Category Archives: insects

Episode 185: Ice Worms, Army Ants, and Other Strange Invertebrates!

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Let’s learn about some weird insects this week! Thanks to Llewelly for suggesting army ants!

Further reading:

If you’re interested in the magazine Flying Snake, I recommend it! You can order online or print issues by emailing the editor, Richard Muirhead, at the address on the website, and there’s a collection of the first five issues on Amazon here (in the U.S.) or here (UK)!

The magnificent, tiny ice worm! The dark speckles in the snow (left) are dozens of ice worms, and the ones on the right are shown next to a penny for scale. Teeny!

ARMY ANTS! WATCH OUT. These are soldier ants from various species:

The Appalachian tiger swallowtail (dark version of the female on the right):

Tiger swallowtails compared:

The giant whip scorpion. Not baby:

Jerusalem cricket. Also not baby but more baby than whip scorpion:

PEOPLE. GET THOSE HORRIBLE THINGS OFF YOUR HANDS.

Show transcript:

Welcome to Strange Animals Podcast. I’m your host, Kate Shaw.

This week we’re going to talk about a number of strange and interesting invertebrates as part of Invertebrate August. Thanks to Llewelly for a great suggestion, and we also have a mystery invertebrate that I learned about from the awesome magazine Flying Snake. Flying Snake is a small UK magazine about strange animals and weird things that happen around the world. It’s a lot of fun and I’ll put a link in the show notes if you want to learn more about it. It’s been published for years and years but I only just learned about it a few months ago, and promptly ordered paper copies of all the issues, but they’re also available online and the first five issues are collected into a book.

So, let’s start with an invertebrate I only just learned about, and which I was so fascinated by I wanted to tell you all about it immediately! It’s called the ice worm, and it’s so weird that it sounds like something totally made up! But not only is it real, there are at least 77 species that live in northern North America, specifically parts of Alaska, Washington state, Oregon, and British Columbia.

The ice worm is related to the earthworm, and in fact it looks like a dark-colored, tiny earthworm if you look closely. It’s usually black or dark brown. It likes the cold—in fact, it requires a temperature of around 32 degrees Fahrenheit, or zero Celsius, to survive. You know, freezing. But the ice worm doesn’t freeze. In fact, if it gets much warmer than freezing, it will die. Some species live in snow and among the gravel in streambeds, and some actually live in glaciers. Ice worms can survive and thrive in such cold conditions because their body contains proteins that act as a natural antifreeze. It navigates through densely packed ice crystals with the help of tiny bristles called setae [see-tee] that help it grip the crystals. Earthworms have setae too to help them move through soil.

During the day, the ice worm hides in snow or ice to avoid the sun, and comes to the surface from the late afternoon through morning. It will also come to the surface on cloudy or foggy days. It eats pollen that gets trapped in snow and algae that is specialized to live in snow and ice, as well as bacteria and other microscopic or nearly microscopic animals and plant material. In turn, lots of birds eat ice worms. Birds also occasionally carry ice worms from one glacier or mountaintop to another by accident, which is how ice worms have spread to different areas.

The glacier ice worm can grow to 15 mm long and is only half a mm thick, basically just a little thread of a worm. It only lives in glaciers. You’d think that in such an extreme environment there would only be small pockets of glacier ice worms, but researchers in 2002 estimated that the Suiattle [soo-attle] Glacier in Washington state contained 7 billion ice worms. That’s Billion with a B on one single glacier. Other ice worm species can grow longer than the glacier ice worm, including Harriman’s ice worm that can grow nearly 2.5 inches long, or 6 cm, and is 2.5 mm thick.

There are tall tales about ice worms that can grow 50 feet long, or 15 meters, but those are just stories. An ice worm that big wouldn’t be able to find enough to eat.

Next, let’s talk about a type of ant. Llewelly suggested the army ant a long time ago, and recently I got an email from Ivy whose list of favorite animals includes the army ant!

The army ant lives in parts of Africa, South America, and Asia, and although there are some 200 species in different subfamilies, recent research suggests that many of them are descended from the same species that lived in the supercontinent Gondwana more than 100 million years ago.

Army ants don’t dig permanent nests like other ants. Instead they make temporary camps, usually in a tree trunk or sometimes in a burrow the ants dig. But these camps aren’t anything like ordinary ant nests. Often they’re formed from the bodies of worker ants, who link their legs together to make a living wall. The walls form tubes that make up chambers and passages of the nest, and inside the nest the queen lays her eggs. There are also chambers where food is stored. But the nest isn’t permanent. At most, the army ant only stays in one place for a few weeks, after the larvae pupate. The colony feeds the food stores to the queen, who lays a new batch of eggs timed to hatch when the new ants emerge from their cocoons. At that point, the colony breaks camp and enters the nomadic phase of behavior until the newly hatched batch of larvae are ready to pupate.

What do they do with the larvae while they wander? Workers carry them around. As in other ant species and the honeybees we talked about recently, an army ant colony is divided into different types of ant. There’s a single queen ant, seasonally hatched males with wings who fly off as soon as they’re grown, and many worker ants. But army ants have another caste, the soldier ant. These are much larger than the worker ants and have big heads and strong, sharp mandibles. Some species of army ant forage primarily on the ground while some hunt through treetops and some underground, but they generally hunt in large, well-organized columns with soldier ants on the outside as guards. In many species, the worker ants are further divided into castes that are specialized for specific tasks.

The queen ant is an egg-laying machine. Queens of some species can lay up to 4 million eggs every month. The queen is wingless, but a new queen doesn’t need to leave the colony the way other ant species do. Instead, when new queens emerge from their cocoons as adults, the colony splits and two new colonies form from the old one, each with one of the new queens. Usually more than two queens hatch, but only two survive.

When males emerge from their cocoons, they immediately fly off and search for another colony. But a male can’t just land and mate with a queen. He has to get through her guards, and they decide whether they like him or not. If they find him adequate, they bite his wings off and bring him to the queen. After he mates, he dies. This sounds like the plot of a weird science fiction novel from the 1960s. If a colony’s queen dies, the worker ants may join another colony.

