Tissue-Specific Localization of Pea Root Infection by Nectria haematococca. Mechanisms and Consequences

doi:10.1104/pp.104.056366

Tissue-Specific Localization of Pea Root Infection by Nectria haematococca. Mechanisms and Consequences¹

Uvini Gunawardena², Marianela Rodriguez, David Straney, John T. Romeo, Hans D. VanEtten and Martha C. Hawes^*

Division of Plant Pathology and Microbiology, Department of Plant Sciences, University of Arizona, Tucson, Arizona 85721 (U.G., M.R., H.D.V., M.C.H.); Department of Cell Biology and Molecular Genetics, University of Maryland, College Park, Maryland 20742 (D.S.); and Department of Biology, University of South Florida, Tampa, Florida 33620 (J.T.R.)

ABSTRACT

TOP
ABSTRACT
RESULTS
DISCUSSION
CONCLUSION
MATERIALS AND METHODS
LITERATURE CITED

Root infection in susceptible host species is initiated predominantlyin the zone of elongation, whereas the remainder of the rootis resistant. Nectria haematococca infection of pea (Pisum sativum)was used as a model to explore possible mechanisms influencingthe localization of root infection. The failure to infect theroot tip was not due to a failure to induce spore germinationat this site, suppression of pathogenicity genes in the fungus,or increased expression of plant defense genes. Instead, exudatesfrom the root tip induce rapid spore germination by a pathwaythat is independent of nutrient-induced germination. Subsequently,a factor produced during fungal infection and death of bordercells at the root apex appears to selectively suppress fungalgrowth and prevent sporulation. Host-specific mantle formationin response to border cells appears to represent a previouslyunrecognized form of host-parasite relationship common to diversespecies. The dynamics of signal exchange leading to mantle developmentmay play a key role in fostering plant health, by protectingroot meristems from pathogenic invasion.

Root-infecting fungal pathogens are a perennial threat to cropsworldwide. Crop loss results from direct damage to root systemsas well as increased susceptibility to other stresses (Bruehl,1986

). Soilborne fungi that cause disease are dispersed as sporesor sclerotia, which remain in a quiescent state until the appearanceof a host plant stimulates germination (Katan, 1996

). Becausethe initiation of infection depends on signals that induce sporegermination, such signaling comprises a potential target fordisease control (Deacon, 1996

). Significant progress has beenmade in defining signal exchange between root exudates and rhizospherebacteria (VanBrussel et al., 1990

; Steele et al., 1999

; Endreet al., 2002

; Loh et al., 2002a

, 2002b

; Ferguson and Mathesius,2003

; Hirsch et al., 2003

; Limpens and Bisseling, 2003

). Rhizobium-legumesymbioses appear to share common elements with infection byvesicular arbuscular mycorrhizal fungi, including recognitionthrough flavonoid signals (e.g. Nair et al., 1991

; Tsai andPhillips, 1991

; Harrison and Dixon, 1993

; Hirsch and Kapulnik,1998

; Garcia-Garrido and Ocampo, 2002

To date, however, our understanding of signal exchange betweenroots and soilborne pathogenic fungi remains in its infancy(Nelson, 2004). Both seed and root exudates can stimulate sporegermination (Curl and Truelove, 1986; Nelson, 1991). Nutrientssuch as sugars and amino acids leaking from roots have beenpresumed to serve as nonspecific signals for germination becausesuch compounds are present in root exudates and also can stimulategermination under controlled conditions (Parkinson, 1955; Lockwood,1988). If it is true that metabolites common to all plants stimulategermination of diverse fungi, then the potential for controllingdisease by manipulating the plant's delivery of signals thatinduce fungal growth may be limited.

Under a variety of conditions, the carbon-rich material collectedas exudates is released predominantly at the root apex (e.g.McDougall and Rovira, 1970; Van Egeraat, 1975; Griffin et al.,1976). This material is composed of border cells, mucilage,and soluble compounds released by border cells and/or the roottip (for review, see Hawes et al., 1998, 2000, 2003). The rootapex also is the principal source of key signals in root-microbesymbioses (Peters and Long, 1988; Nagahashi and Douds, 2004).The concentration of Bradyrhizobium japonicum nodulation geneinducing flavonoids in the 1-mm root tip of soybean seedlings,in fact, is 10-fold higher than any other part of the plant(Graham, 1991). Yet, paradoxically, the root tip seldom is infectedor colonized (Foster et al., 1983; Lagopodi et al., 2002). Instead,infection by microbial pathogens and symbionts generally isinitiated just behind the root apex, in the zone of elongation(e.g. Bauer, 1981; Bruehl, 1986; Balu $s$ ka et al., 1996). Thisregion where newly generated cells from the apical meristemundergo rapid elongation has been defined as the mycorrhizalinfection zone to reflect its susceptibility to infection bymycorrhizal fungi (Brunner and Scheidegger, 1992). The regionof elongation also is the primary site of infection by fungalpathogens (Fig. 1). The reasons why this site is highly susceptible,while newly generated cells within root tips escape infection,has received little attention.

View larger version (64K):
[in this window]
[in a new window]

Figure 1. Localized infection by N. haematococca in the (A) apical and root cap meristem (visualized with trypan blue, which stains dead cells), (B) maturation zone, (C) elongation zone/FIZ, (D) border cells, and (E) root cap. F, Dispersal of border cell mantles along the length of an inoculated root as it grows. Arrows (and inset) indicate clumps of border cells supporting fungal growth. G to I, Cross section of root apex (apical meristem, root cap meristem, root cap body) after removal of border cells from uninoculated control seedlings (G), after removal of border cell mantles from inoculated root with infection into peripheral root cap (H), and after removal of border cell mantles from a root tip infected throughout the root cap and apical meristem (I). Arrows indicate individual fungal hyphae.

Pea (Pisum sativum) has been an important experimental modelfrom the time of Mendel and Darwin, and remains among the world'smost important food crops. Nectria haematococca mating populationVI (Fusarium solani f. sp. pisi) has served as a long-standingmodel for aspects of pea root infection (Chi et al., 1964

; Cookand Flentje, 1967

; deWit-Elshove and Fuchs, 1971

; Kraft, 1974

;Loria and Lacy, 1979

; VanEtten et al., 1980

; Stahl et al., 1994

).Spores of this fungus, which causes foot and root rot, germinatewithin 24 h in a 7-mm radius of a germinating seed (Short andLacy, 1974

). Glc and amino acids, which are present in pea rootexudate and can induce spore germination, have been proposedto comprise the plant signals triggering germination (Schrothet al., 1963

; Ayers and Thornton, 1968

; Short and Lacy, 1976

).Spore germination also is induced by specific flavonoids andisoflavonoids (Ruan et al., 1995

). These metabolites commonlyare found in root exudates of legumes (d'Arcy-Lameta, 1986

;Maxwell and Phillips, 1990

; Cooper and Rao, 1992

; Recourt etal., 1992

; Wojtaszek et al., 1993

; Tsanuo et al., 2003

). Flavonoid-inducedspore germination is partially blocked by H89, a cAMP-dependentinhibitor of protein kinase A. Root exudate-induced spore germinationwas found to occur by two independent mechanisms, the flavonoid-responsivepathway that is inhibited by H89 and a nutrient-responsive pathwaythat is impervious to H89 (Ruan et al., 1995

). This discoveryprovides an experimental framework to compare the role of nonspecificgermination stimulators like sugars and amino acids versus specificcompounds released by roots of host plants, in the early stagesof root-microbe recognition and response.

Previously, we presented evidence consistent with the hypothesisthat root tips are protected from fungal infection by the productionof root border cells (Gunawardena and Hawes, 2002; Woo et al.,2004). In this study, we used N. haematococca and pea as modelsto examine the possibility that differential spore germination,pathogenicity gene expression, or defense gene expression isresponsible for localized root infection. Instead, we observedthat infection by N. haematococca induces border cell deathin correlation with development of a factor that selectivelyinhibits fungal growth.

