Class I [beta]-1,3-Glucanases in the Endosperm of Tobacco during Germination

Rupture of the seed coat and rupture of the endosperm are separate events in the germination of Nicotiana tabacum L. cv Havana 425 seeds. Treatment with 10-5 M abscisic acid (ABA) did not appreciably affect seed-coat rupture but greatly delayed subsequent endosperm rupture by more than 100 h and resulted in the formation of a novel structure consisting of the enlarging radicle with a sheath of greatly elongated endosperm tissue. Therefore, ABA appears to act primarily by delaying endosperm rupture and radicle emergence. Measurements of [beta]-1,3-glucanase activity, antigen content, and mRNA accumulation together with reporter gene experiments showed that induction of class I [beta]-1,3-glucanase genes begins just prior to the onset of endosperm rupture but after the completion of seed-coat rupture. This induction was localized exclusively in the micropylar region of the endosperm, where the radicle will penetrate. ABA treatment markedly inhibited the rate of [beta]-1,3-glucanase accumulation but did not delay the onset of induction. Independent of the ABA concentration used, onset of endosperm rupture was correlated with the same [beta]-1,3-glucanase content/seed. These results suggest that ABA-sensitive class I [beta]-1,3-glucanases promote radicle penetration of the endosperm, which is a key limiting step in tobacco seed germination.     

Pathogenesis-related functions of plant β-1,3-glucanases investigated by antisense transformation — a review

Plant β-1,3-glucanases (βGlu) have been implicated in several physiological and developmental processes, e.g., cell division, microsporogenesis, pollen germination, fertilization and seed germination. These enzymes, particularly the antifungal class-I vacuolar isoforms, are also believed to be part of the defences of plants against fungal infection. The function of βGlu in tobacco and Nicotiana sylvestris has been investigated by antisense transformation. Transformation with GLA, the gene encoding the A isoform of tobacco class-I βGlu, in reverse orientation regulated by the strong cauliflower mosaic virus 35S RNA promoter effectively and specifically blocked the induction of class-I βGlu. This induction was in response to ethylene treatment and following infection with the pathogenic fungus, Cercospora nicotianae, tobacco mosaic virus (TMV) and tobacco necrosis virus (TNV). Nevertheless, the plants compensated for this deficiency by producing a functionally equivalent (i.e., ‘ersatz’) enzyme or enzymes. The fact that compensation occurred specifically in response to infection suggests that βGlu activity has an important role in pathogenesis. Antisense transformation substantially reduced lesion size and number in virus-infected local-lesion hosts. These results suggest novel antisense-based strategies for protecting plants against virus infection. They also raise the intriguing possibility that viruses use a defence mechanism of the host, production of antifungal βGlu, to promote their own replication and spread.     

Only Specific Tobacco (Nicotiana tabacum) Chitinases and [beta]-1,3-Glucanases Exhibit Antifungal Activity

Different isoforms of chitinases and [beta]-1,3-glucanases of tobacco (Nicotiana tabacum cv Samsun NN) were tested for their antifungal activities. The class I, vacuolar chitinase and [beta]-1,3-glucanase isoforms were the most active against Fusarium solani germlings, resulting in lysis of the hyphal tips and in growth inhibition. In additon, we observed that the class I chitinase and [beta]-1,3-glucanase acted synergistically. The class II isoforms of the two hydrolases exhibited no antifungal activity. However, the class II chitinases showed limited growth inhibitory activity in combination with higher amounts of class I [beta]-1,3-glucanase. The class II [beta]-1,3-glucanases showed no inhibitory activity in any combination. In transgenic tobacco plants producing modified forms of either a class I chitinase or a class I [beta]-1,3-glucanase, or both, these proteins were targeted extracellularly. Both modified proteins lack their C-terminal propeptide, which functions as a vacuolar targeting signal. Extracellular targeting had no effect on the specific activities of the chitinase and [beta]-1,3-glucanase enzymes. Furthermore, the extracellular washing fluid (EF) from leaves of transgenic plants expressing either of the secreted class I enzymes exhibited antifungal activity on F. solani germlings in vitro comparable to that of the purified vacuolar class I proteins. Mixing EF fractions from these plants revealed synergism in inhibitory activity against F. solani; the mixed fractions exhibited inhibitory activity similar to that of EF from plants expressing both secreted enzymes.     

