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Plant Physiol. (1998) 117: 465-472 Coordinate Accumulation of Antifungal Proteins and Hexoses Constitutes a Developmentally Controlled Defense Response during Fruit Ripening in Grape1
Center for Plant Environmental Stress Physiology, Purdue University, 1165 Horticulture Building, West Lafayette, Indiana 47907-1165
During ripening of grape (Vitis labruscana L. cv Concord) berries, abundance of several proteins increased, coordinately with hexoses, to the extent that these became the predominant proteins in the ovary. These proteins have been identified by N-terminal amino acid-sequence analysis and/or function to be a thaumatin-like protein (grape osmotin), a lipid-transfer protein, and a basic and an acidic chitinase. The basic chitinase and grape osmotin exhibited activities against the principal grape fungal pathogens Guignardia bidwellii and Botrytis cinerea based on in vitro growth assays. The growth-inhibiting activity of the antifungal proteins was substantial at levels comparable to those that accumulate in the ripening fruit, and these activities were enhanced by as much as 70% in the presence of 1 M glucose, a physiological hexose concentration in berries. The simultaneous accumulation of the antifungal proteins and sugars during berry ripening was correlated with the characteristic development of pathogen resistance that occurs in fruits during ripening. Taken together, accumulation of these proteins, in combination with sugars, appears to constitute a novel, developmentally regulated defense mechanism against phytopathogens in the maturing fruit.
Plants have evolved a number of strategies to resist fungal
infection. One strategy involves the accumulation of defense proteins that have direct inhibitory activity against the hyphae and/or germinating spores of the pathogen. Among these are PR proteins including chitinases (PR-3 family), thaumatin-like proteins (PR-5 family), and nsLTPs. Typically, these antifungal proteins are expressed
constitutively at low levels in cells and accumulate in response to
fungal attack or in response to other inducers of acquired resistance
(Uknes et al., 1992 Another physiological adaptation of plants that affects fungal
pathogenesis, but one that has received considerably less attention, is
the accumulation of sugars. Results from studies of several host/pathogen systems have implicated accumulation or depletion of
sugars in resistance to fungal infection (VanderPlank, 1984 We report here that accumulation of hexoses in grape (Vitis
labruscana L. cv Concord) berries is accompanied by a
developmental-stage-specific increase in a suite of proteins that are
homologous to proteins known to be antifungal determinants. These
proteins have been identified as a thaumatin-like protein (Salzman et
al., 1994 Unless otherwise stated, all plant material was obtained from
field-grown vines of grape (Vitis labruscana L. cv Concord).
Protein Purification
Electrophoresis and Detection Methods and Antibody Production For determination of protein levels in fruit, fresh berries were deseeded and ground in a mortar and pestle with 5× sample buffer (Laemmli, 1970 ), 250 µL g 1 fresh weight of
fruit. The homogenate was boiled for 3 min and centrifuged at
13,000g for 10 min, and the supernatant was applied to
SDS-PAGE 15% gels, 25 µL of extract per lane. For immunodetection, proteins were electroblotted onto nitrocellulose according to the
method of Zhu et al. (1996) and detected by reaction with IgY
polyclonal antibodies (Salzman et al., 1996) raised against tobacco
(Nicotiana tabacum L.) osmotin, tobacco chitinase T2 (Yun et
al., 1996), or grape LTP. After reaction with the primary antibody, blots were incubated with alkaline phosphatase-linked rabbit
anti-chicken IgY secondary antibodies (Jackson Immunoresearch, West
Grove, PA), and the color product was developed according to standard protocols (Bio-Rad).
Amino Acid Sequence Determination Purified proteins were subjected to SDS-PAGE and then electroblotted to a PVDF (Bio-Rad) membrane (Zhu et al., 1996). Protein bands were visualized with Coomassie blue R and excised from the membrane. The N-terminal amino acid sequence determination was performed by the Purdue Laboratory for Molecular Structure (West Lafayette, IN) on a sequencer (model 470A, Applied Biosystems) using
the Edman degradation method.
