Products of Proline Catabolism Can Induce Osmotically Regulated Genes in Rice

doi:10.1104/pp.116.1.203

Products of Proline Catabolism Can Induce Osmotically Regulated Genes in Rice¹

Suresh Iyer and Allan Caplan^*

Department of Microbiology, Molecular Biology, and Biochemistry, University of Idaho, Moscow, Idaho 83844-3052

ABSTRACT

Top
Abstract
Introduction
Methods
Results
Discussion
References

Many plants accumulate high levels of free proline (Pro) in response to osmotic stress. This imino acid is widely believedto function as a protector or stabilizer of enzymes or membranestructures that are sensitive to dehydration or ionically induceddamage. The present study provides evidence that the synthesisof Pro may have an additional effect. We found that intermediatesin Pro biosynthesis and catabolism such as glutamine and $Delta$ ¹-pyrroline-5-carboxylic acid (P5C) can increase the expressionof several osmotically regulated genes in rice (Oryza sativa L.),including salT and dhn4. One millimolar P5C or its analog, 3,4-dehydroproline,produced a greater effect on gene expression than 1 mm l-Pro or75 mm NaCl. These chemicals did not induce hsp70, S-adenosylmethioninesynthetase, or another osmotically induced gene, Em, to any significantextent. Unlike NaCl, gene induction by P5C did not depend on thenormal levels of either de novo protein synthesis or respiration,and did not raise abscisic acid levels significantly. P5C- and3,4-dehydroproline-treated plants consumed less O₂, had reducedNADPH levels, had increased NADH levels, and accumulated manyosmolytes associated with osmotically stressed rice. These experimentsindicate that osmotically induced increases in the concentrationsof one or more intermediates in Pro metabolism could be influencingsome of the characteristic responses to osmotic stress.

INTRODUCTION

Top
Abstract
Introduction
Methods
Results
Discussion
References

During periods of drought or NaCl stress plants increase their pools of free Pro far in excess of the demands of protein synthesis.They do this by inducing Pro biosynthetic enzymes while repressingfurther synthesis of catabolic enzymes (Delauney and Verma, 1993;Kiyosue et al., 1996; Verbruggen et al., 1996). Although it hasbeen suggested that this increase in free Pro levels is a symptomthat results from imbalances in other metabolic pathways (Bhaskaranet al., 1985; Pérez-Alfocea and Larher, 1995), there is considerableevidence that high levels of Pro can be beneficial to stressedplants. For example, exogenously applied Pro was able to reducethe inhibitory effects of excess NaCl or insufficient water onthe growth of rice (Oryza sativa L.) (Kavi Kishor, 1989; Krishnamurthy,1991). Additionally, a genetic modification that increased thebasal level of Pro in tobacco reduced the plant's sensitivityto NaCl (Kavi Kishor et al., 1995). This protection can be explainedin at least two ways. On one hand, Pro may interact with enzymesto preserve protein structure and activity within the cell. Invitro studies have shown that high concentrations of Pro reduceenzyme denaturation attributable to heat, freeze-thaw cycles,and high NaCl (Pollard and Wyn Jones, 1979; Rajendrakumar et al.,1994). Alternatively, Pro may protect proteins and membranes fromdamage by inactivating hydroxyl radicals or other highly reactivechemical species that accumulate when stress inhibits electron-transferprocesses (Smirnoff and Cumbes, 1989; Saradhi et al., 1995).

These two models of action presume that free Pro functions solely as a solute to shield macromolecules from physical and chemicalfactors. However, in some organisms other than plants, Pro andits precursor, P5C, have a number of additional effects on physiologicalprocesses and gene expression. Pro stimulates calcium uptake inneuronal cells of the mammalian central nervous system (Henziet al., 1992). P5C selectively inhibits the initiation of translationof mammalian RNAs (Mick et al., 1988) and selectively enhancesthe accumulation of P₁450 mRNA in mice (Nemoto and Sakurai, 1991).Pro also serves as a key source of energy in insect flight muscles(Bursell and Slack, 1976). More generally, Pro oxidation to P5C,and P5C reduction back into Pro, provides cells with a means togenerate NADH and NADP⁺ from surplus amino acids (Fig. 1) (Phang, 1985). Because an increasein the ratio of NADP⁺ to NADPH can accelerate the catabolism of Glc through the pentosephosphate shunt (Yeh and Phang, 1988), changing the relative ratesof Pro synthesis and breakdown can be used to alter the productionof substrates for unrelated pathways such as purine biosynthesis.

