Arthropods! Ch 28 Presentation
Common Characteristics of all Arthropods Typical arthropod: Segmented Coelomate with Bilateral symmetry Invertebrate with exoskeleton Jointed structures called appendages Appendage—any structure (e.g. leg, antenna) that grows out of the body of an animal In arthropods, appendages are adapted for walking, sensing, feeding, mating, etc. Arthropods are earliest known invertebrates to exhibit jointed appendages Joints allow for flexibility of rigid exoskeleton (think knight in suit of armor) Joints enable many uses for various appendages (e.g. mating in spiders, stinging in scorpions)
Exoskeletons Support and Protect Exoskeleton—hard, thick outer covering of protein and chitin In some species, exoskeleton is continuous over entire body, in others it is separate plates held together by hinges Exoskeleton supports internal tissues, provides places for muscle attachment In many terrestrial species, exoskeleton covered with waxy layer to minimize water loss In many aquatic species, exoskeleton reinforced with calcium carbonate
Oh no, it’s MOLTING! Why molt? Exoskeletons are heavy and thick (the larger the muscles, the heavier/thicker must the exoskeleton be), so weight is limited for arthropods Terrestrial and flying arthropods have thinner, lighter (but more fragile) exoskeletons but are less protected Molting—shedding the old exoskeleton (new soft skeleton formed underneath first) Animal takes in air/water and contracts muscles, which swell and split old skeleton Most arthropods molt 4-7x during lifetime before becoming adults Mid-molt, animals are vulnerable to predators, so many hide or remain motionless until their new skeleton hardens http://youtu.be/2A1i10ZIB-w http://youtu.be/ffo37DlH5DM http://youtu.be/4QIgW639Oog
Segmentation Most arthropods are segmented but do not have as many segments as worms In most groups, segments fused into three zones: Head, thorax, abdomen Sometimes head and thorax fused together into cephalothorax
Breathing Arthropods have efficient gas exchange—generally quick, active animals with high oxygen requirements Three types of respiratory structures: Gills Tracheal tubes Book lungs In some arthropods, gas exchange occurs across exoskeleton (so it must be thin and permeable) Aquatic arthropods use gills Land arthropods use either tracheal tubes or book lungs Most insects use tracheal tubes (branching networks of hollow air passages that carry air throughout body) Air enters and leaves body through openings on thorax and abdomen called spiracles Spiders and their relatives use book lungs, air-filled chambers with leaf-like plates (maximize surface area for gas exchange)
Tracheal Tubes and Spiracles Book Lungs Book Lungs
Acute Sensory Perception Why can arthropods respond so quickly to their environment? Strong muscular contraction Detect movement, chemicals and sound with antennae Antennae have odor and sound receptors that are used in communication with other members of species (spiders lack these) Pheromones—chemical odor signals given off by animals (signal animals to engage in variety of behaviors) Accurate vision: EYES Most arthropods have one pair of large compound eyes and 3-8 simple eyes Simple eyes- single lensed-structures for detecting light Compound eyes—visual structures with many lenses Each lens registers a tiny portion of the field of view, so the total image is made of thousands of parts (panoramic view)
What structures allow this damselfly to sense its environment? Eyes What structures allow this damselfly to sense its environment?
