Herbivory-induced volatiles function as defenses increasing fitness of the native plant Nicotiana...
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Schuman et al. eLife 2012;1:e00007. DOI: 10.7554/eLife.00007 1 of 29
Herbivory-induced volatiles unction asdeenses increasing tness o the nativeplant Nicotiana attenuatain natureMeredith C Schuman, Kathleen Barthel, Ian T Baldwin*
Department o Molecular Ecology, Max Planck Institute or Chemical Ecology, Jena,Germany
Abstract From an herbivores rst bite, plants release herbivory-induced plant volatiles (HIPVs)which can attract enemies o herbivores. However, other animals and competing plants can
intercept HIPVs or their own use, and it remains unclear whether HIPVs serve as an indirect deense
by increasing tness or the emitting plant. In a 2-year eld study, HIPV-emitting N. attenuata plantsproduced twice as many buds and fowers as HIPV-silenced plants, but only when native Geocoris
spp. predators reduced herbivore loads (by 50%) on HIPV-emitters. In concert with HIPVs, plants
also employ antidigestive trypsin protease inhibitors (TPIs), but TPI-producing plants were not tter
than TPI-silenced plants. TPIs weakened a specialist herbivores behavioral evasive responses to
simulated Geocoris spp. attack, indicating that TPIs unction against specialists by enhancing
indirect deense.
DOI: 10.7554/eLie.00007.001
Introduction
Plant indirect deenses are traits that disable or remove herbivores by manipulating tri-trophic interactions to the advantage o the plant (Price et al., 1980). They attract and inorm the third trophic level
predators or parasitoids, resulting in increased attacks on herbivores (Turlings and Wckers, 2004)
Indirect deenses are widespread and include domatia, extraoral nectar, and ood bodies which pro
vide shelter and nutrition or predators and parasitoids, as well as herbivory-induced plant volatiles
(HIPVs) which convey inormation about eeding herbivores (Heil, 2008). Field studies with the native
tobacco Nicotiana attenuata, a desert annual, and with maize have shown that HIPVs can reduce her
bivore loads by 24% to more than 90%, by increasing both predation and parasitization o herbivores
(Kessler and Baldwin, 2001; Rasmann et al., 2005; Halitschke et al., 2008; Degenhardt et al.
2009;Allmann and Baldwin, 2010) and deterring herbivore oviposition (Kessler and Baldwin, 2001)
I HIPVs really unction as deenses, they should increase Darwinian ftness, defned as successu
reproduction, or plants under herbivore attack (Karban and Baldwin, 1997). But because HIPVs can
be perceived by many other members o the ecological communityrom herbivores, pollinators
predators and parasitoids to competing or parasitic plantsit is not clear whether HIPVs increaseplant ftness in nature (Dicke and Baldwin, 2010; Kessler and Heil, 2011). The feld studies described
above have either spanned too short a time to reveal Darwinian ftness benefts, or have not reported
ftness data at all (Kessler and Baldwin, 2001; Rasmann et al., 2005; Halitschke et al., 2008
Degenhardt et al., 2009;Allmann and Baldwin, 2010). Two laboratory studies showed that parasiti
zation o herbivores can increase plant reproduction (van Loon et al., 2000; Hoballah and Turlings
2001), but the parasitization in these studies was not mediated by HIPVs. Hence three decades ate
their description, it remains unclear whether HIPVs are really indirect deenses.
Long-term feld studies comparing HIPV-emitting vs -defcient plants are required in order to
demonstrate a deensive unction or HIPVs. Experimental additions o pure volatiles or mixes to
*For correspondence: baldwin@
ice.mpg.de
Present address: Federal
Research Center or CultivatedPlants, Institute or Breeding
Research on Horticultural And
Fruit Crops, Julius Khn Institute,
Dresden, Germany
Competing interests:See page 26
Funding:See page 26
Received: 7 May 2012
Accepted: 11 July 2012
Published: 15 October 2012
Reviewing editor: Detle Weigel,
Max Planck Institute or
Developmental Biology,Germany
Copyright Schuman et al. This
article is distributed under the
terms o the Creative Commons
Attribution License, which
permits unrestricted use and
redistribution provided that the
original author and source are
credited.
RESEARCH ARTICLE
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plants growing in nature has worked well to test short-term eects o specifc compounds (Kessler
and Baldwin, 2001;Allmann and Baldwin, 2010), but only endogenously produced HIPV emis-
sions can ensure specifc, lasting and consistent dierences under feld conditions. Most evidence
or the utility o HIPVs comes rom studies in which predators and parasitoids learn to associate
HIPVs with prey; nave predators and parasitoids are just as likely to respond to HIPVs as not
to respond (Allison and Hare, 2009). Thus the inducibility o HIPV emission, which ensures asso
ciation with herbivore eeding, is likely essential or HIPV unction, but it is difcult to engineer
(Kos et al., 2009). Engineered constitutive HIPV emissions have been used, either on predators
and parasitoids trained to associate target volatiles with prey in short-term laboratory experi
ments (Kappers et al., 2005; Schnee et al., 2006), or in set-ups in which target volatiles are
always associated with prey (Rasmann et al., 2005; Degenhardt et al., 2009). When plants areengineered constitutively to emit HIPVs, they no longer provide accurate inormation about the
location o eeding herbivores, and predators will not associate these signals with prey in nature
Genetically silencing the biosynthesis o HIPVs, however, permits naturally inducible wild-type
(WT) plants to serve as HIPV emitters, or comparison with transormed lines lacking specifc vola
tile components (Halitschke et al., 2008; Skibbe et al., 2008). Furthermore, feld experiments
that manipulate the production o HIPVs which not only attract the third trophic level, but also
inuence the second trophic level (e.g., as eeding stimulants and host location cues), require
additional experimental manipulations to preserve the plant-herbivore part o the tritrophic
interaction.
eLie digest As the population o the world continues to increase beyond 7 billion, andagricultural pests continue to rapidly evolve resistance to pesticides, it is becoming ever more
important to cultivate arable land in a way that is sustainable or both humans and the environment.
A better understanding o the dierent mechanisms used by wild plants to deter herbivores will
help to increase crop production without harming the environment.
Plants use both direct and indirect methods to end o herbivores. Direct deense methods
include the production o chemicals that are toxic to herbivores or give them indigestion, and thegrowth o sticky prickles and spines that can injure or kill the herbivore. Indirect deense methods,
on the other hand, generally rely on the plant attracting organisms that are either predators or
parasites o the herbivore.
Plants produce odors known as herbivory-induced plant volatiles (HIPVs) that are thought to
oer indirect deense against herbivores by betraying their location to predators and parasites.
However, HIPVs also infuence other members o the ecological community, sometimes in ways that
are detrimental to plants. Moreover, despite 30 years o research, no study has demonstrated that
HIPVs increase the tness o a plant, so it is unclear what they have evolved to do.
Now, a 2-year eld study by Schuman et al. has shown plants that emit green lea volatiles (which
are a type o HIPV) produce twice as many buds and fowersa measure o tnessas plants that
have been genetically engineered not to emit green lea volatiles. This study was conducted with
Nicotiana attenuata, which is a wild tobacco plant that is oten targeted by Manduca sexta, a type
o moth that is also known as the tobacco hornworm. Green lea volatiles only increased plantstness when various species o Geocorisa bug that preys on Manduca sextareduced the
number o herbivores by a actor o two. This is the rst evidence that HIPVs oer indirect deense
against herbivores.
