Báo cáo khoa học: Salicylic acid and the hypersensitive response initiate distinct signal transduction pathways in tobacco that converge on the as-1-like element of the PR-1a promoter pot

Pfitzner Universita¨t Hohenheim, Institut fu¨r Genetik, FG Allgemeine Virologie, Stuttgart, Germany Tobacco pathogenesis-related protein 1a PR-1a is induced in plants during the hypersen

Salicylic acid and the hypersensitive response initiate distinct signal

Rose Gru¨ner*, Georg Strompen†, Artur J P Pfitzner and Ursula M Pfitzner

Universita¨t Hohenheim, Institut fu¨r Genetik, FG Allgemeine Virologie, Stuttgart, Germany

Tobacco pathogenesis-related protein 1a (PR-1a) is induced

in plants during the hypersensitive response (HR) after

exposure of plants to salicylic acid (SA) and by

develop-mental cues.Gene activation by these diverse stimuli is

mediated via an as-1-like element in the PR-1a upstream

region.To further analyze the significance of this cis-acting

sequence, an authentic as-1 element from the cauliflower

mosaic virus 35S RNA promoter was inserted into the

PR-1apromoter in place of the as-1-like motif.Reporter

gene analysis in transgenic tobacco plants demonstrated that

as-1 can functionally replace the as-1-like element in the

PR-1a promoter in response to all stimuli.However,

reporter gene induction from the as-1 carrying promoter was

enhanced in response to SA compared to the wild-type

promoter, and the ratio of reporter gene activities in SA treated leaf tissue to tissue exhibiting the HR increased with the as-1 promoter construct.Our findings support a model where PR-1a gene expression relies on at least two distinct signal transduction pathways initiated by SA and by a yet unknown signal produced during the HR, that promote different, albeit related, transcription complexes on the PR-1a as-1-like element.Analysis of PR-1 proteins in plants expressing salicylate hydroxylase yielded additional evidence that an HR dependent pathway leads to high level PR-1 gene induction in tobacco

Keywords: GUS reporter gene expression; PR-1 protein induction; salicylate hydroxylase; transgenic tobacco plants

Infection of plants with pathogens usually results in a

distinct host response depending on the genetic constitution

of the plant and the pathogen.In an incompatible

inter-action, the pathogen remains localized at the primary

infection sites that often are visible as necrotic local lesions

on the leaves.This local defense reaction is referred to as the

hypersensitive response (HR).Subsequently, the HR

trig-gers a general resistance mechanism rendering uninfected

parts of the plant less sensitive to further attack by

pathogens, a phenomenon called systemic acquired

resist-ance (SAR) [1].The elicitation of the HR and SAR

reactions is accompanied by the coordinated induction of a

heterogeneous group of proteins in the infected and

uninfected leaves, commonly referred to as

pathogenesis-related (PR) proteins

PR proteins were first described in tobacco plants infected with Tobacco mosaic virus (TMV) exhibiting the HR [2,3]

By now, related proteins have been identified across the plant kingdom in both dicotyledonous and monocotyled-onous species.In tobacco, seven families of PR proteins are known [4].Yet, the biological functions of PR proteins are not clear.It is intriguing that PR proteins are also expressed

in substantial amounts in healthy plants upon the transition

to flowering [5–7], suggesting that they play a role during plant development

Although not defined clearly by their function, the expression of PR genes has served as a reliable marker for the induction of SAR [8–11].Therefore, PR genes are also referred to as SAR genes [8].To identify components of the complex defense signaling pathways, several groups have studied the regulation of PR gene expression.Initially, PR-1 proteins were found to be inducible to high levels by the exogenous application of salicylic acid (SA) in healthy tobacco plants [12].Consistent with this finding, tissue levels

of SA have been demonstrated to increase significantly locally and systemically in plants displaying the HR [13–15] Furthermore, plants that are inhibited in SA accumulation show defects in SAR and in the expression of PR genes [16–19].It was thus hypothesized that SA is an endogenous regulator of pathogen resistance and of PR gene expression [20].Subsequently, some PR genes were found to be responsive to agents other than SA.From these findings and from the study of Arabidopsis mutants exhibiting aberrant SAR expression patterns, it appears that different pathways encompassing SA or ethylene/jasmonic acid as signal molecules can lead to the induction of PR genes and SAR

in plants infected by pathogens [21]

Correspondence to U.M.Pfitzner, Universita¨t Hohenheim, Institut fu¨r

Genetik, FG Allgemeine Virologie, Emil-Wolff-Str.14,

D-70599 Stuttgart, Germany.

Fax: + 49 711459 2937, Tel.: + 49 711459 2395,

E-mail: pfitzner@uni-hohenheim.de

Abbreviations: HR, hypersensitive response; PR, pathogenesis-related;

SA, salicylic acid; SAH, salicylic acid hydroxylase; SAR, systemic

acquired resistance; TMV, Tobacco mosaic virus.

*Present address: Baxter Deutschland GmbH, Edisonstr.3–4,

D-85716 Mu¨nchen-Unterschleißheim, Germany.

Present address: Universita¨t Tu¨bingen, ZMBP, Entwicklungsgenetik,

Auf der Morgenstelle 3, D-72076 Tu¨bingen, Germany.

(Received 29 July 2003, revised 9 October 2003,

accepted 22 October 2003)

To dissect the functional architectures of PR gene

promoters responsive to different signal molecules,

repor-ter gene constructs were generated and tested for regulated

gene expression.In addition, in vivo and in vitro studies

were performed to unravel interactions of nuclear proteins

with DNA sequences in the promoter regions of PR

genes.By these means, diverse sequence elements and

their cognate binding proteins have been identified in

accordance with the view that PR genes are regulated

differently.In the)906 bp promoter region of the tobacco

gene encoding the acidic PR-1a protein, a duplicated

TGACG motif has been shown to control reporter gene

expression in transgenic plants in response to SA, to the

HR, and to developmental stimuli [22].This element is

referred to as as-1-like motif because of its relatedness to

the as-1 element.The as-1 element was originally

identi-fied in the 35S RNA promoter from cauliflower mosaic

virus (CaMV) [23], and has been shown to mediate a

moderate induction of the 35S RNA promoter by SA

[24].Transcription factors belonging to the TGA family of

basic leucine zipper proteins interact in vitro with as-1

[23,25], and, similarly, with the PR-1a as-1-like motif [22]