Movement of plant viruses is delayed in a beta-1,3-glucanase-deficient mutant showing a reduced plasmodesmatal size exclusion limit and enhanced callose deposition

Susceptibility to virus infection is decreased in a class I beta-1,3-glucanase (GLU I)-deficient mutant (TAG4.4) of tobacco generated by antisense transformation. TAG4.4 exhibited delayed intercellular trafficking via plasmodesmata of a tobamovirus (tobacco mosaic virus), of a potexvirus (recombinant potato virus X expressing GFP), and of the movement protein (MP) 3a of a cucumovirus (cucumber mosaic virus). Monitoring the cell-to-cell movement of dextrans and peptides by a novel biolistic method revealed that the plasmodesmatal size exclusion limit (SEL) of TAG4.4 was also reduced from 1.0 to 0.85 nm. Therefore, GLU I-deficiency has a broad effect on plasmodesmatal movement, which is not limited to a particular virus type. Deposition of callose, a substrate for beta-1,3-glucanases, was increased in TAG4.4 in response to 32 degrees C treatment, treatment with the fungal elicitor xylanase, and wounding, suggesting that GLU I has an important function in regulating callose metabolism. Callose turnover is thought to regulate plasmodesmatal SEL. We propose that GLU I induction in response to infection may help promote MP-driven virus spread by degrading callose.     

Intracellular transport and processing of a tobacco vacuolar β-1,3-glucanase

The class I β-1,3-glucanases are basic, vacuolar enzymes implicated in the defense of plants against pathogen infection. The tobacco (Nicotiana tabacum L.) enzyme is synthesized as a preproprotein with an N-terminal signal peptide for targeting to the lumen of the endoplasmic reticulum and an N-glycosylated C-terminal extension which is lost during protein maturation. The transport and processing of β-1,3-glucanase in cellsuspension cultures of the tobacco cultivar Havana 425 was investigated by pulse-chase labelling and cell fractionation. We verified that mature β-1,3-glucanase is localized in the vacuole of the suspension-cultured cells. Comparison of the time course of processing in homogenates, the soluble fraction, and membrane fractions indicates that proglucanase is transported from the endoplasmic reticulum via the Golgi compartment to the vacuole. Processing to the mature form occurs in the vacuole. Treatment of cells with tunicamycin, which inhibits N-glycosylation, and digestion of the ³⁵S-labelled processing intermediates with endoglycosidase H indicate that β-1,3-glucanase has a single N-glycan attached to the C-terminal extension. Glycosylation is not required for proteolytic processing or correct targeting to the vacuole.     

Pathogenesis-related acidic beta-1,3-glucanase genes of tobacco are regulated by both stress and developmental signals

Three pathogenesis-related (PR) proteins of tobacco are acidic isoforms of beta-1,3-glucanase (PR-2a, -2b, -2c). We have cloned and sequenced a partial cDNA clone (lambda FJ1) corresponding to one of the PR-2 beta-1,3-glucanases. A small gene family encodes the PR-2 proteins in tobacco, and similar genes are present in a number of plant species. We analyzed the stress and developmental regulation of the tobacco PR-2 beta-1,3-glucanases by using northern and western analyses and a new technique to assay enzymatic activity. Stress caused by both thiamine and tobacco mosaic virus (TMV) infection resulted in a dramatic increase in the levels of PR-2 mRNA, protein, and enzyme activities. The increased PR-2 gene expression in upper uninoculated leaves of plants infected with TMV also suggests a role in systemic acquired resistance. During floral development, a number of beta-1,3-glucanase activities were observed in all flower tissues. However, PR-2 polypeptides were observed only in sepal tissue. In contrast, an mRNA that hybridized to the PR-2 cDNA was present in stigma/style tissue and the sepals. Primer extension analysis confirmed the identity of the PR-2 mRNA in sepals, but indicated that the beta-1,3-glucanase gene expressed in the stigma/style of flowers was distinct from the PR-2 genes. The induction of PR-2 protein synthesis by both stress and developmental signals was accompanied by a corresponding increase in the steady-state levels of PR-2 mRNA, suggesting that PR-2 gene expression is regulated, in part, at the level of mRNA accumulation.     