Schuman et al. also studied the eects o molecules called protease inhibitors that are thought
to unction as direct deenses by making it dicult or herbivores to digest plants. They ound that
the ability to produce protease inhibitors did not increase the tness o plants under herbivore
attack; however, tobacco hornworms that had been ed plants containing protease inhibitors were
ound to be more sluggish in response to attack, which suggests that protease inhibitors can
enhance the indirect deenses o plants. The results suggest that employing both direct and indirect
deensessuch as a combination o biological pesticides and genetic engineering to produce both
HIPVs and protease inhibitorsis the best approach or deending agricultural plants against pests.DOI: 10.7554/eLie.00007.002
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When HIPVs do attract the third trophic level, how can herbivores adapt? Many herbivores can
outgrow their vulnerability to predators and parasitoids, but plant direct deenses can slow herbivore
growth and prolong vulnerability as postulated by the slow growth-high mortality hypothesis (Benrey
and Denno, 1997; Williams, 1999; Kessler and Baldwin, 2001, 2004; Kaplan and Thaler, 2011). The
solanaceous specialists Manduca sexta and M. quinquemaculata (Lepidoptera, Sphingidae) are resist
ant to the potent alkaloid toxin nicotine (Wink and Theile, 2002), but sensitive to the nutritional value
o plant tissue (Zavala and Baldwin, 2004). Non-toxic protease inhibitor (PI) proteins, which inhibi
protein digestion and thus decrease the availability o organic nitrogen in the orm o amino acids
(Zavala et al., 2008), are widespread in owering plants (Hartl et al., 2011), and trypsin proteaseinhibitors (TPIs) slow the growth oM. sexta on N. attenuata (Zavala et al., 2008). However, herbivores
can overcome PIs by producing insensitive or desensitized proteases, inactivating or degrading PIs
eating more plant tissue, and eating more nutritious young tissue (Winterer and Bergelson, 2001
Steppuhn and Baldwin, 2007; Zavala et al., 2008). In the latter two cases, PIs could reduce plant
ftness. Although TPI-producing N. attenuata plants produce more seeds than TPI-defcient plants
when attacked by M. sexta under controlled glasshouse conditions (Zavala and Baldwin, 2004)
whether TPIs unction as a direct deense in nature is unknown.
We tested the hypotheses that HIPVs and TPIs deend plants in nature by increasing herbivore
predation and thereby plant Darwinian ftness. To do so, we monitored the perormance, predation and
mortality o Manduca spp. (M. sexta and M. quinquemaculata) on wild-type N. attenuata plants
and RNAi transormed lines silenced or the production either o a specifc group o HIPVs, or o TPIs
and compared the resulting plant reproductive output in terms o bud and ower production (we are
not permitted to allow transgenic plants to disperse ripe seed). Because N. attenuata is an annual
opportunistic out-crosser, seeds are produced within one growing season, mostly rom ertilization via
sel-pollen (Sime and Baldwin, 2003), and we can relate bud and ower production to lietime seed
production, which is commonly accepted as a measure o Darwinian ftness (Baldwin, 1998; van Loon
et al., 2000; Hoballah and Turlings, 2001).We hypothesized that HIPVs would increase plant repro
duction by increasing predation o herbivores, and that TPIs alone would not increase reproduction
under herbivore attack, but would either increase predation or increase herbivores susceptibility to
predators. We then assembled a toolbox o wild-type and transgenic lines chosen to test these
hypotheses.
We chose a genotype oN. attenuata native to the Great Basin Desert o southwestern Utah. In
many years, Manduca spp. larvae cause the most deoliation o N. attenuata plants in this area
(Kessler and Baldwin, 2001) and thus the N. attenuata UT genotype is likely adapted to deend
against Manduca spp. Eggs and young larvae oManduca spp. are predated by Geocorisspp. (bigeyed bugs) which occur naturally in the Utah habitat and are attracted to components oN. attenu
atas HIPV bouquet (Kessler and Baldwin, 2001; Halitschke et al., 2008; Skibbe et al., 2008)
Specifcally, Utah Geocorisspp. predators are attracted to the sesquiterpene (E)--bergamotene as
well as green lea volatiles (atty acid-derived C6 aldehydes, alcohols and esters) (Kessler and
Baldwin, 2001; Halitschke et al., 2008; Schuman et al., 2009). Green lea volatiles, or GLVs, can
be silenced via a single upstream 13-lipoxygenase, NaLOX2, which specifcally supplies lipid
hydroperoxides or their production (Allmann et al., 2010). Although GLVs are released upon
mechanical damage, the oral secretions (OS) oM. sexta convert 3-(Z)-GLVs to the 2-(E)-structures
resulting in greater Geocoris spp. predation than the damage-induced (Z):(E) ratio (Allmann and
Baldwin, 2010). GLVs are released immediately upon damage (Allmann and Baldwin, 2010) and
may thereore be a frst line o deense.
Like GLVs, many other HIPVs are also released ater mechanical damage, but change in amount o
ratio upon herbivory, and thus GLVs mirror the unctional complexity o the total HIPV blendFurthermore, GLVs prime or directly regulate responses in neighboring plants (Kessler et al., 2006
Paschold et al., 2006), attract herbivores as well as predators (Halitschke et al., 2008), and are impor
tant cues or pollinating and ovipositing moths (Kessler and Baldwin, 2001, 2006; De Moraes et al.
2001; Fraser et al., 2003), thus perorming several roles which may harm or beneft plant ftness in
addition to their role in attracting predators. Perhaps most signifcantly, GLVs also stimulate Manduca
spp. eeding, and silencing plant GLV production results in reduced herbivore damage (Halitschke
et al., 2004; Meldau et al., 2009). All these qualities made the manipulation o GLV emissions an idea
means to test rigorously the ftness consequences o HIPV emissions and to evaluate whether these
emissions can truly be considered deensive.
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Results
GLV and TPI production are reduced or eliminated in transormed linesWe chose a line o irPI plants with no detectable TPI activity (Steppuhn and Baldwin, 2007)
and a line o irLOX2plants with GLV emissions
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Figure 2. Hexane extracts o leaves rom eld-grown plants. (A) Hexane extracts rom pooled lea samples
o eld-grown plants or a qualitative assessment o green lea volatile (GLV) pools, analyzed by GC-MS with
a split ratio o 1/100 onto a nonpolar column; only (E)-hex-2-enal was identied due to poor resolution o
(E)-hex-2-enal and (Z)-hex-3-en-1-ol on the nonpolar column; no ester peaks were detected. For raw data, see
F3A_SchumanBarthelBaldwin2012chromatograms.xlsx (Dryad: Schuman et al., 2012). (B) Example chromatograms
rom hexane extracts o individual lea samples rom eld-grown plants, analyzed by GC-FID on a wax column. Thedominant compound was (E)-hex-2-enal; (Z)-hex-3-en-1-ol was also present in quantiable amounts. (Z)-3-hexenyl
acetate was chosen as an internal standard because no esters were detectable in the preliminary qualitative
GC-MS analysis (1A), and because its chemical similarity to (E)-hex-2-enal and (Z)-hex-3-en-1-ol made it a
good choice o internal standard or normalization and calculation o yield rom extracts. For raw data, see
F3B_SchumanBarthelBaldwin2012chromatograms.xlsx (Dryad: Schuman et al., 2012). IS: internal standard.
DOI: 10.7554/eLie.00007.004
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were not dierent (p>0.05 in Fishers exact tests), indicating that Geocorisspp. continued to explore
irLOX2and hemi-irLOX2plants but not to predate rom them over a week o inestation ollowed by
5 days oM. sexta egg predation assays (during which M. sexta eggs were simultaneously applied to
all genotypes); and we ollowed predation oM. sexta larvae rom all our genotypes in parallel over 1
week, during which irLOX2and hemi-irLOX2were inested with more larvae than WT and irPIdue to
sustained higher predation rates on WT and irPI; but predation remained higher on WT and irPI.Predation o both larvae and eggs without GLV supplementation was two to our times as great on
GLV-emitting WT and irPIplants: 43%/60% (WT/irPI) or larvae and 34%/39% or eggs, vs 17%/33%
(irLOX2/hemi-irLOX2) or larvae and 9%/20% or eggs (Fishers exact tests: N=30 larvae, p=0.047 o
irLOX2vs WT, p=0.069 or hemi-irLOX2vs irPI; N=88 eggs, p0.05 in Fishers exact
tests), indicating that Geocorisspp. regularly survey all plants and use GLVs as a short-distance cue to
determine which plants harbor prey. Figure 5shows larval predation rates at the beginning o the
Figure 3. GLV production and emission in transormed lines; graphs show means+SEM. (A) GLVs extracted with hexane rom lea tissue o eld-
grown WT, irPI, and hemi-irLOX2plants grouped in triplets or inestation M4 in 2011(Figure 4A). Leaves were harvested rom every plant at
the beginning (June 14) and in the middle o M4 (June 22) and leaves rom plants in 10 randomly chosen triplets were analyzed. Only (E)-hex-2-
enal and (Z)-hex-3-en-1-ol were quantiable in lea extracts. Dierent letters (a and b) indicate signicant dierences (p0.05) in Schee post hoc
tests ollowing one-way ANOVAs or (Z)-hex-3-en-1-ol (top panel, F2,26=9.556, p=0.001; bottom panel, F2,26=12.196, p
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Figure 4. Experimental timeline and layout. (A) Timeline o eld experiments in 2010 and 2011. Dierent assays
and measurements are represented by individual arrows, and rectangles span the time rame o each assay or
measurement; narrow rectangles represent single days. Four experimental Manduca inestations (M1M4) structurethe overall experimental design: M1M3, with laboratory Manduca, and M4, with wild Manduca larvae. (B and C)
Layouts o eld plots in (B) 2010 and (C) 2011. Thick lines denote the borders o the experiment, thin lines denote
irrigation lines (vertical borders o plot were also irrigation lines in [B] 2010), and R# denotes row number (used or
identiying replicates during the experiment). The genotype key in (B) applies to both (B) and (C).
