Hypothalamic neurons regulate fundamental body functions including sleep, blood pressure, temperature, hunger and metabolism, thirst and satiety, stress, and social behavior. This is achieved by means of the secretion of various hypothalamic neuropeptides and neurotransmitters that affect endocrine, metabolic, and behavioral activities. Developmental impairments of hypothalamic neuronal circuits are associated with neurological disorders that disrupt both physiological and psychological homeostasis. Hypothalamic cell specification and morphogenesis can be uniquely studied in zebrafish, a vertebrate organism readily amenable to genetic manipulations. As embryos are optically transparent and develop externally, they provide a powerful tool for in vivo analyses of neurons and their circuits. Here, we discuss the current knowledge regarding the neuroanatomy of the zebrafish hypothalamus and recent studies identifying critical determinants of hypothalamic differentiation. Taken together, these reports demonstrate that the molecular pathways underlying development of the hypothalamus are largely conserved between zebrafish and mammals. We conclude that the zebrafish has proved itself a valuable vertebrate model for understanding the patterning, specification, morphogenesis, and subsequent function of the hypothalamus.
SUMMARY The hypothalamo-neurohypophyseal system (HNS) is the neurovascular structure through which the hypothalamic neuropeptides oxytocin and arginine-vasopressin exit the brain into the bloodstream, where they go on to affect peripheral physiology. Here, we investigate the molecular cues that regulate the neurovascular contact between hypothalamic axons and neurohypophyseal capillaries of the zebrafish. We developed a transgenic system in which both hypothalamic axons and neurohypophyseal vasculature can be analyzed in vivo. We identified the cellular organization of the zebrafish HNS as well as the dynamic processes that contribute to formation of the HNS neurovascular interface. We show that formation of this interface is regulated during development by local release of oxytocin, which affects endothelial morphogenesis. This cell communication process is essential for the establishment of a tight axovasal interface between the neurons and blood vessels of the HNS. We present a unique example of axons affecting endothelial morphogenesis through secretion of a neuropeptide.
Controlling cellular processes with light can help elucidate their underlying mechanisms. Here we present ZAPALOG, a small-molecule dimerizer that undergoes photolysis when exposed to blue light. Zapalog dimerizes any two proteins tagged with the FKBP and DHFR domains until exposure to light causes its photolysis. Dimerization can be repeatedly restored with uncleaved zapalog. We implement this method to investigate mitochondrial motility and positioning in cultured neurons. Using zapalog, we tether mitochondria to constitutively active kinesin motors, forcing them down the axon towards microtubule (+) ends until their instantaneous release via blue light, which results in full restoration of their endogenous motility. We find that one-third of stationary mitochondria cannot be pulled away from their position and that these firmly anchored mitochondria preferentially localize to VGLUT1-positive presynapses. Furthermore, inhibition of actin polymerization with Latrunculin A reduces this firmly anchored pool. Upon release from exogenous motors, mitochondria are preferentially recaptured at presynapses.
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