Phytochelatin synthase genes from Arabidopsis and the yeast Schizosaccharomyces pombe.

Phytochelatins (PCs), a family of heavy metal-inducible peptides important in the detoxification of heavy metals, have been identified in plants and some microorganisms, including Schizosaccharomyces pombe, but not in animals. PCs are synthesized enzymatically from glutathione (GSH) by PC synthase in the presence of heavy metal ions. In Arabidopsis, the CAD1 gene, identified by using Cd-sensitive, PC-deficient cad1 mutants, has been proposed to encode PC synthase. Using a positional cloning strategy, we have isolated the CAD1 gene. Database searches identified a homologous gene in S. pombe, and a mutant with a targeted deletion of this gene was also Cd sensitive and PC deficient. Extracts of Escherichia coli cells expressing a CAD1 cDNA or the S. pombe gene catalyzing GSH-dependent, heavy metal-activated synthesis of PCs in vitro demonstrated that both genes encode PC synthase activity. Both enzymes were activated by a range of metal ions. In contrast, reverse transcription-polymerase chain reaction experiments showed that expression of the CAD1 mRNA is not influenced by the presence of Cd. A comparison of the two predicted amino acid sequences revealed a highly conserved N-terminal region, which is presumed to be the catalytic domain, and a variable C-terminal region containing multiple Cys residues, which is proposed to be involved in activation of the enzyme by metal ions. Interestingly, a similar gene was identified in the nematode, Caenorhabditis elegans, suggesting that PCs may also be expressed in some animal species.

Purification and immunological identification of metallothioneins 1 and 2 from Arabidopsis thaliana.

Gene families encoding two types of metallothioneins (MTs) MT1 and MT2, have been identified in Arabidopsis thaliana, and their respective mRNAs have been shown to be regulated by copper in a tissue-specific manner (J. Zhou and P.B. Goldsbrough [1994] Plant Cell 6: 875-884; J. Zhou and P.B. Goldsbrough [1995] Mol Gen Genet 248: 318-328; A.S. Murphy and L. Taiz [1995] Plant Physiol 109: 1-10). However, to date the protein products have not been identified. To purify MT proteins from Arabidopsis, we isolated low-molecular-mass, copper-binding, thiol-rich proteins using selective precipitation followed by size-exclusion, copper-affinity, and thiol-affinity chromatographies. Polyclonal antibodies raised against Arabidopsis MT-glutathione-S-transferase fusion proteins cross-reacted with the 4.5- and 8-kD bands in immunoblots of low-molecular-mass, copper-binding proteins purified from seedling, mature leaf, and mature root tissues. The identity of the proteins was subsequently confirmed by amino acid sequencing. MT1 expression was constitutive in roots and inducible by copper in mature leaves; the reverse pattern was observed for MT2. MT2 expression was also concentrated in the growing tip of the root. The accumulation of the MT1- and MT2-encoded proteins thus parallels the regulation of their respective mRNAs with regard to tissue specificity and induction by copper. In addition, a new type of MT, designated MT3, was derived from the database, detected by reverse transcription-polymerase chain reaction, and tentatively identified at the protein level by amino acid sequencing of a 7-kD cysteine-rich polypeptide.

Isolation of a cDNA encoding a novel leucine-rich repeat motif from Sorghum bicolor inoculated with fungi.

A sorghum cDNA clone has been isolated that encodes a protein containing six imperfect leucine-rich repeats (LRRs) of approximately 22 amino acids in length. The putative protein, designated SLRR, also contains a signal peptide, and six potential N-glycosylation sites. Comparisons of SLRR and its LRR consensus sequences found significant homology to the extracellular binding domains of receptor-protein kinases RLK5 and TMK1 of Arabidopsis, and some plant disease resistance genes. Results from RNA gel blot analyses showed that SLRR mRNA accumulates rapidly in mesocotyls and juvenile leaves by 6 h postinoculation with the fungus Colletotricum graminicola. Further experiments suggest that the gene encoding SLRR is neither systemically induced by fungal inoculation, nor transcriptionally activated in a host-fungal-pathogen-specific manner. The presence of LRRs strongly suggests that the SLRR protein is involved in protein-ligand binding and therefore may be a component of a signal transduction pathway.

Betaine aldehyde dehydrogenase in sorghum.

