Hostname: page-component-78c5997874-ndw9j Total loading time: 0 Render date: 2024-11-06T03:54:14.987Z Has data issue: false hasContentIssue false

Influence of Soil Moisture Stress on Vegetative Growth and Mycorrhizal Colonization in Hound’s-tongue (Cynoglossum officinale)

Published online by Cambridge University Press:  30 December 2016

Mina Momayyezi*
Affiliation:
Graduate Student and Professor, Faculty of Land and Food Systems, University of British Columbia, Vancouver, BC V6T 1Z4, Canada
Mahesh K. Upadhyaya
Affiliation:
Graduate Student and Professor, Faculty of Land and Food Systems, University of British Columbia, Vancouver, BC V6T 1Z4, Canada
*
*Corresponding author’s E-mail: [email protected]
Rights & Permissions [Opens in a new window]

Abstract

Hound’s-tongue is an invasive, biennial weed that thrives in dry rangelands of British Columbia. Rosette formation in the first year of growth and a deep root system offer this weed a competitive advantage against associated grasses under dry conditions. To study effects of water stress on seedling growth and mycorrhizal colonization in hound’s-tongue, seedlings of this weed were grown in pots in a greenhouse and subjected to four (100, 80, 60, and 40% of field capacity) soil moisture treatments. Effects of soil moisture stress (SMS) on several growth parameters as well as mycorrhizal colonization of roots were studied. The total biomass, shoot and root fresh and dry weights, leaf number, petiole length, leaf area, and specific leaf weight (leaf dry weight per unit leaf area) decreased with increasing SMS; shoot and root water content was not affected. Because of a greater effect of SMS on root compared with the shoot biomass, shoot:root ratio increased as the moisture stress increased. Water stress decreased mycorrhizal colonization and arbuscule and vesicle abundance. A reduction in total biomass, leaf number and leaf area per plant, petiole length, and mycorrhizal colonization may reduce the competitive advantage of hound’s-tongue over its neighbors under drought conditions. The effect on plant size may also influence herbivory, by biocontrol agents and other herbivores, and fecundity of this weed.

Type
Weed Biology and Ecology
Copyright
© Weed Science Society of America, 2016 

Soil moisture stress (SMS) is a major factor limiting plant productivity in dry rangelands of British Columbia. Response to SMS depends on the species, stage of the life cycle, and the severity of stress. Plant species use a variety of mechanisms to deal with this stressor (Bray Reference Bray1997; Chaves et al. Reference Chaves, Pereira, Maroco, Rodrigues, Ricardo, Osόrio, Carvalho, Faria and Pinheiro2002; Hsiao Reference Hsiao1973). Knowledge of how SMS influences growth parameters of a species, which could impact its interaction with biotic and abiotic environments, is important to understanding its performance under drought conditions.

Hound’s-tongue (family Boraginaceae) is a biennial or short-lived perennial weed, a native of Eurasia and Asia. This invasive weed is found in several provinces of Canada and thrives mostly under dry rangeland conditions (Boorman and Fuller Reference Boorman and Fuller1984; Upadhyaya et al. Reference Upadhyaya, Tilsner and Pitt1988; Upadhyaya and Cranston Reference Upadhyaya and Cranston1991). In addition to competition for resources and allelopathic influence (Furness et al. Reference Furness, Adomas, Dai, Li and Upadhyaya2008), which could reduce yield of associated grasses, this weed contains pyrrolizidine alkaloids, which are poisonous to livestock (Baker et al. Reference Baker, Smart, Ralphs and Molyneux1989; Knight et al. Reference Knight, Kimberling, Stermitz and Roby1984; Upadhyaya and Cranston Reference Upadhyaya and Cranston1991). Rosette formation in the first year of establishment and a deep root system provide competitive advantage to this weed against associated grasses under dry rangeland conditions. Upadhyaya and Furness (Reference Upadhyaya and Furness1994) studied effects of SMS on hound’s-tongue leaf-surface morphology and reported that neither the abundance nor the morphology of trichomes on leaf surface plays any significant role in acclimation of this weed to drought conditions. Beyond this research, little information is available on how SMS influences various growth parameters of hound’s-tongue that could influence its interaction with associated species.

