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Volume 16, Number 21,
Issue of November 1, 1996
pp. 6878-6885
Copyright ©1996 Society for Neuroscience
Changes in the Regulatory Effects of Cell-Cell Interactions on
Neuronal AChR Subunit Transcript Levels after Synapse Formation
Marjory S. Levey and
Michele H. Jacob
Worcester Foundation for Biomedical Research, Shrewsbury,
Massachusetts 01545
 ABSTRACT
- INTRODUCTION
- MATERIALS AND METHODS
- RESULTS
- DISCUSSION
- FOOTNOTES
- REFERENCES
ABSTRACT 
Nicotinic acetylcholine receptors (AChRs) mediate excitatory
synaptic transmission in the chick ciliary ganglion. AChR protein and
mRNA levels are increased by both innervation and retrograde signals
from target tissues during synapse formation. We now show that AChR
 3,  4, and 5 subunit transcript levels stop increasing after
synaptogenesis. Moreover, maintenance of these mRNA levels requires the
continued presence of regulatory signals from both pre- and
postganglionic tissues. Unilateral preganglionic denervation or
postganglionic axotomy causes declines in 3, 4, and 5
transcript levels, ranging from twofold to 3.5-fold, relative to
contralateral control neuron values in newly hatched chicks. The
reductions are not merely an injury response; c4-tubulin mRNA levels
are not affected by either axotomy or denervation. Further, similar
decreases in AChR mRNA levels are observed after local application of
colchicine to the postganglionic nerves, which blocks fast transport
without disturbing axonal integrity. These results also demonstrate a
developmental change in the regulatory effects of target tissues.
Reductions in 5 mRNA levels caused by axotomy or colchicine
treatment after peripheral synapse formation contrast with the lack of
an effect on 5 when synapse formation with the target tissue is
prevented. The ability of the target tissue to regulate 5 mRNA
levels after synaptogenesis is interesting, because this subunit may be
necessary for the formation of high-conductance AChRs. The specific
regulatory effects of target tissues and inputs at different
developmental stages demonstrate that neurons continually depend on
signals from their pre- and postsynaptic tissues to accomplish mature
levels of AChR subunit expression and optimal functioning of that
neuronal circuit.
Key words:
nicotinic acetylcholine receptors (AChRs);
parasympathetic ciliary ganglion neurons;
development;
synapse
formation and maturation;
denervation;
axotomy;
regulation of gene
expression;
mRNA
INTRODUCTION
Although nervous system function depends on
synaptic communication, the cellular and molecular mechanisms that
regulate neuronal synapse formation and maintenance are largely
undefined. Neurons engage in two distinct types of synaptic
interactions: they receive innervation and form synapses on target
tissues. We have shown recently that innervation and target tissues
have differential inductive effects on AChR subunit transcript levels
in developing neurons during synapse formation (Levey et al., 1995 ).
The present study was undertaken to determine whether similar
regulatory interactions control the maintenance of neuronal
synapses.
The chick parasympathetic ciliary ganglion (CG) is a uniquely
well-suited model for identifying in vivo mechanisms that
regulate synapse formation and maintenance, because the synaptic
interactions are amenable to experimental manipulation in
situ (Jacob and Berg, 1987, 1988; Arenella et al., 1993; Dourado
et al., 1994; Levey et al., 1995). AChRs mediate excitatory synaptic
transmission in the chick CG (Martin and Pilar, 1963a,b). Neuronal
AChRs are pentameric complexes (Anand et al., 1991; Cooper et al.,
1991). Subunit analysis of CG AChRs show that they collectively contain
3, 4, and 5 subunits. In addition, a small subpopulation, only
~20%, also contain 2 (Conroy and Berg, 1995). Before innervation,
few AChRs are detected in CG neurons (Jacob, 1991). AChR expression
increases dramatically during synapse formation (Smith et al., 1985;
Jacob, 1991; Corriveau and Berg, 1993). Innervation and target tissues
have redundant, as well as unique, inductive effects on AChR mRNA
levels (Levey et al., 1995). 3 and 4 transcript levels are
increased by both presynaptic inputs and target tissues. In contrast,
innervation increases 5 mRNA levels, but target tissues have little
effect. The abundance of high-conductance AChR channels also increases
relative to low-conductance AChRs during synapse formation and
maturation (Margiotta and Gurantz, 1989). In vitro
expression studies suggest that 5 may be necessary for the formation
of high-conductance AChRs (Ramirez-Latorre et al., 1996). Developmental
increases in CG 5 mRNA levels relative to the more abundant 3
transcripts suggest that a greater number of AChRs contain 5 at
later embryonic stages (Levey et al., 1995). Thus, increases in AChR
transcript levels induced by innervation and target tissues may cause
changes in AChR number, subunit composition, and functional properties
that are likely to increase levels of synaptic activity during the
critical period of synapse stabilization and elimination and neuronal
cell death.
