Science 14Feb2020

P. syringaebecause it can recognize five ef-
fector families represented by alleles that are
rarely present in the same genetic background,
but that are distributed among nearly half
of theP. syringaestrains analyzed. Given that
ZAR1 is also required for the recognition of
AvrAC fromX. campestris( 37 ), this NLR ap-
pears to have particularly broad-spectrum
resistance that inhibits a diverse collection of

pathogens. Like AvrAC, theseP. syringaeef-

fectors may target and modify a diverse col-

lection of receptor-like cytoplasmic kinases,

leading to the downstream activation of

the ZAR1 resistome ( 38 – 40 ). Both CAR1 and

ZAR1 are conserved among 1135 sequenced

A. thalianaecotypes ( 41 ), which suggests

that they play a major role in immunity. It

will now be interesting to identify further

NLRs involved in recognition of other ef-

fectors, as they may offer insight into new

immune pathways.

Because of the prominence of ETI against

P. syringae, we hypothesize that ETI avoid-

ance will be a crucial virulence strategy of

successful pathogens, involving the loss and/or

modification of ETI-eliciting effectors ( 42 , 43 ).

In addition, meta-effector interactions will

also modulate ETI responses, as shown by the

loss of recognition of three effectors when

expressed in the PmaES4326 background

and the well-established interactions between

AvrRpt2 and AvrRpm1 ( 44 ). Finally, as dem-

onstrated by the differential recognition of

AvrE when encoded chromosomally versus

on a plasmid (see fig. S12), we hypothesize

that effector dosage must be regulated to

maximize virulence benefits while avoiding

host detection.

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ACKNOWLEDGMENTS

We thank all members of the Guttman and Desveaux labs

for helpful discussion and valuable input on this project;

H.Kim,L.Li,S.Park,andN.Hoffmannforhelpwithplant

assays; and D. Seto for crucial help with CRISPR/Cas9

mutagenesis.Funding:Supported by Natural Sciences and

Engineering Research Councilof Canada Discovery Grants

(D.S.G. and D.D.), a Natural Sciences and Engineering

Research Council of Canada Postgraduate Award (B.L.

and A.M.), Canada Research Chairs in Comparative Genomics

(D.S.G.) and Plant-Microbe Systems Biology (D.D.),

and the Center for the Analysis of Genome Evolution and

Function (D.S.G. and D.D.).Author contributions:B.L.,

M.M.D., D.D., and D.S.G. designed the project; M.M.D. and

R.N.D.A. assembled, annotated, and quality-controlled the

genomes, including hrp box promoter identification; M.M.D.

conceived and carried out the pipeline to identify, delimit,

and engineer representative effectors; B.L. and A.M. cloned

and delivered effectors intoP. syringae,performedWestern

analysis,andperformedgrowthandHRassays;B.L.and

A.M. screened effectors for ETI responses; B.L., M.M.D.,

A.M., and R.N.D.A. analyzed the data; B.L., M.M.D., D.D.,

and D.S.G. wrote the paper; and all authors reviewed and

agreed on the manuscript.Competing interests:The authors

declare no competing interests.Data and materials

availability:Accession numbers for all genome assemblies

used in this study are available in data S1 to S4. All data that

support the findings of our study are available in the

manuscript or supplementarymaterials. All strains with

International Collection of Microorganisms from Plants (ICMP)

designations are availablefrom ICMP at https://scd.

landcareresearch.co.nz/Search?collectionId=ICMP.

SUPPLEMENTARY MATERIALS

science.sciencemag.org/content/367/6479/763/suppl/DC1

Materials and Methods

Figs. S1 to S15

Tables S1 to S8

References ( 45 – 65 )

View/request a protocol for this paper fromBio-protocol.

20 March 2019; resubmitted 18 October 2019

Accepted 17 January 2020

10.1126/science.aax4079

Laflammeet al.,Science 367 , 763–768 (2020) 14 February 2020 6of6

Fig. 4. ETI governs host specificity onA. thaliana.
TheP. syringaeisolate PmaYM7930 harbors one
additional ETI-eliciting effector (HopAR1, which
induces ETI via the RPS5 NLR) that is not present
in the closely related and highly virulent strain
PmaES4326. (A) Visual symptoms of representa-
tive wild-type Col-0 andrps5mutant plants
sprayed with PmaYM7930 compared to
Col-0 sprayed with PmaES4326 using a standard
no-flash setting. (B)Samephotosasin(A)
but with a green-pass filter to enhance the
difference between diseased and healthy tissue.
(CandD) In planta bacterialgrowth assays (C)
and plant disease scores based on the proportion
of yellow chlorotic plant tissue (D) illustrate
that the recognition of HopAR1 by RPS5 signifi-
cantly reduces bacterial growth and disease
symptoms. Letters above bars represent signif-
icance groups atP<0.05(Studentttests with
Holm-Bonferroni multiple test correction).

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