The term “mycorrhiza” refers to a symbiotic relationship between a plant and a soil-borne fungus in which the plant provides resources for growth of the fungus, which in turn helps the plant acquire water and nutrients from the soil. Mycorrhizal fungi play an important role in uptake of nutrients (particularly phosphorus), stimulate plant growth and productivity, increase drought tolerance and subsequent recovery from water stress, improve water use efficiency and the ability of plants to extract water from the soil, and offer protection against soil-borne pathogens (Barea et al. Reference Barea, Pozo, Azcon and Azcon-Aguilar2005; Boomsma and Vyn Reference Boomsma and Vyn2008; Kaya et al. Reference Kaya, Higgs, Kirnak and Tas2003; Johansson et al. Reference Johansson, Paul and Finlay2004; Subramanian et al. Reference Subramanian, Charest, Dwyer and Hamilton1995). SMS has been reported to influence mycorrhizal colonization in some but not all plant species (Busso et al. Reference Busso, Bolletta, Flemmer and Montani2008; Wu and Xia Reference Wu and Xia2006). While it has been reported that hound’s-tongue is a mycorrhizal weed (Pendleton and Smith Reference Pendleton and Smith1983), whether SMS influences colonization of roots of this weed by arbuscular, vesicular mycorrhizal fungus is not known.

The objectives of this study were: (1) to study effects of SMS on important vegetative growth parameters of hound’s-tongue and (2) to determine whether SMS influences mycorrhizal colonization of this weed. This information is necessary to improve our understanding of the ecophysiology of this serious rangeland weed.

Material and Methods

Hound’s-tongue nutlets collected at Lethbridge, AB (49.69°N, 112.84°W) were soaked in water for 2 to 3 h, and a dissecting needle was used to remove the pericarps and seed coats from the embryos. The embryos were placed on two 11-cm-diameter Whatman No.1 filter disks wetted with 2 ml of deionized distilled water in 9 cm petri dishes for 48 to 72 h under laboratory conditions. Seedlings with ≥5-mm-long radicles were planted in 14-cm-diameter pots containing a sandy-loam potting soil with 6% organic matter in the Horticulture Greenhouse of the University of British Columbia, Vancouver, BC (49.26°N, 123.25°W) under natural light supplemented with high-pressure sodium lamps (10 hd−1; minimum photosynthetically active radiation: 400 µE m−2 s−1) and at 22 to 28 C temperature. Seedlings were thinned to one per pot and given SMS treatments starting at the third true-leaf stage, as described in the following section. Natural, soil-borne spores were the source of mycorrhizal inoculum.

SMS Treatments

Hound’s-tongue seedlings were given four SMS (100, 80, 60, and 40% of field capacity [FC]) treatments. To determine the soil moisture content at the FC, 300 g (four replications) soil was watered to saturation (point of no additional water absorption) and drained for 24 h, and its percent moisture content was calculated by weighing it before and after drying at 60 C for 72 h. The amount of soil moisture to achieve 80, 60, and 40% FC was calculated, and the various soil moisture treatments were achieved by adding an appropriate amount of water to a fixed weight of soil. The soil moisture content at 100, 80, 60, and 40% FC was approximately 0.348, 0.191, 0.126, and 0.084 m−3 water m−3 soil, respectively. The soil water content during the experiment was measured using a ProCheck soil moisture sensor (Decagon Devices, Pullman, WA) every second day during the experiment, and water was added as necessary to maintain the desired moisture levels.

