Month: February 2020

Categories
Biodiversity Blog Faculty Spotlight Geology Global Change Research

Virginia Tech paleontologists identify 1 billion-year-old green seaweed fossils, ancestors to modern land plants

[vc_row][vc_column][vc_column_text]From VT News | February 24, 2020

Virginia Tech paleontologists have made a remarkable discovery in China: 1 billion-year-old micro-fossils of green seaweeds that could be related to the ancestor of the earliest land plants and trees that first developed 450 million years ago.

The micro-fossil seaweeds — a form of algae known as Proterocladus antiquus — are barely visible to the naked eyed at 2 millimeters in length, or roughly the size of a typical flea. Professor Shuhai Xiao said the fossils are the oldest green seaweeds ever found. They were imprinted in rock taken from an area of dry land — formerly ocean — near the city of Dalian in the Liaoning Province of northern China. Previously, the earliest convincing fossil record of green seaweeds were found in rock dated at roughly 800 million years old.

The findings — led by Xiao and Qing Tang, a post-doctoral researcher, both in the Department of Geosciences, part of the Virginia Tech College of Science — are featured in the latest issue of Nature Ecology & Evolution. “These new fossils suggest that green seaweeds were important players in the ocean long before their land-plant descendants moved and took control of dry land,” Xiao said.

A computerized depiction of ancient green seaweed in the ocean, with the fossilized plants in the foreground.
In the background of this digital recreation, ancient microscopic green seaweed is seen living in the ocean 1 billion years ago. In the foreground is the same seaweed in the process of being fossilized far later. Image by Dinghua Yang.

 

“The entire biosphere is largely dependent on plants and algae for food and oxygen, yet land plants did not evolve until about 450 million years ago,” Xiao said. “Our study shows that green seaweeds evolved no later than 1 billion years ago, pushing back the record of green seaweeds by about 200 million years. What kind of seaweeds supplied food to the marine ecosystem?”

Shuhai said the current hypothesis is that land plants — the trees, grasses, food crops, bushes, even kudzu — evolved from green seaweeds, which were aquatic plants. Through geological time — millions upon millions of years — they moved out of the water and became adapted to and prospered on dry land, their new natural environment. “These fossils are related to the ancestors of all the modern land plants we see today.”

However, Xiao added the caveat that not all geobiologists are on the same page – that debate on the origins of green plants remains debated.Not everyone agrees with us; some scientists think that green plants started in rivers and lakes, and then conquered the ocean and land later,” added Xiao, a member of the Virginia Tech Global Change Center.

 

 

There are three main types of seaweed: brown (Phaeophyceae), green (Chlorophyta), and red (Rhodophyta), and thousands of species of each kind. Fossils of red seaweed, which are now common on ocean floors, have been dated as far back as 1.047 billion years old.

“There are some modern green seaweeds that look very similar to the fossils that we found,” Xiao said. “A group of modern green seaweeds, known as siphonocladaleans, are particularly similar in shape and size to the fossils we found.”

Photosynthetic plants are, of course, vital to the ecological balance of the planet because they produce organic carbon and oxygen through photosynthesis, and they provide food and the basis of shelter for untold numbers of mammals, fish, and more. Yet, going back 2 billion years, Earth had no green plants at all in oceans, Xiao said.

Geobiology professor Shuhai Xiao, right, poses for a portrait with his postdoctorate Qing Tang in Derring Hall.
Geobiology professor Shuhai Xiao (right) and postdoctorate researcher Qing Tang in their Derring Hall lab.

 

It was Tang who discovered the micro-fossils of the seaweeds using an electronic microscope at Virginia Tech’s campus and brought it to Xiao’s attention. To more easily see the fossils, mineral oil was dripped onto the fossil to create a strong contrast.

“These seaweeds display multiple branches, upright growths, and specialized cells known as akinetes that are very common in this type of fossil,” he said. “Taken together, these features strongly suggest that the fossil is a green seaweed with complex multicellularity that is circa 1 billion years old. These likely represent the earliest fossil of green seaweeds. In short, our study tells us that the ubiquitous green plants we see today can be traced back to at least 1 billion years.”

According to Xiao and Tang, the tiny seaweeds once lived in a shallow ocean, died, and then became “cooked” beneath a thick pile of sediment, preserving the organic shapes of the seaweeds as fossils. Many millions of years later, the sediment was then lifted up out of the ocean and became the dry land where the fossils were retrieved by Xiao and his team, which included scientists from Nanjing Institute of Geology and Paleontology in China.

