Hike with Urban Wildlife Ecologists

Sam and Yasmine own by the water at low tide

It was an unusually sunny spring day in Seattle when I arrived at Discovery Park to hike with Sam and Yasmine—two energetic, young urban wildlife ecologists from the University of Washington. I was a bit early for our meeting, so I decided to wander down one of the many trails and do a little exploring.

Native trees and shrubs lined the trail, wildflowers were in bloom, and bird song filled the air. I watched a white-crowned sparrow hop from shrub to shrub and branch to branch, as light filtered through the canopy. It was a peaceful and pleasant ramble. You could almost get lost in nature’s spectacle if it were not for the other visitors that shuffled by at regular intervals. 

That is the thing with urban parks, they are sort of a mixed bag—both a respite for wildlife and a central hub of activity for the populous. Often, they are the only way many people can access wild space. But just how wild are these spaces? And what becomes of the wildlife that call the “urban jungle” home?

Shortly after returning to our meeting spot in front of the visitor center, Sam joined me with her dog Sequoia, in tow. Yasmine arrived only a few minutes later. Quick introductions and an exchange of M&Ms between friends, and we were off on the trail.

The Hike

  • Trailhead: Discovery Park Visitor Center
  • Distance: approximately 3 miles (12 miles of trails)
  • Elevation Gain: unknown (varies)
  • Details: There is ample parking at the trailhead and several routes to choose from. When the visitor center is open it has restrooms, informational displays, and maps.

Youthful Indiscretions

Both Sam and Yasmine grew up in urban areas—Sam outside of San Francisco and Yasmine just outside of DC.  During their youth they also both spent a lot of time outdoors.

“I was always obsessed with animals and being outside,” said Sam about her childhood. “I was that nerdy kid in the classroom reading animal encyclopedias….” she went on.

“I got lyme disease a couple of times because I was always running out into the woods,” Yasmine shared.

Urban Wildlife Ecologist

Both were also pulled toward urban wildlife.

Sam recalled the area she grew up— “I was amazed by how much wildlife is there.” This realization coupled with opportunities to get involved in research at the undergraduate level helped direct her academic future.

Now Sam is in her first year as a Ph.D. student at the University of Washington studying Seattle’s coyote population.

“I look for coyote scat,” she said bluntly. “There are supposedly coyotes all over Seattle, but I have yet to see one. I have found their poop in some places through.”

Yasmine, on the other hand, started her academic career pursuing vet school. Like Sam, however, she got involved in undergraduate research—studying invasive fish in the Chesapeake watershed.  She worked on a variety of projects but ultimately kept coming back to urban wildlife.

Yasmine is now in the early stages of her Ph.D. program. “I am still figuring it out,” she explained. “I am going to be collecting carcasses to look at urban wildlife health,” she went on—to look for parasites, viruses, and assess their overall condition. She plans to source coyote carcasses from the USDA and Washington Department of Fish and Wildlife’s Control Operations.  As she put it—she will be “recycling” carcasses—giving them a new purpose.

Human Discovery

I followed Sam and Yasmine along a well-established trail, passing by both native plantings, grassy knolls, and large swaths of invasive species. While we walked, Yasmine shared a bit about Discovery Park’s history.

“It was used by a lot of tribes for thousands of years,” she began.

“And then it became a military base, and all of this became raised for horse pastures and hundreds of buildings at its prime, like 80 years ago,” Yasmine gestured around. Finally, in the 1970s it was repurposed as a park and restoration work became.

It is an “earlier succession park,” according to Yasmine, as it was planted only in the last 50 years and it is still undergoing active restoration. 

Sam piped in with the size of the park—”534 acres.” That is a nice chunk of real estate for urban wildlife. 

Lots of invasive species and native planting at Discovery Park

Scoop the Poop

As we continued past a few buildings and through pockets of forest along the trail, I asked Sam to elaborate on the scat project.

“I have only collected a couple of scat,” said Sam. “Our main push for scat collection will be this summer.” She explained how there was some concern about the quality of scat collected in the winter with all the rainfall in Seattle. But she was able to get some good quality data from the few she collected.

