Small-Scale Variation in Fuel Loads Differentially Affects Two Co-Dominant Bunchgrasses in a Species-Rich Pine Savanna

Paul R. Gagnon; Kyle E. Harms; William J. Platt; Heather A. Passmore; Jonathan A. Myers

doi:10.1371/journal.pone.0029674

Abstract

Ecological disturbances frequently control the occurrence and patterning of dominant plants in high-diversity communities like C₄ grasslands and savannas. In such ecosystems disturbance-related processes can have important implications for species, and for whole communities when those species are dominant, yet mechanistic understanding of such processes remains fragmentary. Multiple bunchgrass species commonly co-dominate disturbance-dependent and species-rich pine savannas, where small-scale fuel heterogeneity may influence bunchgrass survival and growth following fires. We quantified how fire in locally varying fuel loads influenced dynamics of dominant C₄ bunchgrasses in a species-rich pine savanna in southeastern Louisiana, USA. We focused on two congeneric, co-dominant species (Schizachyrium scoparium and S. tenerum) with similar growth forms, functional traits and reproductive strategies to highlight effects of fuel heterogeneity during fires. In experimental plots with either reduced or increased fuels versus controls with unmanipulated fuels, we compared: 1) bunchgrass damage and 2) mortality from fires; 3) subsequent growth and 4) flowering. Compared to controls, fire with increased fuels caused greater damage, mortality and subsequent flowering, but did not affect post-fire growth. Fire with reduced fuels had no effect on any of the four measures. The two species responded differently to fire with increased fuels – S. scoparium incurred measurably more damage and mortality than S. tenerum. Logistic regression indicated that the larger average size of S. tenerum tussocks made them resistant to more severe burning where fuels were increased. We speculate that locally increased fuel loading may be important in pine savannas for creating colonization sites because where fuels are light or moderate, dominant bunchgrasses persist through fires. Small-scale heterogeneity in fires, and differences in how species tolerate fire may together promote shared local dominance by different bunchgrasses.

Citation: Gagnon PR, Harms KE, Platt WJ, Passmore HA, Myers JA (2012) Small-Scale Variation in Fuel Loads Differentially Affects Two Co-Dominant Bunchgrasses in a Species-Rich Pine Savanna. PLoS ONE 7(1): e29674. https://doi.org/10.1371/journal.pone.0029674

Editor: Justin Wright, Duke University, United States of America

Received: January 12, 2011; Accepted: December 2, 2011; Published: January 17, 2012

Copyright: © 2012 Gagnon et al. This is an open-access article distributed under the terms of the Creative Commons Attribution License, which permits unrestricted use, distribution, and reproduction in any medium, provided the original author and source are credited.

Funding: The National Science Foundation (DEB 0516175) provided financial support. The funder had no role in study design, data collection and analysis, decision to publish, or preparation of the manuscript.

Competing interests: The authors have declared that no competing interests exist.

Introduction

Changes in populations of dominant plants can have important consequences for entire biological communities and ecosystems [1]. Plants that are dominant in terms of biomass or stature can be key contributors to ecosystem productivity (e.g. [2], [3]) and community assembly or invasibility [4]–[6]. Grime [7] asserted that to understand vegetation structure and dynamics, studies of plant dominance should have high priority because “the struggle between potential dominants provides a potent driving force for successional change and is a major determinant of the fate of subordinate species.”

Ecological perturbations can control the occurrence and patterning of potentially dominant species [8]. Such disturbances are intrinsically heterogeneous both spatially and temporally. Examples include fires [9]–[11], drought and climatic variability [12], [13], grazing [9], [14], windstorms and other gap-opening events, among others [15]–[17]. If disturbance effects are sufficiently variable at small scales, the resulting heterogeneity might enable multiple species to share dominance in the community.

Multiple C₄ bunchgrass species frequently co-dominate the groundcover in many fire-dependent and species-rich grasslands and savannas (e.g., [9], [12], [18]–[23]). The interstices among these large, relatively fire-tolerant grasses constitute the matrix within which smaller but more diverse “subordinate species” (sensu [7]) occur. Where multiple bunchgrass species have the potential to dominate particular fire-prone sites, local heterogeneity in disturbances like fire might affect potential dominants differently [21].

Pine savannas in the southeastern USA are among the plant communities wherein multiple bunchgrass species commonly co-dominate. We use the term “savannas” to emphasize the near continuous groundcover of grasses and discontinuous pine canopy that typifies these ecosystems [24], [25]. Frequent fires regularly crop dominant bunchgrasses that account for the bulk of living herbaceous biomass in these ecosystems [18], [21]. Spatially heterogeneous fuels, especially the needles, cones and branches of overstory pines, cause local variation in fires [11], [26]–[28]. Although it has yet to be demonstrated empirically, small-scale variation in these fires is hypothesized to play a critical role in maintaining high species richness in pine savanna understories [11], [26]. A better understanding of how local variation in fires affects bunchgrass survival and growth, including how effects differ among species, should offer key insights into why species sometimes co-dominate these pine-savanna ecosystems.

We explored how variation in fire disturbance affected co-dominant perennial bunchgrasses in a species-rich pine savanna. We sought to quantify the extent to which variation in fire severity, manipulated through contrasting fuel loads, damaged and killed potentially dominant grass tussocks of different species and how the subsequent growth and reproductive output of surviving tussocks varied across species and fire treatments. In a pine savanna in southeastern Louisiana, USA, we focused on two congeneric, co-dominant bunchgrasses of similar growth form and clonal habit to highlight effects of varying fuel loads during fires. We compared fire-induced damage and mortality along with post-fire growth and flowering of bunchgrasses in experimental plots in which we either reduced or increased fuel loads compared to unmanipulated controls. Fuel loads in pine savannas vary substantially with proximity to overstory pines (e.g., [29]), and we designed our fuel treatments based on previously measured natural variability in fuel loads for this ecosystem [11]. We hypothesized that: 1) adding fuels to increase local fire severity would increase damage and mortality to the two co-dominant bunchgrasses; 2) those bunchgrass tussocks that survived fires with added fuels would grow more during the remainder of the growing season, likely owing to locally increased space and resource availability; 3) bunchgrass tussocks that survived fires with added fuels would be more likely to flower, again likely owing to locally increased space and resource availability; and 4) response of the two species to burning would differ in terms of damage, mortality and growth. Based on our results, we explored how variation in fires driven by small-scale fuel heterogeneity could be important for understanding shared plant dominance in fire-prone habitats.

