[The structure and function of habenula].

The habenula (Hb) is an evolutionarily conserved diencephalic structure in vertebrates. It is considered as an emotion center and plays critical roles in regulating diverse types of emotion-related behaviors, including anxiety, fear, reward, depression, and nicotine withdrawal. On the one hand, action selection- and emotion-relevant inputs are transferred to the Hb through the basal ganglia and limbic system, respectively. At the same time, sensory inputs of multiple modalities also converge on the Hb. Among them, the visual input of the Hb from the retina ganglion cells ‒ thalamus pathway has been found to play a critical role in light-preference behavior of zebrafish. On the other hand, the Hb projects to two main neuromodulatory systems, the dopaminergic system and the serotoninergic system. As the Hb receives both internal emotion inputs and external sensory inputs and regulates the function of neuromodulatory systems, its functions are quite diverse and complex. In this review, we summarize the progress in both the structure and connection of the Hb and propose future study direction.

Amperometric Monitoring of Sensory-Evoked Dopamine Release in Awake Larval Zebrafish.

Dopamine plays crucial roles in a broad spectrum of brain functions, and neural circuit mechanisms underlying dopaminergic regulation have been intensively studied in the past decade. As larval zebrafish have relatively simple and highly conserved dopaminergic systems, it can serve as an ideal vertebrate animal model to tackle this issue at a whole-brain scale. For this purpose, it is important to develop methods for monitoring endogenous dopamine release in intact larval zebrafish. Here, we developed a real-time method to monitor dopamine release at high spatiotemporal resolution in the brain of awake larval zebrafish using carbon fiber microelectrodes. As an example for application, we combined this method with genetic tools and in vivo calcium imaging and found that food extract can activate pretectal dopaminergic neurons, which in turn release dopamine at the visual center through their projection, providing a dopaminergic circuit mechanism for olfactory modulation of visual functions. Thus, our study demonstrates, for the first time, the utility of carbon fiber microelectrodes for monitoring sensory-evoked dopamine release in the brain of an awake small organism. SIGNIFICANCE STATEMENT: With carbon fiber microelectrodes, we have succeeded in monitoring sensory-evoked dopamine release in the brain of an awake small organism for the first time. By elucidating the circuitry origin of the dopamine release, we illustrated the potential application of this method in dissection of the neural circuitry mechanisms underlying dopaminergic neuromodulation.

[Establishment of an anesthesia model induced by etomidate in larval zebrafish].

Despite the wide application of general anesthetic drugs in clinic, it is still unclear how these drugs induce the state of general anesthesia. Larval zebrafish has emerged as an ideal model for dissecting the mechanism of neural systems due to the conserved and simple brain structure. In the present study, we established an anesthesia model from behavioral to electrophysiological levels using larval zebrafish for the first time. Bath application of etomidate, as a kind of intravenous anesthetic drugs, suppressed the spontaneous locomotion of zebrafish in a concentration-dependent manner. Consistently, in vivo fictive motor patterns of spinal motoneurons recorded extracellularly were significantly inhibited as well. Furthermore, using in vivo extracellular recording and whole-cell recording, we found that etomidate application suppressed local field potentials (LFP) of the brain and blocked visually evoked responses of optic tectal neurons. The study indicates that larval zebrafish can serve as an ideal vertebrate animal model for studying neural mechanisms underlying general anesthesia.

[Progress in the study of the blood-brain barrier].

Blood-brain barrier (BBB) precisely controls the material exchange between the blood and brain tissue, and plays a critical role in the maintenance of brain microenvironment homeostasis. Brain microvascular endothelial cells connect tightly with each other and intertwine with surrounding pericytes and astrocytes to form the BBB. These cells regulate the development and function of the BBB through expressing tight and adherens junction proteins, transporters, and relevant signal molecules. Neurons and microglia can also regulate the function of BBB in physiological and pathological conditions. Recent studies indicate that the occurrence and progress of various neurological diseases are accompanied with structural and functional impairment of the BBB. Therefore, elucidation of the mechanisms underlying BBB development and function will further benefit our understanding of neurovascular interaction and provide an important theoretical basis for the treatment of neurological diseases. In this review, we briefly summarize the progress of BBB research.

Haemodynamics-driven developmental pruning of brain vasculature in zebrafish.

