2012
DOI: 10.1111/j.1600-0706.2012.20458.x
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When resources don't rescue: flowering phenology and species interactions affect compensation to herbivory in Ipomopsis aggregata

Abstract: The ability of plants to tolerate, or compensate for, herbivore damage is highly variable and has been the subject of much research. Although many plants can compensate for herbivore damage, and some even overcompensate, we cannot yet generalize about the conditions that promote a positive response to damage. Here, we asked how abiotic resources (i.e. plant nutrient status) coupled with biotic interactions – i.e. subsequent interactions with pollinators, seed predators and nectar robbing bumble bees – affect t… Show more

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Cited by 27 publications
(25 citation statements)
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“…In order to confirm that insects can select for overcompensation, ecologists need a better understanding of the costs and benefits (i.e., trade-offs) of reproductive and vegetative overcompensation on lifetime plant fitness (Tewari et al 2013, Scholes et al 2017b, West and Louda 2018. Other specific areas that need more research include (1) plant overcompensatory growth effects on pollination services (Lay et al 2011, Brody and Irwin 2012, Thomsen and Sargent 2017, (2) tradeoffs between male and female plant fitness (Gronemeyer et al 1997, Strauss et al 2003, (3) trade-offs between resource allocation to overcompensatory responses and chemical and physical defenses (Poveda et al 2012, Mesa et al 2017, (4) overcompensatory responses to damage by multiple herbivore species (Anderson and Paige 2003, Stephens et al 2013, Gagic et al 2016), (5) the role of fungal associations in plant overcompensatory responses (Borowicz 2013, Allsup andPaige 2016), and (6) the effects of damage timing Whitham 1989, Trumble et al 1993) and damage frequency (Scholes et al 2017a) on overcompensatory responses. In addition, ecologists evaluating overcompensation need to demonstrate that overcompensation is both genetically controlled and heritable in natural populations.…”
Section: Evolution Of Overcompensationmentioning
confidence: 99%
“…In order to confirm that insects can select for overcompensation, ecologists need a better understanding of the costs and benefits (i.e., trade-offs) of reproductive and vegetative overcompensation on lifetime plant fitness (Tewari et al 2013, Scholes et al 2017b, West and Louda 2018. Other specific areas that need more research include (1) plant overcompensatory growth effects on pollination services (Lay et al 2011, Brody and Irwin 2012, Thomsen and Sargent 2017, (2) tradeoffs between male and female plant fitness (Gronemeyer et al 1997, Strauss et al 2003, (3) trade-offs between resource allocation to overcompensatory responses and chemical and physical defenses (Poveda et al 2012, Mesa et al 2017, (4) overcompensatory responses to damage by multiple herbivore species (Anderson and Paige 2003, Stephens et al 2013, Gagic et al 2016), (5) the role of fungal associations in plant overcompensatory responses (Borowicz 2013, Allsup andPaige 2016), and (6) the effects of damage timing Whitham 1989, Trumble et al 1993) and damage frequency (Scholes et al 2017a) on overcompensatory responses. In addition, ecologists evaluating overcompensation need to demonstrate that overcompensation is both genetically controlled and heritable in natural populations.…”
Section: Evolution Of Overcompensationmentioning
confidence: 99%
“…Apical damage has led to compensation, and occasionally overcompensation, for herbivore damage in other systems. Haphazard variation in the timing and duration of insect herbivory and flowering delays due to apical damage can, however, reduce the likelihood of successful seed production and limit the reliability of fitness gains from compensation (Huhta et al 2000;Brody and Irwin 2012;Adhikari and Russell 2014). This variability increases the potential value of strong early-season apical investment, relative to fitness costs spread across multiple later flowering heads, when fitness must be realized under cumulative season-long insect pressure.…”
Section: Electronic Supplementary Materialsmentioning
confidence: 99%
“…Although C. canescens plants had the potential to tolerate loss of the large, early apical flower head investment, such tolerance was insufficient on average to override the fitness costs imposed by cumulative floral herbivory. The relative advantage of high early investment, that escapes herbivores, compared to that of releasing additional investment to other flowers, likely varies extensively in time and space (i.e., Brody and Irwin 2012;Klimešová et al 2014;Krimmel and Pearse 2016). For instance, Adhikari and Russell (2014) found a greater proportion of flowering heads developed in response to apical damage in another native thistle (Cirsium altissimum), but the fecundity of axillary flower heads was insufficient to provide compensatory seed production.…”
Section: Interaction Between Apical Damage and Cumulative Herbivorymentioning
confidence: 99%
“…[10], or the compensatory continuum hypothesis [5], but rather provide a reason that variables, such as net assimilation rate and leaf area ratio, are related to compensatory responses, and why compensatory growth is not always positively related to resource level [11].…”
Section: Discussionmentioning
confidence: 99%