Materials and Methods

Study site, focal organisms and experimental design

We compared effects on dominant bunchgrasses of fires burning different fuel loads at Camp Whispering Pines, a restored, species-rich pine savanna in southeastern Louisiana, USA (30° 41′ N; 90° 29′ W; mean annual temperature = 19°C, mean annual rainfall = 1626 mm [30]). The terrain is moderately dissected, 25–50 m above mean sea level. The site's Pleistocene-aged fine sands mixed with and capped by loess are among the most fertile pine savanna soils [31]. The site has never been plowed, and for 15 years had been burned biennially during the early growing season (April-May) [30] prior to the time of the experiment. The overstory is primarily longleaf pine (Pinus palustris Mill.) that regenerated naturally after the site was logged in the early 1900 s [24]. The pine savanna on this 270 ha site contains >300 vascular plant species (W. J. Platt et al., unpublished data), including diverse groundcover forbs, shrubs and grasses at small scales (∼30 species • m⁻²; K. E. Harms et al., unpublished data). Multiple bunchgrass species are dominant in the groundcover at the site; the two most common in the focal plots were Schizachyrium scoparium (Michx.) Nash and S. tenerum Nees (see Results). For additional ecological details about the research site and its management history, see Platt et al. [30].

We manipulated fine-fuel quantities to produce small-scale heterogeneity in fires. We randomly assigned one of three levels of fine-fuel treatments to each of 24 square, 4-m² plots in two separate burn units (N = 24×2 = 48 plots) burned under prescription on different days in the early growing season (May 10 & 14, 2007). We randomly chose plot locations away from clonal shrubs and overstory trees to reduce variability in fuel quantities (i.e., needles, cones and branches). To each of one-third of the plots in each burn unit we added 8 kg of dry, uncompacted longleaf pine needles (i.e., fuel-addition treatment), spread evenly over the plot on the same morning as the two fires. This quantity of pine straw (2 kg • m⁻²) mimicked the upper range of observed fuel loads at this relatively productive study site [11], [32]. Another third we left as control plots with unmanipulated fuels. In the remainder we clipped and removed existing biomass above 5 cm (i.e., fuel-reduction treatment). Following fuel treatments but before burning, plots contained on average 3076 g • m⁻² (fuel addition), 1076 g • m⁻² (control) and 444 g • m⁻² (fuel reduction) (1SE = 57, 57 and 23 respectively) of total aboveground biomass (we estimated these quantities from nearby plots treated similarly, with fuels collected and then weighed after drying for 48 hours at 100°C). These quantities included natural herbaceous litter and any natural or added pine straw, plus such naturally occurring fine fuels as pine cones and small pine twigs. To reduce variability among plots within a given treatment, we removed any coarser woody fuels like large branches prior to burning and did not include such fuels in this estimate. During the late morning on two dry days with light breezes, we established backing fires in the two different burn units and then set head-fires that we allowed to burn through the plots. Fuel-reduction plots burned with fine-scale patchiness, while control and fuel-addition plots all burned thoroughly. Fuels in all fuel-addition plots burned almost completely to ash.

One of us (PRG) performed three separate censuses of all bunchgrasses in the interior 1-m² square quadrat within each of the 48, 4-m² treatment plots. For each census, he mapped and measured every tussock of grass >1-cm in basal diameter and identified each tussock to species. The first census was in late March 2007 (spring census) prior to burning. The second was in June (summer census), roughly three weeks after burning, by which time the large majority of tussocks not killed by fires were resprouting. The third census was in October/November 2007 (fall census) at the end of the growing season. Viewed from above, most tussocks were approximately elliptical in shape; measuring them consisted of 2 diameters at 90° (length and width). In addition to basal-area measurements in the fall census, he also noted whether or not each tussock was flowering (the timing of the fall census was planned to facilitate collection of these flowering data).

Quantitative analyses

Our initial exploratory analyses focused primarily on data from the spring census (pre-fire and pre-treatment). Our dataset of tussocks included species designation and basal area from the modeled ellipses of each individual bunchgrass tussock in every quadrat. We calculated simple means for number of tussocks and basal area of each species. We also tallied the proportion of each species in every quadrat in terms of both number and basal area. Our subsequent analyses focused solely on the two common species of Schizachyrium (S. scoparium and S. tenerum). To evaluate statistical difference in size between S. scoparium and S. tenerum tussocks, we used log-transformed basal area (in cm²) of tussocks from the spring census as our response variable, species as a fixed effect and both burn unit and plot as random variables. We used a Kenward-Roger approximation to account for lack of balance in the dataset for this and all subsequent analyses (both species occurred in most but not all quadrats). We performed this analysis using the Mixed procedure in SAS v. 9.1.3 [33].

We examined the extent to which fires burning different fuel loads damaged Schizachyrium tussocks. Our response variable was total basal area of each species per plot (square-root transformed to normalize residuals). Damage was indicated by reduction in basal area per plot between the spring and summer censuses. Fuel treatment was a 3-level fixed effect applied at the whole plot level. Species functioned as a split-plot effect within fuel-treatment whole plots. The two burn units were random-effect blocks. Census was our repeated variable. Here we graphically present least-square means and standard errors from the model that included data from each of the three censuses as analogous repeated measures (Figure 1 A and B). By coincidence when we randomly assigned treatments to plots, S. scoparium had more individuals and total basal area in plots assigned to both fuel-added and fuel-reduced treatments, whereas S. tenerum had more in control plots. Because of this significant pre-treatment difference between species, in the Results we interpret tests for significance from an analogous model that treated pre-fire basal area (spring census) as a covariate and only included data from summer and fall censuses in our response variable. By thus controlling for the pre-treatment difference between species, we are able to focus our discussion on the effects of the applied experimental treatment. We ran both homogeneous and heterogeneous variance models and chose the former on the basis of lower AIC (Akaike Information Criterion; Ch. 9 in [34]). We performed this repeated measures analysis of covariance (ANCOVA) using the Mixed procedure in SAS v. 9.1.3 [33].

Download:

Figure 1. Tussock number and basal area of two Schizachyrium bunchgrasses in three fuel levels.

Basal area (A and B) and number of tussocks (C and D) for Schizachyrium scoparium (A and C) and S. tenerum (B and D) in control, increased and reduced fuel treatments in spring, summer and fall censuses (least squares means +/−95% confidence intervals).

https://doi.org/10.1371/journal.pone.0029674.g001

We next examined effects of fires burning different fuel loads on mortality of individual Schizachyrium tussocks. Our response variable in each plot was number of tussocks per species (log transformed to normalize residuals), with reduction in number between spring and summer censuses indicating killed tussocks. Fuel treatment was a 3-level fixed effect applied at the whole-plot level; species functioned as a split-plot effect within fuel-treatment whole plots. The two burn units were random-effect blocks. Census was our repeated variable. As per our analyses of basal area, we graphically present least-square means and standard errors from the model that considered data from each of the three censuses as analogous repeated measures (Figure 1 C and D). However, in the Results we interpret tests for significance from an analogous model that treated pre-fire number of tussocks (spring census data) as a covariate and included only data from summer and fall censuses in our response variable. We thus controlled for the pre-treatment difference between species and can more easily focus our discussion on the effects of the applied experimental treatment. We ran both homogeneous and heterogeneous variance models and chose the former on the basis of lower AIC (Ch. 9 in [34]). We performed repeated measures ANCOVA using the Mixed procedure in SAS v. 9.1.3. [33].