The brain blood vasculature consists of a highly ramified vessel network that is tailored to meet its physiological functions. How the brain vasculature is formed has long been fascinating biologists. Here we report that the developing vasculature in the zebrafish midbrain undergoes not only angiogenesis but also extensive vessel pruning, which is driven by changes in blood flow. This pruning process shapes the initial exuberant interconnected meshwork into a simplified architecture. Using in vivo long-term serial confocal imaging of the same zebrafish larvae during 1.5-7.5 d post-fertilization, we found that the early formed midbrain vasculature consisted of many vessel loops and higher order segments. Vessel pruning occurred preferentially at loop-forming segments via a process mainly involving lateral migration of endothelial cells (ECs) from pruned to unpruned segments rather than EC apoptosis, leading to gradual reduction in the vasculature complexity with development. Compared to unpruned ones, pruned segments exhibited a low and variable blood flow, which further decreased irreversibly prior to the onset of pruning. Local blockade of blood flow with micro-bead obstruction led to vessel pruning, whereas increasing blood flow by noradrenergic elevation of heartbeat impeded the pruning process. Furthermore, the occurrence of vessel pruning could be largely predicted by haemodynamics-based numerical simulation of vasculature refinement. Thus, changes of blood flow drive vessel pruning via lateral migration of ECs, leading to the simplification of the vasculature and possibly efficient routing of blood flow in the developing brain.

Improvement in Tol2 transposon for efficient large-cargo capacity transgene applications in cultured cells and zebrafish ( Danio rerio).

Most viruses and transposons serve as effective carriers for the introduction of foreign DNA up to 11 kb into vertebrate genomes. However, their activity markedly diminishes with payloads exceeding 11 kb. Expanding the payload capacity of transposons could facilitate more sophisticated cargo designs, improving the regulation of expression and minimizing mutagenic risks associated with molecular therapeutics, metabolic engineering, and transgenic animal production. In this study, we improved the Tol2 transposon by increasing protein expression levels using a translational enhancer ( QBI SP163, ST) and enhanced the nuclear targeting ability using the nuclear localization protein H2B (SHT). The modified Tol2 and ST transposon efficiently integrated large DNA cargos into human cell cultures (H1299), comparable to the well-established super PiggyBac system. Furthermore, mRNA from ST and SHT showed a significant increase in transgene delivery efficiency of large DNA payloads (8 kb, 14 kb, and 24 kb) into zebrafish ( Danio rerio). This study presents a modified Tol2 transposon as an enhanced nonviral vector for the delivery of large DNA payloads in transgenic applications.

Real-time analysis of large-scale neuronal imaging enables closed-loop investigation of neural dynamics.

Large-scale imaging of neuronal activities is crucial for understanding brain functions. However, it is challenging to analyze large-scale imaging data in real time, preventing closed-loop investigation of neural circuitry. Here we develop a real-time analysis system with a field programmable gate array-graphics processing unit design for an up to 500-megabyte-per-second image stream. Adapted to whole-brain imaging of awake larval zebrafish, the system timely extracts activity from up to 100,000 neurons and enables closed-loop perturbations of neural dynamics.

[Physiological properties and functions of microglia].

Microglia, the resident immune effective cells of the central nervous system, play crucial roles in mediating immune-related process. It becomes activated quickly in response to even minor pathological insults and participates in series of immune responses. Under physiological conditions, most microglia stay in a typical resting state, with ramified processes continuously extending and retracting from surrounding neural tissues, suggesting an important function of resting microglia. Recent studies indicate that resting microglia can regulate many physiological processes, including neural development, neural circuit formation, neuronal activity and plasticity, and animal grooming behavior. Here, we review the properties of resting microglia and further discuss how microglia participate in the above-mentioned functional regulation under physiological conditions.

[Visual system and prey capture behavior of larval zebrafish].

Studying neural circuits is a crucial step for understanding neural mechanisms underlying animal behaviors. Larval zebrafish is a low vertebrate animal model with incomparable advantages in neural circuit study. In this review, we describe the zebrafish visual system and its downstream targets, with special emphasis on their possible roles in prey capture behavior. Prey capture is executed mainly through the visual system and its downstream circuits, including reticulospinal commanding neurons, motor-controlling circuits within the spinal cord, and other un-identified functional units. With the development of approaches in monitoring and manipulating neuronal activity and behavioral assays, we will get deep insights about neural basis for prey capture in near future, which will shed light on elucidating neural circuit mechanisms of behavior.

