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First published online 28 August 2008
doi: 10.1242/dev.023200
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1 Department of Molecular and Cellular Biology, Center for Brain Science, Broad
Institute, Harvard Stem Cell Institute, Harvard University, 16 Divinity
Avenue, Cambridge, MA 02138, USA.
2 Developmental Genetics Program, New York University School of Medicine, New
York, NY 10016, USA.
Author for correspondence (e-mail:
schier{at}mcb.harvard.edu)
Accepted 31 July 2008
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SUMMARY |
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TOP
SUMMARY
INTRODUCTION
MATERIALS AND METHODS
RESULTS
DISCUSSION
REFERENCES |
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Key words: Neurogenesis, Trigeminal sensory ganglia, Trp, Zebrafish
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INTRODUCTION |
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TOP
SUMMARY
INTRODUCTION
MATERIALS AND METHODS
RESULTS
DISCUSSION
REFERENCES |
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). The
vertebrate somatosensory system consists of sets of sensory ganglia located in
the peripheral nervous system (PNS) (for a review, see
Lynn, 1975). Trigeminal
sensory ganglia innervate most of the head
(Noden, 1980), whereas the
dorsal root ganglia (DRG) flank the spinal cord and innervate the body
(Swett and Woolf, 1985).
Trigeminal sensory neurons project to several brainstem nuclei, whereas DRG
neurons send afferent axons to the spinal cord (for a review, see
Marmigere and Ernfors,
2007).
The multimodal nature of the information detected by the somatosensory
system is reflected in the neuronal diversity of sensory ganglia (for reviews,
see Julius and Basbaum, 2001;
Marmigere and Ernfors, 2007).
Two major subpopulations of somatosensory neurons can be distinguished: the
proprioceptive neurons transduce innocuous stimuli such as light touch,
whereas the nociceptive neurons detect potentially harmful stimuli. To cover a
wide range of sensory information, nociceptive neurons express diverse
channels and receptors that respond to these stimuli. For example, TrpV1 is a
heat sensing channel expressed in thermosensitive neurons
(Caterina et al., 1997),
whereas TrpA1 is expressed in a subset of neurons responsive to chemical
irritants such as allyl isothiocyanate (mustard oil), the pungent ingredient
of mustard (Bandell et al.,
2004; Jordt et al.,
2004). Another subset of neurons is defined by expression of the
P2X3 receptor, an ATP sensor involved in the modulation of nociceptive signals
(Chen et al., 1995). Thus, in
contrast to other sensory systems, the somatosensory ganglia contain a diverse
array of sensory neurons that are tuned to very distinct classes of stimuli.
How this diversity is achieved during development is poorly understood.
Studies of the central nervous systems (CNS) in both vertebrates and
invertebrates have revealed that the temporal pattern of neuron specification
contributes to the generation of neuronal diversity (for a review, see
Pearson and Doe, 2004). During
development of Drosophila melanogaster, for example, neuroblasts
undergo stem cell-like divisions to generate neuronal progeny in an ordered
sequence (Truman and Bate,
1988; Pearson and Doe,
2003). Similarly, different neurons of the layered mammalian
cortex form at precise developmental times (for a review, see
McConnell, 1995). Neurons
located deep in the cortex are born before neurons that populate more
superficial layers, resulting in an inside out progression of neurogenesis. In
both systems, progenitors gradually lose competence to generate early-born
fates. In the PNS, cell birthdating and genetic studies in mouse and chick
suggest that DRG neurons derive from three waves of neurogenesis
(Carr and Simpson, 1978;
Frank and Sanes, 1991;
Lawson and Biscoe, 1979;
Ma et al., 1999;
Maro et al., 2004;
Marmigere and Ernfors, 2007).
The second wave gives rise to the majority of proprioceptive and nociceptive
neurons, whereas the first and third waves generate predominantly
proprioceptive and nociceptive neurons, respectively. It is unclear whether
similar or different strategies are used during the diversification of
trigeminal sensory neurons or how different nociceptive subsets are specified.
Here, we address these issues using the zebrafish trigeminal ganglia as a
model system.