Preparation of Roots for Observing Mycorrhizae

Hound’s-tongue rosettes were harvested 8 wk after the start of SMS treatments. The roots were separated from the shoots and washed thoroughly under running tap water to remove soil. To measure mycorrhizal colonization, roots were cut into 2 cm fragments, placed in 50 by 30 by 5 mm plastic cassettes (TRUFLOW Biopsy Cassettes, Fisher Scientific, Toronto, ON), and boiled in 10% KOH for 3 to 5 min. The cassettes were washed under tap water, immersed in 3% HCl for 2 min, and washed under running tap water and then with deionized distilled water. The roots were removed from the cassettes and stained with 0.05% trypan blue (Sigma-Aldrich, St. Louis, MO) in deionized distilled water, glycerol, and lactic acid (1:1:1) solution (Cao et al. Reference Cao, Wu and Zou2013; Gange et al. Reference Gange, Bower, Stagg, Aplin, Gillam and Bracken1999). The stained roots were observed under a Leica DM750 microscope (40×; Leica Microsystems, Concord, ON), and mycorrhizal colonization and percent arbuscule and vesicle abundance were measured using the scoring procedure described by Trouvelot et al. (Reference Trouvelot, Kough and Gianninazzi-Pearson1986). There were 10 replications of one plant each per treatment. Mycorrhizal colonization and arbuscule and vesicle abundance in five 2-cm-long root segments from each plant were recorded, and averages were calculated.

Effect of SMS on Hound’s-tongue Growth

Plant, root, and shoot fresh biomass were recorded. Roots and shoots were weighed before and after drying at 60 C for 48 h to measure their dry biomass, and the percent moisture content was calculated. Leaf number per plant was recorded. Leaf greenness (three readings per plant for the youngest true leaf), leaf area per plant, and petiole length were measured using a SPAD-502Plus chlorophyll meter (Konica Minolta Optics, Ramsey, NJ), a leaf area meter, and a Vernier calliper, respectively. The SPAD-502Plus determines leaf greenness, an indicator of relative chlorophyll content, by measuring leaf absorbance in blue (400 to 500 nm) and red (600 to 700 nm) wavelength regions. The specific leaf weight (SLW; dry leaf biomass [g] per leaf area [cm2]) was calculated.

A completely randomized design with 10 replications of one plant each per SMS treatment was used. The experiment was conducted twice. All data were subjected to analysis of variance using the general linear model (GLM) procedure of the SAS software (version 9.2; SAS Institute 2009). Data were checked for normality and uniformity of variance and were transformed as needed. Multiple mean comparisons were run using the GLM procedure of SAS (P=0.001, Bonferroni adjustment) and the P value was adjusted for the number of t-tests. Since there were significant treatment by experiment interactions for most of the parameters observed, results of both experiments are presented.

Results and Discussion

Effect of Soil Moisture Level on Plant Growth

Hound’s-tongue plant fresh biomass decreased with decreasing soil moisture level (P≤0.001) (Figure 1A). Compared with 100% FC, plants at 40 and 60% FC were 87 and 70% smaller on a fresh biomass basis in experiment 1 and 84% and 60% smaller in experiment 2, respectively. While the plants in experiment 2 were shorter compared with experiment 1, effects of soil moisture level on plant shoot and root biomass were generally similar. SMS reduced hound’s-tongue plant biomass due to reductions in both the shoot and the root biomass; both shoot and root fresh and dry weights decreased with decreasing soil moisture level (P≤0.001) (Figure 1B, C). Interestingly, as soil moisture level decreased, the shoot to root biomass ratio (S:R) increased significantly. S:R of hound’s-tongue plants grown at 100, 80, 60, and 40% FC were 0.35, 0.61, 1.00, and 1.41, respectively, in experiment 1, and 0.50, 0.82. 0.91, and 1.44, respectively, in experiment 2. This suggests that the reduction of hound’s-tongue root dry biomass with increasing SMS was much greater compared with that of the shoot dry biomass, resulting in an increase in the S:R ratio. Except for a significant (P≤0.001) reduction in shoot water content at 40% FC compared with all other SMS treatments in experiment 2, soil moisture level did not influence the shoot or root water content (Figure 2).

Figure 1 Effect of soil moisture level (% of FC) on hound’s-tongue (A) plant, (B) shoot, and (C) root fresh (——) and dry (- - - -) biomass; (∙) and (○) indicate results of experiments 1 and 2, respectively. Values are means±SE of 10 replicates of one plant each.

Figure 2 Effect of soil moisture level (% of FC) on (A) shoot and (B) root water content of hound’s-tongue plants; (∙) and (○) indicate results of experiments 1 and 2, respectively. Values are means±SE of 10 replicates of one plant each.

