|
|
|
|
|
|
|
||||
| Home Help Feedback Subscriptions Archive Search Table of Contents | ||||
First published online 11 April 2007
doi: 10.1242/dev.004416
| |||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||
Meeting Review |
1 RIKEN Centre for Developmental Biology, Kobe 650-0047, Japan.
2 Temasek Life Sciences Laboratory, National University of Singapore, 117604
Singapore.
e-mails: fumio{at}cdb.riken.jp; karuna{at}tll.org.sg
SUMMARY
The RIKEN Centre for Developmental Biology recently hosted a joint UK-Asian Pacific Developmental Biology Network meeting called `Development and Emergence of Function in the Nervous System'. The meeting's program, which was organized by James Briscoe and Krishnaswamy VijayRaghavan, covered a spectrum of processes and mechanisms in neurodevelopment, ranging from the patterning of neural tissue to the initiation of a functional nervous system. One idea to have emerged during this meeting is that `form underlies function'. Here we discuss some of the themes that were addressed and provide a broad impression of what was a highly stimulating and successful conference.
Introduction
The nervous system is an organ of enormous complexity, and its research brings together diverse fields, such as genetics, molecular and cell biology, physiology and behavioral biology. In the past, studies of neural development mainly followed a molecular morphogenetic approach, whereas those involving the postembryonic nervous system relied more heavily on electrophysiology and functional output. Contemporary developmental neurobiology is now breaking down the barriers that once existed between these two formerly more distinct disciplines of research. This meeting aimed to provide an overview of the `development and emergence of function in the nervous system' within the context of this current trend in neurodevelopment, and brought together researchers working on a variety of model organisms, ranging from Drosophila to mice.
Pattern formation in the nervous system
The assembly of functional neuronal circuits depends on the correct
specification of the various cell types in the developing nervous system. This
was exemplified by work describing the specification of neuronal subtypes in
the vertebrate neural tube and the function of graded Hedgehog (Hh) signaling
in this process. James Briscoe (National Institute of Medical Research,
London, UK) showed that 2- to 3-fold changes in Gli activity in the chick
spinal cord mimic the switch in neuronal subtypes seen upon 2- to 3-fold
changes in Hh concentrations. He found that neural progenitors can integrate
both the duration and concentration of sonic hedgehog (Shh) levels to
determine their neuronal identities, and that this is mediated by a
progressive desensitization to Shh signaling
(Stamataki et al., 2005
). The
diversity of motoneuron subtypes is also known to be specified by unique
combinations of the LIM-homeodomain transcription factors, which are thought
to regulate the expression of downstream guidance receptors and ligands.
Ryuichi Shirasaki (Osaka University, Osaka, Japan) showed that the mouse
dermomyotome is a source of a secreted long-range attractant that is specific
for a motoneuron subtype. Interestingly, the fibroblast growth factor receptor
1 (FGFR1) is specifically expressed in this motoneuron subtype, which is
genetically defined by the LIM code during axon pathfinding. Furthermore, the
LIM code programs these motoneurons to express FGFR1 in vivo, providing
insights into how downstream effectors of the LIM code direct wiring in the
developing central nervous system (CNS)
(Shirasaki et al., 2006). The
specification and patterning of interneurons in the zebrafish neural tube was
described by Kate Lewis (University of Cambridge, UK). Unlike motoneurons, the
axons of interneurons remain within the CNS and their development is not as
well understood. Lewis described her laboratory's studies into the role of Hh,
retinoic acid and Notch/Delta signaling in the formation of zebrafish CiA
interneurons (which are analogous to V1 cells in amniotes).
Evolution of placodal complexity
Although the development of the CNS of all bilateria shares some
commonalities, many additional cell types have evolved independently within
each group. The underlying molecular basis for this complexity can be revealed
by comparative analyses of the cell types and the signaling pathways that
govern their diversification. Sebastian Shimeld (University of Oxford, UK)
discussed the development of sense organs and, in particular, of placode-like
cell types in the sea squirt Ciona intestinalis. Although this simple
chordate does not have a recognizable lens placode, many of the genes that
regulate the development of the lens placode (for a review, see
Medina-Martinez and Jamrich,
2007) in higher vertebrates are present in the Ciona
genome; these genes are expressed in the anterior and lateral invaginations
that later form the oral siphon, the neural complex or the atrial siphon,
structures that are all associated with `sensory' functions
(Shimeld et al., 2005). Tanya
Whitfield (University of Sheffield, UK) discussed the development of the otic
placode in zebrafish, and compared it with that of a jawless fish, the
lamprey. Whereas Hh signaling is necessary and sufficient for posterior
identities in the developing zebrafish ear, changes in otx1
expression (rather than changes in Hh signaling) can account for all the major
differences between the inner ears of jawed and jawless embryos. In
particular, the acquisition of a domain of otx1 expression appears to
have generated the differences in ear development between agnathans and
gnathostomes (Hammond and Whitfield,
2006).
