Molecular Mechanisms of Proline-Mediated Tolerance to Toxic Heavy Metals in Transgenic Microalgae

doi:10.1105/tpc.004853

Molecular Mechanisms of Proline-Mediated Tolerance to Toxic Heavy Metals in Transgenic Microalgae

Surasak Siripornadulsil^a, Samuel Traina^b, Desh Pal S. Verma^c and Richard T. Sayre¹^,a^,d

^a Biophysics Program, Ohio State University, Columbus, Ohio 43210
^b Department of Natural Resources, Ohio State University, Columbus, Ohio 43210
^c Department of Molecular Genetics and Plant Biotechnology Center, Ohio State University, Columbus, Ohio 43210
^d Department of Plant Biology and Biophysics Program, Ohio State University, Columbus, Ohio 43210

¹ To whom correspondence should be addressed. E-mail sayre.2{at}osu.edu; fax 614-292-7162

Abstract

TOP
Abstract
INTRODUCTION
RESULTS
DISCUSSION
METHODS
References

Pro has been shown to play an important role in amelioratingenvironmental stress in plants and microorganisms, includingheavy metal stress. Here, we describe the effects of the expressionof a mothbean ${Delta}$ ¹-pyrroline-5-carboxylate synthetase (P5CS) genein the green microalga Chlamydomonas reinhardtii. We show thattransgenic algae expressing the mothbean P5CS gene have 80%higher free-Pro levels than wild-type cells, grow more rapidlyin toxic Cd concentrations (100 µM), and bind fourfoldmore Cd than wild-type cells. In addition, Cd-K edge extendedx-ray absorption fine structure studies indicated that Cd doesnot bind to free Pro in transgenic algae with increased Prolevels but is coordinated tetrahedrally by sulfur of phytochelatin.In contrast to P5CS-expressing cells, Cd is coordinated tetrahedrallyby two oxygen and two sulfur atoms in wild-type cells. Measurementsof reduced/oxidized GSH ratios and analyses of levels of malondialdehyde,a product of the free radical damage of lipids, indicate thatfree Pro levels are correlated with the GSH redox state andmalondialdehyde levels in heavy metal–treated algae. Theseresults suggest that the free Pro likely acts as an antioxidantin Cd-stressed cells. The resulting increased GSH levels facilitateincreased phytochelatin synthesis and sequestration of Cd, becauseGSH–heavy metal adducts are the substrates for phytochelatinsynthase.

INTRODUCTION

TOP
Abstract
INTRODUCTION
RESULTS
DISCUSSION
METHODS
References

Cd is widely used in a variety of industrial processes, includingplastic manufacturing, electroplating, and Ni-Cd battery production,as well as in pigments (Alloway, 1995; Dudka and Adriano, 1997).These industries, as well as mining and smelting industries,release substantial amounts of Cd into the environment eachyear (Nriagu and Pacyna, 1988). In animals and humans, chronicor toxic exposure to Cd can induce a variety of health disorders,including kidney damage (Buchet et al., 1980; Hellstrom et al.,2001), osteomalacia (Nogawa and Kido, 1993; Tsuritani et al.,1996), developmental defects, and prostate cancer (Desi et al.,1998).

Plants readily take up Cd from the soil. However, exposure tohigh levels of Cd results in reduced rates of photosynthesis,chlorosis, growth inhibition, browning of root tips (Kahle,1993), decreases in water and nutrient uptake, and finally death(di Toppi and Gabbrielli, 1999). At the molecular level, Cdtoxicity is associated with the formation and disruption ofsulfhydryl and metal thiolate bonds, alterations in proteinsecondary structure, changes in the redox status of the cell,and interference with essential metal uptake, transport, andmetabolism (Brennan and Schiestl, 1996; Chaoui et al., 1997;Ouariti et al., 1997; Nies, 1999; Sandalio et al., 2001). Inaddition, Cd poisoning of metalloproteins involved in redoxor electron transfer processes may result in increased freeradical production, leading to nonspecific damage to proteins,lipids, and other biomolecules (Stohs et al., 2000; Schützendübelet al., 2001).

There are a variety of mechanisms by which organisms reduceheavy metal toxicity, including production of heavy metal bindingfactors and proteins (metallothionein, GSH, and phytochelatinconjugates), exclusion of toxic heavy metals from cells by ion-selectivemetal transporters, and excretion or compartmentalization (Howeand Merchant, 1992; Kaplan et al., 1995; Lee et al., 1996; Cohenet al., 1998; Guerinot, 2000; Hu et al., 2001). One mechanismby which many plants and algae respond to and apparently detoxifytoxic heavy metals is the production of Pro (Delauney and Verma,1993; Schat et al., 1997; Shah and Dubey, 1998; Mehta and Gaur,1999; Verma, 1999). The accumulation of Pro in stressed plantsis associated with reduced damage to membranes and proteins(Alia et al., 1997; Shah and Dubey, 1998; Verma, 1999). Prosynthesis has been implicated in the alleviation of cytoplasmicacidosis and may maintain NADP⁺/NADPH ratios at values compatiblewith metabolism (Hare and Cress, 1997). Rapid catabolism ofPro upon relief of stress also may provide reducing equivalentsthat support mitochondrial oxidative phosphorylation and thegeneration of ATP for recovery from stress-induced damage (Hareand Cress, 1997). However, there has been much disagreementregarding the mechanism(s) by which Pro reduces heavy metalstress. Free Pro has been proposed to act as an osmoprotectant(Paleg et al., 1984; Delauney and Verma, 1993; Taylor, 1996),a protein stabilizer (Kuznetsov and Shevyakova, 1997; Shah andDubey, 1998), a metal chelator (Farago and Mullen, 1979), aninhibitor of lipid peroxidation (Mehta and Gaur, 1999), a hydroxylradical scavenger (Smirnoff and Cumbes, 1989), and a singletoxygen scavenger (Alia et al., 2001). It is evident that thereis no clear consensus regarding the mechanism(s) by which Proreduces heavy metal stress.

We have investigated the role of Pro in facilitating Cd detoxificationand ameliorating salt stress in microalgae by comparing theresponses of wild-type and transgenic algae, which have nearlytwofold higher free Pro levels, with toxic levels of Cd andtreatment with seawater. We demonstrate that increased freePro levels provide enhanced protection from Cd- and salt-inducedstress. Furthermore, we show that Pro reduces Cd stress notby sequestering Cd but by reducing Cd-induced free radical damageand by maintaining a more reducing environment (higher GSH levels)in the cell. The Pro-dependent increase of cytoplasmic GSH levelsin Cd-treated cells facilitates Cd sequestration and its detoxificationas phytochelatin conjugates.

