Several hypothalamic nuclei aresexually dimorphic; i.e., there are clear differences in both structure and function between males and females.[19] Some differences are apparent even in gross neuroanatomy: most notable is thesexually dimorphic nucleus within thepreoptic area,[19] in which the differences are subtle changes in the connectivity and chemical sensitivity of particular sets of neurons. The importance of these changes can be recognized by functional differences between males and females. For instance, males of most species prefer the odor and appearance of females over males, which is instrumental in stimulating male sexual behavior. If the sexually dimorphic nucleus is lesioned, this preference for females by males diminishes. Also, the pattern of secretion ofgrowth hormone is sexually dimorphic;[20] this is why in many species, adult males are visibly distinct sizes from females.
Other striking functional dimorphisms are in the behavioral responses toovarian steroids of the adult. Males and females respond to ovarian steroids in different ways, partly because the expression of estrogen-sensitive neurons in the hypothalamus is sexually dimorphic; i.e., estrogen receptors are expressed in different sets of neurons.[citation needed]
Estrogen andprogesterone can influence gene expression in particular neurons or induce changes incell membrane potential andkinase activation, leading to diverse non-genomic cellular functions. Estrogen and progesterone bind to their cognatenuclear hormone receptors, which translocate to the cell nucleus and interact with regions of DNA known ashormone response elements (HREs) or get tethered to anothertranscription factor's binding site.Estrogen receptor (ER) has been shown to transactivate other transcription factors in this manner, despite the absence of anestrogen response element (ERE) in the proximal promoter region of the gene. In general, ERs andprogesterone receptors (PRs) are gene activators, with increased mRNA and subsequent protein synthesis following hormone exposure.[citation needed]
Male and female brains differ in the distribution of estrogen receptors, and this difference is an irreversible consequence of neonatal steroid exposure.[citation needed] Estrogen receptors (and progesterone receptors) are found mainly in neurons in the anterior and mediobasal hypothalamus, notably:
thepreoptic area (whereLHRH neurons are located, regulating dopamine responses and maternal behavior;[21]
Median sagittal section of brain of human embryo of three months
In neonatal life, gonadal steroids influence the development of the neuroendocrine hypothalamus. For instance, they determine the ability of females to exhibit a normal reproductive cycle, and of males and females to display appropriate reproductive behaviors in adult life.
If afemale rat is injected once with testosterone in the first few days of postnatal life (during the "critical period" of sex-steroid influence), the hypothalamus is irreversibly masculinized; the adult rat will be incapable of generating anLH surge in response to estrogen (a characteristic of females), but will be capable of exhibitingmale sexual behaviors (mounting a sexually receptive female).[23]
By contrast, amale rat castrated just after birth will befeminized, and the adult will showfemale sexual behavior in response to estrogen (sexual receptivity,lordosis behavior).[23]
In primates, the developmental influence ofandrogens is less clear, and the consequences are less understood. Within the brain, testosterone is aromatized (toestradiol), which is the principal active hormone for developmental influences. The humantestis secretes high levels of testosterone from about week eight of fetal life until five to six months after birth (a similar perinatal surge in testosterone is observed in many species), a process that appears to underlie the male phenotype. Estrogen from the maternal circulation is relatively ineffective, partly because of the high circulating levels of steroid-binding proteins in pregnancy.[23]
Sex steroids are not the only important influences upon hypothalamic development; in particular,pre-pubertal stress in early life (of rats) determines the capacity of the adult hypothalamus to respond to an acute stressor.[24] Unlike gonadal steroid receptors,glucocorticoid receptors are very widespread throughout the brain; in theparaventricular nucleus, they mediate negative feedback control ofCRF synthesis and secretion, but elsewhere their role is not well understood.
The hypothalamus has a centralneuroendocrine function, most notably by its control of theanterior pituitary, which in turn regulates various endocrine glands and organs.Releasing hormones (also called releasing factors) are produced in hypothalamic nuclei then transported alongaxons to either themedian eminence or theposterior pituitary, where they are stored and released as needed.[25]
Anterior pituitary
In the hypothalamic–adenohypophyseal axis, releasing hormones, also known as hypophysiotropic or hypothalamic hormones, are released from the median eminence, a prolongation of the hypothalamus, into thehypophyseal portal system, which carries them to the anterior pituitary where they exert their regulatory functions on the secretion of adenohypophyseal hormones.[26] These hypophysiotropic hormones are stimulated by parvocellular neurosecretory cells located in the periventricular area of the hypothalamus. After their release into the capillaries of the third ventricle, the hypophysiotropic hormones travel through what is known as the hypothalamo-pituitary portal circulation. Once they reach their destination in the anterior pituitary, these hormones bind to specific receptors located on the surface of pituitary cells. Depending on which cells are activated through this binding, the pituitary will either begin secreting or stop secreting hormones into the rest of the bloodstream.[27]
In the hypothalamic–pituitary–adrenal axis,neurohypophysial hormones are released from the posterior pituitary, which is actually a prolongation of the hypothalamus, into the circulation.