Similar to other vertebrates, the trigeminal sensory ganglia in zebrafish
form on either side of the head, between the eye and ear
(Fig. 1A). The first trigeminal
sensory neurons are born at around 11 hours post fertilization (hpf) and
rapidly assemble into a ganglion (Knaut et
al., 2005). By 24 hpf, the ganglia mediate the response to
mechanical stimuli (Saint-Amant and
Drapeau, 1998) and chemical irritants (D.P. and A.F.S.,
unpublished), resulting in a highly stereotypic escape behavior. It has
remained unclear how the different modalities within the trigeminal ganglia
are generated. To address this issue, we analyzed how the timing of
neurogenesis regulates trigeminal sensory neuron specification. We developed a
novel technology (BAPTISM) to compare neuronal birth date and specification in
vivo and interfered with early or late periods of neurogenesis. Our results
indicate that the full repertoire of trigeminal sensory neuron cell types and
larval behaviors depends on early neurogenesis.
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MATERIALS AND METHODS |
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TOP
SUMMARY
INTRODUCTION
MATERIALS AND METHODS
RESULTS
DISCUSSION
REFERENCES |
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).
huc:kaede;p2x3b:egfp and
huc:kaede;trpa1b:egfp embryos were
generated by breeding homozygous adults. neurogenin1hi1059
homozygous embryos were generated by inbreeding heterozygous adults and
identified by their touch insensitivity at 24 hpf.
Whole-mount in situ hybridization and antibody staining
The zebrafish trpv1 cDNA was generated by performing RT-PCR with
Superscript II (Invitrogen) using primers based on the sequence from 5'
and 3' RACE (FirstChoice RLM-RACE, Ambion) and Ensembl exon predictions.
Full-length sequence has been deposited in GenBank under accession number
EU423314. The huc cDNA was obtained from GenBank (accession number
AI959250); the p2x3a cDNA was obtained from the Seguela laboratory
(Kucenas et al., 2006) and the
p2x3b cDNA was obtained from the Voigt laboratory
(Boue-Grabot et al., 2000).
Preparation of RNA probes and in situ hybridization were performed as
described previously (Ober and
Schulte-Merker, 1999). RNA probes against trpa1b, trpv1,
p2x3a, p2x3b and huc were labeled with DIG (Roche) and detected
with an anti-DIG antibody (Roche) using NBT/BCIP (Roche). Immunohistochemistry
was performed as described (Trevarrow et
al., 1990). Antibodies against HuC (Molecular Probe) and HNK-1
were diluted 1:500 and detected using an anti-mouse antibody conjugated to HRP
(Jackson Immunolab) and the Cy3-tyramide system (NEN Life Science). Antibodies
against phospho-histone H3 (Upstate) were diluted 1:250 and detected using an
anti-rabbit antibody conjugated to FITC (Jackson Immunolab).
Morpholino injections
neurogenin1 morphants were generated by injection of 6 ng of
neurogenin1 morpholino (5'-cgatctccattgttgataacctta-3')
(Genetools) at the one-cell stage.
BrdU birthdating analysis
Embryos aged between 24 hpf and 92 hpf were anesthetized with Tricaine
(Sigma) and immobilized on a plate of 3% agarose. BrdU 100 mM (5 µl; Sigma)
was injected into the brain ventricle. Injected embryos were allowed to
develop until 96 hpf when they were fixed with 4% paraformaldehyde (Sigma).
Embryos were permeabilized with proteinase K (30 mg/ml; Sigma) and stained
using antibodies against HuC (Molecular Probes) and BrdU (Becton-Dickinson).
HuC was revealed by an anti-mouse IgG2
b antibody coupled with
horseradish peroxidase using the tyramide amplification system (Cy3) (NEN Life
Science). Embryos were then treated for 1 hour with 2 M HCl to expose the
incorporated BrdU. BrdU antibody was revealed by an anti-mouse IgG1 antibody
coupled to HRP (Vector Laboratories) using the tyramide amplification system
(FITC) (NEN Life Science). Embryos were mounted in 0.3% agarose and imaged
with a Pascal confocal microscope using a 40x water immersion objective
(Zeiss). Double labeling for BrdU and HuC was used to identify neurons that
were born after BrdU injection. The average of neurons born after a specific
time point was obtained by adding the number of double-labeled neurons
detected in each ganglion divided by the total number of ganglia analyzed. The
average of neurons born between 24 hpf and 72 hpf was obtained by adding the
number of double-labeled neurons detected in each ganglion when BrdU was
injected at 24, 28, 32, 36, 40, 44, 48, 52, 56, 60, 64 and 68 hpf divided by
the total number of ganglia analyzed.
