Abstract

Before the arrival of white-nose syndrome in North America, the northern long-eared bat (Myotis septentrionalis) was a common cavity-roosting bat species in central Appalachian hardwood forests. Two successive prescribed burns on the Fernow Experimental Forest, West Virginia, in 2008 and 2009, were shown to positively affect maternity colony day-roost availability and condition in the near-term. However, whether immediate benefits were temporary and if burned forests actually experienced an accelerated loss of trees and snags possibly suitable for bats more than background loss in unburned forests became an important question following the species’ threatened designation. In 2016, we revisited 81 of 113 northern long-eared bat maternity colony day-roosts initially discovered in 2007–2009 with the objective of ascertaining if these trees and snags were still standing and thus potentially “available” for bat use. Initial tree or snag stage condition class and original year of discovery were contributory factors determining availability by 2016, whereas exposure to prescribed fire and tree/snag species decay resistance were not. Because forest managers may consider using habitat enhancement to improve northern long-eared bat survival, reproduction, and juvenile recruitment and must also protect documented day-roosts during forestry operations, we conclude that initial positive benefits from prescribed burning did not come at the expense of subsequent day-roost loss greater than background rates in these forests at least for the duration we examined.

1. Introduction

Conservation of day-roosts is a central management tenet for many bat species. In much of eastern North America, particularly the heavily forested central and southern Appalachian Mountains, lack of forests and/or trees and snags is not a limiting factor per se as much as forest stand structure that provides optimal condition and spatial configuration of suitable roosts. For example, endangered Indiana bat (Myotis sodalis) summer maternity colonies often require recently fire or flood-disturbed older-age stands containing trees and snags with exfoliating bark and high solar exposure as their ideal roost conditions are ephemeral and transitory [14]. Unfortunately, with disrupted disturbance regimes, i.e., fire suppression, these suitable and often ephemeral conditions can be rare regionally in maturing deciduous forests [5]. Return of fire to the central Appalachian landscape through prescribing burning has been shown to improve foraging habitat conditions for bats generally by reducing forest “clutter” such as midstory growth [6, 7].

For day-roost conditions, burning improves, at least temporarily, conditions for Indiana bats and the threatened northern long-eared bats (Myotis septentrionalis) [5, 8]. In the maternity season, female northern long-eared bat day-roosts are in cavities of live trees or standing snags across a wide variation in bole size and solar exposure [9]. Although some northern long-eared bat day-roosts are lost from collapse or combustion during a prescribed burn [8], repeated fires can accelerate the processes of both cavity formation and transitioning a healthy tree to a declining tree or snag [10] that is more suitable for a day-roost [11]. Similarly, in the near-term, northern long-eared bat maternity colonies select day-roosts in burned stands more than expected relative to unburned stands based on availability [8]. Ford et al. [12] observed a postfire reduction in trees and standing snags of species favored by northern long-eared bats. However, the proportion of trees and snags in advanced stages of decline or decay suitable for northern long-eared bat day-roosts increased postfire among highly used tree and snag species such as black locust (Robinia pseudoacacia) relative to unburned stands. Additionally, maternity colony social cohesion, as measured by the centrality of day-roosts used and numbers shared by conspecifics, was greater in burned stands than unburned stands [12].

The use of fire as a forest management tool in the central Appalachians typically is targeted towards other stewardship needs such as controlling shade-tolerant competition to foster oak (Quercus spp.) regeneration or to maintain early successional habitat types [13, 14]. Although evidence suggests that burning can provide benefits to bats in the region, questions remain about the longevity of bat day-roosts and the long-term effects following fire [15]. Disruption of northern long-eared bat maternity colony social networks can be caused by day-roost losses exceeding 30% from one year to the next [16]. Because this species has been heavily impacted by white-nose syndrome, with population declines exceeding 90% in the central Appalachians [17], forest managers now seek to enhance summer maternity day-roosting habitat for this species to promote successful reproduction and juvenile recruitment [18]. For northern long-eared bats, it is not known if prescribed fire provides only short-term day-roost benefits followed by an accelerated loss relative to background conditions. This could have conservation implications for the use of fire in forests where northern long-eared bats occur or the use of fire as a specific bat habitat management tool.