RESULTS

TOP
ABSTRACT
RESULTS
DISCUSSION
CONCLUSION
MATERIALS AND METHODS
LITERATURE CITED

Despite Formation of a Mantle of Hyphae at the Root Tip, Infection of Host Roots by Pathogenic Fungi Occurs in the Zone of Elongation and Root Tips Remain Uninfected

Radicles (length 2.5 cm) were inoculated uniformly with sporesand transferred to cellophane growth pouches. Visible lesionsdeveloped 3 d after inoculation with N. haematococca strain34-18 (Funnell et al., 2001), containing the conditionally dispensable(CD) chromosome with pea pathogenicity genes (PEP; Han et al.,2001; Funnell et al., 2002). Under the conditions used, infectionat the cotyledonary attachment site (foot root) occurred in15% ± 8% of inoculated seedlings (data not shown). Onthe root, visible lesions that encompassed and killed cellswithin the root cap and apical meristem were rare (Fig. 1A).Lesions developed in the maturation zone only when it was wounded(Fig. 1B). On most roots, a tan lesion developed within thesite where the elongation zone had been, at the time of inoculation(Fig. 1C). This site, which corresponds to the mycorrhizal infectionzone (Brunner and Scheidegger, 1992), therefore is referredto as the fungal infection zone (FIZ) to reflect its susceptibilityto pathogenic as well as symbiotic fungi. The presence of lesionsin the FIZ was not correlated with negative effects on growthand development; 1 week after inoculation, mean root length,shoot height, and number of lateral roots for 225 control and200 infected plants, respectively, were 174 ± 15 and180 ± 20 mm, 52 ± 14 and 54 ± 9 mm, and21 ± 4 and 25 ± 6 per root.

Most plants (>90%) also developed mantles of hyphae supportedby growth on border cells (Fig. 1D). Despite being covered infungal hyphae, visible lesions in the root cap were rare (Fig. 1E).When lesions developed at the cap periphery, cap turnoverwas induced and mantles detached and were dispersed along thelength of the root as it grew (Fig. 1F, arrows); at higher magnification,a nucleus of border cells could be seen within each mantle (Fig. 1F,inset, arrow). In roots with lesions confined to the rootcap periphery (as in Fig. 1E), the cellular structure of theroot cap (Fig. 1H) was comparable to that of control root caps(Fig. 1G). By contrast, visible lesions throughout the apex(as in Fig. 1A) were associated with disintegration of cellularorganization, and fungal hyphae could be seen throughout thetissue (Fig. 1I, arrows).

The same results were obtained with four pea cultivars (EarlyFrosty, Lincoln, Progress 9, and Green Arrow) as well as alfalfa(Medicago sativa) inoculated with N. haematococca 34-18, andon cv Little Marvel in response to other pea pathogens, includingPhoma pinodella (L.K. Jones) T409, Mycosphaerella pinoides (Berk.& Bloxam) T417, Thielaviopsis basicola, and nine differentisolates of N. haematococca (data not shown). In each case,nearly all roots developed lesions in the FIZ but not withinthe root tip, despite the presence of mantles on root caps (asin Fig. 1D). In response to inoculation of Little Marvel withN. haematococca strains 94-2-4 and 44-100, which lack the CDchromosome, mantles that formed were smaller than those producedby other strains, and 50% ± 7% of inoculated seedlingsfailed to develop a visible lesion in the FIZ. The non-pea pathogenicstrain of T. basicola did not induce any lesions or mantleson roots of pea seedlings, and no mantles or lesions developedin response to N. haematococca 34-18 on roots of nonhost species,including wheat, cotton, soybean, cucumber, pumpkin, or corn(data not shown).

Root Tip Escape from Infection: Spore Germination at the Root Tip

Exudates Stimulate Rather Than Inhibit Spore Germination
One hypothesis to explain how fungus-covered root tips avoidinfection is that border cells and associated mucilages forma physical barrier to prevent contact between infective propagulesand the root cap periphery. No evidence for physical exclusionwas found (Fig. 2). A second possibility, that spores fail togerminate at the root tip region, was explored. Spores (10⁵/mL)added to pea roots began to germinate within 1 h, and >90%had germinated within 2 h. Washed border cells alone were equallyeffective (Table I). The presence of the CD chromosome did notinfluence the rate of germination. No significant germinationoccurred in water over a 6-h period.

View larger version (132K):
[in this window]
[in a new window]

Figure 2. Germination of N. haematococca spores in situ, in response to root cap and border cell exudates. After immersion of root tips into a suspension of spores at 10⁵/mL, spores start to germinate within 1 h (arrows). Inset, Left, At 10⁶ spores/mL, chlamydospore formation occurs. Inset, Right, Fungal hyphae grow around border cells without apparent penetration.

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

Table I. Stimulation of spore germination by pea root cap and border cell exudates^a

Bulk exudate or border cells alone, when separated from theroot, induced maximum spore germination (Table II). At 10⁴ spores/mL,100% germination occurred within 1 h. Germination was reducedat higher spore concentrations, presumably due to endogenousgermination inhibitors (e.g. Bruehl, 1986

). At 10⁶ spores/mL,germination decreased to 72% ± 8%, and chlamydosporeformation was induced (Fig. 2, inset left); adding Glc (2.5mg/mL) to the medium did not increase germination or suppresschlamydospore formation (data not shown). At 10⁷ spores/mL,no germination occurred (Table II).

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

Table II. Dosage response for root cap and border cell exudate stimulated germination of N. haematococca 34-18 spores

The data represent mean values from three different trials each of which contained two replicates.

The Nature of the Spore Germination Stimulant
The germination stimulation activity was stable to freezingand boiling for 30 min and, in preliminary tests, was retainedin the water phase when exudates were extracted with organicsolvents (data not shown). One candidate for the activity thereforeis amino acids present within root exudates (Bruehl, 1986

; Phillipset al., 2004

). Total dry weight of root cap and border cellexudates, after separation from the root and border cells, was17.3 µg per root. Sixteen of 20 protein amino acids plusthe non-protein amino acid ${gamma}$ -aminobutyric acid were present,at a total amino acid concentration of >1.2 µg perroot. Levels of individual amino acids, in picograms per root,were as follows: Asp, 360; Thr, 101; Ala, 118; Val, 80; Met,10; Ile, 45; Leu, 60; Tyr, 62; His, 190; Arg, 85; and ${gamma}$ -aminobutyricacid, 140. Ser, Glu, Gly, Cys, Phe, and Trp were present intrace amounts. When protein amino acid ratios were reconstitutedin water and mixed with N. haematococca spores, no germinationoccurred over a 6-h period (Table III). Therefore, amino acidsdo not appear to account for the rapid germination stimulationby root cap and border cell exudates.

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

Table III. Inhibition of root cap and border cell exudate-stimulated spore germination by the protein kinase A inhibitor H89^a

To determine whether exudate-induced germination occurs viathe nutrient- or the flavonoid-responsive pathway (Ruan et al.,1995

), the protein kinase A inhibitor H89 was used. When assayedin growth media, Glc-Asn, or minimal medium with Glc as theonly carbon source (M100 minimal medium), germination was unaffectedby H89 (Table III). By contrast, H89 completely inhibited exudate-inducedspore germination for at least 24 h, the longest time periodevaluated (Table III). Staining with the vital stain fluoresceindiacetate after 24 h exposure to H89 was indistinguishable fromthat of untreated spores, and when removed from H89 and platedonto growth medium, the conidia germinated and grew normally;this indicated that the inhibition of germination was not dueto loss of spore viability (data not shown).

Root Tip Escape from Infection: Expression of N. haematococca PEP Genes and Plant Defense Genes during Mantle Formation at the Root Tip

Expression of Fungal Pathogenicity Genes
One hypothesis to explain how root tips avoid infection is thathyphae fail to express PEP genes when growing on border cells.A strain expressing uidA encoding ${beta}$ -glucuronidase (GUS) underthe control of the pisatin demethylase (PDA) promoter was usedas a reporter system for PEP gene expression (Straney and VanEtten,1994). This promoter is induced during infection of pea andin response to pisatin (Fig. 3A). Incipient mantles were visibleon root tips within 24 h (Fig. 3B). At the same time, pisatin(15 µg/g tissue dry weight) was produced in the FIZ, butnone was detectable in the root tip (data not shown). Despitethe absence of detectable pisatin production, expression ofPDA-GUS was visible as blue hyphae within the mantles within24 h (Fig. 3B, arrow). In some cases, mantles failed to detachand PDA-GUS expression was maintained over several days (Fig. 3C).Expression of other PEP genes also was induced within 24h after inoculation of the root tip (Fig. 3D) and remained elevatedfor at least 60 h (data not shown).

View larger version (93K):
[in this window]
[in a new window]

Figure 3. Expression of PEP genes during early stages of mantle development. A, Expression of PDA-GUS in germinating spores exposed to pisatin; B, expression of PDA-GUS in border cell mantles 24 h post inoculation; C, expression of PDA-GUS in older mantle surrounding infected root tip; and D, expression of PEP5 (left) and PEP2 (right) genes of N. haematococca at time 0 and at 24 h after inoculation. Two-day-old seedlings containing a full set of border cells were inoculated with 10⁶ spores of N. haematococca, and RNA from root tips was recovered at specific time points after inoculation, as described in "Materials and Methods." A 100-bp ladder was used to establish agreement between expected size and actual size of fragments obtained by amplification of each gene.