Circadian regulation of developmental synaptogenesis via the hypocretinergic system.

The circadian clock orchestrates a wide variety of physiological and behavioral processes, enabling animals to adapt to daily environmental changes, particularly the day-night cycle. However, the circadian clock's role in the developmental processes remains unclear. Here, we employ the in vivo long-term time-lapse imaging of retinotectal synapses in the optic tectum of larval zebrafish and reveal that synaptogenesis, a fundamental developmental process for neural circuit formation, exhibits circadian rhythm. This rhythmicity arises primarily from the synapse formation rather than elimination and requires the hypocretinergic neural system. Disruption of this synaptogenic rhythm, by impairing either the circadian clock or the hypocretinergic system, affects the arrangement of the retinotectal synapses on axon arbors and the refinement of the postsynaptic tectal neuron's receptive field. Thus, our findings demonstrate that the developmental synaptogenesis is under hypocretin-dependent circadian regulation, suggesting an important role of the circadian clock in neural development.

TRPC1 is essential for in vivo angiogenesis in zebrafish.

RATIONALE: Wiring vascular and neural networks are known to share common molecular signaling pathways. Activation of transient receptor potential type C channels (TRPCs) has recently been shown to underlie chemotropic guidance of neural axons. It is thus of interest to examine whether TRPCs are also involved in vascular development. OBJECTIVE: To determine the role of TRPC1 in angiogenesis in vivo during zebrafish development. METHODS AND RESULTS: Knockdown of zebrafish trpc1 by antisense morpholino oligonucleotides severely disrupted angiogenic sprouting of intersegmental vessels (ISVs) in zebrafish larvae. This angiogenic defect was prevented by overexpression of a morpholino oligonucleotide-resistant form of zebrafish trpc1 mRNA. Cell transplantation analysis showed that this requirement of Trpc1 for ISV growth was endothelial cell-autonomous. In vivo time-lapse imaging further revealed that the angiogenic defect was attributable to impairment of filopodia extension, migration, and proliferation of ISV tip cells. Furthermore, Trpc1 acted synergistically with vascular endothelial growth factor A (Vegf-a) in controlling ISV growth, and appeared to be downstream to Vegf-a in controlling angiogenesis, as evidence by the findings that Trpc1 was required for Vegf-a-induced ectopic angiogenesis of subintestinal veins and phosphorylation of extracellular signal-regulated kinase. CONCLUSIONS: These results provide the first in vivo evidence that TRPC1 is essential for angiogenesis, reminiscent of the role of TRPCs in axon guidance. It implicates that TRPC1 may represent a potential target for treating pathological angiogenesis.

Transient receptor potential canonical channels in angiogenesis and axon guidance.

Wiring of vascular and neural networks requires precise guidance of growing blood vessels and axons, respectively, to reach their targets during development. Both of the processes share common molecular signaling pathways. Transient receptor potential canonical (TRPC) channels are calcium-permeable cation channels and gated via receptor- or store-operated mechanisms. Recent studies have revealed the requirement of TRPC channels in mediating guidance cue-induced calcium influx and their essential roles in regulating axon navigation and angiogenesis. Dissecting TRPC functions in these physiological processes may provide therapeutic implications for suppressing pathological angiogenesis and improving nerve regeneration.

Long-range retrograde spread of LTP and LTD from optic tectum to retina.

Neural activity can induce persistent strengthening or weakening of synapses, known as long-term potentiation (LTP) or long-term depression (LTD), respectively. As potential cellular mechanisms underlying learning and memory, LTP and LTD are generally regarded as synapse-specific "imprints" of activity, although there is evidence in vitro that LTP/LTD may spread to adjacent synapses. Here, we report that LTP and LTD induced in vivo at retinotectal synapses of Xenopus tadpoles undergo rapid long-range retrograde spread from the optic tectum to the retina, resulting in potentiation and depression of bipolar cell synapses on the dendrites of retinal ganglion cells, respectively. The retrograde spread of LTP and LTD required retrograde signaling initiated by brain-derived neurotrophic factor and nitric oxide in the tectum, respectively. Such bidirectional adjustment of the strength of input synapses in accordance to that of output synapses may serve to coordinate developmental refinement and learning functions of neural circuits.