Related stories

Geosciences’ Shuhai Xiao finds fossils dating back 550 million years, among earliest known displays of animal mobility

Virginia Tech-led study finds oldest footprints of bug dating back 540-plus million years

CONTACT:
Steven Mackay
540-231-5035

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Categories
Blog Energy Global Change

$3 million investment provides boost to university energy efficiency efforts

[vc_row][vc_column][vc_column_text]From VT News | February 24, 2020

Over $3.1 million in approved funding will help Virginia Tech amplify its energy conservation efforts over the next year.

The investment will continue to catalyze the university’s Five-Year Energy Action Plan, a comprehensive blueprint to improve energy efficiency and reduce energy costs within five years in the 50 most energy-intensive, “energy hog” buildings on the Blacksburg campus.

In the first four phases of the Energy Action Plan, the university has reduced its carbon emissions by approximately 23,000 tons per year and saved more than $2.3 million in equivalent annual energy costs.

The plan is swiftly approaching full integration — and expected to yield more than $6 million in overall energy cost savings.

When the Office of Energy Management within the Virginia Tech Facilities Department conducted an energy benchmarking analysis of buildings on the Blacksburg campus in 2015-16, it discovered 50 buildings accounted for more than 70 percent of overall university energy costs; that is just 35 percent of all buildings on campus.

The Energy Action Plan combines energy data analysis with energy accounting and retrofitting projects to achieve significant energy cost reductions. Since 2016, four phases of the Energy Action Plan have been implemented with 10 new energy-intensive buildings incorporated into each phase.

One of the cornerstones of the Energy Action Plan is leveraging data to optimize energy usage to achieve energy efficiency at scale on campus. Ten new buildings are added to the university’s energy management platform during each phase. New smart meter infrastructure also continues to be installed in campus buildings. These efforts, paired with ongoing energy audits in the field, enable practitioners to identify energy consumption patterns in real time to optimize lighting, ventilation, heating, and air based on demand.

Also under the plan, ongoing retrofitting projects, especially in laboratories – largescale energy contributors on campus – continue to help improve energy efficiency in energy hog buildings.

“As we approach the final phase of the of the initial Energy Action Plan, energy conservation remains at the forefront of all Facilities Department activities at Virginia Tech. Through efforts like the Energy Action Plan, award-winning sustainability program, and strong environmental standards for new and existing construction, we will continue to make headway in our energy reduction and sustainability efforts,” said Christopher H. Kiwus, associate vice president and chief facilities officer.

Among the proposed projects under Phase 5 (2019-20) of the Energy Action Plan are:

Implementation of energy retrofit projects identified in Phase 4, which include:

  • LED lighting overhaul in a range of buildings.
  • Lab ventilation optimization.
  • Retro-commissioning of HVAC energy systems.
  • Power plant compressed air system optimization.
  • Integration of 10 additional energy-intensive buildings into the university’s energy management platform.
  • Ongoing meter replacement and maintenance.
  • Implementation of rooftop solar project at the Sterrett Facilities Complex.

“It is an undeniably exciting time to be at Virginia Tech, and this rings especially true as it relates to sustainability. Current initiatives like the Energy Action Plan and revisions to the Climate Action Commitment are strong indicators of the university’s long-term engagement in environmental stewardship. We will continue to work collaboratively in seeking out new opportunities to invest time, knowledge, and financial resources in pursuit of a more sustainable society,” said Dwayne Pinkney, senior vice president and chief business officer.

The  Climate Action Commitment is the university’s guiding framework around sustainability and energy efficiency in campus operations, facilities, curriculum, and research. In continued commitment to sustainability, President Tim Sands recently called for  renewal of the commitment.

A working group of university leaders across operations, academics, research, students, and community representatives are currently examining Climate Action Commitment goals to ensure the most rigorous sustainability standards are implemented.

Energy efficiency is a connecting theme among the subcommittees tasked with delivering recommendations for the commitment’s latest iterations.

For example, the Energy Opportunities subcommittee is reviewing progress and opportunities around energy efficiency as they relate to the campus steam plant, on-campus chiller plantsVirginia Tech Electric Service, and energy demand reductions conducted throughout the year by the Facilities Department.

Similarly, the Buildings Opportunities subcommittee is striving to deliver recommendations that build upon the successes of the Five-Year Energy Action Plan by investigating new ways to boost energy efficiency in new and existing buildings on campus.