BAPTI and BAPTISM methods
For BAPTI, fish homozygous for huc:kaede were used. For
BAPTISM, huc:kaede;p2x3b:egfp and
trpa1b:egfp; huc:kaede embryos were used. Embryos
were mounted in 0.3% agarose. Kaede was converted from green to red
fluorescence at 24 hpf by exposing the whole trigeminal sensory ganglion to
405 nm light for 1 minute. Embryos were allowed to develop until 72 hpf and
imaged with a Pascal confocal inverted microscope using a 25x water
immersion objective (Zeiss). For BAPTISM, a second conversion was performed on
the whole trigeminal sensory ganglion as described above and embryos were
imaged again following the second conversion.
Blocking cell proliferation
Wild-type and neurogenin1 morphant embryos were incubated in a
mixture of 2% DMSO, 20 mM hydroxyurea and 150 µM aphidicolin at 20 hpf,
whereas mock-treated embryos were incubated in 2% DMSO alone. Embryos were
stained using anti-phospho histone H3 antibody (Upstate) and HuC antibody
(Molecular Probes). Primary antibodies were recognized using FITC-anti-rabbit
and rhodamine-anti-mouse secondary antibodies.
Behavioral assays
Zebrafish larvae were placed into a 10 cm diameter well dish. The touch
assay was carried out by poking the embryo on its face with a glass needle.
Response was scored as positive if the fish escaped following touch. Allyl
isothiocyanate (mustard oil) (Sigma) was diluted in DMSO (1:100) and was
delivered by gently streaming liquid out of an injection needle onto the face
of the larva. The flow was adjusted so that the fish would not respond to an
equivalent dose of DMSO.
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RESULTS |
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TOP
SUMMARY
INTRODUCTION
MATERIALS AND METHODS
RESULTS
DISCUSSION
REFERENCES |
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). To
study the temporal pattern of neurogenesis in the trigeminal sensory ganglion
in zebrafish, we first analyzed the expression of the zebrafish homologue of
HuC (Kim et al., 1996).
huc mRNA highlighted the first differentiated trigeminal neurons at
11 hours post fertilization (hpf) on each side of the head
(Fig. 1B). Each ganglion
contained 14±2 neurons (Fig.
1D). By the time the trigeminal sensory ganglia are responsive to
external stimuli (24 hpf), each ganglion contained an average of 31±1
neurons (Fig. 1C,D). To follow
the development of the trigeminal sensory ganglia at later stages, we used a
transgene that expressed the fluorescent protein Kaede under the control of
the huc promoter (Sato et al.,
2006). We found that at 24 hpf each trigeminal sensory ganglion
had an average size of 37±3 neurons and by 72 hpf reached an average
size of 53±6 neurons (Table
1; Fig. 2B;
Fig. 6A; see Movie 3 in the
supplementary material). To gain further insight into the temporal pattern of
trigeminal neurogenesis after 24 hpf, we used 5-bromo-2-deoxyuridine (BrdU)
incorporation. Between 24 hpf and 92 hpf, a single injection of BrdU was given
per embryo. The time points for injection were separated by 4-hour intervals,
because BrdU remained available for incorporation for about 4 hours after
injection (see Fig. S1 in the supplementary material). At 96 hpf, double
labeling for BrdU and HuC was used to identify neurons that were born before
or after BrdU injection (Fig.