Likewise, a related cis-acting element involved in SA

responsive reporter gene expression has been identified in

the homologous Arabidopsis PR-1 promoter by functional

analyses in transgenic plants [26].The Arabidopsis

cis-acting element comprises the sequence TGACG, which is

directly repeated only 12 bp upstream of the identified

promoter element.TGA transcription factors have been

shown to bind to this motif in vitro [27–29], and an

inducible in vivo footprint has revealed significant changes

in DNA accessibility to the identified element upon SAR

induction [26].In addition, overexpression of

trans-dominant TGA mutant proteins, which are no longer

able to bind to their target sequences, has resulted in

reduced accumulation of chemically inducible PR-1

mRNAs in transgenic tobacco and Arabidopsis plants

[30,31].Thus, as-1-like elements and TGA transcription

factors seem to be intimately connected with the

expres-sion of PR-1 genes in both tobacco and Arabidopsis.This

association is even more supported by the finding that

TGA factors from Arabidopsis, tobacco and rice have

been shown to interact in vivo and in vitro with NPR1/

NIM1 [27–29,32,33] NPR1/NIM1 has been identified as a

key regulator of SAR in Arabidopsis acting downstream

of SA in the SAR signaling pathway [10,11,21], and

analysis of npr1 mutant plants has established that

efficient expression of the Arabidopsis PR-1 gene after

SAR induction relies on a functional NPR1/NIM1 gene

[10,11].Furthermore, it has been demonstrated recently

that Arabidopsis TGA2 acts as a transcriptional activator

in transgenic plants in response to SA, and that this

activity is abolished in the npr1 mutant [31].Taken

together, substantial evidence has accumulated suggesting

a prominent role for as-1-type elements and TGA

transcription factors in the regulated expression of some

PRgenes

Here we report that the level of SA inducible gene

expression is controlled by the as-1-like element in the

strong)1533 bp PR-1a promoter from tobacco.To further

analyze the functional significance of as-1-like elements and

their binding factors in the induction of PR genes, we have

modified the PR-1a promoter to contain an authentic as-1 element As-1 can functionally replace the as-1-like element

in the PR-1a promoter.Substitution by as-1 enhances SA inducible reporter gene expression from the promoter by a factor of 3 in transgenic plants, and the ratio of inducible reporter gene expression from the as-1 containing promoter

in SA treated tissue to necrotic tissue infected with TMV is increased compared to the wild-type promoter.These findings emphasize that as-1 related elements and their binding factors play crucial roles in the regulation of the tobacco PR-1a gene.Furthermore, our results demonstrate that the properties of the PR-1a promoter are subject to change by insertion of a variant as-1 element.The data are

in accord with the conclusion that the tobacco PR-1a promoter is targeted by at least two distinct signal trans-duction pathways, elicited by SA and by a yet unknown signal produced during the HR, respectively, which mediate PR-1agene activation through a common DNA sequence, the as-1-like element

Experimental procedures

Construction of plasmids containing reporter genes Recombinant DNA techniques were performed according

to standard procedures [34]

For the construction of the PR-1 reporter gene, a 0.27 kb StyI/PstI fragment from kW38-1, comprising parts of the 5¢ region and the open reading frame encoded by the W38-1 gene [35], was inserted into StyI/PstI cleaved pT5S/HDP containing the PR-1a gene.The resulting plasmid was linearized with EcoRV, which cuts in the PR-1a 3¢ untrans-lated region 56 bp 3¢ to the stop codon, and a SacI linker was added to the blunt ends.The W38-1::PR-1a chimeric gene was excised from the plasmid as StyI/SacI fragment and inserted into p-1533PR1a[GUS] [7], from which the GUS reporter gene had been removed as a StyI/SacI fragment The)1533as-1m4[GUS] construct was generated by the addition of the 0.64 kb HindIII/XhoI fragment from p-1533PR1a[GUS] to the 5¢ end of p-906as-1m4[GUS] [22] The as-1m4 mutation replaces the as-1-like element occuring from positions)592 to )577 in the PR-1a promoter

To obtain construct)906as-1[GUS], site-directed muta-genesis was employed on p-906PR1a encompassing the PR-1asequence from)906 to +28.The DNA was primed with PR-46 (5¢-TGACGTTAACTAACTAT-3¢) containing

an A to C nucleotide substitution with respect to the wild-type promoter (underlined).By this procedure, a unique HpaI restriction enzyme site (bold) was introduced in p-906PR1a at position)597 just upstream of the as-1-like motif (from )592 to )577).The mutant plasmid was digested with HpaI and BamHI and ligated to a 0.6 kb HpaI/BamHI fragment obtained from p-906PR1a by PCR amplification with a pUC universal primer and PR-47 (5¢-CAAGCTTGTTAACTGACGTAAGGGATGACGGC CATGTTCAAGTTT-3¢), which contains an authentic as-1 element as found in the CaMV 35S RNA promoter (in bold letters).The as-1 element was inserted at position)591 in the PR-1a promoter.The as-1 containing)906 bp PR-1a promoter region was added as HindIII/BamHI fragment

to p0[GUS] to give plasmid )906as-1[GUS].To obtain p-1533as-1[GUS], the 0.64 kb HindIII/XhoI fragment from

p-1533PR1a[GUS] was ligated to HindIII/XhoI cleaved

p-906as-1[GUS]

All plasmids generated by site-directed mutagenesis or

PCR amplification of fragments were verified by DNA

sequence analysis

Construction of an expression vector containing

thenahG gene from Pseudomonas putida

P putida PpG7 containing plasmid NAH7 (DSM 4476)

was obtained from the German Collection of

Microorgan-isms and Cell Cultures, Braunschweig, and grown in

mineral medium with the addition of 0.05% sodium

salicylate according to the instructions of the supplier.In

order to isolate the nahG gene, two primers were designed

Primer nahG-1 (5¢-TTCCCGGGGCCATCACGAGTA

CAGCATGA-3¢) is identical to the 5¢ end of the nahG gene

including the ATG translation start codon (bold) with an

additional SmaI restriction enzyme site at its 5¢ end.Primer

nahG-2 (5¢-AAGAGCTCGTCAACGTTGTCACCCTT

G-3¢) is complementary to the 3¢ end of the nahG gene

including the translation stop codon (bold) and carries a

SacI restriction enzyme site at its 5¢ end.The primers were

used in standard PCR amplifications on plasmid DNA

isolated from P putida by the alkaline lysis procedure.A

single reaction product of 1.3 kb was detected on ethidium

bromide stained agarose gels.The PCR product was

subcloned into pUC19 cleaved with SmaI and SacI and

sequenced over its entire length.The nucleotide sequence

determined was found to be identical to the sequence of the

nahGgene described previously [36].For fusion of the nahG

gene to the CaMV 35S RNA promoter, the 1.3 kb SmaI/

SacI fragment was integrated into pBin19/35S[GUS] [37]

from which the GUS reporter gene had been removed.The

resulting plasmid was designated pBin19/35S[nahG]

