1 / 65

Animal Kingdom Evolution

Animal Kingdom Evolution. 5 Defining characteristics of the animal kingdom: 1) Heterotrophic eukaryotes; ingestion 2) Lack cell walls; collagen 3) Nervous & muscular tissue 4) Sexual; diploid; cleavage; blastula; gastrulation; larvae; metamorphosis 5) Regulatory genes: Hox genes.

sonnyb
Download Presentation

Animal Kingdom Evolution

An Image/Link below is provided (as is) to download presentation Download Policy: Content on the Website is provided to you AS IS for your information and personal use and may not be sold / licensed / shared on other websites without getting consent from its author. Content is provided to you AS IS for your information and personal use only. Download presentation by click this link. While downloading, if for some reason you are not able to download a presentation, the publisher may have deleted the file from their server. During download, if you can't get a presentation, the file might be deleted by the publisher.

E N D

Presentation Transcript

  1. Animal Kingdom Evolution 5 Defining characteristics of the animal kingdom: 1) Heterotrophic eukaryotes; ingestion 2) Lack cell walls; collagen 3) Nervous & muscular tissue 4) Sexual; diploid; cleavage; blastula; gastrulation; larvae; metamorphosis 5) Regulatory genes: Hox genes

  2. Animal phylogeny • *Monophyletic; colonial flagellated protist ancestor • First split • 1- Parazoa vs. Eumetazoa dichotomy: • *(Parazoa)~ no true tissues example sponges • *(Eumetazoa)~ true tissues • all other animals

  3. Parazoa *Parazoa: No true tissues • Invertebrates • No true tissues, unspecialized cells: *Sponges Closest lineage to protists • Phylum Porifera

  4. Phylum: Porifera(“pore bearer”) • *Sessile (attached to bottom) • Spongocoel (central cavity) • *Osculum (large opening) • Choanocytes (flagellated collar cells) • *Hermaphroditic (produce both sperm and eggs)

  5. Eumetazoa: True Tissues: Everything but sponges • 2nd split – Body Symmetry • Radiata vs.Bilateria dichotomy: 1) *radial body symmetry *Cnidaria (hydra; ‘jellyfish’; sea anemones) & *Ctenophora (comb jellies) 2) *bilateral body symmetry (also: **cephalization) • all other animals

  6. Eumetazoa The Radiata, Diploblastic • Radial symmetry • Phy: Cnidaria (hydra, jellies, sea anemones, corals) • *No mesoderm; gastrovascular cavity (GVC)(sac with a central digestive cavity) • Hydrostatic skeleton (fluid held under pressure) • Polyps and medusa • Cnidocytes (cells used for defense and prey capture) • Nematocysts (stinging capsule) • Phy: Ctenophora (comb jellies)

  7. 3. Gasturlation: diploblastic vs. triploblastic • 3- Gastrulation: germ layer development; ectoderm (outer), mesoderm (middle), endoderm (inner) • diploblastic-2 layers; no mesoderm; • Radiata • Phy: Cnidaria (hydra, jellies, sea anemones, corals) • triploblastic-all 3 layers • *bilateria symmetry • All others

  8. 4- Acoelomate, Pseudocoelomate, and Coelomate • All are triploblastic animals • *acoelomates solid body, no body cavity • (Platyhelminthes-flatworms) • mesoderm but, GVC with only one opening • *Some cephalization • *pseudocoelomates body cavity, but not lined with mesoderm called • (Rotifers); *1st with a complete digestive track • Parthenogenesis: type of reproduction in which females produce offspring from unfertilized eggs • Coelomate: true coelom (body cavity) lined with mesoderm called • Phy: Nematoda (roundworms) • Complete digestive track; no circulatory system

  9. Animal phylogeny5 • *Protostomes • Phylogenetics debated…. 1)Phy: Nemertea (proboscis and ribbon worms) • *Complete digestion and closed circulatory system (blood) 2) Phy: the lophophorates (sea mats, tube worms, lamp shells)

  10. The Coelomates: Protostomes, II 3) Phy: Mollusca (snails, slugs, squid, octopus, clams, oysters, chiton) • Soft body protected by a hard shell of calcium carbonate • Foot (movement), visceral mass (internal organs); mantle (secretes shell); radula (rasp-like scraping organ) • Ciliated trochophore larvae (related to Annelida?)