Exploring renewable energy opportunities, including solar, biomass, and wind on Virginia Tech properties — and through new partnership building — is central to the efforts of the Renewable Energy Opportunities subcommittee.

The latest information around Virginia Tech’s sustainability achievements, including updates to the Climate Action Commitment, will be shared in the Virginia Tech Daily.

More information about the Climate Action Commitment revision process, working group, and subcommittees may be found here.

Please  click here to learn more about the Five-Year Energy Action Plan. For specific questions on the plan, please contact the Office of Energy Management at 540-231-6348.
Related links

 

CONTACTS:

Alexa Briehl
540-231-7899

Mark Owczarski
540-231-5396

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Categories
Blog Climate Change Conservation Drinking water Educational Outreach Global Change Research Water

Virginia Water Center recognized as a national leader in water education and outreach

[vc_row][vc_column][vc_column_text]From VT News | February 24, 2020

For the first time, the Virginia Water Resources Research Center, housed at Virginia Tech, received a status of “outstanding” from the U.S. Department of the Interior. Virginia’s Water Center was one of 12 such centers in the nation to receive this designation.

“The water center operates as something of a clearinghouse and a focal point for water education, outreach, and research at Virginia Tech,” explained Professor Stephen Schoenholtz, director of the Virginia Water Center and a faculty member in the Department of Forest Resources and Environmental Conservation. “We’re an independent, nonsiloed place to foster and promote research on water issues across a wide range of areas.”

The Virginia Water Resources Research Center traces its origins to the federal Water Resources Research Act of 1964, which sought to establish research centers on matters related to water supply, water quality protection, and water resource management in all 50 states as well as the District of Columbia, Puerto Rico, the U.S. Virgin Islands, and Guam. Virginia Tech was selected to house the commonwealth’s center in 1965. The Virginia Water Resources Research Center was written into the Code of Virginia by the General Assembly in 1982 and is currently housed within Virginia Tech’s College of Natural Resources and Environment.

U.S. water centers and institutes that are part of the 1964 act receive funding in five-year cycles, and their output is evaluated by an independent panel of scientists from the U.S. Geological Survey. The most recent review, for the years 2011 through 2015, credited the program as having done an exemplary job of communicating water news and information to the broader public. The Virginia Water Resources Research Center was further praised for its focus on research aimed at solving state water issues.

“Engagement and outreach have been a big focus for our center over the last decade,” Schoenholtz said. “We aim to provide unbiased information for water resource management decisions that are being made at the state, regional, and national level.”

Among the center’s outreach efforts is a database of breaking water news stories, water-related legislation decisions and documents, and links to information about water-related subjects pertaining to the state. The center produces Virginia Water Radio, a weekly program focusing on a specific water issue or topic of interest in Virginia. The broadcasts are tied to the Virginia Standards of Learning and can be used in K-12 classrooms throughout the state.

The center provides seed grants for undergraduate and graduate students studying water resources and funds an internship program for undergraduate students at Virginia Tech. This spring, two interns traveled with Schoenholtz to Washington, D.C., to meet with federal policymakers to discuss water issues affecting Virginia. The center also led Virginia Tech in developing a unique undergraduate degree program in water: resources, policy, and management, which takes an interdisciplinary approach to water science, management, and policy.

Looking ahead, Schoenholtz would like to increase student training and expand grant opportunities for undergraduate and graduate students. Discussions are also underway about offering master’s and doctoral degrees in water science.

“Water issues range from very local, affecting individual households, to global scales that affect everyone, and those challenges are only going to increase in the face of climate change and growing population,” Schoenholtz noted. “With the Virginia Water Center, we have a wide range of possibilities to address these challenges while working to keep the public aware of the numerous resources available to them.”

Written by David Fleming

CONTACT:

Krista Timney
540-231-6157

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Categories
Blog IGC IGCoffeeConvo Interfaces of Global Change IGEP

IGCoffeeConvo with Todd Schenk

[vc_row][vc_column][vc_column_text]Written by Macy Kailing

We kicked off the first IGCoffeeConvo of the spring 2020 semester on February 12th. These IGC events provide a unique opportunity to chat casually with and get to know GCC faculty. GCC Faulty Todd Schenk met with IGC Fellows Ariel Heminger, Caleb O’Brien, Kerry Gendreau, and Macy Kailing. Collectively, the group represented four different departments which showcased a fundamental value of the Global Change Center and IGC program – interdisciplinarity!