Magnocellular and parvocellular neurosecretory cells of the paraventricular nucleus, magnocellular cells in supraoptic nucleus
Increase in the permeability to water of the cells ofdistal tubule andcollecting duct in the kidney and thus allows water reabsorption and excretion of concentrated urine
It is also known thathypothalamic–pituitary–adrenal axis (HPA) hormones are related to certain skin diseases and skin homeostasis. There is evidence linking hyperactivity of HPA hormones to stress-related skin diseases and skin tumors.[33]
The hypothalamus coordinates many hormonal and behavioural circadian rhythms, complex patterns ofneuroendocrine outputs, complexhomeostatic mechanisms, and important behaviours. The hypothalamus must, therefore, respond to many different signals, some of which are generated externally and some internally.Delta wave signalling arising either in the thalamus or in the cortex influences the secretion of releasing hormones;GHRH andprolactin are stimulated whilstTRH is inhibited.[citation needed]
Olfactory stimuli are important forsexual reproduction andneuroendocrine function in many species. For instance, if a pregnant mouse is exposed to the urine of a 'strange' male during a critical period after coitus then the pregnancy fails (theBruce effect). Thus, during coitus, a female mouse forms a precise 'olfactory memory' of her partner that persists for several days. Pheromonal cues aid synchronization ofoestrus in many species; in women, synchronizedmenstruation may also arise from pheromonal cues, although the role of pheromones in humans is disputed.[citation needed]
Peptide hormones have important influences upon the hypothalamus, and to do so they must pass through theblood–brain barrier. The hypothalamus is bounded in part by specialized brain regions that lack an effective blood–brain barrier; thecapillaryendothelium at these sites is fenestrated to allow free passage of even large proteins and other molecules. Some of these sites are the sites of neurosecretion - theneurohypophysis and themedian eminence. However, others are sites at which the brain samples the composition of the blood. Two of these sites, the SFO (subfornical organ) and the OVLT (organum vasculosum of the lamina terminalis) are so-calledcircumventricular organs, where neurons are in intimate contact with both blood andCSF. These structures are densely vascularized, and contain osmoreceptive and sodium-receptive neurons that controldrinking,vasopressin release, sodium excretion, and sodium appetite. They also contain neurons with receptors forangiotensin,atrial natriuretic factor,endothelin andrelaxin, each of which important in the regulation of fluid and electrolyte balance. Neurons in the OVLT and SFO project to thesupraoptic nucleus andparaventricular nucleus, and also to preoptic hypothalamic areas. The circumventricular organs may also be the site of action ofinterleukins to elicit both fever and ACTH secretion, via effects on paraventricular neurons.[citation needed]
It is not clear how all peptides that influence hypothalamic activity gain the necessary access. In the case ofprolactin andleptin, there is evidence of active uptake at thechoroid plexus from the blood into thecerebrospinal fluid (CSF). Some pituitary hormones have a negative feedback influence upon hypothalamic secretion; for example,growth hormone feeds back on the hypothalamus, but how it enters the brain is not clear. There is also evidence for central actions ofprolactin.[citation needed]
Findings have suggested thatthyroid hormone (T4) is taken up by the hypothalamicglial cells in theinfundibular nucleus/median eminence, and that it is here converted intoT3 by the type 2 deiodinase (D2). Subsequent to this, T3 is transported into thethyrotropin-releasing hormone (TRH)-producingneurons in theparaventricular nucleus.Thyroid hormone receptors have been found in theseneurons, indicating that they are indeed sensitive to T3 stimuli. In addition, these neurons expressedMCT8, athyroid hormone transporter, supporting the theory that T3 is transported into them. T3 could then bind to the thyroid hormone receptor in these neurons and affect the production of thyrotropin-releasing hormone, thereby regulating thyroid hormone production.[35]
The hypothalamus functions as a type ofthermostat for the body.[36] It sets a desired body temperature, and stimulates either heat production and retention to raise the blood temperature to a higher setting or sweating andvasodilation to cool the blood to a lower temperature. Allfevers result from a raised setting in the hypothalamus; elevated body temperatures due to any other cause are classified ashyperthermia.[36] Rarely, direct damage to the hypothalamus, such as from astroke, will cause a fever; this is sometimes called ahypothalamic fever. However, it is more common for such damage to cause abnormally low body temperatures.[36]
