Chapter 3), the hypothalamic hormones (Chapter 4) and neurotransmitters (Chapter 5). This chapter will describe how neurotransmitters influence the release of hypothalamic and pituitary hormones and the hormones of the adrenal medulla, pancreas, thymus and gastrointestinal tract. It will also examine the electrophy-siological properties of neurosecretory cells and the effects of drugs on the release of neurohormones.
The cascade of chemical messengers
As shown in Figure 6.1, and using the adrenal gland as an example, there is a cascade of chemical messengers that regulate target tissue function from the brain to the endocrine glands. For example, neurons release a neurotransmitter that regulates the secretion of neurohormones (such as CRH) from hypothalamic neurosecretory cells. These hypothalamic hormones stimulate the cells of the adenohypophysis (anterior pituitary) to synthesize and release their hormones. Many pituitary hormones, such as ACTH, act on endocrine target cells, such as the adrenal cortex, causing them to synthesize and release their own hormones (e.g. cortisol) which then stimulate biochemical changes in target cells elsewhere in the body, including the brain. In each step of this pathway, the individual neurotransmitters and peptide hormones bind to membrane receptors that activate a second messenger, such as cAMP, within the target cell (see Chapter 10). Steroid hormones (such as cortisol) act on receptors located inside the target cells (see Chapter 9). This chapter describes the effects of neurotransmitters on hypothalamic neurosecretory cells.
Neural control of hypothalamic neurosecretory cells
6.2.1 Neural input to the endocrine hypothalamus
Figure 4.1 illustrates the different nuclei of the hypothalamus, many of which have neurons, or nerve terminals, which release a variety of neurotransmitters including GABA, glutamate, kisspeptin, opioids, dopamine, norepinephrine and serotonin. These neurotransmitters all bind to receptors on hypothalamic neurosecretory cells. This chapter describes the magnocellular hypothalamic neurosecretory cells of the paraventricular and supraoptic nuclei (PVN and SON), whose axons terminate in the posterior pituitary, and the parvicellular hypothalamic neurosecretory cells, whose axons terminate in the median eminence (see Figure 3.1).
15 - An overview of behavioral neuroendocrinology: present, past and future
- Michael Wilkinson, Dalhousie University, Nova Scotia, Richard E. Brown, Dalhousie University, Nova Scotia
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The aim of this book
The aim of this book is to introduce students to the language and concepts of neuroendocrinology, including how the neuroendocrine system influences behavior. It began with a consideration of the many chemical messengers in the body, classified as “true” hormones, neurohormones, neurotransmitters, pheromones, parahormones, prohormones, growth factors, cytokines, adipokines, vitamins and neuropeptides. As more became known about the neuroendocrine system, it became clear that these classifications are not unambiguous and a single chemical might fit into two or more classes of messenger and perform different functions. This means that while the classification of chemical messengers is useful to begin the study of neuroendocrinology, by the end it provides little help in understanding the different actions of peptides, steroids, neuropeptides and neurotransmitters on different target cells, even within the same tissue.
The hormones of the endocrine and pituitary glands are generally accepted as the major components of the neuroendocrine system. However, the traditional endocrine function of hormones being released into the bloodstream to act on peripheral target cells represents only a small part of the neuroendocrine activity of hormones such as testosterone, cholecystokinin or somatostatin. These hormones also have significant effects in the brain, via specific receptors, and can alter neural regulation of autonomic reflexes, behavior and emotional states. The hypothalamus provides the link between the brain and the traditional endocrine system and provides the locus for external factors, such as environmental influences, to regulate endocrine target organs. Thus, while the endocrine system consists of a number of closed-loop feedback systems that maintain homeostatic control over the synthesis, storage, release and deactivation of hormones, external stimuli can alter these systems. For example, environmental stimuli, social interactions and cognitive factors can greatly alter the functioning of the endocrine system by altering the neurotransmitter/neuropeptide pathways that regulate the release of hypothalamic hormones.
