1. Classification
Criteria for classification as reported in an ancient Chinese encyclopedia (Lakoff 1987):
“…it is written that animals are divided into:
those that belong to the Emperor
embalmed ones
those that are trained
suckling pigs
mermaids
fabulous ones
stray dogs
those that tremble as if they were mad
those that have just broken a flower vase

2. Systematics- studies diversity of life
It is the study and classification of organisms with the goal of reconstructing their evolutionary history
Taxonomy- the field of science that classifies life into groups

3. Biological Kingdoms
2 Kingdoms
Traditional view
plants
animals

4. Plantae Fungi Animalia
Biological Kingdoms
5 Kingdoms
Whittaker, 1969
Plantae Fungi Animalia
Protista
Monera

5. Biological Kingdoms Five kingdom system: Six kingdom system:
Monera
Protista
Fungi
Plantae
Animalia
Six kingdom system:
Eu-
bacteria
Protista
Fungi
Plantae
Animalia
Archae-bacteria
Three domain system:
Eu-
bacteria
Archae-bacteria
E U K A R Y A
Eight kingdom system:
Eu-
bacteria
Archezoa
Fungi
Plantae
Animalia
Archae-bacteria
Chromista
Protista

6. Classification: Six kingdom system
Eubacteria
Archaebacteria
E. coli
Cyanobacteria
Protista
Paramecium
Diatom
Slime mold
Plantae
Fungi
Animalia

7. Six kingdom system: Monera Protista Plantae Fungi Animalia Eu-
bacteria
Archae-bacteria
Protista
Plantae
Fungi
Animalia

8. What are some
of the ways we
can classify animals?

9. Primary Grouping Criterion
Cellular complexity
Plantae Fungi Animalia
Protista
Monera
(Eubacteria & Archaebacteria)
Eukaryotic
Prokaryotic

10. Plantae Fungi Animalia
Other Grouping Criteria
Single-celled vs. multicellular
Mode of nutrition
absorption
photosynthesis
ingestion
Plantae Fungi Animalia
Protista
Monera
Note: Criteria can overlap

11. Other Grouping Criteria
Mode of Reproduction
sexual
asexual
Respiratory System
gas exchange across skin
lungs
gills

12. Other Grouping Criteria
Skeleton
internal/external
bone/cartilage/chitin…
Circulatory System
none
open/closed

13. Age of Systematics 1700’s Carl Linnaeus Incurable classifier
Flair for creative simplicity

14. Linnaeus Swedish doctor Professor of Medicine & Natural History
14 books in 3 years
Fish book: 3,000 pages

15. Linnaeus 1753: published book describing World’s plants
Start of naming process
ID: flowers - number & structure of the parts

16. Linnaeus Descriptions: “poetic precision”
Result: easily applied system
2 word names: “binomial nomenclature”

17. Binomial Nomenclature
2 word name (genus + species)
1st level classification
Elephas maximus
Loxodonta africanas

18. Tiger = Panthera tigris
Leopard = Panthera pardus
Lion = Panthera leo

19. Panda Bear = Ailuropoda melanoleuca
Black Bear = Ursus americanus
Polar Bear = Ursus maritimus

20. Linnaean Hierarchy Kingdom Phylum (or Division) Class Order Family
Genus
Species
Plantae & Fungi

21. Linnaean Hierarchy
“King Philip came over from Germany stoned.”

22. Names Common names Confusing Ambiguous Scientific names
Agreed upon system
Portuguese Man-of-War
Bluebottle
Physalia physalis

23. Names Language Latin or Latinized Giving names
A highly technical process
Name is author’s choice

24. Commemorate People Gardenia jasminoides (Dr. Alexander Garden)
Camellia japonica (Joseph Kamel)
Strelitzia reginae (Queen Charlotte of Mecklenburg-Strelitz)
Siegesbeckia orientalis (Dr. Siegesbeck)

25. Descriptive Cardinalis cardinalis (red) Railus aquaticus (watery)
Passer domesticus (house)

26. Geographic Location Kuhlia sandwicensis (Hawaii)
Periplanata americana (American cockroach)
Zosterops japonica
(Japanese white-eye)

27. Pronunciation
Divide into syllables
Choose where to place emphasis

29. Example of Coral Classification
The Mushroom Coral
Fungia scutaria
Kingdom Animalia
Phylum Cnidaria
Class Anthozoa
Order Scleractinia
Family Fungiidae
Genus Fungia
Species scutaria

