|
|
|
|
|
|
|
||||
| Home Help Feedback Subscriptions Archive Search Table of Contents | ||||
First published online 28 January 2009
doi: 10.1242/dev.032607
| |||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||
Center for Molecular Genetics, Division of Biological Sciences, University of California San Diego, La Jolla, CA 92093, USA.
* Author for correspondence (e-mail: wloomis{at}ucsd.edu)
Accepted 4 January 2009
 |
SUMMARY |
|---|
TOP
SUMMARY
INTRODUCTION
MATERIALS AND METHODS
RESULTS
DISCUSSION
REFERENCES |
|---|
-aminobutyric acid (GABA) is released from prespore cells and
binds to GrlE, a G protein-coupled receptor (GPCR). Analysis of SDF-2
production in mutant strains lacking G
subunits and GPCRs, either as
pure populations or when mixed with other mutant strains, uncovered the
non-cell-autonomous roles of GrlA, G4 and G7. We found that
G7 is essential for the response to GABA and is likely to be coupled to
GrlE. GrlA-null and G4-null cells respond
normally to GABA but fail to secrete it. We found that they are necessary for
the response to a small hydrophobic molecule, SDF-3, which is released late in
culmination. Pharmacological inhibition of steroidogenesis during development
blocked the production of SDF-3. Moreover, the response to SDF-3 could be
blocked by the steroid antagonist mifepristone, whereas hydrocortisone and
other steroids mimicked the effects of SDF-3 when added in the nanomolar
range. It appears that SDF-3 is a steroid that elicits rapid release of GABA
by acting through the GPCR GrlA, coupled to G protein containing the G4
subunit. SDF-3 is at the head of the cascade that amplifies the signal for
encapsulation to ensure the rapid, synchronous formation of spores.
Key words: Steroids, SDF-2, SDF-3, G protein-coupled receptor, GrlA
|
INTRODUCTION |
|---|
|
TOP
SUMMARY
INTRODUCTION
MATERIALS AND METHODS
RESULTS
DISCUSSION
REFERENCES |
|---|
Sporulation is triggered when the activity of the cAMP-dependent protein
kinase PKA rapidly increases (Anjard et
al., 1998a
). Several intercellular signaling pathways control the
internal concentrations of cAMP that activate PKA
(Anjard and Loomis, 2005;
Anjard and Loomis, 2006;
Anjard and Loomis, 2008). SDF-1
is a phosphopeptide of 
1.2 kDa secreted at the onset of culmination that
induces spore formation after 90 minutes through a process that requires
protein synthesis (Anjard et al.,
1998b). Later on during development, other factors induce rapid
spore differentiation independently of any protein synthesis. A 34 amino acid
peptide, SDF-2, results in a decrease in cAMP phosphodiesterase activity and
cytokinins stimulate the activity of the adenylyl cyclase ACR
(Anjard and Loomis, 2005;
Anjard and Loomis, 2008).
Simultaneously removing the brake on the accumulation of cAMP and accelerating
its rate of synthesis can lead to a jump in PKA activity.
The activity of the cAMP phosphodiesterase, RegA, is dependent on
phosphorylation of its response regulator domain
(Shaulsky et al., 1996;
Thomason et al., 1999).
Phosphates are relayed to RegA from the two-component histidine kinase, DhkA,
via the H2 intermediate RdeA (Wang et al.,
1999; Thomason et al.,
1999; Anjard and Loomis,
2005). DhkA is the surface receptor for SDF-2 and its activity is
controlled by ligand binding (Wang et al.,
1999; Anjard and Loomis,
2005). When SDF-2 is present in the extracellular environment,
phosphorelay from DhkA to RegA is blocked.
Production of SDF-2 is also finely controlled. It is generated from the
acyl-CoA-binding protein, AcbA, which is released from prespore cells and
processed extracellularly by the prestalk-specific protease TagC. When cells
are exposed to low levels of SDF-2, AcbA is released and the TagC protease is
exposed to the outside. Thus, low levels of SDF-2 `prime' the cells for
production of more SDF-2. However, priming is inhibited by glutamate, which is
present outside the cells at 1 mM
(Anjard and Loomis, 2006).
Glutamate binds to the G protein-coupled receptor (GPCR) GrlE, and the signal
is transduced via a trimeric G protein containing G9. Priming by low
levels of SDF-2 is unaffected by the presence of 10 mM glutamate in cells
lacking either GrlE or G9 (Anjard
and Loomis, 2006). Release of AcbA and cell surface exposure of
the protease can also be triggered by 10 nM -aminobutyric acid (GABA)
(Anjard and Loomis, 2006;
Kinseth et al., 2007).
Glutamate is a competitive inhibitor of GABA induction of AcbA release and
both signals are dependent on GrlE (Anjard
and Loomis, 2006). However, the affinity of GrlE for glutamate
appears to be 100-fold lower than it is for GABA. Surprisingly,
G9-null mutants respond normally when GABA is added
(Anjard and Loomis, 2006).