Let’s talk specifically about the Dorylus genus of army ants for a few minutes, which live in Africa and Asia. Dorylus army ants live in simply enormous colonies. When the colony goes foraging, there may be 15 million ants marching in a dense column, and they can eat half a million animals every single day.

That’s why the army ant is so feared. The column of ants is made up of worker ants in the middle with the much larger soldier ants along the edges. The columns don’t move very quickly, but the ants attack, kill, and eat any living animal they encounter that can’t run away. This includes insects, spiders, scorpions, and lots of worms, but also eggs and baby birds, other baby animals, frogs and toads, and even larger animals. What isn’t eaten on the spot is carried back to the camp to feed larvae and the queen.

Army ants are also beneficial to the ecosystem and to humans specifically in many ways. A column of army ants that marches through a village will eat so many insects that they act like a really high quality exterminating service for homes and gardens. They also scare insects and other animals that flee from the ant columns, and a lot of animals benefit from the general chaos. Birds of many species will follow army ants in flocks, grabbing insects as they flee the ants. Some birds even make special calls to alert others that army ants are on the move, so that everybody gets a chance for easy food. Even more animal species will follow the column to clean up what they leave behind, including partially eaten carcasses, animals that were killed but rejected as food, and even the feces of the birds that follow the ants.

And, of course, a lot of animals just eat the army ants. Chimpanzees make different types of tools to help them safely harvest army ants. Most commonly, a chimp will use a stick it’s modified to the right length and shape, referred to as an ant-dipping probe. It will put one end of the stick down in the column of army ants and wait until ants start climbing up the stick. When there are enough ants on the stick, it will remove the stick and eat the ants off of it. It’s an ant-kebob!

If you’re wondering why the chimps aren’t attacked by the ants, or why the ants don’t figure out they’re climbing a stick to nowhere, Dorylus army ants, like most army ant species, are all blind. They communicate by releasing pheromones, which are chemicals with specific signatures that other ants can sense, something like smells. Some species that mostly live above-ground have re-evolved sight to a limited degree.

The mandibles of Dorylus army ant soldiers are so strong, and the ant is so tenacious about holding on, that people in some East African tribes traditionally use them to stitch up wounds. The soldier ant is held so that it bites with one mandible on each side of a wound, holding the edges of skin together. Then the person severs the ant’s body from its head, killing it—but the jaws are so strong that they will continue to stay in place for several days while the wound heals.

In Central and South America, the army ant genus Eciton [ess-ih-tahn] is very similar to Dorylus. Some species can cross obstacles like streams by building a living bridge out of individuals to allow the rest of the column to cross.

Whew, okay, I should probably have made the army ant its own episode, because there’s so much cool research about it that I could just go on forever. But let’s move on to a much different insect next, a butterfly that lives in the eastern United States, especially in the Appalachian Mountains. This is the Appalachian tiger swallowtail, which has yellow wings with black stripes and a black border, and a black body. Some females have all-black wings with orange spots. When the genetic makeup of the butterfly was examined, it turns out that the species originated as a hybrid of the Eastern tiger swallowtail and the Canadian tiger swallowtail. This kind of hybridization is rare in the wild. The Appalachian tiger swallowtail lives in the mountains, usually in high elevations, and while its range overlaps with both parent species, it almost never hybridizes with either. It has inherited the Canadian butterfly’s tolerance for cold but is twice its size. Researchers estimate that the hybridization occurred around 100,000 years ago.

I learned that interesting fact about the Appalachian tiger swallowtails from the May 2018 Flying Snake issue, and let’s go ahead and learn about a mystery invertebrate I also read about in that issue of Flying Snake.

The mystery is from The Desert Magazine, which was published between 1937 and 1985. It was a monthly magazine that focused on the southwestern United States, with article titles like “Rock Hunter in the Sawange Range” and “Ghost City of the White Hills.” Both those headlines are from the January 1947 issue, which is also where the first mention of the Baby of the Desert shows up in the letters section. Flying Snake excerpts the relevant letters from that issue and a few later issues, but I got curious and found the originals online.

I’ll quote part of the original letter because it’s really weird and interesting:

“Gentlemen: Would like to ask if there is such a thing as a very poisonous desert resident called ‘Baby of the Desert,’ so named because of the resemblance of its face to that of a human baby. Whether this so-called ‘Baby of the Desert’ is supposed to be insect, reptile or rodent, I could not find out. …[I]t was considerably smaller than the Gila monster.”

The letter was signed William M. Weldon from South Pasadena, California.

The editor responded, “The question of the Baby of the Desert, Baby-face, or Niño de la Tierra, as it is variously called, came up for discussion on the Letters page of the magazine two years ago. A reader sent in a description of the fearsome beast as it had been pictured to him and asked for confirmation from someone who had seen it.”

Because of the mention of another letter asking about the Baby of the Desert, two years before, I went through the letters sections of all the 1945 issues to find the original. I couldn’t find it in 1945, but I did find a nice letter from James Mayberry in California, who found a desert tortoise with blue paint on its shell. He thought someone had brought the tortoise back from a visit to the desert. James named the tortoise Mojave but knew it needed to go home, so he sent it to the Desert Magazine. I’m delighted to say that the editor took it out to a lonely desert hill where there were other tortoises and let Mojave go. Tortoises live a long time so Mojave might still be stumping around out there, the blue paint on his shell faded in the sun.

Then I went back through the 1944 issues and found the letter in the July issue. It was from Albert Lloyd of Tulsa, Oklahoma, who wrote, “Perhaps some reader can supply authentic information about a small denizen of the deserts and mesas of the Southwest, which the Mexicans call Niño de la Tierra, or Child of the Earth. During four years of roaming around New Mexico and Arizona I was never fortunate enough to see one. But I have talked with several who claim to have seen it. They describe it as a doll-like animal, about three or four inches in length, walking on all fours, with head and face like that of an infant. They claim it will not attack you unless molested and that its bite is more deadly than a rattlesnake’s.”

The editor of the Desert Magazine suggested that the Baby of the Desert was an insect. “[I]t appears that the Baby-face is actually our old friend the yellow and black striped Jerusalem cricket or Sand-cricket, who is nocturnal and usually found under boards or stones.”