31. Biological Species
Organisms that are genetically similar, and have ability to interbreed and produce viable, fertile offspring

32. Offspring is sterile
mule
donkey
horse

33. Kingdom Monera Species number low (~17, 000) Changing as we learn more
Two Divisions
Eubacteria (Bacteria & Cyanobacteria)
Archaebacteria

34. Kingdom Monera Prokaryotic Single-celled Diverse energy types:
Chemoautotrophic- Purple sulfur bacteria
Photoautotrophic- cyanobacteria
Heterotrophic- E. coli

35. Kingdom Monera
Some with cell walls, but cell walls composed of peptidoglycan, not cellulose (as in higher plants).
Asexual reproduction

36. Kingdom Monera

37. Eubacteria
pneumonia
cyanobacteria
anthrax

38. Archaebacteria
Purple sulfur bacteria

39. Kingdom Protista Eukaryotic
Generally single-celled; if multicellular, cells not organized into tissues
Heterotrophic & autotrophic forms
~ 45,000 species

40. Kingdom Protista 3 informal groups Plant-like (algal) protists
Animal-like protists
Fungus-like protists

41. Plant-like Protists Diatoms Dinoflagellates Green algae Brown Algae
Red algae
Diatoms
Dinoflagellates

42. Chlorophyta: Green Algae
Halimeda opuntia
Caulerpa sertularioides
Codium edule
Dictyosphaeria cavernosa
Caulerpa racemosa

43. Phaeophyta: Brown Algae
Turbinaria ornata
Padina japonica
Hydroclathrus clathratus
Sargassum polyphyllum
Sargassum echinocarpum

44. Rhodophyta: Red Algae Ahnfeltia concinna Acanthophora spicifera
Hypnea chordacea
Galaxaura fastigiata
Asparagopsis taxiformis

45. Animal-like Protists
Amoeba
Cilliates
Flagellates
13,000 species

46. Fungus-like Protists Mildew Water molds Blights 475 species
Downey mildew
475 species
Slime molds

47. Kingdom Plantae Eukaryotic Multicellular organisms True tissues.
Photoautotrophic nutrition.
Most adapted for a terrestrial existence and possessing vascular tissues.

48. Kingdom Plantae Cells with chloroplasts and cellulose cell walls.
Includes mosses, ferns, pine trees, cycads, ginkgos, and flowering plants.

49. Kingdom Plantae Sea grasses
Halophilia hawaiiana- only form of seagrass in Hawaii

50. Mangroves

51. Kingdom Fungi
Eukaryotic
Generally multicellular, organisms (a few species, e.g., yeast are unicellular).
Nutrition:
Heterotrophic
Saprophytic (absorptive)

52. Kingdom Fungi
Most with cell walls (usually composed of chitin) and complex life histories.
Includes molds, yeasts, rusts, and mushrooms, marine fungi

53. Toad stool
Shelf fungus
Rhizopus
Yeast

54. Fungus infection in fish

55. Kingdom Animalia Eukaryotic Multicellular organisms True tissues.
Heterotrophic nutrition

56. Kingdom Animalia Most exhibit significant capacity for locomotion.
Cells not surrounded by cell walls.
Includes sponges, sea anemones, snails, insects, sea stars, fish, reptiles, birds, and human beings.

57. Phylogentic Relationships of Animals
Platyhelminthes
Porifera
Mollusca
Chordata
Arthropoda
Annelida
Cnideria
Nematoda
Echinodermata
pseudocoelom
segmentation
acoelom
Protostome: schizocoelem
Deuterostomes:
eucoelom
radial symmetry
bilateral symmetry
no true tissues
true tissue
Ancestral Protist

58. Phylum Porifera Class Hexactinellida Class Calcaria Class Desmospongia
Sclerospongia
Boring sponge
Purple and yellow
tube sponge

59. Portuguese Man-Of-War
Phylum Cnidaria
Class
Hydrozoa
Class
Scyphozoa
Class
Cubozoa
Class
Anthozoa
Hydra
Portuguese Man-Of-War
Stinging Limu
Fire Coral
True jellyfish
Box jellies
Sea wasps
Corals
Anemones