To separate size of tussocks from other species effects on survival, we performed logistic regression. We assigned “1” to every individual tussock tallied in our spring census that resprouted by the fall census and “0” to those that did not resprout; these survival tallies served as our binomial response variable. Fuel treatment was again our 3-level fixed effect applied at the whole-plot level, with species treated as split-plot. Basal area from the spring census served as a covariate to control for differences in initial tussock size. The two burn units were random-effect blocks. For this analysis, we used a binomial distribution with a logit link in the Glimmix procedure in SAS v. 9.1.3 [33] and simultaneously calculated odds ratios.

To determine whether survivors grew differently following fires burning different fuel loads, we analyzed individual growth of tussocks. For our response variables, we calculated growth over two time periods. The first period was the early growing season, including the first few weeks post-fire, to see how fires immediately affected tussock size (equals mean tussock basal area in summer minus spring, divided by number of tussocks in spring). The second period was for the duration of the growing season to determine whether tussocks grew different amounts where their density was reduced by fires in fuel-addition plots (equals mean basal area of tussocks in fall minus summer, divided by number of tussocks in summer). Again fuel treatment was our 3-level fixed effect applied at the whole-plot level, and species was our split-plot fixed effect. The two burn units were random-effect blocks. We ran both homogeneous and heterogeneous variance models and chose the latter (grouped by fuel treatment) based on lowest AIC (Ch. 9 in [34]). We again used the Mixed procedure in SAS v. 9.1.3 for this analysis [33].

To determine whether fires burning different fuel loads affected subsequent flowering by surviving tussocks, we again used logistic regression. To avoid problems of unbalanced data in this analysis, we focused on S. scoparium because S. tenerum was not present in several plots. We assigned “1” to every flowering tussock of S. scoparium in our fall census and “0” to non-flowering tussocks; resulting tallies served as our binomial response variable. Fuel treatment was our 3-level fixed effect. Basal area from the fall census served as a covariate to control for differences in tussock sizes. The two burn units were random-effect blocks. For this analysis, we used a binomial distribution with a logit link in the Glimmix procedure in SAS v. 9.1.3 [33] and simultaneously calculated odds ratios.

Results

Within study plots, the two Schizachyrium species were dominant among all bunchgrass species in terms of both basal area and number. In our spring census, they accounted for 92% of total bunchgrass basal area and 91% of all individual tussocks. Of the two, S. scoparium accounted for 51% of total basal area and 63% of total number, whereas S. tenerum accounted for 41% and 28%, respectively. This disparity indicates that on average, S. scoparium tussocks were more numerous but smaller than those of S. tenerum (back-transformed lsmeans = 7.26 vs. 12.94 cm² {+/−1SE = 5.87, 8.94 vs. 10.52, 15.87}, respectively; F_1,554 = 40.20, P<0.001). Within our two burn units, several species in the genus Andropogon combined to account for 5% of total basal area and 6% of individual tussocks, whereas the genus Aristida (all A. purpurea Nutt.) accounted for 1% of each. Subsequent analyses focus exclusively on the two co-dominant Schizachyriums.

As expected, fire with added fuels caused substantially more damage to tussocks than fire with control or reduced fuel levels (Figure 1A and B). Repeated measures ANCOVA using basal area in summer and fall as the response variable and basal area in spring (pre-fire) as a pre-treatment covariate indicated a significant effect of fuel treatment (F_2,69.3 = 10.37, P<0.001); where fuels were added, there was significantly less bunchgrass basal area after fires than with either control or reduced fuels, which were similar. There was also a significant effect of census (F_1,81 = 22.42, P<0.001); mean total basal area in the fall increased significantly over summer levels, reflecting the fact that tussocks increased in size during the growing season. Although there was no main effect of species (F_1,58.2 = 0.02, P = 0.887), species did interact significantly with fuel treatments (F_2,58 = 3.61, P = 0.033). This interaction was caused by a marked difference between the two species where we added fuels; whereas these fires reduced basal area of S. tenerum by approximately half (51.8%), this same treatment reduced basal area of S. scoparium by 84.2%. There was no effect on basal area of burning with either reduced or control fuels; for both species in these two treatments, basal area slightly increased (non-significantly) over pre-fire levels. Pre-fire basal area was predictive of post-fire basal area (F_1,62 = 268.56, P<0.001), as was the interaction of the covariate with fuel treatment (F_2,65.4 = 11.25, P<0.001) and the three-way interaction of pre-fire basal area with fuel and species (F_3,70.2 = 5.56, P = 0.002). No other covariate interactions were statistically significant, so we excluded those from our analysis (as per [34]; see Table S1).

Fire with added fuels also caused substantially more mortality to tussocks than fire with either control or reduced fuel levels (Figure 1C and D). ANCOVA using number of individual tussocks in the summer and fall as the response variable and number in springtime as a pre-treatment covariate indicated a significant effect of fuel treatment (F_2,43.9 = 34.35, P<0.0001); where fuels were added, there were significantly fewer tussocks after fires than with either control or reduced fuels, which were similar. Effect of census was also significant (F_1,90 = 9.14, P = 0.003); mean number of combined tussocks in the fall increased significantly over summer levels, reflecting establishment of new recruits during the growing season. There was no main effect of species (F_1,48.8 = 1.38, P = 0.245), but as with basal area (above), a species-by-fuel treatment interaction was significant (F_2,44.7 = 6.50, P = 0.003). Whereas fire with added fuels killed 2/3 of S. tenerum tussocks (67.1%), this treatment killed 4/5 of S. scoparium individuals (80.5%). By contrast, fire with neither reduced nor control fuel levels caused any detectable mortality. In these latter two fuel treatments, and especially in reduced fuel plots, the number of S. scoparium individuals increased during the 3 censuses, whereas the number of S. tenerum individuals remained constant, as indicated by a significant 3-way interaction of fuel treatment, census and species (F_2,90 = 3.32, P = 0.041). Pre-fire number of tussocks was predictive of post-fire numbers (F_1,78 = 83.2, P<0.001), but no covariate interactions were significant (see Table S2).