But responses in the letters section in following issues, February and April 1947, don’t agree. S.G. Chamberlin of San Fernando, California wrote, “Some years ago…we uncovered what we first thought to be a Jerusalem Cricket. The coloring was the same and it was a little more than two inches long. Later in the day a ranch hand brought us a Jerusalem Cricket and then we noticed quite a difference in the bodies and heads of the two insects. The round face of the first one did attract our attention although we didn’t think of a baby at the time. The ranch foreman placed them in different bottles to show them to a man in the Farm Bureau office who was versed in such things. He reported back that the first insect was called Vinegarones or Sun Spider and supposed to be harmless.

“At the ranch we were told that on the Mexican border there was a similar insect that is supposed to be poisonous.”

And Coila Harris of South Laguna, California wrote, “I was interested in the recent letters about ‘Baby Face.’ This is not the Jerusalem cricket or potato bug, as many believe, but could be mistaken for one of these insects. Baby-face lives down Mexico way. When we were living in El Paso, one of the weird looking bugs was found under our house. It had a body of a large Tarantula, the head was white as a bleached bone and looked like a bald headed baby, a dreadful thing. I was told at the time that Mexicans consider them so poisonous, that if bitten on the finger by one, they chop off the finger.”

Unfortunately for me, the second I saw the mention of a vinegarone, I had a good idea of what this animal might be. And I really don’t want to look at pictures of vinegaroons.

I do try very hard not to be biased against gross-looking insects, because for one thing, they aren’t hurting me and gross is in the eye of the beholder. One person’s “ooh gross” is the other person’s “Oh, that is so neat!” Spiders don’t bother me and as long as I don’t have to look closely at an invertebrate’s mouthparts and things, I’m usually okay. But I get a big case of the nopes when it comes to the vinegaroon.

The vinegaroon is an arachnid, related to spiders and scorpions. It sort of looks like a mixture of the two, although there are lots of species and they vary quite a lot. It’s also called the whip scorpion. The name vinegaroon comes from the acidic liquid it squirts from the base of its whip-like tail if it feels threatened, which smells like vinegar. It lives in tropical and subtropical parts of the Americas and Asia, with one species known from Africa. Most species prefer dark, humid areas and live in burrows in rotting wood or under rocks and leaf litter, but the giant whip scorpion lives in more arid areas in the southwestern United States and Mexico.

The giant whip scorpion grows to around 2.5 inches long, or 6 cm, not counting the long whip-like tail. Like all vinegaroons, it eats insects, slugs, and other small animals. But no one could look at it and think “baby.” It has big claw-like pedipalps in addition to six walking legs and a pair of front legs that are extremely long and thin, that it uses to feel around with. It has eyes—in fact, like spiders it has eight eyes—but it doesn’t see very well and mostly navigates by touch. It’s dark brown or black with some lighter brown markings on its abdomen.

The Jerusalem cricket looks superficially similar to the vinegaroon although it’s not an arachnid. It’s also not a cricket, and it doesn’t have anything to do with Jerusalem since it’s native to the western United States and Mexico. In fact, it’s related to the weta of New Zealand. It lives in the same sort of places that vinegaroons like, burrowing in moist soil and rotting wood, but it mostly eats decaying plant material although it will sometimes eat small insects. It can bite, although it’s not venomous or poisonous, but it can give off a horrible smell if it’s disturbed. It’s yellowish to dark reddish-brown with a black-striped abdomen and a rounded head. It also does not look anything like a baby.

BUT, while it’s known by a couple of Navajo names that translate to variations on “red skull bug,” in Spanish it’s called cara de niño, which means child’s face, or niño de la tierra.

So I think the Desert Magazine editor was right. The Baby of the Desert is the Jerusalem cricket. But I wouldn’t be a bit surprised if the Jerusalem cricket is sometimes confused with the giant whip scorpion. They’re both large nocturnal creatures with a similar body shape and coloring, that live in the same areas and occupy the same habitat. And they’re both horrifically creepy-looking. You know what? I bet you anything that “Baby of the Desert” and “baby-face” are ironic names. BAD BABY.

The Jerusalem cricket doesn’t have any kind of hearing organs akin to ears but it can sense vibrations. Instead of chirping, it drums its abdomen on the ground to attract a mate. This is what the drumming sounds like.

[Jerusalem cricket drumming]

You can find Strange Animals Podcast online at strangeanimalspodcast.blubrry.net. That’s blueberry without any E’s. If you have questions, comments, or suggestions for future episodes, email us at strangeanimalspodcast@gmail.com. If you like the podcast and want to help us out, leave a rating and review on Apple Podcasts or just tell a friend. We also have a Patreon at patreon.com/strangeanimalspodcast if you’d like to support us that way.

Thanks for listening!

Episode 184: The Mosquito!

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Thanks to Kaiden who suggested we learn about mosquitoes this week! You know what eats a lot of mosquitoes? Bats! If you don’t already listen to the excellent podcast Varmints!, jump on over to it to listen to last week’s episode about bats! I cohosted with Paul and had a great time, and I know you’ll like the episode and the podcast in general. It’s family friendly and lots of fun!

Further reading:

The Paleobiologist Who Inspired the Science in ‘Jurassic Park’

SMACK SMACK SMACK SMACK:

Mosquito larvae:

An elephant mosquito in amber:

Show transcript:

Welcome to Strange Animals Podcast. I’m your host, Kate Shaw.

This week we have a great listener suggestion from Kaiden, who wants to learn about mosquitoes! This is especially great because last week I was a guest co-host on the awesome podcast Varmints!, and we talked about bats! As you may know, bats eat a LOT of mosquitoes. I’ll put a link to the Varmints! page in the show notes in case you don’t already subscribe. I think you’d like it.

The mosquito is a common insect that lives all over the world, except for Antarctica and Iceland. There are something like 3,500 species of mosquito known. In areas where it gets cold in winter some species of mosquito may hibernate, but most enter a state called diapause. This basically means that any eggs and larvae delay their development until it warms up, then develop into adults normally.

The mosquito is a type of fly, and like other flies it only has one pair of wings. Most mosquito species are only 3-6 millimeters long, gray or black in color, with long, extremely thin legs and narrow wings. The largest known species of mosquito is called the elephant mosquito, which can grow up to 18mm long. That’s almost three-quarters of an inch. Its wingspan is even larger, 24 mm, which is just shy of a full inch across.