  11. The Coelomates: Protostomes, III 4) Phy: Annelida (earthworms, leeches, marine worms) • True body segmentation (specialization of body regions) • Closed circulatory system • Metanephridia: excretory tubes • “Brainlike” cerebral ganglia • *Hermaphrodites, but cross- fertilize

  12. The Coelomates: Protostomes, IV 5) Phy: Arthropoda trilobites (extinct); crustaceans (crabs, lobsters, shrimps); spiders, scorpions, ticks (arachnids); insects (entomology) • *2 out of every 3 organisms (most successful of all phyla) • *Segmentation, • *hard exoskeleton (cuticle)~ molting, • *jointed appendages; open circulatory system (hemolymph); • *extensive cephalization

  13. Insect characteristics • Outnumber all other forms of life combined • Malpighian tubules: outpocketings of the digestive tract (excretion) • Tracheal system: branched tubes that infiltrate the body (gas exchange) • *Metamorphosis…... • *•incomplete: young resemble adults, then molt into adulthood (grasshoppers) • *•complete: larval stages (looks different than adult); larva to adult through pupal stage

  14. The Coelomates: *Deuterostomes, I • 1) Phy: Echinodermata (sea stars, sea urchins, sand dollars, sea lilies, sea cucumbers, sea daisies) • Spiny skin; sessile or slow moving • Often pentaradial • Water vascular system by hydraulic canals (tube feet)

  15. Deuterostomes • Next branch • Chordates • *Notochord: longitudinal, flexible rod located between the digestive and the nerve cord • *Dorsal, hollow nerve cord; eventually develops into the brain and spinal cord • *Pharyngeal slits; become modified for gas exchange, jaw support, and/or hearing • *Muscular, postanal tail

  16. Invertebrate chordates • Both suspension feeders….. • Subphy: Urochordata (tunicates; sea squirt); mostly sessile & marine • Subphy: Cephalochordata (lancelets); marine, sand dwellers • *Importance: vertebrates closest relatives; in the fossil record, appear 50 million years before first vertebrate • *Paedogenesis: development of sexual maturity in a larva (link with vertebrates?)

  17. Subphylum: Vertebrata • Retain chordate characteristics with specializations…. • *Neural crest: group of embryonic cells near dorsal margins of closing neural tube • *Pronounced cephalization: concentration of sensory and neural equipment in the head • *Cranium and vertebral column • *Closed circulatory system with a ventral chambered heart

  18. Vertebrate diversity • Phy: Chordata • Subphy: Vertebrata • Superclass: Agnatha jawless vertebrates (hagfish, lampreys) • *Most primitive, living vertebrates

  19. Vocabulary tetrapods (‘4-footed’) amniotes (shelled egg)

  20. Superclass Gnathostomata, I • Placoderms (extinct): first with hinged jaws and paired appendages • Class: Chondrichthyes~ *Sharks, skates, rays • *Cartilaginous fishes; well developed jaws and paired fins; continual water flow over gills (gas exchange); lateral line system (water pressure changes) • *Life cycles: • *Oviparous- eggs hatch outside mother’s body • *Ovoviviparous- retain fertilized eggs; nourished by egg yolk; young born live • *Viviparous- young develop within uterus; nourished by placenta

  21. Superclass Gnathostomata, III • Class: Amphibia • *1st tetrapods on land • Frogs, toads, salamanders, caecilians • Metamorphosis; lack shelled egg;moist skin for gas exchange

  22. Superclass Gnathostomata, IV • Class: Reptilia • Lizards, snakes, turtles, and crocodilians • *Amniote (shelled) egg with extraembryonic membranes (gas exchange, waste storage, nutrient transfer); • absence of feathers, hair, and mammary glands; *ectothermic; scales with protein keratin (waterproof); lungs; ectothermic (dinosaurs endothermic?)

  23. Superclass Gnathostomata, V • Class: Aves • Birds • *Flight adaptations: wings (honeycombed bone); feathers (keratin); toothless; one ovary • *Evolved from reptiles (amniote egg and leg scales); endothermic *(4-chambered heart) • Archaeopteryx (stemmed from an ancestor that gave rise to birds)

  24. Superclass Gnathostomata, VI • Class: Mammalia • *Mammary glands; hair (keratin); endothermic; 4-chambered heart; large brains; teeth differentiation • *Evolved from reptilian stock before birds • *Monotremes (egg-laying): platypus; echidna • *Marsupials (pouch): opossums, kangaroos, koalas • *Eutherian (placenta): all other mammals

