Complex Animals: Annelids & Arthropods - CrashCourse Biology #23
Summary
TLDRThis script from Crash Course Biology explores the significance of annelids and arthropods, two of the most successful animal groups on Earth. It delves into their evolutionary traits, such as segmentation and synapomorphies, and highlights the diversity within these groups, from earthworms and leeches to insects and crustaceans. The video script also touches on the importance of these creatures in maintaining soil health and plant life, emphasizing the interconnectedness of all life on our planet.
Takeaways
- 🪱 Earthworms process about 16,000 pounds of soil per acre per year, making plant life possible.
- 🦟 80% of known animal species are arthropods, with approximately a billion billion of them worldwide.
- 🐛 Segmentation is a key evolutionary trait in Annelida, Arthropoda, and Chordata, indicating complexity.
- 🧬 Annelids, such as earthworms, leeches, and lugworms, exhibit clear segmentation in their bodies.
- 🔬 Synapomorphies are traits that set one group of animals apart from others, such as segmentation in Annelids.
- 🐍 Arthropods have segmented bodies, exoskeletons made of chitin, and paired, jointed appendages.
- 🕷 Cheliceriformes, including spiders and scorpions, have long fang-like pincers, simple eyes, and lack antennae.
- 🐜 Hexapoda, primarily insects, have three-part bodies, three pairs of jointed legs, compound eyes, and antennae.
- 🦋 Complete metamorphosis in insects allows for a dramatic transformation from larva to adult.
- 🦞 Crustaceans, such as crabs and lobsters, have three body segments and some have developed bioluminescence.
Q & A
Why do the narrator's distant relatives earn their respect?
-The narrator respects them because they are among the most successful organisms on Earth, processing large amounts of soil and being crucial for plant life and, consequently, human life.
What is the significance of annelids in cultivated land?
-Annelids like earthworms process about 16,000 pounds of soil per acre each year, making plant life and human life possible by aerating the soil and enriching it with nutrients.
How do arthropods compare to humans in terms of numbers and complexity?
-There are about a billion billion arthropods on Earth, and they make up 80% of known animal species. Although they outnumber humans, humans are far more complex in terms of physical and cognitive abilities.
What are the two traits that indicate an animal's relative complexity?
-The two traits are the number of germ layers they develop as embryos and whether they have a coelom, a body cavity that holds their organs.
What is segmentation, and why is it important in animal evolution?
-Segmentation is the repetition of anatomically identical units that can be modified for different purposes as animals evolve. It has proven to be extremely useful from an evolutionary perspective, allowing for diversity and specialization.
Which three major animal groups display segmentation?
-The three major groups are Annelida, Arthropoda, and Chordata, which include the vertebrates.
What are synapomorphies and plesiomorphies?
-Synapomorphies are traits that set a group of animals apart from their ancestors and other related groups, while plesiomorphies are very basic traits shared by animals with a common ancestry.
What is a key synapomorphy of annelids?
-A key synapomorphy of annelids is their segmentation, as their bodies look like rings fused together, and they also have chaetae (bristles) for movement.
How do arthropods' segmented bodies contribute to their diversity?
-Early arthropods had little variation between segments, but as they evolved, segments fused and specialized for different functions, leading to a great diversity of forms like scorpions, butterflies, and lobsters.
What are the defining characteristics of arthropods?
-Arthropods have segmented bodies typically divided into a head, thorax, and abdomen, an exoskeleton made of chitin, and paired and jointed appendages.
Outlines
🌏 The Dominance of Earthworms and Arthropods
This paragraph introduces the earthworm and its significant role in soil processing, which is vital for plant and human life. It emphasizes the sheer number of arthropods on Earth and their diversity, highlighting that 80% of known animal species fall into this category. The speaker points out human complexity in activities like arm wrestling and playing the guitar, but notes that the foundation of such complexity started with a shared trait with these simpler organisms. The paragraph delves into the concepts of germ layers and coelom in embryonic development, and introduces segmentation as a key trait in the evolution of complexity, particularly in Annelida and Arthropoda phyla. It also touches on the shared ancestry of segmented animals, dating back to about 600 million years ago.