The hypothalamus contains neurons that react strongly to steroids andglucocorticoids (the steroid hormones of theadrenal gland, released in response toACTH). It also contains specialized glucose-sensitive neurons (in thearcuate nucleus andventromedial hypothalamus), which are important forappetite. The preoptic area contains thermosensitive neurons; these are important forTRH secretion.[citation needed]
Oxytocin secretion in response to suckling or vagino-cervical stimulation is mediated by some of these pathways;vasopressin secretion in response to cardiovascular stimuli arising from chemoreceptors in thecarotid body andaortic arch, and from low-pressureatrial volume receptors, is mediated by others. In the rat, stimulation of thevagina also causesprolactin secretion, and this results inpseudo-pregnancy following an infertile mating. In the rabbit, coitus elicitsreflex ovulation. In the sheep,cervical stimulation in the presence of high levels of estrogen can inducematernal behavior in a virgin ewe. These effects are all mediated by the hypothalamus, and the information is carried mainly by spinal pathways that relay in the brainstem. Stimulation of the nipples stimulates release of oxytocin and prolactin and suppresses the release ofLH andFSH.[citation needed]
Cardiovascular stimuli are carried by thevagus nerve. The vagus also conveys a variety of visceral information, including for instance signals arising from gastric distension or emptying, to suppress or promote feeding, by signalling the release ofleptin orgastrin, respectively. Again, this information reaches the hypothalamus via relays in the brainstem.[citation needed]
The extremelateral part of theventromedial nucleus of the hypothalamus is responsible for the control offood intake. Stimulation of this area causes increased food intake. Bilaterallesion of this area causes complete cessation of food intake. Medial parts of the nucleus have a controlling effect on the lateral part. Bilateral lesion of the medial part of the ventromedial nucleus causeshyperphagia and obesity of the animal. Further lesion of the lateral part of the ventromedial nucleus in the same animal produces complete cessation of food intake.
There are different hypotheses related to this regulation:[38]
Lipostatic hypothesis: This hypothesis holds thatadiposetissue produces ahumoral signal that is proportionate to the amount of fat and acts on the hypothalamus to decrease food intake and increase energy output. It has been evident that ahormoneleptin acts on the hypothalamus to decrease food intake and increase energy output.
Gutpeptide hypothesis:gastrointestinal hormones like Grp,glucagons,CCK and others claimed to inhibit food intake. The food entering the gastrointestinal tract triggers the release of these hormones, which act on the brain to produce satiety. The brain contains both CCK-A and CCK-B receptors.
Glucostatic hypothesis: The activity of the satiety center in the ventromedial nuclei is probably governed by theglucose utilization in the neurons. It has been postulated that when their glucose utilization is low and consequently when the arteriovenous blood glucose difference across them is low, the activity across the neurons decrease. Under these conditions, the activity of the feeding center is unchecked and the individual feels hungry. Food intake is rapidly increased by intraventricular administration of2-deoxyglucose therefore decreasing glucose utilization in cells.
Thermostatic hypothesis: According to this hypothesis, a decrease in body temperature below a given set-point stimulates appetite, whereas an increase above the set-point inhibits appetite.
The medial zone of hypothalamus is part of a circuitry that controls motivated behaviors, like defensive behaviors.[39] Analyses ofFos-labeling showed that a series of nuclei in the "behavioral control column" is important in regulating the expression of innate and conditioned defensive behaviors.[40]
Antipredatory defensive behavior
Exposure to a predator (such as a cat) elicits defensive behaviors in laboratory rodents, even when the animal has never been exposed to a cat.[41] In the hypothalamus, this exposure causes an increase inFos-labeled cells in the anterior hypothalamic nucleus, the dorsomedial part of the ventromedial nucleus, and in the ventrolateral part of the premammillary nucleus (PMDvl).[42] The premammillary nucleus has an important role in expression of defensive behaviors towards a predator, since lesions in this nucleus abolish defensive behaviors, like freezing and flight.[42][43] The PMD does not modulate defensive behavior in other situations, as lesions of this nucleus had minimal effects on post-shock freezing scores.[43] The PMD has important connections to the dorsalperiaqueductal gray, an important structure in fear expression.[44][45] In addition, animals display risk assessment behaviors to the environment previously associated with the cat. Fos-labeled cell analysis showed that the PMDvl is the most activated structure in the hypothalamus, and inactivation withmuscimol prior to exposure to the context abolishes the defensive behavior.[42] Therefore, the hypothalamus, mainly the PMDvl, has an important role in expression of innate and conditioned defensive behaviors to a predator.