  25. Order: Primates (evolution) • *Characteristics: hands & feet for grasping; large brains, short jaws, flat face; parental care and complex social behaviors • Suborder: Prosimii •lemurs, tarsiers • Suborder: Anthropoidea •monkeys, apes, humans (opposable thumb) • *45-50 million years ago • *Paleoanthropology: study of human origins • *Hominoid: great apes & humans • Hominid (narrower classification): √ australopithecines (all extinct) *√ genus Homo (only 1 exant, sapiens)

  26. Human evolution • Misconceptions: • 1- Chimp ancestor (2 divergent branches) • 2- Step-wise series (coexistence of human species) • 3- Trait unison(all traits at once) vs. mosaic evolution(over time) (*bipedalism, upright, enlarged brain)

  27. The first humans • Ape-human split (5-7 mya) • Australopithecus; “Lucy” (4.0 mya) • Homo habilis; “Handy Man” (2.5 mya) • Homo erectus; first to migrate (1.8 mya) • Neanderthals (200,000 ya) • Homo sapiens (100,000 ya?) • Multiregional model (parallel evolution) • “Out of Africa” (replacement evolution)

  28. Tissues: groups of cells with a common structure and function (4 types) • Anatomy: structure • Physiology: function • Type 1- Epithelial: outside of body and lines organs and cavities; held together by tight junctions • basement membrane: dense mat of extracellular matrix • Simple: single layer of cells • Stratified: multiple tiers of cells • Cuboidal (like dice) • Columnar (like bricks on end) • Squamous (like floor tiles) • Glandular (can secrete) mucous membrane

  29. Connective Tissue (6 kinds) • Type 2- Connective Tissue: bind and support other tissues; scattered cells through matrix 3 kinds of fibers: • A-Collagenous fibers (collagen protein) non elastic B-Elastic fibers (elastin protein) C-Reticular fibers (thin branched collagen fibers) • Loose connective tissue: binds epithelia to underlying tissue; holds organs (has all 3 fiber types) • Two types of cells dominate • 1-Fibroblasts- secretes the protein for extracellular fibers • 2-Macrophages- amoeboid WBC’s; phagocytosis • Adipose tissue (specialized form)- fat storage; insulation

  30. Connective Tissue, Type II • Fibrous connective tissue: parallel bundles of cells • 1-Tendons- muscles to bones • 2-Ligaments- bones to bones; joints (BOBOLI) • Cartilage: collagen in a rubbery matrix (chondroitin); flexible support • Bone: mineralized tissue by osteoblast cells • Blood: liquid plasma matrix; erythrocytes (RBC’s) carry O2; leukocytes (WBC’s) immunity

  31. Nervous Tissue, Type III • 3-Nervous: senses stimuli and transmits signals from 1 part of the animal to another • *Neuron: functional unit that transmits impulses • *Cell body (contains nucleus) • *Dendrites: transmit impulses from tips to rest of neuron • *Axons: transmit impulses toward another neuron or effector

  32. Muscle Tissue (3 kinds) • 4- Muscle: capable of contracting when stimulated by nerve impulses; myofibrils composed of proteins actin and myosin; 3 types: • A- Skeletal: voluntary movement (striated) • B- Cardiac: contractile wall of heart (branched striated) • C- Smooth: involuntary activities (no striations)

  33. Internal regulation • Interstitial fluid: internal fluid environment of vertebrates; exchanges nutrients and wastes • *Homeostasis: “steady state” or internal balance • *Negative feedback: change in a physiological variable that is being monitored triggers a response that counteracts the initial fluctuation; i.e., body temperature • *Positive feedback: physiological control mechanism in which a change in some variable triggers mechanisms that amplify the change; i.e., uterine contractions at childbirth

  34. Metabolism: sum of all energy-requiring biochemical reactions • *Catabolic processes of cellular respiration • Calorie; kilocalorie/C • *Endotherms: bodies warmed by metabolic heat • *Ectotherms: bodies warmed by environment • Basal Metabolic Rate (BMR): minimal rate powering basic functions of life (endotherms) • Standard Metabolic Rate (SMR): minimal rate powering basic functions of life (ectotherms)

  35. Chapter 48 ~ Nervous System

  36. Neurons Glial cells Axon Dendrite Synapse Neurotransmitters Action potential Motor neurons Interneurons Sensory neurons Myelin sheath Schwann cells Reflex arc http://outreach.mcb.harvard.edu/animations/synaptic.swf The Nervous System