Expression of Plant Defense Genes
An alternative mechanism for protecting the root tip is theinduction of defense pathways. In a previous study, when seedlingswere inoculated with spores from N. haematococca 34-18, chitinaseexpression in the FIZ increased within 24 h and remained elevatedthrough 72 h, but no such increase in expression occurred inthe root tip (Gunawardena and Hawes, 2002

). Because root tipsrarely develop lesions, the defense gene elicitor salicylicacid (SA) was used in this study to examine defense responsesin the root tip. At a concentration of 5 or 10 mM SA, chitinaseexpression in the FIZ was found to be comparable to that whichwas previously shown to occur in response to infection; thus,expression was induced by >3-fold in the FIZ after 24 h andremained elevated through 72 h (data not shown). Root growthin response to 5 or 10 mM SA, under the same conditions wasinhibited by 46% ± 6% (5 mM) and 64% ± 5% (10mM). As in roots inoculated with fungal spores, however, noincreased chitinase expression was observed in the root tipafter 24 h exposure to 5 or 10 mM SA. Only when earlier stageswere examined was increased expression found to occur in theroot tip, with a transient increase at 3 to 6 h (Fig. 4A). Despitecontinuous exposure to levels of SA that induced continuousdefense expression in the FIZ, expression in the root tip returnedto control levels within 8 h and remained low throughout a 72-hperiod of observation. These data suggest that molecular responsesto stress in the root tip are markedly distinct from those inthe FIZ.

View larger version (36K):
[in this window]
[in a new window]

Figure 4. Inverse relationship between expression of defense genes and cell cycle genes in root tips treated with SA at a level that inhibits root growth. Relative levels of (A) chitinase mRNA and (B) cyclin mRNA were normalized to actin as a control. Seedlings were grown in cellophane pouches in which SA was added at a concentration that resulted in approximately 50% inhibition of root growth; root lengths were measured nondestructively as by Bauer (1981)

before harvesting root tips for RNA-blot analysis, as by Gunawardena and Hawes (2002)

Expression of Cell Cycle Genes
The induction of defense pathways in some tissues is inverselycorrelated with expression of cell cycle-associated genes (Logemannet al., 1995

; Sommssich and Hahlbrock, 1998

). To examine thepotential impact of defense gene expression on cell cycle inroot meristems, total RNA isolated from root tips was probedwith four cell cycle-related genes during the early stages ofSA treatment when chitinase expression is induced. Histone 3,histone 4, and cdk expression was unaffected by SA (data notshown), but cyclin expression was reduced by >2-fold after3 h exposure to 10 mM SA (Fig. 4B). The reduced expression ofcyclin was transient and inversely correlated with chitinase.Thus, cyclin expression decreased as chitinase increased, andboth returned to normal at 8 h (Fig. 4, A and B). The same relationshipoccurred at 5 mM SA (data not shown). The failure to maintaindefense pathways during mantle formation, even under stresssufficiently severe to inhibit growth, would be predicted toleave the root tip especially vulnerable to infection.

Root Tip Escape from Infection: Development of a Fungal Growth Inhibitor

Border Cell Death during Mantle Formation
Unlike in root lesions or culture medium where sporulation beginswithin 24 h, fungus in mantles grew solely as hyphae and failedto sporulate even after 10 to 14 d (Fig. 1, D and F). Mantledevelopment was examined in detail to explore cell-cell interactionsbetween plant and pathogen. Within 18 h after inoculation, bordercell death occurred in a dosage-dependent manner in responseto pea pathogens, including N. haematococca, P. pinodella, andT. basicola (Table IV). In N. haematococca isolates 94-2-4 and44-100 lacking the CD chromosome, a 10-fold increase in inoculumwas required for border cell death to occur, and no significantcell death occurred in response to an isolate of T. basicolathat is not pathogenic on pea (Table IV). The mechanism of bordercell death was explored because direct penetration of bordercells by N. haematococca was not observed. Most appeared togrow around the cells and then spread to the other areas (Fig. 2,inset right). The possibility that a toxic factor is secretedby the fungus was assessed by challenging populations of bordercells with exudate collected from roots after inoculation withN. haematococca or from culture filtrates of N. haematococcagrown in M100 medium. No evidence was found for a toxin thatby itself, in the absence of the fungus, killed border cells.Contact between border cells and fungal cells appears to berequired for border cell death to proceed.

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

Table IV. Loss of viability in border cells from pea seedlings inoculated with spores of pathogenic fungi

For each concentration of spores, border cells from three seedlings were collected and viability was measured by staining with the vital stain fluorescein diacetate, as described in "Materials and Methods." Data represent mean values obtained from at least three independent trials.

Production of a Fungal Growth Inhibitor
Inhibition of fungal growth occurred in response to cocultivationwith border cells (Fig. 5). Whereas growth of fungus on bulkroot cap exudates was linear over the course of several days,growth on border cells ceased after 1 d. To determine whethernutrients were limiting or an inhibitor was produced, exudatewas collected from control seedlings or from seedlings inoculatedwith N. haematococca and differences in available sugar werecorrected by adding Glc. At 2 to 3 d after inoculation, a significantlyhigher rate of fungal growth occurred in exudate from controlversus inoculated roots (Fig. 6A). When the concentration ofexudate from inoculated seedlings was reduced by one-half, twiceas much growth occurred (P < 0.015), but no such increaseoccurred when exudate from control roots was diluted (P value0.237; Table V). The fungal growth inhibitor was effective againstother N. haematococca isolates, with or without the CD chromosome(Fig. 6B). By contrast, M. pinoides grew equally well in exudatesof control seedlings and those inoculated with N. haematococca,suggesting that the inhibitor is selective in its effects onfungal growth (Fig. 6C).

View larger version (17K):
[in this window]
[in a new window]

Figure 5. Differential growth of N. haematococca in root exudates (R.E.) compared with border cells. Spores were added to samples of border cells or bulk root cap exudate, and growth was monitored over the course of 3 d, as described in "Materials and Methods." Values represent means from four independent experiments, and SEs were less than 10% of the mean.

View larger version (14K):
[in this window]
[in a new window]

Figure 6. Inhibition of growth of N. haematococca in root exudates of inoculated seedlings. A, Spores (10⁵/mL) of N. haematococca 34-18 were added to samples of root exudate collected from control or inoculated seedlings, and growth was monitored over the course of 3 d, as described in "Materials and Methods." The difference in the growth was statistically significant for the growth in the second (P value 0.009) and the third day (P value 0.006) but not for the first day (P value 0.745). B, Growth of N. haematococca 94-2-4 in exudate from seedlings inoculated with strain 34-18 and collected as described in "Materials and Methods." Values for exudate from control or inoculated seedlings at day 2 and day 3 were statistically distinct at P < 0.05. C, Growth of M. pinoides in exudate from seedlings inoculated with N. haematococca strain 34-18 and collected as described in "Materials and Methods." Values were not statistically distinct at P < 0.05.

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

Table V. Presence of a fungal growth inhibitor in root cap and border cell exudate from inoculated roots: increased growth in response to dilution of exudate^a

	DISCUSSION

TOP ABSTRACT RESULTS DISCUSSION CONCLUSION MATERIALS AND METHODS LITERATURE CITED

The term rhizosphere was coined by Hiltner (1904)

based on hisrecognition that microorganisms grow in the immediate vicinityof roots and that these microbial communities impact plant health.Localized microbial growth in the rhizosphere occurs becausenutrient-rich materials are released from roots into the extracellularenvironment (Rovira, 1956

, 1959

; Harmsen and Jager, 1962

). Intensiveresearch therefore has been dedicated to defining microbialtraits that foster their ability to colonize this habitat (Rovira,1991

; Gilbert et al., 1996

; Dunn et al., 2003

). Surprisingly,however, despite a long-standing recognition that the plantgenotype is at least as important as microbial genotype in controllingrhizosphere community structure (e.g. Atkinson et al., 1975

;Curl and Truelove, 1986

), there never has been a correspondingemphasis on defining plant genes that control the compositionand release of root exudates (O'Connell et al., 1996

; Smithet al., 1999

In part, this omission has been based on a presumption thatmost exudation involves a continuous global release of sugars,amino acids, and other nutrients along the surface of the root,and that this mixture would be predicted to support growth ofmicrobial populations in a nonspecific manner (e.g. Bar-Yosef,1996). Available evidence from root systems grown in systemsranging from culture plates to hydroponics to native soil hasnever been in support of such a model (for review, see Haweset al., 2003). In most plant species, the bulk of carbon-richmaterial released from roots is programmed to separate at theapex of the root (e.g. McDougall and Rovira, 1970; Van Egeraat,1975). Most of the material, moreover, is packaged in livingcells (Knudson, 1919; Griffin et al., 1976; Vermeer and McCully,1982). As a root moves into regions where specific microorganismsare present, this mixture is the first source of signals tocontact dormant propagules in the soil. As with any living plantcell, however, the material contained within border cells isonly accessible to microorganisms that carry the genes neededto recognize and respond to those signals (Hawes et al., 1998,2000, 2003). The capacity of fungi and bacteria to recognizeand respond to other substrates in the form of mucilage, cellwall breakdown products, and other materials that detach alongwith border cells also appears to be species and genotype specific(Goldberg et al., 1989; Teplitski et al., 2000; Knee et al.,2001).