The present studies extend our knowledge of the regulation of AChR
expression at later developmental stages in four ways. First, we show
that 3, 4, and 5 transcript levels stop increasing after
synapse formation, thus extending previous analyses of AChR mRNA levels
in normal developing CGs by including stages before and after
synaptogenesis (Corriveau and Berg, 1993). Second, declines in 3,
4, and 5 mRNA levels after axotomy and denervation demonstrate
that the maintenance of all three mRNA levels requires the continued
presence of both innervation and retrograde signals from the target
tissues in mature CG neurons in situ, as established
previously only for 3 (Boyd et al., 1988). Third, the specificity of
the regulatory response to axotomy, a key concern relevant to all
lesion studies, is addressed by demonstrating similar declines in AChR
mRNA levels after colchicine treatment of postganglionic nerves.
Colchicine blocks fast transport without disturbing axonal integrity
(Karlsson and Sjostrand, 1969; Pilar and Landmesser, 1972; Davis,
1990). Fourth, the results demonstrate a developmental change in the
ability of the target tissue to regulate 5 mRNA levels after synapse
formation. Thus, both input and target tissues play a key role in the
induction and maintenance of AChR expression in neurons.
MATERIALS AND METHODS
Normal developing ciliary ganglia (CGs). White
Leghorn embryonated chick eggs (Spafas, Norwich, CT) were maintained at
37°C in a forced-draft turning incubator until use. Embryos were
staged according to the Hamburger and Hamilton (1951) classification
scheme. CGs were dissected at selected stages of synapse formation and
maturation, ranging from embryonic day 4 (E4) to posthatch day 12 (PH12). CGs were frozen immediately in liquid nitrogen and stored at
 80°C until use for RT-PCR.
Surgical manipulations. Surgical manipulations to disrupt
synaptic connections were performed on CGs in chicks 2 d after
hatching using methods described previously (Jacob and Berg, 1987). For
preganglionic denervation, the single input from the accessory
oculomotor (Edinger-Westphal) nucleus was severed. For postganglionic
axotomy, all of the ciliary and choroid nerves emerging from the CG
were lesioned. Denervation or axotomy was performed unilaterally,
preserving the contralateral ganglion as an intact control. After
surgery, chicks were maintained in a heated brooder for 2, 5, or
10 d after denervation and 1, 3, or 5 d after axotomy. The
total absence of the pupillary light reflex was used as a criterion for
a successful operation. The ganglion was also examined during
dissection to confirm that the appropriate nerves remained completely
severed. The success rate of the surgery was ~95%. Operated and
contralateral control ganglia from the same animal were always paired
and processed in parallel for RT-PCR or light microscopic analysis.
Colchicine treatment. Local application of colchicine to CG
postganglionic nerves was performed using minor modifications of a
method described previously (Pilar and Landmesser, 1972). The
modifications include the use of 5% (w/v), rather than 10-20%,
colchicine in PBS and treatment at 1.5 weeks, rather than 1-2 d, after
hatching. The modifications enhanced survival; ~85% of the
experimentally manipulated chicks survived. In comparison to the
surgery used for denervation and axotomy, colchicine treatment requires
the chicks to be anesthetized for a longer time (~20 min compared
with 3 min), which may compromise survival at the earlier age. Briefly,
chicks were anesthetized with methoxyfluorane, and a small incision was
made along the caudal portion of the lower eyelid on one side only. The
eyeball was gently retracted, and the CG postganglionic nerves were
exposed. A small sterile cotton pellet, which had been soaked in 5%
colchicine in PBS and air dried in a sterile dish, was applied
unilaterally to a distal portion of the postganglionic nerves for 10 min. The pellet was then removed, and the area was thoroughly rinsed
with sterile PBS. The incision along the lower eyelid was sutured, and
the chicks were allowed to recover. Controls in which the nerves were
treated similarly, but colchicine was omitted from the pellet, had AChR
mRNA levels resembling untreated age-matched CGs. To compare the
effects of colchicine treatment to those of axotomy, chicks were also
axotomized at 1.5 weeks after hatching.