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Figure 1. Stylized outline of Pro metabolism in the cytosol (larger rectangle) and the mitochondria (smaller rectangle). Step 1 is carriedout by the multifunctional enzyme P5C synthase. The remainingsteps are carried out by P5C reductase (P5CR), Pro dehydrogenase(PDH), and P5C dehydrogenase (P5CDH).

It has been established that many of the genes associated with carbon use are regulated by both growth hormones and changesin levels of particular pathway intermediates or end products(Thomas and Rodriguez, 1994). This dual control provides plantswith a means of modulating the impact of the hormone on the expressionof a biochemical pathway according to the availability of othermetabolites in the cell. We recently found evidence that a superficiallysimilar set of dual controls affects the expression of a ricegene called salT (Garcia et al., 1997). We found that the levelof expression of this gene is a particularly sensitive indicatorof abiotic stress. It is inducible by NaCl, drought, and ABA (Claeset al., 1990), often under conditions that do not induce any othergene tested. However, it is also inducible by Pro (Garcia et al.,1997), although it plays no apparent role in Pro metabolism. Thefact that exogenous application of ABA and Pro are equally effectiveinducers of gene expression may be an indication that they maybe co-regulators of metabolism during osmotic adjustment. In thispaper we provide evidence that precursors to Pro, or their analogs,affect respiration, solute accumulation, and the expression ofsalT and the dehydrin dhn4 (Close et al., 1989), and thereforemight serve as modulators of some of the biochemical changes accompanyingNaCl stress in rice.

	MATERIALS AND METHODS

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Plant Material and Growth Conditions

Rice (Oryza sativa L. var Cypress) seeds were sown on vermiculite and grown in an environmentally controlled growth chamberat 25°C and 70% RH with a 16-h photoperiod. Seedlings were wateredthree times a week and supplied with nutrient solution (Yoshidaet al., 1976

), including 100 µg L¹ silica once a week. Three-week-old seedlings were transferredto 1-L bottles and grown hydroponically in nutrient solution thatwas changed every 10 to 14 d. All experiments were conducted on6-week-old seedlings at the three-leaf stage.

Treatment of Plants for Biochemical Analyses

All chemicals tested were obtained from Sigma. All imino acid stock solutions were prepared in distilled water. SHAM and AntiA stocks were prepared in 80% ethanol. Seedlings were treatedby replacing the nutrient solution in the bottles with fresh solutioncontaining the appropriate chemicals at the desired concentrations,as indicated below. Sheath, blade, or root material was harvestedafter 24 h of treatment, frozen in liquid N₂, and stored at $-$ 80°C.

RNA Preparation and Northern-Blot Analyses

Total RNA was prepared according to Hepburn et al. (1983)

with the following modifications. Typically, 1 g of sheath materialwas homogenized in 2 mL of extraction buffer containing 100 mmTris-Cl (pH 8.4), 4 m urea, 6% p-aminosalicylic acid, 2% triisopropylnaphthalenesulfonic acid, 1% (w/v) SDS, 2 mm EDTA, and 10 mm $beta$ -mercaptoethanol,then extracted twice with phenol:chloroform (1:1, v/v) and oncewith chloroform. RNA was precipitated with 4 m lithium chloride,and the pellet was washed and dried as described (Hepburn et al.,1983

). For northern-blot analyses, 12 µg of total RNA was electrophoresedon 1.2% formaldehyde-agarose gels and blotted onto nylon membranes(Hybond-N, Amersham) following standard procedures (Maniatis etal., 1982

). Blots were hybridized with appropriate ³²P-labeled cDNA probes prepared using the Radprime DNA-labelingkit (GIBCO-BRL) according to the manufacturer's recommendations.Hybridizations were carried out in 6× SSPE, 5× Denhardt's solution,0.5% (w/v) SDS, and 50 µg mL¹ heparin at 65°C for 16 h. The filters were washed with 1× SSPEand 0.1% (w/v) SDS at 65°C and autoradiographed. Probes consistedof the rice genes salT (Claes et al., 1990