Accordingly, in 2016, we tracked fate (standing or fallen) of northern long-eared bat maternity colony day-roost trees and snags recorded from 2007 to 2009 at the Fernow Experimental Forest (FEF) in northcentral West Virginia [8, 11, 12] in burned and unburned areas. We predicted that the probability of a day-roost tree or snag remaining in 2016 would be negatively related to initial tree or snag condition class when first discovered, positively related to tree or snag species wood specific gravity as a surrogate for wood decay resistance, negatively related to exposure to fire, and negatively related to time of original discovery.

2. Methods

2.1. Study Area

We examined data for northern long-eared bat day-roosts that were originally collected by [5, 8] from the FEF in northeastern West Virginia (39°03′15″N 79°41′15″W). The FEF is a 1,900 ha experimental forest managed by the U.S. Forest Service, Northern Research Station, located in the unglaciated Allegheny Plateau portion of the central Appalachians. Topography is characterized by steep slopes and plateau-like ridgetops. Elevations range from 530 m to 1100 m [19]. Mean annual precipitation at FEF is 145.8 cm and mean annual temperature is 9.2°C, with an average frost-free period of 145 days [20]. Forest stands on the FEF are a mosaic of second- and third-growth, mixed-mesophytic, and northern hardwood types that have been managed by various even- and uneven-aged harvesting practices or have been left undisturbed following initial harvesting in the early 20th century [19, 21]. On parts of the FEF and much of the surrounding Monongahela National Forest, American chestnut (Castanea dentata) and oaks (Quercus spp.), such as northern red oak (Quercus rubra), historically dominated the forest overstory. However, chestnut blight (Cryphonectria parasitica) and subsequent lack of intense disturbance, including fire and harvesting, since the mid-20th century has allowed forest composition in unmanaged stands to shift toward shade-tolerant tree species, such as maples (Acer spp.) and American beech (Fagus grandifolia) [21]. Since 2002, prescribed fire has been used to promote oak regeneration in some FEF forest stands where the regeneration layer is currently dominated by sugar maple (Acer saccharum), red maple (Acer rubrum), yellow-poplar (Liriodendron tulipifera), black cherry (Prunus serotina), American beech, sweet birch (Betula lenta), and basswood (Tilia americana) [8, 22]. In early spring of 2007 and 2008, consecutive prescribed fires were conducted in a 121 ha compartment on the FEF that had been relatively free of management except for scattered light timber stand improvement entries in the previous decades. Treatment stands were burned using a strip head fire technique, ignited with handheld drip torches after fire-blackened perimeters were established [12].

2.2. Data Collection

During the summers of 2007–2009, we mist-netted and captured northern long-eared bats on the FEF in and around the burned compartment. Captured adult females were outfitted with radio-transmitters and tracked to their maternity colony day-roosts for the life of the transmitter or until the transmitter fell off. For complete details on mist-netting and tracking techniques, see [8, 11, 12]. Numerous metrics were recorded to describe and differentiate day-roost characteristics between the burned compartment and adjacent unburned stands such as diameter at breast height, crown class, condition class, bark retention, cavity presence, roost type (cavity or bark), and tree height of day-roost as well as surrounding basal area, and these data are presented elsewhere [8, 11, 12]. Because all located day-roosts from 2007 to 2009 were georeferenced and tagged, in the summer of 2016, U.S. Forest Service, Northern Research Station staff relocated a large portion of the day-roosts to establish necessary protective buffer zones pursuant to the requirements in the northern long-eared bat 4(d) rule [23]. Located day-roosts were then recorded as live tree, standing snag, or fallen. No other measurements were collected nor were day-roosts checked for continued occupancy by northern long-eared bats or any other myotids, as the impacts of WNS and subsequent precipitous population declines ∼90% observed in Big Springs Cave, a sizable bat hibernaculum on the FEF, made that unlikely. It is possible that the other cavity-roosting bat species present, the big brown bat (Eptesicus fuscus), used these as day-roosts; however, none were noted roosting in earlier surveys [8], and their presence on FEF is relatively low [24].