RESULTS

TOP
Abstract
INTRODUCTION
RESULTS
DISCUSSION
METHODS
References

Overexpression of the Mothbean ${Delta}$ ¹-Pyrroline-5-Carboxylate Synthetase Gene in Chlamydomonas reinhardtii
To enhance Pro synthesis in transgenic algae, we introduceda mothbean ${Delta}$ ¹-pyrroline-5-carboxylate synthetase (P5CS) geneinto the nuclear genome of Chlamydomonas. P5CS catalyzes thefirst dedicated step in Pro synthesis from glutamate (Hu etal., 1992). The mothbean P5CS cDNA was cloned into plasmid pSSCR7and cotransformed with plasmid p389, encoding an Arg succinyllyase (arg7-8), into the nuclear genome of Chlamydomonas strainCC-425 (cell-wall-less, arg7-8) by electroporation (Shimogawaraet al., 1998). Transformed cells were selected for their abilityto grow in the absence of Arg and for the presence of the P5CSgene by PCR amplification using P5CS gene-specific primers.The identity of the P5CS PCR product was confirmed by DNA sequenceanalysis. Genomic DNA gel blot analysis of three transgeniclines indicated that one to nine copies of the mothbean P5CSgene were inserted into the genomes of the various transgeniclines (data not shown).

In the absence of Cd, all three P5CS transgenic algal strainsgrew to slightly higher stationary-phase cell densities thanwild-type cells. These results suggest that enhanced Pro productiondoes not impair and may slightly enhance the growth of C. reinhardtiiunder nonstressed growth conditions (Figure 1A) . However,in the presence of toxic concentrations of Cd (100 µM),mothbean P5CS transgenic cells (P5CS-1) had as much as a 1.5-foldincreased growth rate relative to wild-type cells (Figure 1B).In addition, algal cultures expressing the P5CS gene had significantlyhigher levels of chlorophyll per cell than wild-type cells whengrown in the presence of toxic concentrations of Cd (100 µM)(Figures 1A to 1D). Among the three P5CS transformants screened,the chlorophyll content per cell of the P5CS-1 strain was highestwhen grown in Cd (100 µM). Surprisingly, algae expressingthe mothbean P5CS gene (P5CS-1, P5CS-2, and P5CS-3) also hadsubstantially higher Cd binding capacities (4.2-, 3.0-, and2.5-fold, respectively) than wild-type cells (Table 1).

View larger version (37K):
[in this window]
[in a new window]

Figure 1. Growth Rates and Chlorophyll Contents of Wild-Type and P5CS-Expressing Transgenic Algae Grown in the Presence and Absence of Cd.

(A) Growth rate in the absence of Cd.

(B) Growth rate in the presence of 100 µM Cd.

(C) Chlorophyll content in the absence of Cd.

(D) Chlorophyll content in the presence of 100 µM Cd.

Data shown are average absorbance units at 750 nm (cell concentration) or chlorophyll concentration per milliliter of culture ± SD from three separate experiments. W.T., wild type.

View this table:
[in this window]
[in a new window]

Table 1. Cd Binding Capacity of Wild-Type (CC-425) and P5CS-expressing Transgenic Algae Grown in the Presence of 50 µM Cd

The P5CS-1 strain, which exhibited the fastest growth, highestchlorophyll content, and greatest Cd binding capacity, was selectedfor further physiological and molecular analyses. To determinewhether expression of the P5CS gene conferred resistance toother types of stress, we compared the survivability of wild-typeand P5CS-1 algae to different periods of seawater exposure.As shown in Figure 2 , the P5CS-1 strain survived up to 12h of exposure to seawater, whereas no survivors were recoveredfrom wild-type cells after a 1-h incubation in seawater.

View larger version (16K):
[in this window]
[in a new window]

Figure 2. Survival of Wild-Type and P5CS-1 Transgenic Algae in Seawater.

Cells were incubated with artificial seawater for 1, 3, 5, 12, or 24 h before growing in Tris-acetate-phosphate medium supplemented with Arg. Black bars represent wild-type cells, and gray bars represent P5CS-1 cells. Data shown are average percent survival after seawater incubation ± SD from three separate experiments.

To determine whether the enhanced stress tolerance of the P5CS-1strain was associated with expression of the P5CS protein, weperformed protein gel blot analyses for expression of the P5CSprotein in P5CS-1 and wild-type cells using mothbean P5CS-specificpolyclonal antibodies (Figure 3A , lanes 1 to 3). As shownin Figure 3A, P5CS-1 transgenic cells expressed the mothbeanP5CS protein. Significantly, the mothbean P5CS antibodies didnot detect any Chlamydomonas proteins in wild-type cells, suggestingthat Chlamydomonas may not express an antigenically similarenzyme. The expression of the P5CS protein also was associatedwith increased cytoplasmic free Pro levels. As shown in Figure 3B,transgenic algae expressing the mothbean P5CS gene had 80%higher free Pro levels than wild-type cells. Previous studieshave reported enhanced accumulation of free Pro in some algalspecies after exposure to toxic concentrations of Cu or Cd (Wuet al., 1995

). However, we observed no Cd-induced (50 µM)increases in free Pro content in wild-type or P5CS-expressingcells (Figure 3B).

View larger version (26K):
[in this window]
[in a new window]

Figure 3. Expression of the Mothbean P5CS Protein and Pro Production in Transgenic Algae.

(A) Protein gel blot of total soluble proteins from P5CS transgenic algae (lanes 1 to 3) and wild-type (W.T.) algae (lanes 4 to 6). The samples were loaded at 10 µg (lanes 1 and 4), 15 µg (lanes 2 and 5), and 20 µg (lanes 3 and 6) of soluble protein. The membrane was immunodecorated with antibodies raised against purified mothbean P5CS protein. Molecular masses (kD) of protein markers (Gibco BRL) are indicated.

(B) Free Pro content of wild-type algae (black bars) and P5CS-1–expressing transgenic algae (gray bars) grown in the presence and absence of 50 µM Cd. Free Pro is expressed per absorbance unit at 750 nm ± SD (cell concentration) from three separate experiments.

Cd-K Edge Extended X-Ray Absorption Fine Structure Spectra
To determine whether cytoplasmic free Pro directly sequesteredCd, we determined the chemical identity of the atoms bindingCd and their associated bond lengths by extended x-ray absorptionfine structure (EXAFS) spectroscopy. The Cd-K edge x-ray absorptionspectra of the model solutions (Cd-GSH, Cd-Pro, and Cd-GSH-Pro)and of Chlamydomonas cells grown in the presence of 50 µMCd are shown in Figure 4A . The corresponding EXAFS spectraand Fourier transforms are shown in Figures 4B and 4C, respectively.The absorption energy (26.72 keV) for Cd-electron ejection isconsistent with the expected values for Cd. The spectra thenwere modeled and fit using the FEFF 8 (Ankudinov et al., 1998

)and EXAFSPAK (George and Pickering, 1995

) software packages.The raw and fitted data are shown in Figures 4B and 4C and listedin Table 2.