The leaf area and the number of leaves per plant decreased as soil moisture level decreased from 100 to 40% FC (P≤0.001) (Figure 3A). In both experiments, the plants grown under 40% FC had 38% shorter petioles compared with those grown at 100% FC (P≤0.001) (Figure 3B). The SLW was lower for plants grown under 40% FC compared with 100% FC in both experiments (P≤0.001) (Figure 3C). The leaf greenness (chlorophyll meter reading) for plants grown under 100% FC was slightly lower compared with those at 80% FC, but this decline was significant (P≤0.001) only in experiment 2 (Figure 3D). Since experiment 1 of this study was conducted in July and August, and experiment 2 was conducted in October and November, the difference in plant growth in the two experiments could be due to the difference in light intensity, day length, and temperature conditions between the summer (July and August) and fall (October and November) in Vancouver, BC. The day length dropped from 14 to 10 h from August to October and the greenhouse temperature from 28 to 22 C.

Figure 3 Effect of soil moisture level (% of FC) on hound’s-tongue (A) leaf area (——) and leaf number (- - - -) per plant, (B) petiole length, (C) specific leaf weight, and (D) leaf greenness (chlorophyll meter reading); (∙) and (○) indicate results of experiments 1 and 2, respectively. Values are means±SE of 10 replicates of one plant each.

Hound’s-tongue is a serious rangeland weed of BC and some other parts of the world (Upadhyaya and Cranston Reference Upadhyaya and Cranston1991; Upadhyaya et al. Reference Upadhyaya, Tilsner and Pitt1988). It infests relatively sunny and dry regions of BC (Upadhyaya et al. Reference Upadhyaya, Tilsner and Pitt1988). Success of this weed under dry rangeland conditions has been attributed to its deep root system, which provides a competitive advantage against shallow-rooted grasses. The effects of SMS on early hound’s-tongue growth reported in this study have several ecological implications for this weed under dry rangeland conditions. The plants with lower leaf area and shorter petiole are expected to be less competitive because of their lower canopy coverage to shade shorter associated species (Tremmel and Bazzaz Reference Tremmel and Bazzaz1993, Weijschedé et al. Reference Weijschedé, Martínková, de Kroon and Huber2006). In addition to impacting the dominance of hound’s-tongue over other species, water stress could also impact survival and distribution of this weed in rangelands. De Jong and Klinkhamer (Reference De Jong and Klinkhamer1988) reported a positive correlation between survival of hound’s-tongue seedlings and water content in the top 10 cm of soil under field conditions; seedling survival was found to improve upon watering. They suggested that soil moisture availability was one of the main factors in determining the spatial distribution of hound’s-tongue in the coastal sand dunes of Meijendel, the Netherlands. However, in our pot-culture, greenhouse experiments, no plant mortality was observed. Because effects of environmental factors during the juvenile phase of plant development are important in determining subsequent survival, distribution, and domination of adult plants, we limited our investigation to only the first 8 wk of the hound’s-tongue life cycle. Even a small advantage during this phase can be pivotal in determining the subsequent success of this weed. Smaller plants produced at high SMS (40 and 60% FC) are also expected to produce a fewer seeds per plant, which may impact the persistence of this weed.

Plant size has been reported to be related to aboveground herbivory (Rowell-Rahier Reference Rowell-Rahier1984; Tiritilli and Thompson Reference Tiritilli and Thompson1988; van der Meijden et al. Reference van der Meijden, Wijn and Verkaar1988). In a study of the relationship between hound’s-tongue plant size and root herbivory by the root weevil Ceuthorhynchus cruciger, Prins et al. (Reference Prins, Nell and Klinkhamer1992) found that attacks by this insect pest were highly size dependent. Weevils preferred larger compared with smaller plants; a higher percentage of flowering plants were infested as the root crown diameter increased. Weevil attack significantly reduced seed production in terms of both number and weight of seeds per unit plant weight. Larger hound’s-tongue plants produced at higher FCs are therefore expected to attract more herbivores, which could influence resource allocation for seed production. Water stress has been reported to influence feeding and oviposition by beet army worm (Spodoptera exigua) in Palmer amaranth pigweed (Moran and Showler Reference Moran and Showler2005). Changes in leaf chemistry can influence insect feeding, growth, and/or reproduction (Mattson and Haack Reference Mattson and Haack1987; White Reference White1984). We have found that SMS influences feeding preference and the biomass of grasshoppers feeding on hound’s-tongue leaf disks, which could be related to the increase in leaf disk N content with increasing SMS (Momayyezi Reference Momayyezi2012).