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assay, when the M. sexta load was comparable across plant genotypes. Over the ollowing week
Geocorisspp. predated a total o 80% o these larvae rom WT and irPIvs 47% rom irLOX2(Fishers
exact test, p=0.015 vs WT) and 67% rom hemi-irLOX2(p=0.382 vs irPI).
In summary, Geocorisspp. had the same opportunity to locate M. sexta larvae and eggs on al
genotypes, but consistently preerred to predate rom GLV-supplemented or -emitting plants.
Manducaspp. damage reduces plant growth and reproductionWe took the dierent number o days in feld or each plant into account in our comparison o growth
and reproduction among genotypes and thereore the staggered planting did not aect this compari-
son (Figure 6, statistics Table 3). The irLOX2and hemi-irLOX2plants suered, in total, a similar amount o
M. sexta damage to WT plants in trials M2 and M3 (Figure 4), and only irPIplants suered signifcantly less
M. sexta damage (Figure 7).
Reduced predation o M. sexta rom irLOX2 and hemi-irLOX2 in trials M2 and M3 in 2011(Figure 4) correlated with the reduced growth and reproduction o both genotypes, by 3050%
or irLOX2and 2030% or hemi-irLOX2vs WT, although this reduction was also apparent in plants
not inested with M. sexta. (Figures 4 and 6, statistics Table 3). In 2010 however, in the absence
o predation, there was no dierence in stem growth, branching, or bud and ower production
among genotypes irrespective oM. sexta inestation (Figure 6, statistics Table 3). Although M
sexta eeding signifcantly aected growth and reproduction o plants overall, the eect was not
signifcant or irLOX2or irPI plants in either year (Figure 6, statistics Table 3), possibly due to
reduced eeding damage resulting rom a lack o TPI-induced compensatory eeding in irP
(Steppuhn and Baldwin, 2007) (Mann-Whitney U-test between irPI and WT on May 28, U=54
p=0.046, Figure 7). Although GLVs are eeding stimulants (Halitschke et al., 2004), we could not
measure reduced M. sexta eeding damage in hemi-irLOX2or irLOX2(Figure 7). Yet hemi-irLOX2
plants, despite strongly reduced GLVs, still suered reduced growth and reproduction rom
Manduca spp. eeding: M. sexta eeding reduced ower production rates by about 50% in WT andby about 30% in hemi-irLOX2plants in 2010, although the overall reduction was only signifcant in
WT; and reduced bud production signifcantly or both WT and hemi-irLOX2by 2530% in 2011
(Figure 6, statistics Table 3).
Damage rom naturally occurring herbivores other than Manducaspp.cannot explain dierences in plant tnessWe monitored herbivore attack to determine whether GLV-silenced plants suered dierent amounts
o damage rom naturally occurring herbivores, which could also cause dierences in their growth
and reproduction. All genotypes were attacked by mirid (Tupiocoris notatus) and noctuid herbivores
Table 1. GLV mix used to externally supplement plant GLV emission in M2 (see Figure 4) (Allmann
and Baldwin, 2010)
Component Nanogram/20 L lanolin
(Z)-hex-3-enal 3530
(E)-hex-2-enal 2690
(Z)-hex-3-en-1-ol 1780
(E)-hex-2-en-1-ol 2440
(Z)-hex-3-enyl acetate 46.6
(E)-hex-2-enyl acetate 35.5
(Z)-hex-3-enyl propanoate 9.00
(E)-hex-2-enyl propanoate 8.08
(Z)-hex-3-enyl butanoate 97.0
(E)-hex-2-enyl butanoate 35.6
Pure GLVs were diluted in 1 mL o hexane and mixed into 14 mL o lanolin to yield the amount shown per 20 L,
representing the emission per g lea material within the rst 20 minutes o W+OS elicitation. Lanolin containing an
equivalent amount o hexane was used as a control.
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GLV-defcient versus matched GLV-producing plants iGeocorisspp. were present. Homozygous irLOX2
plants were excluded rom these matched experiments because they did not suer reduced growth
or reproduction rom M. sexta eeding, and because they were too small in comparison to other lines in
2011 (Figure 6).
In both 2010 and 2011, we selected triplets o WT, irPIand hemi-irLOX2plants similar in size, repro
ductive output, apparent health, and prior damage; damage rom naturally occurring herbivores did
not dier among these genotypes (Figure 7). In 2010, matched plants were part o inestation M1
(Figure 4) and thus it was not necessary to control or prior reproduction or M. sexta damage. Plants in
2010 received three lab strain M. sexta larvae per plant to a lower stem lea. We recorded the mortality
oM. sexta larvae and the reproductive output o plants until they began to set unripe seed. No repro-
ductive meristems were removed, but owers were removed and counted periodically over the frst10 days, as was done during inestation M3 in 2011 (Figures 4and 6, statistics Table 3), to track plan
reproduction while avoiding ripe seed capsules: the distribution o ripe seed is not permitted or geneti
cally modifed plants. In the absence oGeocorisspp. in 2010, genotypes did not dier in M. sexta
mortality (N=51 larvae)which in every observed case was due to a ailure o the larva to eedor plan
reproduction (N=17 plants) (Figure 9). This, and the act that ower production did not dier among
genotypes in 2011 through inestation M3 despite ower removal (Figure 6), indicates that owe
removal itsel does not cause a dierence among genotypes, and suggests that the other dierences
among genotypes in growth and reproduction seen in 2011 (Figure 6, statistics Table 3) are real.
In 2011, hemi-irLOX2, irPIand WT plants were matched prior to inestation M4 to exclude dier-
ences in growth, reproduction and Manduca spp. damage arising during M. sexta inestations M2 and
M3 and rom caged Manduca spp. during the egg predation assay (Figures 4,7,and 8). Instead o
regularly removing owers, we removed all reproductive meristems rom matched plants in 2011 by
cutting inorescences at their base. This allowed us to ollow a new set o reproductive meristemsthrough to seed set without incurring ripe seed. Because plants were matched prior to the assay, a
similar number o reproductive meristems were cut rom all plants, and thus all plants were similarly
aected by this cutting (Figure 8, see Discussion).
Because oviposition by native Manduca spp. moths provided sufcient eggs prior to the beginning
o M4 (Figure 4), we decided to conduct this inestation with wild larvae and thereby demonstrate tha
native larvae, like larvae o the lab strain, are susceptible to GLV-mediated predation. To make M4 a
realistic test, we placed one wild Manduca spp. neonate per plant on a lower stem lea to mimic nat
ural oviposition rates (Kessler and Baldwin, 2001). We again recorded the mortality oManduca spp
larvae and the new reproductive output o plants until they began to set unripe seed. During the frst
Table 2. Numbers (N) oGeocorisspp. individuals (nymphs and adults) within 5 cm radii around
plants used or predation experiments, counted within hal an hour during the main period o
Geocorisspp. activity.