), sam (S-adenosylmethioninesynthase; Van Breusegem et al., 1994b

), and rab16 (Mundy and Chua,1988

), a rice hsp70 (Sasaki et al., 1994

) that is homologous tothe major maize heat-shock 70 protein, the wheat gene Em (Littset al., 1987

), and the barley genes dhn4 and dhn5 (Close et al.,1989

, 1995

O₂-Uptake Studies

Sheath material from each seedling was cut into small pieces that measured about 3 mm and weighed between 65 and 95 mg, suspendedin 2 mL of distilled water in a cuvette fitted with an O₂ electrode(Hansatech, Norfolk, UK), and stirred continuously. The O₂ concentrationin the solution was measured at 25°C and recorded by an Omnitracerrecorder (Houston Instruments, Austin, TX). The O₂ concentrationin air-saturated water was assumed to be 240 µm. All values presentedare the means from three independent experiments. Each experimentalvalue in turn is the mean from five measurements, each from anindependent seedling of the same treatment.

Measurement of NADH and NADPH Levels

Extraction of reduced pyridine nucleotides was done according to the method of Klingenberg (1974)

. One gram of quick-frozenand powdered sheath material was suspended with continuous stirringin 10 mL of 0.5 m alcoholic KOH, precooled at $-$ 17°C in an ice-NaClbath. The extracts were incubated in a 90°C water bath for 5 minand cooled rapidly on ice. After 5 min, the pH of the extractswas adjusted to 7.8 by slowly adding 4 mL of triethanolamine HCl-phosphatemixture with cooling and stirring. After incubation at room temperaturefor 10 min, the flocculated, denatured proteins were removed bycentrifugation at 28,000g for 10 min at 4°C. The clear supernatantswere used for the assay.

Pyridine nucleotide assays were performed according to the method of Peine et al. (1985). NADH and NADPH were assayed by anenzymatic-cycling technique, including an enzyme reaction andthe coupled nonenzymatic dichlorophenol indophenol reduction viaphenazine methosulfate. The reaction mixture contained 60 mm Trisbuffer (pH 7.6), 4 mm EDTA, 1 m ethanol or 30 mm Glc-6-P, 7 mmphenazine methosulfate, and 1 mm dichlorophenol indophenol. Alcoholdehydrogenase (80 units) was used for NADH determination and Glc-6-Pdehydrogenase (5 units) was used to determine NADPH. The stoichiometricdichlorophenol indophenol reduction was monitored at 625 nm usinga spectrophotometer (model DU-50, Beckman). The change in absorbance(A₆₂₅) in a reaction mixture containing 100 µL of the extractfor a period of 5 min was recorded, and the rate of reductionof absorbance (A₆₂₅ min¹) was calculated. A standard curve was prepared by determiningthe A₆₂₅ min¹ obtained with four different amounts of NADH or NADPH from 0to 100 nm. The rate of reduction was directly proportional tothe amount of NADH or NADPH added. Each experiment was repeatedtwo to three times, as indicated.

ABA Measurements

Six-week-old rice plants were treated for 24 h, as indicated. At the end of this period, sheaths were harvested and immediatelyfrozen in liquid N₂. ABA was extracted according to the methoddescribed by Walker-Simmons (1987)

with slight modifications.Typically, about 200 mg of frozen sheath material was ground toa fine powder using a precooled mortar and pestle. This was extractedwith 20 mL of methanol containing 100 mg L¹ 2,6-di-tert-butyl-4-methyl phenol (Aldrich) and 0.5 g L¹ citric acid monohydrate. Extracts were stirred in the dark at4°C for 20 h and then centrifuged at 3000g for 10 min. The supernatantswere purified by passage through Sep-Pak C₁₈ cartridges (Waters)and dried. Samples were then resuspended in 0.1 mL of methanoland 0.9 mL of distilled water. Before assaying, samples were centrifugedbriefly to remove insoluble material.

ABA levels were determined according to the instructions of the manufacturer (Idetek, Inc., Sunnyvale, CA). The absorbanceof the immunochemical assay was read at 405 nm using an EIA reader(model EL308, Bio-Tek Instruments, Inc., Winooski, VT). Measuredvalues were compared with a standard curve made from 1 mm (±)-cis,trans-ABA(Sigma) dissolved in methanol and diluted from 5.0 to 50 pmolmL¹ in 50 mm Tris, pH 7.5, with 150 mm NaCl and 1.0 mm MgCl₂. Eachexperiment was replicated twice and the results were averaged.

