Sunday, April 21, 2013

Down on the Aphid Ranch

Originally this post was just going to be about vines.  There are four basic plant forms: trees, shrubs (small, branched trees), herbs (non-woody, soft plants), and vines.  Vines are woody but not strong, and they grow as tall as trees by climbing up other structures, often trees, and they usually have roots that are good for holding on, like this:

English ivy with roots that are good for holding on to buildings or trees.
 Some vines are evergreen like the English ivy on the back wall of our classroom:
English ivy doesn't lose its leaves in winter.
And some are deciduous like the milkweed vine on the lamppost by the playground:
Milkweed vines lose their leaves in winter.
Like I said, I was originally going to post about vines.  BUT when I was looking through my vine pictures, I noticed a very lucky but accidental detail on this picture of the English ivy:
New growth on the English ivy with some curious dots on the stem.
Look very closely at the stem, and you will notice there are ants walking on that stem:
Ants going up and down the ivy stem.
I started to wonder what ants were doing walking on an ivy stem, since there is not likely to be much ant food at the top of an ivy vine.  Then I looked even closer and I saw this:
An farmer ant and her aphids.
Now we have a story!!!  The picture is a little blurry, which means you're going to have to go out to the outdoor classroom and see this for yourselves.  The dark spots are insects called aphids (which can also be whitish or greenish), and the reddish brown spot is an ant.  What the ant is doing is called aphid farming.  It's a bit gross, but it's so amazing that it's completely worth learning about.

To explain aphid farming, we have to go back to plant sap.  Remember plants do photosynthesis and make sugars, which are dissolved in plant sap, making plant sap slightly sweet?  Aphids have pointy, needle-shaped mouthparts they poke into soft plant tissues, and they suck the plant sap out of plants for their own food - much like the psyllids we learned about back in the fall.  Since aphids live closely with plants, they are said to be in a relationship called a symbiosis.  In this relationship, the aphids are harmful to the plants because they 'sap' their energy.  The aphids benefit by getting food.  A symbiosis where one organism benefits and the other is harmed is called parasitism. 

Here's where it gets slightly gross.  Aphids drink a lot of plant sap, and they digest most of the sugar in it, but not all.  The leftover sap with a tiny bit of sugar in it goes on through and out the other end of the aphids' digestive system.  In all other organisms, this substance would be called feces or poo, but in aphids, the substance is a clear and sugary liquid, so it's called honeydew.  (Do NOT confuse this kind of honeydew with the delicious green melon you find in the produce section.)  If you have ever noticed sticky, clear spots on the hood and windshield of your car if you park it under a tree in summer, you have seen the results of the mist of honeydew that rains from the aphids in the tree.  Take a deep breath...it's really only plant sap run through an aphid!

OK, here's where it gets really gross, but also really, amazingly neat.  The sugars in the honeydew are technically a food source (like any other sugar), and ants eat sugar.  Put those two facts together, and you know what that ant is doing with the aphids on the leaf in the picture above.  Yes, some ants eat honeydew.  The ants know a good food source when they find it, so they protect the aphids and fight off aphid predators.  They even move the aphids around to better sap sources if their honeydew production slows down.  Some ants even keep aphid eggs in their ant nests in the ground during winter and place them on new plant growth in the spring so the aphid eggs have food when they hatch.  The ants are said to farm the aphids - just like humans farm cattle!  Dairy cattle ranchers protect the cows and move them around to new pastures with more food.  Cattle farmers also protect calves and raise them to adults.  And cattle are farmed to provide a liquid food source: milk! 

It's amazing to me that humans are not the only type of organism that does farming.  Ants live in groups and have very complex behaviors, as exhibited by the aphid farming.  Their behaviors often mimic human behaviors: they have 'jobs', fight battles, farm aphids (and fungi - neat story for another time), build large complicated structures and much more.