🐛 The Evolutionary Advantages of Segmentation in Annelida and Arthropoda
The second paragraph explores the concept of segmentation in more detail, explaining it as a trait that allows for the repetition and modification of anatomical units, which is crucial for evolutionary adaptability. It identifies Annelida as the earliest phylum to exhibit segmentation, with earthworms, leeches, and lugworms as examples. The paragraph also discusses synapomorphies, which are shared derived traits that distinguish a group from its ancestors, and plesiomorphies, which are basic traits shared by animals with a common ancestry. The speaker provides examples of synapomorphies in annelids, such as chaetae for traction, and delves into the different classes within Annelida, including oligochaetes, hirudinea, and polychaetes, each with their unique characteristics.
🦋 The Incredible Diversity and Evolution of Arthropods
This paragraph focuses on the Arthropoda phylum, which includes an immense variety of species due to the specialization of body segments. The speaker discusses the synapomorphies of arthropods, such as segmented bodies, exoskeletons made of chitin, and paired, jointed appendages. The paragraph then breaks down the phylum into four subphyla, starting with Cheliceriformes, which includes spiders, scorpions, and horseshoe crabs, and highlights their unique features like the cephalothorax and the absence of antennae. Myriapoda is next, with millipedes and centipedes, characterized by their numerous legs and terrestrial lifestyle. Hexapoda, mostly insects, is noted for its vast number of species and the unique evolutionary path that led to their current diversity. Lastly, Crustacea is mentioned, which includes marine creatures like crabs and lobsters, known for their complex appendages and bioluminescence in some species.
Mindmap
Keywords
💡Annelids
💡Arthropods
💡Segmentation
💡Coelom
💡Synapomorphy
💡Plesiomorphy
💡Chordata
💡Oligochaetes
💡Myriapoda
💡Metamorphosis
💡Crustaceans
Highlights
Earthworms and other annelids are among the most successful organisms on Earth, processing about 16,000 pounds of soil per acre annually.
Approximately 80% of known animal species are arthropods, which include a vast diversity of creatures like insects, spiders, and shrimp.
Despite their numerical dominance, simpler organisms lack the complexity of humans in areas such as physical strength, musical ability, and cognitive tasks.
The concept of segmentation in animal evolution, where anatomically identical units are repeated and modified, is a key factor in increased complexity.
Annelida, Arthropoda, and Chordata are the three most diverse and largest groups of animals, all of which exhibit segmentation.
All segmented animals share a common ancestor that lived around 600 million years ago, highlighting a deep evolutionary connection.
In humans, segmentation is evident in anatomical structures such as vertebrae, ribs, and the folds in our brains, which have evolved from simple to complex forms.
Annelida, including earthworms, are the earliest phylum to display segmentation, characterized by their ring-like body structure.
Synapomorphies, such as chaetae bristles in annelids, are traits that distinguish a group of animals from their ancestors and other related groups.
Plesiomorphies, like the worm-shaped body of Platyhelminthes, Nematodes, and Annelids, indicate a shared ancestry among these groups.
Oligochaetes, a class within Annelida, are known for their role in soil aeration and nutrient cycling, contributing to plant growth.
Hirudinea, or leeches, are characterized by their powerful suckers and are mostly parasitic, feeding on blood and bodily fluids.
Polychaetes are marine worms with many bristles, known for their diversity and contribution to the beach environment through their castings.
Arthropods' success is attributed to their segmented bodies, which have evolved to become specialized for various functions, leading to great diversity.
Arthropods share several synapomorphies, including a segmented body, an exoskeleton made of chitin, and paired, jointed appendages.
Cheliceriformes, including spiders and scorpions, are distinguished by their lack of antennae and presence of fang-like pincers.
Myriapoda, such as millipedes and centipedes, are known for their numerous legs and terrestrial lifestyle, with millipedes being early land dwellers.
Hexapoda, primarily insects, are characterized by their three-part bodies, compound eyes, and antennae, showcasing the vast diversity within this group.