  37. Nervous systems • Effector cells~ muscle or gland cells • Nerves~ bundles of neurons wrapped in connective tissue • Central nervous system (CNS)~ brain and spinal cord • Peripheral nervous system (PNS)~ sensory and motor neurons

  38. Structural Unit of Nervous System • Neuron~ structural and functional unit • Cell body~ nucelus and organelles • Dendrites~ impulses from tips to neuron • Axons~ impulses toward tips • Myelin sheath~ supporting, insulating layer • Schwann cells~ PNS support cells • Synaptic terminals~ neurotransmitter releaser • Synapse~ neuron junction

  39. Simple Nerve Circuit http://msjensen.cehd.umn.edu/1135/Links/Animations/Flash/0016-swf_reflex_arc.swf • Sensory neuron: convey information to spinal cord • Interneurons: information integration • Motor neurons: convey signals to effector cell (muscle or gland) • Reflex: simple response; sensory to motor neurons • Ganglion (ganglia): cluster of nerve cell bodies in the PNS • Supporting cells/glia: nonconductiong cell that provides support, insulation, and protection

  40. Neural signaling http://bcs.whfreeman.com/thelifewire/content/chp44/4403s.swf http://outreach.mcb.harvard.edu/animations/actionpotential.swf • Membrane potential(voltage differences across the plasma membrane) • *Intracellular/extracellular ionic concentration difference • K+ diffuses out (Na+ in); large anions cannot follow….selective permeability of the plasma membrane • Net negative charge of about -70mV

  41. http://bcs.whfreeman.com/thelifewire/content/chp44/4402s.swf Neural signaling http://www.mind.ilstu.edu/curriculum/neurons_intro/flash_electrical.php?modGUI=232&compGUI=1827&itemGUI=3158 • Excitable cells~ cells that can change membrane potentials (neurons, muscle) • Resting potential~ the unexcited state of excitable cells • Gated ion channels (open/close response to stimuli): photoreceptors; vibrations in air (sound receptors); chemical (neurotransmitters) & voltage (membrane potential changes) • Graded Potentials (depend on strength of stimulus): • 1- Hyperpolarization (outflow of K+); increase in electrical gradient; cell becomes more negative • 2- Depolarization (inflow of Na+); reduction in electrical gradient; cell becomes less negative

  42. Neural signaling • Threshold potential: if stimulus reaches a certain voltage (-50 to -55 mV)…. • The action potential is triggered…. • Voltage-gated ion channels (Na+; K+) • 1-Resting state •both channels closed • 2-Threshold •a stimulus opens some Na+ channels • 3-Depolarization•action potential generated •Na+ channels open; cell becomes positive (K+ channels closed) • 4-Repolarization•Na+ channels close, K+ channels open; K+ leaves •cell becomes negative • 5-Undershoot•both gates close, but K+ channel is slow; resting state restored • Refractory period~ insensitive to depolarization due to closing of Na+ gates

  43. Neural signaling • “Travel” of the action potential is self-propagating • Regeneration of “new” action potentials only after refractory period • Forward direction only • Action potential speed: • 1-Axon diameter (larger = faster; 100m/sec) • 2-Nodes of Ranvier (concentration of ion channels); saltatory conduction; 150m/sec

  44. Synaptic communication • Presynaptic cell: transmitting cell • Postsynaptic cell: receiving cell • Synaptic cleft: separation gap • Synaptic vesicles: neurotransmitter releasers • Ca+ influx: caused by action potential; vesicles fuse with presynaptic membrane and release…. • Neurotransmitter http://www.bayareapainmedical.com/neurtrns.html

  45. Neurotransmitters http://www.blackwellpublishing.com/matthews/neurotrans.html • Acetylcholine (most common) •skeletal muscle • Biogenic amines(derived from amino acids) •norepinephrine •dopamine •serotonin • Amino acids • Neuropeptides(short chains of amino acids) •endorphin

  46. Nervous System (know this slide) • Central Nervous System • Crainial Nerves • Spinal Nerves • Peripheral Nervous System • Sensory (afferent) Division • Sensing external environment • Sensing internal environment • Motor (Efferent) Division • Autonomic Nervous System • Sympathetic Nervous System • increase energy consumption • Parasympathetic Nervous System • conservation of energy • Somatic Nervous System • voluntary, conscious control, muscles

  47. Vertebrate PNS

More Related