In this study, we observed strong host selectivity in germinationand mycelial growth in response to exudates from the root capand border cells. There was no mantle formation without a pathogenicfungus and susceptible host. Most important, spore germinationoccurred very rapidly by the same pathway as flavonoid-inducedgermination, and when this pathway was blocked, spores remainedin a quiescent state. Thus, availability of nonspecific metaboliteslike amino acids and sugars, shown previously to induce germinationof fungal spores, is not sufficient to induce germination andgrowth when the flavonoid-responsive pathway is blocked. Manipulationof specific genes in plant roots to control the release of factorscontrolling spore germination therefore might be predicted toprotect roots from infection by soilborne pathogens withoutnecessarily compromising symbiotic infection by beneficial bacteriaand fungi. If the factor is a flavonoid, for example, then localizedexpression of enzymes that modify their activity by glycosylationcould be used to test their role in germination (Hsieh and Graham,2001). Known flavonoids and isoflavonoids in the aglyone formare soluble in organic solvents, but the germination stimulantfrom pea did not exhibit this property. However, such productsfrequently occur in root exudates as water-soluble conjugates(e.g. Graham, 1991; Recourt et al., 1992). Moreover, H89 caninfluence activity of multiple targets, and it is possible thatmore than one pathway may be involved in synthesis of specificsignals that induce spore germination (Syin et al., 2001; Leemhuiset al., 2002).

Border cells appear to be a primary, if not the only, sourceof the germination stimulant. Thus, exudates released from bordercells alone induced germination as effectively as the mixtureof bulk root cap and border cell exudates. Soilborne pathogenicfungi can interact with border cells by several mechanisms (forreview, see Hawes et al., 1998, 2000). Zoospores of pathogenicPythium spp. exhibit genotype-specific chemotaxis to the bordercells of host species, then penetrate and cause cell death withinminutes (Goldberg et al., 1989). Host-specific toxins from pathogenicCochliobolus spp. kill border cells only in genotypes of oatsand corn carrying specific genes for susceptibility to the fungi(Hawes and Wheeler, 1982; Hawes, 1983). Border cells of corndevelop papillae, in a genotype-specific manner, in responseto infection by Colletotrichum graminicola (Sherwood, 1987).In this study, an additional mechanism appears to operate, inwhich cell-cell contact is needed for border cell death andalso for production of a substance that modulates fungal growth.Border cells of bean cultivars undergo hypersensitive cell deathin response to Pseudomonas phaseolicola strains carrying appropriateavirulence genes (M.C. Hawes, unpublished data), and a similarmechanism involving elicitation of programmed cell death mightoperate in response to fungal pathogenesis.

Ectomycorrhizal fungi and Fusarium oxysporum previously havebeen reported to associate and grow among border cells at theroot tip of host species during initial interaction with hostroots (Fusconi, 1983; Horan et al., 1988; Brunner and Scheidegger,1992; Turlier et al., 1994; Rodriguez-Galvez and Mendgen, 1995;Kroes et al., 1998). This was presumed to involve a saprophyticinteraction based on the incorrect notion that border cellsdie before detachment from the root, so no information is availableabout the mechanism of cell death. Nevertheless, the data suggestthat growth on border cells in early stages of contact is aphenomenon common to diverse fungi. Eighty percent of land plantsdevelop symbiotic associations with arbuscular mycorrhizal fungi,and this capacity is tightly correlated with production of bordercells; the small number of species that fail to develop suchassociations, including Arabidopsis (Arabidopsis thaliana),are the same species that fail to produce populations of livingborder cells (Niemira et al., 1996; Arriola et al., 1997). Arecent study has documented that a product from border cellsstimulates branching in the arbuscular mycorrhizal fungus Gigasporagigantea, which might in part explain this correlation betweenproduction of border cells and susceptibility to mycorrhizalinfection (Nagahashi and Douds, 2004).

CONCLUSION

TOP
ABSTRACT
RESULTS
DISCUSSION
CONCLUSION
MATERIALS AND METHODS
LITERATURE CITED

In summary, even under conditions highly conducive to disease(i.e. succulent young roots inoculated directly with thousandsof spores and maintained at warm temperatures in cellophanepouches), lesion development on unwounded roots is tightly localizedwithin the region of elongation. Our results are consistentwith the hypothesis that the root tip escapes infection by amultiphasic guarding effect of border cells that release signalsto stimulate spore germination then modulate hyphal growth.The result is to allow the establishment of a stable relationshipin which the fungus survives without damaging root function.Further research is needed to examine the possibility that havinga pathogen like N. haematococca established in the root-rhizosphereenvironment of its host, without causing disease, may actuallyprovide ecological benefits to the plant. As with symbioticbacteria and fungi, the capacity to live in close proximityand utilize resources of the plant without causing lesions thatinhibit growth and development could be advantageous to soilbornefungal pathogens.

MATERIALS AND METHODS

TOP
ABSTRACT
RESULTS
DISCUSSION
CONCLUSION
MATERIALS AND METHODS
LITERATURE CITED

Seedling Germination and Maintenance of Nectria haematococca Cultures

Pea (Pisum sativum) seeds were surface sterilized by immersionin 95% ethanol for 10 min followed by 30 min in 5% sodium hypochlorite(Brigham et al., 1998). Throughout a 6-h period of imbibitionin sterile water, seeds that floated were discarded. Remainingseeds were spread on germination paper overlaid on 1% wateragar and incubated at 24°C for 2 d in the dark.

Nectria haematococca (Berk. & Br) mating population VI,isolate 34-18, containing the CD chromosome with PEP genes wasused in most experiments (Funnell et al., 2001, 2002; Han etal., 2001). Other isolates were N. haematococca T2, T8, T23,T406, T547, SUF1111, and 77-13-4 that cause foot and root rotin pea (Delserone et al., 1999; Funnell et al., 2001); strains94-2-4 and 44-100, without the CD chromosome, which do not causefoot and root rot (Wassman and Van Etten, 1996; H.D. VanEtten,unpublished data); and pea pathogens Phoma pinodella (L.K. Jones)T409, Mycosphaerella pinoides (Berk. & Bloxam) T417, andThielaviopsis basicola D127 (Delserone et al., 1999; H.D. VanEtten,unpublished data). A non-pea pathogenic isolate of T. basicola,Smith Henson 2, a pathogen of tobacco, was used as a control.Isolates were maintained on V8 juice agar plates (medium 29;Stevens, 1974). For T. basicola cultures, 0.1% Glc was addedto the medium. The cultures were at least a week old when sporeswere harvested. The conidial suspension was centrifuged at 3,500gfor 1 min, washed once with sterilized water, and resuspendedin water. Spores were enumerated using a hemocytometer, andthe concentrations were adjusted to the desired values by dilutionwith water.

Root Infection Assays

Four seedlings with a radicle length of 2.5 cm were inoculatedwith spores, then inserted into a cellophane growth pouch (MegaInternational, Minneapolis) containing 15 mL of water, coveredto prevent drying, and incubated at 24°C in cellophane growthpouches for up to 10 d. Infection was evaluated by direct observationand/or plating onto medium to assess fungal growth, as described(Gunawardena and Hawes, 2002). For mantle formation and infectionby different fungal isolates, at least 15 seedlings for eachtreatment in at least three trials were included for each combination.

