Amy Concilio

Research

The Front Range has experienced increased winter precipitation and nitrogen deposition over the last several decades, which appears to be affecting invasive species encroachment.

GLOBAL CHANGE AND ECOSYSTEM TRANSFORMATION IN THE COLORADO FRONT RANGE

Over the last several decades, the Front Range of Colorado has been experiencing interacting agents of global change that may be driving the system toward full-scale transformation. Winter precipitation and nitrogen availability have increased over the last 30 years (via climate change and increased anthropogenic nitrogen deposition), which may be responsible (at least in part) for increased dominance of exotic cool season annual and perennial plants that the region has experienced over the same time period.  The native black-tailed prairie dog, considered a keystone species in many intact grasslands, appears to be interacting with these new communities in unexpected ways—by denuding the landscape and facilitating winter dust storms.  Understanding how and why these changes are occurring is essential to making better land management decisions.  As a post-doctoral scholar working with Drs. Tim Seastedt and Jesse Nippert (KSU), I am researching mechanisms that allow invasive species to become dominant in grasslands of the Front Range.  We set up a series of in-situ experiments (in which precipitation, nitrogen availability, and invader presence are being manipulated) to test hypotheses about plant community response to changing climatic and edaphic conditions and to quantify competitive interactions between invasive and native plants under past, present, and future predicted conditions.  Results from these experiments will be used (in conjunction with studies on the role of prairie dogs in this altered landscape) to better inform land management in a time of rapid environmental change.

We are using snow fences to manipulate snow depth and study the effects of climate change on Bromus tectorum spread in the eastern Sierra Nevada, CA. The fences create zones of increased and decreased snow.

GLOBAL CHANGE EFFECTS ON BROMUS TECTORUM IN THE EASTERN SIERRA NEVADA, CA

The invasive annual grass Bromus tectorum (cheatgrass, downy brome) is ubiquitous across the Great Basin Desert, where it has displaced native plant communities and caused changes to the fire cycle.  It is currently limited at the western edge of the Great Basin along the eastern escarpment of the Sierra Nevada range, probably due to physiological constraints associated with cold winter temperatures and deep snowpack.  However, predicted changes in climatic and edaphic conditions (due to climate change and anthropogenic nitrogen deposition) may facilitate upward range expansion.  For my dissertation research, I worked with Dr. Michael E. Loik (UC- Santa Cruz) to set up a series of manipulative experiments to determine how global change might affect the spread of B. tectorum in the eastern Sierra Nevada.  We focused on changes in snowpack (using snow fences to simulate areas of increased and decreased snow), spring rainfall (using irrigation to simulate storms of different frequency and magnitude), and increased anthropogenic nitrogen deposition (by adding 0, 5, or 10 g N m-2 annually to plots).  Results from this work were published with M.E. Loik and J. Belnap in Global Change Biology.  With Dr. Alden Griffith (Wellesley College), we are continuing to monitor B. tectorum populations in response to natural interannual variations in snowpack and simulated increases and decreases in snow (using the same snow fences).  In 2015, we will have collected 10 years of data on this project.  We anticipate that this long-term empirical dataset may provide new insight into how the interaction of temperature and snowfall affects B. tectorum population growth at high elevation. 

The eastern Sierra Nevada is a land of extremes in climate and topography. Although the region has remained relatively pristine, it faces new challenges with climate change and potential invasive species encroachment.