Experiment Genotype Geocorisspp. per day (n) Plants (n
Larval predation Dates May 21 22
May 2123, 2011 WT 3 4 19
irPI 6 6 24
irLOX2 6 4 20
hemi-irLOX2 8 2 20
Total 23 16 83
Egg predation Dates June 3 4 5 7
June 26, 2011 WT 2 5 2 1 18
irPI 3 7 1 5 21
irLOX2 4 2 0 3 21
hemi-irLOX2 1 1 2 2 24
Total 10 15 5 11 84
Numbers are shown as subtotals or each plant genotype and grand totals per day (in bold).
DOI: 10.7554/eLie.00007.009
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Table 3. Results o MannWhitney U-tests, KruskalWallis tests, and ANOVAs or control vs M. sexta-inested plants o each genotype
grown in the feld in 2010 and 2011 (Figures 6 and 9)
2010 Branches Stem, buds, fowers
MannWhitney,KruskalWallis
MANOVA, Wilks lambda
Comparison Genotype d 2 p* d F p
Treatment All 1 0.022 1.000 3, 148 0.463 0.709
Genotype All 3 2.909 0.802 9, 360.344 1.186 0.303
Branches (n) Rosette diameter (cm) Stem length (cm) Buds (n) Flowers (n)
2011 Students t-test Students t-test MANOVA, Wilkslambda
MANOVA, Wilkslambda
MANOVA, Wilkslambda
Comparison Genotype d t p d t p d F p d F p d F p
Treatmenttime WT 26 1.696 0.102 26 0.870 0.932 5, 22 3.871 0.011 5, 22 3.188 0.026 3, 24 1.213 0.326
irPI 26 1.024 0.315 26 0.161 0.873 5, 22 0.991 0.446 5, 22 0.656 0.660 5, 22 0.525 0.755
irLOX2 25 1.112 0.277 25 0.058 0.954 5, 21 0.606 0.696 5, 21 0.535 0.748 5, 21 0.540 0.744
hemi-irLOX2 22 1.753 0.094 22 1.140 0.267 5, 18 1.118 0.386 5, 18 3.001 0.038 4, 19 0.723 0.587
2010: Numbers o side branches (MannWhitney, KruskalWallis), stem length, and nal numbers o buds and fowers (MANOVA) were recorded in a
single measurement at the end o M1 (Figure 4). Numbers o newly produced fowers were counted repeatedly upon fower removal, and Wilks
Lambda F values or the main eect oM. sexta eeding are shown rom repeated-measures ANOVAs across all measurements; Wilks F values or theM. sexta-by-time interaction were not signicant. *Bonerroni-corrected p-values.
2011: Because many plants had ew or no side branches beore the nal measurement, and rosette diameters did not change over the period that plants
were measured, t-tests are shown or the nal measurement o these parameters in M3 (Figure 4). For stem lengths, numbers (n) o buds, and numbers
o fowers, Wilks lambda F values or the M. sexta-by-time interaction are shown rom repeated-measures ANOVAs across all measurements. Signicant
p-values are given in bold.
DOI: 10.7554/eLie.00007.011
to third larval instars in which larvae are vulnerable to Geocorisspp. predation (Kessler and Baldwin
2001), wild Manduca spp. mortality was 38% on hemi-irLOX2plants vs 6276% on matched WT and
irPIplants; the overall mortality o larvae on all three lines was signifcantly dierent (N=21 larvae,
Bonerroni-corrected pairwise comparisons by Friedman tests, p
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Figure 7. Herbivore damage to plants during the 2010 and 2011 eld seasons (means+SEM). For a timeline o
Manduca inestations M1M4, see Figure 4A. (A) Total canopy damage due to naturally occurring herbivores
beore the start o inestation M1 in 2010, N=17. For raw data, see F7A_SchumanBarthelBaldwin2012herbivoreDamage2010.
xlsx (Dryad: Schuman et al., 2012). (B) Total canopy damage due to naturally occurring herbivores beore
inestation M2 (May 5) and near the end o M3 (May 27) in 2011, N=2428. a, b Dierent letters denote signicant
(p
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Manducaspp. response to mock predator attack is altered by TPIconsumptionTPIs had a less consistent and, contrary to our expectations, negative eect on Manduca spp
predation (Figure 5); urthermore, there was no positive eect o TPIs on plant growth and repro
duction (Figure 6, statistics Table 3) and only a marginal eect o TPIs on Manduca spp. growth
under natural conditions (N=1326 second instar larvae during M2, one-way ANOVAs with geno
type as the actor, F3,77=2.792, p=0.046, all post hoctests p>0.05, Figure 10; N=8 second insta
larvae during M4, paired t-test between matched WT and irPI, p=0.052). We hypothesized tha
the reduced access to protein or larvae eeding on TPI-producing plants might nevertheless
aect Manduca spp. behavior independently o larval size. Indeed, wild Manduca spp. larvae eed
ing on WT plants (inestation M4, Figure 4) reacted more sluggishly to experimental provocation
than size-matched larvae on irPI plants: they were 75% less likely to attack when lited o o
the lea (N=5 second-instar larvae matched or size, p=0.035 in paired t-test) (Figure 10
Videos 1and 2).We were careul not to harm wild larvae so that we could monitor their natural mortality and
consequences or plant reproduction (Figure 9). To more accurately imitate Geocorisspp. attack
we developed an o-plant assay with larvae rom the laboratory M. sexta strain eeding on
detached leaves rom feld-grown plants, in which size-matched larvae were poked, pierced and
lited using an insect pin to mimic the Geocorisspp. beak (Figure 10, Videos 3and 4). Similarly
to the on-plant assay, larvae ed on WT leaves were 50% less likely to successully attack the insect
pin, either when initially poked, or poked and lited with the pin (N=20 frst-instar larvae matched
or size, p
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Figure 9. Cumulative mortality oManduca spp. larvae and numbers o reproductive units produced by inested
plants in 2010, in the absence oGeocoris spp. predation, and in 2011, when Geocoris spp. were active predators
oManduca spp. (A) In 2010, fowering plants matched or size (N=17) were each inested with three M. sexta
neonates rom a laboratory culture (N=51 larvae), which were allowed to reach the nal instar on plants. The upper
panel shows larva mortality over time, which reached a maximum o 40% by the th instar, ater 12 days. Flower
production (lower panel) did not dier, nor did any other parameters o plant size and reproduction (Figure 6,
Table 3) including number o buds produced by June 6, which was day 19 ater inestation and day 49 ater
planting in the eld. For raw data, see F9A_SchumanBarthelBaldwin2012data2010.xlsx (Dryad: Schuman et al.,
2012). (B) In 2011, plants (N=21) were matched or size, prior reproduction, health, and previous damage byManduca spp. and other herbivores (Figures 7 and 8) ollowing the end o inestation M3 (Figure 4), and
reproductive meristems were removed. Matched plants were inested with one wild Manduca spp. neonate each
(M4 in Figure4), and Manduca spp. larvae were allowed to reach the ourth (penultimate) instar. Larval mortality
(upper panel) reached a maximum o 76% ater larvae transitioned rom the second to third instar (days 9 and 10),
at which time larval mortality on hemi-irLOX2was only hal as great as on WT or irPI; larvae beyond this stage are
not susceptible to Geocoris spp. (Kessler and Baldwin, 2001). Flower and bud production (lower panel) was twice
as great in WT and irPI as in hemi-irLOX2, and numbers o fowers and buds correspond to numbers o seed
capsules: hemi-irLOX2plants also produced ewer unripe seed capsules than WT or irPI plants. For raw data, see
F9B_SchumanBarthelBaldwin2012data2011.xlsx (Dryad: Schuman et al., 2012). a, b, c Dierent letters indicate
Figure 9. Continued on next page
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continued to grow (p=0.016 in Students t-test); mortality did not dier (p=0.527 in Fishers exac
test) (Figure 10).
Thus TPIs did not increase plant reproduction under attack rom Manduca spp. in nature, but may
support indirect deense by weakening the response o larvae to predator attack. The contradictory
higher predation rates oManduca spp. larvae rom irPIthan rom WT plants (Figure 5) might reect
Geocorisspp.s eeding preerence, i irPI-ed larvae are more nutritious than WT-ed larvae (Kaplan
and Thaler, 2011).