Neurogenesis
Neurons derive from neural progenitors within the neuroepithelium. Mitotic
progenitors generate one daughter that is a functional selfcopy and a second
that becomes a postmitotic neuron, a process that in many species is achieved
by asymmetric cell division (Yu et al.,
2006). The neuronal progenitor neuroblast cells of
Drosophila provide a model system that is widely used to study this
form of cell division, and two talks highlighted aspects of the regulation of
self-renewal and differentiation in these cells and their progeny. On
dividing, a neuroblast generates a small, more differentiated daughter known
as a ganglion mother cell, which inherits the homeodomain protein Prospero.
Andrea Brand (Gurdon Institute, University of Cambridge, UK) described how a
genome-wide survey using the dam methylase modification method revealed that
Prospero binds to and represses the transcription of a number of genes
necessary for neuroblast function, such as those involved in cell cycle
regulation. Interestingly, Prospero also simultaneously binds to and activates
genes involved in neuronal differentiation, suggesting that this protein
serves as an important gene expression pattern switch that operates from
proliferation through to terminal differentiation. She also described an
elegant method used to show that ganglion mother cells undergo multiple cell
divisions in the absence of Prospero, reconfirming Prospero's role at the cell
biological level (Choksi et al.,
2006).
Neuronal polarity and growth cone guidance
Neurons extend multiple processes known as neurites, one of which is
specified as the axon, whereas the remainder become dendrites. Although the
establishment of this neuronal polarity requires extensive remodeling of
microtubules and the actin cytoskeleton, the transport of membrane components
to the growth cone is also essential in axon extension. Michiko Shirane
(Kyushu University, Fukuoka, Japan) showed that protrudin, a MAP-K-regulated
factor, participates in this process by binding to the GTPase RAB11, resulting
in the positive regulation of membrane recycling during axonal extension
(Shirane and Nakayama,
2006).
The mechanisms that determine from which points on the surface of the neuronal cell body neurites begin to extend and how one neurite is selected to be the neuron's sole axon remain obscure. In recent years, the role of the centrosome has come into focus as a site that may integrate intrinsic and extrinsic cues to bias the selection of one neurite. Guy Tear (King's College London, UK) suggested that Mushroom body defect (Mud), a Drosophila homolog of NuMA, might be involved in this process. He showed that this protein localizes to the neuronal centrosome and that a lack of Mud function can result in defects in axon outgrowth.
Mu-ming Poo (University of California, Berkeley, USA and Shanghai
Institutes for Biological Sciences, Shanghai, China) is known for his series
of demonstrations that the turning response of growth cones toward a
chemoattractant is determined by differences in the concentrations of cAMP and
cGMP, and that the true intracellular mediator of this mechanism is local
changes in the concentration of Ca2+ ions
(Henley and Poo, 2004). In his
talk, he extended the analysis to axon-dendrite selection. In his model,
external signals that induce axonogenesis trigger downstream positive-feedback
cascades, allowing one neurite to be committed to an axonal fate, while the
others passively undergo dendritic differentiation. This scenario might open
up new perspectives into the establishment of neuronal polarity.
Projection
The global patterning of axonal projections is of fundamental interest. In
the visual system, continuous positional information in the retina determines
the projection destinations of individual neurons, and some form of
fine-tuning appears to be required in order to maintain nearest-neighbor
interactions between neurons. In Drosophila, retinal axons release
two anterograde signals - Hh and Epidermal growth factor (Egf) - on entering
the lamina, prompting the formation and differentiation of target neurons. In
her talk, Iris Salecker (National Institute of Medical Research, London, UK)
proposed that the ligand Jelly belly and Anaplastic lymphoma kinase work
together to form a third anterograde pathway that mediates the fine-tuning of
retinal axon targeting (Bazigou et al.,
2007).