Since we have evidence for direct binding of GABA to GrlE, it appears that
this GABAB-type receptor, unlike its mammalian homologs, binds both
glutamate and GABA, but is coupled only to G9 when it binds
glutamate.
In an effort to determine which trimeric G protein is coupled to GrlE when
it binds GABA, we surveyed all available mutations affecting G
subunits. We found that cells lacking G7 failed to produce SDF-2 in
response to GABA, although glutamate still inhibited priming by low levels of
SDF-2. Since these cells develop well but fail to accumulate SDF-2, it is
likely that the GABA signal transduction pathway is activated by GrlE when it
is coupled to a G7. All the other G mutants responded normally
to GABA, SDF-2 and glutamate. However, cells lacking G4 failed to
accumulate SDF-2 in their sori, suggesting that there might be another
GPCR-mediated signal transduction pathway in the sporulation cascade. To try
to identify the receptor that might be coupled to G4, we screened
mutant strains lacking specific GPCRs for the production of SDF-2, and found
that fruiting bodies of a mutant strain lacking GrlA contained no measurable
SDF-2. By analyzing material released by wild-type cells late in development,
we were able to recognize a novel factor, SDF-3, that triggers GABA signaling
in wild-type cells but not in cells lacking either GrlA or G4. SDF-3
stands at the head of the cascade as we now understand it.
|
MATERIALS AND METHODS |
|---|
|
TOP
SUMMARY
INTRODUCTION
MATERIALS AND METHODS
RESULTS
DISCUSSION
REFERENCES |
|---|
). Most of the other strains were obtained from the
Dictyostelium Stock Center
(http://dictybase.org).
The strain identifiers are: gpa1- (DBS0236088);
gpa2- (DBS0236094); gpa3-
(DBS0235986); gpa4- (DBS0235984);
gpa5- (DBS0236451); gpa7-
(DBS0236106); gpa8- (DBS0236107);
gpa9- (DBS0236109); grlE-
(DBS0236112); gadA- (DBS0235989);
acbA- (DBS0236991). The grlA- strain
(Prabhu et al., 2007) was the
kind gift of Angelica Noegel.
To generate a strain lacking GABA transaminase, a 1593 bp genomic fragment
starting 328 bp upstream of gabT coding sequence (Dictybase ID:
DDB_G0268104) was amplified by PCR using the forward primer
5'-GTCAGATTGAAATTACCCACCCC-3' and the reverse primer
5'-GAGGTGAGATTCCAATGTTCGTG-3'. The PCR product was cloned into
pGEMT-EASY (Promega, A1360) as previously described
(Anjard and Loomis, 2006) and
sequenced. The BSR cassette from pBSR519
(Puta and Zeng, 1998) was
cloned into the unique HindIII site located at the beginning of the
gabT coding sequence. For gene disruption, 10 µg of the plasmid
was linearized with NotI before electroporation into
1x107 AX4 or KP cells. Clones were selected with 5 µg/ml
Blasticidin S for 2 weeks then subcloned before analysis. Disruption of the
endogenous gabT gene in transformants was confirmed by a series of
four PCR amplifications using primers located outside the cloned sequences and
primers located within the BSR cassette. More than 50% of the tested clones
were positive for gabT disruption.
The bioassay was carried out on KP cells and their derivatives after 18
hours development in monolayers as previously described
(Anjard et al., 1998a). Cells
were incubated in cAMP buffer (20 mM MES pH 6.2, 20 mM NaCl, 20 mM KCl, 1 mM
MgSO4, 1 mM CaCl2, 5 mM cAMP) at a density of
1x103 cells/cm2 in the wells of a 24-well dish at
23°C. After 18 hours incubation, samples or defined products were added
and the numbers of spores and undifferentiated cells were counted 1 hour later
unless otherwise indicated. The priming effect of SDF-2 results in a
positive-feedback loop that gives an all-or-none response when SDF-2 is above
threshold concentration. SDF-2 and SDF-3 activity was determined by serial
dilution of the samples before addition to KP cells. Quantitation is only
accurate within a factor of two. One unit corresponds to the lowest dilution
giving full induction of spore formation. The number of units in the sample
was standardized to 1x103 producing cells whenever
applicable.
The response of cells from strains that are not sporogenous to SDF-3 and
steroids was measured following dissociation of culminants that had developed
on filters or non-nutrient agar (Anjard and
Loomis, 2006). Filters (25 mm diameter) were each spread with
5x106 to 1x107 cells and allowed to develop
for 20 hours at 22°C. Each filter was then examined under a dissecting
microscope. Only those filters on which most of the structures were similar
were used and any asynchronously developing culminants were removed from these
filters with a needle. The grlA- strain developed better
when spread at lower density (5x106 cells per filter),
whereas the gpa4- strain does not develop synchronously on
filters. The gpa4- strain was developed by plating on
non-nutrient agar made with 2% agar in phosphate buffer, resulting in a more
homogenous and synchronous development. The procedure to collect cells from
gpa4- was otherwise identical to that for the other
strains. The cells were allowed to develop and monitored every 15 minutes.