DiscussionOur data demonstrate that herbivore-induced GLV emissions unction as indirect deenses by
increasing predation o Manduca spp. twoold, resulting in a twoold increase in bud and ower
production or N. attenuata in its native habitat. In contrast, there was no positive eect o TPIs onplant growth and reproduction and no signifcant eect o TPIs on Manduca spp. growth under nat
ural conditions; however, TPIs may support indirect deense by weakening the response o larvae to
predator attack. Although this indicates that predation rates rom irPIplants should be reduced, we
observed a tendency towards higher predation rates rom irPIthan rom WT plants; this could reect
Geocoris spp.s preerence i irPI-ed larvae are more nutritious than WT-ed larvae (Kaplan and
Thaler, 2011).
WT levels o TPIs in hemi-irLOX2 plants are likely due to gene dosageeectsThe hemi-irLOX2plants used in this study were created by crossing homozygous irPIand irLOX2
plants, but the irPIconstruct was not active in the hemizygous state (Figure 1). We continued to use
this cross or its less severely reduced GLV production in comparison to homozygous irLOX2plants
(Figures 2and 3), which likely permitted growth and reproduction comparable to irPIand WT in2011 that was essential or plant matching prior to the fnal assays oManduca spp. mortality and
plant reproduction (M4, Figures 4and 9). It is common molecular biology knowledge that unctiona
RNAi constructs may be rendered ineective as a result o insufcient gene dosage, or example
Travella et al. (2006)and reerences therein, which may occur when an RNAi construct is present in
the hemizygous state (Garca-Prez et al., 2004). The 35S promoter which drives the transcription
o the RNAi construct may also be methylated: an epigenetic eect which can reduce the dose o
RNAi in individual plants within a single transormed line (A Weinhold, unpublished data). This may
have occurred in the irPIparent used or the creation o the hemi-irLOX2line, although loss o activ
ity o the irPIconstruct was not observed in the homozygous irPIline over the lietime o plants in
the feld (Figure 1).
Our best measures o reproduction or transgenic plants in the eld
demonstrate the positive eect o GLV-mediated indirect deenseAlthough the production o viable ospring is the accepted defnition o Darwinian ftness, we are notpermitted to allow transgenic plants to disperse ripe seed in the feld, and measures to prevent seed
dispersal, such as bagging meristems, strongly aect production o buds and owers and can also
aect seed viability by increasing temperature, and decreasing respiration and photosynthesis o
reproductive tissue and associated green tissue.
For feld-grown N. attenuata plants, ewer than 5% o buds and owers (in total) are aborted by
healthy (not diseased) plants, and abortion seems always to be due to damage by insects (M C
Schuman and I T Baldwin, personal observation, June 2010). Plants are sel-compatible and more
than 70% o seed set rom plants in native populations results rom ertilization via sel-pollen
signicant dierences (p
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Figure 10. Mock Geocoris spp. predation assays with Manduca spp. larvae ed on WT or irPI plants. (A) Response
o wild Manduca spp. (Figure 4A) on plants in the eld to poking with a toothpick and liting with a eatherweight
orceps (N=5 second-instar larvae matched or size). We rst poked larvae below the horn three times, 3 s apart,
with the end o a toothpick and counted how oten they attacked the toothpick, dened as the larva whipping itshead around toward the toothpick and making contact. We then lited larvae rom the plant using the orceps and
counted how oten they attempted to attack, or succeeded in attacking the orceps over 15 s. In an attempted
attack, the larvae moved rom hanging at a 180 angle below the orceps vertically toward the orceps; and in a
successul attack, the ront end o the larva made contact with the orceps, beore returning to its original position.
All individuals were recorded and responses were counted rom videos (see Videos 1and 2). *p
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(Sime and Baldwin, 2003). Thus numbers o buds and owers correlate to lietime seed capsule
production, which in turn correlates to lietime seed production, which has been used as a proxy
measure o Darwinian ftness (Baldwin, 1998; van Loon et al., 2000; Hoballah and Turlings, 2001)
The transgenic lines used do not vary in seed mass or their seedling viability under laboratory
conditions.
Meristem removal rom plants beore inestation M4 was necessarydespite matching, and aected all plants similarly
During the 2011 experiment, we saw a large and reproducible dierence in predation rom GLV-emitting versus GLV-defcient plant genotypes, which was not observed in 2010 due to an absence o
Geocorisspp. predators in that year. This dierence in predation rate correlated to a dierence in
plant growth and reproduction which was also not observed in 2010. To rigorously test the conse-
quences o GLV-mediated predation oManduca spp. on plant reproduction, we selected triplets o
WT, irPIand hemi-irLOX2plants similar in size, previous reproductive output, apparent health, and
prior damage to carry out Manduca spp. mortality and plant reproduction assays (M1 in 2010, M4 in
2011, Figure4). We removed all reproductive meristems rom matched plants in 2011 to allow us to
ollow plant reproduction over ull Manduca spp. larval development without incurring ripe trans
genic seed capsules. In 2010 (and during inestation M3 in 2011, Figure4), we had removed and
counted owers regularly to track reproduction while avoiding ripe seed; this did not cause a dier-
ence in reproduction among genotypes (Figure 6), but we elected to avoid ower removal during
inestation M4 by removing reproductive meristems prior to the beginning o the assay.
The hemi-irLOX2plants chosen in 2011 had produced more owers than WT but not more than
irPIprior to the start o inestation M4 (Figures 4 and 8). This did not correspond to more cuts on
average or hemi-irLOX2when removing reproductive meristems: meristems were cut at the bases o
inorescences which contained mostly buds, and the number o these did not dier or the plants
chosen, nor did the number o side branches (Figure 8) which bore most reproductive meristems
Thereore, in the absence o additional eects during inestation M4, the reproduction o the matched
hemi-irLOX2plants should have been similar to that o WT and irPI.
Conclusions and outlookBy indicating the long-sought indirect deensive unction o HIPVs, these data set the stage or the use o
HIPVs as part o integrated pest management strategies (IPM), which rely in part on recruiting biologica
control agents to reduce pesticide use (Horne and Page, 2008). These agents are usually naturally occur
ring generalist parasitoids and predators, such as Geocorisspp. (Eubanks and Denno, 1999,2000;Allison
and Hare, 2009;Allmann and Baldwin, 2010). HIPVs are produced by genotypes o most, i not all crop
plants and IPM would beneft rom selective breeding or engineering o HIPV emission (Kos et al., 2009
rather than relying on alternatives such as controlled release dispensers, which have mixed success and
require large amounts o synthetic HIPVs (Kaplan, 2012). PIs may be employed to enhance the efciency
o indirect deense, especially combined with toxins like Bt that directly target herbivores and are sae o
biological control agents. With growing concerns about feld-evolved Bt resistance (Liu et al., 2010), indir
ect deenses promise an eective frst line o deense against agricultural pests, to which not even special-
ist herbivores are likely to rapidly evolve resistance.
Materials and methods
Plants, growth conditions and eld plantations
Seed germination, glasshouse growth conditions, and the Agrobacterium tumefaciens (strain LBA4404)mediated transormation procedure have been described previously (Krgel et al., 2002)
Seeds o the 31st generation o the inbred UT line oNicotiana attenuata (Torr. ex S. Wats.) were
used as the wild-type plant in all experiments. For the feld experiment, seedlings were transerred
to 50 mm peat pellets (Jiy) 15 days ater germination and gradually hardened to the environmenta
conditions o high sunlight and low relative humidity over 10 days. Small, adapted, size-matched
rosette-stage plants were transplanted into a feld plot in a native habitat in Utah and watered thor-
oughly once at planting and as needed over the frst 2 weeks until roots were established; all plants
received the same watering regime in each year. WT, irPI, irLOX2 and hemi-irLOX2 plants were
arranged in quadruplets (N=4050) o one plant per genotype, with individuals 0.5 m
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apart, a distance sufcient to allow predators
and herbivores to distinguish volatiles rom
neighboring plants (Kessler and Baldwin
2001). Quadruplets were arranged so that no two
adjacent plants were o the same genotype
(Figure4). In 2010, the feld plot was a frst-yea
plot located at latitude 37.141, longitude
114.027; in 2011, plants were planted at a sec-
ond, older feld site across a river rom the frstlocated at latitude 37.146, longitude 114.020
Field plantations were conducted under APHIS
permission numbers 06-242-3r-a3 (2010 and
2011) and 10-349-102r (2011).