61. Phylum Platyhelminthes
Phylum Ctenophora
Phylum Platyhelminthes

62. Phylum Mollusca More than 500,000 known species Class Polyplacophora
Gastropoda
Class
Bivalvia
Class
Cephalopoda
chitons
Snails
nudibranchs
Squid
Octopus
Cuttlefish
Nautilus
clams
More than 500,000 known species

63. Phylum Mollusca Well developed circulatory system
Nervous system with brain
Some with good eyes

64. Body Plan Three main parts: Muscular foot- for movement
Visceral mass- contains most of the internal organs
Mantle cavity- houses gills

65. Generalized Mollusc Anatomy
mantle
visceral mass
foot

66. Feeding Types
Grazers (radula- scraping tongue)
Filter feeding
Egg eaters
Active predation

67. Subclass Opithistobranchia
Class Gastropoda
Subclass Opithistobranchia
Spanish Dancer (nudibranch)
& egg mass

68. Subclass Prosobranchia
Class Gastropoda
Subclass Prosobranchia
Cone shell
Opihi
Cowery
Triton’s trumpet
periwinkle

69. Class Polyplacophora
Chitins

70. Class Bivalvia

71. Class Cephalopoda
Day octopus

72. Octopus Intelligence

73. Mimic octopus from Indonesia
flatfish
Sea snake
lionfish

74. Blue-ringed octopus Highly venomous
                                     
The brilliantly colored blue ringed octopus (Hapalochlaena lunulata) hunts using a venom so powerful it can kill a human
Highly venomous

75. Phylum Arthropoda Subphylum Uniramia Subphylum trilobita Subphylum
Chelicerata
Insects
Millipedes
Centipede
Beetles
trilobites
Horseshoe crab
Sea spiders
spiders
Subphylum
Crustacea
Crabs Krill
Shrimp Lobster
Ispod amphipod

76. Phylum Arthropoda Insects, crabs, spiders, barnacles
Most species; 80% are insects
Hard chitin exoskeleton (must shed to grow)
Circulatory system with blood, heart
10,000,000? species

77. Class Crustacea Yellow spotted guard crab Hawaiian cleaner shrimp
Spiny lobster
Anemone carrying hermit crab
Banded coral shrimp

78. Phylum Echinodermata Class Astroidae Class Ophiuroidae Class
Echinoidae
Class
Holothuroidae
Sea stars
Brittle stars
Sea urchins
Sea cucumbers
Class
Crinoidae
Crinoids

79. Phylum Echinodermata No circulatory system No respiratory system
Excretion (N elimination) by diffusion
Simple nervous system, no brain
Water-vascular system

80. Phylum Echinodermata Water Vascular System
Tube feet & associated plumbing
Used for walking, clinging to substrate & holding food

81. Class Echinoidea: sea urchins
Slate pencil urchin
Collector urchin
Echinometra mathaei
Echinothrix calamaris
Colobocentrotus atratus

82. Class Holothuroidea: Sea Cucumbers
Polyplectana kerfersteninii
Holothuria atra

83. Class Asteroidea: Sea Stars
Linckia sp.
Acanthaster planci

84. Class Ophiuroidea: Brittle Stars

85. Class Crinoidea: Feather Stars

86. Phylum Chordata Subphylum Urochordata Subphylum Cephalochordata
Vertebrata
tunicates
lancets
Agnathans
Fish
Sharks
tetrapods

87. Subphylum
Urochordata
tunicate
                                                                           

88. Subphylum
Cephalochordata
lancet

89. Phylum Porifera Class Hexactinellida Class Calcaria Class Desmospongia
Sclerospongia
Boring sponge
Purple and yellow
tube sponge

90. Characteristics No true tissues or organs No symmetry
No nerves or muscles
Sessile
Reproduce sexually and asexually
Skeletons composed of CaCO3 or SiO2 spicules or spongin
Filter feeders

91. Skeletal Structure
Consists of organized cells supported by a skeleton of:
spongin fibers
calcareous spicules
silica spicules
a combination of these, or perhaps no skeletal structure at all

92. Sponges Phylum Porifera
No Gut
Sponges Phylum Porifera

93. Predators A few species of fish seaslugs
hawks bill and loggerhead turtles
Can use toxins to ward off predators

94. Refuge Sponges provide habitat for wide variety of animals.
As many as 16,000 different species of animals have been found in one loggerhead sponge.