beta]-1,3-Glucanase Is Cryoprotective in Vitro and Is Accumulated in Leaves during Cold Acclimation

We have used isolated spinach (Spinacea oleracea L.) thylakoid membranes to investigate the possible cryoprotective properties of class I [beta]-1,3-glucanase (1,3-[beta]-D-glucan 3-glucanohydrolase; EC 3.2.1.39) and chitinase. Class I [beta]-1,3-glucanase that was purified from tobacco (Nicotiana tabacum L.) protected thylakoids against freeze-thaw injury in our in vitro assays, whereas class I chitinase from tobacco had no effect under the same conditions. The [beta]-1,3-glucanase acted by reducing the influx of solutes into the membrane vesicles during freezing and thereby reduced osmotic stress and vesicle rupture during thawing. Western blots probed with antibodies directed against tobacco class I [beta]-1,3-glucanase showed that in spinach and cabbage (Brassica oleracea L.) leaves an isoform of 41 kD was accumulated during frost hardening under natural conditions.     

Local expression of enzymatically active class I β-1, 3-glucanase enhances symptoms of TMV infection in tobacco

Mutant tobacco plants deficient for class I beta-1,3-glucanase (GLU I) are decreased in their susceptibility to virus infection. This is correlated with delayed virus spread, a reduction in the size exclusion limit of plasmodesmata and increased cell-wall deposition of the beta-1,3-glucan callose. To further investigate a role of GLU I during cell-to-cell movement of virus infection, we inserted the GLU I coding sequence into TMV for overexpression in infected cells. Compared with the size of local lesions produced on plants infected with virus expressing either an enzymatically inactive GLU I or a frameshift mutant of the gene, the size of local lesions caused by infection with virus expressing active GLU I was consistently increased. Viruses expressing antisense GLU I constructs led to lesions of decreased size. Similar effects were obtained for virus spread using plants grown at 32 degrees C to block the hypersensitive response. Together, these results indicate that enzymatically active GLU I expressed in cells containing replicating virus can increase cell-to-cell movement of virus. This supports the view that GLU I induced locally during infection helps to promote cell-to-cell movement of virus by hydrolyzing callose. Moreover, our results provide the first direct evidence that a biological function of a plant beta-1,3-glucanase depends on its catalytic activity.     

Effect of 1,3;1,6-β-D-glucan on Infection of Detached Tobacco Leaves with Tobacco Mosaic Virus

Glucan preparations were obtained by transformation of laminaran from the alga Laminaria cichorioides with endo-β-1,3-glucanase from marine mollusks. These preparations, like those of other sources, have an inhibitory effect on tobacco mosaic virus (TMV) infection of detached leaves of local and systemic host tobacco plants.     

Effects of gibberellins, darkness and osmotica on endosperm rupture and class I β-1,3-glucanase induction in tobacco seed germination

The “Havana 425” cultivar of Nicotiana tabacum L. is photodormant. Gibberellins (e.g. 10^?5 M GA₄ or GA₇) can substitute for light in releasing dormancy. Measurements of β-1,3-glucanase activity, mRNA accumulation and the activity of the class I β-1,3-glucanase B promoter indicated that class I β-1,3-glucanases are induced by GA₄ in the dark in association with germination. As in the light, this induction occurred prior to endosperm rupture and was localized exclusively in the micropylar region of the endosperm where the radicle will penetrate. Abscisic acid (ABA, 10^?5 M) did not appreciably affect GA-induced release of photodormancy or seed-coat rupture, but it delayed endosperm rupture and inhibited the rate of class I β-1,3-glucanase accumulation. Seeds imbibed in the light in the presence of osmotica, e.g. 0.04 M polyethylene glycol 6000, showed delayed seed-coat and endosperm rupture, delayed onset of β-1,3-glucanase induction, and decreased rates of β-1,3-glucanase accumulation. These delays were shortened by GA₄ treatment. Our results suggest that GAs and ABA act at two distinct sites during germination and that expansive growth of the embryo acts in two ways by triggering β-1,3-glucanase induction and by providing force for endosperm penetration. This provides further support for our working hypothesis that class I β-1,3-glucanases promote endosperm weakening and facilitate radicle penetration.     