Now you might be thinking, why scat? Why study excrement? Choosing to study something like scat, begs the question— “Why?” I asked Sam 

Sam explained how her work is in collaboration with Woodland Park Zoo and Robert Long who is a proponent for non-invasive carnivore survey techniques. You don’t have to handle an animal to learn all about it. The idea of non-invasive techniques is that you can learn a lot without interacting directly with the animals you are studying, thus reducing potential unintended stress or harm. “I think it is really cool,” Sam exclaimed.

Plus, there is a lot to learn! Sam swabs the outside of the scat to “identify the coyote that pooped the poop,” as she put it most eloquently. Then the inside of the scat sample is swabbed and analyzed to determine what it consumed. “I will be doing everything genetically,” said Sam. However, according to Sam, you can determine a lot about the animals’ diet by manually going through it and looking at the hairs embedded in the undigested remains.

Why care?

Our eyes peeled to the ground, Sam, Yasmine, and I continued to scout the area, dreams of big piles of poo dancing through our heads. As we walked, I asked Sam and Yasmine to tell me more about urban wildlife and why someone should care about keeping tabs on the urban jungle.

Yasmine spoke up first “It is beneficial for us and to them to learn how to coexist,” she stated because “they are here anyway.”

If we understand urban wildlife better, we can learn how to respond to their presence and develop management techniques that make sense.

She went onto discuss, as she put it, “the disease angle.” “A lot of these animals are vectors for disease,” she explained. “How can we ensure they have enough space, so they don’t end up in human spaces?” Therefore, it is important to understand what makes urban wildlife tick; “so, they don’t pass a disease on to our pets or kids or something.”

Clever Coyotes

Even if people wanted to eliminate coyotes from urban environments, which I believe Sam and Yasmine would argue is a mistake, it would be very difficult to accomplish.

“They are very adaptable,” shared Sam. “When you remove coyotes it creates a vacuum that coyotes will go fill… They have density-dependent fecundity.” Meaning, if you reduce the populations, coyotes simply produce more offspring.

Yasmine agreed in Sam’s assessment. “They really thrive in so many different cities in ways other animals don’t,” said Yasmine. Sharing how during the first coyote project she worked on she found coyote using railroads and living in trainyards. It “blew my mind,” said Yasmine.

Cool Coyotes

After walking past several viewpoints along the trail, I asked Sam and Yasmine if they knew of any other “cool coyote facts?”

“They are the top predator in Seattle,” responded Yasmine. They suppress many other meso-carnivore species, like skunks, raccoons, opossum, and foxes.  This can, in turn, boost overall biodiversity and ecosystem functioning by allowing prey of smaller predatory species to survive.

And what about people? The jury is still out. Yasmine explained that you will find papers saying opposite things when it comes to how coyotes respond to people. “It seems to vary by city,” said Yasmine. In some places, it seems they avoid people spatially, while others say they don’t mind being in the same space but will avoid people temporally. Either way, they don’t like us very much.

Of course, there is still much to learn about coyote and how they interact within their community. They are part of a “messy web,” said Yasmine.

A nice viewpoint next to an area being restored

Coyote Threats

So, with everything seemingly going well for coyote in urban environments, I asked Sam and Yasmine if there are any threats that coyote face.  Yasmine had mentioned parasites and diseases as part of her research project. Is there something out there wiping out coyote populations?

The short answer seems to be no. But Yasmine did share a few threats that coyotes face.

“The first thing that comes to mind is mange,” responded Yasmine. Caused by parasitic mites, mange is a problem for coyotes that live in colder climates. Infected animals will scratch themselves too much, so that they lose their fur, leaving them susceptible to the elements.   

Environmental toxins are another challenge. Led and arsenic are also potentially problematic to coyotes. As well as anticoagulant rodenticides. These chemicals have the potential to bioaccumulate or build-up, in the tissue of animals. They can also be biomagnified (increase) through the food chain, such that predators, like coyotes, face the brunt of the toxic effects as they consume prey riddled with toxins.

Food for Thought

At this point, we followed the road down to the beach. We passed by stands of stinging nettle and Yasmine shared her favorite ways to harvest and prepare stinging nettle by blanching and sautéing it. All this talk of food, of course, got me interested in learning more about Sam’s project.

“What do coyote eat?” I asked.