Celecoxib impairs heart development via inhibiting cyclooxygenase-2 activity in zebrafish embryos.

BACKGROUND: Celecoxib, a cyclooxygenase-2 inhibitor, is a commonly ingested drug that is used by some women during pregnancy. Although use of celecoxib is associated with increased cardiovascular risk in adults, its effect on fetal heart development remains unknown. METHODS: Zebrafish embryos were exposed to celecoxib or other relevant drugs from tailbud stage (10.3-72 h postfertilization). Heart looping and valve formation were examined at different developmental stages by in vivo confocal imaging. In addition, whole mount in situ hybridization was performed to examine drug-induced changes in the expression of heart valve marker genes. RESULTS: In celecoxib-treated zebrafish embryos, the heart failed to undergo normal looping and the heart valve was absent, causing serious blood regurgitation. Furthermore, celecoxib treatment disturbed the restricted expression of the heart valve markers bone morphogenetic protein 4 and versican-but not the cardiac chamber markers cardiac myosin light chain 2, ventricular myosin heavy chain, and atrial myosin heavy chain. These defects in heart development were markedly relieved by treatment with the cyclooxygenase-2 downstream product prostaglandin E2, and mimicked by the cyclooxygenase-2 inhibitor NS398, implying that celecoxib-induced heart defects were caused by the inhibition of cyclooxygenase-2 activity. CONCLUSIONS: These findings provide the first in vivo evidence that celecoxib exposure impairs heart development in zebrafish embryos by inhibiting cyclooxygenase-2 activity.

A protocol for simultaneous Ca2+ and morphology imaging of brain endothelial tip cells in larval zebrafish.

Endothelial tip cells (ETCs) located at growing blood vessels display high morphological dynamics and associated intracellular Ca2+ activities with different spatiotemporal patterns during migration. Examining the Ca2+ activity and morphological dynamics of ETCs will provide an insight for understanding the mechanism of vascular development in organs, including the brain. Here, we describe a method for simultaneous monitoring and relevant analysis of the Ca2+ activity and morphology of growing brain ETCs in larval zebrafish. For complete details on the use and execution of this protocol, please refer to Liu et al. (2020).

Development of light response and GABAergic excitation-to-inhibition switch in zebrafish retinal ganglion cells.

The zebrafish retina has been an important model for studying morphological development of neural circuits in vivo. However, its functional development is not yet well understood. To investigate the functional development of zebrafish retina, we developed an in vivo patch-clamp whole-cell recording technique in intact zebrafish larvae. We first examined the developmental profile of light-evoked responses (LERs) in retinal ganglion cells (RGCs) from 2 to 9 days post-fertilization (dpf). Unstable LERs were first observed at 2.5 dpf. By 4 dpf, RGCs exhibited reliable light responses. As the GABAergic system is critical for retinal development, we then performed in vivo gramicidin perforated-patch whole-cell recording to characterize the developmental change of GABAergic action in RGCs. The reversal potential of GABA-induced currents (E(GABA)) in RGCs gradually shifted from depolarized to hyperpolarized levels during 2-4 dpf and the excitation-to-inhibition (E-I) switch of GABAergic action occurred at around 2.5 dpf when RGCs became light sensitive. Meanwhile, GABAergic transmission upstream to RGCs also became inhibitory by 2.5 dpf. Furthermore, down-regulation of the K(+)/Cl() co-transporter (KCC2) by the morpholino oligonucleotide-based knockdown approach, which shifted RGC E(GABA) towards a more depolarized level and thus delayed the E-I switch by one day, postponed the appearance of RGC LERs by one day. In addition, RGCs exhibited correlated giant inward current (GICs) during 2.5-3.5 dpf. The period of GICs was shifted to 3-4.5 dpf by KCC2 knockdown. Taken together, the GABAergic E-I switch occurs coincidently with the emergence of light responses and GICs in zebrafish RGCs, and may contribute to the functional development of retinal circuits.

Overexpression of Wld(S) or Nmnat2 in mauthner cells by single-cell electroporation delays axon degeneration in live zebrafish.