GC-Flame Ionization Detector Analyses of Sugars, Polyols, and Acids

Plant material was ground to a fine powder in liquid N₂, and then extracted and derivatized according to a procedure modifiedfrom the work of Sweeley et al. (1963)

. The trimethylsilyl derivativesof sugars, polyols, and acids were assayed, quantitated, and verifiedas described by Garcia et al. (1997)

	RESULTS

Top Abstract Introduction Methods Results Discussion References

Pro Metabolites Are More Potent Than Pro as Inducers of Gene Expression

Garcia et al. (1997)

have shown that 10 to 50 mm Pro inhibits rice growth and induces salT as effectively as 171 mm NaCl.Because endogenously made Pro is not distributed uniformly eitherwithin cells or between them (Pahlich et al., 1983

; Vartanianet al., 1992

), exogenously provided Pro may similarly be partitionedunequally. A simplistic explanation that is consistent with ourobservations (Garcia et al., 1997

) is that an unequal accumulationof exogenous Pro in rice temporarily produces an osmotic stress.An alternative and more direct explanation is that Pro serveseither as an inducer or as the precursor for an inducer of someof the genes needed to counter osmotic stress. To help distinguishbetween these explanations, we first sought to establish the chemicalspecificity of this effect. To do this, we tested several Proanalogs and pathway precursors listed in Table I. The resultsof northern-blot analysis of RNA from rice plants treated withsome of these substances are shown in Figure 2. salT is barelydetected in carefully cultured rice plants (Claes et al., 1990

;Garcia et al., 1997

), but in this particular experiment growthconditions inadvertently led to some salT messenger accumulationin control plants. This stress was not so severe as to inducedhn4, another osmotically regulated gene (Close et al., 1989

),but did sensitize the plants so that transcription increased inresponse to 1 mm Pro, whereas normally, much higher Pro levelsare needed (Garcia et al., 1997

). However, neither this treatmentnor 75 mm NaCl was as effective as treatments with two oxidizedderivatives of Pro: P5C and its analog, DHP.

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Table I. Summary of relevant biological properties of Pro analogs on Pro metabolism

Of these compounds, only Pro and P5C are natural to all cells. $-$ , Little to no effect; ±, weakly effective; +, effective;++, very effective; and unk, unknown (not tested).

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Figure 2. Effect of NaCl, Pro, P5C, and DHP on gene expression. Six-week-old rice plants were grown hydroponically for 24 h in mediumsupplemented with the indicated concentration of each chemical.At the end of the treatment, RNA was prepared from the sheathsand 12 µg was separated on 1.2% formaldehyde-agarose gels.The gel was then processed for northern-blot analysis using standardmethods and probed with radioactive fragments of each gene indicated.

A time-course experiment was done to determine whether rice responded more quickly to one of these imino acids. Plant sheathswere assayed for salT expression 3, 8, and 24 h after treatmentwith 1 mm l-Pro, P5C, and DHP. Little or no salT expression wasseen before 24 h (data not shown). At that time, there was approximately2-fold more salT RNA in DHP-treated plants than in plants treatedwith P5C. There was no response to Pro in this experiment.

To verify that the effect of Pro derivatives on osmotically responsive gene expression was specific, filters were rehybridizedwith a third osmotically regulated gene, Em (Litts et al., 1987),and one basic metabolic gene, sam (Van Breusegem et al., 1994b).Each of the three osmotically regulated genes responded differentlyto the treatments. Whereas the accumulation of Em mRNA was notaffected by the treatments used, mRNA levels for salT and dhn4were markedly, albeit differentially, affected by P5C and DHP.P5C and DHP also induced another dehydrin gene, rab16 (Mundy andChua, 1988), but only marginally affected a cold-induced dehydrin,dhn5 (Close et al., 1995; data not shown). These treatments actuallyreduced sam expression somewhat, indicating that they had notincreased either transcription, RNA processing, or messenger stabilityindiscriminately. Further studies using plants that were not alreadyexpressing salT showed that two other Pro analogs, d-Pro and thiaproline,were no better than Pro as inducers of salT (Fig. 3), Em, dhn4,and dhn5 (data not shown). In this case, we also assayed for theexpression of hsp70 (Sasaki et al., 1994), which can be inducedby severe osmotic stress (Borkird et al., 1991), but found thatits expression was not coordinated with salT.

