Ocular Necessities: A Neuroethological Perspective on Vertebrate Visual Development.

Background: By examining species-specific innate behaviours, neuroethologists have characterized unique neural strategies and specializations from throughout the animal kingdom. Simultaneously, the field of evolutionary developmental biology (informally, "evo-devo") seeks to make inferences about animals' evolutionary histories through careful comparison of developmental processes between species, because evolution is the evolution of development. Yet despite the shared focus on cross-species comparisons, there is surprisingly little crosstalk between these two fields.

Serotonin Strengthens a Developing Glutamatergic Synapse through a PI3K-Dependent Mechanism.

It is well established that, during neural circuit development, glutamatergic synapses become strengthened via NMDA receptor (NMDAR)-dependent upregulation of AMPA receptor (AMPAR)-mediated currents. In addition, however, it is known that the neuromodulator serotonin is present throughout most regions of the vertebrate brain while synapses are forming and being shaped by activity-dependent processes. This suggests that serotonin may modulate or contribute to these processes.

Protocol for measuring visual preferences of freely swimming Xenopus laevis tadpoles.

Xenopus tadpoles display innate visually guided behaviors which are thought to promote survival by guiding them toward sources of food and away from predators. Experimentally, studying these behaviors can provide insight into the formation and function of the neural circuits which underlie them. Here, we present a protocol for measuring visual preferences of freely swimming tadpoles.

A circadian-dependent preference for light displayed by Xenopus tadpoles is modulated by serotonin.

Innate visually guided behaviors are thought to promote survival by guiding organisms to sources of food and safety and away from harm without requiring learning. Historically, innate behaviors have been considered hard-wired and invariable, but emerging evidence shows that many innate behaviors are flexible and complex due to modulation. Here, we investigate the modulation of the innate preference for light displayed by the tadpole, an exceptionally invasive and well-studied organism that is known to display several different innate visually guided behaviors.

Electrophysiological Approaches to Studying Normal and Abnormal Retinotectal Circuit Development in the Tadpole.

The tadpole retinotectal projection is the main component of the amphibian visual system. It comprises the retinal ganglion cells (RGCs) in the eye, which project an axon to synapse onto tectal neurons in the optic tectum. There are many attributes of this relatively simple projection that render it uniquely well-suited for studying the functional development of neural circuits.

An Innate Color Preference Displayed by Tadpoles Is Persistent and Requires the Tegmentum.

Many animals, especially those that develop externally, are equipped with innate color preferences that promote survival. For example, tadpoles are known to phototax most robustly towards mid-spectrum ("green") wavelengths of light while avoiding shorter ("blue") wavelengths. The innate preference to phototax towards green likely promotes survival by guiding the tadpoles to green aquatic plants-their source of both food and safety.

Presenilin Regulates Retinotectal Synapse Formation through EphB2 Receptor Processing.

As the catalytic component of γ-secretase, presenilin (PS) has long been studied in the context of Alzheimer's disease through cleaving the amyloid precursor protein. PS/γ-secretase, however, also cleaves a multitude of single-pass transmembrane proteins that are important during development, including Notch, the netrin receptor DCC, cadherins, drebrin-A, and the EphB2 receptor. Because transgenic PS-KO mice do not survive to birth, studies of this molecule during later embryonic or early postnatal stages of development have been carried out using cell cultures or conditional knock-out mice, respectively.

Preparations and Protocols for Whole Cell Patch Clamp Recording of Xenopus laevis Tectal Neurons.

The Xenopus tadpole retinotectal circuit, comprised of the retinal ganglion cells (RGCs) in the eye which form synapses directly onto neurons in the optic tectum, is a popular model to study how neural circuits self-assemble. The ability to carry out whole cell patch clamp recordings from tectal neurons and to record RGC-evoked responses, either in vivo or using a whole brain preparation, has generated a large body of high-resolution data about the mechanisms underlying normal, and abnormal, circuit formation and function. Here we describe how to perform the in vivo preparation, the original whole brain preparation, and a more recently developed horizontal brain slice preparation for obtaining whole cell patch clamp recordings from tectal neurons.

