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Plant Physiol, March 2002, Vol. 128, pp. 788-789
NEWS FROM THE ARCHIVES
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ABSCISIC ACID: A UNIVERSAL SIGNALING FACTOR? |
In 1986, two papers appeared that
raised the possibility that abscisic acid (ABA) might be a universal
signaling factor. In the first, Le Page-Degivry et al. (1986)
established the presence of ABA in the brains of rats and pigs. In the
second, Huddart et al. (1986) proposed, based on experiments with
various smooth muscle preparations and a cyanobacterium that ABA may
serve as a universal Ca2+ agonist across taxonomic
kingdoms. This month's News from the Archives reviews
how the concept of ABA being a universal signaling factor has fared in
the ensuing years.
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ABA Present in Brains |
Le Page-Degivry et al. (1986) identified
(+)-cis-ABA in the brains of pigs and rats by means of a very
specific radioimmunoassay. The authors found that the final product of
purification from mammalian brain had the same properties as authentic
ABA: It cross-reacted in the ABA radioimmunoassay and had
the same retention properties and the same gas chromatography/mass
spectrometry characteristics. Moreover, like (+)-cis-ABA itself, the
brain factor decreased the stomatal apertures of abaxial epidermis
strips of Setcreasea purpurea. They also found evidence
for the presence of ABA conjugates (esters and glucosides) in brain
similar to those found in plants. Of course, the presence of ABA in the
brain could be interpreted to be a consequence of a diet containing
ABA. This would not, however, account for the especially high levels of
ABA found in the pig brain compared with other organs (heart, liver,
kidneys, and lungs). Moreover, rats fed a synthetic diet poor in ABA
were actually found to have higher levels of brain ABA
than rats fed a normal diet. While their discovery of ABA in mammalian
brains was intriguing, the authors did not speculate as to a possible function of ABA in brain tissue. Nor has much been published about a
possible role for ABA in brain function in the ensuing years.
The one exception is a report by Pidoplichko and Reymann
(1994), who provided evidence that pre-exposure to trans,trans-ABA, which is not the ABA isomer used by plants, induced a
marked increase of the fast component of
N-methyl-D-Asp (NMDA)-gated currents in isolated rat hippocampal neurons. Since the NMDA
receptor is a subtype of the ionotropic Glu receptor
(iGluR) gene family, and members of this family have
recently been discovered in Arabidopsis (Chiu et al., 1999), perhaps a
closer examination of the effects of ABA and its various isomers on
plant iGluR function might be worthwhile.
In short, the role, if any, of ABA in brain function remains as
mysterious as the day its presence in brains was first reported.
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ABA: A Ca2+ Agonist in Smooth Muscle? |
Huddart et al. (1986) presented evidence concerning the effects
of ABA on several mammalian smooth muscle preparations and on a
cyanobacterium. Studies on smooth muscles from the vas deferens and
bladder of rat showed that 10 6 M ABA enhanced
field stimulation responses by 25%. This effect was inhibited by the
Ca2+ channel blocker nifedipine. In
K+-depolarized bladder smooth muscle in which the
fast Ca2+ channels were inactivated, 106
M ABA augmented contraction tension and enhanced the slow
tonic phase of the response, which is known to be dependent on the
activity of slow Ca2+ channels. Even more impressive
effects were found with rat ileal smooth muscle. ABA at concentrations
of 109 to 108 M caused
enhancement of K+ contracture tension by up to 400%. This
response is strongly dependent upon extracellular Ca2+.
Preliminary data indicated that ABA enhances the influx of
Ca2+ occurring after K+ depolarization by about
60%. Thus, the results attained by Huddart et al. (1986) using all
three smooth muscle preparations were consistent with the idea that ABA
might act as a plasma membrane Ca2+ channel agonist.
The first follow-up study from Huddart's laboratory seemed to confirm
the effects of ABA on smooth muscle function. Langton and Huddart
(1988) reported that ABA was particularly effective in potentiating the
tonic component of K+-induced contractures in rat smooth
muscle vas deferens, particularly in muscles isolated from the
epididymis. Lynch (1991), however, found that the ABA analog SD217595
at 106 M caused an inhibition
of K+-induced phasic and tonic contractions of rat bladder
detrusor smooth muscle strips. The inhibition of contraction induced by SD217595 was in stark contrast to the potentiation of smooth muscle contraction reported previously by Huddart's group with the parent molecule ABA. Later, Masters et al. (1994), also of Huddart's laboratory, published a near retraction of Langton and Huddart's (1988) results, and concluded that ABA was without significant Ca2+-modulatory activity in their rat vas deferens smooth
muscle preparation. Like Lynch (1991), however, they found that the ABA
analog SD217595 possessed strong Ca2+ entry
blocking ability.
In short, data concerning the positive effects of ABA on smooth muscle
preparations seem conflicted at best.