The expertise among the group ranged from evolutionary biology to disease and invasion ecology to human dimensions of climate change. A highlight of our discussion was realizing that everyone is passionate about similar global issues but are taking different pathways and approaches to address them. Todd told us about his approach to address climate change through environmental policy and planning, using his role on the sustainability panel at Virginia Tech as one example.

We then had an enlightening conversation about the panel’s mission to reduce the carbon footprint of the university, our excitement about implementing the strategies as a community, and the ways people, including students, could get involved.

Overall, this IGCoffeeConvos reminded us that interdisciplinary teams are necessary to accomplish big goals but may require us to start by finding common ground.

If you are a GCC Faculty member and interested in participating in an upcoming IGCoffeeConvo, please contact Nicole Ward at nkward@vt.edu. Fellows should keep an eye on their email inboxes for opportunities to join in on future IGCoffeeConvo meetings![/vc_column_text][/vc_column][/vc_row]

Categories
Biodiversity Blog Global Change Interfaces of Global Change IGEP Research Student Spotlight

Korin Jones wins 1st place for poster at Biological Sciences Research Day

[vc_row][vc_column][vc_column_text]February 10, 2020

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Congratulations to Korin Jones for his 1st place poster earlier this month at Virginia Tech’s Biological Sciences Reseach Day. The topic of his poster was an experiment conducted to determine the initial impact of the fungal pathogen, Batrachochytrium dendrobatidis (Bd), on the skin microbiome of spring peepers (Pseudacris crucifer). Frogs were collected, exposed to Bd and then kept in the lab. His group found that the skin microbiome changed significantly with time spent in the lab, but not due to initial exposure to Bd.  They noticed that both species richness and the phylogenetic diversity of species present declined over time. Korin noted that “what was most interesting is that identity of the bacteria present within the microbiome homogenized over time, while the relative abundances of those bacteria became more varied. Who was there became very similar, but their proportions differed from frog to frog.”

Korin explained that overall, this experiment supports the idea that the environment is an important factor in microbiome composition. It also suggests that the proportions of microbes capable of persisting on frog skin within a laboratory environment might be determined by interspecific interactions.

Check out his award-winning poster here!

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Categories
Blog Climate Change Conservation Global Change Research Water

Researchers seek to impact New Zealand water quality by understanding forest-water interactions

[vc_row][vc_column][vc_column_text]From VT News | February 7, 2020

Forest systems, a crucial resource for fresh water around the world, are under increasing pressure from global change factors like climate change, population growth, and land management decisions. To meet future demands for clean water, scientists need a clear understanding of the dynamics of water and nutrients in forest systems.

To broaden understanding of those systems, two faculty members in Virginia Tech’s College of Natural Resources and Environment are partnering with the New Zealand government-owned research entity Scion. They are undertaking an ambitious collaborative project that will utilize remote sensing technology, isotopic tracing, and manipulative field studies to develop a comprehensive model of water and nutrient flow through forested watersheds and streams.

“One of the big questions facing New Zealand is how climate change drivers and land use changes are going to affect ecosystem services,” explained Associate Professor Brian Strahm, of the Department of Forest Resources and Environmental Conservation. “There is a lot of uncertainty about what the future will look like. The broad purpose of this grant is to try to reduce some of that uncertainty and give the people of New Zealand confidence in their land use choices going forward.”

The five-year research project, called Forest Flows, will develop forest hydrology models to measure and predict the storage and release of water in forest catchments while simultaneously allowing scientists to collect data on nutrient cycling, with a particular emphasis on the export, utilization, and cycling of nitrogen.

“A major goal is to disentangle the soil and hydrologic processes controlling nutrient cycling and export from forested watersheds,” said Associate Professor Kevin McGuire, also of the Department of Forest Resources and Environmental Conservation and associate director of the Virginia Water Resources Research Center. “You can’t really look at the cycling of nitrogen at the watershed level without understanding how it’s transported and reacts within soil.”

To explore that question, researchers will use isotopic “tracers” in the water and in nitrogen to measure the movement of water and nutrients through a forest system.

“We’ll be using stable isotopes to track the movement of water and nitrogen through these systems,” Strahm said. “It’s a little like putting a flag or a tracker on a molecule of water or an atom of nitrogen and seeing where it goes through the environment.”