The olfactory sensory system exhibits a different set of properties. In the
fly, about 50 olfactory sensory neuron subtypes [defined by their exclusive
expression of a single, specific odorant receptor (OR)] project to the primary
olfactory center, known as the antennal lobe. This is in contrast to the
mouse, which has 1000 types of OR. The expression of ORs in the mouse is
highly specific, with a single gene encoding a specific receptor (the `one
neuron - one gene' principle). Axons from neurons that express the same OR
converge on the same glomeruli (relay units in the antennal lobe), thereby
transforming olfactory sensory input into a discrete positional code. Chihiro
Hama (RIKEN Centre for Developmental Biology, Kobe, Japan) presented evidence
that in Drosophila, the on-off state of the Notch signaling pathway
plays a part in this process (Fig.
1A). Olfactory sensory neurons are derived from sensory organ
precursors (SOPs) in the antennal anlage via asymmetric cell divisions, during
which Notch-on classes and one Notch-off class of neurons are generated. The
combination of this binary Notch code with the positional information of the
precursors within the antennal disc provides a degree of regional guidance to
projecting axons and directs the expression of specific ORs, indicating that
the Notch on-off combinatorial code is crucial in coupling projection pattern
with selective OR expression (Endo et al.,
2007).
|
).
Sakano's model of the preliminary roadmaps that are laid down by positional
cues and modulated by neuronal activity-dependent fine-tuning, indicates that
the general principles of neurogenesis hold true in the mammalian olfactory
system as well. In other talks, Paul Whitington (University of Melbourne, Australia) spoke about several guidance molecules that function at specific switch points in pathfinding Drosophila sensory neurons, and Alain Ghysen (INSERM, Montpellier, France) introduced novel and fundamental work on how lateral line neurons project to the CNS in zebrafish in a manner he described as "touching at a distance".
Formation of functional circuits
Repetitive stereotyped behavioral patterns, such as walking and respiration, arise from the programmed firing of motoneurons that are organized into neural circuits. It is thought that these neural networks, known as central pattern generators, are genetically programmed, but how the functional circuit is formed remains obscure. Michael Bate and Sarah Crisp (University of Cambridge, UK) have taken the neuronal activity that drives the sequential muscle contractions along the AP axis of the Drosophila larval body, which underlie the wave-like crawling movements of larvae, as a model for studying the development of a motor circuitry. By visualizing muscle activity using GFP technology, they made real-time observations of the initiation of muscular contractions in late-stage embryos and found that the development of motor activity patterns over time is highly reproducible. This raises the possibility that the central pattern generator engages in the self-tuning of its circuitry via the spontaneous activity of its constituent neurons as it develops.
As the fruit fly metamorphoses from a crawling larva into a walking, flying adult, its nervous system undergoes massive rearrangements. Darren Williams (MRC Centre for Developmental Neurobiology, King's College London, UK) introduced his work on neuron remodeling and the non-apoptotic role that caspase proteases play in large-scale pruning. Alongside this, he described the global role that lineage-specific apoptosis plays in generating adult-specific circuits and how it reveals the modular way in which the nervous system is generated from developmental units termed `hemilineages'. Krishnaswamy VijayRaghavan (National Center for Biological Sciences, Bangalore, India) reported that, upon metamorphosis, several re-arborization events involving motoneurons and interneurons depend on the moulting hormone ecdysone and the intracellular cascade downstream of canonical Wnt signaling. A genetic approach revealed that the post-eclosion changes in these neurons depend on activity, once again highlighting the importance of activity-dependent fine-tuning in neural circuit formation.
In the mammalian hippocampus and olfactory nervous system, new neurons are continuously born even into adulthood, and it is believed that apoptotic cell death serves as a mechanism for pruning away incorrect or unnecessary neurons. Woong Sun (Korea University College of Medicine, Seoul, South Korea) discussed a knockout mouse engineered to lack the pro-apoptotic gene Bax, the study of which revealed that apoptosis plays an adaptive role in fundamental brain functions, such as associated learning.