2.3. Data Analysis

To assess the effect of being subjected to prescribed fire or unburned (FIRE), initial tree or snag condition class (STAGE: 1–7) [25], surrogate decay resistance rank from tree species specific gravity values collected at the FEF (RANK) [26], diameter at breast height (DBH), and year of initial discovery (YEAR: 2007–2009), we modeled the outcome of day-roosts remaining standing and presumably available versus fallen. Ideally, these data would be analyzed using a survival analysis approach [27]; however, without annual assessments from 2009 to 2016, this was not possible. Therefore, because we could only assess the final time step outcome, we used a generalized linear model with a binomial distribution and a logit link function (PROC GENMOD, SAS 10.2, Cary, NC). Surrogate decay resistance ranks were different among all species of trees and snags; therefore, this variable also served as a surrogate for species. Because determining if fire had an effect on day-roost availability was our primary question, all candidate models contained the FIRE variable. With FIRE, we modeled and ranked all combinations of the four variables (STAGE, RANK, DBH, and YEAR) using Akaike’s information criteria (AIC) value corrected for small sample size [28].

3. Results

Of 113 northern long-eared bat day-roosts recorded from 2007 to 2009, 81 were relocated in the 2016 search effort with 78 being used in our analyses. Three of these day-roosts had been cut from long-term silvicultural studies prior to the listing of the northern long-eared bat and were excluded. Of the 15 that were originally live trees, 12 remained alive and standing in 2016, 2 had become standing dead snags, and 1 tree had fallen. Of the 63 that were originally standing snags, 39 remained standing in 2016, whereas 24 had fallen. Trees and snags that remained available as day-roosts averaged 29.8 ± 9.8 cm diameter at breast height at the time of original discovery, whereas those that had fallen averaged 26.6 ± 6.8 cm. Black locust, red maple, and sassafras (Sassafras albidum) comprised approximately 70% of the day-roosts relocated in 2016 with 40%, 36%, and 38%, respectively, becoming unavailable by 2016. Conversely, of the 10 northern red oaks, 3 chestnut oaks (Quercus prinus), one black oak (Quercus velutina), and one white oak (Quercus alba) monitored through 2016, only a single northern red oak, originally in decay stage 3, and the one white oak, originally in decay stage 6, had fallen by 2016.

The model retaining fire, initial decay stage, and year of initial day-roost discovery was the top supported model (Table 1). Day-roost species or size were not as important, as no model containing decay resistance rank or diameter at breast height was within ΔAICc < 2. The only other variable combinations with support were fire and year of initial day-roost discovery or fire and initial decay stage (Table 1). From the top supported model, there was no difference in standing versus fallen outcomes attributable to exposure to prescribed burning (Table 2, Figure 1). Both original year of day-roost discovery and initial condition class affected day-roost availability by 2016, though parameter estimate confidence intervals just crossed zero (Table 2). Day-roosts discovered initially in 2009 were less likely to remain standing in 2016 than those from 2007 to 2008 (Figure 1). Day-roosts in higher condition classes, i.e., live trees in decay stage 2 or snags with a higher degree of decay, upon initial discovery 2007–2009, were more likely to have fallen by 2016 (Figure 1).

4. Discussion

Ford et al. [8, 12] showed that relatively small-sized live trees and trees or snags in decay condition classes 2–6 [25] composed approximately 50% of day-roosts used on the FEF by northern long-eared bats. Black locust along with red maple, northern red oak, and black oak were the only species selected more than availability would suggest from the FEF’s diverse tree species pool [5, 8, 12]. Irrespective of the introduction of fire, abundant numbers of small to medium-sized black locust and sassafras trees and snags with cavities suitable for northern long-eared bat day-roosts would be common in these FEF stands owing to the stand age and known patterns of stand development in the central Appalachians [29]. Although some day-roosts located initially in 2007 were snags that predated the two prescribed burns on the FEF, northern long-eared bats in 2008 and 2009 did use snags that were a direct result of tree mortality following fire [8, 12].