Collection of Root Cap and Border Cell Exudates

Root tips (approximately 1–2 mm of the root apex, includingthe root cap and apical meristem) of intact 2-d-old seedlingswith a radicle length of 2.5 cm were immersed in 1 mL of waterand washed by gently pipetting with water, as described (Zhuet al., 1997; Brigham et al., 1998). Border cells (approximately4,000 cells per root tip) were removed from the collected exudatesby centrifugation at 3,500g for 1 min and washed twice to removeall extracellular material. Root cap and border cell exudaterefers to the supernatant component obtained after this centrifugationstep.

To collect exudates and culture filtrates for border cell toxinassays, two sets of 50 seedlings (radicle length 2.5 cm) wereplaced on 1% water agar overlaid with germination paper. Eachseedling was inoculated with 50 µL of water containing0 or 10⁶ spores of N. haematococca applied to the radicle. Thetrays were covered and incubated at 24°C in the dark for24 h. Root tips of the inoculated versus control seedlings wereimmersed in 1 mL of water, and the tips were gently washed bypipetting water onto the tip. The resulting suspensions werepassed through a 0.2-µm filter, and a 500-µL samplewas distributed into each of six wells of a 24-well plate. Thesewere inoculated with 10⁶ spores of N. haematococca or waterper well. The plate was sealed with parafilm and shaken at roomtemperature for 24 h. The contents of the wells were pooled,centrifuged, and the supernatant filtered (0.2 µm) beforeassaying for toxicity. Culture filtrates were harvested fromfungal cultures grown 7 d in M100 minimal medium inoculatedwith 10⁶ spores/mL.

To collect exudates for fungal growth assays, control or inoculatedseedlings were processed as described above. After 24 h at 24°C,each seedling was inserted into a 5-mL glass test tube withthe root tip submerged in water, and incubated in the dark at24°C. After 24 h, the liquid was recovered, centrifugedat 3,900g for 5 min, and the supernatant frozen in 100- to 150-mLaliquots, lyophilized, and dissolved in 500 µL of water.Carbohydrate concentration in exudates was measured (Dische,1962), based on mean values of five independent batches of collectedroot exudates. Protein concentration was measured (catalog no.500-0006; Bio-Rad, Hercules, CA). The carbohydrate concentrationin root tip exudates of inoculated seedlings contained lesscarbohydrate (180 ± 15 µg/100 µL) than thatof the noninoculated seedlings (325 ± 25 µg/100µL), and Glc was added to equalize available sugar inthe two samples. Protein in exudates from inoculated seedlingswas increased to 145 ± 10 from 95 ± 10 in exudatesfrom uninoculated controls.

Spore Germination Assays

To evaluate germination, spores were added to exudate, bordercells, or culture medium in a 24-well microtiter plate in afinal volume of 400 µL. Replicate 10-µL sampleswere spotted onto a glass slide, and percent germination of200 to 300 spores was recorded. For all experiments, water wasused as a control. To evaluate dosage response, exudates from0, 2.5, 5, and 10 tips were contained in 400 µL of waterand mixed with varying concentrations of spores. H89 (catalogno. 371963; Calbiochem, San Diego) was dissolved in water andadded at a final concentration of 100 µM (Ruan et al.,1995).

Amino Acid Analysis and Assay

Free amino acid analysis was conducted with a Dionex model MBF/SSamino acid/peptide analyzer (Sunnyvale, CA) equipped with aGilson Spectra/GLo fluorometer (Middleton, WI) with wavelengthof excitation at 360 nm and emission at 455 nm. Exudate fromLittle Marvel pea (10.9 mg dry weight, collected from 650 roottips and separated from border cells as described above) wasloaded onto a 0.4- x 12.0-cm column packed with DC-5A cationexchange resin (Dionex) by a 10-µL calibrated injectionloop. The separated amino acids were subject to detection followingpost-column derivatization with o-phthaldialdehyde (OPA; Roth,1971). Peak identification and integration of peak areas wasperformed with Shimadzu C-R3A Chromatopac data processor/recorder(Columbia, MD). The peaks were identified by absolute retentiontime and quantified by peak area using a standard curve generatedfrom standards of known concentration by the least squares methodof linear regression. Amino acids were sequentially eluted fromthe column using six buffers of increasing pH in a constant0.2 M solution of Na⁺ cations. These buffers contained 2.0 gof NaOH (Gallard-Schlesinger AnalaR grade; Plainview, NY), 8.76g of NaCl (Gallard-Schlesinger AnalaR grade), 0.25 g of NaEDTA,and 1.0 mL of phenol (Mallinckrodt, Hazelwood, MO) per liter.The sample buffer was titrated to pH 1.0, eluent A to pH 3.1,eluent B to pH 3.5, and eluent C to pH 4.2 using formic acid.Eluent D was titrated to pH 7.1 with H₃PO₄ (Fisher Scientific,Loughborough, UK), and eluent E was brought to pH 10.0 with3.5 g of H₃BO₄ (Gallard-Schlesinger AnalaR grade) and two pelletsof NaOH. An additional regenerant buffer, eluent F, contained4.0 g of NaOH, 5.84 g of NaCl, 0.25 g of Na₂EDTA, and 1.0 mLof phenol per liter.

For primary amino acids, eluents were pumped through the columnat a flow rate of 15.0 mL/h (column temperature 43°C), and20-µL aliquots of exudate were injected into the eluentflow. After leaving the column, the amino acid containing eluentwas mixed with OPA/2-mercaptoethanol complex, 9.0 g of OPA dissolvedcompletely in 2 to 3 mL of methanol, 12.0 mL of 2-mercaptoethanol,61.8 g of H₃BO₃, 48.0 g of KOH, and 3.0 mL of Brij-35 per litersolution, at a flow rate of 5 mL/h. The eluent-OPA/2-mercaptoethanolmixture entered delay coil B, where fluorophor formation occurred(1 min, room temperature) prior to measurement in the fluorometer.

Border Cell Viability during Mantle Formation

Border cell toxin bioassays were carried out as described (Hawesand Wheeler, 1982; Hawes, 1983). At indicated intervals afterinoculation of roots, border cells were washed into 1 mL ofwater. Viability was evaluated using the vital stain fluoresceindiacetate. Each trial consisted of at least two independentexperiments, each of which included at least two replicatescontaining three individual samples. To assess for the presenceof an extracellular toxin developing during infection, a 500-µLsample of the filtered suspensions from inoculated or uninoculatedseedlings was applied to two wells of a 24-well plate. Washedborder cells from five roots (approximately 20,000 total cells)were introduced into each well. The plate was covered in aluminumfoil and gently shaken for 6 h at room temperature. A sampleof the suspension was diluted to 100 µL, and 10 µLof this suspension was used to assess the viability; valuesare expressed as percentage of control viability of border cellsmaintained in water. Viability of control border cells was 89%± 8% at the start and was reduced to 70% ± 15%after 24 h. Three independent trials, each of which containedtwo replicates, were carried out.

To evaluate toxin production in fungal culture, four seedlingswere inserted into sterile growth pouches containing 15 mL ofthe fungal culture filtrate (M100+), M100 medium (M100), orwater. Two replicates for each treatment were set up for eachtrial. The bags were placed in a plastic container and wereloosely wrapped with Saran Wrap (Dow Chemical, Midland, MI)to prevent drying. The containers were placed in a 24°Cincubator in the dark. At 24 and 48 h after initiation of theexperiment, the four seedlings in each treatment were pooled,washed, and the viability of the border cells evaluated by microscopicobservation using fluorescein diacetate as the vital stain.

Fungal Growth in Root Cap and Border Cell Exudates

Exudates (100 µL at 0.2 mg) from control or inoculatedseedlings were mixed with 500 spores in wells of a 96-well microtiterplate. Blank wells with exudate or border cells without fungalinoculum served as controls. Fungal growth was assessed by measuringA₆₂₀ using a microwell plate reader (Titertek Multiscan MCC/340;Huntsville, AL) and subtracting the blank well values. For eachvalue, the spectrophotometric data were confirmed by visualinspection using a dissecting microscope (SV8; Zeiss, Jena,Germany).