Insects have evolved the ability to fly, which has been crucial to their success, and have developed metamorphosis as a life cycle strategy.
Crustaceans, such as crabs and lobsters, have adapted to aquatic environments with unique characteristics like bioluminescence and multifunctional appendages.
Transcripts
Hey there, I'm just hanging out with some distant relatives here.
I've got to say I've got a lot of respect for these guys,
because they are some of the most successful organisms on the earth.
We think we run things on this planet, but we don't.
They do.
On one acre of cultivated land, annelids like this earthworm
process about 16,000 pounds of soil a year, which makes plant life
and our lives
therefore, possible.
And not only are there about a billion billion arthropods
like this in the world, that's 10 to the 18th power by the way,
but also 80% of known animal species are arthropods.
Now, don't get me wrong, even though bugs and spiders
and worms and shrimp totally outnumber us humans,
we are far more complex than them.
When it comes to arm wrestling and guitar playing
and long division, we'd totally school them.
But complexity like ours had to start somewhere.
And it started with a very special trait
that we share with these animals.
Can you see the resemblance?
Last time we talked about how, in the very simplest animals,
there are two traits that indicate an animal's relative complexity:
there's how many germ layers they develop when they're embryos
and whether or not they have a coelom, or body cavity
that holds their organs.
So it's in the next two phyla, Annelida and Arthropoda, where we
find the new big thing in animal complexity: segmentation.
Segmentation is the repetition of anatomically identical units
that can be added to and modified to serve different purposes
as animals evolve.
And evolution is the way to win it, folks.
In fact, the three biggest and most diverse groups of animals
in the world are the ones that display segmentation:
Annelida, Arthropoda and Chordata, which includes the vertebrates.
All segmented animals have a common ancestor
that probably lived about 600 million years ago.
That's how long ago it was when one of your grandparents
and one of the earthworm's grandparents
and one of the beetle's grandparents
all played on the same softball team.
Pretty crazy.
Segmentation has proven to be unbelievably useful
from an evolutionary perspective.
In humans, you see anatomically identical pieces repeated
along an axis from our butts to our heads.
They can be a little hard to see because they're so highly modified,
but think about our vertebrae: They're segments!
Our ribs are segments!
The cartilage around our trachea? Those are segments!
Even the folds in our brains are segments.
They're crazy-evolved segments, but segments just the same.
Among today's animal phyla, the earliest to display segmentation
is Annelida, which includes leeches, earthworms and lugworms.
See how their whole bodies look like rings fused together?
Segments!
In fact, the word Annelida comes from the Greek for "little rings,"
and when you look at any annelid, you see that they're all
really obviously segmented.
Now, this segmentation is a great example
of synapomorphy in annelids.
Synapomorphies are traits that set one group of animals apart from its
ancestors and from other groups that came from the same ancestors.
So unlike their flatworm and nematode cousins,
Annelids are segmented and they've also got little bristles
on their bodies called chaetae that provide traction
and help them move through the dirt.
These are both little extra somethings that annelids' have,
that less complex relatives don't have and that their common
ancestors didn't have.
Synapomorphies, literally "shared derived traits,"
are usually the defining traits of a phylum.
But you can also learn something about an animal's lineage
by comparing plesiomorphies, very basic traits
that are shared by animals with a common ancestry.
So, between the Platyhelminthes, the Nematodes and the Annelids,
one plesiomorphy is that they're all worm-shaped,
which tells you they have a common, distant, ancestor
that was wormy-lookin'.
So as we talk about these phyla and the classes within them,
notice how they're similar and different from each other.
For instance, within Annelida, there are three different classes.
Everybody's favorite, of course, is the oligochaetes, the earthworms
Their name refers to the synapomorphy I just mentioned:
they have "chaetae", or bristles,
but only an "oligo", few of them.
And they're everyone's favorite because they eat soil and crap
it out the other end, allowing air and water
to circulate in soil.
Plus their poo is rich in things that plants need to grow,
like nitrogen, calcium, magnesium, and phosphorus.
And now i'm going to go wash my hands.