When stalks became apparent under the rising sori, the cells were collected by
vortexing the filters in 1 ml cAMP buffer followed by centrifugation at 4000
rpm (1250 g) for 1 minute in a microcentrifuge. The cells were
counted and diluted to 3.6x104/ml. Because the window of
development during which induction of sporulation can be assayed is only 15-30
minutes, only preparations that contained 10-20% spores were used. Five
hundred microliters of the suspension was added to each well of a 24-well
plate, resulting in a cell density of 104/cm2. Inducing
compounds were added at various concentrations and the number of spores
counted after 1 hour.
Cell growth and development
Cells were grown in HL5 medium at 22°C with shaking at 180 rpm for
oxygenation (Sussman, 1987).
Exponentially growing cells at a density of 2-5x106/ml were
harvested by centrifugation. Cells were washed with PDF buffer (20 mM Na/K
phosphate pH 6.5, 20 mM KCl, 1.2 mM MgSO4), centrifuged again at
1000 rpm (200 g) for 5 minutes and resuspended at a density of
1-2x108 cells/ml in PDF before being deposited on
nitrocellulose filters placed on pads saturated with PDF or on non-nutrient
agar plates made with 2% agar in PDF. Developing cells were then incubated at
22°C in a humid chamber for the indicated time. Spore viability assays
were performed as described (Anjard and
Loomis, 2006).
Purification of SDF-3
After a series of characterizations as described in the Results, a
procedure was developed to obtain a stock of SDF-3 used for later experiments.
A 20 ml suspension of Klebsiella aerogenes in 20 mM phosphate buffer
(pH 6.5) was prepared using bacteria collected from four SM plates. About
2x107 AX4 cells were collected and mixed with the K.
aerogenes suspension and plated on 22 SM plates. After 3 days incubation
at 22°C, the Dictyostelium cells cleared the plate and proceeded
to culminate. The fruiting bodies were collected in 20 ml water and SDF-3 was
extracted using 20 ml chloroform. The chloroform was evaporated under vacuum
and SDF-3 was dissolved in 20 ml 10% ethanol. A 2 ml suspension (50/50) of
Amberlite XAD-2 was added. The resin was pelleted and washed once with 25 ml
10% ethanol then 30% and 50% ethanol before elution with four times 5 ml of
70% ethanol. After vacuum evaporation, the pellet was redissolved in 200 µl
10% methanol. A 100 µl sample was loaded on a Majic C-18 column (internal
diameter 1 mm x length 150 mm) using an ultrafast HPLC apparatus (Microm
BioResources). The LC mobile phase A was 2.5% methanol in water and the LC
mobile phase B was 100% methanol. The LC flow rate was 50 µl/minute, and
the LC gradient was 100% A to 95% B in 20 minutes then held at 95% B for 5
minutes. Fractions of 50 µl were collected and tested by bioassay. Most of
the activity was found in fractions 20-21 (see Fig. S1 in the supplementary
material). These fractions were pooled, evaporated, and resuspended in 100%
methanol to create a main stock at 1000 units SDF-3/µl. This stock was kept
at -20°C and appears very stable. Intermediate stocks at 100, 10 and 1
unit/µl were prepared in 10% methanol (final).
Chemicals
GABA, L-glutamate, vigabatrin, terbamine, cAMP and most steroids
were supplied by Sigma. Progesterone and metyrapone were obtained from
Aldrich, corticosterone from Fluka. Dexamethasone was supplied by BIOMOL
International (Plymouth, MA, USA). Stock solutions were prepared as
recommended by suppliers. For most steroids, 50 mM stocks were prepared in
100% methanol, with more dilute intermediate stocks prepared in 10% methanol.
For terbamifine and aldosterone, DMSO was used for the 50 mM stock solution.
Anti-GABA antibodies (AB5016) were purchased from Chemicon International
(Temecula, CA, USA). A 1/10 intermediate stock of anti-GABA antibodies was
prepared in PBS; a final dilution of 1/5000 is sufficient to block the
induction effect of 20 nM GABA in the bioassay.
|
RESULTS |
|---|
|
TOP
SUMMARY
INTRODUCTION
MATERIALS AND METHODS
RESULTS
DISCUSSION
REFERENCES |
|---|
7 is required for the GrlE response to GABA; Anjard and Loomis,
2006). The GABA signal is transduced by the GPCR GrlE, which
activates a pathway that is independent of PKA
(Anjard and Loomis, 2006). GrlE
also functions in the signal transduction pathway by which glutamate inhibits
priming by SDF-2. The trimeric G protein subunit G9 is required for the
glutamate response but not for the GABA response. To determine the G
subunit involved in the GABA response, we analyzed all available G
mutant strains that could develop at least to the mid-culmination stage. Null
mutants in four putative G proteins (G6, G10, G11,
G12) were not available and null mutants lacking G2 or G3
fail to develop, even to the aggregation stage
(Kumagai et al., 1991;
Brandon et al., 2002).