Rosette leaves of hound’s-tongue have been reported to contain high concentrations of the pyrrolizidine alkaloids heliosupine, acetyl-heliosupine, and echinatine (Knight et al. Reference Knight, Kimberling, Stermitz and Roby1984; Upadhyaya et al. Reference Upadhyaya, Tilsner and Pitt1988). Concentration of these alkaloids, which are responsible for livestock poisoning, can reach as high as 2.1% on the dry weight basis. These alkaloids also have antifeedant and deterrent effects against generalist herbivores (Van Dam et al. Reference Van Dam, Vuister, Bergshoeff, de Vos and van Der Meijden1995). Water leachate of hound’s-tongue leaves and embryos has been reported to exert allelopathic influence on associated rangeland grasses (Furness et al. Reference Furness, Adomas, Dai, Li and Upadhyaya2008; Rashid et al. Reference Rashid, Furness, Upadhyaya and Ellis2005). Whether SMS influences poisoning and/or allelopathic potential of leaves of this weed remains to be investigated.

Effect of Soil Moisture Level on Mycorrhizal Colonization

The results of this study show that SMS has a strong negative influence on mycorrhizal colonization and arbuscule and vesicle abundance in hound’s-tongue roots. Soil moisture level influenced mycorrhizal colonization significantly (P≤0.001) in both experiments (Figure 4A). It increased linearly as soil moisture level increased from 40 to 100% FC (Figure 4A). Mycorrhizal colonization of roots of plants grown under 100% FC was 6-fold higher compared with those grown at 40% FC. Similarly, arbuscule and vesicle abundance also increased as soil moisture level increased from 40 to 100% FC in both experiments (P≤0.001) (Figure 4B, C). Mycorrhizal colonization and arbuscule and vesicle abundance were generally lower in the second experiment compared with the first, and the increase in arbuscule abundance with increasing soil moisture level appeared to be curvilinear in both experiments. Interestingly, the magnitude of impact of SMS was greatest on mycorrhizal colonization, followed by arbuscule and vesicle abundance, in that order. This could be because the fungus colonizes the roots first, forms arbuscules, and then vesicles, which are storage structures particularly for lipids (Peterson et al. Reference Peterson, Massicotte and Melville2004). The influence of SMS on mycorrhizal colonization could be due to a drought-induced reduction in the supply of photosynthate from the shoot to the roots, production of a messenger in the shoot that is transmitted to the roots, a direct effect on the roots, hyphal desiccation in dry soil, inhibition of fungal spore germination in soil, and/or inhibition of root infection (Augé Reference Augé2001; Querejeta et al. Reference Querejeta, Egerton-Warburton and Allen2007). Pyrrolizidine alkaloids have been reported to inhibit fungal mycelium growth (Hol and van Veen Reference Hol and van Veen2002). Whether alkaloids found in hound’s-tongue are involved in the influence of SMS on mycorrhizal colonization of its roots or in the allelopathic effect of this weed on its neighbors remains to be investigated. Regardless of the mechanism involved, a reduction of mycorrhizal colonization of roots of this weed by SMS in combination with a decrease in root biomass can reduce competitive ability of this weed against its neighbors. The effect of mycorrhizal colonization on competitive interaction of hound’s-tongue with associated species would, of course, depend on the species present in the mixture (mycorrhizal vs. nonmycorrhizal) and their response to mycorrhizal colonization (Allen and Allen Reference Allen and Allen1984, Reference Allen and Allen1990; Benjamin and Allen Reference Benjamin and Allen1987; Crush Reference Crush1974; Fitter Reference Fitter1977; Hall Reference Hall1978; Harnett et al. Reference Harnett, Hetrick, Wilson and Gibson1993; West Reference West1996).