Ants and aphids are in a symbiosis - they live very closely together.  Their symbiosis involves both organisms benefiting from each other.  The aphids get protection, and the ants get food.  A symbiosis where both organisms benefit is called a mutualism.  Humans and cattle are in a similar mutualism.

The new growth on our ivy is very likely to have a constant supply of aphids and ants, so you should be able to find them any time!

Wednesday, April 10, 2013

The Hackberry: A Lesson in Bark

Do you remember looking at the hackberry tree last fall?  It's the big tree in our outdoor classroom by the entrance to the parking lot.  The hackberry is the tree whose leaves had hackberry leaf galls.  I promised I'd come back to the hackberry because of its unique bark.
The stem (ok, trunk) of our hackberry tree with its great hackberry bark.
The hackberry is generally an unnoticed tree in most parts of the U.S., but here in Nashville, it's so common it could be our city's official tree.  Hackberries have a huge influence on our lives here.  They provide wonderful shade for us in the summer and help keep our city air cooler and cleaner.  Hackberries can grow big and strong in the toughest of urban conditions as long as there is enough water.  They also are among the most common wild tree outside the city.  Hackberries provide lots of wildlife habitat and food.  Hackberries often have hollow portions which provide excellent homes for birds and small mammals.  The trees' berries, which are technically edible to humans, are a good source of winter food for birds.  You may have noticed when the late winter robins and starlings arrived a couple weeks ago that there were lots of purple bird bombs (bird droppings) on cars and sidewalks.  Most of those were the result of birds eating hackberries.  Nashville has felt the downside of hackberries too.  Hackberries can be a bit brittle, especially if they are hollow inside.  Tornadoes and great storms sometimes break off hackberry limbs, which can land on power lines or houses. 
Close-up of the edge of a ridge in hackberry bark showing the layers unique to hackberry bark.
To really appreciate the hackberry, you have to get up close and personal to it.  Specifically, look at its bark.  The bark of hackberries varies widely from almost completely smooth to almost completely bumpy, but there are two things it always has in common.  First, hackberry bark is always the same steely whitish gray color.  Second, the bark always has at least some bumps or ridges, which are made of layers and look somewhat like topographic maps.  No other bark that I have ever seen has layered bumps like this.
Our giant hackberry tree with very rough bark for a hackberry.
We have investigated bark before when we looked at scars in the sourwood tree, but let's dive in a little deeper - there's more good stuff here.  Bark is a plant organ.  Organs are structures that accomplish some function in an organism.  You may be more familiar with animal organs like the brain, the stomach, the skin, the lungs, etc.  Bark has two basic functions in plants: it protects the stem and it transports food all around the tree.  We have two separate organs for protection and food transport in our bodies.  Our skin provides protection from the outside, and our blood vessels transport blood around the body.  Blood carries digested food and many other things all around the body.  Let's investigate bark's two functions a little closer.

First: protection.  Bark seals off the tree from the environment.  It prevents the tree from drying out in the heat or getting soggy in the rain, just like our skin protects us.  Bark also keeps out insects and diseases, also like skin.  The stuff in bark that forms a seal against the world is called cork.  Cork is a spongy, softer material found in most types of bark, and it is waterproof due to the presence of a wax called suberin.  Some trees make more cork than others, and humans harvest cork for sealing bottles from the corkiest tree - the cork oak.  In most trees, the cork is interspersed with harder material in the outermost part of the bark.  The ridgy bumps as well as the smooth parts of hackberry bark both contain enough cork to protect the hackberry tree.

The second function of bark is food transport.  Trees and plants use the sun to make their energy in a process called photosynthesis.  Photosynthesis is the name for the chemical reaction that plants do to make sugar, and that chemical reaction is powered by sunlight.  Plants' basic food is sugar, which they can use for energy (just like you do) or for building other necessary plant parts.  Trees do photosynthesis in their leaves, but they need food in all parts of the plant.  The sugars from photosynthesis combine with water in the tree to form a liquid called sap, and liquid sugar is easy for trees to move around.  Tiny tubes in the bark transport dissolved sugars in the form of tree sap from the leaves to the rest of the plant, which is very similar to how the tiny tubes called blood vessels transport blood (which contains dissolved sugars too!) all around your body. 