Generation and analysis of transgenic plants

Constructs for expression in plants were integrated into the

binary vector pBin19, and Agrobacterium-mediated

trans-formation was employed to introduce gene constructs into

the genome of tobacco (Nicotiana tabacum L.cv.Samsun

NN) as described previously [22].Primary transformants

were allowed to self-fertilize, and progeny plants were

selected on medium containing 400 mgÆL)1kanamycin

For the induction of reporter gene constructs and of the

endogenous PR-1 proteins, eight leaf disks of 1 cm diameter

were cut from at least two different fully expanded leaves

of each transgenic plant.The leaf disks were floated for

72–96 h in a Petri dish on water or on neutral solutions of

1 mMor 5 mMSA as indicated.From plants which were

tested for gene induction by application of SA as well as

during the HR, leaf disks for chemical treatment were

collected from a single leaf which was cut from the plant just

prior to virus inoculation.Infection of tobacco plants with

TMV has been described previously [22].Eight leaf disks

were collected from necrotic tissue of transgenic plants

5–7 days after virus inoculation.For the analysis of PR-1

gene expression in nahG transgenic plants, two zones of leaf

material, a narrow zone including the lesion and a more

distant zone, were excised from the leaves around single

lesions with two different cork borers of 7 and 14 mm

diameter, respectively.Leaf disks were extracted with GUS lysis buffer.Analysis of GUS reporter gene expression and immunodetection of PR-1 proteins was conducted as reported [22,37].For monitoring the expression of the PR-1 reporter gene, protein extracts were separated by gradient gel electrophoresis.GUS activity is given in units (1 unit¼ 1 nmol of 4 MUÆh)1per mg protein)

To verify the correct insertion of the as-1[GUS] con-structs in transgenic plants exhibiting high GUS reporter enzyme induction, genomic DNAs were isolated from transformants according to Fulton et al.[38].Standard PCR was performed on the genomic DNAs using PR-19, identical to the PR-1a promoter, and a GUS primer complementary to the 5¢ end of the reporter gene.PCR products were cut with HpaI which cleaves only in the as-1 containing promoter regions, but not in the PR-1a wild-type promoter.Reaction products were analyzed on ethidium bromide stained agarose gels

Results

The)1533 bp PR-1a promoter directs high level induction of a PR-1 reporter protein in transgenic tobacco plants

Functional analysis of the tobacco PR-1a promoter by several groups had demonstrated that the 0.9 kb upstream region of the PR-1a gene is sufficient to yield regulated reporter gene expression in transgenic tobacco plants [7,39,40].Yet, gene induction levels from the 0.9 kb PR-1a promoter are significantly lower (average fold induction of GUS reporter gene activity < 75) than induction of the endogenous PR-1a gene (?100-fold).Previously, we have shown that a longer PR-1a upstream region, the)1533 bp promoter, is able to direct higher levels of GUS reporter gene expression in transgenic plants [7].To assess the strength of the)1533 bp PR-1a promoter region in direct comparison to the expression of the endogenous PR-1 genes, we have fused a PR-1 reporter gene to the)1533 bp promoter and monitored expression of the reporter protein

in transgenic tobacco plants

The PR-1 reporter gene is a chimera constructed in vitro

by the replacement of a 0.27 kb StyI/PstI fragment in the PR-1agene with the respective fragment from the W38-1 pseudogene [35].The open reading frame of the chimeric PR-1gene, designated W38-1::PR-1a, is colinear with the open reading frame encoded by the PR-1a gene, and differs

by only six amino acids from the PR-1a preprotein in the N-terminal moiety of the protein.Most importantly, the W38-1pseudogene part of the W38-1::PR-1a chimeric gene contains an amino acid exchange close to the signal peptide cleavage site (Gly vs.Arg in the PR-1a preprotein at positon )2 of the signal peptide), thus giving rise to an alternatively processed mature protein in plants, which can be distin-guished through its smaller size from the naturally occurring PR-1a, PR-1b and PR-1c proteins by SDS gel electrophor-esis (Fig.1 and data not shown).When put under control of the CaMV 35S RNA promoter in transgenic tobacco plants, the chimeric W38-1::PR-1a gene is equally well expressed as a similarly constructed 35S[PR-1a] transgene (Fig.1 and data not shown).Tobacco plants transformed with the)1533PR1a[W38-1::PR-1a] construct were infected

with TMV, and protein extracts from independent

trans-formants were monitored prior to and after infection for

expression of the endogenous PR-1 proteins and the

W38-1::PR-1a reporter protein by immunodetection.As shown

in Fig.1, two bands were observed consistently with

extracts from transformants exhibiting the HR after virus

infection.The upper, more prominent band corresponds to

the endogenous acidic PR-1 proteins, of which the PR-1a

protein constitutes approximately 50% (data not shown)

The lower band corresponds to the recombinant

W38-1::PR-1a protein.Although expressed weaker than the

endogenous PR-1a protein (approximately 5-fold less than

PR-1a), the recombinant W38-1::PR-1a protein is clearly

detected in all extracts containing considerable amounts of

the endogenous PR-1 proteins, thus demonstrating that the

)1533 bp PR-1a upstream region represents a promoter

that encompasses important cis-acting elements for both

regulated as well as high level expression of the PR-1a gene

Theas-1-like element controls the level of SA inducible

gene expression from the strong)1533 bp PR-1a

promoter in transgenic tobacco plants

Previously, we have shown that an as-1-like motif, located

from positions)592 to )577 in the PR-1a upstream region,

contributes significantly to the level of reporter gene

expres-sion from the weaker )906 bp PR-1a promoter [22].To

analyze the significance of the as-1-like motif for expression

from the strong )1533 bp PR-1a promoter, we have

introduced the as-1m4 mutation, which completely destroys

the as-1-like motif [22], in the)1533 bp PR-1a upstream

region to give construct )1533as-1m4[GUS] (Fig.2A)

Tobacco plants were transformed in parallel with

)1533PR1a[GUS] or )1533as-1m4[GUS], and

transform-ants were monitored for inducible reporter gene expression

after floating of leaf disks on H2O or on a solution of 1 mM

SA.As seen previously with the)906 bp PR-1a promoter,

insertion of the as-1m4 mutation drastically reduced reporter

gene expression from the strong)1533 bp promoter region

(Fig.2B).On the other hand, induction of GUS activity by

SA was still preserved with the mutant promoter, albeit at a

lower level (Fig.2B), just as observed previously for the

)906as-1m4 mutantPR-1apromoter [22].Thus, the as-1-like

motif represents an important cis-acting element controlling the level of expression from both the weaker)906 and the strong)1533 bp PR-1a promoter regions in a similar way

Replacement of theas-1-like element by as-1 enhances

SA inducible and developmentally controlled reporter gene expression from thePR-1a promoter in transgenic tobacco plants