Acknowledgements
- Michael Wilkinson, Dalhousie University, Nova Scotia, Richard E. Brown, Dalhousie University, Nova Scotia
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8 - Regulation of hormone levels in the bloodstream
- Michael Wilkinson, Dalhousie University, Nova Scotia, Richard E. Brown, Dalhousie University, Nova Scotia
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As illustrated in Figures 6.5 and 6.11, pituitary (LH, FSH and ACTH) and steroid (cortisol) hormone levels in the bloodstream fluctuate dramatically over short periods of time (minutes to hours). In addition, hormones such as GH, ACTH and melatonin show marked circadian variations in their secretion patterns (Figure 6.5). These patterns are physiologically important; for example, we saw in the case of LH secretion, a continuous release, rather than a pulsatile secretion, will not stimulate the ovaries or testes correctly (Figure 7.4). In other words, fertility is dependent on an appropriate pulsatile LH signal reaching the gonads. This principle might be generally applicable to all pituitary hormone secretions. The measurement, or assay, of hormone levels is therefore an important clinical goal, as well as a crucial aid in understanding how hormone levels in blood are regulated and how the neuroendocrine system functions in health and disease. This chapter thus begins with an examination of the methods for measuring hormone levels in the circulation.
Analysis of hormone levels
The level of a circulating hormone can be measured directly in blood samples or estimated by measuring hormone levels in the saliva, urine or feces, measuring urinary metabolites, or by using bioassays. The determination of glucocorticoids levels in hair, for example, is a way to detect long-term exposure to stress.
8.1.1 Direct measurement of circulating hormones
In the past 20 years, there have been striking changes in the analytical techniques used to estimate hormone levels. Until recently, the benchmark in determination of hormone levels was the radioimmunoassay. However, this method, employing antibodies specific to each hormone, and radioactively labeled hormones, is slow, labor-intensive and raised safety problems in the use and disposal of radioactive materials. It is now routine to analyze hormone levels using rapid and automated chemiluminescent or immunometric assays that produce data in a matter of hours, rather than days.
A widely used assay is the Enzyme-linked Immunosorbent Assay (ELISA).
3 - The pituitary gland and its hormones
- Michael Wilkinson, Dalhousie University, Nova Scotia, Richard E. Brown, Dalhousie University, Nova Scotia
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The pituitary gland
The pituitary gland, which is also called the hypophysis, is attached to the hypothalamus at the base of the brain (Figure 3.1). Secretion of the hormones of the pituitary gland is regulated by the hypothalamus and it is through the hypothalamic-pituitary connection that external and internal stimuli can influence the release of the pituitary hormones, thus producing the neural-endocrine interaction. The pituitary has been called the body's “master gland” because its hormonal secretions stimulate a variety of endocrine glands to synthesize and secrete their own hormones. However, it is really the hypothalamus that is the master gland, because it controls the pituitary.
The pituitary gland consists of two primary organs: the anterior pituitary (adenohypophysis or pars distalis) which is a true endocrine gland, and the posterior pituitary (neurohypophysis) which is formed from neural tissue and is an extension of the hypothalamus (Figure 3.1). The pituitary gland is attached to the hypothalamus by the pituitary (hypophyseal) stalk. Further details of the anatomy and physiology of the pituitary gland can be found elsewhere (Norman and Litwack 1997; Amar and Weiss 2003; Boron and Boulpaep 2005; Gardner and Shoback 2011).
The neurohypophysis (posterior pituitary)
The neurohypophysis consists of neural tissue and contains the nerve terminals (about 100,000) of axons whose cell bodies are located in the paraventricular nucleus (PVN) and supraoptic nucleus (SON) of the hypothalamus. The axons of these large magnocellular neurosecretory cells project down from the hypothalamus through the part of the pituitary stalk called the infundibulum and terminate in the posterior pituitary gland (Figure 3.2). The neurosecretory cells of the PVN and SON manufacture the hormones oxytocin and vasopressin (also called antidiuretic hormone, ADH), which are transported down the axons and stored in nerve terminals in the posterior pituitary. The axon terminals in the posterior pituitary are surrounded by supporting cells called pituicytes.