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Figure 3. Effect of several Pro analogs on gene expression. Plants were treated with 1 mm of each chemical and analyzed as describedin the legend to Figure 2. C, Control, untreated.

Respiration Rate Affects Gene Induction by NaCl and Glu, but Not P5C

We next investigated whether salT mRNA levels could be elevated by making the precursors to P5C more available. P5C is synthesizedfrom Glu and NADPH (Fig. 1). Figure 4 shows that 1 mm Glu didenhance the expression of salT, but less effectively than thesame amount of DHP. It is interesting that supplying plants withboth Glu and enough Anti A to block O₂ consumption by approximately20% (data not shown) induced genes better than either could alone(Fig. 4). The same effect was found when plants were treated withNaCl. Figure 4 shows that Anti A treatment had no effect on itsown. Nevertheless, it enhanced the induction of salT by NaCl whenthe two treatments were combined. Based on these changes in messengerlevel, it appears that plants are either more sensitive to NaCland Glu, or alternatively, better able to synthesize or accumulatethe NaCl-induced signal, when NADH levels are increased or NADPHlevels are reduced (see Table II).

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Figure 4. Glu and NaCl are more effective inducers when respiration is inhibited. Plants were treated with 1 mm Glu or DHP, 75 mm NaCl,or 20 µm Anti A for 24 h, and then analyzed as described in thelegend to Figure 2.

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Table II. Respiratory activity of sheath segments from plants grown for 24 h with metabolic inhibitors, DHP, or P5C

Each value is the average ± se of two NADPH or three O₂ and NADH experiments.

A priori the entry of amino acids into plants might be physiologically coupled to an influx of ions. In this event these inorganicmolecules might be the true inducers of salT and dhn4. If so,inhibiting respiration with Anti A should have the same effecton DHP- and P5C-induced gene expression as on NaCl-induced geneexpression. Instead, neither Anti A nor Anti A with SHAM affectedP5C-induced gene expression (Fig. 5, A and B). In fact, Anti Aactually reduced the response to DHP-treatment slightly (Fig.4). This latter result will be examined further in the presentationof Figure 7. As in earlier experiments, sam messenger levels decreasedduring those treatments that induced salT (Figs. 2 and 4).

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Figure 5. P5C induction does not depend on respiration. Plants were treated with or without 1 mm P5C, and with (+) or without ( $-$ ) 20µm Anti A (A) or 20 µm Anti A and 2 mm SHAM (B), for 24 h, andthen analyzed as described in the legend to Figure 2. C, Control,untreated.

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Figure 7. Gene induction by DHP depends on respiration. Six-week-old rice plants were treated for 24 h with 1 mm DHP or P5C, 20µm Anti A, and 2 mm SHAM as indicated. RNA was preparedfrom the sheaths, processed for northern-blot analysis, and probedwith salT, sam, and hsp70. C, Control, untreated.

Gene Induction by P5C Does Not Depend on Protein Synthesis

We also compared the effect of CHX on induction by NaCl and by P5C. The expression of salT was not induced by NaCl if proteinsynthesis was inhibited by CHX (Fig. 6). If imino acid treatmentinduced gene expression like inorganic ions, then we expectedthat the effect of P5C would similarly be blocked by CHX. Instead,CHX had no effect on P5C-inducible expression of salT, or on thelevels of Em. Unexpectedly, CHX did induce expression of dhn4in the absence of other stimuli. It also reduced the responseof this gene to both NaCl and P5C. It is possible that a single,rapidly turning-over protein is both repressing dhn4 in healthysheaths and necessary to help positive regulatory factors bindtheir targets in stressed sheaths, but further work on this modelis beyond the scope of the current study.

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Figure 6. P5C induction does not depend on protein synthesis. Plants were treated with or without 1 mm P5C or 75 mm NaCl, and with (+)or without ( $-$ ) 20 µm CHX for 24 h, and then analyzed as describedin the legend to Figure 2. C, Control, untreated.