Plasticity
There is growing evidence that the molecules that control neural circuitry
development also represent the building blocks of experience-driven plasticity
in the adult brain. Dendritic growth, spinogenesis, facilitation of synaptic
plasticity mechanisms and the enhanced expression of neurotrophins, are
processes that are involved in experience-driven plasticity that also occur
during hippocampal and cortical development. Shona Chattarji (NCBS, Bangalore,
India) showed that many of the plasticity mechanisms above are also triggered
in the adult amygdala, the emotional hub of the brain, following an aversive
experience. He found that in rats exposed to chronic stress, dendritic arbors
and spine density are increased in the projection neurons of the lateral
amygdale (Vyas et al., 2003).
A positive correlation was also observed between spinogenesis and enhanced
anxiety-like behavior in transgenic mice overexpressing the neurotrophin BDNF.
This structural remodeling is accompanied by electrophysiological changes at
excitatory glutamatergic synapses. A rat model of fear-conditioning confirmed
that stress experiences cause high levels of fear. Thus, Chattarji suggests
that prolonged stress may leave its mark in the amygdala by forming new
synapses that have an enhanced capacity for subsequent potentiation, thereby
creating an ideal synaptic substrate for the emotional symptoms of stress
disorders.
Long-term potentiation (LTP) of synapses is a form of synaptic plasticity
that is thought to play a crucial role in behavioral learning and that can be
induced by the activation of NMDA-type glutamate receptors. Another form of
synaptic plasticity is long-term depression (LTD), one form of which involves
the downregulation of AMPA-type glutamate receptors that mainly mediate
postsynaptic excitation. LTD can be blocked by LTP. Graham Collingridge
(University of Bristol, UK) reported that this interaction is mediated by a
kinase cascade. LTP is enabled by the activation of NMDA receptors, which
triggers an influx of Ca2+ ions and the activation of a pathway
that involves the PI3 kinase and protein kinase B (AKT). And, as is seen in
signaling downstream of insulin, the end result is the inhibition of glycogen
synthase kinase 3 ß (GSK3ß), which intensifies the downregulation of
the AMPA-type receptors that underpin LTD
(Peineau et al., 2007). This
work shows how controlling the balance of two glutamate receptors can minutely
regulate physiological activity at the synapse.
NMDA receptor-mediated LTP begins with local biochemical reactions that
occur at and around the synaptic junction, but the maintenance of LTP requires
changes in transcriptional regulation as well. Kentaro Abe and Masatoshi
Takeichi (RIKEN CDB, Kobe, Japan) proposed a new mechanism by which
postsynaptic signals via the NMDA receptor can be transduced to the nucleus,
involving the direct nuclear import of ß-catenin, a molecule that also
functions as a cytoplasmic binding-partner of the classic cadherins in cell
adhesion, and as an important downstream factor in canonical Wnt signaling.
Canonical Wnt signal transduction inhibits the degradation of cytoplasmic
ß-catenin, allowing it to enter the nucleus and regulate the
transcription of target genes. Abe and Takeichi found that activation of the
NMDA receptor in hippocampal pyramidal neurons causes calpain-mediated
cleavage of ß-catenin. The resultant molecular fragment resists
cytoplasmic degradation and accumulates in the nucleus, where it demonstrably
functions as a transcriptional activator for at least one target of the
canonical Wnt pathway. In novelty exploration tests, mice showed this same
calpain activity-dependent cleavage of ß-catenin, evidence that this
novel signaling pathway operates in vivo as well
(Abe and Takeichi, 2007).
Conclusion
This meeting featured research into nervous system development primarily in Drosophila, zebrafish and mouse, but the degree of commonality among the questions that concern the development and functioning of the nervous systems of these phylogenetically distant taxa was nonetheless surprising. One main question addressed was how patterning and projection mechanisms arrange initially undifferentiated cells into a highly orchestrated neuronal circuitry. The relationship between the structural changes that take place in development and the plasticity of functional circuits was also striking. The concept `form underlies function' emerged from these talks. At the same time, studies described by Sakano, VijayRaghavan and Bate highlighted developmental contexts in which `function underlies form'. Thus, the relationship between function and form seems more mutually coherent than previously thought. In this sense, the advent of tools and methodologies that simultaneously enable the high-resolution study of the form and function of the neuronal components within a circuit in real time, represents a wonderful opportunity for scientists to push back the horizons and open up new insights as never before.