Social defeat
Likewise, the hypothalamus has a role insocial defeat: nuclei in medial zone are also mobilized during an encounter with an aggressive conspecific. The defeated animal has an increase in Fos levels in sexually dimorphic structures, such as the medial pre-optic nucleus, the ventrolateral part of ventromedial nucleus, and the ventral premammilary nucleus.[6] Such structures are important in other social behaviors, such as sexual and aggressive behaviors. Moreover, the premammillary nucleus also is mobilized, the dorsomedial part but not the ventrolateral part.[6] Lesions in this nucleus abolish passive defensive behavior, like freezing and the "on-the-back" posture.[6]
Recent research has questioned whether the lateral hypothalamus's role is only restricted to initiating and stopping innate behaviors and argued it learns about food-related cues. Specifically, that it opposes learning about information what is neutral or distant to food. According this view, the lateral hypothalamus is "a unique arbitrator of learning capable of shifting behavior toward or away from important events".[46]
^Malenka RC, Nestler EJ, Hyman SE (2009). "Chapter 6: Widely Projecting Systems: Monoamines, Acetylcholine, and Orexin". In Sydor A, Brown RY (eds.).Molecular Neuropharmacology: A Foundation for Clinical Neuroscience (2nd ed.). New York: McGraw-Hill Medical. pp. 175–176.ISBN9780071481274.Within the brain, histamine is synthesized exclusively by neurons with their cell bodies in the tuberomammillary nucleus (TMN) that lies within the posterior hypothalamus. There are approximately 64000 histaminergic neurons per side in humans. These cells project throughout the brain and spinal cord. Areas that receive especially dense projections include the cerebral cortex, hippocampus, neostriatum, nucleus accumbens, amygdala, and hypothalamus. ... While the best characterized function of the histamine system in the brain is regulation of sleep and arousal, histamine is also involved in learning and memory ... It also appears that histamine is involved in the regulation of feeding and energy balance.
^Isgor C, Cecchi M, Kabbaj M, Akil H, Watson SJ (2003). "Estrogen receptor beta in the paraventricular nucleus of hypothalamus regulates the neuroendocrine response to stress and is regulated by corticosterone".Neuroscience.121 (4):837–45.doi:10.1016/S0306-4522(03)00561-X.PMID14580933.S2CID31026141.
^Bear MF, Connors BW, Paradiso MA (2016). "Hypothalamic Control of the Anterior Pituitary".Neuroscience: Exploring the Brain (4th ed.). Philadelphia: Wolters Kluwer. p. 528.ISBN978-0-7817-7817-6.
^Horn AM, Robinson IC, Fink G (February 1985). "Oxytocin and vasopressin in rat hypophysial portal blood: experimental studies in normal and Brattleboro rats".The Journal of Endocrinology.104 (2):211–24.doi:10.1677/joe.0.1040211.PMID3968510.
^Date Y, Mondal MS, Matsukura S, Ueta Y, Yamashita H, Kaiya H, et al. (March 2000). "Distribution of orexin/hypocretin in the rat median eminence and pituitary".Brain Research. Molecular Brain Research.76 (1):1–6.doi:10.1016/s0169-328x(99)00317-4.PMID10719209.
^Watanobe H, Takebe K (April 1993). "In vivo release of neurotensin from the median eminence of ovariectomized estrogen-primed rats as estimated by push-pull perfusion: correlation with luteinizing hormone and prolactin surges".Neuroendocrinology.57 (4):760–4.doi:10.1159/000126434.PMID8367038.
^Spinazzi R, Andreis PG, Rossi GP, Nussdorfer GG (March 2006). "Orexins in the regulation of the hypothalamic–pituitary–adrenal axis".Pharmacological Reviews.58 (1):46–57.doi:10.1124/pr.58.1.4.PMID16507882.S2CID17941978.
^Fliers E, Unmehopa UA, Alkemade A (June 2006). "Functional neuroanatomy of thyroid hormone feedback in the human hypothalamus and pituitary gland".Molecular and Cellular Endocrinology.251 (1–2):1–8.doi:10.1016/j.mce.2006.03.042.PMID16707210.S2CID33268046.
^Malenka RC, Nestler EJ, Hyman SE (2009). "Chapter 10: Neural and Neuroendocrine Control of the Internal Milieu – Table 10:3". In Sydor A, Brown RY (eds.).Molecular Neuropharmacology: A Foundation for Clinical Neuroscience (2nd ed.). New York: McGraw-Hill Medical. p. 263.ISBN9780071481274.
^Canteras, N.S. (2002). "The medial hypothalamic defensive system:Hodological organization and functional implications".Pharmacology Biochemistry and Behavior.71 (3):481–491.doi:10.1016/S0091-3057(01)00685-2.PMID11830182.S2CID12303256.
^Ribeiro-Barbosa ER, Canteras NS, Cezário AF, Blanchard RJ, Blanchard DC (2005). "An alternative experimental procedure for studying predator-related defensive responses".Neuroscience and Biobehavioral Reviews.29 (8):1255–63.doi:10.1016/j.neubiorev.2005.04.006.PMID16120464.S2CID8063630.
![Hypothalamic nuclei on one side of the hypothalamus, shown in a 3-D computer reconstruction[18]](/mt/?noimg=&dark=on&url=http%3a%2f%2fen.wikipedia.org%2fwiki%2fFile%3a3D-Hypothalamus.JPG)