Quantitative RT-PCR. Total RNA was extracted from individual
ganglia by the guanidinium isothiocyanate-hot phenol method (Feramisco
et al., 1982) as modified by the addition of glycogen as carrier. Known
concentrations of an AChR 3, 5, 4, or c4-tubulin mutated
internal standard, equivalent to the quantity of that transcript
present in that age- operated or control ganglion (as determined
initially by competitive RT-PCR), were added to the ganglion at the
start of RNA extraction (Levey et al., 1995). The mutated standards
resemble the regions of the cellular mRNAs targeted for amplification
with the exception of 2 bp changes required to replace an existing
restriction endonuclease site with a novel restriction site. Ganglionic
RNA and the mutated internal standard cRNA were amplified by
quantitative RT-PCR in the presence of [32-P]dCTP
using forward and reverse primers for 3, 5, 4, and
c4-tubulin, as reported previously (Levey et al., 1995). Restriction
enzyme mapping and gel electrophoresis were used to distinguish PCR
products derived from the mutated standard and the ganglionic mRNA.
Fragments were transferred to a Zeta probe blotting membrane (Bio-Rad,
Hercules, CA) and exposed x-ray film. The ratio of the ganglionic mRNA
products and the mutated standard products was determined by
densitometric scanning (PDI densitometer, Huntington Station, NY) of
the resulting autoradiogram.
Neuronal cell counts and morphology. Neuron numbers were
counted in axotomized and contralateral control ganglia 1 and 3 d
after surgery and in colchicine-treated ganglia and their contralateral
controls after 5 and 15 d. Neuron numbers in ganglia 10 d
after denervation and 5 d after axotomy and their contralateral
controls were taken from Jacob and Berg (1987) (Table
1). Briefly, ganglia were fixed in 4% paraformaldehyde
in PBS, processed for paraffin histology, serially sectioned at 8 µm,
and stained with toluidine blue (Arenella et al., 1993; Levey et al.,
1995). All neurons possessing a nucleus with a distinct nucleolus were
counted in each section of the ganglion. Cell counts were corrected for
double counting by the method of Abercrombie (1946). The same control,
axotomized, and colchicine-treated ganglion sections were also used to
calculate the percentage of ciliary neurons undergoing chromatolysis.
Ciliary neurons in which the Nissl substance was fragmented and
dispersed throughout the cytoplasm were considered chromatolytic.
Choroid neurons were not evaluated, because axotomy causes no apparent
change in the distribution of their normally dispersed individual
cisternae of rough endoplasmic reticulum. Ciliary and choroid neurons
were distinguished on the basis of differences in their size, shape,
and staining intensity of the cytoplasm (Landmesser and Pilar, 1974a).
Table 1.
Neuronal
survival
Denervation
|
Axotomy
|
Colchicine
|
|
Control |
Operated |
|
Control |
Operated |
|
Control |
Treated |
|
| P10 |
ND |
2390
± 210a |
P1 |
2382
± 54 |
1983 ± 98 |
P5* |
2268
± 92 |
2201 ± 53 |
|
|
|
P3 |
2522
± 133 |
1785 ± 77 |
P15* |
2363 ± 105 |
2334
± 97 |
|
|
|
P5 |
2370
± 250a |
1490
± 110a |
|
|
|
P5* |
2219
± 87 |
1422 ± 72 |
|
|
Denervated, axotomized, colchicine-treated, and contralateral
control CGs were fixed, embedded in paraffin, serially sectioned,
stained with toluidine blue, examined by bright-field microscopy, and
counted separately for surviving neurons at the indicated postoperative
days (P) as described in Materials and Methods. Cell-cell interactions
were surgically disrupted at PH2, except where there is an asterisk
after the days, indicating that those chicks were experimentally
manipulated 1.5 weeks after hatching. Postganglionic axotomy causes a
gradual decline in neuron number over time, whereas preganglionic
denervation and blockade of fast axonal transport with colchicine have
no effect on the number of surviving neurons. Each value represents the
mean ± SEM of three ganglia that were counted separately. ND, Not
determined, because the number of neurons in contralateral control
ganglia is not significantly different at any of the posthatch ages
examined, ranging from 3 to 25 d (Student's t test).
|
|
a
These values were taken from Jacob and Berg
(1987).
|
|
RESULTS
AChR subunit mRNA levels increase dramatically during
synaptogenesis, and then plateau, in CG neurons developing in
situ
AChR 3, 4, and 5 transcript levels in individual chick
CGs were established at selected stages of synapse formation and
maturation (Fig. 1). Absolute levels were measured using
quantitative RT-PCR and known concentrations of a mutated AChR subunit
cRNA internal standard (Levey et al., 1995). Data were normalized to
transcript copies per neuron to account for developmental changes in CG
neuron number (Landmesser and Pilar, 1974b; Furber et al., 1987).