1E; see Movie 1 in the supplementary material). This analysis
revealed that new trigeminal neurons arose continuously from 24 hpf to 96 hpf
(Fig. 1G). The number of new
neurons added to a single ganglion per 4-hour interval ranged from one to
eight with an average of 2.03±0.48 neurons. This rate of neurogenesis
leads to an estimated addition of 23±4 neurons per ganglion from 24 hpf
to 72 hpf, consistent with the increase of HuC-expressing neurons from
37±3 at 24 hpf to 53±6 at 72 hpf
(Table 1;
Fig. 2B;
Fig. 6A; see Movie 3 in the
supplementary material). Taken together, our analysis indicates that
neurogenesis in trigeminal sensory ganglia consists of an early burst shortly
after 11 hpf and a continuous slower phase after 24 hpf. We refer to
trigeminal sensory neurons born before and after 24 hpf as early-born and
late-born neurons, respectively.
|
). The
converted Kaede remains stable for several days
(Hatta et al., 2006;
Kimura et al., 2006). To
specifically label early-born trigeminal sensory neurons, Kaede was
photoconverted at 24 hpf in transgenic embryos expressing Kaede under the
control of 
6 kb of huc cis-regulatory region
(huc:kaede) (Sato et
al., 2006). This resulted in the red-fluorescent labeling of
neurons born before 24 hpf. At 72 hpf, these early-born trigeminal sensory
neurons were still evident by expression of the converted, red-fluorescent
Kaede (huc:kaedered)
(Fig. 2B, white arrows).
Because the huc:kaede transgene continues to be expressed in
these neurons, they also expressed de novo synthesized unconverted
green-fluorescent Kaede (huc:kaedered +
huc:kaedegreen)
(Fig. 2B, white arrows). By
contrast, neurons born after 24 hpf did not contain converted red-fluorescent
Kaede but only contained the unconverted green-fluorescent Kaede
(huc:kaedegreen)
(Fig. 2B, white arrowheads).
Our analysis confirmed the presence of early-born and late-born neurons in the
trigeminal sensory ganglia of 72 hpf zebrafish embryos. Of the 53±6
neurons per ganglion present at 72 hpf
(Table 1;
Fig. 2B; see Movie 3 in the
supplementary material), 35±4 were born before 24 hpf
(Table 1;
Fig. 2B, white arrows; see
Movie 3 in the supplementary material), whereas 18±3 neurons were added
after 24 hpf (Table 1;
Fig. 2B, white arrowheads; see
Movie 3 in the supplementary material). These results are consistent with the
observations that each ganglion contains 37±3
huc:kaede-expressing neurons at 24 hpf
(Table 1;
Fig. 6A) and that 23±4
neurons are added per ganglion based on BrdU labeling
(Fig. 1G). BAPTI thus supports
and extends the findings obtained using BrdU and makes it possible to analyze
the temporal dynamics of neurogenesis in living zebrafish embryos.
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We applied BAPTISM to investigate whether early-born and late-born neurons
contribute to different subpopulations of trigeminal sensory neurons. We
focused on two subpopulations of neurons: those expressing trpa1b and
those expressing p2x3b. Both genes are expressed in the trigeminal
sensory ganglia of zebrafish starting at 24 hpf
(Kucenas et al., 2006) (D.P.
and A.F.S., unpublished). We used transgenic zebrafish expressing EGFP under
the control of the cis-regulatory regions of p2x3b or
trpa1b. Both transgenes reflect the expression patterns of the
endogenous genes (Kucenas et al.,
2006) (M.C. and A.F.S., unpublished). BAPTISM analysis of embryos
carrying the p2x3b:egfp transgene revealed that both
early-born and late-born neurons contributed to the p2x3b-expressing
subpopulation (Fig. 4A,B, green
arrows and arrowheads) (see Movies 4 and 5 in the supplementary material). Per
ganglion, 14±1 p2x3b-expressing neurons were derived from
early-born neurons, and 3±1 p2x3b-expressing neurons were
derived from late-born neurons (Table
1; Fig. 4A,B,E,
green arrows and arrowheads) (see Movies 4 and 5 in the supplementary
material). This indicated that both early-born and late-born neurons have the
potential to form p2x3b-expressing neurons. The specification of the
p2x3b-expressing subpopulation of trigeminal sensory neurons
therefore appears to be determined independently of birthdate. BAPTISM
analysis of trpa1b:egfp-expressing embryos revealed that
early-born neurons contributed to the trpa1b-expressing neurons
(Fig. 4C,D,E green arrows) (see
Movies 6 and 7 in the supplementary material). Per ganglion, 13±2
trpa1b-expressing neurons were derived from early-born neurons
(Table 1;
Fig. 4C,D,E, green arrows; see
Movies 6 and 7 in the supplementary material). By contrast, none of the
late-born neurons expressed trpa1b
(Fig. 4C-E, white arrowheads;
see Movies 6 and 7 in the supplementary material). Of the 132 late-born
neurons analyzed in seven
huc:kaede;trpa1b:egfp embryos, none
expressed trpa1b:egfp
(Table 1;
Fig. 4C-E; see Movies 6 and 7
in the supplementary material). This indicates that trpa1b-expressing
neurons are exclusively formed from early-born neurons, and that late-born
neurons do not contribute to this subset of trigeminal sensory neurons. These
results suggest that early-born neurons are competent to form both
trpa1b-expressing and p2x3b-expressing neurons, whereas
late-born neurons are restricted in their cell type specification.