View larger version (23K):
[in this window]
[in a new window]

Figure 4. Cd-K Edge X-Ray Absorption Spectra (A), EXAFS Spectra (B), and EXAFS Fourier Transform (C) of Cd-GSH, Cd-Pro, and Cd-Chlamydomonas Complexes.

Waves are as follows: A, GSH-Cd(NO₃)₂ solution; B, Pro-Cd(NO₃)₂ solution; C, GSH-Pro-Cd(NO₃)₂ solution; D, Chlamydomonas wild type (CC-425) grown in 50 µM Cd; E, Chlamydomonas expressing P5CS grown in 50 µM Cd. Solid lines represent experimental data, and dashed lines represent results of the least-squared fit to the EXAFS.

View this table:
[in this window]
[in a new window]

Table 2. Cd-K Edge EXAFS Curve-Fitting Results for Chlamydomonas Cells Grown in the Presence of Cd (50 µM) and for Model Solutions

The results of the EXAFS fit to all three model solutions (Cd-GSH,Cd-Pro, and Cd-GSH-Pro) are in agreement with the crystallographicdata for CdCO₃ (otavite) (Graf, 1961

). For CdCO₃, the coordinationnumber is 6 and the interatomic distance is 2.2892 Å.The Cd-O interatomic distance between all three model samplesand CdCO₃ differs by <0.02 Å. In addition, the resultsof the EXAFS fit to the first shell of the Cd-GSH, Cd-Pro, andCd-GSH-Pro solutions (Table 2) show strong similarities betweenthe model compounds and CdCO₃. Finally, the coordination numbersfor the model compounds are close to the ideal value of 6 forpure O coordination. As expected, there is an $~$ 20% error in calculatingthe coordination in the first shell. These results suggest thatthe Cd-GSH model solutions were oxidized and that the sulfhydrylgroup was unavailable for Cd coordination.

In the wild-type microalgal samples, the Cd EXAFS spectra couldbe fit only by including both O and S in the first coordinationshell, at bond lengths of 2.2 and 2.5 Å, respectively(Figure 4). As shown in Figures 4B and 4C and Table 2, the resultsof the EXAFS fit to Chlamydomonas wild-type cells are in excellentagreement with a combination of crystallographic data for CdCO₃(otavite) (Graf, 1961) and Cd-S (hawleyite) (Traill and Boyle,1955). For Cd-S (hawleyite) and CdCO₃ (otavite), the coordinationnumbers are 4 and 6 and the interatomic distances are 2.53 and2.29 Å, respectively. The Cd-O and Cd-S interatomic distancesof wild-type cells differ from those of CdCO₃ and Cd-S by <0.02and 0.01 Å, respectively. The presence of O ligands forCd in wild-type cells is consistent with that in previous chemicaltitration and Fourier transform infrared studies of Cd bindingto Chlamydomonas (Adhiya et al., 2002). By contrast, in P5CS-1transgenic algae, the EXAFS spectrum is best fit by Cd coordinationto four sulfur atoms at a bond distance of $~$ 2.5 Å. In addition,the results of the EXAFS fit to the transgenic algae are inagreement with the crystallographic data for Cd-S (Traill andBoyle, 1955) and for Cd-phytochelatin complexes (Pickering etal., 1999), including the ligand type, coordination number,and the Cd-ligand interatomic distance. Although one might anticipatethat S ligation to Cd would produce a less "peaky" edge thanis observed for Cd-O moieties (Salt et al., 1995), careful examinationof Figure 4 shows that the EXAFS oscillations of the wild-typeand P5CS-1 strains are somewhat out of phase. Overall, the EXAFSdata strongly suggest that Cd is sequestered by phytochelatinsand not Pro in P5CS-1 transgenic algae. This interpretationis further supported by comparative analyses of the model compoundsand the algal samples. As indicated in Table 2, the Debye-Wallerfactors (0.0072 to 0.0096 Å² for Cd-O) for the model solutionswere increased relative to that for wild-type algae (0.0039Å² for Cd-O). The increased Debye-Waller factors for themodel samples presumably arise from static disorder within theCd-O populations. This disorder also is observed in transgenicalgae, suggesting that Cd is not complexed by the same conjugatesas those observed in wild-type algae.

To further define the role of sulfhydryls in Cd binding in P5CStransgenic cells, we measured GSH levels in cells grown in thepresence and absence of sufficient Cd (50 µM) to inducephytochelatin synthesis (Howe and Merchant, 1992; Wu et al.,1995; Cai et al., 1999). Under these conditions, GSH can bindCd directly, and the heavy metal adduct serves as the substratefor phytochelatin synthase (Vatamaniuk et al., 2000). As discussedpreviously, conjugation of heavy metals to phytochelatin isa primary means of detoxifying heavy metals in plants and algae.As shown in Figure 5C , there was a nearly threefold increasein GSSG levels in wild-type cells when grown in the presenceof Cd. By contrast, there was no increase in GSSG levels inP5CS transgenic cells. When the reduced and oxidized forms ofGSH were expressed as a molar ratio (GSH:0.5 GSSG), it was apparentthat wild-type cells had a fourfold reduction in their GSH:0.5GSSG ratio relative to P5CS-1–expressing cells when grownin the presence of Cd. These results suggest that in the presenceof Cd, the redox state of the cytoplasm of P5CS-expressing cellsremains more reducing than that of wild-type cells.

View larger version (24K):
[in this window]
[in a new window]

Figure 5. MDA Content and GSH:0.5 GSSG Redox State of Wild-Type (black bars) and P5CS-1–Expressing Transgenic Algae (gray bars).

(A) MDA content per cell.

(B) Redox state of cells as measured by GSH content.

(C) GSSG content per cell.

(D) GSH:0.5 GSSG redox ratio.

Data are means ± SD of three separate experiments.

The production of free radicals has obvious implications forcontrol of the redox state of the cell. Free radicals oftenare quenched by reductants, including GSH. Cd has been demonstratedto cause increased levels of free radicals in cells in partby impairment of normal electron transfer processes (Hussainet al., 1987

; Brennan and Schiestl, 1996

; Chaoui et al., 1997

;Ouariti et al., 1997

; Stohs et al., 2000

; Sandalio et al., 2001

;Schützendübel et al., 2001

). To quantify the relativeCd-dependent free radical damage in P5CS-1 transgenic cellsand wild-type cells, we compared the extent of free radical–mediateddamage of cells grown in the presence and absence of Cd. Asshown in Figure 5A, the levels of malondialdehyde (MDA), a productof lipid peroxidation (Heath and Packer, 1968

), were 70% higherin wild-type algae than in P5CS-1 algae when grown in the presenceof Cd (50 µM Cd). Significantly, transgenic algae expressingthe P5CS gene exhibited no increase in MDA levels when grownin the presence of 50 µM Cd, unlike wild-type cells. Importantly,the relative reduction (70%) in MDA levels in Cd-treated P5CS-1cells compared with wild-type cells was inversely proportionalto the increase in free Pro content of the P5CS-1 cells (80%).These results strongly suggest that Pro acts directly as anantioxidant to protect the cell from free radical damage andmaintain a more reducing environment that is favorable for phytochelatinsynthesis and Cd sequestration.