Co-development of G2-null with acbA-null
cells resulted in the asynchronous formation of small fruiting bodies that
contained SDF-2 (Table 1).
|
|
mutants were developed and tested for the
presence of SDF-2 in the sorus. Both gpa4-null and gpa7-null
strains failed to accumulate SDF-2 (Table
1). Dissociated cells collected at the mid-culmination stage were
plated in multitest wells at 104 cells/cm2 and presented
with 1 pM SDF-2 or 10 nM GABA. One hour later, the increase in the number of
spores was determined. All of the mutant strains responded to SDF-2 by rapid
sporulation, as expected because the SDF-2 receptor is a histidine kinase
rather than a GPCR (Table 1).
However, the gpa7-null strain failed to respond to GABA. This
G protein may function in trimeric G proteins that are coupled to GrlE
when it has bound GABA. Activation of GrlE is required both for the release of
AcbA precursor by prespore cells and for exposure of the TagC protease on the
cell surface of prestalk cells. Defects in either aspect were tested
independently (Anjard and Loomis,
2006). The presence of secreted but unprocessed AcbA was tested by
digesting the extracellular media with trypsin, which mimics TagC activity.
Trypsin treatment did not generate any activity (<0.2 units/103
cells) from the supernatant of gpa7-null cells primed with GABA,
indicating that AcbA was not released. The activation of TagC protease
activity by GABA can be tested by adding recombinant AcbA and measuring the
production of SDF-2. Even after addition of recombinant AcbA, no SDF-2
(<0.2 units/103 cells) was obtained from the supernatant of
gpa7-null cells primed by GABA. Thus, G7 is required to
transduce GABA activation in both cell types.
We also tested for inhibition of SDF-2 priming by 10 mM glutamate. As
previously described, the strain lacking G9 is insensitive to
inhibition by glutamate (Anjard and Loomis,
2006). By contrast, glutamate inhibited priming in the strain
lacking G7, showing that GrlE discriminates among trimeric G proteins
depending on which ligand is bound.
Surprisingly, we found that cells lacking G4 had no measurable SDF-2
in their sori although dissociated cells responded normally to SDF-2, GABA and
glutamate (Table 1). The
simplest explanation for this phenotype is a defect in the initiation of GABA
signaling, resulting in the lack of AcbA release and subsequent processing to
SDF-2.
Synergy among strains
Mutants that do not produce an intercellular signal are often rescued when
they develop together with the wild type or other strains that provide the
signal (Sussman, 1954). We
used this synergy assay systematically. Six mutants unable to generate SDF-2
were co-developed with each of the other mutants. The production of SDF-2 by
each of these chimeras was tested, allowing us to establish synergy groups
based on their ability to rescue each other
(Fig. 1). Mutants lacking
G4 produced normal levels of SDF-2 if allowed to develop together with
an equal number of cells of strains that are defective in production of SDF-2
but nonetheless able to release GABA (Fig.
1). However, SDF-2 production was not rescued in
G4 mutants when they were developed together with
gadA-null cells that are compromised in the synthesis of GABA as the
result of loss of glutamate decarboxylase (GadA). Although G4 is
expected to act in an intracellular manner, its role is bypassed when the
cells are presented with GABA. Mutants lacking components in the same signal
transduction pathway leading to release of an intercellular signal fail to
synergize.
|
4 and cells
lacking any of the components of the GABA response (group 2) suggests that the
rescuing cells are responding to a factor that triggers GABA release. This
factor is likely to act through a GPCR because a trimeric G protein subunit,
G4, is implicated in the pathway. Therefore, we considered which of the
genes encoding GPCRs might be candidates for the receptor.
GrlA is coupled to G4
Prabhu et al. (Prabhu et al.,
2007) recently characterized a GPCR encoded by grlA that
is dispensable for growth and early development but necessary for
post-aggregative events. grlA is expressed at low levels in
vegetative cells and at high levels after 12 hours of development. It encodes
a seven-transmembrane protein of 90 kDa with well-conserved residues in the
intracellular loops where G proteins bind. By contrast, the N-terminal
ligand-binding domain displays little homology to characterized proteins.
Using a construct in which GFP was fused to the C-terminus of GrlA, Pradhu et
al. showed that the protein was present on the plasma membrane
(Prabhu et al., 2007).
Disruption of the gene resulted in a delay in culmination and a reduced
efficiency of sporulation. Activation of PKA by addition of 8-Br-cAMP to
grlA- cells dissociated from early culminants was found to
rescue sporulation, showing that the defect lay in the pathway leading to
activation of PKA late in development
(Prabhu et al., 2007). We
found that grlA- cells do not accumulate measurable SDF-2
in their sori, which could account for the defects in sporulation. However,
grlA- cells synergize with cells of any of the strains
lacking components of the GABA response (grlE-,
gpa7-, acbA-). These strains did not
accumulate more than 0.2 units SDF-2/103 cells when developed as
pure populations, whereas chimeric fruiting bodies had >5000
units/103 cells (Fig.
1).
The grlA- cells failed to synergize when developed
together with cells lacking either G4 or GadA; no SDF-2 was found in
these chimeric fruiting bodies. Taken together, these results suggest that a
novel secreted factor activates the receptor GrlA coupled to G4,
resulting in release of GABA synthesized by GadA
(Fig. 1).