To address the question whether the PR-1a as-1-like motif is

a genuine as-1-type element, possibly targeted by the same transcription factor(s) as as-1, we have introduced an authentic as-1 element in place of the as-1-like motif in the )906 and )1533 bp PR-1a promoter regions.The resulting reporter gene constructs were designated )906as-1[GUS] and)1533as-1[GUS], respectively (Fig.3A).Tobacco plants were transformed in parallel with)906as-1[GUS], )1533as-1[GUS], or the respective wild-type promoter constructs, and transformants were monitored for reporter gene expression after treatment of leaf disks with H2O or a solution of 1 mM

SA.As shown in Fig.3B, inducibility of GUS activity was maintained with any plant containing either of the as-1[GUS] transgenes.Surprisingly, plant extracts from transformants with the as-1[GUS] constructs yielded on average threefold

Fig 2 Effect of mutation of the as-1-like element on SA inducible reporter gene expression from the -1533 bp PR-1a promoter in trans-genic tobacco plants (A) Sequences of the wild-type and the as-1m4 containing promoter regions in the GUS reporter gene constructs.(B) Functional promoter analysis in transgenic plants.Tobacco plants were transformed with constructs )1533PR1a[GUS] or )1533as-1m4[GUS].Leaf disks were cut from grown-up independent trans-formants (10 plants for each construct), and floated for 3 days on water or on 1 m M SA.Protein extracts from leaf disks were measured for GUS activities.Average GUS activities in water and in SA treated leaf disks and average reporter gene induction were calculated for each construct.Average reporter gene induction is the ratio of average GUS activities in SA to water treated leaf disks.

Fig 1 Expression of a PR-1 reporter protein under control of the

-1533 bp PR-1a promoter in transgenic tobacco plants Independent

transformants with the )1533PR1a[W38-1::PR-1a] chimeric gene

(lanes 3–6) were inoculated with Tobacco mosaic virus

(TMV).Pro-teins were isolated from plants prior to (–) and 5 days after infection

(+).Extracts were analyzed for expression of the endogenous and the

recombinant PR-1 proteins by immunodetection after electrophoretic

separation of protein extracts.Lanes 1 and 2 contain equal amounts of

protein isolated from transgenic plants expressing the PR-1a or the

W38-1::PR-1a chimeric gene under control of the CaMV 35S RNA

promoter.

higher GUS activities than extracts from plants containing

the respective wild-type promoter constructs (Fig.3B).To

ensure that an as-1 element in the context of the PR-1a

promoter is indeed able to mediate higher average reporter

gene induction in transformed plants, we have isolated

genomic DNAs from four plants each exhibiting the highest

GUS activities from the transformations with the)906 and

)1533as-1[GUS] constructs.A 1.0-kb fragment was

ampli-fied from the isolated DNAs by PCR, and the PCR products

were cleaved with HpaI (Fig.3A).In all cases, the highest

GUS activities measured in transformed plants correlated

with the presence of a HpaI restriction endonuclease site

occurring at position)597 only in the )906as-1 and )1533

as-1 sequences, but not in the wild-type promoter regions

(data not shown)

Likewise, GUS reporter gene expression was monitored

in transgenic plants during normal development, as it has

been shown that the PR-1a promoter responds not only to

environmental, but also to developmental signals [7].Again,

higher levels of GUS activity were observed consistently

with transformants containing the as-1[GUS] transgenes

and not with the wild-type promoter constructs (data not

shown).Taken together, these results demonstrate that as-1

can functionally replace the as-1-like motif in the tobacco

PR-1apromoter in planta

Replacement of theas-1-like element by as-1 reduces

the ratio of reporter gene activities in necrotic tissue

exhibiting the HR to SA treated tissue

To analyze the effect of an as-1 containing PR-1a promoter

on gene induction during the HR, the selfed progeny from

two independent primary transformants with the )1533as-1[GUS] construct, 313–6 and 313–7, were selected on MS medium in the presence of kanamycin.Transformant 313–6 had displayed an intermediate reporter gene expression in the initial SA induction experiment shown in Fig.3B, whereas transformant 313–7 had exhibited high responsive-ness to SA.Resistant seedlings were transferred to soil.In parallel, seedlings containing wild-type PR-1a promoter constructs were selected.At the six-leaf stage, leaf disks were cut from the plants and floated on H2O or a solution of

1 mM SA.Immediately afterwards the same plants were infected with TMV GUS reporter gene expression was determined in protein extracts isolated from leaf disks after

4 days of chemical treatment or 7 days after virus inocu-lation.As shown in Fig.4A, reporter gene induction was considerably stronger in response to TMV infection in comparison to chemical treatment in transformants con-taining the)906 or the )1533 bp PR-1a wild-type promoter constructs (9.2- and 14.3-fold higher GUS activities, respectively, after TMV infection).In contrast, transform-ants containing the)1533as-1[GUS] transgene consistently exhibited higher levels of SA inducible GUS expression compared to reporter gene induction measured in TMV infected plants exhibiting the HR.TMV infection of transformants 313–6 and 313–7 produced only 2.7- to 4.8-fold stronger GUS activities than chemical treatment (Fig.4A).To account for possible errors in GUS activities between individual plant extracts due to experimental variations, GUS enzyme extracts were also analyzed for the expression of the endogenous PR-1 proteins by immunodetection.In all cases, induction of the endogenous PR-1 proteins was significantly stronger in virus infected

Fig 3 Effect of replacement of the as-1-like element by as-1 on SA inducible reporter gene expression from the PR-1a promoter in transgenic tobacco plants (A) Sequences of the wild-type and the as-1 containing promoter regions in the GUS reporter gene constructs.A HpaI restriction endonuclease site, which was generated by a single nucleotide exchange for DNA manipulation, is underlined in the as-1 containing promoter region.(B) Functional promoter analysis in transgenic plants.Tobacco plants were transformed with constructs )906as-1[GUS], )1533as-1[GUS],

or the respective wild-type promoter constructs.Leaf disks were cut from grown-up independent transformants (10 plants for each construct), and floated for 3 days on water or on 1 m M SA.Protein extracts from leaf disks were measured for GUS activities.Average GUS activities in water and

in SA treated leaf disks and average reporter gene induction were calculated for each construct.Average reporter gene induction is the ratio of average GUS activities in SA to water treated leaf disks.

tissue than in leaf tissue subjected to SA (Fig.4B).These

results demonstrate that GUS reporter gene induction in

plant lines with the)906 and )1533 bp PR-1a wild-type

promoter constructs reflects induction of the endogenous PR-1 proteins by the different stimuli.Therefore, as-1 enhances gene expression from the PR-1a promoter in response to SA, but it does not seem to markedly affect PR-1agene induction during the HR

PR-1 proteins are induced to high levels in necrotic tissue from tobacco plants expressing thenahG gene from