Defense- and Cell Cycle-Related Gene Induction

Root tips and FIZ were excised at intervals after treatmentwith SA (sodium salt; Sigma Chemical, St. Louis), then frozenand stored at –80°C. Northern analysis was as described(Gunawardena and Hawes, 2002). Probes (below) were labeled with³²P by the random primer method using the Prime It II kit fromStratagene (catalog no. 300385; La Jolla, CA). Hybridizationwas carried out at 42°C for heterologous probes and at 50°Cfor homologous probes using the Ultra Hyb hybridization bufferobtained from Ambion (catalog no. 8670; Austin, TX). Densityquantification of the signals obtained from the northern analysiswas done using the NIH Image software program (developed atthe United States National Institutes of Health and availableon the Internet at http://rsb.info.nih.gov/nih-image). Relativelevel means the ratio of the density values obtained for thesignal of interest compared with that of the actin signal forthe same evaluated RNA. Probes included chitinase (a 1.1-kbfragment of the genomic clone of the chitinase gene from pea,obtained from Dr. Lee Hadwiger at Washington State University,Pullman, WA; Chang et al., 1995), cyclin (1.5 kb cDNA of cyclingene of parsley; Logemann et al., 1995); CDK1 (1.16-kb cDNAof cyclin dependent kinase of pea, obtained from Thomas Jacobs,University of Illinois, Champaign-Urbana), H4 histone (a 550-bpcDNA of histone 4 of parsley; Logemann et al., 1995), H3 (a600-bp cDNA of histone 3 of parsley; Logemann et al., 1995),and, as a control, a 600-bp cDNA fragment of actin (Gunawardenaand Hawes, 2002).

Statistical Analysis

Statistical analysis was done using paired data analysis withStudent's t test.

ACKNOWLEDGMENTS

This work was a portion of a Ph.D. dissertation by the firstauthor (Department of Plant Pathology, College of Agricultureand Life Sciences, University of Arizona).

Received November 19, 2004; returned for revision February 15, 2005; accepted February 19, 2005.

FOOTNOTES

¹ This work was supported by the U.S. Department of Agriculture(grants awarded to M.C.H.).

² Present address: Diversa, San Diego, CA 92121.

Article, publication date, and citation information can be foundat www.plantphysiol.org/cgi/doi/10.1104/pp.104.056366.

^{^*} Corresponding author; e-mail mhawes{at}u.arizona.edu; fax 520–621–9290.

LITERATURE CITED

TOP
ABSTRACT
RESULTS
DISCUSSION
CONCLUSION
MATERIALS AND METHODS
LITERATURE CITED

Arriola L, Niemira BA, Safir GR (1997) Border cells and arbuscular mycorrhizae in four Amaranthaceae species. Phytopathology 87: 1240–1242[Medline]

Atkinson TG, Neal JL, Larson RI (1975) Genetic control of the rhizosphere microflora of wheat. In GW Bruehl, ed, Biology and Control of Soil-borne Plant Pathogens. American Phytopathological Society, St. Paul, pp 116–122

Ayers WA, Thornton RH (1968) Exudation of amino acids by intact and damaged roots of wheat and peas. Plant Soil 28: 193–207[CrossRef]

Balu $s$ ka F, Volkmann D, Barlow PW (1996) Specialized zones of development in roots: view from the cellular level. Plant Physiol 112: 3–4[Web of Science][Medline]

Bar-Yosef B (1996) Root excretions and their environmental effects: influence on availability of phosphorus. In Y Waisel, A Eshel, U Kafkafi, eds, Plant Roots: The Hidden Half. Marcel Dekker, New York, pp 581–606

Bauer WD (1981) Infection of legumes by rhizobia. Annu Rev Plant Physiol 32: 407–449

Brigham LA, Woo HH, Wen F, Hawes MC (1998) Meristem-specific suppression of mitosis and a global switch in gene expression in the root cap of pea (Pisum sativum L.) by endogenous signals. Plant Physiol 118: 1223–1231[Abstract/Free Full Text]

Bruehl GW (1986) Soilborne Plant Pathogens. Macmillan, New York

Brunner I, Scheidegger C (1992) Ontogeny of synthesized Picea abies (L.) Karst.—Hebeloma crustuliniforme (Bull. ex St Amans) Quel ectomycorrhizas. New Phytol 120: 359–369

Chang CM, Horowitz D, Culley D, Hadwiger L (1995) Molecular cloning and characterization of a pea chitinase gene expression in response to wounding, fungal infection and the elicitor chitosan. Plant Mol Biol 28: 105–111[CrossRef][Web of Science][Medline]

Chi CC, Childers WR, Hanson EW (1964) Penetration and subsequent development of three Fusarium species in alfalfa and red clover. Phytopathology 54: 434–436

Cook RJ, Flentje NT (1967) Chlamydospore germination and germling survival of Fusarium solani f. sp. pisi in soil as affected by soil water and pea seed exudation. Phytopathology 57: 178

Cooper JE, Rao JR (1992) Localized changes in flavonoid biosynthesis in roots of Lotus pedunculatus after infection by Rhizobium loti. Plant Physiol 100: 444–450[Abstract/Free Full Text]

Curl EA, Truelove B (1986) The Rhizosphere. Springer-Verlag, New York

d'Arcy-Lameta A (1986) Study of soybean and lentil root exudates. Plant Soil 92: 113–123

Deacon JW (1996) Ecological implications of recognition events in the pre-infection stages of root pathogens. New Phytol 133: 135–145[CrossRef]

Delserone LM, McCluskey K, Matthews DE, VanEtten HD (1999) Pisatin demethylation by fungal pathogens and non pathogens of pea: association with pisatin tolerance and virulence. Physiol Mol Plant Pathol 55: 317–326[CrossRef]

deWit-Elshove A, Fuchs A (1971) The influence of the carbohydrate source on pisatin breakdown by fungi pathogenic to pea (Pisum sativum). Physiol Plant Pathol 1: 17–24

Dische Z (1962) General color reactions. In RL Whistler, ML Wolfrom, F Shafizadeh, eds, Methods in Carbohydrate Chemistry: Analysis and Preparation of Sugars, Vol I. Academic Press, New York, pp 478–481

Dunn AK, Klimowicz AK, Handelsman J (2003) Use of a promoter trap to identify Bacillus cereus genes regulated by tomato seed exudate and a rhizosphere resident, Pseudomonas aureofaciens. Appl Environ Microbiol 69: 1197–1205[Abstract/Free Full Text]

Endre G, Kereszt A, Kevei Z, Mihacea S, Kalo P, Kiss GB (2002) A receptor kinase gene regulating symbiotic nodule development. Nature 417: 962–966[CrossRef][Medline]

Ferguson BJ, Mathesius U (2003) Signaling interactions during nodule development. J Plant Growth Regul 22: 47–72[CrossRef]

Foster RC, Rovira AD, Cock TW (1983) Ultrastructure of the Root-Soil Interface. American Phytopathological Society, St. Paul

Funnell DL, Matthews PS, VanEtten HD (2001) Breeding for highly fertile isolates of Nectria haematococca MPVI that are highly virulent on pea and in planta selection for virulent recombinants. Phytopathology 91: 92–101[Medline]

Funnell DL, Matthews PS, VanEtten HD (2002) Identification of new pisatin demethylase genes (PDA5 and PDA7) in Nectria haematococca and non-Mendelian segregation of pisatin demethylating activity and virulence on pea due to loss of chromosomal elements. Fungal Genet Biol 37: 121–133[CrossRef][Medline]

Fusconi A (1983) The development of the fungal sheath on Cistus incanus short roots. Can J Bot 61: 2546–2553

Garcia-Garrido JM, Ocampo JA (2002) Regulation of the plant defence response in arbuscular mycorrhizal symbiosis. J Exp Bot 53: 1377–1386[Abstract/Free Full Text]

Gilbert GS, Clayton MK, Handelsman J (1996) Use of cluster and discriminant analyses to compare rhizosphere bacterial communities following biological perturbation. Microb Ecol 32: 123–147[Web of Science][Medline]

Goldberg NP, Hawes MC, Stanghellini ME (1989) Specific attraction to and infection of cotton root cap cells by zoospores of Pythium dissotocum. Can J Bot 67: 1760–1767

Graham TL (1991) Flavonoid and isoflavonoid distribution in developing soybean seedling tissues and in seed and root exudates. Plant Physiol 95: 594–603[Abstract/Free Full Text]

Griffin GJ, Hale MG, Shay FJ (1976) Nature and quantity of sloughed organic matter produced by roots of axenic peanut plants. Soil Biol Biochem 8: 29–32[CrossRef]

Gunawardena U, Hawes MC (2002) Tissue specific localization of root infection by fungal pathogens: role of root border cells. Mol Plant-Microbe Interact 15: 1128–1136[Web of Science][Medline]

Han Y, Liu X, Benny U, Kistler HC, Van Etten HD (2001) Genes determining pathogenicity to pea are clustered on a supernumerary chromosome in the fungal plant pathogen, Nectria haematococca. Plant J 25: 305–314[CrossRef][Medline]