We used previously characterized, homozy
gous, inverted-repeat (ir) RNAi transormed lines
o the second transormed generation (T2) to
silence GLV biosynthesis: irLOX2line number A-04-52-2 (Allmann et al., 2010), and TPI activity: irP
line number A-04-186-1 (Steppuhn and Baldwin, 2007). Vector construction and the pSOL3 plasmid
have been described previously (Bubner et al., 2006). A cross was created between irLOX2and irP
homozygous lines; however, the hemizygous irPIconstruct did not silence TPI activity or transcripts
and these plants thereor served as vector controls or comparison with irPIand had slightly greate
residual GLV production than irLOX2(see Results). They are thus reerred to as hemizygous (hemi-
irLOX2plants.
Manducaspp. eggs and larvaeWild Manduca spp. eggs were collected or feld assays when available rom natural ovipositions. M
sexta and M. quinquemaculata (hereater Manduca spp.) were both ovipositing at the time experi
ments were conducted; the species o larvae was identifed at the third instar and recorded (earlier
instars o these two species cannot be distinguished morphologically). M. sexta and M. quinquemaculata
oral secretions (OS) are highly similar in their composition (Halitschke et al., 2001) and elicit simila
volatiles (Halitschke et al., 2001; Kessler and Baldwin, 2001) and deense genes (Schittko et al.
2001) in N. attenuata. Eggs rom laboratory-reared M. sexta, kindly provided by Dr. Carol Miles at
SUNY Binghampton, were used in the feld when wild Manduca spp. eggs were not sufciently abundant
Eggs were allowed to hatch in well-aerated boxes on resh N. attenuata lea tissue over a moistenedpaper towel. M. sexta larvae used to elicit glasshouse-grown plants, or to collect oral secretions (OS
or plant treatments, were taken rom an in-house colony at the Max Planck Institute or Chemical
Ecology in Jena, Germany.
Manducaspp. inestation and W+OS treatment o plantsBecause GLVs inuence Manduca spp. oviposition (De Moraes et al., 2001; Kessler and Baldwin
2001; Fraser et al., 2003), and the timing and extent oManduca spp. oviposition varies rom year to
year, we created even, synchronous oviposition events by inesting plants with Manduca spp. larvae
either rom a lab-reared culture or rom wild collections (see Manduca spp. eggs and larvae). Larvae
used or plant inestations were placed as neonates on a rosette or lower stem lea at a standardized
position or each assay, and monitored mornings and evenings, during times outside o the main
period oGeocorisspp. activity that occurs at midday. Plants in feld experiments were either inested
with Manduca spp. larvae as described above, or let uninested (control). There were our inestationsover both years o the experiment, denoted M1-M4 in Figure4.
For measuring headspace GLVs in the feld and or glasshouse assays, plants were treated with
wounding and M. sexta OS (W+OS) as a standardized method to mimic Manduca spp. eeding. Pure
OS collected rom ourth to fth instar M. sexta larvae rom the Jena colony ed on WT plants was
diluted 1:5 with distilled water beore use; even 1000-old diluted OS is still sufcient to cause most
OS-elicited responses (Schittko et al., 2000). For feld-grown plants, a similar, mature, non-senescent
lea was chosen rom each plant; or glasshouse-grown plants, the two adjacent older leaves (nodes
+1, +2) to the lea undergoing a source-sink transition (node 0) on rosette-stage plants were used o
PIand LOX2transcript quantifcation, and the +2 node o a separate set o bolting plants was used o
Video 1. On-plant assay, plant 7u, irPI, June 18, 2011.
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end o each run. The GC was programmed as
ollows: injector held at 250C, initial column
temperature at 40C held or 5 min, then ramped
at 5C/min to 185C and fnally at 30C/min to
300C, held or 0.17 min. Helium carrier gas was
used and the column ow set to 1 mL/min
Compounds eluted rom the GC column were
transerred to the MS or analysis. The MS was
programmed as ollows: transer line at 250Ctrap temperature 110C, maniold temperature
50C, source heater 200C and scan range rom
40 to 399 m/z at 1.33 spectra per second as pre-
viously described (Schuman et al., 2009). The
identifcation o compounds was conducted by
GC retention time compared to pure standards
and mass spectra compared to standards and
mass spectra databases, Wiley version 6 (Wiley) and NIST (National Institute o Standards and
Technology) spectral libraries.
For the quantifcation o GLV pools in lea tissue rom feld-grown plants, the hexane extraction
protocol was adjusted based on GC-MS results rom pooled samples (described above), and a GC-FID
with a wax column was used or the quantitative analysis o extracts. Hexane (300 L) were added to
50 mg tissue (N=10) spiked with 15 g (Z)-hex-3-enyl acetate, a GLV not ound in GC-MS samples, as
an IS. The extraction proceeded as described above. Analytes were separated by Varian CP-3800
GC-FID connected to a ZB-Wax column (30 m0.25 mm i.d., 0.25 m flm thickness; Phenomenex). 1 L
o samples was injected by a CP-8400 autoinjector (Varian) onto the column in a splitless mode; the
injector was returned to a 1:70 split ratio 2 min ater injection through the end o each run. The GC was
programmed as ollows: injector held at 230C, initial column temperature at 40C held or 7 min, then
ramped at 5C/min to 115C and fnally at 30C/min to 250C, held or 0.5 min. Helium carrier gas was
used and the column ow set to 1 mL/min. Compounds eluted rom the GC column were transerred
to a Varian FID set at 250C or analysis (airow 300 mL/min, hydrogen 30 mL/min, nitrogen make-up
gas 5 mL/min). Individual volatile compound peaks were quantifed by peak areas using MS Work
Station Method Builder and Batch Report sotware (Varian) and normalized to the peak area o the IS
(Z)-hex-3-enyl acetate in each sample. Peak identifcation and quantifcation was done by comparison
to standard curves o pure compounds in hexane. Compounds present in quantifable amounts were(Z)-hex-3-en-1-ol, (E)-hex-2-enal and the IS (Z)-hex-3-enyl acetate.
Relative quantication o GLVs and (E)--bergamotene in the plantheadspaceFor measurement o GLVs in the headspace o feld-grown plants, intact leaves were harvested (N=3
and kept resh by placing the petioles in microcentriuge tubes flled with water. Immediately beore
each measurement, one lea was treated with W+OS, and a 1 cm2 disc was stamped out and placed in
a 4 mL GC vial. Ater 15 min, the headspace in the vial was measured with a ZNose 4200 portable gas
chromatograph with a 1 m DB5 column (Electronic Sensor Technology, Newbury Park, CA, USA) by
inserting the ZNose inlet needle through the septum o the GC vial into the headspace. The program
was as ollows: valve set at 165C, inlet at 200C, trap at 250C; 30 s sampling time, column ramped
rom 30C to 190C at 4C/s, data collection or 20 s. Genotypes were analyzed in an alternating orde
within each replicate: frst replicate 1 o all genotypes, then replicate 2, then replicate 3. Retentiontimes o GLV aldehydes and alcohols, the most abundant GLV headspace components, were deter-
mined using pure standards.
For the analysis o GLVs in the headspace o glasshouse-grown plants, the +2 lea was enclosed
immediately ater W+OS elicitation in a ood-quality 50 mL plastic container (Huhtamaki) with an acti
vated charcoal flter attached to one side or incoming air, and connected to sel-packed Poropak Q fl-
ters containing 20 mg o Poropak (Sigma-Aldrich) packed with silanized glass wool and Teon tubing
in the column bodies (ARS, Inc.) as previously described (Halitschke et al., 2000; Schuman et al.