Larger tussocks of both species were significantly more likely to survive fires. To untangle the effect of tussock size from other possible species effects, we used logistic regression to analyze tussock survival as a binomial response variable and initial tussock size as a covariate. The effect of fuel treatment was significant (F_2,68.2 = 59.00, P<0.001) and initial tussock size predicted tussock fate (F_1,1256 = 17.00, P<0.001). With tussock size accounted for, there was no additional difference in survival between the two Schizachyrium species (F_1,1256 = 0.14, P = 0.7114), nor were any higher order interactions significant (see Table S3). According to the odds ratios, tussock survival was not statistically different between fires with control vs. reduced fuel levels (odds ratio = 1.776, 95% confidence = 0.740, 4.262; note that this odds-ratio indicates {non-significantly} higher survival rates in control than in reduced fuels). However, the odds of tussock survival were significantly lower in fires with added fuels than in the other two treatments (for added-fuels vs. removed-fuels, odds ratio = 0.021, 95% confidence = 0.010, 0.044). From this analysis we conclude that the difference in survival between the two Schyzachyrium species in fires with added fuels was mainly a function of the larger average size of S. tenerum tussocks.

Fires with added fuels caused substantial reduction in tussock size, but growth in basal area after the fires was similar across fuel treatments. Our measure of tussock growth was mean growth per tussock (in cm²) at the plot level. Comparing spring (pre-fire) to summer (immediate post-fire) census data, the effect of fuel treatment was again significant (F_2,48.6 = 30.87, P<0.001) but there was no effect of species nor fuel-treatment-by-species interaction (F_1,63.5 = 1.59, P = 0.212 and F_2,48.6 = 1.95, P = 0.514, respectively). Growth in the post-fire environment (tussock size in the fall versus summer census) indicated no effect of fuel-treatment (F_2,35.1 = 0.84, P = 0.441), species (F_1,21.5 = 0.62, P = 0.438) nor their interaction (F_2,19.4 = 0.11, P = 0.896; see Table S4).

Tussocks that survived fires with added fuels were more likely to flower than tussocks growing where fuels were removed. Only S. scoparium had multiple individuals present in almost all plots, so our flowering analysis focused on that species to ensure adequate replication. We modeled likelihood of flowering as a binomial response variable using logistic regression, with individual tussock size (i.e., basal area) at census 3 as a covariate. As expected, tussock size was highly predictive of the likelihood of flowering (F_1,572 = 42.67, P = 0.001); larger tussocks were more likely to flower. The overall effect of fuel-treatment was marginally significant (F_2,30.77 = 3.09, P = 0.060; see Table S5). Odds of flowering for S. scoparium tussocks were similar for control and reduced plots (odds ratio = 1.492, 95% confidence = 0.700, 3.183) and between added-fuels and controls. However, surviving S. scoparium tussocks had increased odds of flowering in added-fuels than in reduced-fuels (odds ratio = 3.244, 95% confidence = 1.241, 8.479).

Discussion

Fire with added fuels alters bunchgrass survivorship, growth and fecundity

Small-scale variation in fuels and resulting fire heterogeneity can have important effects on the survivorship, growth and fecundity of dominant species in fire-prone habitats. The two Schizachyrium species were much more prevalent in our research plots than all other bunchgrasses combined. Together, S. scoparium and S. tenerum composed 91% of all identifiable tussocks and 92% of total bunchgrass basal area. Fires with added fuels significantly increased mortality and reduced basal area (i.e., caused negative growth) of these two co-dominants, and these effects persisted through the end of the growing season. The result was that our fire with added fuels treatment opened substantial new space. Reduced bunchgrass dominance could result if other species are able to exploit and monopolize this new space. Although the detrimental effect on bunchgrasses of adding fuels was to be expected, virtually every tussock in both control and reduced fuel treatments survived burning with zero reduction in basal area. Some threshold of fuel loading appeared to be operating, below which these bunchgrasses were impervious to fire; clearly the naturally occurring fuel loads in our unmanipulated controls were below this threshold. That reduced fuels and concordant reduction in fire intensity offered no benefit to bunchgrass tussocks compared to controls suggests that both focal species were well adapted to fires like those in our control plots.

Longleaf pines are important drivers of potential dynamism in the understory through their production of fuels. Historically, longleaf pine trees occurred patchily on the landscape [24], [25], [35]; the distribution of their fuels would have been similarly patchy, even where their fuels were sufficiently continuous to carry fire throughout [26], [27], [29]. The substantial quantities of needles, cones and branches dropped by pines on the understory generate local hotpots during frequent fires [25], [29], [36], [37]. These fuels vary temporally as well as spatially, as when hurricanes and other intense disturbances generate treefalls that drop fuels in irregular pulses. Our fuel addition treatment was designed to mimic the heavy loads of fine and coarse fuels under treefalls or beneath standing pines after several years without fire; had we included plots directly under trees, fuel quantities in control plots would have been substantially greater. Fire is clearly a potent ecological filter [38]–[40]; our results indicate that in habitats like this one, the strength of this filtering may vary substantially with the location of individual plants and perhaps even single branches of, in this case, pine trees. Our results highlight the importance of fuel heterogeneity in pine savannas for locally reducing bunchgrass basal area and altering local survivorship of dominant bunchgrasses. If bunchgrasses compete with other species for limited resources, the resulting opening of new space at small scales may facilitate colonization by other species and thus support the maintenance of high diversity in this species-rich ecosystem [32]. Alternatively, if bunchgrasses facilitate the establishment of non-dominant species (as suggested by [41]), then this new open space might remain so until ruderals or other colonizing species are able to take hold.

After the fires, growth of individual tussocks showed no indication of density dependence, but rate of flowering increased following more severe burning. Because of fire-induced mortality, plants that survived fire with added fuels occurred at substantially lower densities than plants in our control and reduced-fuels treatments. We expected basal area of these sparsely growing plants to increase faster than that of their counterparts growing at higher densities, but this was not the case. Our fuel treatment affected basal area only during the brief interval that included burning, and during that interval, plant basal area decreased only where we added fuels; fuel treatment had no effect on post-fire growth rates. Unlike post-fire growth, differential rates of flowering by S. scoparium did suggest possible density dependent influences. The more widely separated plants that survived fire with added fuels had higher odds of flowering than more densely growing counterparts where fuels were reduced. These results suggest that for these bunchgrasses growing at such densities, crowding has an effect on reproduction but not growth. Alternatively, this increase in flowering could have been a compensatory stress response in plants that were more severely damaged in the added fuel plots. Growth of surviving tussocks did not accelerate after their density decreased, suggesting that the new space created by burning was likely to persist for some time, and so remain available for colonization by other species where space is limiting.

Effects of added fuels differed between the two co-dominants

Our study of two co-dominant bunchgrasses is unique in that we explore implications for species of within-fire heterogeneity at the neighborhood level driven by variation in fuel loading. Although many studies have explored the effects of fire on dominant bunchgrasses, these have typically viewed fire as a uniform disturbance at the landscape scale. None that we are aware of have focused on the ecological implications of species differences in the context of small-scale variation in individual fires.