Functional Implications of the Subcellular Localization of Ethylene-Induced Chitinase and [beta]-1,3-Glucanase in Bean Leaves

Plants respond to an attack by potentially pathogenic organisms and to the plant stress hormone ethylene with an increased synthesis of hydrolases such as chitinase and [beta]-1,3-glucanase. We have studied the subcellular localization of these two enzymes in ethylene-treated bean leaves by immunogold cytochemistry and by biochemical fractionation techniques. Our micrographs indicate that chitinase and [beta]-1,3-glucanase accumulate in the vacuole of ethylene-treated leaf cells. Within the vacuole label was found predominantly over ethylene-induced electron dense protein aggregates. A second, minor site of accumulation of [beta]-1,3-glucanase was the cell wall, where label was present nearly exclusively over the middle lamella surrounding intercellular air spaces. Both kinds of antibodies labeled Golgi cisternae of ethylene-treated tissue, suggesting that the newly synthesized chitinase and [beta]-1,3-glucanase are processed in the Golgi apparatus. Biochemical fractionation studies confirmed the accumulation in high concentrations of both chitinase and [beta]-1,3-glucanase in isolated vacuoles, and demonstrated that only [beta]-1,3-glucanase, but not chitinase, was present in intercellular washing fluids collected from ethylene-treated leaves. Based on these results and earlier studies, we propose a model in which the vacuole-localized chitinase and [beta]-1,3-glucanase are used as a last line of defense to be released when the attacked host cells lyse. The cell wall-localized [beta]-1,3-glucanase, on the other hand, would be involved in recognition processes, releasing defense activating signaling molecules from the walls of invading pathogens.     

The effect of ethylene on the cell-type-specific and intracellular localization of β-1,3-glucanase and chitinase in tobacco leaves

We have studied the effect of ethylene on the localization of the basic isoforms of glucan endo-1,3--glucosidase (-1,3-glucanase, EC 3.2.1.39) and endo-chitinase (chitinase, EC 3.2.1.14) in leaves of Nicotiana tabacum L. cv. Havana 425. Comparisons of the enzyme contents of the lower epidermis of the leaf, leaf expiants with the lower epidermis removed, and intercellular wash fluid indicate that both enzymes are localized inside epidermal cells of untreated leaves. Ethylene treatment (20 l·l^-1, 4d) induced a marked -10- to 30-fold-coordinated accumulation of the enzymes. This was due primarily to induction of the basic isoforms inside chlorenchyma cells of the leaf interior. The localization of basic -1,3-glucanase was confirmed by immunofluorescence histochemistry and immunogold cytochemistry. Immunolabelling was confined to electron-dense bodies of the cell vacuole. No extracellular immunolabelling was detected in control or ethylene-treated leaves. We conclude that ethylene changes the cell-type-specific distribution but not the intracellular compartmentation of the two enzymes. These results support the generalization that basic isoforms of chitinase and -1,3-glucanase are intracellular whereas the acidic isoforms are secreted into the extracellular space.Abbreviations IgG immunoglobulin G - IWF intercellular wash fluid - PBS 0.14 M NaCl, 0.1 M K₂HPO₄, pH 7.5 - TMV tobacco mosaic virus We thank Monique Seldran and Alfred Milani for expert technical help, Patricia Ahl-Goy, Ciba-Geigy, AG, Basel for supplying IWF from TMV-infected leaves, and our colleagues Thomas Boller and Lilian Sticher for their comments and criticism.     