Ganglia were sampled at ages ranging from E4 to PH12. E4 precedes
innervation, which begins at E4.5 (Jacob, 1991). By E8, functional
chemical synapses are present on every neuron (Landmesser and Pilar,
1972). Innervation occurs before target tissue synaptogenesis. From
E8.5 to E14, CG neurons establish synapses on their target striated and
smooth muscles in the eye (Meriney and Pilar, 1987; Pilar et al.,
1987).
Fig. 1.
AChR 3, 4, and 5 subunit transcript
levels increase during pre- and postganglionic synapse formation and
then plateau in CG neurons developing in situ. Absolute
amounts of AChR 3, 4, and 5 subunit mRNAs were measured in
individual ganglia at selected stages preceding, during, and after
synapse formation by using RT-PCR with mutated internal standards.
Values are normalized to the number of transcript copies per neuron to
account for developmental changes in neuron number. Neuron numbers per
ganglion were taken from Landmesser and Pilar (1974b) and Furber et al.
(1987). Each value represents the mean ± SEM of two to eight
separate determinations. In cases in which error bars are not visible,
they are within the symbol.
[View Larger Version of this Image (17K GIF file)]
Low but detectable levels of 3, 4, and 5 transcripts are
present before innervation (Fig. 1). All three transcript levels
increase during synapse formation. The greatest rise occurs between E9
and E15, during the time when target tissues are innervated and
preganglionic inputs mature in efficacy and morphology, with calyces
forming on ciliary neurons (Landmesser and Pilar, 1972). Subsequently,
AChR transcript levels are not significantly altered up to PH12, the
latest time point examined (Student's t test). Overall,
AChR 3, 4, and 5 mRNA levels increase 7-fold, 5-fold, and
16-fold, respectively, during synapse formation and maturation, from E4
to PH12 (Fig. 1). Similar increases in 3, 4, and 5 mRNA levels
were reported previously for CGs from E8 to E18, as determined by
quantitative RNase protection experiments (Corriveau and Berg, 1993).
3 transcripts are two- to threefold more abundant than 5 and 4
mRNAs at all developmental stages examined, except at the earliest
stages, when 5 is least abundant, and 3 is present at fivefold
higher levels (Fig. 1). In comparison, 4 and 5 are present at
similar levels. In total, these results suggest that innervation and
target tissues both induce increases in AChR subunit mRNAs in CG
neurons during synapse formation, after which AChR transcript levels
stop increasing.
AChR subunit mRNA levels decline after surgical transection of
synaptic connections in the mature CG
To determine the separate role of innervation and target tissue
interactions in maintaining AChR 3, 4, and 5 transcript levels
in mature CG neurons, transection of the preganglionic accessory
oculomotor nerve (denervation) or postganglionic ciliary and choroid
nerves (axotomy) was performed unilaterally in newly hatched chicks.
The CG from the unoperated contralateral side served as an internal
control.
AChR 3, 4, and 5 subunit mRNA levels decline rapidly after
denervation and axotomy (Fig. 2). Reductions in the
three transcript levels range from twofold to 3.5-fold relative to
contralateral control neuron values by 10 d after denervation and
5 d after axotomy. These times were selected because substantial
reductions in AChR protein levels are known to occur by then (Jacob and
Berg, 1987). In addition, sampling the CG up to 5 d after axotomy
minimizes any possible contribution of a loss of presynaptic terminals,
because axotomy of the chick CG for 9 d, a longer period, reduces
the total synaptic contact area on the neurons by only 37% (Brenner
and Johnson, 1976). Transcript levels were normalized to account for
decreases in neuron number observed to occur after axotomy but not
after denervation (Table 1) (Jacob and Berg, 1987). No compensatory
change is detected in AChR mRNA levels in unoperated contralateral CGs
from the same animals.
Fig. 2.
AChR 3, 4, and 5 subunit mRNA levels
rapidly decline after surgical disruption of synaptic connections in
mature CG neurons. AChR subunit transcript levels were quantified in
individual CGs after unilateral surgical transection of the
preganglionic nerve (denervation) or postganglionic connections with
target tissues (axotomy) in newly hatched chicks. Denervated CGs
(dotted bars) and axotomized CGs (lined
bars) were paired with the contralateral control CG
(solid bars) from the same animal, sampled at the
indicated times, and assayed using RT-PCR with known concentrations of
mutated AChR cRNA internal standard. Data are expressed as the number
of transcript copies per neuron to account for decreases in neuron
number observed after axotomy but not denervation (see Table 1).