Well-developed Nervous Systems Arthropods process information from sense organs with well-developed nervous systems Consists of double ventral nerve cord (pearl necklace), an anterior brain, and several ganglia http://youtu.be/0uTdTRXNdEY
Arthropod Circulation Open circulatory system—blood is pumped by a heart, through vessels that bathe the tissues of the body, returns to heart through open spaces
Complex Digestive Systems Mouth, stomach, intestine, anus, glands that produce digestive enzymes
Diversity of Mouthparts Mouthparts are grouped and adapted for a vast variety of foods eaten by arthropods Mandibles for chewing, pinching, holding Pairs of appendages for moving food around while chewing http://youtu.be/yBHqJrKtlso http://youtu.be/ZJyeFSq3STM Some insects have blade- or needle-like mouthparts for piercing for drawing blood, etc., while others have sponging tongues to lap up food, rolled-up proboscises for sucking up food
Insect Mouthparts Most mouthparts of arthropods include one pair of mandibles (green) http://youtu.be/QOIJPG25gr0 These are adapted for holding, chewing, or biting various foods Labrum: upper-most mouthpart (red) fused plate to hold food in place during chewing Maxillae (yellow): hold and manipulate food during mastication Hairs and “teeth” along inner ridge Palps used for sensing the characteristics of potential foods Modified into proboscis or straw-like tube for sucking up food http://youtu.be/MYWPWTme_YI Labium: “floor” of the mouth, assists during chewing (blue) Hypopharynx: base of labium, assists in swallowing
Crustacean Mouthparts Three pairs of appendages modified into mouthparts that manipulate and bring food into mouth (mandibles followed by two pairs of maxillae) http://youtu.be/25F7xMVNt-w Paired appendages offer opposable surfaces for grinding and biting food Often followed by setae used to collect food
Arachnid Mouthparts Spiders and scorpions have chelicerae—pointed appendages used to grasp food In spiders, they are hollow and contain venom glands
Other well-developed systems Excretory: Malpighian tubules that remove waste from abdomen; attached to and empty into the intestine Muscular: muscle is attached to inner surface of exoskeleton on both sides of joints
Sexual Reproduction Most arthropods have separate males and females and reproduce sexually Fertilization usually internal, sometimes external in aquatic species A few species hermaphroditic Barnacles Parthenogenesis—asexual reproduction in which new individual develops from unfertilized egg (ex. Bees, wasps, ants, aphids; males with only one X chromosome) Reproductive diversity one reason why more arthropod species than ALL the other animal species combined
Arthropod Diversity Arachnidae: Spiders, scorpions, mites, and ticks Spiders have two body sections: cephalothorax, abdomen Six pairs of jointed appendages Chelicerae: first pair of appendages located near the mouth Modified into pincers or fangs, spiders have no mandibles for chewing Pedipalps: second pair, adapted for handling food and sensing food Arachnids have no antennae Spiders can make elaborate webs– though all spiders spin silk, not all make webs Silk secreted in glands in abdomen, then spun together into thread by spinnerets located at rear of spider Ticks, mites, scorpions: only one body section (head, thorax, and abdomen completely fused Mites feed on fungi, plants, animals Small but can expand body size up to 3x original size Scorpions have long tail with venomous stinger at tip, enlarged pincers
Arthropod Diversity Crustacea: body sections, two pairs of antennae for sensing, two compound eyes, mandibles for crushing food (ex. Shrimp, lobsters, crabs, barnacles, crawdads Crustacean mandibles open and close side to side Many have five pairs of walking legs Used for walking, seizing prey, cleaning appendages First pair of walking legs often modified into strong claws for defense
Arthropod Diversity Chilopoda: centipedes, Diplopoda: millipedes Have Malpighian tubules for excreting wastes Tracheal tubules for gas exchange Centipedes are carnivorous with painful bites May have 15-181 body segments, each with one pair of legs Millipedes don’t bite, eat mostly plants and dead material on forest floors Spray foul-smelling fluid from stink glands as defense May have 20 to 100+ segments, with two spiracles and legs each
Arthropod Diversity Merostomata: Horseshoe crabs—”living fossils” Three living genera, one (Limulus) lives along North American East Coast, two live in Asian tropics Limulus fossils unchanged since Triassic Period 220 mya Heavily protected by extensive exoskeleton; live in deep coastal waters; forage for algae, annelids, mollusks Migrate to shallow water in spring, mate at night during high tide
Arthropod Diversity Insecta: the most successful class of arthropods 3 body segments, six legs, more species of insects than all other animals combined Reproduction: usually once during lifetime, internal fertilization Parthenogenesis: in aphids all female offspring; in bees/ants/wasps all male Most lay large # of eggs, increases chances of offspring survival to reproductive maturity
Metamorphosis Metamorphosis—change in body shape from egg to adult, controlled by series of chemical changes in animal EggLarvaPupaAdult If insect goes through all four stages: complete If insect goes through some stages: incomplete (nymph stage) Complete metamorphosis advantageous for arthropods because larvae don’t compete with adults for the same food
Origins of Arthropods Successfully covered the whole surface of Earth more than any other group of animals because of their ability to survive in almost every habitat Exoskeletons, life cycles, high reproductive output, small size, jointed appendages Most likely evolved from annelid ancestor Evolved fused body segments that adapted for movement, sensing environment More complex than annelids (eyes, nervous tissue) Trilobites were major group of ancient arthropods, but have been extinct 248 million years