This research will build on their recent study published in the journal Water Resources Researchthat modeled hillslope water flow to estimate how natural systems behave in response to land use or climate changes. The research was carried out at the U.S. Forest Service’s Coweeta Hydrological Lab in North Carolina.

“The hillslope study is what got us in the ballgame with Scion,” Strahm said. “Our experimental hillslope is tightly controlled, which allows us to do very specific manipulations of precipitation. We can basically make our own rain or alter nitrogen availability in that system. Scion would like us to build on that kind of work, adjusting those experimental variables so that they are relevant to the future of New Zealand.”

Recognized as a global leader in forest hydrological research in the 1970s and 1980s, New Zealand has experienced a significant land use shift from forestry to cattle and dairy. As a result of that shift, and as climate change threatens more periods of flooding and drought, there is increasing attention on the ways that land management decisions will impact water quality in the future.

“New Zealand wants to understand this challenge at the scale of their nation, so that they can better understand how independent land management decisions will scale up to impact water quality moving ahead,” Strahm said. “They want to be prepared to deal with future climate change drivers and make sure that their land use decisions are compatible with their social and cultural values.”

While the project is focused on the unique challenges of New Zealand forest watersheds, both professors, who are affiliated faculty members of the Global Change Center housed under Virginia Tech’s Fralin Life Sciences Institute, noted that this research has both local and global implications.

“The issues we’re looking at in New Zealand are applicable anywhere,” McGuire said. “Here in Virginia, most of our drinking water originates in forested watersheds. What happens in those forests and how water is used has huge implications for water quality and availability.”

The project’s total grant amount of approximately $9 million (NZ$13,736,775) is funded to Scion by the New Zealand Ministry of Business, Innovation, and Employment. Virginia Tech’s subcontract from Scion will include support for a student researcher to participate in the project.

-Written by David Fleming

 

CONTACT:

Krista Timney
540-231-6157

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Categories
Biodiversity Blog Climate Change Conservation Global Change Habitat Loss Pollution Research Water

Bye-bye mayfly: Can the burrowing mayfly’s decline serve as a warning system for the health of our environment?

[vc_row][vc_column][vc_column_text]From VT News | February 6, 2020

Sally Entrekin Field
Sally Entrekin samples a stream in search of aquatic insects, including mayfly nymphs.

 

Mayflies have long been indicators of the ecological health of the lakes, rivers, and streams. The more mayflies present in water, the better the water quality.

But scientists from Virginia Tech and the University of Notre Dame recently discovered that a particular species — the burrowing mayfly — had a population decrease of nearly 84 percent from 2015 to 2019. The measurements, using radar, took place during the annual insect emergence events at Lake Erie, when the transition of almost 88 billion insects moving from the waterways to the air marks one of world’s largest annual insect emergence events.

Although it was previously impossible to analyze the emergence of the burrowing mayfly, researchers were finally able to do so by using meteorological radar data and new methods in tracking the presence of airborne creatures. By observing the swarms on a year-to-year basis, the data showed a shockingly simple trend: over the same timeframe and time of year, the mayfly swarms are growing smaller.

“This refined radar technology that allows for tracking and quantifying aquatic insect populations at such a large scale is instrumental in understanding land-water connections,” explained Sally Entrekin, an associate professor in the Department of Entomology in the Virginia Tech College of Agriculture and Life Sciences.

The finding speaks to more than just the mayfly’s decline: It highlights the growing problem of insect decline and the cascading effects that has on ecosystems around the world.

“Radar technology — coupled with traditional field sampling — can start to address the scope and magnitude of insect declines from global change in aquatic ecosystems,” said Entrekin.

Entrekin and her colleagues, Phil Stepanian, Charlotte Wainwright, Djordje Mirkovic, Jennifer Tank, and Jeffrey Kelly, recently published their findings in the Proceedings in the National Academy of Sciences.

The emergence is visually spectacular (where the skies are darkened by the shear mass of flying insects), but this event also represents a new availability of food for many creatures throughout the food chain, providing more than 3,000 tons of insects for consumption by birds and other land-based plants and animals.

Adult_mayfly
An adult burrowing mayfly. Image credit (also header image): Whitney Cranshaw, Colorado State University, Bugwood.org

 

Fish, birds, bats, and other animals consume the mayflies as a source of food and nutrients. Some insect-eating birds in these areas have synchronized breeding habits that coincide with mayfly emergence, and they rely on them as a high-quality food source for their young. These bird populations have also taken a downturn, which has been partially attributed to the lack of insects to eat, particularly aquatic insects.