Results represent the mean ± SEM. The number of ganglia assayed
is shown above each bar. Declines in 3, 4, and
5 mRNA levels range from 2-fold to 3.5-fold by 10 d after
denervation and 5 d after axotomy, compared with contralateral
control neuron values. Asterisks, Statistically
significant differences based on the Student's two-sided
t test: *p < 0.05;
**p < 0.01; ***p < 0.001.
[View Larger Version of this Image (28K GIF file)]
Greater reductions in 3 and 4 mRNA levels occur after axotomy
compared with denervation (Fig. 2; see also Fig. 5) (Student's
t test). In contrast, 5 mRNA levels are decreased to the
same extent at matched ages after these manipulations. Declines in 5
levels after axotomy contrast with the lack of an effect on 5 after
target tissue removal before synaptogenesis, which avoids direct damage
to CG neurons (Levey et al., 1995). This observation suggests a
developmental change in the regulatory response to the target tissue
after synapse formation. However, it also raises the important question
as to whether declines in AChR mRNA levels after axotomy represent a
general injury response or specific regulation attributable to the loss
of a target-derived signal.
Fig. 5.
Summary of the declines in AChR 3, 4, and
5 subunit mRNA levels per neuron over time after denervation and
axotomy. The number of 3, 4, and 5 transcript copies per
neuron after axotomy (solid symbols) or denervation
(open symbols) is presented as a percent of those
present in contralateral control neurons. Values represent the
mean ± SEM and were calculated from the data presented in Figure
2. Reductions in 3 and 4 mRNA levels are significantly greater
after axotomy compared with denervation (Student's t
test). In contrast, 5 mRNA levels are decreased to a similar extent
at matched ages after these two surgeries.
[View Larger Version of this Image (27K GIF file)]
Reductions in AChR subunit transcript levels after axotomy and
denervation appear to be specific. The number of transcript copies per
neuron encoding c4-tubulin, a neuron-specific form of -tubulin
(Sullivan et al., 1986), are not altered over the same time course by
either experimental manipulation (data not shown). Similarly,
cytoplasmic -actin mRNA levels are not detectably affected after
axotomy (Boyd et al., 1988).
Decreases in AChR mRNA levels after axotomy represent specific
regulation and not merely a response to axonal injury
To establish further whether declines in AChR mRNA levels in
axotomized neurons result from specific regulation and not axonal
injury, localized colchicine application to CG postganglionic nerves
was used to mimic the effects of axotomy without disturbing axonal
integrity (Pilar and Landmesser, 1972). Colchicine treatment blocks
fast axonal transport (Karlsson and Sjostrand, 1969; Davis, 1990).
Similar to axotomy, colchicine causes a characteristic chromatolytic
reaction, which is likely attributable to the disruption of rapid
protein transport and includes fragmentation and dispersal of the Nissl
substance (Pilar and Landmesser, 1972). A small cotton pellet
containing a dried 5% colchicine solution was applied briefly to the
postganglionic nerves on one side only at 1.5 weeks after hatching,
which resulted in greater survival than manipulating the chicks at the
earlier ages used previously (Pilar and Landmesser, 1972) (see
Materials and Methods). For comparison, CGs were also axotomized at
this later age. Serial paraffin sections were used to establish the
proportion of ciliary neurons undergoing chromatolysis after colchicine
treatment and axotomy. Choroid neurons were not evaluated, because they
do not undergo a typical chromatolytic reaction after axotomy; there is
no apparent change in the normally dispersed distribution of individual
rough endoplasmic reticulum cisternae in the cytoplasm (Pilar and
Landmesser, 1972). In control ganglia, 95% of the ciliary neurons have
a dense perinuclear ring of Nissl substance that is visible after
toluidine blue staining (Fig. 3). After colchicine
treatment, ~50% of the ciliary neurons have a typical chromatolytic
staining pattern indicative of the dispersal of Nissl substance,
whereas the remaining ciliary neurons appear normal at 5 d. After
axotomy, all of the ciliary neurons have a characteristic chromatolytic
appearance within 5 d. Chromatolysis is not an indication of cell
death (Bodian and Mellors, 1945). No change in neuron number was
observed up to 15 d after colchicine treatment (Table 1).