Dedication
- Michael Wilkinson, Dalhousie University, Nova Scotia, Richard E. Brown, Dalhousie University, Nova Scotia
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Preface to the second edition
- Michael Wilkinson, Dalhousie University, Nova Scotia, Richard E. Brown, Dalhousie University, Nova Scotia
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In this second edition of An Introduction to Neuroendocrinology, we have rewritten and greatly extended the original content. The revised text includes entirely new reference lists and a complete new set of illustrations. The book reflects the many advances that have occurred in the study of neuroendocrinology during the past 20 years. Nevertheless, and although the text is based largely on modern references, our primary aim is to provide an introductory description of mammalian neuroendocrine control systems. Several books are available that cover this topical and clinically relevant field, but, although valuable, these tend to be advanced texts of the edited, multi-author type. Our book is designed to provide the basic principles necessary to understand how the brain controls, and responds to, the endocrine hormones. It will be suitable for a variety of different students and especially those who might not have been previously exposed to a focused course in neuroendocrinology. Thus, students in psychology, biology and science should be able to master much of the basic material. However, the book is also highly appropriate for honors students and first-year graduate students in physiology, anatomy, neuroscience and medicine. This book is therefore designed for students in two levels of classes: introductory classes, in which all of the material will be new to the student, and more advanced classes, in which the students will be familiar with many of the terms and concepts through courses in biology, physiology, psychology or neuroscience, but who have not studied neuroendocrinology as an integrated discipline.
This book offers an overall outline of the neuroendocrine system and will provide the vocabulary necessary to understand the interaction between hormones and the brain. In addition, we provide a concise description of those topics that must underpin any attempt to learn, and to teach, neuroendocrinology. For example, there are chapters on basic neuroscience (neurotransmitters and neuropeptides), the physiology of the endocrine glands (hormones), receptors and receptor signaling mechanisms (e.g. G proteins; nuclear receptors), hormone assay and gene expression techniques (e.g. ELISA; in situ hybridization) and a description of the immune system, with particular emphasis on the integration of immune and neuroendocrine pathways.
Index
- Michael Wilkinson, Dalhousie University, Nova Scotia, Richard E. Brown, Dalhousie University, Nova Scotia
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2 - The endocrine glands and their hormones
- Michael Wilkinson, Dalhousie University, Nova Scotia, Richard E. Brown, Dalhousie University, Nova Scotia
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The endocrine glands
The location of the human endocrine glands is shown in Figure 2.1. The pineal gland is a small gland lying deep between the cerebral cortex and the cerebellum at the posterior end of the third ventricle in the middle of the brain. The hypothalamus exerts some degree of control over most of the endocrine glands through the release of neurohormones, neuropeptides and neurotransmitters. The pituitary gland hangs from the bottom of the hypothalamus at the base of the brain and sits in a small cavity of bone above the roof of the mouth.
The thyroid gland is located in the neck and the small parathyroid glands are embedded in the surface of the thyroid. In the chest is the thymus gland, which is very important for the production of T lymphocytes that play a critical role in the immune response. The heart and lungs also act as endocrine glands that secrete hormones. The gastrointestinal (GI) tract, consisting of the stomach and intestines, is also an important source of hormones. The liver secretes several hormones such as somatomedin (also called IGF-1), important for growth. The adrenal glands are complex endocrine glands situated on top of the kidneys. The pancreas secretes hormones involved in regulating blood sugar levels and the kidney also produces hormone-like chemicals. The testes and ovaries produce gonadal hormones, or sex hormones, which, in addition to the maintenance of fertility and sex characteristics, have important effects on behavior. During pregnancy, the placenta acts as an endocrine gland. The endocrine glands occur in similar locations in all vertebrates. A large endocrine gland is fat (adipose tissue) which can be found beneath the skin (subcutaneous), in the abdominal cavity surrounding the heart and GI tract (see Figure 2.1), and within tissues such as liver and muscle. Fat secretes a variety of hormones called adipokines. Finally, two of the largest tissues in the body – skeletal muscle and bone – secrete factors that act in an endocrine fashion.