DISCUSSION

TOP
Abstract
INTRODUCTION
RESULTS
DISCUSSION
METHODS
References

It was shown previously that exposure of Chlamydomonas to toxiclevels of Cd induces phytochelatin synthesis (Howe and Merchant,1992; Kaplan et al., 1995; Hu et al., 2001; Rubinelli et al.,2002). The induction of phytochelatin synthesis by Cd resultsin a severalfold increase in cellular Cd levels (Howe and Merchant,1992; Kaplan et al., 1995; Cai et al., 1999; Hu et al., 2001).In addition to its effects on phytochelatin synthesis, Cd hasbeen shown to alter patterns of gene expression, most notablythat of genes whose products are involved in chlorophyll synthesisand Fe uptake. We have observed that the steady state transcriptlevels of the chlL gene, which encodes the regulatory Fe-S subunitof the light-independent protochlorophyllide synthase, and theCRD1 gene, which encodes an enzyme involved in chlorophyll synthesis(Rubinelli et al., 2002), are increased after short-term exposureto Cd. In addition, the expression of the H43 gene, which encodesa periplasmic Fe chaperonin, is upregulated substantially (x40)by Cd exposure (25 µM for 2 h) (Rubinelli et al., 2002).Presumably, the function of increased H43 expression is to facilitateFe²⁺ uptake to competitively reduce Cd uptake through a commonmetal ion transporter (Cohen et al., 1998; Guerinot, 2000).

Here, we show that exposure of Chlamydomonas to minimally toxiclevels (50 to 100 µM) of Cd results in reduced growthrates and chlorophyll content per cell (70% less chlorophyllper cell) and increased lipid peroxidation and GSH oxidation.Although many plants and algae respond to heavy metal stresswith increased steady state levels of Pro, it is apparent thatChlamydomonas does not accumulate more Pro in response to Cdexposure. We found that transgenic strains expressing the mothbeanP5CS were only slightly more tolerant to toxic levels of Cd(50 µM) than wild-type strains (Figure 5D), but P5CS-1transgenic algae had fourfold higher Cd levels per cell thanwild-type strains (Table 1). This increased Cd content per cellseems counterintuitive given the enhanced Cd tolerance of P5CS-expressingstrains. The chemical form in which this excess Cd is sequesteredin P5CS-expressing strains differs from the Cd conjugates observedin wild-type strains. In P5CS-expressing strains, most Cd isbound by sulfur ligands that have physical properties consistentwith coordination by phytochelatin (Pickering et al., 1999).In wild-type Chlamydomonas, we observed that a substantial portionof the Cd ligands are provided by oxygen. These results areconsistent with earlier Fourier transform infrared and titrationstudies for wild-type strains, which indicated that carboxylategroups accounted for nearly half of all Cd binding sites (Adhiyaet al., 2002).

Notably, Chlamydomonas does not appear to make class I or IImetallothioneins (Cai et al., 1999). Therefore, there are twopossible mechanisms to account for the increased Cd-thiolateor Cd-phytochelatin complexes present in P5CS transgenic algae.These mechanisms include enhanced phytochelatin synthesis orreduced degradation and/or export of phytochelatins (Cd) fromthe cell (Lee et al., 1996). We favor the first hypothesis,because it is evident that there were substantially increasedGSH levels (80% higher), relative to GSSG levels, in P5CS-expressingstrains (Figures 5B and 5C). As indicated previously, Cd-GSHadduct and not GSSG is the substrate for phytochelatin synthesis(Vatamaniuk et al., 2000). Thus, increased GSH-Cd levels wouldlead to enhanced phytochelatin-Cd synthesis and accumulation.Although phytochelatin-Cd export has been demonstrated in microalgae,we cannot account for any mechanism by which Pro could alteror reduce the rate of phytochelatin (Cd) export from algal cells.In fact, we observed increased Cd export from P5CS-expressingcells relative to wild-type cells, consistent with greater flux(export) of Cd from P5CS transgenic cells as phytochelatin-Cdadducts (our unpublished observation).

To account for the increased GSH levels in P5CS transgenic cells,we turn to indirect evidence that indicates the mothbean P5CS-expressingcells have lower levels of products derived from free radicaldamage than wild-type cells (when grown in the presence of Cd).Analyses of the levels of MDA, a product of lipid peroxidation,in wild-type and P5CS-1 strains grown in the presence of Cdindicate that there is no increase in free radical–dependentperoxidation of lipids in high-Pro strains (Figure 5A). By contrast,exposure of wild-type strains to Cd resulted in nearly a twofoldincrease in MDA levels and a fourfold reduction in the GSH/0.5GSSG ratio (relative to P5CS cells in the presence of Cd) (Figure 5D).The increase in GSSG content relative to GSH content presumablyis attributable to oxidation by free radicals (Figures 5B and 5C)(Misra, 1974; Albro et al., 1986). Similar increases inCd-dependent free radical damage have been observed in otherbiological systems, including plants and chloroplasts (Aliaet al., 1997). Significantly, the increase in GSH/0.5 GSSG ratios(fourfold) in P5CS cells relative to wild-type cells was identicalto the relative increase in bound Cd per cell (fourfold).

The mechanisms by which Pro reduces free radical damage includephysical quenching of oxygen singlets and chemical reactionwith hydroxyl radicals (Rustgi et al., 1977; Floyd and Nagy,1984; Smirnoff and Cumbes, 1989; Lissi et al., 1993; Alia etal., 2001). Floyd and Nagy (1984) demonstrated that Pro readilyforms stable nitroxyl radicals (in vitro) in the presence ofhydroxyl radicals (·OH), whereas Rustgi et al. (1977)have shown that C5 of Pro can react with hydroxyl radicals.In addition, Pro has been shown to react directly with singletoxygen (¹O₂), forming reversible charge-transfer complexes,which effectively quench free radicals. The propensity to formcharge-transfer complexes via singlet oxygen is dependent inpart on the ionization potential of the amine (Alia et al.,2001). Significantly, Pro has a low ionization potential andthus can readily form reversible charge-transfer complexes with¹O₂, effectively quenching this reactive oxygen species (Aliaet al., 2001). Pro also has been shown to quench free radicalsin vivo. Alia et al. (1997) demonstrated that Pro can reducefree radical–mediated damage in isolated chloroplastsexposed to high light intensities.