Moreover, there is no change in the proportion of chromatolytic ciliary
neurons at 5 d compared with 15 d after colchicine exposure
(Fig. 3). There is a 37% reduction in total neuron number at 5 d
after axotomy, but this is much lower than the number of chromatolytic
ciliary neurons, 82 and 98%, seen at 3 and 5 d after
axotomy, respectively (Table 1, Fig. 3). Thus, colchicine treatment and
axotomy cause similar morphological changes in the neurons. The
difference in the percentage of the affected neurons may reflect a lack
of penetration of colchicine at adequate concentrations into all axons
of the postganglionic nerves.
Fig. 3.
Brief colchicine application to CG postganglionic
nerves causes a typical chromatolytic reaction in ciliary neurons
similar to axotomy. Unilateral colchicine treatment of CG
postganglionic nerves was used to block fast axonal transport without
disturbing axonal integrity (for details, see text and Material and
Methods). Ciliary neuron morphology was compared in colchicine-treated,
axotomized, and contralateral control CGs at 5 d after the
manipulation. CGs were fixed, embedded in paraffin, serially sectioned,
stained with toluidine blue, and examined by bright-field microscopy.
A, Micrographs demonstrating the typical appearance of
neurons in contralateral control, colchicine-treated, and axotomized
CGs. Ciliary neurons contain a dense perinuclear ring of Nissl
substance (closed arrows) in control CGs. Colchicine
treatment causes a characteristic chromatolytic reaction, including
dispersal of the Nissl throughout the cytoplasm (open
arrows), in some ciliary neurons, whereas others appear normal
(closed arrows). After axotomy, ciliary neurons have a
typical chromatolytic staining pattern (open arrows).
B, The proportion of ciliary neurons in
colchicine-treated, axotomized, and contralateral control CGs
undergoing chromatolysis at the indicated times after treatment or
surgery. Each value represents the mean ± SEM of two to three
ganglia that were serially sectioned and counted separately. Colchicine
treatment causes approximately one-half of the ciliary neurons to
exhibit a typical chromatolytic staining pattern resembling the
morphological changes seen after axotomy.
[View Larger Version of this Image (79K GIF file)]
AChR subunit mRNA levels are reduced to a comparable extent after
colchicine exposure and axotomy (Fig. 4). Colchicine
causes twofold and 1.5-fold declines in 3 and 5 mRNA levels,
respectively, compared with contralateral control neuron values after
5 d. Similarly, axotomy causes 3.5-fold and twofold reductions in
3 and 5 transcript levels, respectively, within 5 d; these
values are identical to the decreases seen when axotomy is performed on
younger chicks (Fig. 2). In total, these results demonstrate that
declines in AChR subunit transcript levels after axotomy represent, at
least in part, specific regulation by retrograde signals from the
target tissue.
Fig. 4.
AChR subunit mRNA levels are reduced to a similar
extent after colchicine treatment and axotomy. AChR 3 and 5
transcript levels are compared in CGs after colchicine treatment of the
postganglionic nerves at 1.5 weeks posthatch (open
bars), CGs axotomized at this later age (lined
bars), and contralateral control CGs (solid
bars), all sampled at 5 d after the manipulation. Values
represent the mean ± SEM. The number of ganglia assayed is shown
above each bar. Similar declines in 3 and 5
transcript copies per neuron after colchicine treatment and axotomy,
relative to contralateral control neuron levels, demonstrate that
retrograde signals from the target tissue specifically regulate AChR
expression in mature CG neurons. Asterisks,
Statistically significant differences based on the Student's two-sided
t test: ***p < 0.001.
[View Larger Version of this Image (23K GIF file)]
DISCUSSION
Major findings reported here are that AChR 3, 4,
and 5 subunit transcript levels increase dramatically during
synaptogenesis and then level off, and the maintenance of these mRNA
levels requires the continued presence of both innervation and target
tissue interactions in mature CG neurons in situ. In
addition, there is a developmental change in the regulatory effect of
the target tissue on 5 mRNA expression. Removing the target tissue
before synaptogenesis causes no change in 5 mRNA levels in the CG,
whereas 3 and 4 mRNA levels are reduced relative to contralateral
control neuron values (Levey et al., 1995). In contrast, 5, 3,
and 4 transcript levels are all specifically decreased when target
tissue interactions are disrupted after synapse formation by either
axotomy or colchicine treatment of the postganglionic nerve, which
blocks fast transport without disturbing axonal integrity. This
developmentally acquired ability of target tissues to regulate 5
mRNA levels after synaptogenesis suggests a dependence on peripheral
synapse formation. Contact between the nerve and muscle may be required
for activity of the signal, or innervation may induce its expression in
the target tissue. This regulatory change is particularly interesting,
because the 5 subunit may be necessary for the formation of
high-conductance AChR complexes. In vitro expression studies
demonstrate that 5 does not form functional channels when
co-expressed with either an -type or a -type subunit (Couturier
et al., 1990). However, AChRs containing 5 together with another
-type and -type subunit have a higher conductance than AChRs
formed by that and subunit in the absence of 5
(Ramirez-Latorre et al., 1996). The relative abundance of
high-conductance AChRs increases on CG neurons during synapse formation
and maturation (Margiotta and Gurantz, 1989). Levels of 5
transcripts also increase relative to the more abundant 3 during
this period, causing a shift from fivefold to only twofold higher 3
(Fig. 1) and, therefore, suggesting that a greater number of AChRs
contain 5, 3, and 4 subunits in mature CG neurons. Overall,
innervation and target tissues both provide regulatory signals that
induce and subsequently maintain mature levels of AChR subunit
transcripts, and these regulatory events are likely to result in
optimal levels of AChR expression and synaptic activity in CG neurons
in situ.