Differential Regulation of beta-1,3-Glucanase Messenger RNAs in Response to Pathogen Infection

The acidic, extracellular, glucan endo-1,3-β-glucosidases (EC 3.2.1.39; β-1,3-glucanases), pathogenesis-related proteins-2, -N, and -O (i.e. PR-2, PR-N, and PR-O) were purified from Nicotiana tabacum (tobacco) and their partial amino acid sequences determined. Based on these data, complementary DNA (cDNA) clones encoding the proteins were isolated. Additional cDNAs were isolated that encoded proteins approximately 90% identical with PR-2, PR-N, and PR-O. Although the proteins encoded by these cDNAs have not been identified, their deduced amino acid sequences have slightly basic or neutral calculated isoelectric points, as well as carboxy-terminal extensions. These physical characteristics are shared by the vacuolar form of β-1,3-glucanase and other vacuolar localized analogs of PR proteins, suggesting that the unidentified proteins may be similarly localized. A preliminary evolutionary model that separates the β-1,3-glucanase gene family from tobacco into at least five distinct subfamilies is proposed. The expression of β-1,3-glucanase messenger RNAs (mRNAs) in response to infection by tobacco mosaic virus was examined. Messages for the acidic glucanases were induced similarly to the mRNAs for other PR proteins. However, the basic glucanase showed a different response, suggesting that different isoforms are differentially regulated by tobacco mosaic virus infection at the mRNA level.     

Evidence for a role of β-1,3-glucanase in dicot seed germination

Class I β-1,3-glucanases are antifungal vacuolar proteins implicated in plant defense that show developmental, hormonal, and pathogenesis-related regulation. The expression was studied in germinating tobacco seeds of a chimeric β-glucuronidase (GUS) reporter gene fused to 1.6 kb of the 5' flanking sequence of the tobacco class I β-1,3-glucanase B (GLB) promoter. Histological staining for GUS activity showed that expression of the GLB promoter is highly localized in a specific zone of the endosperm in germinating seeds. The temporal and spatial patterns of GUS and β-1,3-glucanase activity found, suggest a novel function for class I β-1,3-glucanases during seed germination in a dicotyledonous plant.     

Developmental,hormonal, and pathogenesis-related regulation of the tobacco class I β-1,3-glucanase B promoter

The class I -1,3-glucanases are antifungal vacuolar proteins implicated in plant defense that show developmental, hormonal, and pathogenesis-related regulation. The tobacco enzymes are encoded by a small gene family with members derived from ancestors related to the present-day species Nicotiana sylvestris and N. tomentosiformis. We studied the expression in transgenic tobacco plants of a chimeric -glucuronidase (GUS) reporter gene fused to 1.6 kb of upstream sequence of the tobacco class I -1,3-glucanase B (GLB) gene, which is of N. tomentosiformis origin. Expression of the GUS reporter gene and the accumulation of class I -1,3-glucanase and its mRNA showed very similar patterns of regulation. In young seedlings the reporter gene was expressed in the roots. In mature tobacco plants it was preferentially expressed in lower leaves and roots and was induced in leaves by ethylene treatment and by infection with tobacco mosaic virus (TMV). Furthermore, it was down-regulated in cultured leaf discs by combinations of the hormones auxin and cytokinin. Histological studies of GUS activity showed that the GLB promoter shows highly localized expression in roots of seedlings. It is also expressed in a ring of cells around necrotic lesions induced by TMV infection, but not in cells immediately adjacent to the lesions or in the lesions themselves. The results of deletion analyses suggest that multiple positive and negative elements in the GLB promoter regulate its activity. The region from –1452 to –1193 containing two copies of the heptanucleotide AGCCGCC, which is highly conserved in plant-stress and defense-related genes, is necessary for high level expression in leaves. Additional regions important for organ-specific and regulated expression were: –568 to –402 for ethylene induction of leaves; –402 to –211 for expression in lower leaves and cultured leaf discs and for TMV induction of leaves; and –211 to –60 for expression in roots.     