The effect of fire with added fuels was measurably different on the two dominant bunchgrass congeners both in terms of damage and mortality. Tussocks of S. scoparium suffered proportionally greater mortality and loss of basal area in fires with added fuels than tussocks of S. tenerum. This outcome suggests that S. tenerum should be relatively more frequent where fuel loads are elevated, such as under pine trees and treefalls, whereas S. scoparium should be relatively more frequent in open areas away from large trees in old-growth pine savannas [24], [35]. Indeed, we have observed elsewhere at this study site that the relative abundance of S. tenerum was increased under pines compared to in gaps (William J. Platt, unpublished data). Others have demonstrated effects of fires in increased fuels under pines that exclude potential woody competitors [11], [29], [35], [37]; our results indicate that locally heavy fuel loads favor some closely related herbaceous species over others in the same functional group.

Tussock size was the main determinant of both mortality and degree of damage in fires with added fuels. Larger tussocks were more likely to survive and suffered proportionally less damage. Tussocks of S. tenerum were larger on average than those of S. scoparium, and in our analyses, this key difference explained the lower rates of damage and mortality of S. tenerum. We observed that at our field site in southeastern Louisiana, tussocks of S. tenerum were more circular in shape and more densely packed with thinner, finer culms (Figure 2). Culms of S. scoparium were coarser and less densely packed in tussocks, which were often irregularly (amoeboid) shaped. Our results indicate that beyond basal area, such morphological differences were inconsequential in predicting tussock ability to endure hotter fires, although additional investigations of bunchgrass morphology and fire effects are merited.

Download:

Figure 2. Side-by-side view of the co-dominant bunchgrass congeners.

The two species, Schizachyrium scoparium (left) and S. tenerum (right), here are both resprouting after a recent prescribed fire.

https://doi.org/10.1371/journal.pone.0029674.g002

Our findings suggest how heterogeneity of fuels might differentially affect population dynamics of dominant bunchgrass species in pine savannas. Fire with added fuels in our study reduced survivorship and caused negative growth (our measure of damage equates to negative growth), and plants exhibited no compensatory growth after fires. These negative impacts from fire with added fuels were more pronounced for S. scoparium than for its co-dominant congener. Numerous demographic studies have concluded that for long-lived iteroparous plants like perennial bunchgrasses, rates of growth and especially adult survivorship consistently influence population growth rates (λ) much more than do other vital rates [42]–[48]. Given this, we speculate that these differential effects will be reflected in both species' population growth rates beyond this one important year during which these plants burned. Our findings indicate that within given fires, local pockets of high severity can favor one co-dominant over another; thus, small-scale heterogeneity in fires (especially as a function of the location of pine trees), and differences in how species tolerate those fires may combine to promote shared local dominance by multiple bunchgrass species.

Supporting Information

Table S1.

Results of repeated measures ANCOVA of bunchgrass basal area.

https://doi.org/10.1371/journal.pone.0029674.s001

(DOCX)

Table S2.

Results of repeated measures ANCOVA of tussock number.

https://doi.org/10.1371/journal.pone.0029674.s002

(DOCX)

Table S3.

Results of logistic regression analysis of tussock survival.

https://doi.org/10.1371/journal.pone.0029674.s003

(DOCX)

Table S4.

Results of ANOVA of bunchgrass growth.

https://doi.org/10.1371/journal.pone.0029674.s004

(DOCX)

Table S5.

Results of logistic regression analysis of flowering in S. scoparium.

https://doi.org/10.1371/journal.pone.0029674.s005

(DOCX)

Acknowledgments

We thank Natalia Aristizábal, Emilio Bruna, Melissa Day, John-Michael May, Christian Savoie, Elizabeth Skendzic, Ernane Vieira Neto and the Harms and Platt Labs for their assistance. The Girl Scouts of America, Larry Ehrlich and Camp Whispering Pines staff provided logistical support.

Author Contributions

Conceived and designed the experiments: PRG KEH WJP. Performed the experiments: PRG HAP JAM KEH WJP. Analyzed the data: PRG HAP WJP JAM KEH. Contributed reagents/materials/analysis tools: PRG KEH WJP. Wrote the paper: PRG. Revised the manuscript for intellectual content: PRG KEH WJP JAM HAP.