P putida

It is envisaged that PR-1 gene induction in local and systemic tissues of infected plants is mediated by SA produced during the course of the HR [20,21,41].However, our finding showing differential inducibility of an as-1 carrying PR-1a promoter in comparison to the wild-type promoter in response to SA vs.the HR, would favor an alternative explanation.In view of the results presented, it seems plausible that two distinct signal transduction path-ways could be targeted by SA and by signals released during the HR, respectively, resulting in the independent activation

of different transcription complexes.These complexes, in turn, could interact differentially with the wild-type and the as-1mutant promoter regions, thus leading to differential PR-1agene activation in response to the different stimuli

To challenge this model, we have made use of tobacco plants expressing the P putida nahG gene which codes for salicylate hydroxylase (SAH).Previously, it has been reported that expression of the bacterial gene in tobacco leads to drastically reduced levels of endogenous SA during the plant defense response [16,19]

The nahG gene from P putida was cloned in a plant expression vector under control of the CaMV 35S RNA promoter and several independent transgenic lines (N t cv Samsun NN) were generated via Agrobacterium-mediated transformation.Primary transformants were analyzed for the activity of SAH by infection with TMV.In wild-type plants, virus infection induces a local necrotic reaction which remains restricted to the primary infection site.On the contrary, six plants out of 9 regenerants transformed with the nahG expression vector exhibited enlarged local lesions as depicted in Fig.5.Typically, lesions had a light-brown center surrounded by two distinct necrotic regions each bounded by a thinner dark-brown margin at 14 days post-infection (Fig.5C) In contrast, the center of local lesions on wild-type plants was surrounded by only a single necrotic region bounded by a dark-brown margin This phenotype has been described previously for TMV infected tobacco plants that were severely depleted from endogenous SA by the expression of the nahG gene [16,17,19].To further demonstrate the enzymatic activity

of SAH, progeny plants from primary transformants, that were no longer able to restrict lesion growth, were monit-ored for endogenous SA levels and for their ability to induce PR-1 proteins after treatment with SA.The amount of total

SA (free SA plus glucosylated SA) reached levels of 7199 ng per gram fresh weight in TMV infected control leaves (N t cv.Samsun NN), which represents a 90-fold induction over

SA levels in noninfected leaves (79.5 ng total SA per gram fresh weight).On the contrary, total SA levels in inoculated tissue from nahG transformants of line 201–10 (58 ng per gram fresh weight) remained even below the levels detected

in noninfected control leaves.Consistent with this result,

Fig 4 Comparison of gene expression from the wild-type and the

-1533as-1 PR-1a promoter regions in response to SA and during the HR

in transgenic tobacco plants (A) Quantitative GUS assay of extracts

from SA treated and TMV infected plants.Leaf disks were cut from

progeny plants of transgenic lines containing the )906PR1a, the

)1533PR1a, or the )1533as-1 (two plants each from lines 313–6 and

313–7) promoter constructs and floated on water or on 1 m M SA.

Immediately after cutting the leaf disks, the same plants were

ino-culated with TMV.GUS activities were measured in protein extracts

isolated from leaf disks floated on water or SA after 4 days and from

TMV infected plants after 7 days.For a more facile comparison of

reporter gene expression between individual plant extracts, GUS

activities determined in extracts from TMV infected plants were

assigned 100% activity, and GUS activities determined in floated leaf

disks were expressed as percentage of the activities in virus infected

plants.The ratio of reporter gene activities in TMV infected tissue to

SA treated tissue is given for each plant.100% GUS activity

corres-ponds to 240.0 units for )906PR1a[GUS], 539.9 units for

)1533PR1a[GUS], 261.6 units for 313–6/A,B, and 921.7 units for

313–7/A,B, respectively.(B) Immunodetection of PR-1 proteins in

extracts from SA treated and TMV infected plants.After measuring

GUS activities, plant extracts shown in A were analyzed for the

accumulation of the endogenous PR-1 proteins.Equal amounts of

protein were loaded on the gels from water (0) or SA treated (S) leaf

disks or from TMV infected plants (T).

plants from lines 201–10 and 201–4 were not able to

accumulate PR-1 proteins to appreciable amounts after

floating of leaf disks on H2O or on solutions of 1 mM or

5 mMSA, thus demonstrating the activity of SAH in these

plant lines (Fig.6A)

Subsequently, plants were infected with TMV.After 7

and 14 days, leaf material was collected from a narrow

zone including the lesion and from a more distant zone

around single lesions of each plant.Whereas samples from

the distant zone of control plants never contained necrotic

leaf material, samples collected from the distant zone of

the transformants consistently included necrotic tissue

14 days after virus infection due to lesion expansion.At

14 days post-infection, lesions on nahG expressing plants from line 201–10 had reached an average diameter of 7.3 ± 0.6 mm and were still growing (Fig 5B,C), whereas lesions on wild-type plants remained restricted to 4.2 ± 0.5 mm Proteins were extracted from the samples and analyzed for the expression of PR-1 proteins Significant amounts of PR-1 proteins were detected in the samples from the narrow zone around lesions collected from tissue of nontransformed plants as well

as from nahG transformants (Fig.6B, lanes 1,3,5,7) However, PR-1 proteins were never detected in tissue further away from the center of the necrotic lesions in control plants (Fig.6B, lanes 6 and 8), whereas high levels

of PR-1 proteins had accumulated at 14 days post-infec-tion in the samples from the distant zone around lesions

in nahG expressing plants (Fig.6B, lane 4) Therefore, although depleted from endogenous SA and thus inca-pable to restrict lesion growth, tobacco leaf tissue undergoing necrosis is able to support efficient induction

of PR-1 proteins

Fig 5 Phenotype of local lesions in transgenic tobacco plants containing

a 35S[nahG] chimeric gene The phenotype of lesions induced by TMV

infection in plant line 201–10 is shown.The bars correspond to 10 mm.

(A) The photograph was taken at 7 days post-infection.At this time

point, lesions on nahG expressing plants are not different in size or

phenotype from lesions on control plants.(B) The same leaf as

depicted in A is shown.The photograph was taken at 14 days

post-infection.(C) Close-up demonstrating discontinuous enlargement of

lesions in nahG transformants.The photograph was taken at

14 days post-infection.

Fig 6 Expression of PR-1 proteins in transgenic tobacco plants con-taining a 35S[nahG] chimeric gene (A) Expression of PR-1 proteins in

SA treated transformants.Leaf disks were cut from wild-type plants (SNN) or from progeny plants of lines 201–10 or 201–4.Equal amounts of protein from disks incubated for 3 days on water (0), on

1 m M (1), or on 5 m M SA (5) were analyzed for the accumulation of PR-1 proteins by immunodetection.(B) Expression of PR-1 proteins in transformants displaying the HR.A wild-type plant (SNN) and a progeny plant from line 201–10, which exhibited lesion expansion as depicted in Fig.5 and impaired accumulation of PR-1 proteins in response to SA as depicted in A, were infected with TMV.Leaf sam-ples were collected 7 and 14 days post-infection from tissue around single lesions.Leaf material of zone 1 (lanes 1,3,5,7) included necrotic tissue from the lesions, whereas leaf material of zone 2 was collected in

a region 7–14 mm away from the center of the lesions.Due to the expansion of local lesions in nahG expressing plants, sample 2 from line 201–10 contained necrotic tissue 14 days post-infection (lane 4), but not sample 2 from the wild-type plant (lane 8).Equal amounts of protein were analyzed for the accumulation of PR-1 proteins by immunodetection.