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To create embryos that lacked late-born neurons, we blocked cell
proliferation after 24 hpf by treating embryos with anti-proliferative drugs
(Lyons et al., 2005).
Phospho-histone H3 labeling indicated that treated embryos displayed a strong
reduction of mitotic cells (Fig.
6H,J). To further analyze the formation and survival of neurons
after treatment, BAPTI was used to label neurons at 24 hpf (see Fig. S2 in the
supplementary material). At 72 hpf, treated embryos contained 32±3
early-born neurons (huc:kaedered) and only
3±1 late-born neurons (huc:kaedegreen)
(for a total of 34±3 neurons), as opposed to 35±4 early-born
neurons and 18±3 late-born neurons (for a total of 53±6 neurons)
in mock-treated embryos (Table
1; see Fig. S2 in the supplementary material). These results
reveal that anti-proliferation treatment does not affect the survival of
early-born neurons but strongly reduces the formation of late-born neurons.
Trigeminal sensory ganglia consisting of early-born neurons still expressed
p2x3b, p2x3b:egfp, trpa1b and trpa1b:egfp
(Fig. 5B,D,F,H). Similar to
untreated embryos, treated embryos contained 17±3
p2x3b:egfp-expressing neurons and 20±1
trpa1b-GFP-expressing neurons
(Table 1;
Fig. 5A-D). In addition, we
detected mRNA expression of other trigeminal subpopulation markers such as the
thermally gated channel TrpV1 and the second P2X3 homologue P2X3a (see Fig. S3
in the supplementary material). These results indicate that late-born neurons
are required neither for the maintenance nor subspecification of early-born
neurons.
BAPTISM indicated that in contrast to early-born neurons, late-born neurons
did not generate trpa1b-expressing neurons
(Fig. 4E). To test whether this
restriction is imposed on the late-born neurons by the presence of early-born
neurons, we specifically removed early-born neurons from the trigeminal
ganglia. Zebrafish embryos that lack the transcriptional regulator
neurogenin1 lack trigeminal sensory ganglia at 24 hpf
(Fig. 6B)
(Andermann et al., 2002;
Cornell and Eisen, 2002;
Golling et al., 2002). We
discovered, however, that neurogenin1 mutants and
neurogenin1 morphants (antisense morpholino-injected embryos) formed
trigeminal sensory ganglia at later stages of development
(Fig. 6D,F,G). In
neurogenin1-depleted embryos, the first huc-expressing
trigeminal sensory neurons appeared around 48 hpf (data not shown). By 96 hpf,
trigeminal ganglia contained fewer neurons than wild-type ganglia but formed
the typical three branched pattern (Fig.
6C-G).
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To directly visualize the formation of late-born neurons in the absence of neurogenin1, we injected neurogenin1 morpholinos into huc:kaede embryos. Morphants had 15±2 neurons per ganglion at 72 hpf, compared with 53±6 neurons in wild type (Table 1; Fig. 2B and data not shown; see Movie 3 in the supplementary material). Consistent with late neurogenesis in neurogenin1 morphants, the number of neurons in neurogenin1-depleted embryos is comparable with the number of late-born neurons in wild-type embryos based on BrdU labeling (23±4 neurons per ganglion) (Fig. 1G) or BAPTI (18±3 neurons per ganglion) (Table 1; Fig. 2B; see Movie 3 in the supplementary material). These results suggest that the trigeminal sensory ganglia of neurogenin1-depleted embryos are solely formed from late-born neurons.