95. Portuguese Man-Of-War
Phylum Cnidaria
Class
Hydrozoa
Class
Scyphozoa
Class
Cubozoa
Class
Anthozoa
Hydra
Portuguese Man-Of-War
Stinging Limu
Fire Coral
True jellyfish
Box jellies
Sea wasps
Corals
Anemones

96. Portuguese Man-Of-War
Class
Hydrozoa
Close Up of a
Portuguese Man-Of-War

97. Class
Scyphozoa

98. Class
Cubozoa
Seawasp
Box Jellies

99. Subclass Zoantharia
Order Actinaria
Sea Anemones
Class
Anthozoa

100. Black Coral & Wire Coral
Subclass Hexacorallia
Order Antipatheria
Black Coral & Wire Coral
Class
Anthozoa
Black coral
Wire coral

101. Class
Anthozoa
“True” Stony Corals
lobe
finger
mushroom
Porites rus

102. Phylum Ctenophora

103. Phylum Platyhelminthes

104. Phylum Platyhelminthes
Flatworms
Blind digestive cavity
Bilaterally symmetrical
Thin, simple circulation
Sensory organs at front
Many parasitic
10,000 species

105. Feeding

106. Camouflage
flatworm
nudibranch

107. Toxins Staurosporine Tetrodoxin
< Staurosporine and its derivatives belong to a group of organic chemical compounds called indolocarbazole alkaloids. They are known as potent antibiotics and strong insecticides.  Two of these compounds, 3-hydroxy-3'-demethoxy-3'-hydroxystaurosporine and 11-hydroxy-4'-N-demethylstaurosporine, were isolated from the marine polyclad flatworm Pseudoceros concineus and his favored food, the ascidian Eudistoma toealensis (Tunicata). Both animals are brightly coloured and show a high abundance in the mangroves of Truk Lagoon, Micronesia. Feeding experiments with tropical reef fish showed that the crude extract from the ascidian was highly deterrent towards fish, suggesting that staurosporine acts as a highly potent chemical defence substance against predators (Schupp et al., 1997). It is not known yet, wether the flatworm's metabolism is able to produce staurosporine by itself. It is more likely that the actual source of the toxic compound is the ascidian. After feeding on the poisonous tunicate the polyclad flatworm becomes unpalatable because it stores the toxin in his own tissues. 
< Tetrodotoxin is a non-protein organic compound (aminoperhydroquinazoline) and one of the strongest paralytic toxins known today. It is a very specific blocker of voltage-gated Sodium (Na+) channels, large integral membrane proteins that form pores through the plasma membrane of neuronal cells that allow Na+ ions to cross. Pores (=gates) open and close in response to a variety of stimuli such as changes in membrane potential or the presence of certain chemicals outside or inside the cell. Their proper functioning is absolutely essential for neuronal action potentials. Tetrododoxin, however, blocks these channels irreversibly leading to rapid paralysis through interference with neuromuscular conduction.

108. Pseudoceros dimidiatus
Hawaiian Flatworms
Pseudoceros cf. rubroanus
Pseudoceros ferrugineus
Planocera cf. oligoglena
Pseudoceros dimidiatus
Pseudobiceros sp.