Harmsen GW, Jager G (1962) Determination of the quantity of carbon and nitrogen in the rhizosphere of young plants. Nature 195: 1119–1120

Harrison MJ, Dixon RA (1993) Isoflavonoid accumulation and expression of defense gene transcripts during the establishment of VAM associations in roots of Medicago truncatula. Mol Plant-Microbe Interact 6: 643–654[Web of Science]

Hawes MC (1983) Sensitivity of isolated root cap cells and protoplasts to victorin. Physiol Plant Pathol 22: 65–76

Hawes MC, Bengough GA, Cassab G, Ponce G (2003) Root caps and rhizosphere. J Plant Growth Regul 21: 352–367[CrossRef]

Hawes MC, Brigham LA, Wen F, Woo HH, Zhu Y (1998) Function of root border cells in plant health: pioneers in the rhizosphere. Annu Rev Phytopathol 36: 311–327[CrossRef][Web of Science][Medline]

Hawes MC, Gunawardena U, Miyasaka S, Zhao X (2000) The role of root border cells in plant defense. Trends Plant Sci 5: 128–132[CrossRef][Web of Science][Medline]

Hawes MC, Wheeler H (1982) Factors affecting victorin induced cell death: temperature and plasmolysis. Physiol Plant Pathol 20: 137–144[CrossRef]

Hiltner L (1904) Uber neuere Erfahrungen und Probleme auf dem Gebiet der Bodenbakteriologie und unter besonderer Berucksichtigung der Grundungung und Brache. Arb Dtsch Landwirt Ges 98: 59–78

Hirsch AM, Bauer WD, Bird DM (2003) Molecular signals and receptors: controlling rhizosphere interactions between plants and other organisms. Ecology 84: 858–868[CrossRef][Web of Science]

Hirsch AM, Kapulnik Y (1998) Signal transduction pathways in mycorrhizal associations: comparisons with the Rhizobium-legume symbiosis. Fungal Genet Biol 23: 205–212[CrossRef][Web of Science][Medline]

Horan DP, Chilvers GA, Lapeyrie FF (1988) Time sequence of the infection process in eucalypt ectomycorrhizas. New Phytol 109: 451–458

Hsieh MC, Graham TL (2001) Partial purification and characterization of a soybean beta-glucosidase with high specific activity towards isoflavone conjugates. Phytochemistry 58: 995–1005[CrossRef][Web of Science][Medline]

Katan J (1996) Interactions of roots with soil-borne pathogens. In Y Waisel, A Eshel, U Kafkafi, eds, Plant Roots: The Hidden Half, Marcel Dekker, New York, pp 811–822

Knee EM, Gong FC, Gao MS, Teplitski M, Jones AR, Foxworth A, Mort AJ, Bauer WD (2001) Root mucilage from pea and its utilization by rhizosphere bacteria as a sole carbon source. Mol Plant-Microbe Interact 14: 775–784[Web of Science][Medline]

Knudson L (1919) Viability of detached root cap cells. Am J Bot 6: 309–310

Kraft JM (1974) The influence of seedling exudates on the resistance of peas to Fusarium and Pythium root rot. Phytopathology 70: 981

Kroes GMLW, Baayen RP, Lange W (1998) Histology of root rot of flax seedlings (Linum usitatissimum) infected by Fusarium oxysporum F. sp. Lini. Eur J Plant Pathol 104: 725–736[CrossRef]

Lagopodi AL, Ram AFJ, Lamers GEM, Punt PJ, Van den Hondel CA, Lugtenberg BJJ, Bloemberg GV (2002) Novel aspects of tomato root colonization and infection by Fusarium oxysporum f. sp. radicis-lycopersici revealed by confocal laser scanning microscopic analysis using the green fluorescent protein as a marker. Mol Plant-Microbe Interact 15: 172–179[Medline]

Leemhuis J, Boutillier S, Schmidt G, Meyer DK (2002) The protein kinase A inhibitor H89 acts on cell morphology by inhibiting Rho kinase. J Pharmacol Exp Ther 300: 1000–1007[Abstract/Free Full Text]

Limpens E, Bisseling T (2003) Signaling in symbiosis. Curr Opin Plant Biol 6: 343–350[CrossRef][Web of Science][Medline]

Lockwood JL (1988) Evolution of concepts associated with soilborne plant pathogens. Annu Rev Phytopathol 26: 93–121

Logemann E, Wu S, Schroder J, Schmeizer E, Sommssich IE, Hahlbrook K (1995) Gene activation by UV light, fungal elicitor or fungal infection in Petroselinum crispum is correlated with repression of cell cycle-related genes. Plant J 8: 865–876[Web of Science][Medline]

Loh J, Carlson RW, York WS, Stacey G (2002a) Bradyoxetin, a unique chemical signal involved in symbiotic gene regulation. Proc Natl Acad Sci USA 99: 14446–14451[Abstract/Free Full Text]

Loh J, Pierson EA, Pierson LS, Stacey G, Chatterjee A (2002b) Quorum sensing in plant-associated bacteria. Curr Opin Plant Biol 5: 285–290[CrossRef][Medline]

Loria R, Lacy ML (1979) Mechanism of increased susceptibility of bleached pea seeds to seed and seeding rot. Phytopathology 69: 573

Maxwell CA, Phillips DA (1990) Concurrent synthesis and release of nod-gene-inducing flavonoids from alfalfa roots. Plant Physiol 93: 1552–1558[Abstract/Free Full Text]

McDougall BM, Rovira AD (1970) Sites of exudation of C-labelled compounds from wheat roots. New Phytol 69: 999–1003

Nagahashi G, Douds DD (2004) Isolated root caps, border cells, and mucilage from host roots stimulate hyphal branching of the arbuscular mycorrhizal fungus, Gigaspora gigantea. Mycol Res 108: 1079–1088[Medline]

Nair MG, Safir GR, Siqueira JO (1991) Isolation and identification of VAM stimulatory compounds from clover (Trifolium repens) roots. Appl Environ Microbiol 57: 434–439[Abstract/Free Full Text]

Nelson EB (1991) Exudate molecules initiating fungal responses to seeds and roots. In DL Keister, PB Cregan, eds, The Rhizosphere and Plant Growth. Kluwer Academic Publishers, Dordrecht, The Netherlands, pp 197–209

Nelson EB (2004) Microbial dynamics and interactions in the spermosphere. Annu Rev Phytopathol 42: 271–309[CrossRef][Web of Science][Medline]

Niemira BA, Safir GR, Hawes MC (1996) Arbuscular mycorrhizal colonization and border cell production: a possible correlation. Phytopathology 86: 563–565

O'Connell KP, Goodman RM, Handelsman J (1996) Engineering the rhizosphere: expressing a bias. Trends Biotechnol 14: 83–88

Parkinson D (1955) Liberation of amino acids by oat seedlings. Nature 176: 35–36

Peters NK, Long SR (1988) Alfalfa root exudates and compounds which promote or inhibit induction of Rhizobium meliloti nodulation genes. Plant Physiol 88: 396–400[Abstract/Free Full Text]

Phillips DA, Fox TC, King MD, Bhuvaneswari TV, Teuber LR (2004) Microbial products trigger amino acid exudation from plant roots. Plant Physiol 136: 2887–2894[Abstract/Free Full Text]

Recourt K, Verkerke M, Schripsema J, vanBrussel AAN, Lugtenberg BJJ, Kijne JW (1992) Major flavonoids in uninoculated and inoculated roots of Vicia sativa subsp. nigra are four conjugates of the nodulation gene-inhibitor kaempferol. Plant Mol Biol 18: 505–513[CrossRef][Web of Science][Medline]

Rodriguez-Galvez E, Mendgen K (1995) The infection process of Fusarium oxysporum in cotton root tips. Protoplasma 189: 61–72[CrossRef]

Roth M (1971) Fluorescence reaction for amino acids. Anal Chem 43: 880–882[Medline]

Rovira AD (1956) Plant root excretions in relation to the rhizosphere effect. 1. The nature of root exudate from pea and oats. Plant Soil 7: 178–194[CrossRef]

Rovira AD (1959) Plant root excretions in relation to the rhizosphere effect. IV. Influence of plant species, age of plant, light, temperature and calcium nutrition of exudation. Plant Soil 11: 53–64[CrossRef]

Rovira AD (1991) Rhizosphere research—85 years of progress and frustration. In DL Keister, PB Cregan, eds, The Rhizosphere and Plant Growth. Kluwer Academic Publishers, Dordrecht, The Netherlands, pp 3–14