A model summarizing the role of free Pro in reducing free radicaldamage and enhancing Cd tolerance is presented in Figure 6 .We propose that Pro reduces heavy metal stress by detoxificationof free radicals produced as a result of Cd poisoning (Figure 6A).Pro may physically quench oxygen singlets or react directlywith hydroxyl radicals. These reactions result in reduced freeradical damage (lower MDA levels) and a more reducing cellularenvironment (higher GSH levels). The high GSH levels in turnfacilitate phytochelatin synthesis and sequestration of heavymetal phytochelatin conjugates in the vacuole. This enhancedsequestration of Cd-phytochelatin complexes in the vacuole accountsfor the transiently increased Cd content of P5CS-expressingcells (Figure 6B).

View larger version (25K):
[in this window]
[in a new window]

Figure 6. Role of Free Pro in Free Radical Quenching.

Phytochelatin synthesis requires the synthesis of GSH by ${gamma}$ -GluCys synthetase and GSH synthetase, followed by binding of Cd and synthesis of Cd-phytochelatin by phytochelatin synthase. ER, endoplasmic reticulum; LMW, low molecular mass.

(A) In wild-type algae, Cd²⁺ induces the production of reactive oxygen species that rapidly oxidize GSH to GSSG. The resulting decreased GSH levels reduce phytochelatin synthesis.

(B) In transgenic algae, reactive oxygen species are reduced in quantity by reacting with free Pro. The resulting increased GSH levels facilitate increased phytochelatin production to sequester Cd.

	METHODS

TOP Abstract INTRODUCTION RESULTS DISCUSSION METHODS References

Strains and Media
The rec A^- Escherichia coli strain XLI-Blue (Stratagene) wasused in all recombinant DNA work. The Chlamydomonas reinhardtiistrain used was the cell wall–deficient, Arg-requiringmutant CC-425 (arg7-8 cw15 mt+ sr-u-2-60), which was obtainedfrom the Chlamydomonas Culture Collection at Duke University(Durham, NC). Chlamydomonas was grown in Tris-acetate-phosphate(TAP) medium supplemented with 50 µg Arg/mL for liquidmedium or 100 µg Arg/mL for solid medium, when required,at 22 to 27°C. Illumination was continuous at 10 µmol·m^-2·s^-1from fluorescent tubes.

Transformation of Chlamydomonas
A KpnI-ApaI fragment ( $~$ 2.45 kb) carrying the ${Delta}$ ¹-pyrroline-5-carboxylatesynthetase (P5CS) gene (Hu et al., 1992) was subcloned intoplasmid pSSCR7 and designated pCRP5CS. The plasmids pCRP5CSand p389 (encoding the arg7-8 gene used for complementationof the Arg auxotrophic mutation in CC-425) were cotransformedinto the nucleus of the cell-wall-less Chlamydomonas strainCC-425 by electroporation (Shimogawara et al., 1998). Five microgramsof total plasmid DNA containing a 1:3 (mol/mol) ratio of p389(arg7-8) and pCRP5CS was used for cotransformation. To increasethe efficiency of insertion of the transforming DNA, the plasmidswere linearized. Transformed colonies appeared 7 to 8 days afterDNA transformation.

Cell Growth and Chlorophyll Content
Cell growth was determined by measuring the optical densityat 750 nm (Sager and Granick, 1953). Chlorophyll determinationswere performed according to Arnon (1949).

Protein Gel Blot Analysis
Cells from late-log-phase cultures of transgenic or wild-typelines were harvested, frozen in liquid nitrogen, and groundwith a mortar and pestle in 50 mM Na-Tricine buffer, pH 8.0,containing 2 mM EDTA, 0.1 mM phenylmethylsulfonyl fluoride,20 µM leupeptin, and 2 mM L-1-chloro-3-(4-tosylannido)-4-phenyl-2-butanone.After centrifugation at 100,000g for 60 min, total soluble proteinswere resolved on SDS-PAGE, transferred to polyvinylidene fluoridemembranes, and immunoblotted using antibody against the purifiedmothbean (Vigna aconitifolia) P5CS protein (Cai et al., 1999).

Pro Determination
Free Pro was determined according to the method of Bates etal. (1973) One liter of cells from late-log-phase cultures oftransgenic or wild-type cells was suspended in 10 mL of 3% salicylicacid, broken by French press at 5000 pounds, and centrifugedat 4000g for 10 min to remove cell debris. To 2 mL of the supernatant,2 mL of acid ninhydrin was added, followed by the addition of2 mL of glacial acetic acid and boiling for 60 min. The mixturewas extracted with toluene, and the free Pro was quantifiedspectrophotometrically at 520 nm from the organic phase.

Cell Growth in Response to Salt Stress
A 1% (v/v) inoculum ( $~$ 1 to 4 x 10⁴ cells/mL) for wild-type orP5CS-1 cells was used to inoculate 100 mL of artificial seawatermedium. After 1, 3, 5, 12, and 24 h of incubation in artificialseawater medium, the viable cell number of each culture wasdetermined by spreading cells on TAP plates containing Arg andcounting the colonies.

Cd-K Edge Extended X-Ray Absorption Fine Structure Spectroscopy
Sample Preparation
Both wild-type and P5CS transgenic algae were grown in 4 L ofTAP medium containing 50 µM Cd for 5 days. Cells werecollected by centrifugation at 800g for 10 min. Cells were washedtwice with deionized water and packed into sample holders forthe Cd-K edge extended x-ray absorption fine structure (EXAFS)spectroscopic measurements.

Data Collection and Analysis
Cd-K EXAFS spectra were collected at room temperature on beamline 4-3 of the Stanford Synchrotron Radiation Laboratory, whichis equipped with Ar-filled ionization chambers. Fluorescencespectra were collected with a 13-element Ge solid-state detector.Counting times were adjusted to provide at least 10⁶ countsper energy step above the Cd-K edge. A total of six scans werecollected for the nonbiological samples: 1 mM Cd(NO₃)₂, 5 mMeach GSH and Cd(NO₃)₂, and 2.5 mM Pro, 2.5 mM GSH, and 5 mMCd(NO₃)₂. For the wild-type and transgenic algae, a total of45 and 24 scans were collected, respectively. Data analysiswas performed using the EXAFSPAK programs (George and Pickering,1995) according to standard methods. EXAFS spectra were extractedfrom the raw absorption data with a two-range spline concomitantwith normalizing the amplitude to the edge jump. The EXAFS oscillations[ ${chi}$ (k)] were analyzed by a curve-fitting procedure to the equation

where F_j(k) is the back-scatteringamplitude from each N_j neighboring atom of the jth type witha Debye-Waller factor of ${sigma}$ _j (to account for thermal vibrationand static disorder); r_j is the distance away from the centralatom; and ${phi}$ _ij(k) is the total phase shift experienced by thephotoelectron. The term exp(-2r_j/ ${lambda}$ _j) is caused by inelastic lossesin the scattering process with ${lambda}$ _j. ${lambda}$ _j is the electron mean freepath. S_i(k) is the amplitude reduction factor attributable toa many-body effect, such as shake up/off at the central atomdenoted by i. EXAFS phase, amplitude, and mean free path functionsfor the Cd-O or Cd-S shell were calculated for CdCO₃ (otavite)or Cd-S (hawleyite) using the program FEFF 8 (Traill and Boyle,1955; Graf, 1961; Konningsberger and Prins, 1988; Ankudinovet al., 1998).