7 - Regulation of hormone synthesis, storage, release, transport and deactivation
- Michael Wilkinson, Dalhousie University, Nova Scotia, Richard E. Brown, Dalhousie University, Nova Scotia
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The endocrine system is driven by hormones released into the bloodstream in order to regulate other, distant organs (see Figure 1.3). These hormones are chemical messages that are decoded by specific recognition sites, or receptors, located in the target cells. Hormones are synthesized and stored in endocrine cells and, when required, they are released into the circulatory system. A number of hormones are transported in the bloodstream by carrier proteins. For example, sex hormone binding globulin is specifically responsible for transport of estradiol and testosterone. Other proteins such as albumin are less specific and serve to transport a variety of hormones. Hormone synthesis, storage, release, transport and deactivation occur through a variety of different mechanisms, depending on the chemical structure of the hormone. For example, peptides such as oxytocin are different in almost every respect from steroid hormones like estradiol. For this reason, the first section of this chapter will examine the chemical structure of hormones.
The chemical structure of hormones
In terms of chemical structure, hormones can be divided into three major groups: (1) steroid hormones; (2) amines; and (3) peptide hormones (Table 7.1). Steroid hormones, like estradiol, are different from the other two groups because of their very low solubility in blood. This is because they are essentially hydrocarbons and therefore need a binding protein to carry them in the bloodstream. A further distinction is the mechanism of their synthesis; steroids and amines are produced from precursors (such as cholesterol and tyrosine, respectively) via specific enzymes, whereas peptides are encoded by specific genes (DNA) that transcribe messenger RNA (mRNA) that is then translated into precursor peptides.
7.1.1 Steroid hormones
The steroid hormones are biosynthesized from cholesterol in the adrenal cortex and gonads. Adrenal steroids include cortisol and aldosterone and the gonadal steroids are progesterone, testosterone and estradiol (see Table 7.1). Note that some steroids are also made in the brain, fat tissue and placenta.
11 - Neuropeptides I: classification, synthesis and co-localization with classical neurotransmitters
- Michael Wilkinson, Dalhousie University, Nova Scotia, Richard E. Brown, Dalhousie University, Nova Scotia
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Summary
Many chemical messengers regulate neural activity, including neurotransmitters (Chapter 5), steroid hormones (Chapter 9) and peptide hormones (Chapter 10). This chapter, and Chapter 12, examines how the class of chemical messengers termed neuropeptides regulates neural activity. The topic of neuropeptides is now an extensive one and we divide the coverage into two parts. This chapter will describe the classification and synthesis of neuropeptides and their co-localization with classical neurotransmitters. Chapter 12 examines the functions of neuropeptides in the brain and neuroendocrine system.
Classification of neuropeptides
The realization that neuropeptides can act as neurotransmitters took place after the discovery of most of the “classical,” or small molecule, neurotransmitters, such as NE, glutamate and ACh. Perhaps the simplest and obvious difference between these two classes of neurotransmitter is the size of the molecules; neuropeptides range in size from 2 to at least 40 amino acids, whereas a molecule such as NE is derived from a single amino acid (tyrosine) (see Table 7.1). Another difference is that neuropeptides are more versatile in their range of biological activities. For example, some peptide hormones are synthesized in endocrine glands, in fat cells and in the GI tract, but are also produced in the brain, where they act as neurotransmitters or neuromodulators. Another significant distinguishing characteristic of neuropeptides is their mode of synthesis. Classical neurotransmitters such as amino acids or catecholamines are formed by two or three enzymatic steps, often in the nerve terminal. Neuropeptides, on the other hand, are synthesized from large prepropeptides in the neuronal cell body (e.g. see section 7.2.1; Figure 7.2).
In terms of nomenclature, peptide hormones were traditionally and sensibly named after the first function they were known to serve. Thus, the pituitary hormones (ACTH, TSH, FSH, GH, etc.) were named for their actions at their target cells; for example, TSH stimulates the thyroid gland. Hypothalamic-releasing hormones (CRH, TRH, GnRH, GHRH, etc.) were named for their functions at pituitary target cells; and the hormones of the gastrointestinal (GI) tract (CCK, VIP, gastrin, etc.) were named based on their gastrointestinal functions.