Though DNA analysis of the collected scat has not started, Sam told me that there is a lot that can be discovered by simply looking at the scat. As far as Sam has seen from samples found at one site, coyotes are eating rabbits and snakes, but also candy bars. Just like bone and fur are preserved in the scat of coyotes, so are wrappers and other pieces of plastic.

Additionally, a good deal of research has already been done on the coyote diet. And findings are incredibly variable. Sam explained that what coyote eat “depends on where you are and the time of year.” At one location in the North East, for example, the coyote diet was “80% berries at one point,” said Sam. Cities teeming with black rats, roof rats, and eastern cottontail are prevalent sources of food—all invasive species.

Finally, Sam said that household cats do not appear to be a regular part of coyote diets, despite what some would believe. Though one site in Los Angeles may be an exception.

Scoop the Poop Reprise

I was not “dung” with this line of questioning, however, and I asked Sam if she knew from her research how many coyotes inhabit the Seattle area?

Though she didn’t know offhand, Sam shared how the scat she was gathering—using a technique called “mark and recapture”—could also be used to determine population size.

The outer coating on each sample of scat contains epithelial gut cells that can be genetically identified down to an individual. As Sam put it, we know “exactly which individual pooped the poop.” With enough sampling, some individuals are likely to be “recaptured,” or identified a second time. It is the recapture data along with the initial captures that allow scientists to estimate population size.

This begs the question—how hard is it to collect samples? According to Sam, it is as easy as picking up your own pet’s waste—only she uses two Ziplock bags while collecting.

Down by the Sea

As we marveled at the amazing advancements in DNA analysis, Sam, Yasmine, and I made our way down to the beach. Sam’s dog Sequoia led the way down to the water. The tide was unusually low, so we decided to walk the shoreline for a while, dodging sea anemone and other critters that lie underfoot.

We talked about grad school, tutoring, and hiking in the Pacific Northwest, among other topics, including scat, as we walked the beach.

“One of the coolest coyote scats I have ever seen was on the Strait of Juan de Fuca on the Olympic peninsula,” shared Yasmine at one point. “There was one on the rocks in the tidepool. There were crabs and mussel shells in the scat!”

Unfortunately, our beach adventure did not turn up any such gems.

Low tide at Discovery Park

Social Structure

It did, however, turn up some juicy gossip on coyote social structure. Coyotes, according to Sam, live in family groups, but often act independently. “It is thought to be one of the reasons for their success,” explained Sam. The flexible groupings allow them to hunt in groups when it is advantageous, or head out on solo or couple adventures.

In addition, coyotes maintain territories that vary in size depending on how much food is available. Territories are defended by members of the family groups or packs.

Coyote Careers

After soaking in some sun, Sam, Yasmine, and I headed back uphill to continue our search for scat. We entered a large field/lawn area that looked promising. But sadly, our efforts were not rewarded. Still, no sign of coyote, though we did hear sea lions barking in the distance.

Feeling a bit defeated, but still hopeful, we continued uphill, our senses on high alert. I wondered what Sam and Yasmine felt about their chosen line of research. I asked what advice they might give to the next generation of wildlife ecologists.

Sam was first to respond. She explained how working in wildlife ecology is “not like what you see in National Geographic.” A lot of opportunities to study wildlife ecology are non-invasive and local. Many international jobs can be exploitive and/or very competitive. She recommended: “Know what you are interested in ecologically.”

Yasmine added, “You need to be flexible…build your own way.”

“More and more the field is becoming collaborative,” added Sam. “Getting involved in projects is a good start.”

Yasmin and Sam pose for the camera with Sam’s dog Sequoia

Citizen Science

Getting involved does not have to start with graduate school!  Citizen science projects in urban wildlife and other sciences are becoming more popular.  Since our hike, Sam and her collaborators have launched the Seattle Coyote Study website where people can sign up to help collect coyote scat for the project.  Volunteering is easy, fun, and flexible, as participants choose when they go out and how often. Check it out at seattlecoyotestudy.wix.com/seattlecoyotestudy.  

Eyes on the Prize

Around this point, we saw a used dog poop bag plopped on the side of the path. Not the sign of life we were looking for, even if it was technically scat.

Our hunt turning up nothing but domestic dog poo, I asked the duo what other signs of wildlife might be fun to look for in an urban setting. There has got to be something better than this!

“Deer sign is one the easiest things to look for,” said Yasmine. In some places, you can see a clear browse line. In other places, it is harder to detect but are still able to find signs of browse on individual plants.