Malondialdehyde Determination
Malondialdehyde (MDA) was determined in both transgenic andwild-type cells grown with or without Cd (50 µM) accordingto the method of Hodges et al. (1999). Cells were collectedfrom a 1-L culture by centrifugation at 800g for 5 min and extractedwith 25 mL of 80:20 (v/v) ethanol:water. One milliliter of thealgal extract was added to a test tube with 1 mL of either 20%(w/v) trichloroacetic acid and 0.01% butyrated hydroxytoluene(-TBA solution) or 20% (w/v) trichloroacetic acid, 0.01% butyratedhydroxytoluene, and 0.65% thiobarbituric acid (+TBA solution).The solutions then were mixed vigorously, heated at 95°Cfor 25 min, cooled, and centrifuged at 3000g for 10 min, andthe absorbance was measured at 440, 532, and 600 nm. The absorbanceof the -TBA solution was used to correct the MDA concentrationfrom the interfering compounds, which can absorb at 532 nm.MDA equivalents were calculated as described by Hodges et al.(1999).

GSH and GSSG Determination
GSH and GSSG were determined in the cell extracts via the GSHreductase–dependent enzymatic cycle (Anderson, 1985).Cells from a 1-L culture were collected by centrifugation at800g for 5 min and frozen in liquid nitrogen. Five volumes pergram fresh weight of 5% 5-sulfosalicylic acid was added, andthe freeze-thaw process was repeated three times to disruptthe cells. After centrifugation at 20,000g for 10 min to removedebris, nonprotein thiol levels were determined spectrophotometricallyusing Ellman's reagent with GSH as a standard. GSSG levels weredetermined after derivatization with 2 µM 2-vinylpyridinefor 60 min. GSH levels were obtained by subtracting the GSSGlevels from the total GSH level in the sample.

Upon request, all novel materials described in this articlewill be made available in a timely manner for noncommercialresearch purposes. No restrictions or conditions will be placedon the use of any materials described in this article that wouldlimit their use for noncommercial research purposes.

Acknowledgments

This research was supported by a grant from the National Oceanographicand Atmospheric Administration to R.T.S. and S.T. and by a grantto D.P.S.V.

Footnotes

Article, publication date, and citation information can be foundat www.plantcell.org/cgi/doi/10.1105/tpc.004853.

Received May 30, 2002; accepted September 3, 2002.

References

TOP
Abstract
INTRODUCTION
RESULTS
DISCUSSION
METHODS
References

Adhiya, J., Cai, X.-H., Sayre, R.T. , and Traina, S. (2002). Binding of aqueous cadmium by the lyophilized biomass of Chlamydomonas reinhardtii. Colloids Surf. A Physiochem. Eng. Aspects 210, 1–11.[CrossRef]

Albro, P.W., Corbett, J.T., and Schroeder, J.L. (1986). Generation of hydrogen-peroxide by incidental metal ion-catalyzed autooxidation of glutathione. J. Inorg. Biochem. 27, 191–203.[CrossRef][Medline]

Alia, Mohanty, P., and Matysik, J. (2001). Effect of proline on the production of singlet oxygen. Amino Acids 21, 195–200.[CrossRef][Web of Science][Medline]

Alia, Saradhi, P.P., and Mohanty, P. (1997). Involvement of proline in protecting thylakoid membranes against free radical-induced photodamage. J. Photochem. Photobiol. B 38, 253–257.[CrossRef]

Alloway, B.J. (1995). Cadmium Heavy Metals in Soils, 2nd ed, B.J. Alloway, ed (London: Chapman and Hall), pp. 122–151.

Anderson, M.E. (1985). Tissue glutathione. In Handbook of Methods for Oxygen Radical Research, R.A. Greenwald, ed (Boca Raton, FL: CRC Press), pp. 317–323.

Ankudinov, A.L., Ravel, B., Rehr, J.J., and Conradson, S.D. (1998). Real-space multiple-scattering calculation and interpretation of x-ray-absorption near-edge structure. Physiol. Rev. B 58, 7565–7576.[CrossRef]

Arnon, D.I. (1949). Copper enzymes in isolated chloroplast: Polyphenoloxidase in Beta vulgaris. Plant Physiol. 24, 1–15.[Free Full Text]

Bates, L.S., Waldren, R.P., and Teare, I.D. (1973). Rapid determination of free proline for water-stress studies. Plant Soil 39, 205–207.[CrossRef]

Brennan, R.J., and Schiestl, R.H. (1996). Cadmium is an inducer of oxidative stress in yeast. Mutat. Res. 356, 171–178.[CrossRef][Web of Science][Medline]

Buchet, J.P., Roels, H., Bernard, A., and Lauwerys, R. (1980). Assessment of renal-function of workers exposed to inorganic lead, cadmium, or mercury-vapor. J. Occup. Environ. Med. 22, 741–750.[Web of Science][Medline]

Cai, X.-H., Brown, C., Adhiya, J., Traina, S.J., and Sayre, R.T. (1999). Growth and heavy metal binding properties of transgenic Chlamydomonas expressing a foreign metallothionein gene. Int. J. Phytoremediation 1, 53–65.

Chaoui, A., Mazhoudi, S., Ghorbal, M.H., and Ferjani, E.E. (1997). Cadmium and zinc induction of lipid peroxidation and effects on antioxidant enzyme activities in bean (Phaseolus vulgaris L.). Plant Sci. 127, 139–147.[CrossRef]

Cohen, C.K., Fox, T.C., Garvin, D.F., and Kochian, L.V. (1998). The role of iron-deficiency stress responses in stimulating heavy metal transport in plants. Plant Physiol. 116, 1063–1072.[Abstract/Free Full Text]

Delauney, A.J., and Verma, D.P.S. (1993). Proline biosynthesis and osmoregulation in plants. Plant J. 4, 215–223.

