Specification of posterior hypothalamic neurons requires coordinated activities of Fezf2, Otp, Sim1a and Foxb1.2.

The hypothalamus is a key integrative center in the brain that consists of diverse cell types required for a variety of functions including homeostasis, reproduction, stress response, social and cognitive behavior. Despite our knowledge of several transcription factors crucial for hypothalamic development, it is not known how the wide diversity of neuron types in the hypothalamus is produced. In particular, almost nothing is known about the mechanisms that specify neurons in the posteriormost part of the hypothalamus, the mammillary area. Here, we investigated the specification of two distinct neuron types in the mammillary area that produce the hypothalamic hormones Vasoactive intestinal peptide (Vip) and Urotensin 1 (Uts1). We show that Vip- and Uts1-positive neurons develop in distinct domains in the mammillary area defined by the differential expression of the transcription factors Fezf2, Otp, Sim1a and Foxb1.2. Coordinated activities of these factors are crucial for the establishment of the mammillary area subdomains and the specification of Vip- and Uts1-positive neurons. In addition, Fezf2 is important for early development of the posterior hypothalamus. Thus, our study provides the first molecular anatomical map of the posterior hypothalamus in zebrafish and identifies, for the first time, molecular requirements underlying the specification of distinct posterior hypothalamic neuron types.

Melanin-concentrating hormone system in the brain and skin of the cichlid fish Cichlasoma dimerus: anatomical localization, ontogeny and distribution in comparison to alpha-melanocyte-stimulating hormone-expressing cells.

Distribution and development of the melanin-concentrating hormone (MCH) system were examined by immunocytochemistry of the brain, pituitary gland and skin of the South American cichlid fish Cichlasoma dimerus. In adults, the most prominent group of MCH-ir perikarya was located in the nucleus lateralis tuberis (NLT). Outside the NLT, in the posterior hypothalamic region, a group of small neurons was found between the third ventricle and the lateral ventricular recess with delicate immunoreactive fibers that did not seem to contribute to the pituitary innervation. MCH-ir perikarya were identified at day 4 after hatching (AH) in a proliferating zone of the hypothalamic floor. Pituitary innervation could be detected at this stage. Another group of small MCH-ir neurons, only detected in pre-juvenile stages, originated close to the third ventricle in the medial hypothalamic region by day 6 AH. alphaMSH-ir neurons were localized in similar regions of the NLT and in the nucleus periventricularis posterior (NPP). Free MCH-ir neuromasts were detected in the ventral and dorsal skin of larval heads. These epidermal sensory organs were in close association with blood vessels and dermal melanocytes, suggesting that MCH synthesized in larval skin might act in an endocrine way reaching different targets and/or in a paracrine mode regulating melanin concentration in dermal melanocytes.

Induction from posterior hypothalamus is essential for the development of the pituitary proopiomelacortin (POMC) cells of the toad (Bufo japonicus).

The role of the posterior hypothalamus in the development of the epithelial hypophysis was studied in Bufo embryos. In animals from which the central part of the neural plate (NP) had been surgically removed at the open neurula stage, the infundibulum did not develop, and the epithelial hypophysis was formed away from the normal site without morphological connection with the brain. Immunoreactive MSH cells and ACTH cells, i.e., the pituitary POMC cells, were not detected in any of the surgically treated animals, while other types of secretory cells (PRL, GH, TSH and GTH cells) were invariably present. In view of the fact that POMC cells originate in the anterior neural ridge, and not in the neural plate, the embryonic brain seems to exert an inductive influence upon the primordial pituitary POMC cells. Since these cells differentiate in a tail graft, isolated from the brain at a later stage (tail-bud stage), the inductive stimuli must be conveyed from/via the posterior hypothalamus to the pituitary anlage between the open neurula and the tail-bud stages.

Asymmetry of brain aromatase activity: region- and sex-specific developmental patterns.

Developmental patterns of aromatase activity (AA) were characterized in individual forebrain regions of the rat at gestational day (GD) 22 and postnatal days (PN) 6 and 15. Aromatase activity was measured separately in homogenates of left and right preoptic area, anterior amygdaloid area, medial amygdaloid nucleus, anterior hypothalamic area and posterior hypothalamic area, by the tritiated water method with [1 beta-3H]-androstenedione as a substrate. Region- and sex-dependent asymmetries of AA with either left-to-right or right-to-left gradients were found. They change between GD22 and PN6 and PN15 according to region-specific patterns. Thus, AA of the male medial amygdaloid nucleus of the left side is higher at GD22, lower at PN6 and equal to the right side at PN15; in females, AA of the left side is lower than AA of the right side at GD22 and higher at PN6 and PN15. In preoptic area, a side difference (left side higher) was only detected in males. Asymmetries may result from differences in the expression of the enzyme by individual cell groups, or from differences in the number of cells per area expressing the enzyme. In either case, the stage-dependent patterns of asymmetry in AA would be expected to influence sex steroid-dependent differentiation processes in individual forebrain areas.

An autoradiographic analysis of the time of origin of neurons in the hypothalamus of the cat.

The pattern of neurogenesis of the cat hypothalamus was studied by the use of the [3H]thymidine autoradiographic method. The neurons of the cat hypothalamus are nearly all generated in a period from embryonic days E21 to E35, and in most cases the neurons in a single nucleus are generated over a much shorter period. The dominant gradient along which the cells are organized is lateral-medial (outside-in). This gradient was apparent in all nuclei except the periventricular and arcuate nuclei. Two other gradients were observed in some, but not all, nuclei. These were along the dorsoventral and the posteroanterior axis. The dorsoventral gradient was uniformly less pronounced than the lateromedial gradient. The posteroanterior gradient was most obvious in the mammillary complex. An analysis of the data suggests that the neurons of individual nuclei do not necessarily have a unique production history. This suggests that insofar as nuclear formation is concerned, factors such as the parental population generating the neurons that populate a nucleus, as well as the early neuronal interconnections, may play a more important role than the birthdates themselves.