The mosquito eats nectar. Oh, sorry, that’s the male mosquito. The female mosquito is the one who drinks blood, and she needs the blood to develop her eggs. But in fact, the female mosquito also eats nectar too, and mosquitoes even help pollinate some flowers. Some species of mosquito can develop eggs without blood, but most need the extra protein and nutrients that blood provides. In some species, the female can produce one clutch of eggs without blood, but she has to have blood to develop more eggs.

The female mosquito has a long, thin proboscis that she uses to pierce the skin of an animal and suck its blood, although the process is a lot more complicated than it sounds. The proboscis is made up of a sheath that protects the other mouthparts, including a pair of mandibles and a pair of maxillae. The mandibles and maxillae are actually the parts that cause the bite. If you look at a mosquito that has landed on your arm and is biting you, it looks like the proboscis must be stuck in your skin like a teensy hypodermic needle, but what you’re seeing is the proboscis sheath. The mosquito touches the sheath to your skin and bends it back slightly, which exposes the mouthparts and acts as a guide as the mouthparts bite you. The mandibles are the pointy ones and the maxillae have flattened ends. The mosquito moves her head slightly back and forth to lever them all into your skin, and the only reason this doesn’t hurt like crazy is because they’re so incredibly tiny, plus it happens very quickly.

Once the mouthparts have pierced the skin, the mosquito injects saliva, which contains proteins that act as an anticoagulant so the blood continues to flow without clotting. The itching and swelling associated with a mosquito bite are due to this saliva, which your body reacts to as a foreign substance, which of course it is.

This biting and saliva injecting process actually takes place very quickly, and then the mosquito sucks the blood up. She can hold up to three times her weight in blood. Not only that, but if she’s not disturbed, she will start digesting the blood quickly and will eject as much of the liquid as possible to make room for more blood, since she doesn’t need the liquid part of the blood.

Vampire bats do this too, if you’ve listened to our vampire bats episode or the new Varmints! episode about bats. They digest the blood they drink quickly, then pee out the excess liquid so they’re light enough to fly. But in the case of the mosquito, she just needs as many nutrients from the blood as possible to develop her eggs. That’s why a single mosquito may bite you numerous times. She needs to fill her stomach with the nutritious solids in the blood while excreting as much extra liquid as she can.

Once she has all the blood she needs, the mosquito will hide somewhere for a few days while her eggs develop. Then she’ll fly out to find a good place to lay them.

Mosquitoes lay their eggs in water, usually stagnant water like small ponds. The larvae stay in the water after they hatch. You may have seen mosquito larvae, since they’re distinctive. They’re only a few millimeters long and skinny, with a bristly-looking head. The larvae come to the surface to breathe through a siphon in the abdomen, so they will hang head downward just under the water’s surface. If something startles them, the larvae will curl up and sort of jerk their way through the water. Mosquito larvae eat algae and other tiny food.

Even after a larva pupates, it can still move around in the water. It doesn’t eat, but it needs to breathe, so it will hang just under the water with the breathing siphon in its abdomen at the surface, just as it did as a larva. After a few days, the pupa splits open and the adult mosquito emerges. Females fly off but the males stay in a group, and female mosquitoes join the group to find a mate.

The mosquito’s feet are adapted to allow it to stand wherever it likes. Its feet have microscopic hairy pads like those found on gecko toes that allow it to stick to smooth surfaces, and it also has microscopic hooks that help it stay in place on skin. And it also has feathery scales on its feet that are only a few microns across that allow it to stand on water. Since some species of female mosquitoes lay their eggs directly into water, being able to stand on the water’s surface is useful.

Mosquitoes spread a lot of diseases, which get injected along with the anticoagulant saliva. These include malaria, West Nile virus, zika, yellow fever, dengue fever, and many others. An estimated two million people die of mosquito-spread diseases every year, which makes the mosquito the deadliest animal in the world.

Because mosquitoes are such disease spreaders, people keep trying to figure out better ways to kill them off or at least stop them from spreading disease. One way to stop mosquitoes from spreading is to make sure there is no stagnant water around your house to breed new mosquitoes. A female mosquito will lay her eggs in even small amounts of water, such as an empty drink can that has collected rainwater, so getting rid of trash helps. In the past, people tried poisoning water or spraying insecticides, but this isn’t always very effective against mosquitoes and also kills other insects that may be beneficial.

But as genetic engineering becomes more sophisticated, scientists have discovered new ways to help stop mosquitoes from spreading disease.

For example, let’s talk briefly about dengue fever. I won’t go into symptoms or anything like that, don’t worry. It’s mostly a tropical disease found primarily in parts of Asia, Africa, and Central and South America, and it’s spread by the yellow fever mosquito, which also spreads many other diseases. People do die from dengue fever but most recover and are fine, but of course no one wants to get sick. There’s a vaccine as of 2016, but it’s not fully effective and has some side effects.

To help stop the spread of dengue fever, people have tried releasing animals into standing water that eat mosquito larvae, such as guppies native to the area. This has actually helped. In northern Vietnam, copepods that eat mosquito larvae were introduced into water storage tanks and did such a good job that the yellow fever mosquito was actually eliminated in the area for years. Some species of elephant mosquitoes, which you may remember from a few minutes ago are the largest mosquitoes in the world, don’t drink blood at all. Its larvae eat the eggs and larvae of other mosquito species, which gives it enough nutrients as an adult to lay plenty of eggs. One species of elephant mosquito specializes in eating the larvae of the yellow fever mosquito and has been introduced into some areas to help control its population.

Genetically modified male yellow fever mosquitoes have been introduced into the wild to mate with ordinary female mosquitoes in many places. The males contain a gene that causes larvae to die before reaching adulthood, and it has helped quite a bit. The yellow fever mosquito population has been reduced by over 90% in the places where the males were released, but it doesn’t affect other mosquito species that don’t carry the diseases. The problem is that genetically modified males have to be continuously bred and released in order for the program to keep working.