Reporter gene expression from the tobacco 0.9 kb PR-1a

upstream region has been studied extensively by several

groups [7,39,40].Although clearly inducible in plants treated

with SA, during the HR, and during adult stages of

development, the 0.9 kb PR-1a upstream region constitutes

a rather variable promoter of only intermediate strength.By

using a PR-1 reporter protein, we here demonstrate that a

longer upstream region, the )1533 bp PR-1a promoter,

yields regulated gene expression on the same order of

magnitude as observed with the endogenous PR-1a gene

(Fig.1).Likewise, GUS reporter gene expression from the

)1533 bp PR-1a promoter proved to be stronger and more

reliable on average than expression from the 0.9 kb

promoter (Fig.3) [7].On the other hand, gene expression

from the)1533 bp PR-1a promoter, as expression from the

short)906 bp PR-1a promoter, is controlled in a similar

way by the same cis-acting sequence, the as-1-like element

(Fig.2) [22] Therefore, the tobacco )1533 bp PR-1a

upstream sequence represents a strong and highly inducible

promoter region whose transcriptional activity largely relies

on the as-1-like element

To further characterize the significance of the as-1-like

element for gene expression, we have inserted an authentic

as-1element from the CaMV 35S RNA promoter in place

of the as-1-like sequence in the PR-1a promoter GUS

reporter gene expression from the as-1 carrying long and

shorter PR-1a upstream sequences was monitored in

transgenic tobacco plants in comparison to the wild-type

promoter regions in response to SA, the HR and

develop-mental cues.Clear induction of gene expression was

retained with the mutant promoter regions towards the

diverse stimuli (Figs 3 and 4 and data not shown).Thus, as-1

from a viral promoter is able to fully replace the as-1-like

element in the tobacco PR-1a promoter.These findings

would imply that the cauliflower mosaic virus, in order to

enable transcription of its genes in planta, has adopted a

cis-acting element from a plant gene active during the

defense response.Furthermore, our results demonstrate

that different as-1 related elements can be functional in the

context of the PR-1a promoter, suggesting that the same or

similar factors are involved in transcription via as-1 and the

as-1-like element in the complex PR-1a upstream region

in planta.Our conclusion is consistent with previous reports

showing that TGA transcription factors, which were

originally isolated via physical interaction with as-1 [25],

bind in vitro to as-1-like elements present in the tobacco

PR-1aand the Arabidopsis PR-1 upstream regions [22,27–29]

Most importantly, however, our data show that reporter

gene induction from an as-1 containing PR-1a promoter is

even stronger on average than reporter gene induction from

the wild-type promoter in SA treated and in mature

untreated plants (Fig.3 and data not shown; threefold

increase of SA responsive reporter gene expression with the

as-1 upstream region).On the contrary, reporter gene

expression was not markedly affected in plants with the

)1533as-1[GUS] chimeric gene during the HR (Fig.4)

Therefore, the as-1 containing mutant promoter appears to

be regulated differently from the wild-type promoter in

response to different stimuli.To account for a differential

inducibility of the PR-1a wild-type and the as-1 carrying

mutant promoter regions by diverse stimuli, it seems plausible to speculate that gene expression from the PR-1a promoter occurs through different pathways activated by exogenous application of SA and by signals elicited during the HR, respectively.Given this case, different, albeit related, transcription complexes could form on the PR-1a promoter in response to varying stimuli.These complexes may include TGA factors to mediate physical association of alternating transcription complexes with the PR-1a upstream region via the as-1-like element.In this scenario, variation of the as-1-like element within the PR-1a promoter could directly affect gene expression by differential inter-action of the mutated promoter region with different transcription complexes

To seek for support for our model of distinct signal transduction pathways leading to the independent activa-tion of the tobacco PR-1a gene by SA and by an unknown

HR released signal, we have made use of transgenic tobacco plants expressing the nahG gene from P putida.The nahG gene codes for salicylate hydroxylase (SAH), which converts

SA to the inactive compound catechol.It has been shown previously that tobacco plants expressing the nahG gene are barely able to induce SA levels above the background in response to TMV infection [16,19].Curiously, plants incapable to accumulate SA to normal levels due to nahG expression exhibit a phenotype of enlarged local lesions upon infection with avirulent pathogens, whereas wild-type plants are able to restrict lesion size more rigorously.This phenotype has been reported for nahG expressing tobacco and tomato plants after infection with TMV, and for Arabidopsis plants after infection with avirulent bacterial and fungal pathogens [16,17,19,42,43].Our tobacco plants transformed with a 35S[nahG] chimeric gene displayed the expected phenotype of enlarged local lesions after TMV infection.Once formed, lesions kept on expanding for several weeks and typically reached diameters of up to

22 mm 8 weeks after virus inoculation on progeny plants of line 201–10 (Fig.5 and data not shown) These results clearly indicate that the transformants, unlike wild-type plants, did not contain sufficient SA to restrict lesion growth.Further proof that the nahG transformants used in this study were severely impaired in the transmission of the

SA signal came from their lack to induce PR-1 proteins to normal levels after exposure of leaf disks to high concen-trations of SA (Fig.6A).Consistently, total SA levels in TMV infected leaves from nahG transformants were shown

to be even lower than the levels detected in noninfected tissue from control plants.Plants handicapped in the accumulation of SA were infected with TMV, and PR-1 proteins were monitored in the necrotic tissue induced by the spreading lesions.Whereas lesions and the accumulation

of PR-1 proteins remained strictly localized in infected wild-type plants over a period of 14 days, the extension and the level of PR-1 protein synthesis increased significantly in the nahG transgenic plants in parallel with the induction of necrosis by the expanding lesions (Fig.6B).Our finding of substantial amounts of PR-1 proteins in nahG plants is consistent with other observations.Friedrich et al.[19] report that SAR associated genes like PR-1 are clearly expressed in the inoculated leaves of TMV infected nahG transgenic plants exhibiting drastically reduced levels of SA Taken together, tobacco plants, although expressing active