To test whether early-born neurons restrict the fate of late-born neurons, we injected neurogenin1 morpholinos into p2x3b:egfp and trpa1b:egfp embryos. Morphants had 8±2 p2x3b:egfp-expressing neurons per ganglion but no trpa1b:egfp-expressing neurons could be detected (Table 1; Fig. 7B,D). neurogenin1 morphants expressed trpv1, p2x3a and p2x3b mRNAs (Fig. 7F; see Fig. S4 in the supplementary material) but not trpa1b (Fig. 7H), consistent with our previous findings. These results indicate that the cell fate restriction of late-born trigeminal neurons can occur independently of early-born neurons.
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;
Jordt et al., 2004) and
zebrafish (D.P. and A.F.S., unpublished) but is not needed for
mechanosensation (Bautista et al.,
2006; Kwan et al.,
2006). These studies raised the hypothesis that only embryos
containing early-born neurons would respond to allyl isothiocyanate. Indeed,
we found that touch and allyl isothiocyanate elicited an escape response in
wild-type larvae and in larvae with only early-born trigeminal sensory neurons
(Table 2; see Movies 8 and 9 in
the supplementary material). By contrast, neurogenin1-depleted
embryos were completely insensitive to allyl isothiocyanate at all stages
tested from 24 hpf to 192 hpf, despite the presence of late-born trigeminal
sensory neurons (Table 2; see
Fig. S5 and Movie 9 in the supplementary material). neurogenin1
mutants did not respond to touch at 24 hpf, consistent with the complete
absence of trigeminal sensory neurons at this stage
(Table 2;
Fig. 6B), but touch response
became apparent around 48 hpf and was fully restored by 96 hpf, concomitant
with the formation of late-born trigeminal sensory neurons
(Table 2;
Fig. 6F,G; see Fig. S5 and
Movie 9 in the supplementary material). These results suggest that early
neurogenesis is required not only for the formation of a specific type of
chemosensory trigeminal neurons but also for the establishment of associated
behaviors.
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DISCUSSION |
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TOP
SUMMARY
INTRODUCTION
MATERIALS AND METHODS
RESULTS
DISCUSSION
REFERENCES |
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30 neurons by 24 hpf. At later
stages trigeminal sensory ganglia grow continuously but at a slower rate to
form 55 neurons by 72 hpf. Our study reveals that a subpopulation of
chemosensory neurons expressing the nociceptive channel TrpA1b forms
exclusively during the early phase of zebrafish neurogenesis
(Fig. 8). Two lines of evidence
support this conclusion. First, in vivo labeling using BAPTISM reveals that
TrpA1b-expressing neurons form exclusively from early-born neurons. Second,
removal of early-born neurons results in the absence of TrpA1b cells and
abrogates the larval escape behavior triggered by the TrpA1b agonist allyl
isothiocyanate. In contrast to TrpA1b neurons, mechanosensory and P2X3b
neurons develop from both early-born and late-born neurons.
Different waves of neurogenesis have also been implicated in the cell type
diversification of mouse DRGs, but, in contrast to the zebrafish trigeminal
ganglion, nociceptive DRG neurons do only derive from the second and third
wave of neurogenesis. It is conceivable that these apparent differences might
be based on differences in marker analysis. For example, the birthdate of
TrpA1b neurons has not been determined in mouse
(Ma et al., 1999;
Maro et al., 2004;
Marmigere and Ernfors, 2007).
In addition, lineage analysis in zebrafish will be required to determine
whether late-born trigeminal neurons are derived from the cells analogous to
the boundary cap cells responsible for the third wave of neurogenesis in the
DRG (Marmigere and Ernfors,
2007).
Specific removal of late-born neurons does not affect the expression of
TrpA1b, TrpV1, P2X3a and P2X3b, and the response to allyl isothiocyanate and
touch. These findings do not exclude the possibility that more extensive gene
expression profiling might identify sensory subtypes that cannot form from
early-born neurons. It is unknown how many different neuronal subtypes reside
in the zebrafish trigeminal ganglion. For example, studies in mouse have shown
that Trpa1 neurons are contained within the TrpV1 population, indicating that
these two markers label a TrpV1+;TrpA1+ and a TrpV1+;TrpA1-subpopulation.