Measurement of Total Sugars Total soluble sugars in grape berries were determined from measurements of the refractive index, which accurately reflects total soluble solids. In grape berries Glc and Fru typically represent 95 to 99% of soluble solids (Zoeklein et al., 1996). Molarity (as Glc
equivalents) of total sugars in freshly expressed juice was calculated
from refractive index measurements using a Glc standard curve.
Chitinase and Antifungal Assays Chitinase activity was determined colorimetrically as described previously (Yun et al., 1996). Hyphal growth measurements were
determined on one-half-strength potato dextrose-broth (Sigma) medium
(Abad et al., 1996). Autoclaved potato dextrose-broth medium was cooled
to 40°C, followed by inclusion of purified antifungal proteins,
individually or in combination, and without or with Glc or Xyl. The
medium was distributed into 2.5-mm (width) by 6-mm (depth) slots in
assay plates and allowed to solidify. The medium in each slot was then
inoculated at one end with a small block of potato dextrose-broth
medium containing fungal hyphae excised from the edge of an actively
growing culture (Abad et al., 1996). Hyphal elongation was quantified
with the aid of a stereomicroscope equipped with a micrometer (Olympus
Optical Co., Ltd., Tokyo, Japan).
Identification of Major Proteins Accumulating in Grape Berries Polypeptides with molecular masses of 32, 29, 27, and 9 kD were the predominant proteins recovered from the juice of grape berries at the fully ripe stage (Fig. 1). These proteins were purified to apparent homogeneity based on Coomassie blue staining of SDS-PAGE gels (Fig. 2). The 27-kD protein (GO) has an N-terminal amino acid sequence that is 72% identical to VVTL1 from Vitis vinifera (Tattersall et al., 1997), and is 68% identical to TPM-1, an osmotin-like protein from
tomato (Fig. 3). GO has a sequence divergent from that of VVTL1, possibly because the proteins were obtained from different genotypes. GO reacted strongly with tobacco anti-osmotin. The 9-kD protein was identified as nsLTP based on the
N-terminal amino acid sequence identity (79%) with NLT4 from V. vinifera × Vitis berlanchen (Coutos-Thevenot et al., 1993) and
conservation of motifs prevalent in other LTPs (Fig. 3). The molecular
mass determined by SDS-PAGE and heat stability are also characteristics
of plant LTPs. Amino acid sequence information was not obtained for the
29- and 32-kD proteins because these were N-terminally blocked.
However, both of these proteins had potent endochitinase activity but
not exochitinase activity (Table I).
These proteins reacted strongly with tobacco anti-chitinase (Yun et
al., 1996) and comigrated with the tobacco homologs on SDS-PAGE gels
(data not shown). Increased accumulation of these two proteins was also
correlated with increases in chitinase activity levels shown to occur
in ripening grapes (Robinson et al., 1997). The 29-kD chitinase (AC)
was more acidic than the 32-kD form based on elution from a
cation-exchange column, and lacked chitin-binding activity, analogous
to class II chitinases. The chitin-binding 32-kD protein (CBC) was more
basic and presumably contained a chitin-binding domain (Fig.
4), both characteristics of class I
chitinases.
Sugar and Antifungal Protein Accumulation Occur Coordinately during Fruit Ripening Total sugar levels in berries increased substantially during the onset of ripening (termed "veraison"), coincident with major accumulation of the antifungal proteins (Fig. 5). During this period the molarity of total sugars, which are composed primarily of Glc and Fru (Zoeklein et al., 1996), increased from 0.58 to 1.1 M Glc equivalents.
The antifungal proteins represented the predominant proteins in the
berries during this period, in part because of reduced abundance of
photosynthetic enzymes. The absolute levels of GO and CBC increased to
as much as 200 µg g1 fresh weight of the
berry, estimated by comparing total protein extracts with known amounts
of purified proteins on SDS-PAGE (data not shown), although
accumulation levels varied among different genotypes (Fig. 1B). High
levels of the proteins also persisted during senescence.