Now on to the class Hirudinea, the leeches,
a lot of which are parasitic and, you know, eat
blood and other bodily fluids.
A synapomorphy of leeches are their powerful suckers
they've got them on both ends of their body,
the posterior one being used to anchor itself while the
anterior one that surrounds its mouth attaches to its host.
All leech species are carnivorous and they are hermaphrodites
like earthworms.
Now, the Polychaetes are bristly worms, hence a synapomorphy
of this class is their "poly" (many) "chaete" (bristles).
Almost all of these are marine species,
and they're really diverse, but the ones you've probably seen
evidence of are the lugworms, the ones that dig holes
at the beach and leave piles of castings on the sand.
Okay, I know you've had enough of worms.
Now we've got Arthropoda to talk about, and that's not
very easy to do because there are A LOT of them.
Like I said, they totally outnumber us.
Just to put things into perspective, there are more
insects in a square mile of rural land than there are
human beings on the earth.
One reason scientists think arthropods do so well has to
do with their—
you guessed it!
-segmented bodies.
Fossils of early arthropods show that there used to be
very little variation between segments, but as they evolved,
segments fused and became specialized for different
functions, which led to crazy amounts of diversity.
So much diversity that Arthropoda includes stuff like scorpions,
butterflies and lobsters.
Which...I know.
Seems like maybe a bit of a stretch.
But here are the synapomorphies that make them all arthropods:
1. They have segmented bodies that, in most cases, are broken up into
three segments: head, thorax and abdomen.
And check this out: Here, segmentation in arthropods
is a good example of a plesiomorphy.
It's a basic, ancient trait that they share
with annelids and us chordates, for that matter,
dating back to that softball game our forebears played
some 600 million years ago.
2. All arthropods have an exoskeleton: a hard outer shell
made out of chitin, which is a really tough carbohydrate that's
chemically similar to the cellulose that you find in plants,
and in order to grow bigger they have to shed it.
And be glad that you don't have to do that.
Because it looks like kind of a traumatic experience for them.
3. Finally, they've all got paired and jointed appendages,
which is actually where their name comes from:
arthropod means "jointed feet."
But it's not just their legs that are jointed. Some of them have
claws and jointed antennae, and they all have these
external mouthparts that are also jointed.
So that's what all arthropods have in common, but they are
grouped into 4 subphyla, based on how they differ
from each other.
First, and perhaps most terrifying, you have your Cheliceriformes,
which includes spiders and scorpions, but also
horseshoe crabs which are kind of nice,
and ticks, which aren't
and mites, which don't bother you at all,
probably...
they might.
Cheliceriformes comes from the Greek for "arm-lips," which--
Whatever, Greeks...
refer to their long fang-like pincers.
Unlike a lot of arthropods, they have simple eyes with
just one lens, not compound eyes like flies, and they lack antennae.
Most Cheliceriformes are landlubbers, but the fossil record
tells us that a lot of them were marine back in the olden days.
Sea spiders and horseshoe crabs are the only ones left now.
The largest class of Cheliceriformes are
the arachnids, the group that includes spiders, scorpions,
ticks and mites.
They have what's called a cephalothorax, which is a
head segment and a thorax segment fused together,
with eight legs and an abdomen behind.
Most arachnids are carnivorous or parasitic and they're
very skittery.
Just sayin'.
Next, Myriapoda, or "many feet," includes what you would expect:
the millipedes and centipedes, these are where the arthropods
were like "let's see how far we can take
this segmentation thing, shall we?"
All Myriapods are terrestrial and have antennae and sort of
scary jaw-like mandibles.
Millipedes are vegetarians, and they may have been some of
the very first animals to live on land, where there
were mosses and primitive vascular plants for them to munch.
Also, although millipedes have a crap-ton of legs, they don't have
as many as a thousand, as their name implies.
They've actually got anywhere between 94 and 394 legs,
depending on the species.
Centipedes, whose name is a little more apt as they generally have
between 20 and about 350 legs, are carnivores and have
poisoned claws to paralyze their prey.
So, if you're looking to cuddle with a Myriapod,
I'm going to advise you to go with a millipede.