Very recently, as of January of 2020, scientists have engineered an antibody for the yellow fever mosquito. It basically stops the dengue virus from replicating in the mosquito, which means it can’t be passed to a human. There have been attempts to do this before, but it was only effective for one or another strain of the dengue virus. This new antibody is effective against all strains of the virus. This will help people while not killing the mosquitoes. The team is also working to engineer an antibody for other mosquito-borne viruses.

So, is it true that some people get targeted by mosquitoes more than others? As someone who seems to be a mosquito magnet when I go outside in the evening when mosquitoes are most active, I would say yes–and science agrees with me. Mosquitoes are attracted to some people more than others. The mosquito has a good sense of smell and can track animals by smelling their sweat and the carbon dioxide they exhale. They also tend to prefer people with type O blood and high body heat, but how attractive a person is to a mosquito depends on genetic traits too.

Some species of mosquito prefer some types of animals over others too. Some feed almost exclusively on birds, for instance. But in a pinch, a female mosquito will bite just about any animal, and it doesn’t even need to be warm-blooded. Mosquitoes will bite reptiles, amphibians, and even fish if they’re partly out of water. Some mosquitoes will even bite caterpillars. Caterpillars don’t have blood, but they do have hemolymph, which is just as nutritious to the mosquito.

Occasionally mosquitoes are found in amber, which as you may recall from episode 108 is fossilized tree resin. The oldest known was found in 79-million-year-old amber, so that means that yes, it could have bitten a dinosaur. But even if it still contained genetic material from dinosaur blood, and even if scientists were able to extract the dinosaur genetic material, it would be damaged DNA. Without a full genome of that particular dinosaur to compare against, we wouldn’t be able to repair the DNA sufficiently to actually clone a dinosaur. But we might be able to clone the actual mosquito and compare it to modern mosquitoes to learn more about them! It’s not as exciting as a dinosaur, but on the other hand there’s not a lot of danger of being stomped on or eaten by a mosquito.

You can find Strange Animals Podcast online at strangeanimalspodcast.blubrry.net. That’s blueberry without any E’s. If you have questions, comments, or suggestions for future episodes, email us at strangeanimalspodcast@gmail.com. If you like the podcast and want to help us out, leave us a rating and review on Apple Podcasts or just tell a friend. We also have a Patreon at patreon.com/strangeanimalspodcast if you’d like to support us that way.

Thanks for listening!

 

Episode 183: BEES! AKA honey and “honey”

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Thanks to Linnea for suggesting bees! Obviously we can’t learn about ALL 20,000 bee species in this episode, but we’ll learn about the honeybee and some other interesting bees!

Further reading:

Bee friendly? Pollinating California’s almond crop

The vulture bee

Western honeybees on a honeycomb:

A vulture bee thinking about “honey”:

The wholesome, solitary ivy bee:

Show transcript:

Welcome to Strange Animals Podcast. I’m your host, Kate Shaw.

It’s August and we’re kicking off a full month of our spineless friends! That’s right, it’s Invertebrate August, and to get us started, we’re going to learn about some really interesting bees. Thanks to Lynnea for the topic suggestion and some great links!

Bees live all over the world and there are thousands of species, something like 20,000 of them. The only place in the world that doesn’t have any bees is Antarctica, which doesn’t have much of anything.

When most of us think of bees, we think of the honeybee. The honeybee is one of the few invertebrates that are domesticated. People really like honey, and at some point humans realized that if they made pets of the bees that make honey, getting at the honey was a lot easier on both the people and the bees. We know that ancient Egyptians had already domesticated the western honeybee because there are tomb paintings of beekeepers and hives.

The honeybee is native to Europe and Asia, and there are about 30 species. The western honeybee is the most widespread. It lives in a structured colony with a queen, worker bees, and a few drones. The worker bees are all females but they don’t mate and lay eggs. Only the queen is fertile, and the drones are males who mate with the queen. Different worker bees have different roles in the hive. Some gather nectar and pollen from flowers, while some take care of the queen’s eggs and babies or build new honeycombs. All worker bees have stingers, which they use to defend the hive. Honeybees are striped yellow and black to warn other animals that they’re dangerous.

Worker bees make honey by partially digesting nectar, then spreading it in empty honeycomb cells to partially dry. When it’s the right consistency, the workers cap the cells. Honey is antibacterial and anti-fungal and will last pretty much forever in the hive. Eventually it will crystallize, though, and the bees will remove crystallized honey from the hive since they can’t eat it that way. Bees make honey to eat, and they need lots of it so they have extra for wintertime and bad weather when the bees stay inside.

In the wild, the honeybee builds its nest in crevices, such as a hollow tree or the rafters of your attic. Worker bees secrete wax from glands on the abdomen and use it to build honeycomb, which is a sheet of hexagonal cells. Hexagonal means six-sided, and each cell does have six sides. A hexagonal shape is the most efficient use of materials, since each side of the hexagon is shared with another cell instead of the bees having to make six sides for each cell. When they finish making one cell, they’ve already got one side made for six other cells that will adjoin that first cell, sort of like the walls separating rooms in your home.

The queen bee lays her eggs in honeycomb cells. An egg hatches into a larva and is fed by worker bees. All bee larvae get fed a secretion called royal jelly for the first three days after hatching. Royal jelly is high in protein. After three days, most larvae will only get fed a mixture of pollen and nectar called bee bread. The only exception is if the colony has eggs that are intended to grow into new queens. Queen bee larvae continue to get fed royal jelly, since they need the extra protein. The established queen bee of the hive also eats royal jelly.

Honeybees who live in an area with lots of flowers can produce so much honey that they completely fill up their hive. In domesticated bees, that’s when the beekeeper harvests the honey, and will usually return the emptied honeycombs to the hive for the bees to reuse. In bees living wild, if the colony stores so much honey that it’s running out of room for eggs, this will trigger a swarm. The queen leaves with about half the worker bees to find a new home. The workers who remain will continue to feed royal jelly to the newly hatched larvae, which means they develop into new queen bees. The workers have to modify the honeycomb cells for queen bees, which are bigger than other bees and don’t fit in an ordinary-sized cell.

The queen bee larvae pupate and metamorphose into mature bees. New queens chew an opening in their cells, which the worker bees have sealed shut, and each immediately fights all the other new queen bees. If one queen emerges before the others, she will kill the others before they have even finished metamorphosing.