109. Phylum Nematoda

110. Phylum Nematoda Roundworms Primitive body cavity Gut & Anus
No circulatory system
Nervous system
Very successful- well adapted to every ecosystem
Many are parasites
Nematodes have successfully adapted to nearly every ecosystem from marine to fresh water, from the polar regions to the tropics, as well as the highest to the lowest of elevations. They are ubiquitous in freshwater, marine, and terrestrial environments, where they often outnumber other animals in both individual and species counts, and are found in locations as diverse as Guam and oceanic trenches. They represent, for example, 90% of all life on the seafloor of the Earth.[3] Their many parasitic forms include pathogens in most plants and animals (including humans). Some nematodes can undergo cryptobiosis.
Nematodes are the most speciose phylum after the arthropods, they occur in nearly every habitat including as parasites in all sorts of plants and animals, (they don't like dry places however). One species is known that can live in old vinegar (Turbatrix aceti)and another that as only been found in German beer mats. Though only about species have been described some scientists estimate there may be as many as a million species all told. They can occur in very dense numbers in the soil and rotting vegetation, as many as have been found in a single rotting apple, while millions occur in the top 3cm (1 inch) of a square metre of good quality soil. While there are a huge number of free living Nematodes there are also a large number of parasitic species, many of which cause diseases to man and other animals as well as to plants, nearly every living organism has been found to be parasitised by one species of nematode or another. Most nematodes are reasonably small, they range in size from 100 micrometres in length (1/10th of a mm or 1/250th of an in) to the female Giant Nematode Dioctophyme renale which may be up to 1 metre, or 3 ft long.
Ecology
Nematodes live in a vast variety of habitats, ecologically they can be divided into free living forms and parasitic forms. Free living forms have a simple life cycle involving 4 juvenile instars on the path from egg to adult. Parasitic species have developed a wide range of variations on this basic theme. The variations involve whether there is a secondary host and the amount of time spent in one or either hosts. There is also considerable variability in the way that they move from one host species to another. thus while many species lay eggs that pass out of the primary host with the faeces where they are eaten by the secondary host which then gets eaten in turn by the primary host after the Nematodes have developed. Because it is not always totally reliable that the secondary host will be eaten just as the Nematode larvae have developed into the infective stage many species have the ability to encyst themselves in the muscle or cuticle of their secondary hosts.
Some species use another animal to transport them from one host to another thus Wuchereria bancrofti releases minute live young called 'microfilaria' into the primary hosts blood stream rather than eggs into the digestive tract. These microfilaria get ingested by mosquitoes when they feed on an infected person. Inside the mosquito they live in the mosquitoes gut where they develop until the Larva 3 stage wait for the mosquito to bite another host whereupon they enter the host via the mosquitoes proboscis sheath and the wound it makes in the hosts skin.
Nematodes in Mankind
Human beings, along with all other living things are host to numerous Nematode parasites. The most common of these is Ascaris lumbricoides with an estimated 700 million people effected globally, this Nematode is not normally fatal and in low numbers may have very little effect on adults, however in heavy doses it can be quite debilitating, especially for children. The Nematodes infecting mankind include several species of filarial worms, the most important of these are Wuchereria bancrofti and Brugia malayi which are very similar and cause lymphatic filariasis, Onchocerca volvulus which causes River Blindness and Loa loa which causes Loiasis. Other species are Dranunculus medinensis known as Guinea Worm, Trichinella spiralis causing Trichinosis, Necator americanus and Ancylostoma duodenale causing Hookworm, Enterobius vermicularis causing Pinworms and Trichuris trichuria causing Whipworm or Trichuriasis.
Anatomy
Basically a Nematode is a long hollow tube within which is another tube, the alimentary canal and the reproductive organs. Nematodes are round in cross section, this is because unlike the other worms that below them in the phyla table they maintain their body fluids under great pressure (on average internal pressure in a nematode equals 70mm of mercury or 1.49 PSI, with a maximum recorded value of 125mm of mercury or 2.41 PSI). To contain this high pressure nematodes have an extremely tough, yet elastic and flexible cuticle. This cuticle consists of up to 9 layers of proteinaceous fibres, with 3 layers being easily discerned, these are called, from the outside in, the cortex, the matrix layer and the fibre layer. Despite its complexity the Nematode cuticle is permeable to both water and gases, so respiration occurs through it. Beneath the cuticle is a hypodermis and a layer of longitudinal muscle. The combination of the flexure of these muscles with the high pressure of the system produces a characteristic whip-like wriggle that Nematodes use to swim. Scientifically this is called undulatory propulsion with sinusoidal waves passing back along the body.