Characterization of SDF-3
We isolated a factor from the supernatant of developed
gadA- cells that was able to stimulate rapid sporulation
of KP cells developing as monolayers. We used gadA- cells
as the source of the factor to avoid having GABA or SDF-2 in the supernatant.
Moreover, we removed SDF-1 from the supernatant by passage over cationic
resin. Doing so allowed us to detect a novel factor that we named SDF-3.
Wild-type cells were used later on as the source of SDF-3 after it became
clear that the new activity could be easily separated from other factors.
|
40-fold
more SDF-3 was found in the organic phase than in the aqueous phase upon
chloroform extraction. SDF-3 passed through an ultrafiltration membrane with a
3 kDa cut-off, indicating that it is a relatively small molecule. The
partially purified SDF-3 was found to be resistant to heating at 100°C or
treatment with proteinase K, indicating that it is not a peptide (see Table S1
in the supplementary material). SDF-3 was further purified by HPLC on a C-18
column using a water-methanol gradient (see Fig. S1 in the supplementary
material). The biological assays to define the effects of SDF-3 were performed
using a stock of this HPLC-purified activity.
SDF-3 rapidly induced high levels of spore formation in KP cells but the
response was 10 minutes slower than with SDF-2
(Fig. 2A). Antibodies against
GABA or AcbA blocked the induction effects of SDF-3, indicating that SDF-3
acts upstream of GABA and SDF-2. Direct assay of SDF-2 showed that it was
released 9 minutes after the addition of SDF-3
(Fig. 2B). This induction was
also prevented by the addition of anti-GABA antibodies. During optimization of
the bioassay for response to SDF-3, it became clear that the delay between
addition of the factor and the appearance of SDF-2 increased linearly with the
volume of the assay. This linearity held up to 500 µl, the volume normally
used in the bioassay (Fig. 2C).
The delay increased to 11 minutes for 600 µl and no SDF-2 production was
observed, even after 1 hour, for volumes above 750 µl (data not shown).
When GABA was used directly to induce SDF-2 production, the delay of 3.5
minutes was independent of the volume used in the bioassay
(Fig. 2C).
Although partially purified SDF-3 was able to induce rapid encapsulation of
wild-type cells dissociated from culminants, it had no effect on culminating
cells lacking GrlA, G4, GrlE or GadA
(Fig. 3). These mutant cells
all responded normally to induction by SDF-1 or the cytokinin
isopentenyladenine, which act through SDF-2-independent pathways (data not
shown).
A time course of SDF-3 accumulation was performed, using the hydrophobic resin Amberlite XAD-2 for purification. Wild-type cells developed for up to 20 hours yielded no detectable SDF-3 activity. Approximately 10-2 units/103 cells were detected in the supernatant of wild-type cells developed for 22 or 24 hours (see Table S2 in the supplementary material). When the cells were extracted with chloroform or methanol, 20- to 40-fold more SDF-3 activity was obtained than from the cell supernatant, indicating that only a small proportion was secreted (see Table S2 in the supplementary material).
We considered the possibility that SDF-3 might correspond to one of the
known small hydrophobic morphogens secreted by Dictyostelium during
development. DIF-1 has been characterized mostly for its role in the
regulation of stalk cell differentiation
(Saito et al., 2008). MPBD
(4-methyl 5-pentylbenzene 1,3 diol) was recently shown to affect both stalk
and spore formation (Saito et al.,
2006). Both DIF-1 and MPBD were tested at various concentrations
but failed to mimic the effects of SDF-3 (data not shown). Cytokinins are
small and somewhat hydrophobic molecules that induce spore formation by
activating the adenylyl cyclase ACR (Anjard
and Loomis, 2008). However, unlike SDF-3, they act independently
of GABA or SDF-2. Moreover, we found that a strain lacking the enzyme that
synthesizes cytokinins, IptA, produces normal levels of SDF-3 (data not
shown).
|
|
|
).
Mifepristone acted as a competitive inhibitor for both hydrocortisone and
SDF-3 (Fig. 5). By contrast, 1
µM mifepristone failed to block spore induction by 1 nM GABA or 1 pM SDF-2
(data not shown), indicating that the inhibitory effect against steroid and
SDF-3 is specific.
We also explored the effects of various inhibitors of the steroid
biosynthetic pathway. The antifungal agent, terbinafine, inhibits squalene
epoxidase such that conversion of squalene to lanosterol is blocked and
steroids cannot be synthesized (Petranyi
et al., 1984; Jandrositz et
al., 1991). Dictyostelium has a single gene encoding a
homolog of squalene epoxidase, sqlE, that is 50% identical to plant
and 40% identical to animal squalene epoxidases. Addition of 1 µM
terbinafine to developing KP cells completely blocked accumulation of SDF-3
(Table 3). Likewise, we tested
aminoglutethimide (AGI), metyrapone and etomidate, which are inhibitors of the
cholesterol side-chain cleavage enzyme and the P450 hydroxylases that are
necessary for conversion of cholesterol to steroids. Each of these drugs
blocked accumulation of SDF-3 when added to developing KP cells
(Table 3). By contrast, the
addition of cerulinin, which blocks the polyketide synthase responsible for
synthesis of DIF-1 and similar compounds
(Serafimidis and Kay, 2005),
failed to block the production of SDF-3. KP cells in monolayers incubated
overnight with terbinafine, AGI, metyrapone or etomidate were still able to
respond to SDF-3 by rapid sporulation. Likewise, addition of terbinafine or
AGI to wild-type cells developed on filters did not significantly affect
morphogenesis but blocked the production of SDF-3 and SDF-2 (data not shown).