Axon degeneration is supposed to be a therapeutic target for treating neurodegenerative diseases. Mauthner cells (M-cells) are ideal for studying axons in vivo because of their limited numbers, large size, and long axons. In this study, we labeled M-cells by single-cell electroporation with plasmids expressing DsRed2 or EGFP. Injury-induced axon degeneration in labeled M-cell was imaged under a confocal microscope, and we found that the Mauthner axons started to degenerate about 24 hr after lesion. The Wld(S) protein containing full-length Nmnat1 is well-known for its axon-protective function in many systems. Overexpression of Wld(S) in M-cells also greatly delayed axon degeneration in live zebrafish. Nmnat2 is the only Nmnat highly expressed in brain. Here we demonstrated that overexpression of Nmnat2 in M-cells significantly delayed axon degeneration in vivo, and disruption of the NAD synthesis activity of Nmnat2 markedly attenuated its axon-protective function. All these data show that injury-induced axon degeneration of M-cell has a mechanism similar to that in mammalians and would be a valuable model for studying axon degeneration in vivo.

Rapid BDNF-induced retrograde synaptic modification in a developing retinotectal system.

In cultures of hippocampal neurons, induction of long-term synaptic potentiation or depression by repetitive synaptic activity is accompanied by a retrograde spread of potentiation or depression, respectively, from the site of induction at the axonal outputs to the input synapses on the dendrites of the presynaptic neuron. We report here that rapid retrograde synaptic modification also exists in an intact developing retinotectal system. Local application of brain-derived neurotrophic factor (BDNF) to the Xenopus laevis optic tectum, which induced persistent potentiation of retinotectal synapses, led to a rapid modification of synaptic inputs at the dendrites of retinal ganglion cells (RGCs), as shown by a persistent enhancement of light-evoked excitatory synaptic currents and spiking activity of RGCs. This retrograde effect required TrkB receptor activation, phospholipase Cgamma activity and Ca2+ elevation in RGCs, and was accounted for by a selective increase in the number of postsynaptic AMPA-subtype glutamate receptors at RGC dendrites. Such retrograde information flow in the neuron allows rapid regulation of synaptic inputs at the dendrite in accordance to signals received at axon terminals, a process reminiscent of back-propagation algorithm for learning in neural networks.

One-step generation of zebrafish carrying a conditional knockout-knockin visible switch via CRISPR/Cas9-mediated intron targeting.

The zebrafish has become a popular vertebrate animal model in biomedical research. However, it is still challenging to make conditional gene knockout (CKO) models in zebrafish due to the low efficiency of homologous recombination (HR). Here we report an efficient non-HR-based method for generating zebrafish carrying a CKO and knockin (KI) switch (zCKOIS) coupled with dual-color fluorescent reporters. Using this strategy, we generated hey2zKOIS which served as a hey2 KI reporter with EGFP expression. Upon Cre induction in targeted cells, the hey2zCKOIS was switched to a non-functional CKO allele hey2zCKOIS-invassociated with TagRFP expression, enabling visualization of the CKO alleles. Thus, simplification of the design, and the visibility and combination of both CKO and KI alleles make our zCKOIS strategy an applicable CKO approach for zebrafish.

Piezo1-Mediated Ca2+ Activities Regulate Brain Vascular Pathfinding during Development.

During development, endothelial tip cells (ETCs) located at the leading edge of growing vascular plexus guide angiogenic sprouts to target vessels, and thus, ETC pathfinding is fundamental for vascular pattern formation in organs, including the brain. However, mechanisms of ETC pathfinding remain largely unknown. Here, we report that Piezo1-mediated Ca2+ activities at primary branches of ETCs regulate branch dynamics to accomplish ETC pathfinding during zebrafish brain vascular development. ETC branches display spontaneous local Ca2+ transients, and high- and low-frequency Ca2+ transients cause branch retraction through calpain and branch extension through nitric oxide synthase, respectively. These Ca2+ transients are mainly mediated by Ca2+-permeable Piezo1 channels, which can be activated by mechanical force, and mutating piezo1 largely impairs ETC pathfinding and brain vascular patterning. These findings reveal that Piezo1 and downstream Ca2+ signaling act as molecular bases for ETC pathfinding and highlight a novel function of Piezo1 and Ca2+ in vascular development.