Cell-cell interactions cause similar regulatory changes in AChR
mRNA and protein levels
Regulatory changes in AChR mRNA levels correlate well with AChR
protein levels, suggesting that the regulation of AChR expression by
cell-cell interactions occurs at the level of gene transcription.
However, it is also possible that cell-cell interactions influence
AChR mRNA stability. AChRs in the late stage embryonic CG (E17-E18)
all contain both 3 and 4 subunits, whereas a subpopulation, or
possibly all, also contain 5 (Vernallis et al.,. 1993; Conroy and
Berg, 1995). AChR subunit transcript levels appear to be rate-limiting
for AChR expression in CG neurons in vivo.
During normal development, 3, 4, and 5 mRNA levels per neuron
increase 7-fold, 5-fold, and 16-fold, respectively, during synapse
formation and are then maintained, again with 3 mRNA levels being at
least twofold more abundant than 5 and 4 at all ages examined
(see also Corriveau and Berg, 1993). AChR protein levels per neuron
follow a similar pattern, increasing 12-fold during synaptogenesis
(Smith et al., 1985). Similarly, declines in 3, 4, and 5 mRNA
levels range from twofold to 3.5-fold after denervation or axotomy and
resemble in extent the threefold declines in AChR protein levels seen
10 d after denervation (Jacob and Berg, 1987; Boyd et al., 1988).
In comparison, axotomy results in 10-fold declines in both the total
number of AChRs (surface plus internal) and the whole-cell ACh induced
response within 5 d (Brenner and Martin, 1976; Jacob and Berg,
1987; Boyd et al., 1988; McEachern et al., 1989). Denervation causes no
detectable change in ACh response (McEachern et al., 1989). Most of the
loss of AChRs occurs in the large intracellular pool in denervated
neurons (Jacob and Berg, 1988). Declines in AChR mRNA and protein
levels after axotomy represent specific regulation and not merely an
injury response. After axotomy, there is no significant change in
c4-tubulin or -actin mRNA levels, membrane electrical properties,
mean diameters of neuronal somas or nuclei, or the GABA sensitivity of
CG neurons, whereas denervation causes a twofold reduction in the GABA
response (Brenner and Johnson, 1976; Brenner and Martin, 1976; Jacob
and Berg, 1987; Boyd et al., 1988; McEachern et al., 1989). No gross
degenerative changes are observed in surviving neurons of axotomized
ganglia at the light or electron microscopic level (Jacob and Berg,
1987, 1988) (this present study). Moreover, colchicine mimics the
effects of axotomy on AChR mRNA levels. Colchicine does not injure
axonal membranes or myelin sheaths; colchicine applied to CG
postganglionic nerves in a similar manner, but at a two- to fourfold
higher concentration, compared with that used here, had no affect on
either impulse conduction through the site of application or
macroscopic appearance of the nerves (Pilar and Landmesser, 1972).
Further, the inhibition of fast axonal transport by colchicine is
reversible (Perisic and Cuenod, 1972; Davis, 1990). All together, these
results suggest that the CG target tissues provide regulatory factors
that directly or indirectly influence AChR mRNA and protein levels in
the innervating neurons. Greater reductions in both internal and
surface AChR protein levels after axotomy, compared with denervation,
correlate with significantly lower 3 and 4 mRNA levels (Fig.