DHP Needs to Be Oxidized to Act as an Inducer of salT

During the course of our studies using metabolic inhibitors, we found that P5C (as well as DHP) reduced O₂ consumption bymore than 40% (Table II). It was possible that exogenously providedP5C and DHP were inhibiting O₂-consuming processes such as peroxidasesor some chloroplastic and glyoxysomal enzymes. However, therewas no additional decrease in O₂ consumption when Anti A was usedwith DHP (Table II), and further studies showed that P5C and DHPtreatments increased NADH levels as much as DHP and Anti A didtogether (Table II).

The NADPH levels may have decreased because Pro synthesis from exogenous imino acids proceeded faster than NADPH regeneration.The excess Pro produced by this treatment may have then been importedinto the mitochondrion and oxidized back to P5C to produce theobserved increase in NADH (see Fig. 1). This cycle of reductionand oxidation might explain the one major difference between theeffect of P5C and DHP on gene expression. SHAM and Anti A hadno effect on salT induction by P5C (Fig. 5). By contrast,Figures 4 and 7 show that treatment with Anti A reduced the effectivenessof DHP as an inducer. Furthermore, combining Anti A with SHAMfurther reduced the effectiveness of DHP (Fig. 7). Based on theseresults, we propose that DHP is not highly active until it isreduced to Pro and then reoxidized into P5C. Thus, when respirationlevels were reduced by treatment with inhibitors, P5C productiondeclined.

We have noticed that most treatments inhibiting respiration (P5C, DHP, Anti A, Anti A plus SHAM) elevated hsp70 mRNA levelsslightly. However, this effect was minor compared with the effectof P5C or DHP on salT and with the effect of other factors suchas ethanol, high-NaCl concentrations, and darkness on hsp70 (Borkirdet al., 1991; Van Breusegem et al., 1994a). None of the treatmentsused here induced sam mRNA levels significantly.

Could P5C Be Inducing ABA?

It has been shown that ABA reduces tissue respiration in stress-free conditions (Gude et al., 1988

; Tetteroo et al., 1995

).Consequently, one explanation for the results in Table II is thatP5C, DHP, or Glu is disturbing the plants in some way so thatABA accumulates until it induces the changes in gene expressionand respiration that we have noted. To test for accumulation ofthis hormone, we measured ABA levels in the sheaths of plantsthat had been grown with NaCl, P5C, and DHP. The results are shownin Table III.

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Table III. P5C does not induce a significant accumulation of ABA

Six-week-old rice plants were grown hydroponically for 24 h with each of the indicated chemicals. At that time, the sheathswere harvested, frozen, and extracted according to establishedprocedures (Walker-Simmons, 1987

). ABA was then measured immunologically.Each value represents the average of two independent treatments± se.

ABA levels in sheaths increased approximately 10-fold if they were grown with 20 µm ABA, the amount of hormone needed to inducesalT to a high level (Claes et al., 1990). NaCl stress, whichis clearly a weaker inducer during this period of time, increasedABA levels 4-fold over basal measurements. No significant ABAaccumulation was detected with Pro, P5C, or DHP, or with NaCland CHX combined. The effect of the imino acids on salT inductiontherefore appears to be ABA independent.

NaCl, P5C, and DHP Treatments Alter Steady-State Levels of Many Organic Solutes

Rice accumulates a variety of small, hydrophilic molecules during osmotic stress (Garcia et al., 1997

). A few of these solutesare believed to be made especially to reestablish the osmoticpotential needed to bring water into the plant (Binzel et al.,1987

) or to protect the structural integrity of some componentsof the cell (Crowe et al., 1984

). If Pro metabolic products areinfluencing the response of the plant to NaCl stress, then externallyprovided P5C and DHP might change the steady-state levels of theseosmotically regulated solutes.

Because NaCl-induced changes in gene expression, cell appearance, and solute accumulation differ in different parts of theplant (Garcia et al., 1997), we analyzed solute pools in two differentorgans: the uppermost blades and the roots (Table IV). The levelsof many solutes in the roots proved to be below the levels ofdetection of our assay. By contrast, blades contained a varietyof sugars, organic acids, and inositol. Treating plants with NaCleffected major changes in the concentrations of many of thesecompounds, not just the sugars and polyols commonly viewed asosmoprotectants. For instance, Glc and Fru levels increased 3-to 4-fold in the blades, whereas malic acid and inositol levelsdoubled. Strikingly, the pool sizes of both Suc and mannitol,which are known to be effective osmoprotectants (Crowe et al.,1984), increased in blades but not in roots.