References

1. Ellison AM, Bank MS, Clinton BD, Colburn EA, Elliott K, et al. (2005) Loss of foundation species: consequences for the structure and dynamics of forested ecosystems. Frontiers in Ecology and the Environment 3: 479–486.
- View Article
- Google Scholar
2. Whittaker RH (1965) Dominance and diversity in land plant communities: Numerical relations of species express importance of competition in community function and evolution. Science 147: 250–260.
- View Article
- Google Scholar
3. Smith MD, Knapp AK (2003) Dominant species maintain ecosystem function with non-random species loss. Ecology Letters 6: 509–517.
- View Article
- Google Scholar
4. Smith MD, Wilcox JC, Kelly T, Knapp AK (2004) Dominance not richness determines invasibility of tallgrass prairie. Oikos 106: 253–262.
- View Article
- Google Scholar
5. Emery SM, Gross KL (2006) Dominant species identity regulates invasibility of old-field plant communities. Oikos 115: 549–558.
- View Article
- Google Scholar
6. Gilbert B, Turkington R, Srivastava DS (2009) Dominant species and diversity: linking relative abundance to controls of species establishment. American Naturalist 174: 850–862.
- View Article
- Google Scholar
7. Grime JP (1987) Dominant and subordinate components of plant communities: Implications for succession, stability and diversity. In: Gray AJ, Crawley MJ, Edwards PJ, editors. Colonization, Succession and Stability. Oxford, UK: Blackwell Scientific Publications. pp. 413–428.
8. Sousa WP (1979) Experimental investigations of disturbance and ecological succession in a rocky inter-tidal algal community. Ecological Monographs 49: 227–254.
- View Article
- Google Scholar
9. Smith MD, Knapp AK (1999) Exotic plant species in a C-4-dominated grassland: invasibility, disturbance, and community structure. Oecologia 120: 605–612.
- View Article
- Google Scholar
10. Gagnon PR, Platt WJ (2008) Multiple disturbances accelerate clonal growth in a potentially monodominant bamboo. Ecology 89: 612–618.
- View Article
- Google Scholar
11. Thaxton JM, Platt WJ (2006) Small-scale fuel variation alters fire intensity and shrub abundance in a pine savanna. Ecology 87: 1331–1337.
- View Article
- Google Scholar
12. Albertson FW, Tomanek GW (1965) Vegetation changes during a 30-year period in grassland communities near Hays, Kansas. Ecology 46: 714–720.
- View Article
- Google Scholar
13. Adler PB, HilleRisLambers J, Kyriakidis PC, Guan QF, Levine JM (2006) Climate variability has a stabilizing effect on the coexistence of prairie grasses. Proceedings of the National Academy of Sciences of the United States of America 103: 12793–12798.
- View Article
- Google Scholar
14. Pierce S, Luzzaro A, Caccianiga M, Ceriani RM, Cerabolini B (2007) Disturbance is the principal alpha-scale filter determining niche differentiation, coexistence and biodiversity in an alpine community. Journal of Ecology 95: 698–706.
- View Article
- Google Scholar
15. Papaik MJ, Canham CD (2006) Species resistance and community response to wind disturbance regimes in northern temperate forests. Journal of Ecology 94: 1011–1026.
- View Article
- Google Scholar
16. Busby PE, Motzkin G, Foster DR (2008) Multiple and interacting disturbances lead to Fagus grandifolia dominance in coastal New England. Journal of the Torrey Botanical Society 135: 346–359.
- View Article
- Google Scholar
17. Gagnon PR, Platt WJ, Moser EB (2007) Response of a native bamboo (Arundinaria gigantea {Walt.} Muhl.) in a wind-disturbed forest. Forest Ecology and Management 241: 288–294.
- View Article
- Google Scholar
18. Walker J, Peet RK (1984) Composition and species-diversity of pine-wiregrass savannas of the green swamp, North Carolina. Vegetatio 55: 163–179.
- View Article
- Google Scholar
19. Collins SL, Gibson DJ (1990) Effects of fire on community structure in tallgrass and mixed-grass prairies. In: Collins SL, Wallace LL, editors. Fire in North American Tallgrass Prairies. Norman, OK USA: University of Oklahoma Press. pp. 81–98.
20. Keddy PA, Smith L, Campbell DR, Clark M, Montz G (2006) Patterns of herbaceous plant diversity in southeastern Louisiana pine savannas. Applied Vegetation Science 9: 17–26.
- View Article
- Google Scholar
21. Brewer JS, Cunningham AL, Moore TP, Brooks RM, Waldrup JL (2009) A six-year study of fire-related flowering cues and coexistence of two perennial grasses in a wet longleaf pine (Pinus palustris) savanna. Plant Ecology 200: 141–154.
- View Article
- Google Scholar
22. Gibson DJ (2009) Grasses and Grassland Ecology. New York: Oxford University Press. 305 p.
23. Edwards EJ, Osborne CP, Stromberg CAE, Smith SA, Consortium CG (2010) The Origins of C-4 Grasslands: Integrating Evolutionary and Ecosystem Science. Science 328: 587–591.
- View Article
- Google Scholar
24. Noel JM, Platt WJ, Moser EB (1998) Structural characteristics of old- and second-growth stands of longleaf pine (Pinus palustris) in the gulf coastal region of the USA. Conservation Biology 12: 533–548.
- View Article
- Google Scholar
25. Platt WJ (1999) Southeastern pine savannas. In: Anderson RC, Fralish JS, Baskin JM, editors. Savannas, Barrens, and Rock Outcrop Plant Communities of North America. Cambridge, UK: Cambridge University Press. pp. 23–51.
26. Hiers JK, O'Brien JJ, Mitchell RJ, Grego JM, Loudermilk EL (2009) The wildland fuel cell concept: an approach to characterize fine-scale variation in fuels and fire in frequently burned longleaf pine forests. International Journal of Wildland Fire 18: 315–325.
- View Article
- Google Scholar
27. Mitchell RJ, Hiers JK, O'Brien J, Starr G (2009) Ecological forestry in the southeast: understanding the ecology of fuels. Journal of Forestry 107: 391–397.
- View Article
- Google Scholar
28. Loudermilk EL, Hiers JK, O'Brien JJ, Mitchell RJ, Singhania A, et al. (2009) Ground-based LIDAR: a novel approach to quantify fine-scale fuelbed characteristics. International Journal of Wildland Fire 18: 676–685.
- View Article
- Google Scholar
29. Williamson GB, Black EM (1981) High-temperature of forest fires under pines as a selective advantage over oaks. Nature 293: 643–644.
- View Article
- Google Scholar
30. Platt WJ, Carr SM, Reilly M, Fahr J (2006) Pine savanna overstorey influences on ground-cover biodiversity. Applied Vegetation Science 9: 37–50.
- View Article
- Google Scholar
31. Earley LS (2004) Looking for Longleaf: The Fall and Rise of an American Forest. Chapel Hill, NC, USA: The University of North Carolina Press.
32. Myers JA, Harms KE (2011) Seed arrival and ecological filters interact to assemble high-diversity plant communities. Ecology 92: 676–686.
- View Article
- Google Scholar
33. SAS (2005) SAS Online Documentation 9.1.3. Cary, North Carolina, USA: SAS Institute Inc.
34. Littell RC, Milliken GA, Stroup WW, Wolfinger RD, Schabenberger O (2006) SAS for Mixed Models. Carey, North Carolina, USA: SAS Institute Inc. 814 p.
35. Platt WJ, Evans GW, Rathbun SL (1988) The population dynamics of a long-lived conifer (Pinus palustris). American Naturalist 131: 491–525.
- View Article
- Google Scholar
36. Varner JM, Gordon DR, Putz FE, Hiers JK (2005) Restoring fire to long-unburned Pinus palustris ecosystems: Novel fire effects and consequences for long-unburned ecosystems. Restoration Ecology 13: 536–544.
- View Article
- Google Scholar
37. Rebertus AJ, Williamson GB, Moser EB (1989) Longleaf pine pyrogenicity and turkey oak mortality in Florida xeric sandhills. Ecology 70: 60–70.
- View Article
- Google Scholar
38. Bond WJ, van Wilgen BW (1996) Fire and plants. London: Chapman and Hall.
39. Bond WJ, Keeley JE (2005) Fire as a global ‘herbivore’: the ecology and evolution of flammable ecosystems. Trends in Ecology & Evolution 20: 387–394.
- View Article
- Google Scholar
40. Pausas JG, Keeley JE (2009) A Burning Story: The Role of Fire in the History of Life. Bioscience 59: 593–601.
- View Article
- Google Scholar
41. Kirkman LK, Mitchell RJ, Helton RC, Drew MB (2001) Productivity and species richness across an environmental gradient in a fire-dependent ecosystem. American Journal of Botany 88: 2119–2128.
- View Article
- Google Scholar
42. Silvertown J, Franco M, Pisanty I, Mendoza A (1993) Comparative plant demography - Relative importance of life cycle components to the finite rate of increase in woody and herbaceous perennials. Journal of Ecology 81: 465–476.
- View Article
- Google Scholar
43. Benton TG, Grant A (1996) How to keep fit in the real world: Elasticity analyses and selection pressures on life histories in a variable environment. The American Naturalist 147: 115–139.
- View Article
- Google Scholar
44. Crone EE (2001) Is survivorship a better fitness surrogate than fecundity? Evolution 55: 2611–2614.
- View Article
- Google Scholar
45. Bruna EM (2003) Are plant populations in fragmented habitats recruitment limited? Tests with an Amazonian herb. Ecology 84: 932–947.
- View Article
- Google Scholar
46. Franco M, Silvertown J (2004) Comparative demography of plants based upon elasticities of vital rates. Ecology 85: 531–538.
- View Article
- Google Scholar
47. Bruna EM, Fiske IJ, Trager MD (2009) Habitat fragmentation and plant populations: is what we know demographically irrelevant? Journal of Vegetation Science 20: 569–576.
- View Article
- Google Scholar
48. Gagnon PR, Bruna EM, Rubim P, Darrigo MR, Littell RC, et al. (2011) Growth of an understory herb is chronically reduced in Amazonian forest fragments. Biological Conservation 144: 830–835.
- View Article
- Google Scholar