Desi, I., Nagymajtenyi, L., and Schulz, H. (1998). Behavioural and neurotoxicological changes caused by cadmium treatment of rats during development. J. Appl. Toxicol. 18, 63–70.[Medline]

di Toppi, L.S., and Gabbrielli, R. (1999). Response to cadmium in higher plants. Environ. Exp. Bot. 41, 105–130.[CrossRef][Web of Science]

Dudka, S., and Adriano, D.C. (1997). Environmental impacts of metal ore mining and processing: A review. J. Environ. Qual. 26, 590–602.[Abstract/Free Full Text]

Farago, M.E., and Mullen, W.A. (1979). Plants which accumulate metals. Part IV. A possible copper-proline complex from the roots of Armeria maritima. Inorg. Chim. Acta 32, L93–L94.[CrossRef]

Floyd, R.A., and Nagy, I. (1984). Formation of long-lived hydroxyl free-radical adducts of proline and hydroxyproline in a Fenton reaction. Biochim. Biophys. Acta. 790, 94–97.[CrossRef][Medline]

George, G.N., and Pickering, I.F. (1995). EXAFSPAK. (Stanford, CA: Stanford Synchrotron Radiation Laboratory), http://www-ssrl.slac.stanford.edu/exafspak.html.

Graf, D.L. (1961). Crystallographic tables for the rhombohedral carbonates. Am. Mineral. 46, 1283–1316.

Guerinot, M.L. (2000). The ZIP family of metal transporters. Biochim. Biophys. Acta 1465, 190–198.[Medline]

Hare, P.D., and Cress, W.A. (1997). Metabolism implications of stress-induced proline accumulation in plants. Plant Growth Regul. 21, 79–102.[CrossRef]

Heath, R.L., and Packer, L. (1968). Photoperoxidation in isolated chloroplasts. I. Kinetics and stoichiometry of fatty acid peroxidation. Arch. Biochem. Biophys. 125, 189–198.[CrossRef][Web of Science][Medline]

Hellstrom, L., Elinder, C.G., Dahlberg, B., Lundberg, M., Jarup, L., Persson, B., and Axelson, O. (2001). Cadmium exposure and end-stage renal disease. Am. J. Kidney Dis. 38, 1001–1008.[Web of Science][Medline]

Hodges, D.M., DeLong, J.M., Forney, C.F., and Prange, R.K. (1999). Improving the thiobarbituric acid-reactive-substances assay for estimating lipid peroxidation in plant tissues containing anthocyanin and other interfering compounds. Planta 207, 604–611.[CrossRef][Web of Science]

Howe, G., and Merchant, S. (1992). Heavy metal-activated synthesis of peptides in Chlamydomonas reinhardtii. Plant Physiol. 98, 127–136.[Abstract/Free Full Text]

Hu, C.-C.A., Delauney, A.J., and Verma, D.P.S. (1992). A bifunctional enzyme ( ${Delta}$ ¹-pyrroline-5-carboxylate synthetase) catalyzes the first two steps in proline biosynthesis in plants. Proc. Natl. Acad. Sci. USA 89, 9354–9358.[Abstract/Free Full Text]

Hu, S., Lau, K.W.K., and Wu, M. (2001). Cadmium sequestration in Chlamydomonas reinhardtii. Plant Sci. 161, 987–996.[CrossRef]

Hussain, T., Shukla, G.S., and Chandra, S.V. (1987). Effects of cadmium on superoxide dismutase and lipid peroxidation in liver and kidney of growing rats: In vivo and in vitro studies. Pharmacol. Toxicol. 60, 355–358.[Web of Science][Medline]

Kahle, H. (1993). Response of roots of trees to heavy metals. Environ. Exp. Bot. 33, 99–119.[CrossRef]

Kaplan, D., Heimer, Y.M., Abeliovich, A., and Goldsbrough, P.B. (1995). Cadmium toxicity and resistance in Chlorella sp. Plant Sci. 109, 129–137.[CrossRef]

Konningsberger, D.C., and Prins, R. (1988). X-Ray Absorption: Principles, Applications, Techniques of EXAFS, SEXAFS and XANES, D.C. Konningsberger and R. Prins, eds (New York: John Wiley & Sons).

Kuznetsov, V.V., and Shevyakova, N.I. (1997). Stress responses of tobacco cells to high temperature and salinity: Proline accumulation and phosphorylation of polypeptides. Physiol. Plant. 100, 320–326.[CrossRef]

Lee, J.G., Ahner, B.A., and Morel, F.M.M. (1996). Export of cadmium and phytochelatin by the marine diatom Thalassiosira weissflogii. Environ. Sci. Technol. 30, 1814–1821.[CrossRef]

Lissi, E.A., Encinas, M.V., Lemp, E., and Rubio, M.A. (1993). Singlet O₂ bimolecular processes: Solvent and compartmentalization effects. Chem. Rev. 93, 699–723.

Mehta, S.K., and Gaur, J.P. (1999). Heavy-metal-induced proline accumulation and its role in ameliorating metal toxicity in Chlorella vulgaris. New Phytol. 143, 253–259.[CrossRef]

Misra, H.P. (1974). Generation of superoxide free radical during the autooxidation of thiols. J. Biol. Chem. 249, 2151–2155.[Abstract/Free Full Text]

Nies, D.H. (1999). Microbial heavy-metal resistance. Appl. Microbiol. Biotechnol. 51, 730–750.[CrossRef][Web of Science][Medline]

Nogawa, K., and Kido, T. (1993). Biological monitoring of cadmium exposure in itai-itai disease epidemiology. Int. Arch. Occup. Environ. Health 65, S43–S46.[Medline]

Nriagu, J.O., and Pacyna, J.M. (1988). Quantitative assessment of worldwide contamination of air, water and soils by trace-metals. Nature 333, 134–139.

Ouariti, O., Boussama, N., Zarrouk, M., Cherif, A., and Ghorbal, M.H. (1997). Cadmium- and copper-induced changes in tomato membrane lipids. Phytochemistry 45, 1343–1350.[CrossRef][Web of Science][Medline]

Paleg, L.G., Stewart, G.R., and Bradbeer, J.W. (1984). Proline and glycine betaine influence protein solvation. Plant Physiol. 75, 974–978.[Abstract/Free Full Text]

Pickering, I.J., Prince, R.C., George, G.N., Rauser, W.E., Wickramasinghe, W.A., Watson, A.A., Dameron, C.T., Dance, I.G., Fairlie, D.P., and Salt, D.E. (1999). X-ray absorption spectroscopy of cadmium phytochelatin and model systems. Biochim. Biophys. Acta 1429, 351–364.[CrossRef][Medline]

Rubinelli, P., Siripornadulsil, S., Gao-Rubinelli, F., and Sayre, R.T. (2002). Cadmium- and iron-stress-inducible gene expression in the green alga Chlamydomonas reinhardtii: Evidence for H43 protein function in iron assimilation. Planta 215, 1–13.[CrossRef][Web of Science][Medline]

Rustgi, S., Joshi, A., Moss, H., and Riesz, P. (1977). ESR of spin-trapped radicals in aqueous solutions of amino acids: Reactions of the hydroxyl radical. Int. J. Radiat. Biol. Relat. Stud. Phys. Chem. Med. 31, 415–440.[Medline]

Sager, R., and Granick, S. (1953). Nutritional studies with Chlamydomonas reinhardtii. Ann. N.Y. Acad. Sci. 56, 831–838.