Sam and Yasmine both agreed that tracks are also a lot of fun to look for, especially in the mud or snow. “When mud has that glaze,” said Sam, “it preserved prints perfectly!”

“And then if you are into birds, listening and looking for birds,” said Yasmine is a great way to connect with urban wildlife. She admitted she has never been that “into birds,” but has grown a greater appreciation for the birds in her neighborhood recently.

“It is amazing the diversity of birds in an urban area,” added Sam. “I was walking around my neighborhood and there was a pileated woodpecker on a telephone pole!” A rare site indeed!

Leaving a Mark

Eventually, Sam, Yasmine, and I made it back to the parking lot. Having completed our loop, we had not turned up a single sample of scat for Sam’s research. Defeated but not down, we said our energetic goodbyes and parted ways.

Upon reflection, though I did not find what I was looking for per se, I found something far greater. Spending time with Sam and Yasmine—their young enthusiasm for research and science—was hopeful and invigorating. There is a lot of good, thoughtful science happening, right now! It might go undetected much of the time. It might even be ignored. But like coyotes in Seattle, the signs are there. You just got to keep looking.

Samantha (Sam) Kreling and Yasmine Hentanti are both Ph.D. students studying urban wildlife at the University of Washington. Sam has a B.S. in Molecular Environmental Biology from the University of California Berkeley and Yasmine has a B.S. in Wildlife Ecology & Management from the University of Maryland.


Hike with a Predator-Prey Wildlife Ecologist

View of the forest from the trailhead.

Wildlife populations are dynamic—ever-changing, depending on circumstances. They increase when resources are abundant and decrease when resources dwindle. Populations are limited by numerous factors that affect their ability to survive and reproduce. Factors, like predation or disease, that limit high-density populations more readily, as well as more sweeping large-scale factors, like habitat change or loss.

However, limiting factors are also wide-ranging and often entangled with each other—a giant web of factors where if you pull on one thread, others are sure to respond. This is where Taylor Ganz, Ph.D. candidate from the University for Washington, comes in. Taylor has been working for the last four years to understand how deer and elk populations in Washington have been changing as they respond to factors in their environment.

I met up with Taylor on a mostly sunny day for a hike in the Capitol State Forest near Olympia, WA to talk about her research and to learn more about population dynamics.

The Hike

  • Trailhead: Mima Falls Trailhead, Olympia, Wa
  • Distance: 6.5 miles
  • Elevation Gain: 700+ feet
  • Details: There is ample parking at the trailhead and a pit toilet. Trailhead is very accessible, but Discover Pass is required for parking. There are many options for trail routes through the area. The Mima falls Loop is part of Olympia’s Capitol State Forest.

For the Love of Science and the Outdoors.

As we started down the tree lined trail, Taylor told me a bit more about her background and research.

“I have always loved science and being outside,” said Taylor. So naturally, in college, she studied physics and mechanical engineering. “I thought I would work in alternative energy design and development,” she explained. 

The problem was instead of doing engineering internships, like her classmates, she found herself drawn toward jobs in outdoor recreation and education. “I was working as a wilderness ranger… a flyfishing guide… a rock-climbing instructor…” For 5 years she worked for NOLS (National Outdoor Leadership School) before deciding “to get back to science.”

She started out at the Yale School of Forestry where she studied air pollution in sensitive alpine environments (tinyurl.com/scienceofsnowmelt), before making her way to the University of Washington to work in the Laura Prugh Lab on wildlife ecology.

Taylor Ganz stopping for a photo during our hike.

Predator-Prey

Now Taylor is deeply entrenched in her research at UW. Taylor’s research is part of a big collaborative project between the Washington Department of Fish and Wildlife and The University of Washington called the Washington Predator-Prey Project (www.predatorpreyproject.weebly.com).

Wolves returned to Washington state in 2008 with just one breeding pair documented. Now, the Washington Department of Fish and Wildlife reports there are at least 145 individual wolves in Washington. The Washington Predator-Prey project was mandated by the state legislature in 2016 with the goal to understand the impacts of the recolonization of the wolves.

Taylor’s part in the project is focused on how deer and elk populations are impacted by predators, like the recolonizing wolves, both directly, by killing them, and indirectly, by influencing their behaviors or other predators.