The ability to synthesize and accumulate glycine betaine is wide-spread among angiosperms and is thought to contribute to salt and drought tolerance. In plants glycine betaine is synthesized by the two-step oxidation of choline via the intermediate betaine aldehyde, catalyzed by choline monooxygenase and betaine aldehyde dehydrogenase (BADH). Two sorghum (Sorghum bicolor) cDNA clones, BADH1 and BADH15, putatively encoding betaine aldehyde dehydrogenase were isolated and characterized. BADH1 is a truncated cDNA of 1391 bp. BADH15 is a full-length cDNA clone, 1812 bp in length, predicted to encode a protein of 53.6 kD. The predicted amino acid sequences of BADH1 and BADH15 share significant homology with other plant BADHs. The effects of water deficit on BADH mRNA expression, leaf water relations, and glycine betaine accumulation were investigated in leaves of preflowering sorghum plants. BADH1 and BADH15 mRNA were both induced by water deficit and their expression coincided with the observed glycine betaine accumulation. During the course of 17 d, the leaf water potential in stressed sorghum plants reached -2.3 MPa. In response to water deficit, glycine betaine levels increased 26-fold and proline levels increased 108-fold. In severely stressed plants, proline accounted for > 60% of the total free amino acid pool. Accumulation of these compatible solutes significantly contributed to osmotic potential and allowed a maximal osmotic adjustment of 0.405 MPa.

Stability and expression of amplified EPSPS genes in glyphosate resistant tobacco cells and plantlets.

The stability and expression of amplified 5-enolpyruvylshikimate-3-phosphate synthase (EPSPS) genes was examined in glyphosate resistant tobacco cells grown in glyphosate-free medium, and in plantlets regenerated from resistant cells. Amplified DNA was maintained in resistant cells grown in the absence of glyphosate for three years. Amplified EPSPS genes were retained in regenerated plantlets at levels comparable to those observed in the resistant cells, and EPSPS mRNA was overexpressed (compared to unselected plantlets). However, glyphosate resistance in cell lines grown in glyphosate-free medium declined 7-fold, and in regenerated plantlets approximately 20-fold, compared to resistant cells maintained under glyphosate selection. In plantlets, reduced resistance correlated with lower levels of EPSPS mRNA. Plantlets regenerated from resistant cells exhibited morphological variation, and had an approximate doubling of their nuclear genome size.

Structure, organization and expression of the metallothionein gene family in Arabidopsis.

Metallothioneins (MTs) are cysteine-rich proteins required for heavy metal tolerance in animals and fungi. Recent results indicate that plants also possess functional metallothionein genes. Here we report the cloning and characterization of five metallothionein genes from Arabidopsis thaliana. The position of the single intron in each gene is conserved. The proteins encoded by these genes can be divided into two groups (MT1 and MT2) based on the presence or absence of a central domain separating two cysteine-rich domains. Four of the MT genes (MT1a, MT1c, MT2a and MT2b) are transcribed in Arabidopsis. Several lines of evidence suggest that the fifth gene, MT1b, is inactive. There is differential regulation of the MT gene family. MT1 mRNA is expressed highly in roots, moderately in leaves and is barely detected in inflorescences and siliques. MT2a and MT2b mRNAs are more abundant in leaves, inflorescences and in roots from mature plants, but are also detected in roots of young plants, and in siliques. MT2a mRNA is strongly induced in seedlings by CuSO4, whereas MT2b mRNA is relatively abundant in this tissue and levels increase only slightly upon exposure to copper. MT1a and MT1c are located within 2 kb of each other and have been mapped to chromosome I. MT1b and MT2b map to separate loci on chromosome V, and MT2a is located on chromosome III. The locations of these MT genes are different from that of CAD1, a gene involved in cadmium tolerance in Arabidopsis.

Cadmium-sensitive, cad1 mutants of Arabidopsis thaliana are phytochelatin deficient.

An allelic series of cad1, cadmium-sensitive mutants of Arabidopsis thaliana, was isolated. These mutants were sensitive to cadmium to different extents and were deficient in their ability to form cadmium-peptide complexes as detected by gel-filtration chromatography. Each mutant was deficient in its ability to accumulate phytochelatins (PCs) as detected by high-performance liquid chromatography and the amount of PCs accumulated by each mutant correlated with its degree of sensitivity to cadmium. The mutants had wild-type levels of glutathione, the substrate for PC biosynthesis, and in vitro assays demonstrated that each of the mutants was deficient in PC synthase activity. These results demonstrate conclusively the importance of PCs for cadmium tolerance in plants.