Induction of UDP-Glucose:Salicylic Acid Glucosyltransferase Activity in Tobacco Mosaic Virus-Inoculated Tobacco (Nicotiana tabacum) Leaves

Salicylic acid (SA) is a putative signal that activates plant resistance to pathogens. SA levels increase systemically following the hypersensitive response produced by tobacco mosaic virus (TMV) inoculation of tobacco (Nicotiana tabacum L. cv Xanthi-nc) leaves. The SA increase in the inoculated leaf coincided with the appearance of a [beta]-glucosidase-hydrolyzable SA conjugate identified as [beta]-O-D-glucosylsalicylic acid (GSA). SA and GSA accumulation in the TMV-inoculated leaf paralleled the increase in the activity of a UDP-glucose:salicylic acid 3-O-glucosyltransferase (EC 2.4.1.35) ([beta]-GTase) capable of converting SA to GSA. Healthy tissues had constitutive [beta]-GTase activity of 0.076 milliunits g-1 fresh weight. This activity started to increase 48 h after TMV inoculation, reaching its maximum (6.7-fold induction over the basal levels) 72 h after TMV inoculation. No significant GSA or elevated [beta]-Gtase activity could be detected in the healthy leaf immediately above the TMV-inoculated leaf. The effect of TMV inoculation on the [beta]-GTase and GSA accumulation could be duplicated by infiltrating tobacco leaf discs with SA at the levels naturally produced in TMV-inoculated leaves (2.7-27.0 [mu]g g-1 fresh weight). Pretreatment of leaf discs with the protein synthesis inhibitor cycloheximide inhibited the induction of [beta]-GTase by SA and prevented the formation of GSA. Of 12 analogs of SA tested, only 2,6-dihydroxybenzoic acid induced [beta]-GTase activity.     

Systemic movement of a tobamovirus requires host cell pectin methylesterase

Systemic movement of plant viruses through the host vasculature, one of the central events of the infection process, is essential for maximal viral accumulation and development of disease symptoms. The host plant proteins involved in this transport, however, remain unknown. Here, we examined whether or not pectin methylesterase (PME), one of the few cellular proteins known to be involved in local, cell-to-cell movement of tobacco mosaic virus (TMV), is also required for the systemic spread of viral infection through the plant vascular system. In a reverse genetics approach, PME levels were reduced in tobacco plants using antisense suppression. The resulting PME antisense plants displayed a significant degree of PME suppression in their vascular tissues but retained the wild-type pattern of phloem loading and unloading of a fluorescent solute. Systemic transport of TMV in these plants, however, was substantially delayed as compared to the wild-type tobacco, suggesting a role for PME in TMV systemic infection. Our analysis of virus distribution in the PME antisense plants suggested that TMV systemic movement may be a polar process in which the virions enter and exit the vascular system by two different mechanisms, and it is the viral exit out of the vascular system that involves PME.     

Induction of Systemic Resistance to Tobacco Powdery Mildew by Tobacco Mosaic Virus, Tobacco Necrosis Virus or Ethephon

Local infections of either TMV or TNV in tobacco plants cv. Havana 425 (hypersensitive to TMV) proved effective in inducing systemic resistance to subsequent inoculation with the powdery mildew fungus Erysiphe cichoracearum DC. The proportion of leaf surface invaded by this pathogen and the amount of conidia it produced were both significantly lower in virus inoculated plants than in non-inoculated controls. However, the decrease in sporulation rate was less regularly observed than the reduction in leaf area infected. TMV was more effective than TNV in protecting tobacco plants from powdery mildew. E. cichoracearum is thus added to the list of challenge pathogens to which TMV or TNV are known to induce resistance in the host plants. Necrotic lesions caused to the leaves by local treatment with Ethephon (an ethylene-releasing compound) also conferred to tobacco some degree of systemic resistance to the same fungal pathogen, more frequently visible as a reduction of leaf area invaded. The protection due to the Ethephon lesions was in present experiments less marked than that of TMV. No effects against subsequent powdery mildew infection were obtained when point freeze necrotic lesions were provoked on the plants.