Saturday, October 27, 2018

New Film: My Forest Has Worms

The Unexpected Threat to Northern Forests


Owners of dogs and cats are well aware of the problems caused when their pets have worms. Luckily, there are remedies for those mammalian issues.

But now there's another serious invasive forest pest, one that we have welcomed, and thought was completely beneficial; one that has insidious behavior, yet seems so benign and desirable to have around. It's advancing into our northern forests, altering their composition, even destroying them. And there's no remedy, no pill to stop it. What hideous critter is this?

Scientists call it "Lumbricus terrestris". Most of us know it better as ... the  common nightcrawler ! Actually, it's not just the nightcrawler that's a problem, but a number of earthworm species, none of which belong here. In the northern reaches of the U.S., where glaciers occurred, there are no native earthworms (states south of the glacier's limit do have native earthworms, which are not a problem in those forests).

The Forest Floor

 First, the background story. Ten thousand and more years ago, huge glaciers covered the northern portion of our continent, as far south as New Jersey in the east, west through the Great Lakes region to the west coast. No native earthworm species, if they were here prior to the glaciers, survived under the ice sheets, which were thousands of feet thick. In the post-glacial period, our forests grew back, following the melting glaciers northward. But native earthworms in the unglaciated regions to the south only advance in the soil a couple dozen feet or so per year, so they couldn't move northward as fast as the forest did when glaciers retreated; thus, our northern forests have existed for millennia without them, and are adapted to the worm-free habitat.

Each autumn, as leaves fell, they accumulated on the forest floor; they were slowly decomposed by fungi, microbes, and other organisms.

A natural forest floor duff layer
But the breakdown was slow, and the organic duff layer was thick on the forest floor; in fact, that's what the duff layer is known as: "the forest floor".

Understory plants, including wildflowers, shrubs, and tree seedlings, take root in that layer, which lies above the mineral soil. They depend upon that carpet of duff for nutrients, and as a rooting medium. In a good site
Intact herbaceous plants
without worms, that layer can be 4 or 5 inches deep. It is an insulating blanket, helping to protect from freezing temperatures in winter, and hot, drying conditions in summer. It's the zone where most rooting takes place, because the duff is well aerated and spongy (you can feel that as you walk on it), holds moisture, and contains the most organic nutrients. Roots that penetrate below the floor layer into the soil act as anchoring roots, but most nutrient uptake is done in the compost-like duff.

In an undisturbed forest, that floor layer becomes a giant web of mycorrhizae, which are root cells modified by the presence of certain fungi (eg, amanitas, boletes, chanterelles, etc).

Chanterelles, a mycorrhizal mushroom
Fungi can't photosynthesize like green plants do, so they can't manufacture their own food. Instead, they either obtain it by decomposing organic matter (in the case of one class of fungi), parasitizing living organisms, or through a complex partnership with plant roots (mycorrhizal fungi). In the latter case, the fungi help to make nutrients and water available to the plants, which in turn surrender food to the fungus. It's a symbiotic relationship, each partner benefiting from the other. (As an interesting side note, it's been reported that the largest known organism on Earth is a fungus in Oregon that is thousands of years old, and occupies nearly 2400 acres! However, it's not a mycorrhizal fungus).

The largest percentage of plant and tree species (80% or more) have mycorrhizal relationships, which are highly important to plants, particularly in poor soils. Mycorrhizal fungi excel at gathering phosphorous from the soil, and trees in nutrient-poor soil do far better when they can form mycorrhizae. That's how a proper forest should be working.

Today's Forest Floor Problem


In our northern states where the non-native earthworms have invaded the hardwood forests, they rapidly eat newly fallen leaves and small twigs, consuming the duff layer, and mixing it into the lower soil layers via their movements into the ground. The duff layer is not replenished as quickly as it is eaten, and disappears. Earthworm activity dramatically decreases the mycorrhizal relationships, and thereby harms the plants that rely on them and the duff layer. The makeup of the soil layers is changed, to the detriment of the forest community that has occupied the land for millennia. Worms break up the organic layer to the point where important elements such as nitrogen, phosphorous, and carbon are leached deeper into the soil, where young plant roots simply can't reach them. Herbaceous plants can virtually disappear, leaving the ground barren and brown. The soil becomes drier due to aeration by the worms. Compare this photo of stark, worm-damaged woods to those of the undamaged old growth forests above:

Worm damaged, impoverished forest floor


Notice how there's no duff under the thin layer of leaves (not to mention the obvious lack of green plant life on the ground). The photo was taken at the height of the growing season, in a suburban forest.

There are some plant species that don't participate in mycorrhizal relationships, and may survive the onslaught. So you may see a diminished complex of plants, comprising a sparse variety of species, with things still looking green. For example, Pennsylvania sedge may take over the area. You may find Jack-in-the-pulpit, or False Solomon's Seal.