SAH, are able to induce PR-1 proteins in tissue undergoing

necrosis, demonstrating that the expression of PR-1 proteins

to high levels during the HR does not depend solely on the

accumulation or transmission of the signal molecule SA

Based on our findings we propose a new model for the

activation of the tobacco PR-1a gene by SA and during the

HR.Foremost, our model implies at least two distinct signal

transduction pathways leading independently from each

other to PR-1a gene induction, an SA dependent pathway

and a pathway relying on unknown signals produced during

the HR (Fig.7).As activation of the PR-1a gene strictly

depends on the as-1-like element [22], we further suggest

that the two independent signaling cascades lead to the

formation of related, albeit different, transcription

com-plexes, which are likely to include TGA factors.Thus, gene

activation via distinct signal transduction events would

converge on the as-1-like element in the tobacco PR-1a

promoter (Fig.7) Our model is consistent with the

existence of small protein families of plant TGA factors

TGA factors from Arabidopsis and tobacco share an

extremely conserved basic domain by which they are able

to interact with different as-1 related target sequences

in vitro[22,32,44,45].Furthermore, using chromatin immu-noprecipitation assays, it has been shown recently that TGA2 and TGA3 are recruited in vivo to the Arabidopsis PR-1promoter in response to a stimulus induction pathway involving SA and NPR1/NIM1 [46].TGA factors differ, however, clearly in other biochemical properties.Some TGA factors activate transcription in yeast via their N-terminal domains, whereas others do not seem to have

an intrinsic transactivation potential [32].Also, some TGA factors interact in the yeast two-hybrid system with NPR1/ NIM1, while others fail to do so [27–29,32].Therefore, it seems plausible that different TGA factors, although binding to the same cis-acting element, are engaged in variant transcription complexes that are induced in plants in response to different stimuli, as proposed in our model (Fig.7)

Our model is in conflict with previous conceptions in at least one important aspect.Generally, SA accumulation in local and systemic tissues of infected plants is considered to

be a product of processes induced by the HR and is thought

to be responsible for PR-1 gene induction during both the

HR and SAR [20,21,41].Yet, plants transformed with the nahGgene clearly demonstrate that PR-1 protein accumu-lation can occur to high levels in necrotic tissue depleted from SA (Fig.6) [19].However, in nahG transgenic plants, PR-1gene expression is abolished in the uninoculated leaves

of tobacco plants displaying the HR after TMV infection [19].Therefore, active SAH is able to fully suppress the SA dependent pathway of systemic PR-1 gene induction in tobacco, but fails to fully suppress HR dependent PR-1 gene activation (Fig.7), although SA levels are diminished to those in noninfected wild-type plants.Apart from the results with nahG transgenic plants, there are other indications in favor of our model.In Arabidopsis plants insensitive to SA due to a mutation in the NPR1/NIM1 gene, PR gene expression is blocked in systemic tissues after induction by a pathogen.However, in local tissues, PR gene expression, including PR-1, is not affected substantially by npr1 [21] Thus, as PR-1 gene induction is abolished nearly completely

in the npr1 mutant in response to SA [10], local induction of PR-1 in infected tissue must be independent of SA in Arabidopsisas well.A recent observation made by Fan and Dong [31] is intriguingly relevant to our model.The authors found that a chimeric transcription factor consisting of a fusion between Arabidopsis TGA2 and the GAL4 DNA binding domain is able to activate a GAL4 responsive reporter gene in Arabidopsis plants after exposure to SA Yet, when a bacterial pathogen was used to infect transgenic plants with the TGA2::GAL4 effector/reporter gene system, only little reporter gene induction was observed, although infection can cause a significant induction of the endo-genous PR genes and also of a PR reporter gene

In conclusion, based on our findings that an as-1 carrying PR-1apromoter is differentially regulated from the wild-type promoter in response to different stimuli and that PR-1 proteins are induced to high levels in necrotic tissue depleted from endogenous SA, we suggest that the tobacco PR-1a gene can be activated by at least two distinct signal transduction pathways which both rely on the as-1-like element in a similar way.Whereas one pathway is triggered

Fig 7 Proposed model for the induction of the tobacco PR-1a gene via

two distinct signal transduction pathways elicited during the HR and by

SA, respectively, that converge on the as-1-like element TMV infection

of tobacco (cv.Samsun NN) triggers the activation of a signal cascade

leading to necrosis.This pathway still operates in transgenic plants

expressing a 35S[nahG] chimeric gene and leads to high level induction

of PR-1 proteins.Application of exogenous SA triggers the activation

of a signal cascade leading to TMV resistance and moderate

induction of PR-1 proteins independent of necrosis.This pathway

mimics SAR (SAR-like response).SA dependent PR-1 gene activation

is (nearly) abolished in transgenic plants expressing a 35S[nahG]

chi-meric gene.As mutation of the as-1-like element markedly reduces

reporter gene expression in SA treated as well as in TMV infected

plants exhibiting the HR (Fig.2) [22], both pathways mediate

indu-cible gene expression through the same cis-acting element in the PR-1a

promoter.On the other hand, an as-1 containing PR-1a promoter

responds differently from the wild-type promoter towards SA and the

HR.Therefore, different, albeit related, transcription factor complexes

interacting with the as-1-like element seem to be involved in the HR

and the SA dependent signal transduction cascades leading to PR-1a

gene activation in tobacco.

by SA accumulating in noninfected tissues during the SAR,

the other pathway is induced by a yet unknown signal

molecule formed in tissues undergoing necrosis during the

HR.The identification of factors whose expression is

regulated solely by SA or by HR released signals will

support our hypothesis

Acknowledgements

We would like to thank Bernhard Roth for communicating SA levels in

tobacco tissue; Ivana Glocova for help with the analysis of transgenic

plants; Maren Babbick for providing photographs of nahG plants; Ingrid

Priessnitz-Hohos for transformation of tobacco plants; and Jochen

Grob for technical assistance.This work was supported by grants from

Genzentrum Mu¨nchen and from Fonds der Chemischen Industrie.

References

1.Ross, A F (1961) Systemic acquired resistance induced by

localized virus infections in plants Virology 14, 340–358.

2.Gianinazzi, S , Martin, C.& Valle´e, J.C (1970) Hypersensibilite´

aux virus, tempe´rature et prote´ines solubles chez le Nicotiana

Xanthi n.c Apparition de nouvelles macromole´cules lors de la

re´pression de la synthe`se virale C.R Acad Sci D270, 2383–2386.

3.Van Loon, L C.& Van Kammen, A.(1970) Polyacrylamide disk

electrophoresis of the soluble proteins from Nicotiana tabacum

var.¢Samsun¢ and ¢Samsun NN¢.II.Changes in protein

constitu-tion after infecconstitu-tion with tobacco mosaic virus Virology 40, 199–

211.

4 Van Loon, L.C & Van Strien, E.A (1999) The families of

pathogenesis-related proteins, their activities, and comparative

analysis of PR-1 type proteins Physiol Mol Plant Pathol 55,

85–97.

5 Fraser, R.S.S (1981) Evidence for the occurrence of the

patho-genesis-related proteins in leaves of healthy tobacco plants during

flowering Physiol Plant Pathol 19, 69–76.