An NMDA receptor-dependent mechanism for subcellular segregation of sensory inputs in the tadpole optic tectum.

In the vertebrate CNS, afferent sensory inputs are targeted to specific depths or layers of their target neuropil. This patterning exists ab initio, from the very beginning, and therefore has been considered an activity-independent process. However, here we report that, during circuit development, the subcellular segregation of the visual and mechanosensory inputs to specific regions of tectal neuron dendrites in the tadpole optic tectum requires NMDA receptor activity.

An Evolutionarily Conserved Mechanism for Activity-Dependent Visual Circuit Development.

Neural circuit development is an activity-dependent process. This activity can be spontaneous, such as the retinal waves that course across the mammalian embryonic retina, or it can be sensory-driven, such as the activation of retinal ganglion cells (RGCs) by visual stimuli. Whichever the source, neural activity provides essential instruction to the developing circuit.

Fragile X mental retardation protein knockdown in the developing Xenopus tadpole optic tectum results in enhanced feedforward inhibition and behavioral deficits.

Background: Fragile X Syndrome is the leading monogenetic cause of autism and most common form of intellectual disability. Previous studies have implicated changes in dendritic spine architecture as the primary result of loss of Fragile X Mental Retardation Protein (FMRP), but recent work has shown that neural proliferation is decreased and cell death is increased with either loss of FMRP or overexpression of FMRP. The purpose of this study was to investigate the effects of loss of FMRP on behavior and cellular activity.

Early development and function of the Xenopus tadpole retinotectal circuit.

The retinotectal circuit is the major component of the amphibian visual system. It is comprised of the retinal ganglion cells (RGCs) in the eye, which project their axons to the optic tectum and form synapses onto postsynaptic tectal neurons. The retinotectal circuit is relatively simple, and develops quickly: Xenopus tadpoles begin displaying retinotectal-dependent visual avoidance behaviors by approximately 7-8 days post-fertilization, early larval stage.

Systems Neuroscience: How the Cortex Contributes to Skilled Movements.

A recent study demonstrates how acute neural circuit manipulations can lead to overestimations of circuit function, while chronic manipulations can reveal compensatory modes of plasticity that restore behavior.

A population of gap junction-coupled neurons drives recurrent network activity in a developing visual circuit.

In many regions of the vertebrate brain, microcircuits generate local recurrent activity that aids in the processing and encoding of incoming afferent inputs. Local recurrent activity can amplify, filter, and temporally and spatially parse out incoming input. Determining how these microcircuits function is of great interest because it provides glimpses into fundamental processes underlying brain computation.

The horizontal brain slice preparation: a novel approach for visualizing and recording from all layers of the tadpole tectum.

The Xenopus tadpole optic tectum is a multisensory processing center that receives direct visual input as well as nonvisual mechanosensory input. The tectal neurons that comprise the optic tectum are organized into layers. These neurons project their dendrites laterally into the neuropil where visual inputs target the distal region of the dendrite and nonvisual inputs target the proximal region of the same dendrite.

Region-specific regulation of voltage-gated intrinsic currents in the developing optic tectum of the Xenopus tadpole.

Across the rostrocaudal (RC) axis of the Xenopus tadpole optic tectum exists a developmental gradient. This gradient has served as a useful model to study many aspects of synapse and dendrite maturation. To compliment these studies, we characterized how the intrinsic excitability, the ease in which a neuron can fire action potentials, might also be changing across the same axis.

Modeling human neurodevelopmental disorders in the Xenopus tadpole: from mechanisms to therapeutic targets.

The Xenopus tadpole model offers many advantages for studying the molecular, cellular and network mechanisms underlying neurodevelopmental disorders. Essentially every stage of normal neural circuit development, from axon outgrowth and guidance to activity-dependent homeostasis and refinement, has been studied in the frog tadpole, making it an ideal model to determine what happens when any of these stages are compromised. Recently, the tadpole model has been used to explore the mechanisms of epilepsy and autism, and there is mounting evidence to suggest that diseases of the nervous system involve deficits in the most fundamental aspects of nervous system function and development.

