Understanding strategies for seed dispersal by wind under contrasting atmospheric conditions

Wright, S. Joseph; Trakhtenbrot, Ana; Bohrer, Gil; Detto, Matteo; Katul, Gabriel G.; Horvitz, Nir; Muller‐Landau, Helene C.; Jones, F. Andrew; Nathan, Ran

doi:10.1073/pnas.0802697105

Cited by 102 publications

(140 citation statements)

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“…Our results are broadly applicable to other species because most plants are also xerochastic (Greene and Johnson 1992;Roche 1992;Nathan et al 1999;Mandak and Pysek 2001;Greene et al 2008;Wright et al 2008;Hamilton-Brown et al 2009). The prevalence of xerochasty suggests that seed release under hot, dry conditions may increase plant fitness, potentially by increasing dispersal distances.…”

Section: Discussionmentioning

confidence: 58%

“…If water supply to capitula is negligible during this period of active drying, then all of the components are available to incorporate with our results and weather data to mechanistically model the effects of evaporative conditions on seed release in the field -with the caveat that in order to know how many seeds release some biological data may be required. The addition of this information to our current knowledge of the effects of wind speed and turbulence on seed release (Greene 2005;Skarpaas et al 2006;Jongejans et al 2007;Wright et al 2008) will greatly improve the predictive power of mechanistic seed release and dispersal models.…”

Section: Discussionmentioning

confidence: 99%

“…Mechanistic seed release models are a key component necessary to understand under which conditions seeds disperse and how far they travel (Jongejans et al 2007;Soons and Bullock 2008;Wright et al 2008;Nathan et al 2011). Seeds that disperse long distances are more likely to have an appreciable impact on migration and gene flow.…”

Section: Discussionmentioning

confidence: 99%

“…Therefore, calls have been made for more research on this important topic (Schippers and Jongejans 2005;Kuparinen 2006;Nathan 2006). As more and more researchers investigate the mechanisms underlying seed release, it is becoming increasingly clear that seed release is not a random process, but occurs under certain predictable conditions (Greene and Johnson 1992;Tackenberg et al 2003;Greene 2005;Skarpaas et al 2006;Jongejans et al 2007;Soons and Bullock 2008;Hamilton-Brown et al 2009;Marchetto et al 2010b;Greene and Quesada 2011), which may vary by species (Wright et al 2008).…”

Section: Introductionmentioning

confidence: 99%

“…Physiologically, we understand what effects dry conditions have on capitula (Smith and Kok 1984;Fahn 1990) and seed attachment structures (Greene and Johnson 1992). Regression models have also been created to relate weather variables to seed release that include temperature (Wright et al 2008) or relative humidity (Greene et al 2008). However, temperature or relative humidity alone is a poor indicator of water loss by plants or of evaporation in general (Anderson 1936;de Bruin and Holtslag 1982;Sumner and Jacobs 2005).…”

Section: Introductionmentioning

confidence: 99%

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Water loss from flower heads predicts seed release in two invasive thistles

Marchetto

Jongejans

Shea

et al. 2012

Plant Ecology & Diversity

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Background: Non-random seed release caused by plant responses to weather conditions is important for seed dispersal. Much is known about the effects of wind speed and turbulence, but our understanding of the effects of water loss on seed release is either qualitative, or indirect and phenomenological. Aims: To quantify the empirical relationship between water loss and seed release. Methods: Capitula of the invasive thistles Carduus acanthoides and C. nutans were collected from the field and treated for either 0, 1, or 2 days in the laboratory at three different vapour pressure deficit levels (3.4, 9.5, and 17.0 hPa) to cause a range of water loss values. Total seed release was quantified before and during wind tunnel trials. Results: Water loss was the only significant predictor of whether or not capitula released any seeds. The number of seeds released was predicted by water loss, capitulum diameter, and herbivore damage, with the same amount of water loss having less effect on larger capitula. Conclusions: These results represent an important step towards using weather data to predict seed release for many xerochastic species. Incorporating the effects of water loss on seed release into mechanistic seed dispersal models will greatly improve predictions of when and how far seeds disperse. While initiation of dispersal in some species is more likely during precipitation events (Pufal and Garnock-Jones 2010), a majority of wind dispersed angiosperms and gymnosperms are xerochastic, meaning that drying enhances seed abscission and release (Greene et al. 2008). For many Asteraceae species, including the invasive thistles Carduus nutans L. and Carduus acanthoides L. (Figure 1), drying causes cohesion tissues located on the outer side of the involucral bracts to lose turgidity and buckle, causing the bracts to be lowered away from the seeds and thus exposing seeds to the wind (Fahn 1990). Drying may also cause contraction of the receptacle away from seeds (Smith and Kok 1984).The ubiquity of xerochastic plant species suggests that seed dispersal models could be made more realistic and accurate for a wide range of species if weather data describing potential evaporation could be used to mechanistically predict seed release. Two important pieces of information need to be re-examined to accomplish this goal. First, we must predict water loss from inflorescences using weather data. A number of models already exist that use weather data to predict water loss from entire plants (de Bruin and Holtslag 1982;Sumner and Jacobs 2005), and even from capitula separately from vegetative structures (Guilioni and Lhomme 2006). The second necessary piece of information, the relationship between water loss and seed release, must still be documented and is the focus of this paper.Currently, our understanding of the effects of water loss and weather on seed release is either qualitative or phenomenological. Physiologically, we understand what effects dry conditions have on capitula (Smith and Kok 1984;Fahn 1990) and seed attachm...

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Section: Discussionmentioning

confidence: 58%

Section: Discussionmentioning

confidence: 99%

Section: Discussionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

See 3 more Smart Citations

Water loss from flower heads predicts seed release in two invasive thistles

Marchetto

Jongejans

Shea

et al. 2012

Plant Ecology & Diversity

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Seed Dispersal

Nathan

Bullock

Ronce

et al. 2009

Encyclopedia of Life Sciences

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On line EncyclopediaThe sedentary life of adult plants accentuates the critical importance of the short phase during which individual plants move: the dispersal of seeds, a common, widespread and fascinating phenomenon. Ultimately, selective pressures favouring dispersal include inbreeding avoidance, reduction of competition with kin and nonkin and the tracking of establishment opportunities in time and space. Proximately, dispersal mechanisms include nonrandom release from the mother plant, and transport by multiple dispersal vectors not necessarily those inferred from the seed morphology. The resulting patterns, often described by dispersal kernes, typically show a decline in seed deposition with distance from the source and a tail of long-distance dispersal events. Dispersal has important consequences for the fate of individuals, populations, communities and ecosystems, enabling metapopulations and metacommunities to persist and playing a critical role in shaping the evolutionary and plastic response of plants to changing environments

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