9 - Steroid and thyroid hormone receptors
- Michael Wilkinson, Dalhousie University, Nova Scotia, Richard E. Brown, Dalhousie University, Nova Scotia
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Summary
In previous chapters, we focused on the neuroendocrine system in terms of a variety of hypothalamic neurotransmitter and hormonal messengers. In Chapter 1, these messengers were seen to act via endocrine, paracrine, autocrine, intracrine and neuroendocrine mechanisms. So far, however, we have not discussed in detail how target cells detect and respond to such messages. Chapter 5 introduced this story by illustrating how neurotransmitters, neurohormones and peptide hormones affect their target cells through receptors localized to the cell membrane. Examples of these receptors are illustrated in Figures 5.2 (ion channel; GABA receptor) and 5.13 (G-protein-coupled receptor) and this type of receptor will be covered in more detail in Chapter 10. The location of receptors on the outside of cells, that is, in the cell membrane, is important for at least two reasons: (1) because peptide hormones are large, water soluble (hydrophilic) molecules which cannot easily pass through the cell membrane; and (2) because cells such as neurons must respond very quickly (seconds) to neurotransmitters like GABA or glutamate that do not have to enter the cell. In marked contrast, steroid hormones (testosterone, estradiol, progesterone, glucocorticoids and mineralocorticoids; Figure 7.3), and thyroid hormones, are small lipophilic (fat soluble) molecules that can readily diffuse through the cell membranes into any cell in the body. As we shall see in this chapter, target cells for steroid and thyroid hormones have receptors that are located inside the cell. These cells therefore respond relatively slowly (minutes to hours) to hormonal stimulation (see Figure 9.1). In brief, the steroid hormone is transported in the blood and released from a binding globulin before freely moving through the cell membrane. Unoccupied steroid hormone receptors (R) are coupled to a molecular chaperone (HSP90; heat shock protein 90) that stabilizes R in the correct shape. When the hormone binds to the receptor-HSP complex, the HSP dissociates and the remaining steroid hormone-receptor complex dimerizes before it enters the cell nucleus. The steroid-R dimer complex then binds to responsive genes via specific hormone response elements (HRE).
List of abbreviations
- Michael Wilkinson, Dalhousie University, Nova Scotia, Richard E. Brown, Dalhousie University, Nova Scotia
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12 - Neuropeptides II: function
- Michael Wilkinson, Dalhousie University, Nova Scotia, Richard E. Brown, Dalhousie University, Nova Scotia
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Summary
As noted in Chapter 11, the human genome contains about 90 genes that encode neuropeptide precursors (pre-propeptides). The biologically active neuropeptide products of the prepropeptides number at least 100, and there are likely to be many more waiting to be discovered. Neuropeptides are synthesized in a wide variety of neurons in many brain regions and more often than not are co-localized and co-released with classical neurotransmitters. Should neuropeptides therefore be categorized as neurotransmitters? An alternative description is that of neuromodulator, since in many instances they modify the neural effects of classical neurotransmitters. A good example of this is shown in Figure 11.2, where co-release of a neuropeptide totally modifies the influence of the co-localized neurotransmitter on a postsynaptic neuron. This chapter will illustrate the neurotransmitter and neuromodulator actions of neuropeptides on the neuroendocrine system, the autonomic nervous system (ANS) and the central nervous system. First, however, we will explore whether neuropeptides are best described as neurotransmitters or neuromodulators, or both.
Neurotransmitter and neuromodulator actions of neuropeptides: a dichotomy or a continuum?
An initial useful exercise is to establish criteria by which a neuromodulator could be defined. Recall that in Chapter 5 several criteria were established to ascertain whether a neurochemical might be considered to be a neurotransmitter (Table 5.1). In brief, these are: (1) synthesized in neurons; (2) present in the presynaptic nerve terminals, usually contained in vesicles, and released into the synapse in amounts sufficient to stimulate the postsynaptic cell; (3) whether endogenously released or applied exogenously, a neurotransmitter should have the same effect on the postsynaptic cell (i.e. it activates the same ion channels or second messenger pathways); (4) receptors specific to the neurotransmitter should be present postsynaptically; (5) receptor antagonists should prevent #3; and (6) a specific deactivating mechanism should exist in the synapse.
Strictly speaking, all of these criteria apply equally well to neuropeptides, with some qualifications. For example, classical neurotransmitters are made by enzymatic transformation (criterion #1) of a single amino acid transported into the neuron from the circulation, whereas neuropeptides are produced via changes in gene expression.