EFFECTS OF NITROGEN DEPOSITION ON BROMUS TECTORUM DOMINANCE AND NATIVE SPECIES DIVERSITY

Increases in nitrogen (N) emissions and deposition have been occurring throughout the western U.S. over the last half-century as a result of industry, agriculture, and transportation.  Plant responses to excess N can vary by functional type or species, and increased N can consequently be associated with changes in species composition.  Fast-growing plants, such as invasive species, generally respond to N additions with the largest increases in productivity because they can more readily take advantage of excess resources.  Consequently, increased N deposition can facilitate the invasion of non-native plants and the loss of native flora and associated fauna.  Although much research has investigated the ecological effects of N deposition on plant communities, there is a particular lack of understanding in arid and semi-arid systems. Those studies that have been conducted in western US deserts have shown that increased N deposition can increase the dominance of invasive annual plants.  As a PhD student, I started a manipulative experiment to look at how plant communities in the eastern Sierra Nevada might change with increased N deposition, with a focus on dominance of the invasive annual grass, Bromus tectorum.  Early results from this work (after the first 4 years) were published with M.E. Loik in Applied Vegetation Science.  Although we measured no change in plant community composition in response to elevated N thus far, we suspect that shifts might occur during years of high precipitation (since plants in this system are probably more limited by water than nutrients).  We are continuing to monitor these same plots over the longer-term to test this hypothesis.

INVASIVE SPECIES EFFECTS ON SOIL NUTRIENT CYCLING

Plants affect the microbial community directly around the root zone, in the rhizosphere, and can subsequently have indirect effects on decomposition in the bulk soil.  Rates of decomposition may be increased or decreased in the presence of plants compared to unplanted soils through the process of rhizosphere priming.  Because of differences in priming between plant species, it is likely that exotic plant invasion could lead to altered decomposition rates compared to uninvaded areas.  There is much evidence that exotic plants do, indeed, affect nutrient cycling and decomposition, but there have been few studies that have examined the magnitude or direction of their rhizosphere priming effect (RPE).  My research focus has been on Bromus tectorum, an annual invasive grass.  There is evidence that invasion by this species may result in higher nitrogen availability, potentially creating a positive feedback for its own spread (since fast-growing exotics like B. tectorum often outcompete natives under conditions of elevated nitrogen availability).  Research on how invasive species, like B. tectorurm, affect RPE could help explain mechanisms behind invasion patterns and impacts.  Working with Drs. Weixin Cheng (UC-Santa Cruz) and Thiago Vargas (Universidade Federal do Paraná, Brazil), we conducted a greenhouse experiment to determine how Bromus tectorum affects soil nitrogen cycling and RPE in the presence of native bunchgrasses in invaded and uninvaded soils.  Our paper was just accepted with revisions in Plant and Soil.

Bromus tectorum infestations at high elevation in the eastern Sierra Nevada are mainly along roadsides and would be relatively easy targets for eradication.

EFFECTIVENESS OF LOW-TECH APPROACHES TO BROMUS TECTORUM CONTROL AT HIGH ELEVATION

At the edge of many exotic plant invasions, outlier infestations exist that can facilitate spread by acting as seed sources to uninvaded sites. Targeting these patches for eradication while they are relatively small in size could significantly reduce the associated long-term costs and impacts of the invasion.  As a PhD student, I evaluated control techniques for eradicating outlier patches of the invasive annual grass Bromus tectorum in the eastern Sierra Nevada, CA, at the high elevation edge of the invasion.  I compared both ecological effectiveness (through in-situ experiments) and associated costs (by recording time, labor, and materials costs) of soil solarization, mulching, and hand pulling followed by seedball and broadcast seeding.  Results from this study were published in Invasive Plant Science and Management.

FEASIBILITY OF INVASIVE SPECIES CONTROL FROM LOGISTICAL, SOCIAL, AND REGULATORY CONTEXTS

Invasive species biologists often think primarily about feasibility of control in terms of ecological effectiveness.  In reality, invasive plant managers working on public lands have broader definitions of feasibility, which might include logistical, social, economic, or regulatory considerations, among others.  Working with Dr. Zdravka Tzankova (UC-Santa Cruz), we are evaluating the feasibility of control of Bromus tectorum in the eastern Sierra Nevada, CA from this broader perspective.  We conducted semi-structured interviews with public land managers in the region and an in-depth literature review of relevant state and federal legislation and policy as well as agency management plans that affect invasive plant control to evaluate barriers and opportunities to B. tecotrum control.  Many of our results are not unique to B. tectorum, but apply more broadly to invasive plant control on public land at the state and federal levels.  Our results were published in the journal Biological Invasions and made available to land managers in the region.  Some of this work was also featured in an article I wrote for the journal Fremontia (May 2013), which is read by professional and amateur botanists and land managers in California. 

Research Activities

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