But please, save some love for Hexapoda, or "six feet,"
most of which are insects.
The synapomorphies they share are three-part bodies,
consisting of a head, a thorax, and an abdomen,
three pairs of jointed legs that come off the thorax,
compound eyes, and two antennae.
Now, think of any random way you could put these
characteristics together, and you'll probably come up
with something that exists.
Because, you guys, there are so many damn insects out there
you have no idea.
There are more species of insects than there are
all other animal species COMBINED.
Which is why I'm taking this opportunity to do a...
BIOLO-GRAPHY, The Insects Edition!
Very little is understood about the evolution of insects,
but scientists think that they probably split off
from their crustacean cousins about 410 million years ago.
And for tens of millions of years, insects and some
little skittery invertebrates were about the only land
dwelling animals.
About 320 million years ago, thanks to the high oxygen
levels of the Carboniferous period, some insects grew to be
terrifyingly big, like the Meganeura, which looked like a
dragonfly with a two-foot wingspan.
But since an insects' size is restrained by
their respiratory systems, as oxygen levels went down,
these massive insects couldn't circulate enough oxygen
to keep their gigantic bodies going, and they died off.
The next major milestone of insect history occurred
around 120 million years ago, which is when
most flowering plants evolved, and with it the
sweet spirit of cooperation that insects and flowering plants
still share to this day.
In fact, some insects and flowering plants have
co-evolved really neat pollination strategies
so that they basically evolved together,
which I think is really sweet.
And as a result of insect pollination,
flowering plants are now the overlords of the plant world.
And thus, everything smells nicer and looks prettier.
Thanks insects!
Insects are the only arthropods that have developed
the ability to fly, and it has served them well.
Insect's wings are just extensions of the cuticle of the thorax,
so unlike birds and bats which have to sacrifice walking legs
in order to evolve wings, insects are just as graceful
on the ground as they are in the air.
But in order to be so awesome, insects had to develop
this crazy thing called metamorphosis.
In partial metamorphosis, the young, called nymphs,
look exactly like the adult of the species,
and undergo a series of molts which allows them to get bigger
and bigger, but they look basically the same the whole time.
Most other types of arthropods do this, and some insects,
including grasshoppers and cockroaches.
However, complete metamorphosis is the process unique to some
insects that lets them completely change shape.
Maggots turn into flies, mealworms turn into beetles,
caterpillars turn into butterflies. The baby insect, called larva-
I have one right here, this is a rhinoceros beetle larva-
pretty gross!
hangs out and eats until it's time to
build a little case around itself called a pupa,
this is the rhinoceros beetle pupa, which is exceptionally creepy
[creepy laugh]
and the when it comes out of the pupa, it's fully grown.
Rhinoceros beetle! It's like, soft at first and then it's chitin
hardens up and it becomes the adult.
So insects are basically wizards, but not as delicious as Crustacea,
the insects of the sea!
Crustaceans include crabs, lobsters, shrimp, and barnacles,
and like insects, they have three body segments:
head, thorax and abdomen.
Although some, have a cephalothorax like spiders do.
While most other arthropods have learned to love the land,
very few crustaceans have.
They have decided to put their energy into developing
other amazing characteristics.
For instance, lobsters and crayfish are like walking multitools:
they have 19 pairs of appendages, some of which are claws,
some are mouthparts, some are regular old walking legs.
Some shrimp have evolved bioluminescence,
which is pretty much the most amazing thing any animal
can do as far as I can tell.
And this Yeti crab... looks like a Yeti.
And we've covered most of the types of animals on earth in, what?
10 minutes?
Well hopefully now you can see the resemblance between these guys.
I love my caterpillar.
Thank you for watching this episode of Crash Course Biology,
if you want to repeat anything that we went over or
do a little bit of review there's a table of contents
that you can click on.
Thank you to everyone who helped put this together
including all of our little animal friends,
and Brandon from the University of Montana
for coming out and helping us out with this.
And if you have any questions or ideas,
please leave them below in the comments
and tell me what you think we should name this one.
That's all. Bye!
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