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Table IV. Solute pools (mg g¹ fresh wt) in blades and roots of rice plants after 24-h treatments with NaCl, P5C, and DHP

nd, Not detected.

We next compared the solute pools in NaCl-grown rice with the pools of plants treated with 1 mm P5C or DHP for the same periodof time. Despite the differences in both the concentration andthe chemistry of the three inducers, they produced qualitativelysimilar effects. In the most general terms, the effects of NaCland P5C were similar in roots, whereas NaCl and DHP treatmentsproduced similar effects in the blades (Table IV). In each ofthese cases, though, the imino acid produced more dramatic effectsthan NaCl on the free solutes assayed. For example, NaCl and P5Cinduced the accumulation of each of the sugars and several organicacids in roots. By contrast, DHP induced the accumulation of malicand salicylic acids, but had no effect on succinic acid or thesugar pools.

A complementary effect was seen in the blades, but here DHP proved as effective as NaCl, whereas P5C did not. For example,both NaCl and DHP markedly increased the amounts of monosaccharidesand Suc, whereas P5C treatment had very little effect. In fact,P5C did not affect the levels of any of the substances assayedin this organ by more than 30%, except for salicylic acid. Whereaswe cannot say at this time whether the changes in the organicacids and sugars are caused by changes in gene expression or areinstead simply consequences of the inhibition of respiration,it is apparent that some of the metabolic correlates of NaCl stresscan be mimicked by treatment with P5C and its analog, DHP.

	DISCUSSION

Top Abstract Introduction Methods Results Discussion References

Plants must change dozens of physiological processes and biochemical pathways to minimize the damaging effects that osmoticstress has on cell structure and enzyme activity. One part ofthis process of osmotic adjustment includes the synthesis of proteases,chaperones, and hydrophilic proteins called dehydrins (Mundy andChua, 1988; Guerrero et al., 1990; Borkird et al., 1991). Anotherpart of the adaptive process includes production and accumulationof comparatively low-molecular-weight osmoprotectants that helpto preserve structural integrity and osmotic potential withindifferent compartments of the cell (Bartels et al., 1991; Vernonand Bohnert, 1992).

The key regulatory molecule that coordinates these defenses is the hormone ABA (LaRosa et al., 1987). However, ABA is notthe sole regulator of all of these genes. Several examples havebeen found of genes that are either induced by NaCl stress butnot by ABA (Thomas et al., 1992), or are dependent on both NaCland ABA for maximal expression (Bostock and Quatrano, 1992). Infact, even the accumulation of Pro itself may be only coincidentwith the increase of intracellular ABA rather than induced byit (Stewart and Voetberg, 1987; Thomas et al., 1992).

Gene Expression Can Be Affected by the Availability of Precursors for P5C Synthesis

We do not know which types of signal molecules mediate ABA-independent gene regulation; however, the results presented hereindicate that one such signal might be derived from the Pro biosyntheticand catabolic pathways. We have found that dhn4 and salT can beinduced not only by NaCl, but also by treating rice plants withexogenous P5C, or with either of two P5C precursors, Glu and Pro.In addition, the transcriptional response to NaCl and Glu is enhancedin plants treated with Anti A. This effect demands further studybefore it can be interpreted. We found that antimycin treatmentreduced the levels of NADPH and elevated those of NADH. It ispossible that the rice P5C synthetase was able to use some ofthis NADH to accelerate Glu reduction. Alternatively, NADP⁺ levels may have risen sufficiently to inhibit P5C reductase (Szokeet al., 1992

) so that P5C could accumulate.

If P5C is used as a signal during osmotic stress, then it should produce the same effects as NaCl. In general, P5C did induceeffects similar to those of NaCl in the sheath. We found thatboth molecules depressed O₂ consumption and enhanced NADH accumulationand gene expression in similar ways. However, differences betweenthese two treatments were seen when assays were performed on bladeends and on roots. In particular, P5C affected solute accumulationin roots, yet had little effect on solute pools in the upper blade.It is known that NaCl is transported well into rice blades (Garciaet al., 1997), but P5C might be catabolized during its passageupward so that too little reaches the blades to affect the physiology.