Figure 4 Effect of soil moisture level (% of FC) on (A) mycorrhizal colonization and (B) arbuscule and (C) vesicle abundance in the mycorrhizal part of roots; (∙) and (○) indicate results of experiments 1 and 2, respectively. Values are means±SE of 10 replicates of one plant each. Observations were taken on five 2-cm-long root segments for each plant.

This study characterizes the influence of SMS on seedling growth and mycorrhizal colonization of hound’s-tongue roots, which can potentially affect the weed’s survival, competition and allelopathic interactions, root functions, fecundity, persistence, and biological control. The results of this study show that SMS influences a variety of plant growth parameters and mycorrhizal colonization of roots in hound’s-tongue, a serious rangeland weed of BC. These effects include reductions in total biomass, fresh and dry weight of shoots and roots, leaf area, SLW (leaf dry weight per unit leaf area), leaf number and petiole length, percent mycorrhizal colonization, and the abundance of arbuscules and vesicles in the colonized parts of the root. These effects may impact interaction of hound’s-tongue with its nonmycorrhizal neighbors or with species that are mycorrhizal but affected to a different extent by the SMS compared with this weed.

Acknowledgments

We thank the Natural Sciences and Engineering Research Council of Canada and the Brigadier Bostock Memorial Fund for financial support, and Valerie LeMay, Professor, Forest Resources and Management, University of British Columbia, for help with statistical analysis.

Footnotes

Associate Editor for this paper: Hilary A. Sandler, University of Massachusetts.