 “Predators can impact individual prey by killing and eating them,” said Taylor, “…this may or may not impact prey at the population level.” Prey might avoid certain areas or move about differently in the presence of a predators. For example, the presence of a predator may cause deer to spend more time hiding and less time feeding. Of course, this can also have an indirect impact on the deer population by limiting food availability or stressing the animals, which could also decrease deer survival.

Taylor works two 5,000 square-kilometers study sites—one in the more populated northeast part of the state and a second in the less populated north-central part (situated on the east slope of the North Cascades). The northeast site has four wolf packs, while the northcentral site only had only two until recently.

Large-Scale Change

Young trees stood at attention on both sides of the wi­de gravel trail as we walked along. You could still see the stumps from the last harvest and grass-lined the trail.

“I am also interest in large-scale changes in the environment, like fires and timber harvest,” Taylor told me. This is why Taylor suggested visiting an active timber harvest site for our hike.  Though her research sites are in the northeast and northcentral parts of Washington state, much of the sites contain active timber harvest as well.

Areas that have been harvested for timber have the potential to create good habitat and forage for deer and elk populations, at least for a few years. Harvesting timber opens the canopy so that sunlight can reach the ground, which can promote the growth of shrubs and herbs that deer and elk feed on. As the trees grow up, they can provide a place to rest and hide from predators.

The trail as we were getting started on our hike.

Keeping Track of Deer

Eventually, we dropped down into a section of forest with taller, but still not mature trees.  Sword fern and Salal became the dominant understory and I was excited to see a few trilliums still in bloom. Enjoying the shaded trail, I asked Taylor to describe just how she goes about finding deer and tracking them.

“We need to track adult females and younger animals,” explained Taylor.  Males are largely ignored for her study as they are abundant enough to get the females pregnant. Instead, the focus is on capturing and collaring adult female deer and elk and their fawns and calves.

“Elk are primarily captured by aerial darting, and mule deer are mostly collared by aerial rocket netting,” said Taylor. But for white-tailed deer, she often uses ground darting and special traps, called clover traps, to lure deer and capture them. Taylor described them as large boxes with a tripwire that closes the door. Bait, like corn, hay, or something called “sweet feed” is used to attract the deer inside. And once captured, the transmitter sends a text to Taylor, so she knows to check the trap.

When Taylor arrives at the trap, she needs to add a GPS tracker to the deer—this is a priority. To do so the clover trap is flattened and laid down on its side, essentially creating a “deer sandwich.” Taylor is then able to apply an anesthetic before tagging the deer.

The other tool Taylor uses to capture adult deer sounds a bit like a fourth of July firework or something military—”suspended rocket net.” This contraption uses a net with weighted corners that launches during capture overhead an unsuspecting deer.  Bait is used to lure the deer into position below the net before it is launched. “It’s kind of like a bug in a spider web,” said Taylor.

One of several Pacific Trillium seen on the hike.

Tough Captures

Later, Taylor told me about the challenges of trying to capture new animals. First, it takes a lot of detective work, looking for “pellet piles” and tracks.  Then the trap must be “appealing for the deer.” Taylor told me about a time her boyfriend and dad came with her into the field. She had them both dig a shallow ramp in the snow up to one of her traps to make it easier for a deer to enter.

“No, we need a really gentle entry,” she told them as they worked. 

From then on, the trap was referred to as “The Ruby Creek Country Club,” based on its luxury accommodations and location.

Technology Revolution

No matter the method, once captured, the adult deer is collared with a GPS tracker, measurements are taken, and blood and hair samples collected. Vital signs are monitored during the process to ensure no harm. If the vitals deteriorate, the deer will be released. Blood is especially important for tracking pregnancy.

In addition, they will often ultrasound the deer in the field as well. And if pregnant, implant what is called a VIT (Vaginal Implant Transmitter). The VIT talks to the deer’s collar, texting Taylor when the VIT has been expelled during birth. From there, Taylor and her team can often track down the new fawn and add an expandable collar that uses radio telemetry to “speak” to the mom’s collar.

Currently, Taylor has about 200 ungulate “on air.” Each spring they capturing between 30-40 newborn fawns and elk calves.