Some of the trees that appear to be particularly sensitive to the disappearance of the forest floor layer are Sugar Maple, Red Maple, Red Oak, Basswood,
Serviceberry (Shadbush), and Hophornbeam. Their seedlings don't do well without the duff's benefits. Ash seedlings, however, can do well (but they're under severe attack now by the Emerald Ash Borer). Nightcrawlers prefer to eat the most nutritious leaves, so the fallen basswood and maple leaves tend to go first; when they're gone, oak leaves will be eaten. The population of worms will be greater in the forests with the greatest quantities of the leaves they prefer, so basswood/maple forests tend to be affected more than oak/beech woods.


The forest is a complex ecosystem, so animal species are also affected. With the presence of earthworms and resultant loss of the floor layer, tiny invertebrates and microscopic organisms decline, which can affect the entire food web, from amphibians and reptiles to birds, small mammals, and large mammals.

Redback Salamander

Salamanders, for instance, go into decline because their young can't find enough of the duff layer-resident food they depend on. And with the drying of the uppermost ground layer, their habitat is degraded.

Where do these earthworms come from?

 

 It's believed that the non-native ones that are found here were first brought in ships from Europe. Soil was used as ballast in the holds of those ships, and it no doubt contained earthworms. Potted plants were also brought here over time. So that's what started it all. Now, we also have some from Asia, including the latest invader, the "Jumping Snake Worm" (aka "Asian Jumping Worm", "Crazy Snake Worm"), Amynthas agrestis. The movement of the invasion front radiates outward from wherever the worms are introduced; it happens much more quickly as a result of human activities than from the natural advancement of the worms.

Now that the worms have become established, we spread them by various means. We move topsoil from one location to another; fishermen may discard unused bait worms; gardeners encourage them in compost piles; well-intended community composting sites provide soil containing worms to anyone who wants it; landscaping practices move plants with soil and worms long distances. Worms deposit tiny eggs and cocoons in the soil, and these can easily be undetected and transported into forest interiors (eg, in soil caught in the tread of tires, or even boots).

Heavy deer populations compound the problem when they browse herbaceous plants and tree seedlings. Add logging to that, and you really have a recipe for declining forest cover.


New film

We have produced a new short film, "My Forest Has Worms", to show the nasty effects invasive worms have on our northern forests. You can view it on our New England Forests Youtube channel, or in the player window below (player might not be available if you're reading this in an email feed).






4 comments:

  1. Good article and film, Ray. I feel it should be important to note that worms contribute to a condition known as "forest decline syndrome", which in New England is caused by three factors, earthworms, invasive plants, and heavy browsing of white-tailed deer, the three seemingly unrelated organisms become linked and are able to proliferate in eachother's presence, take how barberry changes soil PH making it more suitable for worms, while the worms in turn provide it with a better seedbed, not to mention that deer will feed on the leaves of barberry and other "ELP" (extended leaf period) plants (mainly invasive species) which have been documented to lead to increase in deer populations, thereby removing competing native vegetation. It's really sad to think that a lot of people actually consider these brown, arid forests with no regeneration "natural".

    That said, I figured I should mention that I have successfully reduced the population of Asian jumping worms in one research plot on my land, and I was quite pleased to see new mycorrhizal growth afterwards. I don't know how well this would work on the more common nightcrawlers, given that they burrow deep into the soil, but it has been effective on the Asian worms. I spoke with Dr. Josef Gorres with the University of Vermont recently and he seemed hopeful about possible control methods for at least Asian jumping worms. Personally, I think if us humans could get our act together and work together we could mitigate or even "erase" a lot of our forest problems, but sadly I don't think that's going to happen any time soon.


    Joshua

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    Replies
    1. How did you get rid of the worms?

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    2. We did not get rid of the worms, there’s no known way to do that. That’s why this is such a problem for our forests. It looks as though the forests will have to evolve and adapt to the presence of worms over probably hundreds or thousands of years. The plant community where worms exist will likely look a lot different than what we are used to today. There are only a few plants that seem to do ok in the worms’ presence, and that may leave the door open to non-native, invasive species that can tolerate them. This will affect not only plants, but many, many animal species as well. Only time will tell.

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  2. Clar, the answer to "what do animals eat" depends on the type of animal. Herbivores (eg, deer, porcupines, etc) eat plants. Carnivores (eg, wolves, lions, weasels, peregrine falcons, etc) are meat eaters, so they eat other animals. Omnivores (eg, bears, coyotes, etc) eat a variety of things, both plants and animals. Some animals specialize in eating insects, or fruits, or fish, or just certain plants or animals. Some, such as vultures, are scavengers that eat other dead animals. Worms happen to eat the forest litter layer; that in itself is fine, except when non-native worms eat too much of it too quickly, and there is no natural control to limit the worms' population. Then we have a bad situation, as you saw in the film. Humans keep creating problems by introducing plant and animal species to environments where they didn't exist previously, upsetting the ecological
    "balance" there; it can take hundreds or thousands of years for evolution to bring things back into a more stable condition.

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