DHP acted much like P5C, with one significant difference: it affected solute accumulation in blades, yet had little effecton solute accumulation in roots. It is known that other biologicalsystems such as bacteria (Wood, 1981), embryonic cartilage cells(Rosenbloom and Prockop, 1970), and isolated maize mitochondria(Elthon and Stewart, 1984) can catabolize DHP in some way. Itis possible that similar reactions are being carried out in rice,allowing some DHP to be converted into either P5C or another inducer.The amount of DHP catabolized in roots may not be sufficient toaffect solute levels, but as it reaches the upper parts of theplant, enough could be catabolized to affect gene expression andsolute accumulation. If DHP was converted into Pro and subsequentlyinto P5C, then the two imino acids should be equally effective.Instead, Pro was a weak inducer in comparison with DHP. This couldbe evidence that DHP is not catabolized into Pro, or, alternatively,that DHP is transported upward by means of a P5C transporter likethose in mammals that discriminate against Pro (Mixson and Phang,1991).

Could the Effects of P5C Be Artifacts of Poisoning?

The effects on gene expression that we have monitored have been produced using toxic or potentially toxic chemicals (TableI). P5C is provided as a 2,4 dinitrophenylhyd-razine salt tostabilize it. This contaminant might inhibit some enzymes in thecells, including those needed for respiration. If so, its targetwas different from known inhibitors such as Anti A, SHAM, andCHX, which did not induce salT. Moreover, Glu proved more effectiveat inducing salT than two toxic imino acids, d-Pro and thiaproline.DHP is also a growth-inhibiting analog that can be incorporatedinto proteins and thereby change gene expression through the misfoldingof newly made transcription factors. If this was its primary modeof action in our studies, then inhibiting its reduction into Proshould have increased its effect on salT expression. However,Anti A and SHAM actually reduced the effect of DHP on the accumulationof salT mRNA.

Does Induction of Dehydrins and salT by Imino Acids Have Biological Significance?

The results summarized here are consistent with the hypothesis that P5C, glutamic- $gamma$ -semialdehyde, or a molecule derived fromthem is able to regulate the expression of some rice genes. However,we have not established how significant this effect is duringosmotic stress. Further studies are also necessary to determinewhy rice is responding to a common metabolite within the Pro biosyntheticpathway rather than to a more stress-specific metabolite. Onetrivial explanation is that the genes chosen to monitor plantresponses, dehydrins and salT, are specifically produced so thatthey can play an unidentified role in Pro metabolism. Alternatively,the synthesis of these gene products may be coordinated with theaccumulation of Pro because they are used in complementary waysto preserve cell structures during stress. Finally, it may beadvantageous to control these genes by both ABA and P5C so thattheir products can accumulate before the concentration of eitherinducer has reached its maximum.

	FOOTNOTES

¹ This research was supported in part by a Seed Grant from the University of Idaho, a grant from the State Board of Educationof Idaho to A.C., and a grant from the U.S. Department of Agriculture(no. 95-37304-2323) to A.W. Sylvester and A.C.
^* Corresponding author; e-mail acaplan{at}novell.uidaho.edu; fax 1-208-885-6518.

Received April 28, 1997; accepted September 23, 1997.

ABBREVIATIONS

Abbreviations: Anti A, antimycin A. CHX, cycloheximide. DHP, 3,4-dehydroproline. P5C, $Delta$ ¹- pyrroline-5-carboxylic acid. SHAM, salicylhydroxamic acid.

	ACKNOWLEDGMENTS

The authors thank Drs. David Oliver and Robert Behal for advice and guidance through the intricacies of biochemistry, andDrs. Zhixiang Chen and Bruce Miller for careful reading of anearlier version of this paper. We thank the following people forproviding genes: Dr. Ralph Quatrano for the clone of Em, Dr. TimClose for the clones of several barley dehydrin genes, includingdhn4, and Dr. Henry Nguyen for the clone of rab16.

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Products of Proline Catabolism Can Induce Osmotically Regulated Genes in Rice1

Copyright Clearance Center: 0032-0889/98/116/0203/09 © 1998 American Society of Plant Physiologists

Products of Proline Catabolism Can Induce Osmotically Regulated Genes in Rice¹

Copyright Clearance Center: 0032-0889/98/116/0203/09

© 1998 American Society of Plant Physiologists