5) (Student's t test). In contrast, 5
mRNA levels are reduced to a similar extent at matched ages after these
two surgeries. Previously, changes in the whole-cell ACh response were
also observed to correlate with 3 and possibly 4, but not 5,
mRNA levels in CG neurons deprived of target tissues before
synaptogenesis (Levey et al., 1995). A correlation between 3 mRNA
levels and ACh current densities has also been observed in chick and
rat sympathetic neurons in vivo and in vitro
(Listerud et al., 1991; Yu et al., 1993; Mandelzys et al., 1994; De
Koninck and Cooper, 1995). Finally, additional causes of the large
declines in AChR protein levels after axotomy may include alterations
in post-transcriptional events, such as translational efficiency,
subunit assembly, transport, insertion and/or metabolic stability of
AChRs. Studies of many different neuronal genes demonstrate that, in
general, greater changes in the level of expression occur in
target-deprived CGs, compared with input-deprived CGs, suggesting that
the target tissue is the more important regulatory influence,
controlling the differentiation state of its innervating neurons (Levey
et al., 1995; Thomas et al., 1995) (M. Jacob and O. Ikonomov,
unpublished observations).
Regulatory effects of innervation and target tissue interactions
change with maturation
During synapse formation, innervation and target tissues have
unique, as well as redundant, inductive effects on AChR subunit mRNA
levels (Levey et al., 1995). 3 and 4 mRNA levels are increased by
both presynaptic inputs and target tissues. In contrast, 5 is
increased by innervation, whereas target tissue interactions have
little, if any, effect. After synaptogenesis, maintenance of all three
transcript levels requires both presynaptic inputs and target tissue
interactions (Fig. 5). Thus, innervation and target tissues have
similar regulatory effects at these later stages. The ability of the
target tissues to regulate 5 mRNA levels after, but not before,
synaptogenesis may be attributable to either a contact-mediated factor
on the surface of the target tissues, or innervation may induce the
expression or release of a new target tissue factor. In comparison,
electrical activity does not appear to regulate AChR expression in
neurons as it does in multinucleated skeletal muscle (Role, 1988;
Hieber et al., 1992; De Koninck and Cooper, 1995).
Precedence exists for reciprocal regulatory interactions at the
peripheral synapse influencing development of the mature
neurotransmitter phenotype in neurons in vivo. Specifically,
innervation of sweat glands in the rat footpad by noradrenergic
sympathetic neurons induces production of a target-derived cholinergic
differentiation activity (Habecker and Landis, 1994; Habecker et al.,
1995). This activity in turn induces the afferent neurons to switch
from a noradrenergic to cholinergic phenotype. This change in
neurotransmitter properties is critical for functional maturation of
the sweat gland, because ACh induces and maintains the secretory
response through muscarinic receptor activation (Grant et al., 1995).
Thus, developmentally regulated reciprocal interactions between the
target tissue and its innervating neurons are responsible for
functional maturation of the circuit.
Similarly, developmental changes in the CG target muscle tissue
correlate with increasing innervation. These alterations include a
transition from smooth muscle to predominantly striated muscle in the
iris and the expression of factors, such as activin A, follistatin and
ciliary neurotrophic factor (CNTF), that influence survival and
differentiation of innervating CG neurons (Pilar et al., 1987; Darland
et al., 1995; Finn and Nishi, 1996). The relationship of these
developmental events to maturational changes in the regulatory effects
of the target tissue on AChR expression are presently unknown. The
specific factors that mediate the regulatory effects of target tissues
and presynaptic input on AChR expression and the molecular mechanisms
of their action remain to be determined. Moreover, the present results
suggest that the target tissue provides multiple factors, with the
factor that influences 5 mRNA levels differing from that (those)
that affects 3 and 4 expression. Interestingly, genes
encoding these subunits are clustered in the avian genome; 4 lies 5
of 3 and is transcribed from the same DNA strand, whereas 5 lies
3 of 3 and is transcribed from the opposite DNA strand (Couturier
et al., 1990).
In summary, innervation and target tissue interactions both play an
essential role in the induction and maintenance of AChR 3, 4, and
5 subunit transcript levels in CG neurons in situ. Thus,
neurons continually depend on signals from their pre- and postsynaptic
tissues to accomplish mature levels of AChR subunit expression and
optimal functioning of that neuronal circuit.
FOOTNOTES
Received May 30, 1996; revised July 31, 1996; accepted Aug. 9, 1996.
This work was supported by grants from National Institutes of Health
(NS-21725 to M.H.J.) and the Pfeiffer Foundation (M.H.J.) and a
Muscular Dystrophy Association postdoctoral fellowship (M.S.L.).
Correspondence should be addressed to Dr. Michele H. Jacob, Worcester
Foundation for Biomedical Research, 222 Maple Avenue, Shrewsbury, MA
01545.
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