Salt, D.E., Prince, R.C., Pickering, I.J., and Raskin, I. (1995). Mechanisms of cadmium mobility and accumulation in Indian Mustard. Plant Physiol. 109, 1427–1433.[Abstract]

Sandalio, L.M., Dalurzo, H.C., Gómez, M., Romero-Puertas, M.C., and del Río, L.A. (2001). Cadmium-induced changes in the growth and oxidative metabolism of pea plants. J. Exp. Bot. 52, 2115–2126.[Abstract/Free Full Text]

Schat, H., Sharma, S.S., and Vooijs, R. (1997). Heavy metal-induced accumulation of free proline in a metal-tolerant and a nontolerant ecotype of Silene vulgaris. Physiol. Plant. 101, 477–482.[CrossRef]

Schützendübel, A., Schwanz, P., Teichmann, T., Gross, K., Langenfeld-Heyser, R., Godbold, D.L., and Polle, A. (2001). Cadmium-induced changes in antioxidative systems, hydrogen peroxide content, and differentiation in Scots pine roots. Plant Physiol. 127, 887–898.[Abstract/Free Full Text]

Shah, K., and Dubey, R.S. (1998). Effect of cadmium on proline accumulation and ribonuclease activity in rice seedlings: Role of proline as a possible enzyme protectant. Biol. Plant. 40, 121–130.

Shimogawara, K., Fujiwara, S., Grossman, A., and Usada, H. (1998). High-efficiency transformation of Chlamydomonas reinhardtii by electroporation. Genetics 148, 1821–1828.[Abstract/Free Full Text]

Smirnoff, N., and Cumbes, Q.J. (1989). Hydroxyl radical scavenging activity of compatible solutes. Phytochemistry 28, 1057–1060.[CrossRef][Web of Science]

Stohs, S.J., Bagchi, D., Hassoun, E., and Bagchi, M. (2000). Oxidative mechanisms in the toxicity of chromium and cadmium ions. J. Environ. Pathol. Toxicol. Oncol. 19, 201–213.[Medline]

Taylor, C.B. (1996). Proline and water deficit: Ups, downs, ins and outs. Plant Cell 8, 1221–1224.[CrossRef][Web of Science]

Traill, R.J., and Boyle, R.W. (1955). Hawleyite, isometric cadmium sulphide, a new mineral. Am. Mineral. 40, 555–559.

Tsuritani, I., Honda, R., Ishizaki, M., Yamada, Y., and Nishijo, M. (1996). Ultrasonic assessment of calcaneus in inhabitants in a cadmium-polluted area. J. Toxicol. Environ. Health 48, 131–140.[Medline]

Vatamaniuk, O.K., Mari, S., Lu, Y.P., and Rea, P.A. (2000). Mechanism of heavy metal ion activation of phytochelatin (PC) synthase: Blocked thiols are sufficient for PC synthase-catalyzed transpeptidation of glutathione and related thiol peptides. J. Biol. Chem. 275, 31451–31459.[Abstract/Free Full Text]

Verma, D.P.S. (1999). Osmotic stress tolerance in plants: Role of proline and sulfur metabolisms. In Molecular Responses to Cold, Drought, Heat and Salt Stress in Higher Plants, K. Shinozaki and K. Yamaguchi-Shinozaki, eds (Austin, TX: R.G. Landers), pp. 153–168.

Wu, J.-T., Chang, S.J., and Chou, T.L. (1995). Intracellular proline accumulation in some algae exposed to copper and cadmium. Bot. Bull. Acad. Sin. 36, 89–93.

This article has been cited by other articles:

L. P. Zhang, S. K. Mehta, Z. P. Liu, and Z. M. Yang
Copper-Induced Proline Synthesis is Associated with Nitric Oxide Generation in Chlamydomonas reinhardtii
Plant Cell Physiol., March 1, 2008; 49(3): 411 - 419.
[Abstract] [Full Text] [PDF]

J. G. Perez-Perez, J. P. Syvertsen, P. Botia, and F. Garcia-Sanchez
Leaf Water Relations and Net Gas Exchange Responses of Salinized Carrizo Citrange Seedlings during Drought Stress and Recovery
Ann. Bot., August 1, 2007; 100(2): 335 - 345.
[Abstract] [Full Text] [PDF]

C. Collin-Hansen, S. A. Pedersen, R. A. Andersen, and E. Steinnes
First report of phytochelatins in a mushroom: induction of phytochelatins by metal exposure in Boletus edulis
Mycologia, March 1, 2007; 99(2): 161 - 174.
[Abstract] [Full Text] [PDF]

C. Chen, S. Wanduragala, D. F. Becker, and M. B. Dickman
Tomato QM-Like Protein Protects Saccharomyces cerevisiae Cells against Oxidative Stress by Regulating Intracellular Proline Levels.
Appl. Envir. Microbiol., June 1, 2006; 72(6): 4001 - 4006.
[Abstract] [Full Text] [PDF]

S. S. Sharma and K.-J. Dietz
The significance of amino acids and amino acid-derived molecules in plant responses and adaptation to heavy metal stress
J. Exp. Bot., March 1, 2006; 57(4): 711 - 726.
[Abstract] [Full Text] [PDF]

I. Yonamine, K. Yoshida, K. Kido, A. Nakagawa, H. Nakayama, and A. Shinmyo
Overexpression of NtHAL3 genes confers increased levels of proline biosynthesis and the enhancement of salt tolerance in cultured tobacco cells
J. Exp. Bot., February 1, 2004; 55(396): 387 - 395.
[Abstract] [Full Text] [PDF]

This Article

Abstract

Full Text (PDF)

All Versions of this Article:
14/11/2837 most recent
tpc.004853v1

Alert me when this article is cited

Alert me if a correction is posted

Services

Email this article to a friend

Similar articles in this journal

Similar articles in Web of Science

Similar articles in PubMed

Alert me to new issues of the journal

Download to citation manager

Citing Articles

Citing Articles via HighWire

Citing Articles via CrossRef

Citing Articles via Web of Science (63)

Citing Articles via Google Scholar

Google Scholar

Articles by Siripornadulsil, S.

Articles by Sayre, R. T.

Search for Related Content

PubMed

PubMed Citation

Articles by Siripornadulsil, S.

Articles by Sayre, R. T.

Agricola

Articles by Siripornadulsil, S.

Articles by Sayre, R. T.