“Much of the technology is really recent,” said Taylor. In the past, radio telemetry was really the only option for tracking animals, which requires more time in the field with receivers and triangulating positions. Now, GPS collars allow you to know where the animal is every 4 hours, and you can see their positions from the comfort of your own home if you want.

Elk Tracking

Of course, every animal is tracked differently. For Elk, for example, a mix of strategies is used, like aerial telemetry, in addition to GPS collar. It is also helpful to consider the behaviors of the animals for tracking. For example, often elk will move large distances in one day. When this movement stops suddenly in late May, this could mean a calf was born.

On the Look Out

At this point, we had made a few turns on our loop and were getting close to Mima Falls, our designated hiking destination. The forest was still fairly shaded with younger trees which made for a cool walk.

As we hiked, Taylor and I kept a lookout for signs of wildlife, but so far had not seen much if anything. Of course, that does not necessarily mean there is nothing around. I often think about the wildlife that I do not see while I am out hiking. Could there be eyes watching us now as we walk through the forest?

Deer are also on the lookout for other wildlife, especially predators. Of course, they are much more capable of detecting the presence of others than us poor-sensing humans. Interestingly, what a deer detects seems to matter a lot—changing their behaviors in possibly meaningful ways.

A shady section of trail.

Wolves, Cougar, and Bear, Oh My!

Taylor mentioned a study out of Yellowstone that showed that when cougars were around, elk tended to move out into the open, but when wolves were around, they tended to move into more densely wooded areas. This makes a lot of sense, as cougar are ambush predators—stalking their prey and going in for a quick kill. Better to be out in the open where a sneak attack is more difficult. While wolves are coursing predators—chasing their prey to exhaustion. Better to be well hidden where it is difficult to chase.

“We have collared wolves and cougar, as well,” Taylor told me, as part of the Washington Predator-Prey Project.  Using a movement modeling technique called a “step selection function,” Taylor is also looking at how deer and elk are responding to predators. 

“Basically, the model considers a handful of possible routes a deer or elk might take, based on their location at a given time, and compares it to the track they actually take. Then, by looking out how their choices change in the presence of cougar, for example, we can see if they are altering their habitat use.”

She is also looking at if humans are influencing these interactions as well. “One of the thoughts is that they might move more toward people because predators tend to be more human adverse,” Taylor shared. 

Playing Nicely

“Do they play nice?” I asked Taylor, referring to the cougars and wolves.

Though not her primary focus, Taylor told me that one of her collaborators is working to answer this very question. One thought is that cougar might move into higher elevation areas if wolves are nearby, but there are more than wolves and cougar to consider.

“Bobcats, bears, and coyotes too. All of these can eat deer and elk at some point during an ungulate’s life,” explained Taylor.

Previous research indicates that some mesopredators, like bobcat and coyotes, will change their temporal activity when apex predators, like wolves, are around. And that coyotes and bobcats may find human interaction less threatening when apex predators are present.

Fun in the Field

We continued past a couple of gorgeous incense cedar trees growing along the trail, admiring them as we went. The forest had not changed a lot, but the trail leveled off during the last stretch to the waterfall.

I asked Taylor if there were other ways, other than trapping, that data was being gathered on wildlife populations for the Washington Predator-Prey Project.

“There is another PhD candidate, Sarah Bassing, that has over 100 camera traps set up,” Taylor exclaimed. “She is looking at interactions on a large scale.”

Taylor also told me about another way they are using camera traps to track scavenger behavior at carcasses.

Scat is also collected for most of the carnivores in the research project. “There is a couple of key pieces of information it can tell us,” explained Taylor: 1) what did the animal eat, and 2) who left the scat?  You can even use how much scatt is collected to estimate how many individuals of a species are out there.

Overall, “There is going to be three PhD dissertations, one master’s thesis, and additional papers” published around the Predator-Prey project. And hopefully a synthesis paper will be written, Taylor suggested, but probably not for many years.

Waterfalling in Love with Plants

We eventually made it to the Mima Falls. It was not particularly spectacular, but we still took a short break to take in the views and snap a couple of photos, before heading back onto the trail.

View of Mima falls

“Well, this is the type of forest I am used to…but with a little less fern and more shrub” said Taylor as we walked along through the canopy-filtered light. The forest was still mostly well-spaced young Douglas-fir.