References

Literature Cited

Allen, EB, Allen, MF (1984) Competition between plants of different successional stages: mycorrhizae as regulators. Can J Bot 62:26252629 Google Scholar
Allen, EB, Allen, MF (1990) The mediation of competition by mycorrhizae in successional and patchy environments. Pages 367389 in Grace JB, Tilman D, eds. Perspectives on Plant Competition. San Diego, CA: Academic Press Google Scholar
Augé, RM (2001) Water relations, drought and vesicular-arbuscular mycorrhizal symbiosis. Mycorrhiza 11:342 Google Scholar
Baker, DC, Smart, RA, Ralphs, M, Molyneux, RJ (1989) Hound’s-tongue (Cynoglossum officinale) poisoning in a calf. J Am Vet Med Assoc 195:929930 Google Scholar
Barea, J, Pozo, MJ, Azcon, R, Azcon-Aguilar, C (2005) Microbial co-operation in the rhizosphere. J Exp Bot 56:17611778 CrossRefGoogle ScholarPubMed
Boomsma, CR, Vyn, TJ (2008) Maize drought tolerance: potential improvements through arbuscular mycorrhizal symbiosis? Field Crops Res 108:1431 Google Scholar
Boorman, LA, Fuller, RM (1984) The comparative ecology of two sand dune biennials: Lactuca virosa L. and Cynoglossum officinale L. New Phytol 69:609629 Google Scholar
Bray, EA (1997) Plant responses to water deficit. Trends Plant Sci 2:4854 Google Scholar
Benjamin, PK, Allen, EB (1987) The influence of VA mycorrhizal fungi on competition between plants of different successional stages in sagebrush grassland. Page 144 in Sylvia DM, Hung LL, Graham JH, eds. Mycorrhizae in the Next Decade, Practical Application and Research Priorities. Gainesville, FL: Institute of Food and Agricultural Sciences Google Scholar
Busso, CA, Bolletta, A, Flemmer, AC, Montani, T (2008) Influence of soil water status on arbuscular mycorrhizas in three perennial grasses in central Argentina. Ann Bot Fennici 45:435447 Google Scholar
Cao, M, Wu, Q, Zou, Y (2013) An improved ink-acetic acid technique for staining arbuscular mycorrhizas of citrus. Int J Agr Biol 15:386388 Google Scholar
Chaves, MM, Pereira, JS, Maroco, J, Rodrigues, ML, Ricardo, CPP, Osόrio, ML, Carvalho, I, Faria, T, Pinheiro, C (2002) How plants cope with water stress in the field? Photosynthesis and growth. Ann Bot 89:907916 CrossRefGoogle ScholarPubMed
Crush, JR (1974) Growth responses to vesicular-arbuscular mycorrhiza in herbage legumes. New Phytol 73:743749 Google Scholar
De Jong, TJ, Klinkhamer, PGL (1988) Population ecology of the biennials Cirsium vulgare and Cynoglossum officinale in a coastal sand-dune area. J Ecol 76:366382 Google Scholar
Furness, NH, Adomas, B, Dai, Q, Li, S, Upadhyaya, MK (2008) Allelopathic influence of houndstongue (Cynoglossum officinale) and its modification by UV-B radiation. Weed Technol 22:101107 Google Scholar
Fitter, AH (1977) Influence of mycorrhizal infection on competition for phosphorus and potassium by two grasses. New Phytol 79:119125 Google Scholar
Gange, AC, Bower, E, Stagg, PG, Aplin, DM, Gillam, AE, Bracken, M (1999) A comparison of visualization techniques for recording arbuscular mycorrhizal colonization. New Phytol 142:123132 Google Scholar
Hall, IR (1978) Effects of endomycorrhiza on the competitive ability of white clover. New Phytol 21:509515 Google Scholar
Harnett, DC, Hetrick, BAD, Wilson, GTW, Gibson, DJ (1993) Mycorrhizal influence of intra- and inter-specific neighbourhood interaction among co-occurring prairie grasses. J Ecol 81:787795 Google Scholar
Hol, WHG, van Veen, JA (2002) Pyrrolizidine alkaloids from Senecio jacobaea affect fungal growth. J Chem Ecol 28:17631772 Google Scholar
Hsiao, TC (1973) Plant responses to water stress. Ann Rev Plant Physiol 24:519570 Google Scholar
Johansson, JF, Paul, LR, Finlay, RD (2004) Microbial interactions in the mycorrhizosphere and their significance for sustainable agriculture. FEMS Microb Ecol 48:113 Google Scholar
Kaya, C, Higgs, D, Kirnak, H, Tas, I (2003) Mycorrhizal colonization improves fruit yield and water use efficiency in watermelon (Citrullus lanatus Thunb.) grown under well-watered and water-stressed conditions. Plant Soil 253:287292 CrossRefGoogle Scholar
Knight, AP, Kimberling, CV, Stermitz, FR, Roby, MR (1984) Cynoglossum officinale (hound’s-tongue)—a cause of pyrrolizidine alkaloid poisoning in horses. J Am Vet Med Assoc 184:647650 Google Scholar
Mattson, W, Haack, R (1987) Role of drought in outbreaks of plant-eating insects. BioScience 37:110118 Google Scholar
Momayyezi, M (2012) The effect of soil moisture stress on allelopathic influence of hound’s-tongue (Cynoglossum officinale L.). M.Sc. Thesis, Univ. of British Columbia, Vancouver, Canada. 74 pGoogle Scholar
Moran, PJ, Showler, AT (2005) Plant responses to water deficit and shade stresses in pigweed and their influence on feeding and oviposition by the beet armyworm (Lepidoptera; Noctuidae). Environ Entomol 34:929937 Google Scholar
Pendleton, RL, Smith, BN (1983) Vesicular-arbuscular mycorrhizae of weedy and colonizer plant species at disturbed sites in Utah. Oecologia 59:296301 Google Scholar
Peterson, RL, Massicotte, HB, Melville, LH (2004) Mycorrhizas: Anatomy and Cell Biology. Wallingford, Oxon, UK: CABI Publishing. 173 pGoogle Scholar
Prins, AH, Nell, HW, Klinkhamer, PGL (1992) Size-dependent root herbivory on Cynoglossum officinale . Oikos 65:409413 CrossRefGoogle Scholar
Querejeta, JI, Egerton-Warburton, LM, Allen, MF (2007) Hydraulic lift may buffer rhizosphere hyphae against the negative effects of severe soil drying in a California Oak savanna. Soil Biol Biochem 39:409417 Google Scholar
Rashid, A, Furness, NH, Upadhyaya, MK, Ellis, BE (2005) Inhibition of seed germination and seedling growth by hound’s-tongue (Cynoglossum officinale L.) seed leachate. Weed Biol Manag 5:143149 Google Scholar
Rowell-Rahier, M (1984) The food plant preferences of Phratora vitellinae (Coleoptera: Chrysomelidae). Oecologia 64:369374 Google Scholar
Subramanian, KS, Charest, C, Dwyer, LM, Hamilton, RI (1995) Arbuscular mycorrhizas and water relations in maize under drought stress at tasselling. New Phytol 129:643650 Google Scholar
Tremmel, DC, Bazzaz, FA (1993) How neighbor canopy architecture affects target plant performance. Ecology 74:21142124 Google Scholar
Tiritilli, ME, Thompson, JN (1988) Variation in swallowtail/plant interactions; host selection and the shapes of survivorship curves. Oikos 53:153160 Google Scholar
Trouvelot, A, Kough, JL, Gianninazzi-Pearson, V (1986) Mesure du taux de mycorhization VA d’ un systeme radiculaire. Recherche de methods d’ estimation ayant une signification fonctionnelle. Pages 217221 in Gianinazzi-Pearson V, Gianinazzi S, eds. Physiological and Genetic Aspects of Mycorrhizae. Paris, France: INRA Google Scholar
Upadhyaya, MK, Cranston, R (1991) Distribution, biology, and control of hound’s-tongue in British Columbia. Rangelands 13:103106 Google Scholar
Upadhyaya, MK, Furness, NH (1994) Influence of light intensity and water stress on leaf surface characteristics of Cynoglossum officinale, Centaurea spp., and Tragopogon spp. Can J Bot 72:13791386 Google Scholar
Upadhyaya, MK, Tilsner, HR, Pitt, MD (1988) The biology of Canadian weeds. 87. Cynoglossum officinale L. Can J Plant Sci 68:763774 Google Scholar
Van Dam, NM, Vuister, LWM, Bergshoeff, C, de Vos, H, van Der Meijden, HV (1995) The “raison d’etre” of pyrrolizidine alkaloids in Cynoglossum officinal: deterrent effects against generalist herbivores. J Chem Ecol 21:507523 Google Scholar
van der Meijden, E, Wijn, M, Verkaar, HJ (1988) Defence and regrowth, alternative plant strategies in the struggle against herbivores. Oikos 51:355363 CrossRefGoogle Scholar
Weijschedé, J, Martínková, J, de Kroon, H, Huber, H (2006) Shade avoidance in Trifolium repens: costs and benefits of plasticity in petiole length and leaf size. New Phytol 172:655666 Google Scholar
West, HM (1996) Influence of arbuscular mycorrhizal infection on competition between Holcus lanatus and Dactylis glomerata . J Ecol 84:429438 Google Scholar
White, TCR (1984) The abundance of invertebrate herbivores in relation to the availability of nitrogen in stressed food plants. Oecologia 63:90105 Google Scholar
Wu, QS, Xia, RX (2006) Arbuscular mycorrhizal fungi influence growth, osmotic adjustment and photosynthesis of citrus under well-watered and water stress conditions. J Plant Physiol 163:417425 Google Scholar
Figure 0