Proteins That Accumulate in Fruits during Ripening Inhibit Growth of Grape-Pathogenic Fungi and This Activity Is Enhanced by Sugars Hyphal growth of grape isolates of Guignardia bidwellii and Botrytis cinerea was inhibited by GO and CBC (Figs. 6 and 7). Virtually no chitinase activity was detected in the GO protein fraction (Table II), indicating that antifungal activity was not attributable to contaminating chitinases. Petri-dish and quantitative assays established that the effects of GO and CBC against B. cinerea and G. bidwellii were enhanced substantially by inclusion of 1 M Glc in the medium (Figs. 6 and 7). This effect was more evident with GO, which had substantially less antifungal activity in the absence of solute (Fig. 7). Fungal-growth inhibition was additive when GO and CBC were assayed in combination; however, no synergism was evident between the two proteins, either in the presence or absence of Glc (Fig. 6). The sugar modulation of antifungal protein activity seemed to be mediated through a nutrition-independent mechanism, because Xyl (a nonmetabolizable osmolyte) also enhanced the activity of the proteins (Table III). The LTP exhibited no antifungal activity against either G. bidwellii or B. cinerea at doses up to 200 µg mL1 (data
not shown).
Antifungal Proteins Are Components of Fungal Resistance Developed during Grape Berry Ripening The demonstration that the grape berry proteins have antifungal activity, and their abundant and developmentally controlled accumulation in berries implicate a potential role for these proteins in host-plant defense against fruit pathogens. Ripe fruits typically are considered vulnerable to pathogen attack because of their enriched levels of sugars and other nutrients, as well as physical changes that facilitate infection (Swinburn, 1983). Plants with climacteric fruits,
such as avocado, tomato, and banana, evolved ethylene during ripening,
which fostered infection by Colletotrichum spp. (Flaishman
and Kolattukudy, 1994). However, for some years it has been known that
grape berries acquire resistance to several pathogens during ripening
(Delp 1954; Lafon and Clerjeau 1988; Pearson, 1988), and it has been
suggested that an osmotin-like protein may be involved in this
acquisition of resistance (Tattersall et al., 1997).
Induction of Antifungal Proteins during Fruit Ripening At least two potentially interrelated mechanisms may be involved in the regulation of antifungal protein accumulation during ripening: osmotic due to sugar accumulation, or sugar signaling. Osmotin accumulation was first shown to occur as a function of salt/osmotic adaptation of tobacco cells in culture (Singh et al., 1985). The
osmotin gene is responsive to hyperosmolarity and pathogen infection,
as well as many inducers that have been implicated as components of the
signal cascades leading from perception of these stresses (Kononowicz
et al., 1992). The osmolarity in grape berries (>1.5 M Glc
equivalents) is far in excess of that required to induce accumulation
of osmotin, chitinases, and nsLTPs (Singh et al., 1985; Torres-Schumann
et al., 1992; Yun et al., 1996). In fact, potentially inductive osmotic
levels (380-580 mM Glc equivalents) occur in fruits
coincident with the acquisition of resistance (Fig. 5).
Sugars and Antifungal Proteins Interact to Mediate Host Plant Defense against Phytopathogens Our results indicate that the antifungal efficacy of GO and CBC is enhanced by concentrations of Glc that occur in fruits as resistance to phytopathogens is acquired. The antipathogenic effect of potential metabolic interactions between sugars and the pathogens apparently involves nutrition-independent mechanisms, since Glc and Xyl, at equivalent osmolarities have the same effect, and Xyl is not metabolized by either G. bidwellii or B. cinerea (neither of these organisms was able to grow on Xyl as a sole C source). The previous concept that sugars furnish an "osmotic challenge" also seems unlikely, since fungal growth rates on medium supplemented with either 1 M Glc or 1 M Xyl were as high or higher than those on basal medium (data not shown). Consequently, the fungi were able to adjust osmotically and generate sufficient turgor for hyphal growth.
* Corresponding author; e-mail bressan{at}hort.purdue.edu; fax 1-765-494-0391. Received December 8, 1997;
accepted February 23, 1998.
Abbreviations: AC, acidic chitinase. CBC, chitin-binding chitinase (basic). GO, grape osmotin. LTP, lipid-transfer protein. nsLTP, nonspecific LTP. PR, pathogenesis-related.
We thank Dr. Meena Narasimhan and Dr. Keyan Zhu-Salzman for their critical review of the manuscript.
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Abstract
Introduction
) or with 1 M Glc
(1Mglc). Values represent mean growth as a percentage of the
control ± SE, n = 6. Controls
consisted of glc