Ruan Y, Kotraiah V, Straney DC (1995) Flavonoids stimulate spore germination in Fusarium solani pathogenic on legumes in a manner sensitive to inhibitors of cAMP-dependent protein kinase. Mol Plant-Microbe Interact 8: 929–938

Schroth MN, Tousson TA, Snyder WC (1963) Effect of certain constituents of bean exudate on germination of chlamydospores of Fusarium solani f. sp. phaseoli in soil. Phytopathology 53: 809–812

Sherwood R (1987) Papilla formation in corn root cap cells and leaves inoculated with Colletotrichum graminicola. Phytopathology 77: 930–934

Short GE, Lacy ML (1974) Germination of Fusarium solani f. sp. pisi chlamydospores in the spermosphere of pea. Phytopathology 64: 558–562

Short GE, Lacy ML (1976) Carbohydrate exudation from pea seeds: effect of cultivar, seed age, seed color and temperature [and relation to fungal rots]. Phytopathology 66: 182–187

Smith KP, Handelsman J, Goodman RM (1999) Genetic basis in plants for interactions with disease-suppressive bacteria. Proc Natl Acad Sci USA 96: 4786–4790[Abstract/Free Full Text]

Sommssich IE, Hahlbrock K (1998) Pathogen defense in plants—a paradigm of biological complexity. Trends Plant Sci 3: 86–90[CrossRef][Web of Science]

Stahl DJ, Theuerkauf A, Heitefuss R, Schafer W (1994) Cutinase of Nectria haematococca (Fusarium solani F. sp. pisi) is not required for fungal virulence or organ specificity on pea. Mol Plant-Microbe Interact 7: 713–725[Web of Science]

Steele HL, Werner D, Cooper JE (1999) Flavonoids in seed and root exudates of Lotus pedunculatus and their biotransformation by Mesorhizobium loti. Physiol Plant 107: 251–258[CrossRef]

Stevens RB (1974) Mycology Guidebook. University of Washington Press, Seattle

Straney DC, VanEtten HD (1994) Characterization of the PDA1 promoter of Nectria haematococca and identification of a region that binds a pisatin-responsive DNA binding factor. Mol Plant-Microbe Interact 7: 256–266[Medline]

Syin C, Parzy D, Traincard F, Boccaccio I, Joshi MB, Lin DT, Yang X, Assemat K, Doerig C, Langsley G (2001) The H89 cAMP-dependent protein kinase inhibitor blocks Plasmodium falciparum development in infected erythrocytes. Eur J Biochem 268: 4842–4849[Medline]

Teplitski M, Robinson JB, Bauer WD (2000) Plants secrete substances that mimic bacterial N-acyl homoserine lactone signal activities and affect population density-dependent behaviors in associated bacteria. Mol Plant-Microbe Interact 13: 637–648[Web of Science][Medline]

Tsai SM, Phillips DA (1991) Flavonoids released naturally from alfalfa promote development of symbiotic Glomus spores in vitro. Appl Environ Microbiol 57: 1485–1488[Abstract/Free Full Text]

Tsanuo MK, Hassanali A, Hooper AM, Khan Z, Kaberia F, Pickett JA, Wadhams LJ (2003) Isoflavanones from the allelopathic root exudate of Desmodium uncinatum. Phytochemistry 64: 265–273[CrossRef][Web of Science][Medline]

Turlier M, Eparvier A, Alabouvette C (1994) Early dynamic interactions between Fusarium oxysporum f. sp. lini and the roots of Linum usitatissimum as revealed by transgenic GUS-marked hyphae. Can J Bot 72: 1605–1612

Van Brussel AAN, Recourt K, Pees E, Splink HP, Tak T (1990) A biovar-specific signal of Rhizobium leguminosarum bv. viciae induces increased nodulation gene inducing activity in root exudate of Vicia sativa subsp. nigra. J Bacteriol 172: 5394–5401[Abstract/Free Full Text]

VanEgeraat AWSM (1975) The possible role of homoserine in the development of Rhizobium leguminosarum in the rhizosphere of pea seedlings. Plant Soil 42: 381–386[CrossRef]

Van Etten HD, Matthews PS, Tegtmeier KJ, Dietert MF, Stein JI (1980) The association of pisatin tolerance and demethylation with virulence on pea in Nectria haematococca. Physiol Plant Pathol 16: 257–268[CrossRef]

Vermeer J, McCully ME (1982) The rhizosphere in Zea: new insight into its structure and development. Planta 156: 45–61[CrossRef]

Wassman CC, Van Etten HD (1996) Transformation-mediated chromosome loss and disruption of a gene for pisatin demethylase decrease the virulence of Nectria haematococca on pea. Mol Plant-Microbe Interact 9: 793–803[Web of Science]

Wojtaszek P, Stobiecki M, Gulewicz K (1993) Role of nitrogen and plant growth regulators in the exudation and accumulation of isoflavonoids by roots of intact white lupin (Lupinus albus L.) plants. J Plant Physiol 142: 689–694

Woo HH, Hirsch AM, Hawes MC (2004) Altered susceptibility to infection by Sinorhizobium meliloti and Nectria haematococca in alfalfa roots with altered cell cycle. Plant Cell Rep 22: 967–973[Medline]

Zhu Y, Pierson LS III, Hawes MC (1997) Induction of microbial genes for pathogenesis and symbiosis by chemicals from root border cells. Plant Physiol 115: 1691–1698[Abstract]

This article has been cited by other articles:

F. Wen, G. J. White, H. D. VanEtten, Z. Xiong, and M. C. Hawes
Extracellular DNA Is Required for Root Tip Resistance to Fungal Infection
Plant Physiology, October 1, 2009; 151(2): 820 - 829.
[Abstract] [Full Text] [PDF]

C. Durand, M. Vicre-Gibouin, M. L. Follet-Gueye, L. Duponchel, M. Moreau, P. Lerouge, and A. Driouich
The Organization Pattern of Root Border-Like Cells of Arabidopsis Is Dependent on Cell Wall Homogalacturonan
Plant Physiology, July 1, 2009; 150(3): 1411 - 1421.
[Abstract] [Full Text] [PDF]

M. Rodriguez-Carres, G. White, D. Tsuchiya, M. Taga, and H. D. VanEtten
The Supernumerary Chromosome of Nectria haematococca That Carries Pea-Pathogenicity-Related Genes Also Carries a Trait for Pea Rhizosphere Competitiveness
Appl. Envir. Microbiol., June 15, 2008; 74(12): 3849 - 3856.
[Abstract] [Full Text] [PDF]

S. A. Sukno, V. M. Garcia, B. D. Shaw, and M. R. Thon
Root Infection and Systemic Colonization of Maize by Colletotrichum graminicola
Appl. Envir. Microbiol., February 1, 2008; 74(3): 823 - 832.
[Abstract] [Full Text] [PDF]

F. Wen, H. D. VanEtten, G. Tsaprailis, and M. C. Hawes
Extracellular Proteins in Pea Root Tip and Border Cell Exudates
Plant Physiology, February 1, 2007; 143(2): 773 - 783.
[Abstract] [Full Text] [PDF]

L. HAMAMOTO, M. C. HAWES, and T. L. ROST
The Production and Release of Living Root Cap Border Cells is a Function of Root Apical Meristem Type in Dicotyledonous Angiosperm Plants
Ann. Bot., May 1, 2006; 97(5): 917 - 923.
[Abstract] [Full Text] [PDF]

This Article

Abstract

Full Text (PDF)

All Versions of this Article:
137/4/1363 most recent
pp.104.056366v1

Alert me when this article is cited

Alert me if a correction is posted

Services

Email this article to a friend

Similar articles in this journal

Similar articles in Web of Science

Similar articles in PubMed

Alert me to new issues of the journal

Download to citation manager

Citing Articles

Citing Articles via HighWire

Citing Articles via CrossRef

Citing Articles via Web of Science (6)

Citing Articles via Google Scholar

Google Scholar

Articles by Gunawardena, U.

Articles by Hawes, M. C.

Search for Related Content

PubMed

PubMed Citation

Articles by Gunawardena, U.

Articles by Hawes, M. C.

Agricola

Articles by Gunawardena, U.

Articles by Hawes, M. C.

Related Collections

Legume Biology

Tissue-Specific Localization of Pea Root Infection by Nectria haematococca. Mechanisms and Consequences1

Tissue-Specific Localization of Pea Root Infection by Nectria haematococca. Mechanisms and Consequences¹