The spore viability of the drug-treated wild-type cells was 20% of that
of untreated wild-type cells. Taken together, these results indicate that
SDF-3 is likely to be a steroid.
|
We also investigated the role of SDF-3 in GABA induction of sporulation and
its inhibition by glutamate. Glutamate has been detected in
Dictyostelium sori in the mM range
(Kelly et al., 1979;
Klein et al., 1990). We found
that 10 µM GABA is sufficient to overcome inhibition by 1 mM or 10 mM
glutamate, suggesting that the concentration of glutamate is saturating in
this range. When 2 units of SDF-3 or 10 nM hydrocortisone was added to the
cells, as little as 10 nM GABA was sufficient to bypass glutamate inhibition
(Fig. 6).
The level of GABA is determined by its rates of synthesis and degradation. Since the main enzyme known to degrade GABA is GABA transaminase, we investigated its role in regulating GABA levels. The Dictyostelium genome contains only one GABA transaminase gene (gabT). The predicted protein is highly similar to mammalian homologs. The role of gabT was investigated by inactivation using the non-reversible GABA transaminase inhibitor vigabatrin or by disruption of gabT. When vigabatrin was added to low-density KP cells, it induced SDF-2 release after 1 hour, followed by an induction of spore formation (Fig. 7A). This induction was prevented by anti-GABA or anti-AcbA antibodies, as well as by the GABA antagonist CGP 55845. The inactivation of gabT in wild-type cells has little consequence for the development cycle. The gabT-null strain finished development 1-2 hours earlier than the wild-type strain and was less synchronous (not shown). Inactivation of gabT in KP cells resulted in a strain that secretes SDF-2 spontaneously. At a cell density of 2x104/cm2, SDF-2 appeared within 16 hours (data not shown), whereas it took 19-20 hours at a density of 1x103 cells/cm2 (Fig. 7B). Addition of CGP 55845, anti-GABA or anti-AcbA antibodies to the gabT-null KP cells after 17 hours of incubation prevented SDF-2 production and the resulting induction of spore formation.
|
DISCUSSION |
|---|
|
TOP
SUMMARY
INTRODUCTION
MATERIALS AND METHODS
RESULTS
DISCUSSION
REFERENCES |
|---|
;
Saito et al., 2008). However,
inhibition of polyketide synthase by cerulinin failed to prevent SDF-3
accumulation and neither DIF-1 nor MPBD mimics SDF-3 activity. By contrast,
drugs that inhibit cholesterol side-chain cleavage and the P450 hydroxylases
that are necessary for conversion of cholesterol to steroids block
accumulation of SDF-3. Various steroids were found to mimic SDF-3 by inducing
SDF-2 production, with hydrocortisone showing the highest activity. Finally,
the most convincing evidence that SDF-3 is a steroid is that mifepristone
blocks its effects as effectively as it blocks those of hydrocortisone. We do
not know the exact structure of SDF-3 because the necessary analytical
techniques require relatively large amounts of purified material. Assuming
that the affinity of SDF-3 for cells is similar to that of hydrocortisone, we
estimate that at most 1 picomole of SDF-3 can be recovered and purified from
1x105 cells (Table
4).
|
|
|
). We
found that GrlA, a plasma membrane-localized GPCR, is necessary for the rapid
response to SDF-3. This receptor appears to be coupled to G proteins
containing G4 because mutants lacking G4 also fail to respond to
SDF-3. G4 had been shown to be required for folate sensing during
growth, presumably coupled to a different GPCR because folate chemotaxis is
unimpaired in cells lacking GrlA (Prabhu
et al., 2007).
SDF-3 induces the production of SDF-2 by stimulating the release of
sufficient GABA to induce secretion of AcbA within 5 minutes. Addition of
antibodies to GABA blocked SDF-2 production if added within the first 4.5
minutes after addition of SDF-3, but not after 5 minutes
(Fig. 2B). When the volume used
in the bioassay was reduced from 500 µl to 100 µl, the difference in the
time of appearance of SDF-2 following addition of SDF-3 and addition of GABA
was reduced to 1 minute, indicating that GABA is constantly secreted for
several minutes, rather than coming as a burst as more time is required to
reach the threshold for SDF-2 production in the larger volume
(Fig. 2C). The response to
threshold levels of GABA appears to be very rapid because addition of 1 nM
GABA to KP cells for only 10 seconds, followed by removal and addition of
fresh buffer, was sufficient to trigger SDF-2 production (data not shown).