6 Neale, A D , Wahleithner, J A , Lund, M , Bonnett, H T , Kelly,

A., Meeks-Wagner, D.R., Peacock, W.J & Dennis, E.S (1990)

Chitinase, b-1,3-glucanase, osmotin, and extensin are expressed in

tobacco explants during flower formation Plant Cell 2, 673–684.

7.Gru¨ner, R.& Pfitzner, U.M.(1994) The upstream region of the

gene for the pathogenesis-related protein 1a from tobacco

responds to environmental as well as to developmental signals in

transgenic plants Eur J Biochem 220, 247–255.

8 Ward, E.R., Uknes, S.J., Williams, S.C., Dincher, S.S.,

Wiederhold, D L , Alexander, D C , Ahl-Goy, P , Me´traux, J.-P.

& Ryals, J.A (1991) Coordinate gene activity in response to agents

that induce systemic acquired resistance Plant Cell 3, 1085–1094.

9 Uknes, S., Mauch-Mani, B., Moyer, M., Potter, S., Williams, S.,

Dincher, S., Chandler, D., Slusarenko, A., Ward, E & Ryals, J.

(1992) Acquired resistance in Arabidopsis Plant Cell 4, 645–656.

10 Cao, H , Glazebrook, J , Clarke, J D , Volko, S & Dong, X.

(1997) The Arabidopsis NPR-1 gene that controls systemic

acquired resistance encodes a novel protein containing ankyrin

repeats Cell 88, 57–63.

11 Ryals, J , Weymann, K , Lawton, K , Friedrich, L , Ellis, D ,

Steiner, H -Y , Johnson, J , Delaney, T P , Jesse, T , Vos, P &

Uknes, S.(1997) The Arabidopsis NIM1 protein shows homology

to the mammalian transcription factor inhibitor IjB Plant Cell 9,

425–439.

12.White, R F.(1979) Acetylsalicylic acid (aspirin) induces resistance

to tobacco mosaic virus in tobacco Virology 99, 410–412.

13 Malamy, J., Carr, J.P., Klessig, D.F & Raskin, I (1990) Salicylic

acid: a likely endogenous signal in the resistance response of

tobacco to tobacco mosaic virus Science 250, 1002–1004.

14.Me´traux, J -P , Signer, H , Ryals, J , Ward, E , Wyss-Benz, M , Gaudin, J., Raschdorf, K., Schmid, E., Blum, W & Inverdi, B (1990) Increase in salicylic acid at the onset of systemic acquired resistance in cucumber Science 250, 1004–1006.

15 Uknes, S., Winter, A.N., Delaney, T., Vernooij, B., Morse, A., Friedrich, L., Nye, G., Potter, S., Ward, E & Ryals, J (1993) Biological induction of systemic acquired resistance in Arabidopsis Mol Plant-Microbe Interact 6, 692–698.

16 Gaffney, T , Friedrich, L , Vernooij, B , Negrotto, D , Nye, G , Uknes, S., Ward, E., Kessmann, H & Ryals, J (1993) Require-ment of salicylic acid for the induction of systemic acquired resistance Science 261, 754–756.

17 Delaney, T , Uknes, S , Vernooij, B , Friedrich, L , Weymann, K , Negrotto, D , Gaffney, T , Gut-Rella, M , Kessmann, H , Ward, E.& Ryals, J.(1994) A central role of salicylic acid in plant disease resistance Science 266, 1247–1250.

18 Vernooij, B , Friedrich, L , Morse, A , Reist, R , Kolditz-Jawhar, R., Ward, E., Uknes, S., Kessmann, H & Ryals, J (1994) Salicylic acid is not the translocated signal responsible for inducing systemic acquired resistance but is required in signal transduction Plant Cell 6, 959–965.

19 Friedrich, L , Vernooij, B , Gaffney, T , Morse, A & Ryals, J (1995) Characterization of tobacco plants expressing a bacterial salicylate hydroxylase gene Plant Mol Biol 29, 959–968.

20 Ryals, J., Neuenschwander, U.H., Willits, M.G., Molina, A., Steiner, H.Y.& Hunt, M.D.(1996) Systemic acquired resistance Plant Cell 8, 1809–1819.

21 Clarke, J D , Volko, S M , Ledford, H , Ausubel, F M & Dong, X.(2000) Roles of salicylic acid, jasmonic acid, and ethylene in cpr-induced resistance in Arabidopsis Plant Cell 12, 2175–2190.

22 Strompen, G., Gru¨ner, R.& Pfitzner, U.M.(1998) An as-1-like motif controls the level of expression of the gene for the patho-genesis-related protein 1a from tobacco Plant Mol Biol 37, 871– 883.

23 Lam, E., Benfey, P.N., Gilmartin, P.M., Fang, R.-X & Chua, N.-H (1989) Site-specific mutations alter in vivo factor binding and change promoter expression pattern in transgenic plants Proc Natl Ac ad Sc i USA 86, 7890–7894.

24 Qin, X.-F., Holuigue, L., Horvath, D.M & Chua, N.-H (1994) Immediate early transcription activation by salicylic acid via the cauliflower mosaic virus as-1 element Plant Cell 6, 863–874.

25 Katagiri, F., Lam, E & Chua, N.-H (1989) Two tobacco DNA-binding proteins with homology to the nuclear factor CREB Nature 340, 727–730.

26 Lebel, E , Heifetz, P , Thorne, L , Uknes, S , Ryals, J & Ward, E (1998) Functional analysis of regulatory sequences controlling PR-1 gene expression in Arabidopsis Plant J 16, 223–233.

27 Zhang, Y., Weihua, F., Kinkema, M., Li, X & Dong, X (1999) Interaction of NPR1 with basic leucine zipper protein transcription factors that bind sequences required for salicylic acid induction of the PR-1 gene Proc Natl Acad Sci USA 96, 6523– 6528.

28.Despre´s, C , DeLong, C , Glaze, S , Liu, E & Fobert, P R (2000) The Arabidopsis NPR1/NIM1 protein enhances the DNA bind-ing activity of a subgroup of the TGA family of bZIP transcription factors Plant Cell 12, 279–290.

29 Zhou, J -M , Trifa, Y , Silva, H , Pontier, D , Lam, E , Shah, J & Klessig, D.F (2000) NPR1 differentially interacts with members

of the TGA/OBF family of transcription factors that bind an element of the PR-1 gene required for induction by salicylic acid Mol Plant-Microbe Interact 13, 191–202.

30 Niggeweg, R., Thurow, C., Kegler, C & Gatz, C (2000) Tobacco transcription factor TGA2.2 is the main component of as-1-binding factor ASF-1 and is involved in salicylic acid- and auxin-inducible expression of as-1-containing target promoters J Biol Chem 275, 19897–19905.