The surviving queen takes over, but she can’t lay eggs that will develop into worker bees yet. She has to mate first. If you listened to episode 175 where we talked about flying ants, you’ll remember that in some species of ant, new queens have a nuptial flight where they mate with males, then store the sperm they collect to use for the rest of their life. Honeybees do this too. When weather conditions are right, the new queen will leave the hive and release pheromones that attract males from various hives in the area. A queen may have several nuptial flights before she has collected enough sperm, which she keeps in a special organ in her body. Then she returns to her hive to start laying eggs that will develop into new worker bees.

Bees are important as domesticated animals not just because we all like honey, but because bees are really good pollinators. The honeybee, and some other bees, have a structure often referred to as a pollen basket on the rearmost legs. It’s a sort of divot in the leg, like a built-in pocket, surrounded by hairs. As the bee crawls around on a flower collecting nectar, pollen sticks to its fuzzy body. The bee gives its front legs a lick and uses them to brush the pollen from its body, then presses the pollen into its pollen baskets. But, of course, it can’t get every grain of pollen off, and some of it rubs off onto the next flower’s stigma, pollinating it.

Some crops, like almonds, depend on beekeepers who bring hives of bees to each orchard in spring. The bees pollinate the almond flowers so they can develop into delicious almonds, which makes the orchard owners happy, and they collect lots of nutritious pollen, which makes the bees and beekeepers happy. Some beekeepers move their bee hives from place to place every spring to help farmers pollinate various crops, but the almond crop is a big deal since the California orchards produce more than 80% of the world’s almonds every year. Beekeepers depend on the money they receive from orchard owners to bring their bees to the orchards, and the orchard owners depend on those bees to make sure there are lots of almonds to harvest later in the year.

But increasingly, there aren’t enough honeybees to pollinate the expanding almond orchards. Colony Collapse Disorder has been known for over a century under various names, but it’s been on the increase since around 2006. A colony will be fine, and then suddenly almost all of the worker bees will just leave and never return. The queen and a few worker bees stay behind. It’s like the opposite of a swarm. It was once known as disappearing disease, but it doesn’t appear to be an actual disease that bees can catch.

Researchers still don’t know what precisely causes colony collapse. The bees left behind are healthy and the hive contains plenty of food. And the disorder doesn’t just happen in one place or one country, it’s happening all over, especially in North America, Europe, and Asia, where the western honeybee is most commonly kept by beekeepers.

It’s probable that a number of factors contribute to colony collapse, from pesticide use and climate change to declining biodiversity and known honeybee parasites and diseases. Researchers suggest that a colony that’s already under stress due to one or more of these factors is less healthy to start with, and the addition of another stress factor can cause worker bees to abandon the hive. Pesticides, herbicides, and fungicides seem to be major contributing factors.

Entomologists, beekeepers, almond farmers, and many others are working to learn more about what causes colony collapse disorder. In the meantime, they’re trying lots of things to improve bee health in general. Many almond farmers have stopped spraying insecticides on their trees until after the bees have finished pollinating the almond flowers, and those who do have to use insecticides make sure they use kinds that are minimally harmful to bees and then they only spray at night when the bees are safely in their hives. Some farmers have started growing weeds and other flowering plants near the almond trees to attract wild bees, which reduces their dependence on domesticated honeybees.

So do other species of bee produce honey? Nope, only honeybees produce honey. Oh, and the honey wasp. That’s right, there are a few species of wasp that produce honey that’s very similar to that made by honeybees. The wasps are native to Central and South America, with one species living in parts of southwestern North America. They prefer humid forests, including rainforests, and they make paper nests in trees the same way many other wasps do. They eat the honey but they also eat nectar and other insects. They’re actually beneficial to farmers since they eat lots of crop pests like boll weevils and leaf miners. They also help pollinate plants. But they are definitely not domesticated and they will sting you like whoa, and they also don’t produce very much honey compared to honeybees.

Most bees eat nectar and pollen, but will sometimes also eat juice from fruit they might happen to find. But the vulture bee eats meat from dead animals, just like a tiny vulture with six legs. It’s a tropical bee that lives in parts of North America, and not only is it related to the honeybee, it actually makes honey. Sort of. It’s not vegetarian honey, let’s put it that way.

There are three species of vulture bee, all of which have been known to science for centuries, but no one realized they ate meat until 1982. The vulture bee has also lost its pollen baskets, since it lives in areas where pollen is hard to come by. That’s why it eats meat instead, since it supplies the bees with protein in the absence of nutritious pollen.

If a vulture bee can’t find a dead animal to eat, it will sometimes sneak into wasp nests and eat young wasps. Since wasps often do the same thing to bees, that seems fair. Oh, and the vulture bee doesn’t have a sting.

The vulture bee’s mandibles have sharp tooth-like points that help them cut into meat. When a bee finds a dead animal, it will actually burrow into the carcass through its eyes. It also releases pheromones that help the other bees from its colony find the carcass. The bees can strip a carcass the size of, say, a big frog, in a few hours and will even chase flies away.

But the vulture bee can’t digest the meat, not as it is. It uses saliva mixed with nectar it’s eaten to break the meat down into a liquid, which it slurps up and brings back to the hive. Like honeybees partially digesting nectar, the vulture bee partially digests the liquefied meat, which mixes it with enzymes from the bee’s body. Then it regurgitates the liquid to dry in honeycomb cells until it has the consistency of honey, which it is. But I would not eat it.

It turns out that when a bee larva pupates, it spins a cocoon. Even honeybees and other social bees do this, despite the fact that they pupate in cozy little hexagonal cells. And it turns out that the silk that social bees and ants spin to make the cocoon is very different from spider and moth silk. The proteins that make up the silk consist of coiled strands that are also coiled around each other, making the silk incredibly strong but still light-weight. Spider and moth silk is much smoother since it’s made up of a larger protein that is sort of a sheetlike structure.

Since there are so many species of bee in the world, there’s simply no way I can do more than scratch the surface of knowledge and this episode is already getting long. We haven’t even talked about mason bees, and I’d planned to focus on them this time but got sidetracked by honeybees! We’ll save mason bees for another time, but let’s finish up with a solitary bee—that is, a type of bee that doesn’t live in colonies.