Similar studies with mammalian cells have shown that activation of GPCRs by
their agonists can activate downstream signaling within 500 milliseconds
(Lohse et al., 2008).
SDF-3 fails to act in a strain lacking the late glutamate decarboxylase GadA, in which GABA levels are less than 20% of those in KP cells. SDF-3 signaling might stimulate GadA or could inhibit the GABA-degrading enzyme GABA transaminase, or both. We found that low-density cultures of a KP strain lacking GABA transaminase spontaneously produce SDF-2 and form many more spores than the parental KP strain (Fig. 7). This spontaneous sporulation was inhibited by addition of antibodies to GABA or the GABA antagonist CGP55845 to the low-density cultures. The levels of intercellular GABA appear to be in kinetic equilibrium determined by the relative rates of secretion and degradation. It is possible that GrlE only requires transient binding of GABA to trigger AcbA release.
SDF-3 also removes the inhibitory effect of glutamate on AcbA release,
allowing a sharper induction by GABA. Since glutamate blocks both AcbA
secretion by prespore cells and TagC exposure in prestalk cells, SDF-3 has to
remove these inhibitions in both cell types. G9 and GrlE are required
to transduce glutamate inhibition (Anjard
and Loomis, 2006). It is possible that the observed
desensitization by SDF-3 results from a modification to the relative affinity
of GrlE for GABA and glutamate.
The results from the synergy experiments clearly put GrlA, G4 and
GadA in one group and GrlE, G7 and AcbA in another
(Fig. 1). None of these mutant
strains produces SDF-2 when developed as pure populations. Mutant strains
lacking a component in one group are able to cooperate with strains lacking a
component of the other group, but not with strains lacking a component in
their own group. The genes mutated in these strains almost all code for
proteins that act internally and are not secreted. Therefore, it is somewhat
surprising that their phenotypes are non-cell-autonomous. However, when viewed
as a signaling cascade in which the internal components generate intercellular
signals connecting the synergy groups, the results are all consistent. The
results also imply that the pathway leading to SDF-2 production is a serial
cascade rather than comprising the integration of converging signals.
As previously mentioned, SDF-3 levels in fruiting bodies are extremely low.
When a unit is defined as the lowest dilution giving full induction of spore
formation in the KP cell bioassay, only 10-2 units
SDF-3/103 cells are recovered
(Table 4). However, SDF-3
triggers release of 50-fold more GABA in terms of units per cell. SDF-2
production occurs in a single burst upon stimulation by GABA and generates
104 units SDF-2/103 cells
(Anjard et al., 1998b;
Anjard and Loomis, 2006). Thus,
the signaling cascade results in a million-fold amplification of the original
signal. Since the bioassay is typically performed in a 500 µl volume with
2000 cells, the activity of SDF-3 and GABA is below the detection limit,
unless the samples have been previously concentrated. This is in contrast to
SDF-2 or SDF-1, which can easily be detected in the extracellular buffer. The
advantages of having such a multistep cascade regulating encapsulation are
that most cells are required to produce SDF-3 such that it can accumulate to
the threshold for GABA induction, and that GABA then elicits a large burst of
SDF-2 production ensuring that all prespore cells are synchronously induced to
encapsulate. Since exposure of the protease domain of TagC on the outside of
prestalk cells, where it can process AcbA into SDF-2, also requires GABA
signaling through GrlE, the signaling cascade coordinates differentiation of
the cell types.
Supplementary material
Supplementary material for this article is available at
http://dev.biologists.org/cgi/content/full/136/5/803/DC1
|
Footnotes |
|---|
|
REFERENCES |
|---|
|
TOP
SUMMARY
INTRODUCTION
MATERIALS AND METHODS
RESULTS
DISCUSSION
REFERENCES |
|---|
Anjard, C. and Loomis, W. F. (2005). Peptide
signaling during terminal differentiation of Dictyostelium.
Proc. Natl. Acad. Sci. USA
102,7607
-7611.
Anjard, C. and Loomis, W. F. (2006). GABA
induces terminal differentiation of Dictyostelium through a GABAB
type receptor. Development
113,2253
-2261.
Anjard, C. and Loomis, W. F. (2008). Cytokinins
induce sporulation in Dictyostelium.
Development 135,819
-827.
Anjard, C., Chang, W. T., Gross, J. and Nellen, W.
(1998a). Production and activity of spore differentiation factors
(SDFs) in Dictyostelium. Development
125,4067
-4075.[Abstract]
Anjard, C., Zeng, C., Loomis, W. F. and Nellen, W.
(1998b). Signal transduction pathways leading to spore
differentiation in Dictyostelium discoideum. Dev.
Biol. 193,146
-155.[CrossRef][Medline]
Anjard, C., Pinaud, S., Kay, R. R. and Reymond, C. D.
(1992). Overexpression of Dd PK2 protein kinase causes rapid
development and affects the intracellular cAMP pathway of Dictyostelium
discoideum. Development
115,785
-790.[Abstract]
Brandon, M. A., Mahadeo, D. C. and Podgorski, G. J.