A cadmium-sensitive, glutathione-deficient mutant of Arabidopsis thaliana.

The roots of the cadmium-sensitive mutant of Arabidopsis thaliana, cad1-1, become brown in the presence of cadmium. A new cadmium-sensitive mutant affected at a second locus, cad2, has been identified using this phenotype. Genetic analysis has grown that the sensitive phenotype is recessive to the wild type and segregates as a single Mendelian locus. Assays of cadmium accumulation by intact plants indicated that the mutant is deficient in its ability to sequester cadmium. Undifferentiated callus tissue was also cadmium sensitive, suggesting that the mutant phenotype is expressed at the cellular level. The level of cadmium-binding complexes formed in vivo was decreased compared with the wild type and accumulation of phytochelatins was about 10% of that in the wild type. The level of glutathione, the substrate for phytochelatin biosynthesis, in tissues of the mutant was decreased to about 15 to 30% of that in the wild type. Thus, the deficiency in phytochelatin biosynthesis can be explained by a deficiency in glutathione.

Increased Activity of [gamma]-Glutamylcysteine Synthetase in Tomato Cells Selected for Cadmium Tolerance.

Two cell lines of tomato (Lycopersicon esculentum Mill cv VFNT-Cherry) were systematically compared for their capacity to tolerate cadmium. Unselected CdS cells died in the presence of 0.3 mM CdCl2. CdR6-0 cells, which were selected from CdS, survived and grew in medium supplemented with 0.3 mM CdCl2. Growth of CdR6-0 cells under this condition was accompanied by synthesis of cadmium-binding phytochelatins and maintenance of cellular glutathione (GSH) levels. CdR6-0 cells also exhibited increased tolerance to buthionine sulfoximine, in both the presence and absence of 0.1 mM CdCl2. The specific activity of [gamma]-glutamylcysteine synthetase (EC 6.3.2.2) was approximately 2-fold higher in CdR6-0 cells than in CdS cells, whereas there was no difference between cell lines in specific activity of GSH synthetase (EC 6.3.2.3). Increased activity of the first enzyme of GSH biosynthesis in CdR6-0 cells, presumably a result of selection for increased cadmium tolerance, provides an enhanced capacity to synthesize GSH and to maintain the production of phytochelatins in response to cadmium. This adaptation may contribute to the enhanced cadmium tolerance of CdR6-0 cells.

Functional homologs of fungal metallothionein genes from Arabidopsis.

Metallothioneins (MTs) are cysteine-rich proteins required for heavy metal tolerance in animals and fungi. Two cDNAs encoding proteins with homology to animal and fungal MTs have been isolated from Arabidopsis. The genes represented by these cDNAs are referred to as MT1 and MT2. When expressed in an MT-deficient (cup1 delta) mutant of yeast, both MT1 and MT2 complemented the cup1 delta mutation, providing a high level of resistance to CuSO4 and moderate resistance to CdSO4. Although the MT-deficient yeast was not viable in the presence of either 300 microM CuSO4 or 5 microM CdSO4, cells expressing MT1 were able to grow in medium supplemented with 3 mM CuSO4 and 10 microM CdSO4, and those expressing MT2 grew in the presence of 3 mM CuSO4 and 100 microM CdSO4. In plants, MT1 mRNA was more abundant in roots and dark-grown seedlings than in leaves. In contrast, MT2 mRNA accumulated more in leaves than in either roots or darkgrown seedlings. MT2 mRNA was strongly induced in seedlings by CuSO4, but only slightly by CdSO4 or ZnSO4. However, MT1 mRNA was induced by CuSO4 in excised leaves that were submerged in medium. These results indicated that Arabidopsis MT genes are involved in copper tolerance. Plants also synthesized metal binding phytochelatins (poly[gamma-glutamylcysteine]glycine) when exposed to heavy metals. The results presented here argue against the hypothesis that phytochelatins are the sole molecules involved in heavy metal tolerance in plants. We conclude that Arabidopsis MT1 and MT2 are functional homologs of yeast MT.

Selection for kanamycin resistance in transformed petunia cells leads to the co-amplification of a linked gene.