The ivy bee lives throughout much of Europe, including the UK, and is a fairly large bee. The female grows to around 13 millimeters long on average although males are smaller. At first glance it looks like a big honeybee but has more vivid black and yellow-orange stripes on its abdomen. If you remember episode 160, where we talked about the Osima avosetta bee that makes her nest out of flower petals, the ivy bee will seem familiar to you. The female digs little nests in the ground to lay her eggs in, one egg per nest, and she leaves nectar and pollen for the babies to eat when they hatch. Then the larvae pupate and emerge as adults in late summer.

The ivy bee gets its name because it mostly eats the pollen and nectar of the ivy plant, which flowers in autumn. Hundreds of ivy bees may swarm over a bank of ivy but they’re not dangerous at all. The bees help pollinate the ivy flowers, which in turn means that there will be plenty of ivy berries in winter for birds to eat. The birds eat the berries but poop out the seeds, which means more ivy will grow. Teamwork!

Quite often you’ll hear people talk about saving the bees, and that’s important. Wild bees of all kinds are declining in number due to habitat loss and pesticides. The best thing you can do to help is to plant flowers, especially flowers native to your area. Even if you can only plant a small flower garden, you will definitely be helping your local wild bees—and butterflies, moths, and other beneficial insects. Teamwork again! You can be part of the bee team!

You can find Strange Animals Podcast online at strangeanimalspodcast.blubrry.net. That’s blueberry without any E’s. If you have questions, comments, or suggestions for future episodes, email us at strangeanimalspodcast@gmail.com. If you like the podcast and want to help us out, leave a rating and review on Apple Podcasts or wherever you listen to podcasts. We also have a Patreon at patreon.com/strangeanimalspodcast if you’d like to support us that way.

Thanks for listening!

Episode 180: Synchronous Fireflies

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Thanks to Adam for the great suggestion of synchronous fireflies! Let’s learn about lightning bugs (or fireflies) in general, and in particular the famous synchronous fireflies!

Further reading:

How Fireflies Glow and What Signals They’re Sending

Further watching:

Tennessee Fireflies

Synchronizing Fireflies in Thailand (it shows an experiment to encourage the fireflies to start blinking by the use of LEDs)

Show transcript:

Welcome to Strange Animals Podcast. I’m your host, Kate Shaw.

This week we’re going to learn about a bioluminescent insect, the firefly, also called the lightning bug, but we’ll especially learn about a specific type of various species called synchronous fireflies! This is a suggestion from Adam, so thank you, Adam!

Fireflies are beetles and they’re common throughout much of the world. I actually call them lightning bugs, but firefly is faster to say so I’m going to use that term in this episode. They’re most common in temperate and tropical areas, especially around places with a lot of water and plant cover, like marshes and wooded streams. This is because the firefly spends most of its life as a larva, and it needs to be able to hide from predators and also find the tiny insects, snails and slugs, worms, and other small prey that it eats. Adults of some species don’t eat at all and may not even have mouths, while adults of other species may eat nectar, pollen, or other insects.

There are probably two thousand species of firefly, with more being discovered all the time. While they vary a lot, all of them emit light in one way or another. We’ll talk about how they produce the light in a minute, but first let’s talk about why they light up. In many species, the larvae can light up and do so to let predators know they taste bad. The larvae are usually called glowworms, although that name is also applied to other animals.

Some firefly species don’t light up at all as adults, but many species use their lights to find a mate. Every species has a distinct flash pattern. In some species, the female can’t fly but will sit on the ground or in foliage and watch for her species’ flash pattern from males flying around. When she sees a male she likes, often one whose light is brightest, she signals him by flashing back. Sometimes a pair will flash back and forth for hours, sometimes just minutes, but eventually the male will find the female and they will mate.

As a result, the firefly is sensitive to light pollution, because it needs to see the flashing of potential mates. If there’s too much light from buildings and street lamps, fireflies can’t find each other. They’re also sensitive to many other factors, so if you have a lot of fireflies where you live, you can be proud to live in a healthy ecosystem. But overall, the number of fireflies are in decline all over the world due to habitat loss and pollution of various kinds.

So how does a firefly light up? It’s a chemical reaction that happens in the lower abdomen in a special organ. The organ contains a chemical called luciferin [loo-SIF-er-in] and an enzyme called luciferase [loo-SIF-er-ace], both of which are found in many insects that glow, along with some other chemicals like magnesium. The firefly controls when it flashes by adding oxygen to its light-producing organ, since oxygen reacts with the chemicals to produce light.

Female fireflies in the genus Photinus, which are common in North America and other areas, can’t fly and instead look for potential mates to fly by. When a male sees a female’s answering flash, he lands near her. But sometimes when the male lands, he’s greeted not by a female Photinus but by a female Photuris firefly. Photuris females often mimic the flash patterns of Photinus, and they do so to lure the males close so they can EAT THEM. Photuris is sometimes called the femme fatale firefly as a result. Some species of Photuris will also mimic the flash patterns of other firefly species, so they don’t specifically pick on Photinus. Also, these names are way too similar. Photuris will even grab and eat fireflies that are caught in spiderwebs, stealing from the spider. I like to imagine these femme fatale fireflies with tiny guns and slinky 1950s-era dresses.

But the really interesting thing is that these femme fatale fireflies aren’t just hungry. They belong to species that can’t manufacture the toxic compounds that other fireflies do. After a female Photuris has mated, she needs this compound to protect her eggs when she lays them, so she gets it by eating fireflies that do produce the compound.

Fireflies vary in size, but they’re generally quite small, with the biggest only about an inch long, or 2.5 cm. They’re usually brown or black, sometimes with orange, red, or yellow markings on the head and yellow streaks on the wing covers. They also have a weird smell, which is probably related to this toxic compound. It’s a type of steroid that’s chemically similar to the toxins excreted by some poisonous toads. In one fantastic article I found online, which I link to in the show notes, the writer says, “A colleague of mine once put a firefly in his mouth—and his mouth went numb for an hour!” In other words, don’t eat fireflies even if you’re a frog or a bird.

In many areas, larval fireflies hibernate during the winter, in underground burrows or under tree bark. Once a larva pupates and transforms into an adult, it only lives a matter of weeks. It mates, lays eggs, and dies.