2009). Ambient air was pulled by vacuum pump or 3 hr through an activated charcoal flter, over the
lea in the trapping container, and through a Poropak Q flter connected by PVC tubing (Rotabilo) to a
Video 3. O-plant assay, replicate 3, irPI, June 24, 2011.
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custom-made valve maniold, as previously
described (Schuman et al., 2009); the maniold
was adjusted such that ow rates through traps
were ca. 300 mL/min. Ater trapping, sampled
leaves were excised at the base o the petiole
scanned, and the lea area was measured in
comparison to a 1 cm2 standard (SigmaScan
5.0; Systat Sotware Inc.) or normalization o
volatile emission to cm2 lea area. Poropak Qflters were wrapped in aluminum oil and
stored at 20C until elution o volatiles with
250 L dichloromethane (Sigma-Aldrich).
Immediately prior to elution, each flter was
spiked with 320 ng o tetralin internal standard (IS
in hexane (Sigma-Aldrich). Filters were eluted into a
GC vial containing a 250 L glass insert. Samples
were analyzed by a CP-3800 GC Varian Saturn 2000 ion trap MS (Varian) connected to a polar
ZB-wax column (30 m0.25 mm i.d., 0.25 m flm thickness; Phenomenex). 1 L o samples was injected
by a CP-8200 autoinjector (Varian) onto the column in a splitless mode; the injector was returned to a 1:70
split ratio rom 2 min ater injection through the end o each run. The GC was programmed as ollows:
injector held at 230C, initial column temperature at 40C held or 3 min, then ramped at 5C/min to
180C and fnally at 10C/min to 240C, held or 1 min. Helium carrier gas was used and the column ow
set to 1 mL/min. Eluted compounds rom the GC column were transerred to the MS or analysis. The MS
was programmed as ollows: transer line at 230C, trap temperature 150C, maniold temperature 80C
and scan range rom 40 to 399 m/z at 1.33 spectra per second as previously described (Schuman et al.
2009). Individual volatile compound peaks were quantifed by peak areas o two specifc and abundant
ion traces per compound using MS Work Station Data Analysis sotware (Varian) and normalized by the
104+132 ion trace peak area o the IS (tetralin) in each sample. The identifcation o compounds was con
ducted by GC retention time compared to pure standards and mass spectra compared to standards and
mass spectra databases, Wiley version 6 (Wiley) and NIST (National Institute o Standards and Technology
spectral libraries. In 3 hr headspace samples we detected (Z)-hex-3-en-1-ol, (Z)-hex-3-en-1-ol, (E)-hex-2
en-1-ol (orms rom (E)-hex-2-enal on flters over trapping periods longer than 20 min), (Z)-hex-3-eny
acetate, (Z)-hex-3-enyl butanoate, (Z)-hex-3-enyl isobutyrate, and (Z)-hex-3-enyl propanoate.
The collection o (E)--bergamotene rom the headspace o glasshouse-grown plants and its extraction rom Poropak Q flters was carried out as or GLVs, except that (E)--bergamotene was collected
2432 hr ater W+OS treatment o the lea. Eluted samples were analyzed by an HP 6890 GC-5973
quadropole MS (Hewlett-Packard) connected to a nonpolar DB-5ms column (30 m0.25 mm i.d., 0.25 m
flm thickness; Agilent). 1 L o samples was injected by a HP 7683 autoinjector (Hewlett-Packard
onto column in a splitless mode; the injector was purged at 50 mL/min 1.5 min ater injection and
switched to gas saver mode (20 mL/min) rom 10 min through the end o each run. The GC was pro
grammed as ollows: injector held at 230C, initial column temperature at 40C held or 2 min, then
ramped at 5C/min to 165C and fnally at 60C/min to 300C, held or 2 min. Helium carrier gas was
used and the column ow set to 2 mL/min. Eluted compounds rom GC column were transerred to
the MS or analysis. The MS was programmed as ollows: source at 230C, quad temperature 150C
and scan range rom 33 to 350 m/z at 4.49 spectra per second. (E)--Bergamotene was quantifed by
peak area using the ion trace 119 m/z in Chemstation sotware (Agilent) and normalized by the 104 ion
trace peak area o the IS (tetralin) in each sample. The identifcation o (E)--Bergamotene and tetralinIS was conducted by GC retention time and mass spectra compared to mass spectra o known standards
as previously described (Schuman et al., 2009).
Manducaspp. bioassaysOne or two larvae were placed on plants at a time or each assay, depending on the number available
and were equally distributed among plants as described under Manduca spp. inestation and W+OS
treatment o plants. However, or inestation M3 (Figure4), we staggered the inestation o dieren
plant genotypes to accommodate dierences in plant growth: WT and irPIplants were initially large
and thereore went into the feld on average earlier than irLOX2and hemi-irLOX2plants, so that al
Video 4. O-plant assay, replicate 3, irPI, June 24, 2011.
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plants were planted at a similar size, which is important or even establishment. We thereore re-inested WT and irPIplants earlier ater M1, to allow irLOX2and hemi-irLOX2plants to catch up in
their growth to WT and irPIbeore re-inestation. However, we then let M. sexta larvae on irLOX2and
hemi-irLOX2as long as on WT and irPI, and we used a combination oGeocorisspp. counts and addi
tional predation assays to make sure that dierences in Geocorisspp. predation were not due to
this staggering o inestation (see Results: Geocorisspp. preerentially predate rom GLV-perumed
or -emitting plants).
Manduca spp. behavior, predation, and growth assays were conducted with frst- and second-insta
larvae, except inestations M1 2010 and M4 in 2011, in which larvae were reared rom the frst through
fth instars on plants; and egg predation assays, in which M. sexta eggs were used.
Larvae used in the o-plant mock predation assays were hatched on the appropriate N. attenuata
genotype (WT or irPI) and hatching was monitored three times per day (morning, noon, evening) so
that the mock predation assay could be timed to 48 hr ater larvae hatched. A protocol o the mock
predation assays is given in Figure 10, and Videos 14depict on-plant (1 and 2) and o-plant (3 and 4)behavioral assays. Larvae or o-plant mock predation assays were kept in aerated plastic boxes on cut
leaves over moist paper towels. Leaves were rereshed twice daily and were kept resh by placing the
petioles in water in 1.5 mL microcentriuge tubes which were closed around the petiole with
Paraflm (Pechiney Plastic Packaging Company). Larval growth was measured as increases in body
length (in millimeters) using calipers or a small, exible, transparent plastic ruler.
Predation assaysPredation rates were recorded or larvae placed on plants as described above, or or two eggs per
plant fxed with droplets o-cellulose glue (Kessler and Baldwin, 2001) to the underside o a rosette
or lower stem lea at a standardized position. For egg predation assays, a wild Manduca spp. larva
was enclosed on a nearby lea to ensure continual GLV emission: a clip cage was closed around the
larva to make it inaccessible to Geocoris spp. predators. Predation was monitored mornings and
evenings. Larvae were considered to be predated when either the larva was missing over multipledays, but clear Manduca spp. eeding damage was present, or when the predated larval carcass was
ound (Figure 5). Mortality was defned as the total number o missing larvae. Eggs were considered
predated when the eggshell was empty but intact except or a small hole which characterizes the
typical damage caused by Geocorisspp. eeding; eggs occasionally collapse during Geocorisspp
predation, but collapsed eggs were not counted unless the eggs were mostly or ully empty and with
a visible hole (Figure 5).
GLV supplementationDuring inestation M2, GLVs were added back to irLOX2and hemi-irLOX2headspaces by placing a
cotton swab adjacent to the M. sexta-inested lea and adding ca. 20 L o lanolin paste, measured
with a seed spoon, containing a mix o pure GLVs representative o the M. sexta-ed headspace and
dissolved in hexane (Table1) (Allmann and Baldwin, 2010) to the cotton swab. Cotton swabs bearing
ca. 20 L o lanolin paste with hexane as a control were placed next to M. sexta-inested leaves o WTand irPIplants. Lanolin pastes were regularly rereshed by adding 20 L in the early aternoon and in
the morning. Placing GLVs next to, rather than on the lea ensured that the supplemented headspace
would not be altered by plant metabolism, and that we could terminate the supplementation by
removing the cotton swabs.