Historically, negative human impacts on mayfly habitat has led to reductions and disappearances of the mayfly swarms. While conservation and habitat rehabilitation have helped to clean up the waterways and bring back the mayflies, in the Mississippi, Ohio, and Illinois rivers, as well as Lake Erie, efforts to bring back the mayfly swarms took nearly 20 years to reach their previous levels. As the research shows, it appears the swarms are once again declining.

Multiple stressors in these waterways attributed to human activity could be a reason for the reduction in mayfly populations. A warming climate puts more stress on certain aquatic environments, leading to decreased oxygen levels, which can result in fewer mayflies coming out of the water. Runoff from rivers into the warmer surface waters of Lake Erie, for instance, can cause algae blooms, which release toxins that these mayflies are especially susceptible to.

Another type of runoff from agricultural land carries commonly applied pesticides, particularly neonicotinoids, which can kill mayflies as immatures in the water. Even when these pesticides are present in nondeadly levels, they can negatively affect mayfly young by stunting their ability to reach adult stage. Many of these factors likely contribute to the decreasing mayfly populations, and policy and conservation efforts will be needed in order to change this trend.

Global insect population decline is an emerging topic that has sparked public awareness, however there are logistical challenges to analyzing these trends. Monitoring the life-cycle of the burrowing mayfly and other aquatic insects offers an early warning system for changes in our ecosystems.

This monitoring system is also applicable in other parts of the world where large aquatic emergence events occur, and it can be useful in pinpointing regions that would benefit from waterway conservation efforts or ecological rehabilitation efforts. With the impact the climate crisis is having on ecosystems, tracking the emergence of certain aquatic insects could serve to motivate and inform the public as to the effect humans are having on their local waterways.

 

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Sally Entrekin and her lab on a collecting trip

CONTACT:

James Mason
540-231-6826

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Categories
Biodiversity Blog Conservation Food & Agriculture Global Change Research Sustainable Agriculture

VT testing bee-friendly forage for cattle

[vc_row][vc_column][vc_column_text]From VT News | February 5, 2020

The “fescue belt” stretches 1,000 miles across the southeastern United States, from Virginia and the Carolinas in the east to Kansas and Oklahoma in the west. It’s named for its predominant grass, tall fescue, which feeds millions of beef cattle over of thousands of farms and ranches.

Tall fescue was planted widely in the southeast in the mid-20th century because it’s a hardy grass, resistant to drought and cold, which makes it perfect to feed cattle during the winter and spring. But it harbors a fungus that can cause health problems in cattle, especially during the hot summer. And it’s an invasive species, native to Europe, that can crowd out wildflowers and other native plants, which could be contributing to the decline in the population of bees and other pollinating insects.

A new study led by Megan O’Rourke, an associate professor in the School of Plant and Environmental Sciences in the College of Agriculture and Life Sciences at Virginia Tech, will address both of these problems. The research team will plant native prairie grasses and wildflowers in pastures at research stations in Virginia and Tennessee, and on six on-farm sites in Northern Virginia, including on Thomas Jefferson Foundation farmland.

“We’re trying to transform the landscape to support both cattle and pollinators by planting more native wildflowers on farmland,” said O’Rourke, an affiliate of the Global Change Center.

The $1.8 million project is funded half by a federal grant and half by contributions of time, land, cattle and money by Virginia Tech, the University of Tennessee, farmers working with the researchers, and a nonprofit called Virginia Working Landscapes. The team will test 20 different wildflowers native to Virginia and Tennessee and will measure which ones attract the most bees and, when planted alongside native grasses, produce the healthiest cattle. The grant was awarded in December, and the work is getting underway in early 2020.

In December, the National Resources Conservation Service of the U.S. Department of Agriculture awarded $12.5 million to 19 different research projects studying various aspects of conservation on agricultural lands; the bees-and-beef study is one of four studies that will be conducted partly or wholly in Virginia, under grants totaling $2.3 million. The bees-and-beef grant is part of a broad effort by the federal government to study and combat the ongoing decline in bee populations.

O’Rourke is one of five Virginia Tech faculty members working on the study. Another is Ben Tracy, a Virginia Tech professor of grassland ecology and Virginia Cooperative Extension specialist who has been studying native prairie grasses and the effects of tall fescue on cattle for the past 15 years or so.