“We run habitat surveys in the summer,” said Taylor. “We have documented three-hundred plants in the understory.”

Taylor admitted that after a long fawn and calf capture season in the winter, focusing on plants is a nice change of pace. “It can feel so relaxing,” she remarked, and “I have been able to learn a lot of plants.”

Of course, good sources of vegetation are important to deer and elk success. I asked Taylor if deer have any preference toward certain plants. Taylor mentioned a study conducted by Lisa Shipley, from Washington State University, where captive deer are observed, and what they eat is recorded “bite for bite.”Mule deer tend to prefer deciduous shrubs, such as willows and serviceberry, while white-tailed deer favor forbs such as heartleaf arnica, bunchberry, and even strawberries.

Understory shrubs along the trail.

Migration

As we looped up the trail, we entered a more mature forest with several older, larger trees. While we walked, our conversation migrated back toward a theme, we touched on a bit earlier—migration. More specifically, what are the patterns of migration, and do landscape-level changes impact migratory routes.

In her Okanogan county site, where her focus is on mule deer, Taylor is particularly excited to better understand seasonal migration patterns. “Most animals move up in spring and move back down in winter,” said Taylor, sometimes moving up to 40 miles over the season. This movement is thought to occur due to changes in available browse as spring moves to higher elevations and latitudes—what is known as the “green wave hypothesis.”

One of the larger trees we walked past on the trail.

A Slow Burn

However, with landscape-level changes, such as fire, Taylor suspects movement patterns will change. “I have two ideas about influences of fire,” she said, “both relating to how they reduce canopy cover. One way is it could make really good forage and they may be attracted to these areas.”

On the other hand, “the canopy cover can really block snow from accumulating.” With reduced canopy cover post-fire, snow may be deeper and reduces food access. Deep snow also reduces deer mobility when they are trying to move fast to escape a predator. The fact that “deep fluffy snow favors predators over prey is well established,” remarked Taylor. She hopes to parse out these effects.

Down Logs

Similarly, down logs can also be thought of as both helpful and harmful to deer. We were noticing a lot of down logs along this section of the trail.  First, logs “can alter the way they are moving,” hindering their ability to escape a predator. But second, logs recycle nutrients to the forest and provide habitat for other forest life.

Lots of down logs in the mature forest.

Why should we care

By now we were more than an hour into our adventure, and I realized I had not asked one of the important questions—why should we care? And, of course, Taylor was quick with a response.  She really knows her stuff!

“There are a couple of reasons,” she began. “Their role in the ecological community and also people really like deer and elk.”

“They are really cool because they are a species people can see and relate to and understand in a way a bobcat perhaps is not,” said Taylor. “I can go out in the field and see 50 deer!”

As for ecological benefits, deer and elk are “middlemen” in the food web—affecting both the landscape of vegetation while also supporting predator populations. There is also some evidence that they are important to transporting seeds and moving nutrients around.

Deaths

One of the most basic concepts of wildlife populations is understanding death.  So, it is not surprising that throughout our hike together, Taylor and I discussed deer and elk death at length.

“Are there any threats to deer and elk?” I asked at one point.

“There are a number of different diseases that regulate a population,” Taylor offered. Though not found in Washington State, Chronic Wasting Disease (CWD) is a potential concern for many populations of ungulates, as it spreads through saliva and tends to be more of a problem in dense areas. 

This is, of course, where predators may come in. By potentially keeping deer and elk populations less dense, diseases, like CWD, may become less of a threat. In addition, problems with too many deer, like wildlife conflict, eating crops, and vehicle collision are also lessened. There is some evidence, especially in the Eastern United States, that predator return could save lives and money.

Necropsy

Part of Taylor’s research is looking at causes of death in deer and elk.  To get a handle on this, she has also been doing necropsies—full field dissections—on the bodies of dead deer and elk found in the field. When Taylor told me about her involvement in this, I swear, her eyes lit up. “I really enjoy it,” she remarked.

The main goal of the necropsy is to see how the deer or elk died. If the animal died from predation, there will be lethal bite marks present, if that part of the carcass hasn’t been eaten. If it died from starvation or another stressor, the bone marrow turns from a “candle wax like material into red jelly.”

Another cool side project is to sample lethal bite marks for DNA and use it to identify the individual or species that killed the animal. 