At the anterior (head) end there is a mouth which has 3 lips behind which predatory species possess a few teeth, this leads to a pharynx which is triangular in cross section. Because of the high pressure within the body unsupported organs such as the intestines tend to collapse in much the same way that an uninflated bicycle tube tends to become oval or flat in cross section when laid flat on the table. The pharynx of Nematodes is an efficient pump and forces food into the intestines, there is a one way valve between the intestines and the pharynx. The pharynx can, when this valve is closed, be used to suck liquid food into the mouth. Digestion is rapid and faeces are expelled under pressure. This pressure is so great that the parasitic nematode Ascaris lumbricoides which is about 12cm to 18cm long (5 to 7 inches) may shoot its faeces 60cm or 2 feet into the air.
Nematodes, especially free living forms generally have a reasonably well developed nervous system. This is comprised of a circum-pharyngeal nerve ring made up from 4 nerve ganglia from which 6 longitudinal nerves extend down through the body to the various parts of the gut and the reproductive organs. There are also 6 shorter nerves which extend forwards from the circum-pharyngeal ganglia towards the mouth. Nematodes have no circulatory or respiratory organs and the excretion of metabolic waste is via two simple ducts or tubules which have no nephridia or flame cells.
Nematodes are copiously reproductive and most of their body cavity, which is a pseudocoelom is filled with paired sets of reproductive organs, either ovaries or testes. Males and females copulate and the male introduces sperm to the females vagina with the help of 2 stiff horny spicules that are a part of his cloaca. Fertilisation is internal and females lay eggs over a prolonged time period, thus a female Ascaris lumbricoides may lay her eggs at the rate of 200,000 per day and have had a total 27 million eggs within her at the start of her reproductive career. Young nematodes hatch from these eggs and go through 4 moults before they become adults.
Nematodes are slender, worm-like animals, typically less than 2.5 millimetres (0.10 in) long. The smallest nematodes are microscopic, while free-living species can reach as much as 5 centimetres (2.0 in) and some parasitic species are larger still. The body is often ornamented with ridges, rings, warts, bristles or other distinctive structures.[11]
The head of a nematode is relatively distinctive. Whereas the rest of the body is bilaterally symmetrical, the head is radially symmetrical, with sensory bristles and, in many cases, solid head-shields radiating outwards around the mouth. The mouth has either three or six lips, which often bear a series of teeth on their inner edge. An adhesive caudal gland is often found at the tip of the tail.[11]
The epidermis is either a syncytium or a single layer of cells, and is covered by a thick collagenous cuticle. The cuticle is often of complex structure, and may have two or three distinct layers. Underneath the epidermis lies a layer of muscle cells. Projections run from the inner surface of these cells towards the nerve cords; this is a unique arrangement in the animal kingdom, in which nerve cells normally extend fibres into the muscles rather than vice versa.[11]
The muscle layer surrounds the body cavity, which is filled with a fluid that lacks any form of blood cells. The gut runs down the centre of the cavity.[11]
Digestive system
The oral cavity is lined with cuticle, which is often strengthened with ridges or other structures, and, especially in carnivorous species, may bear a number of teeth. The mouth often includes a sharp stylet which the animal can thrust into its prey. In some species, the stylet is hollow, and can be used to suck liquids from plants or animals.[11]
The oral cavity opens into a muscular sucking pharynx, also lined with cuticle. Digestive glands are found in this region of the gut, producing enzymes that start to break down the food. In stylet-bearing species, these may even be injected into the prey.[11]
There is no stomach, with the pharynx connecting directly to the intestine that forms the main length of the gut. This produces further enzymes, and also absorbs nutrients through its lining. The last portion of the intestine is lined by cuticle, forming a rectum which expels waste through the anus just below and in front of the tip of the tail. The intestine also has valves or sphincters at either end to help control the movement of food through the body.[11]
Excretory system
Nitrogenous waste is excreted in the form of ammonia through the body wall, and is not associated with any specific organs. However, the structures for excreting salt to maintain osmoregulation are typically more complex.[11]
In many marine nematodes, there are one or two unicellular renette glands that excrete salt through a pore on the underside of the animal, close to the pharynx. In most other nematodes, these specialised cells have been replaced by an organ consisting of two parallel ducts connected by a single transverse duct. This transverse duct opens into a common canal that runs to the excretory pore.[11]
Nervous system
Four nerves run the length of the body on the dorsal, ventral, and lateral surfaces. Each nerve lies within a cord of connective tissue lying beneath the cuticle and between the muscle cells. The ventral nerve is the largest, and has a double structure forward of the excretory pore. The dorsal nerve is responsible for motor control, while the lateral nerves are sensory, and the ventral combines both functions.[11]