Although similar studies have yet to be performed in zebrafish, our results
indicate that early-born neurons can form a multimodal sensory ganglion
independently of late-born neurons. This mode of rapid multimodal neuronal
specification contrasts with the sequential patterning in systems such as the
mammalian cortex. Mammalian cortical neurons are arranged in a laminar
structure composed of six layers. Early-born neurons form the deep layer 6 and
as development proceeds, newly born neurons populate increasingly superficial
layers (for a review, see McConnell,
1995). Thus, each subset of mammalian cortical neurons forms
during a defined time window, whereas multiple subpopulations of zebrafish
trigeminal sensory neurons are generated in a short time interval. The latter
strategy is well suited for the life history of zebrafish. Embryos develop
externally, and larvae hatch and become free-living at about 48 hpf. Thus,
functional sensory systems have to be in place early in development. This is
particularly true for the trigeminal sensory ganglia and their vital function
in the detection of noxious stimuli. Thus, the early neurogenesis and
multimodal cell fate specification in this system allow for the rapid
formation of a functional organ essential for survival in the wild.
|
). Our results argue against a role of early-born trigeminal
neurons as a source of inhibiting cues, because the absence of these cells in
neurogenin1 mutants does not alleviate the restriction of late-born
neurons. Intrinsic timing mechanisms could contribute to progenitor
restriction. Such a mechanism is observed in the mammalian cortex, where late
cortical progenitors placed into a younger host fail to form the deep cortical
neurons normally formed by early progenitors (for a review, see
McConnell, 1995). A similar
mechanism might account for the restriction of late-born trigeminal sensory
neurons. Detailed characterization of trigeminal sensory neuron progenitors is
needed to determine whether extrinsic regulatory signals might arise from
cells surrounding the trigeminal sensory neurons or whether intrinsic
mechanisms restrict fate specification.
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). For example, neurons whose cell bodies are located in the
anterior-dorsal region of the ganglion tend to innervate the anterior-dorsal
region of the head. It is possible that there is a third, proximal-distal axis
to this map. Late-born neurons are generally located in deeper cell layers of
the ganglion than early-born neurons (see Fig. S6 in the supplementary
material) and TrpA1b-expressing neurons are located more superficially (see
Fig. S6 in the supplementary material). As detectors of external sources of
noxious chemicals, TrpA1b-expressing neurons would need to project into
superficial layers of the skin. It is possible that the location of early-born
neurons in superficial regions of the ganglia might allow or force innervation
of superficial regions of the skin. By contrast, deeper neurons might project
more deeply and detect internal, potentially proprioceptive stimuli. Detailed
comparisons of birth dates, cell types and peripheral axon projections are
required to test this model.
BAPTISM - a novel method to analyze birthdate and fate of neurons
Our study introduces a novel method, BAPTISM, for the in vivo analysis of
the birthdate and fate of neurons. Conversion of the fluorescent protein Kaede
serves as a marker to distinguish neurons born at different times. Birthdate
is then correlated with fate by addition of non-convertible EGFP markers that
label different neural subpopulations. BAPTISM has several advantages compared
with more traditional birthdating techniques such as BrdU incorporation.
First, BAPTISM can be used repeatedly throughout embryogenesis, unlike the
more invasive BrdU injections that can damage cells and embryos. Second,
BAPTISM labels neurons independently of their position in the cell cycle,
whereas BrdU is only incorporated during S-phase. Third, BAPTISM is temporally
precise, because labeling is instantaneous, whereas BrdU has to be taken up by
cells and then remains available for several hours. Fourth, and most
importantly, BAPTISM allows continuous in vivo observation: cells can be
followed throughout development. By contrast, the visualization of
BrdU-labeled cells is restricted to the single time point when the specimen is
fixed. By using multiple spectrally distinct fluorescent proteins, BAPTISM can
be extended to follow multiple subpopulations at once. Finally, this method
can be adapted easily to study additional neuronal assemblies and other
organs.
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ACKNOWLEDGMENTS |
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Footnotes |
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REFERENCES |
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TOP
SUMMARY
INTRODUCTION
MATERIALS AND METHODS
RESULTS
DISCUSSION
REFERENCES |
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