When I asked Taylor if she found any pattern in causes of death from the necropsy, she could not say anything conclusive, as the final stages of data collection were still underway. However, she did note that car collisions were up there, along with predation, and occasional evidence for starvation or disease. How much each of these limits deer and elk populations is still being investigated. “We are seeing some evidence that there is some nutrient limitation,” said Taylor, “but not exclusively.”

Overall, deer and elk are not very threatened. White-tailed deer have, in fact, expanded their range. Mule deer have been on the decline, but they are not considered imperiled, at least not yet. 

Good Habitat

We hiked on, meandering through an interesting section of regenerating forest next to a thin stand of tall trees. I asked Taylor if the area would be suitable for deer and elk and was met with a resounding “yes.”

“This is a good place for cover and lots of good food to get into,” said Taylor. Also, “they love edge habitat.”

However, “in another 15 years it may not be great,” explained Taylor. The trees were planted at a high density, so as they grow taller and without thinning, they will likely shade out the understory, creating a food desert for the deer. 

Toward the end of our hike, we walked through a section of dense forest, like what we might expect for the stand of trees in front of us. The forest floor was dark and there was little vegetation—not a good habitat for deer.

Section of regenerating forest along the trail.

Births

It was during our walk through this dense dark forest, after passing a wet swampy area that white-tailed deer would most assuredly love, that I inquired about the other half of the population puzzle—births.

In biology class, you are taught that there are K-selected species and r-selected species. K-selected species have few offspring, a low growth rate, and stabilize around a carrying capacity. While r-selected species have many offspring, a growth rate, and their population size tends to fluctuate more widely.

Where do deer and elk fit into this picture? Somewhere in between. “They aren’t laying thousands of eggs,” said Taylor, but, like an r-selected species, white-tailed deer are very fecund.  On average a white-tailed deer will give birth to 1.6 fawns a year. Their maturation time is also impressive as white-tailed deer in good condition can breed at 6 months old. Mule deer are similar with a longer maturation time, but similar growth rate. Elk, on the other hand, do not twin and may not have a calf every year—putting them on the more K-selected side of the spectrum.

White-tailed deer also fall more to the r-selected side of the spectrum when it comes to recovery. “They are moving further westward, and their range is expanding,” reminded Taylor. Some people even compare them to rats or rabbits in their ability to reproduce. “I don’t know to the extent they are overshooting the carrying capacity of the landscape, but the potential is there,” said Taylor. 

The Sign

Over two hours into our discussion and we were nearing the trailhead. It was so much fun talking to Taylor and listening to her speak with such focus and passion, I could not believe we were near the end. And we had not seen a single deer, let alone any deer track or scat!

However, just as we were wrapping up, Taylor found something—hair! Was it a sign of wildlife? Not exactly, but it did illustrate a cool feature of deer and elk.

“So, this is probably just domestic animal,” Taylor explained, but “one thing you can do to tell if it is predatory or prey is to fold it.” Predators have several layers of hair to protect against the elements and keep them warm. “These hairs won’t kink very easily,” said Taylor. “Deer hair,” on the other hand, “are really slippery and hollow, so they kink easily.” Deer hair will also fall out easily if a predator grabs them.

And there you have it. Only a few minutes later and we were back at our vehicles saying our goodbyes.

Predator fur discovered on the trail.

Complexity

Predator-prey relationships on the surface seem so simple. One species pitted against another; it can seem like an obvious win-lose situation. But speaking with Taylor, this kind of thinking dissolves—it is much more complicated than that.

Predator-Prey relationships are more like a dance, perhaps a tango, but with more than one partner. What happens to one population affects another, both directly and indirectly, which, in turn, may affect something else altogether. Thus, something as simple as the amount of snow on the ground or the density of trees in a forest has the potential to create a ripple effect over the entire ecosystem. As the old adage goes: we’re all in this together.

Taylor Ganz is a Ph.D. candidate at the University of Washington in Wildlife Science. She has a Masters in Environmental Science from Yale School of Forestry & Environmental Studied,  a B.S. in Mechanical Engineering from the University of Southern California, and a B.A. in Physics from Lewis and Clark College. She also has multiple years of experience as a Senior Field Instructor of National Outdoor Leadership School, and still enjoys teaching for them on occasion.