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ABA: A Ca2+ Agonist in Cyanobacteria? |
In the case of cyanobacteria, Huddart et al. (1986) reported
that 107 M ABA caused a significant ratio in
the heterocyst to vegetative cell ratio of Nostoc 6720. Preliminary data also indicated that ABA led to an increase in
Ca2+ uptake (see also Pandey et al., 1996). The
Ca2+ ionophore A23187, like ABA, also caused an increase in
heterocyst frequency. Subsequent studies revealed that ABA and A23187 also led to an increase in nitrogenase activity (Smith et al., 1987;
see also Marsálek and Simek, 1992). The physiological
significance of the above studies is heightened by the discovery that
cyanobacteria produce ABA (Zahardnickova et al., 1991). Current
evidence, therefore, is consistent with the idea that ABA may be an
important physiological factor in cyanobacteria.
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ABA and Temperature Signaling in Sponges |
The idea that ABA may also serve a signaling role in
animal cells received a big boost from the recent findings of Zocchi et
al. (2001). These authors demonstrated that ABA stimulates an
ADP-ribosyl cyclase activity in sponges. This enzyme converts NAD+ into cADP-Rib, a potent and universal intracellular
Ca2+ mobilizer that has also been implicated in ABA signal
transduction in plants (Wu et al., 1997). Pharmacological evidence
indicated that ADP-ribosyl cyclase in Axinella
polypoides was activated by temperature increases by means of
an ABA-induced, protein kinase A-dependent mechanism. Sponges (phylum
Porifera) are among the oldest multicellular animals, their evolution
dating back to 600 million years ago. These results suggest an ancient
evolutionary origin of this stress-signaling cascade.
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FOOTNOTES |
www.plantphysiol.org/cgi/doi/10.114/pp.900026.
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LITERATURE CITED |
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Chiu J, DeSalle R, Lam HM, Meisel L, Coruzzi G
(1999)
Molecular evolution of glutamate receptors: a primitive signaling mechanism that existed before plants and animals diverged.
Mol Biol Evol
16: 826-838[Abstract]
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Huddart H, Smith RJ, Langton PD, Hetherington AM, Mansfield TA
(1986)
Is abscisic acid a universally active calcium agonist?
New Phytol
104: 161-173
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Langton PD, Huddart H
(1988)
Voltage and time dependency of calcium mediated phasic and tonic responses in rat vas deferens smooth-muscle
 the effect of some calcium agonist and antagonist agents.
Gen Pharmacol
19: 775-787[Medline] -
Le Page-Degivry MT, Bidard JN, Rouvier E, Bulard C, Lazdunski M
(1986)
Presence of abscisic acid, a phytohormone, in the mammalian brain.
Proc Natl Acad Sci USA
83: 1155-1158[Abstract/Free Full Text]
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Lynch M
(1991)
A possible role for abscisic acid analogs as calcium-channel blockers in mammalian smooth muscle.
Gen Pharmacol
22: 895-901[Medline]
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Marsálek B, Simek M
(1992)
Abscisic acid and its synthetic analog in relation to growth and nitrogenase activity of Azotobacter and Nostoc muscorum.
Folia Microbiol
37: 159-160
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Masters AK, Huddart H, Hetherington AM
(1994)
Actions of abscisic acid and the analog SD217595 on calcium-mediated activity of rat vas deferens smooth muscle.
Gen Pharmacol
25: 481-486[Medline]
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Pandey PK, Singh BB, Mishra R, Bisen PS
(1996)
Ca2+ uptake and its regulation in the cyanobacterium Nostoc MAC.
Curr Microbiol
32: 332-335[Medline]
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Pidoplichko VI, Reymann KG
(1994)
Abscisic acid potentiates NMDA-gated currents in hippocampal neurons.
Neuroreport
5: 2311-2316[ISI][Medline]
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Smith RJ, Hobson S, Ellis IR
(1987)
The effect of abscisic acid on calcium-mediated regulation of heterocyst frequency and nitrogenase activity in Nostoc 6720.
New Phytol
105: 543-549
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Wu Y, Kuzma J, Marechal E, Graeff R, Lee HC, Foster R, Chua NH
(1997)
Abscisic acid signaling through cyclic ADP-ribose in plants.
Science
278: 2126-2130[Abstract/Free Full Text]
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Zahardnickova H, Marsálek B, Polisenska M
(1991)
High performance thin layer chromatographic and high performance liquid chromatographic determination of abscisic acid produced by cyanobacteria.
J Chromatog
555: 239-245[CrossRef]
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Zocchi E, Carpaneto A, Cerrano C, Bavestrello G, Giovine M, Bruzzone S, Guida L, Franco L, Usai C
(2001)
The temperature-signaling cascade in sponges involves a heat-gated cation channel, abscisic acid, and cyclic ADP-ribose.
Proc Natl Acad Sci USA
98: 14859-14864[Abstract/Free Full Text]
Peter V. Minorsky
Department of Natural Sciences Mercy College Dobbs Ferry, NY 10522
© 2002 American Society of Plant Physiologists
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ABSCISIC ACID: A UNIVERSAL...
ABA Present in Brains