(2002). Galpha3 and protein kinase A represent cross-talking
pathways for gene expression in Dictyostelium discoideum.
Dev. Growth Differ. 44,457
-465.[CrossRef][Medline]
Jandrositz, A., Turnowsky, F. and Högenauer, G.
(1991). The gene encoding squalene epoxidase from
Saccharomyces cerevisiae: cloning and characterization.
Gene 107,155
-160.[CrossRef][Medline]
Kelly, P. J., Kelleher, J. K. and Wright, B. E.
(1979). The tricarboxylic acid cycle in Dictyostelium discoideum:
metabolite concentrations, oxygen uptake and 14c-labelled amino acid labelling
patterns. Biochem. J.
184,581
-588.[Medline]
Kinseth, M., Anjard, C., Fuller, D., Guizzunti, G., Loomis, W.
F. and Malhotra, V. (2007). The Golgi associated protein
GRASP is required for unconventional protein secretion during development.
Cell 130,524
-534.[CrossRef][Medline]
Klein, G., Cotter, D. A., Martin, J. B. and Satre, M.
(1990). A natural-abundance 13C-NMR study of Dictyostelium
discoideum metabolism: monitoring of the spore germination process.
Eur. J. Biochem. 193,135
-142.[Medline]
Kumagai, A., Hadwiger, J. A., Pupillo, M. and Firtel, R. A.
(1991). Molecular genetic analysis of two Galpha protein subunits
in Dictyostelium. J. Biol. Chem.
266,1220
-1228.
Lohse, M. J., Hein, P., Hoffmann, C., Nikolaev, V. O.,
Vilardaga, J. P. and Bünemann, M. (2008). Kinetics of
G-protein-coupled receptor signals in intact cells. Br. J.
Pharmacol. 153,125
-132.[CrossRef]
Petranyi, G., Ryder, N. S. and Stütz, A.
(1984). Allylamine derivatives: new class of synthetic antifungal
agents inhibiting fungal squalene epoxidase. Science
224,1239
-1241.
Prabhu, Y., Mondal, S., Eichinger, L. and Noegel, A. A.
(2007). A GPCR involved in post aggregation events in
Dictyostelium discoideum. Dev. Biol.
312, 29-43.[CrossRef][Medline]
Puta, F. and Zeng, C. (1998). Blasticidin
resistance cassette in symmetrical polylinkers for insertional inactivation of
genes in Dictyostelium. Folia Biol.
44,185
-188.
Saito, T., Taylor, G. W., Yang, J. C., Neuhaus, D., Stetsenko,
D., Kato, A. and Kay, R. R. (2006). Identification of new
differentiation inducing factors from Dictyostelium discoideum.
Biochim. Biophys. Acta
1760,754
-761.[Medline]
Saito, T., Kato, A. and Kay, R. R. (2008).
DIF-1 induces the basal disc of the Dictyostelium fruiting body.
Dev. Biol. 317,444
-453.[CrossRef][Medline]
Schreiber, J. R., Hsueh, A. J. and Baulieu, E. E.
(1983). Binding of the anti-progestin RU-486 to rat ovary steroid
receptors. Contraception
128, 77-85.
Serafimidis, I. and Kay, R. R. (2005). New
prestalk and prespore inducing signals in Dictyostelium.
Dev. Biol. 282,432
-441.[CrossRef][Medline]
Shaulsky, G., Escalante, R. and Loomis, W. F.
(1996). Developmental signal transduction pathways uncovered by
genetic suppressors. Proc. Natl. Acad. Sci. USA
93,15260
-15265.
Sussman, M. (1954). Synergistic and
antagonistic interactions between morphogenetically deficient variants of the
slime mould Dictyostelium discoideum. J. Gen.
Microbiol. 10,110
-120.
Sussman, M. (1987). Cultivation and synchronous
morphogenesis of Dictyostelium under controlled experimental
conditions. Methods Cell Biol.
28, 9-29.[Medline]
Thomas, P., Dressing, G., Pang, Y., Berg, H., Tubbs, C.,
Benninghoff, A. and Doughty, K. (2006). Progestin, estrogen
and androgen G-protein coupled receptors in fish gonads.
Steroids 71,310
-316.[CrossRef][Medline]
Thomason, P. A., Traynor, D., Stock, J. B. and Kay, R. R.
(1999). The RdeA-RegA system, a eukaryotic phospho-relay
controlling cAMP breakdown. J. Biol. Chem.
274,27379
-27384.
Wang, N., Soderbom, F., Anjard, C., Shaulsky, G. and Loomis, W.
F. (1999). SDF-2 induction of terminal differentiation in
Dictyostelium discoideum is mediated by the membrane-spanning sensor
kinase DhkA. Mol. Cell. Biol.
19,4750
-4756.
CiteULike 
Complore 
Connotea 
Del.icio.us 
Digg 
Reddit 
Technorati 
Twitter What's this?
Related articles in Development:
| |||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||