Figure 1 Effect of soil moisture level (% of FC) on hound’s-tongue (A) plant, (B) shoot, and (C) root fresh (——) and dry (- - - -) biomass; (∙) and (○) indicate results of experiments 1 and 2, respectively. Values are means±SE of 10 replicates of one plant each.

Figure 1

Figure 2 Effect of soil moisture level (% of FC) on (A) shoot and (B) root water content of hound’s-tongue plants; (∙) and (○) indicate results of experiments 1 and 2, respectively. Values are means±SE of 10 replicates of one plant each.

Figure 2

Figure 3 Effect of soil moisture level (% of FC) on hound’s-tongue (A) leaf area (——) and leaf number (- - - -) per plant, (B) petiole length, (C) specific leaf weight, and (D) leaf greenness (chlorophyll meter reading); (∙) and (○) indicate results of experiments 1 and 2, respectively. Values are means±SE of 10 replicates of one plant each.

Figure 3

Figure 4 Effect of soil moisture level (% of FC) on (A) mycorrhizal colonization and (B) arbuscule and (C) vesicle abundance in the mycorrhizal part of roots; (∙) and (○) indicate results of experiments 1 and 2, respectively. Values are means±SE of 10 replicates of one plant each. Observations were taken on five 2-cm-long root segments for each plant.