Frontmatter
- Michael Wilkinson, Dalhousie University, Nova Scotia, Richard E. Brown, Dalhousie University, Nova Scotia
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4 - The hypothalamic hormones
- Michael Wilkinson, Dalhousie University, Nova Scotia, Richard E. Brown, Dalhousie University, Nova Scotia
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Summary
Chapters 2 and 3 surveyed the hormones of the endocrine and pituitary glands. This chapter outlines the functions of the hypothalamus, and the hypothalamic neurosecretory cells and examines the role of the hypothalamus in controlling the release of pituitary hormones.
Functions of the hypothalamus
The hypothalamus is located at the base of the forebrain, below the thalamus (see Figure 3.1), and is divided into two halves, along the midline, by the third ventricle, which is filled with cerebrospinal fluid (CSF). As shown in a coronal (frontal) section in Figure 4.1, the hypothalamus contains many groups, or nuclei, of nerve cell bodies. The medial basal hypothalamus, consisting of the VMH, ARC and median eminence, is often referred to as the “endocrine hypothalamus” because of its neuroendocrine functions. For students interested in further details, a description of the anatomy of the hypothalamus can be found elsewhere (Norris 2007; Page 2006; Squire et al. 2008).
It is beyond the scope of this book to consider in detail the many and complex roles of the hypothalamus in maintaining normal bodily functions. But bear in mind that this brain center exerts an amazing diversity of critical controls, including growth, reproduction, temperature control, metabolism and body weight, emotional behavior (anger, fear, euphoria), motivational arousal (hunger, thirst, aggression and sexual arousal), circadian rhythms, stress and fluid balance. It contains multiple internal connections between neurons, but in addition receives neural information from other brain regions such as amygdala, hippocampus and spinal cord. The hypothalamus is well supplied with blood vessels and is therefore the recipient of essential information from the bloodstream, such as temperature and hormone levels. Thus, we can appreciate the importance of the hypothalamus in integrating and responding to all of this information by modifying its output of neural and neuroendocrine signaling.
These functions of the hypothalamus can be “localized” to particular nuclei, although any boundaries, such as those outlined in Figure 4.1, should be regarded only as approximate guides.
1 - Classification of chemical messengers
- Michael Wilkinson, Dalhousie University, Nova Scotia, Richard E. Brown, Dalhousie University, Nova Scotia
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Hormones, the brain and behavior
Neuroendocrinology is the study of how the brain controls the endocrine systems that keep us alive and able to reproduce. However, an essential and critical characteristic of this neural control of the endocrine systems is that endocrine hormones in turn have profound effects on brain function through feedback systems. Research on hormones and the brain is intensive and covers many fields: from cell and molecular biology and genetics to anatomy, physiology, pharmacology, biochemistry, medicine, psychiatry and psychology. This book will examine the interactions between hormones, the brain and behavior. Thus, the primary focus will be on how the endocrine and nervous systems affect each other to produce an integrated functional neuroendocrine system that influences physiological and behavioral responses. As preliminary background reading, students are referred to any modern text on Human Physiology (see “Further reading” at the end of this chapter).
When you hear the term “hormone,” for example steroid hormone, you think of the endocrine glands and how their secretions influence physiological responses in the body, but this is only part of the picture. Many of the endocrine glands (although not all of them) are influenced by the pituitary gland, the so-called “master gland,” and the pituitary is itself controlled by various hormones secreted from the hypothalamus, a part of the brain situated directly above the pituitary gland. The release of hypothalamic hormones is in turn regulated by neurotransmitters released from nerve cells (neurons) in the brain. Some neurotransmitters released within the brain also control behavior, and the secretion of neurotransmitters from specific nerve cells can be modulated by the level of specific endocrine hormones in the circulation. This is called hormone feedback. Thus, neurotransmitter release influences both hormones and behavior and, in turn, hormones regulate the release of neurotransmitters. This interaction between hormones, the brain and behavior involves a wide variety of chemical messengers which are described in this chapter.
Contents
- Michael Wilkinson, Dalhousie University, Nova Scotia, Richard E. Brown, Dalhousie University, Nova Scotia
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- Book:
- An Introduction to Neuroendocrinology
- Published online:
- 05 June 2015
- Print publication:
- 04 June 2015, pp vii-xii
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