ACKNOWLEDGMENTS
We thank Doug Sipp for editing the manuscript and the meeting participants who allowed us to include their work. We are grateful to the UK Foreign and Commonwealth Office and the Asia-Pacific Developmental Biology Network (APDBN; www.apdbn.org). We apologize that we could not refer to the work of all participants owing to space limitations.
REFERENCES
Abe, K. and Takeichi, M. (2007). NMDA-receptor
activation induces calpain-mediated beta-catenin cleavages for triggering gene
expression. Neuron 53,387
-397.[CrossRef][Medline]
Bazigou, E., Apitz, H., Johansson, J., Loren, C. E., Hirst, E.
M., Chen, P. L., Palmer, R. H. and Salecker, I. (2007).
Anterograde Jelly belly and Alk receptor tyrosine kinase signaling mediates
retinal axon targeting in Drosophila. Cell
128,961
-975.[CrossRef][Medline]
Choksi, S. P., Southall, T. D., Bossing, T., Edoff, K., de Wit,
E., Fischer, B. E., van Steensel, B., Micklem, G. and Brand, A. H.
(2006). Prospero acts as a binary switch between self-renewal and
differentiation in Drosophila neural stem cells. Dev.
Cell 11,775
-789.[CrossRef][Medline]
Endo, K., Aoki, T., Yoda, Y., Kimura, K. and Hama, C.
(2007). Notch signal organizes the Drosophila olfactory circuitry
by diversifying the sensory neuronal lineages. Nat.
Neurosci. 10,153
-160.[CrossRef][Medline]
Hammond, K. L. and Whitfield, T. T. (2006). The
developing lamprey ear closely resembles the zebrafish otic vesicle: otx1
expression can account for all major patterning differences.
Development 133,1347
-1357.
Henley, J. and Poo, M. M. (2004). Guiding
neuronal growth cones using Ca2+ signals. Trends Cell
Biol. 14,320
-330.[CrossRef][Medline]
Medina-Martinez, O. and Jamrich, M. (2007).
Foxe view of lens development and disease. Development
134,1455
-1463.
Peineau, S., Taghibiglou, C., Bradley, C., Wong, T. P., Liu, L.,
Lu, J., Lo, E., Wu, D., Saule, E., Bouschet, T. et al.
(2007). LTP Inhibits LTD in the Hippocampus via Regulation of
GSK3beta. Neuron 53,703
-717.[CrossRef][Medline]
Serizawa, S., Miyamichi, K., Takeuchi, H., Yamagishi, Y.,
Suzuki, M. and Sakano, H. (2006). A neuronal identity code
for the odorant receptor-specific and activity-dependent axon sorting.
Cell 127,1057
-1069.[CrossRef][Medline]
Shimeld, S. M., Purkiss, A. G., Dirks, R. P., Bateman, O. A.,
Slingsby, C. and Lubsen, N. H. (2005). Urochordate
betagamma-crystallin and the evolutionary origin of the vertebrate eye lens.
Curr. Biol. 15,1684
-1689.[CrossRef][Medline]
Shirane, M. and Nakayama, K. I. (2006).
Protrudin induces neurite formation by directional membrane trafficking.
Science 314,818
-821.
Shirasaki, R., Lewcock, J. W., Lettieri, K. and Pfaff, S. L.
(2006). FGF as a target-derived chemoattractant for developing
motor axons genetically programmed by the LIM code.
Neuron 50,841
-853.[CrossRef][Medline]
Stamataki, D., Ulloa, F., Tsoni, S. V., Mynett, A. and Briscoe,
J. (2005). A gradient of Gli activity mediates graded Sonic
Hedgehog signaling in the neural tube. Genes Dev.
19,626
-641.
Vyas, A., Bernal, S. and Chattarji, S. (2003).
Effects of chronic stress on dendritic arborization in the central and
extended amygdala. Brain Res.
965,290
-294.[CrossRef][Medline]
Yu, F., Kuo, C. T. and Jan, Y. N. (2006).
Drosophila neuroblast asymmetric cell division: recent advances and
implications for stem cell biology. Neuron
51, 13-20.[CrossRef][Medline]
CiteULike 
Complore 
Connotea 
Del.icio.us 
Digg 
Reddit 
Technorati 
Twitter What's this?
| |||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||