Presenilin 1 regulates homeostatic synaptic scaling through Akt signaling.

Neurons adapt to long-lasting changes in network activity, both in vivo and in vitro, by adjusting their synaptic strengths to stabilize firing rates. We found that homeostatic scaling of excitatory synapses was impaired in hippocampal neurons derived from mice lacking presenilin 1 (Psen1(-/-) mice) or expressing a familial Alzheimer's disease-linked Psen1 mutation (Psen1(M146V)). These findings suggest that deficits in synaptic homeostasis may contribute to brain dysfunction in Alzheimer's disease.

A novel role for {gamma}-secretase: selective regulation of spontaneous neurotransmitter release from hippocampal neurons.

With a multitude of substrates, γ-secretase is poised to control neuronal function through a variety of signaling pathways. Presenilin 1 (PS1) is an integral component of γ-secretase and is also a protein closely linked to the etiology of Alzheimer's disease (AD). To better understand the roles of γ-secretase and PS1 in normal and pathological synaptic transmission, we examined evoked and spontaneous neurotransmitter release in cultured hippocampal neurons derived from PS1 knock-out (KO) mice.

Multisensory integration in mesencephalic trigeminal neurons in Xenopus tadpoles.

Mesencephalic trigeminal (M-V) neurons are primary somatosensory neurons with somata located within the CNS, instead of in peripheral sensory ganglia. In amphibians, these unipolar cells are found within the optic tectum and have a single axon that runs along the mandibular branch of the trigeminal nerve. The axon has collaterals in the brain stem and is believed to make synaptic contact with neurons in the trigeminal motor nucleus, forming part of a sensorimotor loop.

Visual avoidance in Xenopus tadpoles is correlated with the maturation of visual responses in the optic tectum.

The optic tectum is central for transforming incoming visual input into orienting behavior. Yet it is not well understood how this behavior is organized early in development and how it relates to the response properties of the developing visual system. We designed a novel behavioral assay to study the development of visually guided behavior in Xenopus laevis tadpoles.

There's more than one way to scale a synapse.

TNFalpha has been proposed to underlie synaptic scaling, but the mechanism and functional significance of this remain unclear. In this issue of Neuron, Cingolani et al. demonstrate that TNFalpha can mediate scaling through the regulation of beta3 integrins.

Development and spike timing-dependent plasticity of recurrent excitation in the Xenopus optic tectum.

Much of the information processing in the brain occurs at the level of local circuits; however, the mechanisms underlying their initial development are poorly understood. We sought to examine the early development and plasticity of local excitatory circuits in the optic tectum of Xenopus laevis tadpoles. We found that retinal input recruits persistent, recurrent intratectal synaptic excitation that becomes more temporally compact and less variable over development, thus increasing the temporal coherence and precision of tectal cell spiking.

Dynamics underlying synaptic gain between pairs of cortical pyramidal neurons.

Changes in connectivity between pairs of neurons can serve as a substrate for information storage and for experience-dependent changes in neuronal circuitry. Early in development, synaptic contacts form and break, but how these dynamics influence the connectivity between pairs of neurons is not known. Here we used time-lapse imaging to examine the synaptic interactions between pairs of cultured cortical pyramidal neurons, and found that the axon-dendrite contacts between each neuronal pair were composed of both a relatively stable and a more labile population.

Homeostatic regulation of intrinsic excitability and synaptic transmission in a developing visual circuit.

One of the major challenges faced by the developing visual system is how to stably process visual information, yet at the same time remain flexible enough to accommodate growth and plasticity induced by visual experience. We find that in the Xenopus retinotectal circuit, during a period in development when the retinotectal map undergoes activity-dependent refinement and visual inputs strengthen, tectal neurons adapt their intrinsic excitability such that a stable relationship between the total level of synaptic input and tectal neuron spike output is conserved. This homeostatic balance between synaptic and intrinsic properties is maintained, in part, via regulation of voltage-gated Na+ currents, resulting in a stable neuronal input-output function.