There is an exception, of course. The winter firefly lives in much of North America and actually overwinters as an adult. It lives in tree bark in the winter, coming out in early spring. But the adult winter firefly doesn’t light up. It’s not even nocturnal like most other species. It comes out during the day and the male finds a mate by following the trail of pheromones released by the female. It eats tree sap and is especially attracted to sap buckets when people are tapping maple trees to make maple syrup, which is why it’s also sometimes called the sap bucket beetle. It mates and lays its eggs in spring, then dies. Larvae pupate in late summer so that new adults have several months to build up energy reserves to get them through the winter.

Synchronous fireflies are native to Southeast Asia and the eastern United States, from Georgia to Pennsylvania. There are several famous sites in the United States for synchronous fireflies, including one that’s very close to me, at Elkmont in the Great Smoky Mountains National Park. There are 19 species of firefly in the park, but only one, Photinus carolinus, flashes synchronously. So many people want to see the display that the park has to have a lottery to see who gets tickets. I’ve never been to see the synchronous fireflies, but I have seen synchronous fireflies, at a spot only a five-minute drive from my house.

WHAT?, you may be thinking, if you know anything about synchronous fireflies. There are only like three spots in the United States where these fireflies live! But this actually isn’t the case. In 2015 another species was discovered in East Tennessee, specifically in the Oak Ridge Wildlife Management Area. I remember reading an article about it and contacting the scientist quoted in the article, because I already knew of some synchronous fireflies near my house. No one else seemed to know about them but me.

I looked for the email I got in response, but unfortunately I must have deleted it at some point. This was way before I’d started the podcast so I didn’t think I’d ever need to refer to it. All I remember is that the scientist’s last name was also Shaw and that he said he’s sure there are lots of small pockets of the synchronous fireflies in East Tennessee and surrounding areas, and that they were a different species from the ones in the Smokies, with a different flashing pattern.

And indeed, there are two species of synchronous fireflies in the United States, Photinus carolinus and Photuris frontalis. Photuris is the one I’ve seen. But there’s also a third species of synchronous fireflies in the United States, but it’s only found in Arizona. The species is Photinus knulli, but it’s rare and doesn’t congregate in huge numbers.

The synchronous fireflies found in mangrove forests and other forested areas in southeast Asia are much more common than the species found in the United States, and flash year-round instead of for only a few weeks in summer. I have a couple of links to synchronous fireflies in the show notes, one of them in Tennessee and one in Thailand. The Thailand video is better since you get a better idea of how in synch the fireflies are. In that case, as the video shows, the fireflies were encouraged to start their light show by an experiment with computer-controlled LEDs hidden in a few trees.

So the videos are good, but what do synchronous fireflies really look like when you’re there in person? I mean, it’s easy to say that all the fireflies light up at once and it’s beautiful, but I’ve seen them and this doesn’t even start to explain how amazing it looks. The videos are accurate but let me try to describe my experience.

The ones I’ve seen live in a very small part of the local watershed, on the hillside above a stream called Clear Creek. They only live on one side of the stream, which fortunately is the side where there’s a hiking trail. It’s amazing because you can look across the creek and see just ordinary fireflies flashing, then turn around and see a spectacular lightshow. And even though it’s literally a few minutes’ walk from a little parking lot, I don’t think anyone but me has ever noticed.

They only flash in mid-June when the days are long, so you have to be out late to see them, around 10pm or later. The first time I saw them I was out hiking and went farther than I’d intended, so it was dark when I was approaching the parking lot.

In East Tennessee on a summer evening, it’s dark under the trees but the sky still holds a little light, so that when you look up through the tree canopy you see patches of dark blue. On this particular stretch of trail, it’s dangerous to walk too fast because there are lots of roots and rocks that you can trip over in the dark. So imagine you’re walking along with just enough light from the sky to tell where the trail is. Clear Creek is to your left, broad and shallow here. You can hear it gurgling over rocks. To your right, the ground rises steeply—not too steep to climb if you wanted to, but too steep to bother.

It’s a summer evening, so of course there are fireflies. You don’t pay any attention until you notice something unusual to your right, on the hillside beneath the trees.

That’s funny, three or four fireflies flashed at exactly the same time. But now that your attention is on the hillside, you see another flash as dozens of fireflies light up at the same time. And a few seconds later, when it happens again, you realize that it’s ALL the fireflies on the entire slope—hundreds of them!

At a distance, the flashing looks like a gold-tinted glitter of light, not a glow. Hundreds of tiny glittering lights blink on and then immediately off, so that the entire hillside looks like it’s covered with tiny electric bulbs winking on and off. The flashes come in groups, two or three flashes in a row over the course of several seconds, then a pause, then more flashes. The fireflies on one side of the hill are slightly out of synch with those on the other side of the hill so that the flashing seems to travel in a wave across the hillside. It’s so beautiful you can hardly believe what you’re seeing. It doesn’t even seem real.

One thing I’ve noticed, after being lucky enough to witness this amazing sight several summers in a row, is that the flashing doesn’t fully synchronize until it’s really dark. If I get there too early, I can see the fireflies are trying, but they aren’t quite in time yet. It has to be dark enough for them to really be able to see each other.

So why do some fireflies synchronize their flashing while most don’t? Researchers aren’t sure, but the best guess is that by flashing all together, it’s easier for females to compare males and choose which male they want to mate with. The males may also be trying to keep other males from flashing before they do, which means they eventually all synch up.

It really is an amazing sight. If you’re ever going to be in East Tennessee in June, let me know and I’ll take you out to see my fireflies, or you can sign up to see the really big displays in the Smokies or other areas. Until then, hopefully my description will help you imagine it.

This is what a firefly sounds like. HA, fooled you, they don’t make any noise at all.

You can find Strange Animals Podcast online at strangeanimalspodcast.blubrry.net. That’s blueberry without any E’s. If you have questions, comments, or suggestions for future episodes, email us at strangeanimalspodcast@gmail.com. If you like the podcast and want to help us out, leave a rating and review on Apple Podcasts or wherever you listen to podcasts. We also have a Patreon at patreon.com/strangeanimalspodcast if you’d like to support us that way.

Thanks for listening!