A cell suspension culture was established from a transgenic petunia (Petunia hybrida L.) plant which carried genes encoding neomycin phosphotransferase II (nptII) and beta-glucuronidase (uidA, GUS). Two selection experiments were performed to obtain cell lines with increased resistance to kanamycin. In the first, two independently selected cell lines grown in the presence of 350 micrograms/ml kanamycin were eight to ten-fold more resistant to kanamycin than unselected cells. Increased resistance was correlated with amplification of the nptII gene and an increase in nptII mRNA levels. Selection for kanamycin resistance also produced amplification of the linked GUS gene, resulting in increased GUS mRNA levels and enzyme activity. Selected cells grown in the absence of kanamycin for twelve growth cycles maintained increased copy numbers of both genes, and GUS enzyme activity was also stably overexpressed. In a second selection experiment, a cell line grown continuously in medium containing 100 micrograms/ml kanamycin exhibited higher nptII and GUS gene copy numbers and an increase in GUS enzyme activity after eleven growth cycles. In this cell line, amplification of the two genes was accompanied by DNA rearrangement.

A serine-to-threonine substitution in the triazine herbicide-binding protein in potato cells results in atrazine resistance without impairing productivity.

A mutation of the psbA gene was identified in photoautotrophic potato (Solanum tuberosum L. cv Superior x U.S. Department of Agriculture line 66-142) cells selected for resistance to 6-chloro-N-ethyl-N'-(1-methylethyl)-1,3,5-triazine-2,4-diamine (atrazine). Photoaffinity labeling with 6-azido-N-ethyl-N'-(1-methylethyl)-1,3,5-triazine-2,4-diamine detected a thylakoid membrane protein with a M(r) of 32,000 in susceptible, but not in resistant, cells. This protein was identified as the secondary quinone acceptor of photosystem II (QB) protein. Atrazine resistance in selected cells was attributable to a mutation from AGT (serine) to ACT (threonine) in codon 264 of the psbA gene that encodes the QB protein. Although the mutant cells exhibited extreme levels of resistance to atrazine, no concomitant reductions in photosynthetic electron transport or cell growth rates compared to the unselected cells were detected. This is in contrast with the losses in productivity observed in atrazine-resistant mutants that contain a glycine-264 alteration.

An Arabidopsis gene with homology to glutathione S-transferases is regulated by ethylene.

A cDNA clone obtained from Arabidopsis leaf RNA encodes a 24 kDa protein with homology to glutathione S-transferases (GST). It is most homologous with a tobacco GST (57% identity). In Arabidopsis, expression of GST mRNA is regulated by ethylene. Exposure of plants to ethylene increased the abundance of GST mRNA, while treatment with norbornadiene had the reverse effect. Ethylene had no effect on the mRNA level in ethylene-insensitive etr1 plants. The abundance of this mRNA increased with the age of plants. DNA hybridizations indicate that GSTs are encoded by a large multigene family in Arabidopsis.

Expression and stability of amplified genes encoding 5-enolpyruvylshikimate-3-phosphate synthase in glyphosate-tolerant tobacco cells.

Two distinct cDNAs for 5-enolpyruvylshikimate-3-phosphate synthase (EPSPS) were obtained from a glyphosate-tolerant tobacco cell line. The cDNAs were 89% identical and the predicted sequences of the mature proteins were greater than 83% identical with EPSPS proteins from other plants. Tobacco EPSPS proteins were more similar to those from tomato and petunia than Arabidopsis. One cDNA clone, EPSPS-1, represented a gene that was amplified in glyphosate-tolerant cells, while the gene for EPSPS-2 was unaltered in these cells. Consequently, EPSPS-1 mRNA was more abundant in tolerant than unselected cells, whereas EPSPS-2 mRNA was at relatively constant levels in these cell lines. Exposure of unselected cells and tobacco leaves to glyphosate produced a transient increase in EPSPS mRNA. However, glyphosate-tolerant cells containing amplified copies of EPSPS genes did not show a similar response following exposure to glyphosate. A significant proportion of the EPSPS gene amplification was maintained when tolerant cells were grown in the absence of glyphosate for eight months. Plants regenerated from these cells also contained amplified EPSPS genes.

Phytochelatin accumulation and cadmium tolerance in selected tomato cell lines.

