The reintroduction of 31 wolves to Yellowstone from 1995 to 1996 triggered a scientifically documented ecological cascade effect, even altering the course of rivers.

In the decades leading up to 1995, Yellowstone National Park in the USA faced a severe ecological imbalance. Since the beginning of the 20th century, gray wolves had been hunted and exterminated in the region due to federal predator control policies. The last confirmed wild wolf in Yellowstone was killed in 1926. The absence of predators led to an uncontrolled growth of moose (Cervus canadensis). Without predatory pressure and with milder winters, the herds began to intensively consume floodplain vegetation, especially willows (Salix spp.) and poplars (Populus spp.). The result was visible degradation on the riverbanks, loss of vegetation cover, and erosion of the slopes.

Researchers noticed that species such as beavers and riverine birds were disappearing. The explanation was straightforward: without willows and poplars, beavers lacked wood to build dams and plants to feed on in winter. Fewer beavers meant fewer dams; fewer dams meant less wetland and less aquatic diversity. The collapse was silent, gradual, and systemic.

Around the 1980s, Yellowstone was a park with large mammals, but with an incompletely functioning ecosystem. It lacked the predatory component capable of… reorganize the food chain.

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The reintroduction of the 31 wolves and the beginning of the “cascade effect”

In 1995 and 1996, after years of political, legal, and scientific debate, the US Fish and Wildlife Service reintroduced 31 gray wolves (Canis lupus) Captured in Canada, these animals were released in specific areas within Yellowstone under constant biological monitoring.

What happened in the following years became known as trophic cascade — a trophic cascade — because a single predator reorganized several layers of the ecosystem.

Wolves started by hunting moose, but more important than the number of moose killed was the change in… behavior of the herds. Moose began to avoid certain valleys and riverside areas where they were exposed to attack, something that ecology calls a “landscape of fear.”

With moose avoiding these areas, Willows, poplars, and aspens began to return.The return of riparian vegetation opened up space for the return of beavers (Castor canadensis), who used the material to build dams and shelters.

This produced a chain reaction:

  • Dams created flooded areas.
  • Flooded areas captured sediments
  • Sediments stabilized the banks and reduced erosion.
  • More insects, amphibians, and fish have found habitat.
  • Riverine birds returned, attracted by the forest structure.

The predator not only controlled its prey, it reorganized an entire ecosystem.

From the return of beavers to changes in rivers.

The most impressive data relate to hydrology. By rebuilding dams, beavers altered water rhythms, created micro-zones of water retention, reduced peak runoff, and increased local recharge of shallow aquifers.

In areas where erosion previously eroded the riverbanks, new growth has begun to emerge. willows over 2 meters tall a few years after the reintroduction of wolves, something documented by research conducted by Oregon State University and other institutions.

Thereby, Sections of rivers like the Lamar and the Yellowstone have changed their morphology.stabilizing riverbanks where there were previously ravines and irregular deposits. What was seen was not “the wolf directly moving rivers,” but rather an ecological system recovering biological processes that shape the river’s course.

Science calls this ecosystem engineering, and it is one of the most cited phenomena in modern conservation literature.

What impact did wolves have on wildlife besides moose?

The impact was not limited to herbivores and beavers. The presence of wolves also altered coyote (Canis latrans) populations, which decreased in overlapping areas, opening up space for smaller species such as red foxes (Vulpes vulpes), which compete with coyotes.

Vultures, crows, and eagles have begun frequenting the carcasses of slaughtered moose, increasing the food supply for scavenging birds during the winter. Brown bears also benefited, competing for carcasses and consuming the remains of slaughtered animals.

In short, an introduced predator:

  • reduced herbivorous pressure
  • reduced a mesopredator (coyote)
  • propelled an engineering species (beaver)
  • favored scavenging birds
  • facilitated the return of riverside birds

This reorganization is what makes the case so instructive in applied ecology.

Concrete data from the historical process for those seeking accuracy.

For those seeking rigorous documentation, the essential data includes:

  • Year of reintroduction: 1995–1996
  • Number of wolves reintroduced: 31 individuals
  • Origin of wolves: Canada (Alberta and British Columbia regions)
  • Location: Yellowstone National Park, USA
  • Species directly affected: moose, coyotes, deer
  • Species indirectly favored: beavers, foxes, river birds, fish
  • Associated ecological concept: trophic cascade
  • Park area: ~8.983 km²
  • Precipitators of river change: beaver dams + return of riparian vegetation

This set of factors transformed the case into global reference for rewilding.

Why Yellowstone became a global symbol of rewilding.

There are many predator reintroductions around the world, but Yellowstone has become the most famous because it featured… five elements that are rarely combined:

  • Comprehensive and continuous scientific monitoring post-reintroduction
  • Keystone species with well-defined ecological roles
  • Documented impacts on vegetation and hydrology
  • Public and media interest, expanding ecological awareness
  • Clear photographic and temporal evidence before/after

The event became the subject of study in universities, documentaries, doctoral theses, and influenced conservation policies outside the US, including in Europe.

What does this case teach us about ecological restoration?

The Yellowstone incident showed that restoring ecosystems isn’t just about planting trees or starting breeding programs—sometimes it’s… to put the right predator back in the right place.

He also showed that:

  • The food chain is not a static thing.
  • Behavior matters as much as biomass.
  • Animals shape geography, not just vegetation.
  • Living systems can “self-correct” if critical parts are replaced.

Unlike an artificial restoration using machines and concrete, Yellowstone restored natural processes that then unfolded on their own.

The reintroduction of 31 wolves de 1995 The 1996 event wasn’t just an environmental project—it was a practical demonstration of how ecology functions as an interconnected system. The wolves didn’t just control moose; they triggered… an ecological waterfall which restored vegetation, brought back beavers, reinforced bird populations, reorganized predatory food chains, and even altered the behavior of rivers.

That’s why Yellowstone is considered one of the largest rewilding experiments ever conducted and perhaps the best documented in the world.