[ref1] 1. Ellison AM, Bank MS, Clinton BD, Colburn EA, Elliott K, et al. (2005) Loss of foundation species: consequences for the structure and dynamics of forested ecosystems. Frontiers in Ecology and the Environment 3: 479–486.
View Article
Google Scholar

[2] View Article

[3] Google Scholar

[ref2] 2. Whittaker RH (1965) Dominance and diversity in land plant communities: Numerical relations of species express importance of competition in community function and evolution. Science 147: 250–260.
View Article
Google Scholar

[5] View Article

[6] Google Scholar

[ref3] 3. Smith MD, Knapp AK (2003) Dominant species maintain ecosystem function with non-random species loss. Ecology Letters 6: 509–517.
View Article
Google Scholar

[8] View Article

[9] Google Scholar

[ref4] 4. Smith MD, Wilcox JC, Kelly T, Knapp AK (2004) Dominance not richness determines invasibility of tallgrass prairie. Oikos 106: 253–262.
View Article
Google Scholar

[11] View Article

[12] Google Scholar

[ref5] 5. Emery SM, Gross KL (2006) Dominant species identity regulates invasibility of old-field plant communities. Oikos 115: 549–558.
View Article
Google Scholar

[14] View Article

[15] Google Scholar

[ref6] 6. Gilbert B, Turkington R, Srivastava DS (2009) Dominant species and diversity: linking relative abundance to controls of species establishment. American Naturalist 174: 850–862.
View Article
Google Scholar

[17] View Article

[18] Google Scholar

[ref7] 7. Grime JP (1987) Dominant and subordinate components of plant communities: Implications for succession, stability and diversity. In: Gray AJ, Crawley MJ, Edwards PJ, editors. Colonization, Succession and Stability. Oxford, UK: Blackwell Scientific Publications. pp. 413–428.

[ref8] 8. Sousa WP (1979) Experimental investigations of disturbance and ecological succession in a rocky inter-tidal algal community. Ecological Monographs 49: 227–254.
View Article
Google Scholar

[21] View Article

[22] Google Scholar

[ref9] 9. Smith MD, Knapp AK (1999) Exotic plant species in a C-4-dominated grassland: invasibility, disturbance, and community structure. Oecologia 120: 605–612.
View Article
Google Scholar

[24] View Article

[25] Google Scholar

[ref10] 10. Gagnon PR, Platt WJ (2008) Multiple disturbances accelerate clonal growth in a potentially monodominant bamboo. Ecology 89: 612–618.
View Article
Google Scholar

[27] View Article

[28] Google Scholar

[ref11] 11. Thaxton JM, Platt WJ (2006) Small-scale fuel variation alters fire intensity and shrub abundance in a pine savanna. Ecology 87: 1331–1337.
View Article
Google Scholar

[30] View Article

[31] Google Scholar

[ref12] 12. Albertson FW, Tomanek GW (1965) Vegetation changes during a 30-year period in grassland communities near Hays, Kansas. Ecology 46: 714–720.
View Article
Google Scholar

[33] View Article

[34] Google Scholar

[ref13] 13. Adler PB, HilleRisLambers J, Kyriakidis PC, Guan QF, Levine JM (2006) Climate variability has a stabilizing effect on the coexistence of prairie grasses. Proceedings of the National Academy of Sciences of the United States of America 103: 12793–12798.
View Article
Google Scholar

[36] View Article

[37] Google Scholar

[ref14] 14. Pierce S, Luzzaro A, Caccianiga M, Ceriani RM, Cerabolini B (2007) Disturbance is the principal alpha-scale filter determining niche differentiation, coexistence and biodiversity in an alpine community. Journal of Ecology 95: 698–706.
View Article
Google Scholar

[39] View Article

[40] Google Scholar

[ref15] 15. Papaik MJ, Canham CD (2006) Species resistance and community response to wind disturbance regimes in northern temperate forests. Journal of Ecology 94: 1011–1026.
View Article
Google Scholar

[42] View Article

[43] Google Scholar

[ref16] 16. Busby PE, Motzkin G, Foster DR (2008) Multiple and interacting disturbances lead to Fagus grandifolia dominance in coastal New England. Journal of the Torrey Botanical Society 135: 346–359.
View Article
Google Scholar

[45] View Article

[46] Google Scholar

[ref17] 17. Gagnon PR, Platt WJ, Moser EB (2007) Response of a native bamboo (Arundinaria gigantea {Walt.} Muhl.) in a wind-disturbed forest. Forest Ecology and Management 241: 288–294.
View Article
Google Scholar

[48] View Article

[49] Google Scholar

[ref18] 18. Walker J, Peet RK (1984) Composition and species-diversity of pine-wiregrass savannas of the green swamp, North Carolina. Vegetatio 55: 163–179.
View Article
Google Scholar

[51] View Article

[52] Google Scholar

[ref19] 19. Collins SL, Gibson DJ (1990) Effects of fire on community structure in tallgrass and mixed-grass prairies. In: Collins SL, Wallace LL, editors. Fire in North American Tallgrass Prairies. Norman, OK USA: University of Oklahoma Press. pp. 81–98.

[ref20] 20. Keddy PA, Smith L, Campbell DR, Clark M, Montz G (2006) Patterns of herbaceous plant diversity in southeastern Louisiana pine savannas. Applied Vegetation Science 9: 17–26.
View Article
Google Scholar

[55] View Article

[56] Google Scholar

[ref21] 21. Brewer JS, Cunningham AL, Moore TP, Brooks RM, Waldrup JL (2009) A six-year study of fire-related flowering cues and coexistence of two perennial grasses in a wet longleaf pine (Pinus palustris) savanna. Plant Ecology 200: 141–154.
View Article
Google Scholar

[58] View Article

[59] Google Scholar

[ref22] 22. Gibson DJ (2009) Grasses and Grassland Ecology. New York: Oxford University Press. 305 p.

