Mapping risk to plant populations from short fire intervals via relationships between maturation period and environmental productivity

Gosper, Carl R.; Miller, Ben P.; Gallagher, Rachael V.; Kinloch, Janine; Dongen, Richard van; Adams, Emma; Barrett, S.; Cochrane, Anne; Comer, Sarah; McCaw, Lachlan; Miller, Russell G.; Prober, Suzanne M.; Yates, Colin J.

doi:10.1007/s11258-022-01229-6

Cited by 6 publications

(15 citation statements)

References 47 publications

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“…While there may be some cases of urgent ex situ conservation needs (e.g., threatened species management), seed collection should minimize impacts on the in situ seed bank. Essential seed collection should be undertaken with reference to the biology of the species and the productivity of the environment (Gosper et al, in press). In some instances, all seeds held within the canopy (serotiny) may be germinated, predated or burnt in a single fire event and soil seed banks may be similarly exhausted in a single fire (Auld & Denham, 2006).…”

Section: Discussionmentioning

confidence: 99%

An integrated approach to assessing abiotic and biotic threats to post‐fire plant species recovery: Lessons from the 2019–2020 Australian fire season

Gallagher

Allen

Mackenzie

et al. 2022

Global Ecol Biogeogr

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Section: Discussionmentioning

confidence: 99%

An integrated approach to assessing abiotic and biotic threats to post‐fire plant species recovery: Lessons from the 2019–2020 Australian fire season

Gallagher

Allen

Mackenzie

et al. 2022

Global Ecol Biogeogr

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“…Some changes will arise from climate-driven alterations to different dimensions of fire regimes, such as increases in severity that are governed by the combination of fire behavior and fire-adaptive (or sensitive) plant traits (Franco et al 2022). Other changes will emerge when shifting fire regimes interact with key demographic and community dynamics pre-fire (Agne et al 2022;Gosper et al 2022;Souto-Veiga et al 2022) and post-fire (Arroyo-Vargas et al 2022;Dawe et al 2022;Brehaut and Brown 2022); some occurring over evolutionary time scales (Lamont 2022;Ladd et al 2022). Finally, some changes will emerge as surprising outcomes from disturbances interacting in a linked (Lindenmayer et al 2022) or compound (Bendall et al 2022) manner.…”

Section: Discussionmentioning

confidence: 99%

“…Beyond characterizing the temporal window of immaturity risk, how the period of immaturity risk varies spatially-and additional drivers of seed abundance other than ontogeny-are critical factors for identifying locations and contexts at particular risk from fire-catalyzed loss of resilience. By modeling the regional distribution of the juvenile (i.e., reproductively immature) period for a wide range of serotinous obligate seeding species across southwestern Australia, Gosper et al (2022; this issue) contribute an important spatial dimension to understanding immaturity risk (Keeley et al 1999). Importantly, they demonstrate that the juvenile period is predicted to continue lengthening with further climate warming, extending the period of immaturity risk even if fire-return-intervals remain constant.…”

Section: Demographic Mechanisms Underpinning Resilience To Firementioning

confidence: 99%

Climate change and altered fire regimes: impacts on plant populations, species, and ecosystems in both hemispheres

Harvey

Enright

2022

Plant Ecol

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“…Fire directly influences the ability of plants to complete their life cycles and thus shapes plant population dynamics (Baltzer et al 2021;Gosper et al 2022). While many species have fire-related traits (Lamont et al 2020;Lamont et al 2019), ongoing fire regime changes, including higher frequency of severe fires (Collins et al 2022), threaten the ability of plants to complete their life cycles (Gallagher et al 2022;Nolan et al 2022).…”

Section: Introductionmentioning

confidence: 99%

“…Yet, high-severity fire can also cause seed death and limit seed dispersal, especially when fire temperatures are extreme (Bradstock et al 1994;Gill, Hoecker, and Turner 2021). Studies on plant reproduction after fire do not usually account for fire severity (Brennan and Keeley 2019;Gosper et al 2022), even though fire severity influences recruitment and time to maturity (McCaw 2008). We reason that incorporating both fire severity and time since fire into ecological studies will help to disentangle the influences of the multiple components of the fire regime and understand plant life cycles under future fire regimes.…”

Section: Introductionmentioning

confidence: 99%

Time since fire shapes plant immaturity risk across fire severity classes

et al. 2023

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Background When fire intervals are shorter than the time required for plants to reproduce, plant populations are threatened by “immaturity risk.” Therefore, understanding how the time between fires influences plants can inform ecosystem management. Quantifying periods of immaturity risk requires investigating the influence of fire intervals across plant life stages, but most studies are indiscriminate of maturity. As fire regimes are multidimensional, it is also important to consider other characteristics of fires such as severity. We conducted a field study in heathy woodland that investigated how fire severity and fire interval influence immaturity risk to serotinous resprouter species, by examining if fire severity interacts with the time since the fire to influence the occurrence of mature individuals and relative abundance of three species: silver banksia (Banksia marginata Cav.), prickly teatree (Leptospermum continentale Joy Thomps), and heath teatree (Leptospermum myrsinoides Schitdl). Results Regression modeling revealed a strong, positive influence of time since the last fire on the proportion of quadrats at a site with mature plants, for all three species. We only detected a small and uncertain influence of fire severity on the proportion of quadrats with mature heath and prickly teatree, and did not observe an effect of fire severity on the maturity of silver banksia. Interestingly, no relationships were observed between time since fire and the relative abundance of plants. That is, only when plant life stages were considered did we detect an effect of fire on plants. Populations of the three species were mostly immature in the first 7 years post-fire, suggesting if sites were uniformly burnt in this time frame, there could be increased risk of local extinctions. Conclusions Our study highlights the importance of examining population processes, such as reproduction, in addition to plant relative abundance. Surprisingly, we did not detect strong differences in plant maturation across fire severity classes; low occurrence of mature plants in recently burnt areas indicated that immaturity risk was high, regardless of fire severity. Ecological studies that distinguish between plant life stages will help to predict the impacts of fire on populations and enhance decision-making. We recommend fire intervals of ≥ 8 years to protect serotinous resprouter plants in heathy woodland vegetation of southern Australia.

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Mapping risk to plant populations from short fire intervals via relationships between maturation period and environmental productivity

Cited by 6 publications

References 47 publications

An integrated approach to assessing abiotic and biotic threats to post‐fire plant species recovery: Lessons from the 2019–2020 Australian fire season

An integrated approach to assessing abiotic and biotic threats to post‐fire plant species recovery: Lessons from the 2019–2020 Australian fire season

Climate change and altered fire regimes: impacts on plant populations, species, and ecosystems in both hemispheres

Time since fire shapes plant immaturity risk across fire severity classes

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