If you've ever tasted maple syrup, you have tasted the concentrated tree sap taken from maple bark.  Maple syrup is sweet because maple trees' leaves did photosynthesis using the sun to make sugar.  Unfortunately the way I've explained this makes me think of maple syrup as tree blood, but that's really not quite true.  Blood is way more complex than sap, and blood has many more functions in our bodies than sap has in trees, but that's a story for another day. 






Friday, April 5, 2013

Tadpoles in the Pond

We have several tadpoles in our classroom's pond.  To see them, you have to be a little bit lucky.  Now that it's warm, the fish are easy to see - they are out in the open water, swimming smoothly and darting skillfully.  But tadpoles are a different story.  They lurk near the bottom in the leaves and muck.  Every once in a while, they clumsily wriggle from one spot to another.  The best time to see them is when you first walk up to the pond - they will wriggle to a hiding spot in response to the shadow you cast over the pond (they respond as if you were a predator!).  If you don't see one right away, wait around and watch - it might be your lucky day.  You could also take matters into your own hands and scoop through the bottom of the pond with a net.  If you do, please keep the tadpole in the water - they are very fragile and can't survive being dry or being squished.
A tadpole in our pond at the outdoor classroom.
Tadpoles are truly strange creatures.  They are the larval (young) form of frogs.  Frogs lay eggs in water, each of which will hatch into a tiny tadpole.  The tadpoles use gills to breathe water - just like fish do.  Tadpoles swim and eat and grow larger and larger, all underwater.  Eventually when conditions are right and they have had enough food, the tadpoles' bodies change form completely.  Their bodies digest and absorb their tail, and they grow tiny forelimbs (arms) and hind legs.  As they change external forms from tadpole to frog, their internal structures change too.  They grow lungs for breathing air!  Adult frogs hop out of the water and live their adult lives mostly on land but near water.  A change in body form like tadpoles have is called a metamorphosis.  If your body changed and suddenly grew wings for flying, that would be a type of metamorphosis.  Other animals that do metamorphosis are insects (maggots become flies, caterpillars to butterflies, etc.).

Tadpoles and frogs are vertebrates.  Vertebrates are any animals that have an internal skeleton with a backbone.  That means mammals, birds, reptiles and fish are also vertebrates.  Can you think of animals that don't have backbones? (Answer below*.)  Any vertebrate that starts its life in the water and undergoes metamorphosis is called an amphibian.  The word amphibian makes sense if you know what the parts of it mean: amphi- means both, and -bian means life form.  Amphibians include frogs, toads, newts and salamanders. 

Why do you think fish are such better swimmers than tadpoles?  Compare the body shape of a tadpole to a fish, then try an experiment.  First, find a pool and a life guard.  Then jump into the swimming pool and swim like normal using your arms and legs to help you.  Then hold your arms and legs into your body and try to swim - it's not so easy without appendages, is it?  Tadpoles do not have fins like fish do, and fins are great for steering while you're swimming.  They have only a tail to help push them along.  That's why tadpoles wriggle around so strangely and fish swim with ease.

How do you think the tadpoles got to our pond?  Frogs had to have laid the eggs that grew into these tadpoles, but how did the frogs get to our pond?  They have to stay near water, and there aren't other ponds nearby.  Frogs could not have gotten to our pond to lay eggs!  One possible answer could be related to the fact that frog eggs are somewhat sticky.  If a bird stood in a different pond and frog eggs stuck to its feet, then the bird came to our pond, it could have brought the eggs that hatched to our tadpoles.  That makes frog eggs disperse just like the kinds of seeds that stick to animal fur - which would be animals imitating plants!

*Invertebrates include insects, spiders, clams, snails, sponges, jellyfish, sea stars, and thousands more types of organisms.