Geocorisspp. countsField plots were monitored daily or Geocorisspp. presence during the experiments in 2010 and
2011; both G. pallensand G. punctipeswere present in 2011, but most individuals observed on
and around plants were G. pallens. Soon ater the frst Geocorisspp. sightings in May 2011 (beore
Table 4. Primers used or quantitative PCR (SYBR Green)
Gene Forward primer sequence (5-3) Reverse primer sequence (5-3) Citation
PI TCAGGAGATAGTAAATATGG ATCTGCATGTTCCACATTGC Fragoso et al. (2011)
LOX2 TTGCACTTGGTGTTTGAGATGGT TTAGTAGAAAATGAGCACCACAA Kallenbach et al. (2010
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the frst inestation, M2), Geocorisspp. populations in the immediate vicinity o experimenta
plants were monitored every 23 days by counting individuals. Counts were conducted during the
main period oGeocorisspp. activity in the early aternoon, by at least two observers in parallel,
in order to complete the count around all Manduca spp.-inested and control plants within 2030 min
Each observer proceeded by looking at a ocal plant and its immediate vicinity or 15 s and then
quickly inspecting the rosette leaves; all Geocoris spp. adults and nymphs seen on, under, or
within 5 cm around the rosette o the plant during this time were counted. Observers moved in
synchrony with each other rom one end o the feld plot to the other, in this way counting preda
tors around plants which had not yet been disturbed.
Plant growth and reproductionPlant size (rosette diameter, stem length and branching) was monitored at the end o inestation M1 in
2010 and rom the beginning o inestation M2 in 2011 (Figure4): rosette diameter was measured as
the maximum diameter ound by gently laying a ruler over the rosette; stem length was measured rom
the base o the stem to the tip o the apical inorescence by placing a ruler beside the stem; and al
side branches 5 cm or longer were counted. Reproductive output was monitored by counting the
number o closed owers removed every 23 days (beore they opened) rom the beginning o ower
ing, and by counting numbers o closed owers and buds 2 mm or larger at the end o inestation M1
in 2010, and during all inestations in 2011. All growth and reproduction data were analyzed or dier
ences in control versus M. sexta-inested plants within each genotype (statistics Table 3). Because
size-matched plants had been planted over one week in 2011, growth and reproduction data rom
plants in 2011 were organized by the number o days since planting or comparison between geno
types (Figure 6).
Removal o fowers during inestations M1 and M3, and o reproductivemeristems prior to inestation M4Flowers were removed and counted periodically over the frst 10 days o inestation M1 and during
inestation M3 (Figures 4 and 6, statistics Table3), in order to track plant reproduction while avoiding
ripe seed capsules: the distribution o ripe seed is not permitted or genetically modifed plants. Fo
inestation M4 in 2011 (Figure4), instead o regularly removing owers, we removed all reproductive
meristems by cutting inorescences, which contained mostly buds, at their base, so that we would be
able to ollow a new set o reproductive meristems through to seed set without incurring ripe seed
Because plants were matched prior to M4 and had the same number o buds and o side branches
(which usually terminate in inorescences) (Figure 8, see Discussion), all plants were similarly aectedby the removal o reproductive meristems.
Herbivore damage and plant healthPhotographs were taken o entire plants and M. sexta-damaged leaves during inestations M2 and M3
in 2011. Damage caused by M. sexta larvae was rated rom photographs by an independent observe
with no knowledge o plant identity. Total percent canopy damage due to M. sexta was rated as 1, 2
3, or 4 using the damage index in Figure 7.
We monitored herbivore attack to determine whether GLV-silenced plants suered dierent
amounts o herbivore damage, which could inuence ftness measurements. The naturally occurring
herbivore community on plants in 2010 and 2011 comprised mirids (Tupiocoris notatus) and noctuid
larvae; in 2011 grasshoppers (Trimerotropisspp.) and ea beetles (Epitrixspp.) were also present
Total canopy damage due to herbivores occurring naturally on the feld plot was quantifed prior to
the inestations in 2010 and 2011 and again during inestation M3 in 2011. Damage was calculatedby identiying damage rom specifc herbivores according to their characteristic eeding patterns,
counting the number o leaves per plant (small leaves were counted as 1/5 to 1/2 o a lea based on
lea area and large leaves were counted as 1 lea), estimating the total percentage o lea area dam-
age due to each herbivore, and dividing the total lea area damage rom each herbivore by the tota
number o leaves. Lea area damage was estimated in categories o 1%, 5%, 10%, 15%, and so on,
in steps o 5%. All such damage estimates were made by MCS or KB, who frst practiced quantiying
damage together until they consistently arrived at the same numbers.
As part o matching plants prior to inestation M4 in 2011, plant health was rated on a scale o 1
(dead) to 5 (healthy) using the index in Figure 7.
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Statistical analysesFishers exact tests were conducted using a macro (J H Macdonald, http://udel.edu/~mcdonald
statfshers.html) or Excel (Microsot). All other statistical analyses were conducted with SPSS 17.0 (IBM)
Count data were analyzed either by Fishers exact tests (independent values) or by Friedman tests
(repeated measures). Levenes test or homogeneity o variance was perormed prior to all t-tests and
ANOVAs and when necessary, data were log2 transormed (volatile and transcript data), square root
transormed (count data) or arcsin transormed (herbivore damage data) to meet requirements o
homogeneity o variance. Parametric data were compared using ANOVAs, MANOVAs, or repeated-
measure ANOVAs ollowed by Schee post hoctests. I variance was not homogeneous ollowing trans-
ormation, data were compared using Kruskal-Wallis tests (or multiple comparisons) or Mann-Whitney
U-tests (or two-way comparisons) and Bonerroni p-value corrections were used to correct or nonpara
metric multiple comparisons. For Kruskal-Wallis tests and Mann-Whitney U-tests, a Monte Carlo algo
rithm was used with 10,000 permutations and a 95% confdence level.
AcknowledgementsWe thank S Allmann or conducting egg predation assays in 2010; C Diezel, M Erb, M Kallenbach
D Kessler, D Marciniak, M Stanton, and A Steppke or help with feld work; S Weigl or rating M. sexta
damage levels; J Gershenzon or the use o the HP GC-MS; M Erb, J Gershenzon, D Heckel,
M Kallenbach, A Kessler, A Steppke, and A Weinhold or comments on the manuscript; Brigham Young
University or the use o their Lytle Preserve feld station; and APHIS or constructive regulatory
oversight.
Additional inormationCompeting interests
ITB: Senior Editor, eLife. The other authors have declared that no competing interests exist.
Funding
Funder Author
Max Planck Society Meredith C Schuman,Kathleen Barthel,Ian T Baldwin
The under had no role in study design, data collection and
interpretation, or the decision to submit the work or publication.
Author contributions
MCS, Conception and design, acquisition o data, analysis and interpretation o data, and drating o
revising the article; KB, Conception and design, acquisition o data, analysis and interpretation o
data, and drating or revising the article; ITB, Conception and design, acquisition o data, analysis and
interpretation o data, and drating or revising the article.
Author(s) Year Dataset title Dataset ID and/or URL
Database, license, and
accessibility information
Schuman MC, Barthel K, Baldwin IT 2012 Herbivory-induced volatilesunction as deensesincreasing tness o thenative plant Nicotianaattenuata in nature
http://dx.doi.org/10.5061/dryad.gs45
Available at Dryad DigitalRepository under a CC0Public Domain Dedication
Major datasets
The following datasets were generated
Additional les
http://dx.doi.org/10.7554/elife.00007http://udel.edu/~mcdonald/statfishers.htmlhttp://udel.edu/~mcdonald/statfishers.htmlhttp://dx.doi.org/10.5061/dryad.gs45fhttp://dx.doi.org/10.5061/dryad.gs45fhttp://dx.doi.org/10.5061/dryad.gs45fhttp://dx.doi.org/10.5061/dryad.gs45fhttp://udel.edu/~mcdonald/statfishers.htmlhttp://udel.edu/~mcdonald/statfishers.htmlhttp://dx.doi.org/10.7554/elife.00007 -
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