Four cell lines of tomato, Lycopersicon esculentum Mill. cv VFNT-Cherry, were selected for their ability to grow in the presence of up to 6 millimolar CdCl(2). The intracellular Cd concentration in these cells was at least 2.3 times higher than in the medium. Growth in media containing higher concentrations of Cd was accompanied by increased production of Cd-binding phytochelatins and a trend toward accumulation of higher molecular weight phytochelatins. At least 90% of the Cd in the most tolerant cells was associated with Cd-phytochelatin complexes. Cell lines maintained an increased tolerance of Cd in the absence of continuous selection pressure.

An ethylene-responsive flower senescence-related gene from carnation encodes a protein homologous to glutathione S-transferases.

Carnation flower petal senescence is associated with the expression of specific senescence-related mRNAs, several of which were previously cloned. The cDNA clone pSR8 represents a transcript which accumulates specifically in senescing flower petals in response to ethylene. Here we report the structural characterization of this cDNA. A second cDNA clone was isolated based on shared sequence homology with pSR8. This clone, pSR8.4, exhibited an overlapping restriction endonuclease map with pSR8 and contained an additional 300 nucleotides. Primer extension analysis revealed the combined cDNAs to be near full-length and the transcript to accumulate in senescing petals. Analysis of the nucleotide sequence of SR8 cDNAs revealed an open reading frame of 220 amino acids sufficient to encode a 25 kDa polypeptide. Comparison of the deduced polypeptide sequence of pSR8 with other peptide sequences revealed significant similarity with glutathione s-transferases from a variety of organisms. The predicted polypeptide sequence shared 44%, 53% and 52% homology with GSTs from maize, Drosophila and man, respectively. We discuss our results in relation to the biochemistry of flower petal senescence and the possible role of glutathione s-transferase in this developmental process.

Characterization of an ethylene-regulated flower senescence-related gene from carnation.

The programmed senescence of carnation (Dianthus caryophyllus L.) petals requires active gene expression and is associated with the expression of several senescence-related mRNAs. Expression of the mRNA represented by the cDNA clone pSR12 has previously been shown to be transcriptionally activated by ethylene specifically in senescing flowers. We report in this paper the structural analysis of this cDNA and its corresponding gene. One cloned genomic DNA fragment, SR12-B, contained the entire transcription unit in 17 exons, interrupted by 16 introns. A second gene, SR12-A, was highly homologous to SR12-B with several nucleotide substitutions and a 489 bp deletion in the 5' flanking DNA sequence. The SR12 transcript has an open reading frame of 2193 bp sufficient to encode a protein of 82.8 kDa. No significant homology at the DNA or protein levels was found with other known genes. We have identified a DNA-binding factor which specifically interacts with two upstream fragments (-149 to -337 and -688 to -1055) of SR12-B. Both fragments apparently compete for the same binding factor. The DNA-binding activity was present in nuclear extracts from both presenescent and senescing carnation petals. The upstream DNA fragments that bind this factor have sequence homology with promoter sequences of other ethylene-regulated genes.

Regulation of senescence-related gene expression in carnation flower petals by ethylene.

Ethylene plays a regulatory role in carnation (Dianthus caryophyllus L.) flower senescence. Petal senescence coincides with a burst of ethylene production, is induced prematurely in response to exogenous ethylene, and is delayed by inhibitors of ethylene biosynthesis or action. We have investigated the role of ethylene in the regulation of three senescence-related cDNA clones isolated from a senescent carnation petal library (KA Lawton et al. [1989] Plant Physiol 90: 690-696). Expression of two of the cloned mRNAs in response to ethylene is floral specific, while the expression of another mRNA can be induced in both leaves and flowers exposed to ethylene. Although ethylene induces expression of these mRNAs in petals, message abundance decreases when flowers are removed from ethylene unless an autoenhancement of ethylene production is induced. This indicates continued perception of ethylene is required for their expression. Interruption of ethylene action following the onset of natural senescence results in a substantial decrease in transcript abundance of two of these mRNAs. However, the abundance of another mRNA remains unaffected, indicating this gene responds to temporal cues as well as to ethylene. As flowers age the dosage of exogenous ethylene required to induce expression of the cloned mRNAs decreases, indicating sensitivity to ethylene changes as the tissue matures. Nuclear run-on transcription experiments indicate that relative transcription rates of cloned mRNAs increase in response to exogenous ethylene.