A preponderance of research, mostly from western North America, suggests that longevity of trees that become snags or current snags following fire can be one-third to one-half as long as that in unburned stands [30]. These comparisons are relatively limited for deciduous forests where we worked or conifer, i.e., southern pine (Pinus spp.) or boreal systems in the East. Our data show no substantive difference in the probability of a burned tree or snag remaining available as a day-roost over time as compared to unburned trees at the FEF. In hardwood forests, surprisingly, snag persistence across most size classes of boles and tree species may only be about 10 years in the southern Piedmont [31] and 20–25 years in the northern Appalachians [32]. At the FEF, either the progression from tree to decaying snag to fallen coarse woody debris may occur quickly; masking fire effects on our resampling effort in 2016 had not allowed enough time to elapse for differentiation among rates of senescence. Despite a slightly higher probability of roost trees remaining available overall in unburned stands, the rates of change of availability between unburned and burned in our study were similar. For the most part, the loss of day-roosts following the two successive prescribed fires on the FEF probably did not cause loss more than background rates that were normally occurring as part of ongoing forest dynamic processes. Year of initial discovery was a factor contributing to long-term availability of day-roosts. Those initially found in 2009 were less likely to be available to northern long-eared bats by 2016. However, we attribute this paradox to the relatively small number (4) of new day-roosts, only in burned stands, added in 2009. It is possible, of course, that these day-roosts were also used in 2007 and 2008 without being documented, as northern long-eared bat maternity colonies often will occupy the same relatively small general location for successive years in temperate deciduous forests so long as day-roosts are suitable [9].

What remains unknown from our assessment of day-roost availability on the FEF is the annual to long-term trend in recruitment and loss in live trees and snags with cavities suitable for northern long-eared bats. Cavity tree and snag abundance can be highly variable in the central and southern Appalachians depending on forest type [33], though often, there is no relationship between these and forest stand age [34]. Archived data from an unmanaged watershed on the FEF showed there was an annual recruitment of 0.4 snags/ha/year >12.7 cm. In mid-1960s, there was an average of 15.5 snags/ha increasing to 38.1/ha by 2019, densities greater than per area needs of northern long-eared bat maternity colonies [35]. Subtle changes in snag species are apparent over these 50+ years with early successional black locust and sassafras comprising a large proportion of snags initially and then oak snags increasing in three decades later, a group highly selected as day-roosts for the northern long-eared bat in the southern Appalachians [36].

5. Conclusions

Some forest dwelling bat species require a shifting mosaic across the landscape of some ephemeral trees or stand conditions [5, 37]. At the landscape scale in central Appalachian oak-pine forests, prescribed fire has been shown capable of providing that stand condition heterogeneity [38]. However, the day-roost ecology of the northern long-eared bat operates more at the forest stand level and with a high cosmopolitan use of a wide range of trees or snags sizes across multiple species including very small (<10 cm dbh) boles in midaged to old-growth deciduous forests [9, 39] amenable to the changes from stand level burning [10]. Assuming potential day-roosts recruitment approximates or exceeds annual losses over successive years and/or any given natural or anthropogenic disturbance does not remove a relatively large number of day-roosts in a given year [16], forest conditions on the FEF probably provide sufficient roost conditions from year to year in most stands. The studies [8, 11, 12] clearly demonstrated benefits to northern long-eared bat maternity colonies as a result of two prescribed burns. Whether this would be true with multiple fires and/or long-term management by frequent fires in this forest or other forest types in the species’ distribution is unknown and merits further research. Also, owing to the decline in bat numbers due to white-nose syndrome, we have no way of knowing if continued use or potential abandonment by bats due to some interactions of being within a burned stand across the decay class continuum would have occurred. Nonetheless, our study adds clarity to fire and roost availability by showing that an accelerated loss of day-roosts in burned stands versus unburned stands did not occur over the time examined. This is useful for both forest managers and those tasked with conserving the northern long-eared bat from a regulatory standpoint.

Data Availability

The datasets used and/or analyzed during the current study are available from the corresponding author upon request.

Disclosure

Any use of trade, firm, or product names is for descriptive purposes only and does not imply endorsement by the U.S. Government.

Conflicts of Interest

The authors declare that they have no conflicts of interest.

Authors’ Contributions

WMF and JBJ conceived the study. WMF provided study oversight, performed the analyses, and prepared the manuscript. JBJ and MTV collected field data. WMF, JBJ, and MTV interpreted the data and edited and prepared the manuscript for submission.

Acknowledgments

The authors thank D. Lowther, R. Hovatter, M. Karp, J. Rodrigue, T. Schuler, and numerous FEF summer interns for field assistance throughout this effort. Financial support for this project was provided by U.S. Forest Service, Northern Research Station.