“The main health problem that fescue causes for cattle, fescue toxicosis, is not fatal, but it probably costs the cattle industry millions of dollars a year,” Tracy said. Affected cattle have trouble regulating their body temperatures in hot weather and they don’t eat as much and gain as much weight as healthy cattle. “Hopefully, adding native grasses and wildflowers to pastures will reduce fescue toxicosis.”

If this study succeeds, adding native wildflowers to pastures in the fescue belt will become a new conservation practice that USDA’s National Resource Conservation Service will cost share.

“If we can find a way, we can improve resources for pollinators and also improve livestock performance,” Tracy said. “It would be a win-win for the environment and for beef cattle producers.”

—Written by Tony Biasotti

CONTACT:

Zeke Barlow
540-231-5417

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Categories
Accolades Blog IGC

GCC Boasts Strong Attendance and Student Awards at SICB

[vc_row][vc_column][vc_column_text]Each year, many Virginia Tech scientists attend the annual conference of the Society for Integrative and Comparative Biology (SICB), one of the worlds leading professional biological societies.  More than a dozen faculty affiliates and graduate fellows of the Global Change Center and IGC IGEP, respectively, were in attendance, as well as several IGC alumni.  Current faculty and students presented a total of 20 poster and platform presentations at the conference this year in Austin, Texas.  Once again our IGC fellows did a wonderful job and represented our programs well.  IGC fellows Jessica Hernandez (BIOL) and Sydney Hope (FWC) both received Broadening Participation Awards from the society, and Jessica also received a highly competitive SICB grant in aid of research!  Brenen Wynd (GEOS) was awarded the Division of Vertebrate Morphology Karel F. Liem award for best student poster!  Congratulations to Jessica, Sydney, and Brenen on their success, and to all the GCC/IGC meeting participants that continue to excel in this and other national research forums.[/vc_column_text][/vc_column][/vc_row]

Categories
Accolades Interfaces of Global Change IGEP News Student Spotlight

4 new fellows join the IGC IGEP in winter 2020

Text welcome on a wooden board in a rainforest jungle of tropical Bali island, Indonesia. Welcome wooden sign inscription in the asian tropics, close up

[vc_row][vc_column][vc_column_text css=”.vc_custom_1580758264739{margin-top: 10px !important;}”]The Interfaces of Global Change Interdisciplinary Graduate Education Program will begin its eighth year with a cohort of four new Ph.D. students! The new IGC Fellows hail from three departments across campus, including: Geosciences, Forest Resources and Environmental Conservation, and Fisheries and Wildlife Conservation.

 

Meet our newest fellows:

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Junyao Kang

Working with Dr. Shuhai Xiao (Geosciences)

Research interests: Geochemistry and geobiology; Neoproterozoic paleoenvironment reconstruction, co-evolution of life and environment through deep time[/vc_column_text][/vc_column_inner][/vc_row_inner][vc_separator][vc_row_inner][vc_column_inner width=”1/3″][vc_single_image image=”47772″ img_size=”250×250″ alignment=”center”][/vc_column_inner][vc_column_inner width=”2/3″][vc_column_text]

Joshua Mouser

Working with Dr. Paul Angermeier (Fish and Wildlife Conservation)

Research interests: Stream ecology, landscape ecology, land-use change[/vc_column_text][/vc_column_inner][/vc_row_inner][vc_separator][vc_row_inner][vc_column_inner width=”1/3″][vc_single_image image=”47621″ img_size=”250×250″ alignment=”center”][/vc_column_inner][vc_column_inner width=”2/3″][vc_column_text]

Caleb O’Brien

Working with Dr. Marc Stern (Forest Resources and Environmental Conservation)

Research interests: Human dimensions of natural resources, climate change adaptation, science communication[/vc_column_text][/vc_column_inner][/vc_row_inner][vc_separator][/vc_column][/vc_row][vc_row][vc_column width=”1/3″][vc_single_image image=”47777″ img_size=”250×250″ alignment=”center”][/vc_column][vc_column width=”2/3″][vc_column_text]

Luciana Pereira

Working with Dr. Leandro Castello (Fish and Wildlife Conservation)

Research interests: Migration and population genetics of Pseudoplatystoma fasciatum in the Amazon[/vc_column_text][/vc_column][/vc_row][vc_row][vc_column][vc_separator style=”shadow”][/vc_column][/vc_row]