[ref23] 23. Edwards EJ, Osborne CP, Stromberg CAE, Smith SA, Consortium CG (2010) The Origins of C-4 Grasslands: Integrating Evolutionary and Ecosystem Science. Science 328: 587–591.
View Article
Google Scholar

[62] View Article

[63] Google Scholar

[ref24] 24. Noel JM, Platt WJ, Moser EB (1998) Structural characteristics of old- and second-growth stands of longleaf pine (Pinus palustris) in the gulf coastal region of the USA. Conservation Biology 12: 533–548.
View Article
Google Scholar

[65] View Article

[66] Google Scholar

[ref25] 25. Platt WJ (1999) Southeastern pine savannas. In: Anderson RC, Fralish JS, Baskin JM, editors. Savannas, Barrens, and Rock Outcrop Plant Communities of North America. Cambridge, UK: Cambridge University Press. pp. 23–51.

[ref26] 26. Hiers JK, O'Brien JJ, Mitchell RJ, Grego JM, Loudermilk EL (2009) The wildland fuel cell concept: an approach to characterize fine-scale variation in fuels and fire in frequently burned longleaf pine forests. International Journal of Wildland Fire 18: 315–325.
View Article
Google Scholar

[69] View Article

[70] Google Scholar

[ref27] 27. Mitchell RJ, Hiers JK, O'Brien J, Starr G (2009) Ecological forestry in the southeast: understanding the ecology of fuels. Journal of Forestry 107: 391–397.
View Article
Google Scholar

[72] View Article

[73] Google Scholar

[ref28] 28. Loudermilk EL, Hiers JK, O'Brien JJ, Mitchell RJ, Singhania A, et al. (2009) Ground-based LIDAR: a novel approach to quantify fine-scale fuelbed characteristics. International Journal of Wildland Fire 18: 676–685.
View Article
Google Scholar

[75] View Article

[76] Google Scholar

[ref29] 29. Williamson GB, Black EM (1981) High-temperature of forest fires under pines as a selective advantage over oaks. Nature 293: 643–644.
View Article
Google Scholar

[78] View Article

[79] Google Scholar

[ref30] 30. Platt WJ, Carr SM, Reilly M, Fahr J (2006) Pine savanna overstorey influences on ground-cover biodiversity. Applied Vegetation Science 9: 37–50.
View Article
Google Scholar

[81] View Article

[82] Google Scholar

[ref31] 31. Earley LS (2004) Looking for Longleaf: The Fall and Rise of an American Forest. Chapel Hill, NC, USA: The University of North Carolina Press.

[ref32] 32. Myers JA, Harms KE (2011) Seed arrival and ecological filters interact to assemble high-diversity plant communities. Ecology 92: 676–686.
View Article
Google Scholar

[85] View Article

[86] Google Scholar

[ref33] 33. SAS (2005) SAS Online Documentation 9.1.3. Cary, North Carolina, USA: SAS Institute Inc.

[ref34] 34. Littell RC, Milliken GA, Stroup WW, Wolfinger RD, Schabenberger O (2006) SAS for Mixed Models. Carey, North Carolina, USA: SAS Institute Inc. 814 p.

[ref35] 35. Platt WJ, Evans GW, Rathbun SL (1988) The population dynamics of a long-lived conifer (Pinus palustris). American Naturalist 131: 491–525.
View Article
Google Scholar

[90] View Article

[91] Google Scholar

[ref36] 36. Varner JM, Gordon DR, Putz FE, Hiers JK (2005) Restoring fire to long-unburned Pinus palustris ecosystems: Novel fire effects and consequences for long-unburned ecosystems. Restoration Ecology 13: 536–544.
View Article
Google Scholar

[93] View Article

[94] Google Scholar

[ref37] 37. Rebertus AJ, Williamson GB, Moser EB (1989) Longleaf pine pyrogenicity and turkey oak mortality in Florida xeric sandhills. Ecology 70: 60–70.
View Article
Google Scholar

[96] View Article

[97] Google Scholar

[ref38] 38. Bond WJ, van Wilgen BW (1996) Fire and plants. London: Chapman and Hall.

[ref39] 39. Bond WJ, Keeley JE (2005) Fire as a global ‘herbivore’: the ecology and evolution of flammable ecosystems. Trends in Ecology & Evolution 20: 387–394.
View Article
Google Scholar

[100] View Article

[101] Google Scholar

[ref40] 40. Pausas JG, Keeley JE (2009) A Burning Story: The Role of Fire in the History of Life. Bioscience 59: 593–601.
View Article
Google Scholar

[103] View Article

[104] Google Scholar

[ref41] 41. Kirkman LK, Mitchell RJ, Helton RC, Drew MB (2001) Productivity and species richness across an environmental gradient in a fire-dependent ecosystem. American Journal of Botany 88: 2119–2128.
View Article
Google Scholar

[106] View Article

[107] Google Scholar

[ref42] 42. Silvertown J, Franco M, Pisanty I, Mendoza A (1993) Comparative plant demography - Relative importance of life cycle components to the finite rate of increase in woody and herbaceous perennials. Journal of Ecology 81: 465–476.
View Article
Google Scholar

[109] View Article

[110] Google Scholar

[ref43] 43. Benton TG, Grant A (1996) How to keep fit in the real world: Elasticity analyses and selection pressures on life histories in a variable environment. The American Naturalist 147: 115–139.
View Article
Google Scholar

[112] View Article

[113] Google Scholar

[ref44] 44. Crone EE (2001) Is survivorship a better fitness surrogate than fecundity? Evolution 55: 2611–2614.
View Article
Google Scholar

[115] View Article

[116] Google Scholar

[ref45] 45. Bruna EM (2003) Are plant populations in fragmented habitats recruitment limited? Tests with an Amazonian herb. Ecology 84: 932–947.
View Article
Google Scholar

[118] View Article

[119] Google Scholar

[ref46] 46. Franco M, Silvertown J (2004) Comparative demography of plants based upon elasticities of vital rates. Ecology 85: 531–538.
View Article
Google Scholar

[121] View Article

[122] Google Scholar

[ref47] 47. Bruna EM, Fiske IJ, Trager MD (2009) Habitat fragmentation and plant populations: is what we know demographically irrelevant? Journal of Vegetation Science 20: 569–576.
View Article
Google Scholar

[124] View Article

[125] Google Scholar

[ref48] 48. Gagnon PR, Bruna EM, Rubim P, Darrigo MR, Littell RC, et al. (2011) Growth of an understory herb is chronically reduced in Amazonian forest fragments. Biological Conservation 144: 830–835.
View Article
Google Scholar

[127] View Article

[128] Google Scholar

Figures

Abstract

Introduction

Materials and Methods

Study site, focal organisms and experimental design

Quantitative analyses

Results

Discussion

Fire with added fuels alters bunchgrass survivorship, growth and fecundity

Effects of added fuels differed between the two co-dominants

Supporting Information

Table S1.

Table S2.

Table S3.

Table S4.

Table S5.

Acknowledgments

Author Contributions

References