At the anterior end of the animal, the nerves branch from a dense circular nerve ring surrounding the pharynx, and serving as the brain. Smaller nerves run forward from the ring to supply the sensory organs of the head.[11]
The body of nematodes is covered in numerous sensory bristles and papillae that together provide a sense of touch. Behind the sensory bristles on the head lie two small pits, or amphids. These are well supplied with nerve cells, and are probably chemoreception organs. A few aquatic nematodes possess what appear to be pigmented eye-spots, but is unclear whether or not these are actually sensory in nature.[11]
Reproduction
Most nematode species are dioecious, with separate male and female individuals. Both sexes possess one or two tubular gonads. In males, the sperm are produced at the end of the gonad, and migrate along its length as they mature. The testes each open into a relatively wide sperm duct and then into a glandular and muscular ejaculatory duct associated with the cloaca. In females, the ovaries each open into an oviduct and then a glandular uterus. The uteri both open into a common vagina, usually located in the middle of the ventral surface.[11]
Reproduction is usually sexual. Males are usually smaller than females (often much smaller) and often have a characteristically bent tail for holding the female for copulation. During copulation, one or more chitinized spicules move out of the cloaca and are inserted into genital pore of the female. Amoeboid sperm crawl along the spicule into the female worm. Nematode sperm is thought to be the only eukaryotic cell without the globular protein G-actin.
Eggs may be embryonated or unembryonated when passed by the female, meaning that their fertilized eggs may not yet be developed. A few species are known to be ovoviviparous. The eggs are protected by an outer shell, secreted by the uterus. In free-living roundworms, the eggs hatch into larvae, which appear essentially identical to the adults, except for an under-developed reproductive system; in parasitic roundworms, the life cycle is often much more complicated.[11]
Nematodes as a whole possess a wide range of modes of reproduction.[12] Some nematodes, such as Heterorhabditis spp., undergo a process called : intrauterine birth causing maternal death.[13] Some nematodes are hermaphroditic, and keep their self-fertilized eggs inside the uterus until they hatch. The juvenile nematodes will then ingest the parent nematode. This process is significantly promoted in environments with a low or reducing food supply.[13]
The nematode model species Caenorhabditis elegans and C. briggsae exhibit androdioecy, which is very rare among animals. The single genus Meloidogyne (root-knot nematodes) exhibit a range of reproductive modes including sexual reproduction, (in which most, but not all, generations reproduce asexually), and both meiotic and mitotic parthenogenesis.
The genus exhibits an unusual form of parthenogenesis, in which sperm-producing males copulate with females, but the sperm do not fuse with the ovum. Contact with the sperm is essential for the ovum to begin dividing, but because there is no fusion of the cells, the male contributes no genetic material to the offspring, which are essentially clones of the female.[11]
Free-living species
In free-living species, development usually consists of four molts of the cuticle during growth. Different species feed on materials as varied as algae, fungi, small animals, fecal matter, dead organisms and living tissues. Free-living marine nematodes are important and abundant members of the meiobenthos. They play an important role in the decomposition process, aid in recycling of nutrients in marine environments and are sensitive to changes in the environment caused by pollution. One roundworm of note is Caenorhabditis elegans, which lives in the soil and has found much use as a model organism. C. elegans has had its entire genome sequenced, as well as the developmental fate of every cell determined, and every neuron mapped.
[Parasitic species
Nematodes commonly parasitic on humans include ascarids (Ascaris), filarias, hookworms, pinworms (Enterobius) and whipworms (Trichuris trichiura). The species Trichinella spiralis, commonly known as the trichina worm, occurs in rats, pigs, and humans, and is responsible for the disease trichinosis. Baylisascaris usually infests wild animals but can be deadly to humans as well. are Heartworms known for causing Heartworm disease by inhabiting the hearts, arteries, and lungs of dogs and some cats. Haemonchus contortus is one of the most abundant infectious agents in sheep around the world, causing great economic damage to sheep farms. In contrast, entomopathogenic nematodes parasitize insects and are considered by humans to be beneficial.
One form of nematode is entirely dependent upon fig wasps, which are the sole source of fig fertilization. They prey upon the wasps, riding them from the ripe fig of the wasp's birth to the fig flower of its death, where they kill the wasp, and their offspring await the birth of the next generation of wasps as the fig ripens.
A newly discovered parasitic tetradonematid nematode, Myrmeconema neotropicum, apparently induces fruit mimicry in the tropical antCephalotes atratus. Infected ants develop bright red gasters, tend to be more sluggish, and walk with their gasters in a conspicuous elevated position. These changes likely cause frugivorous birds to confuse the infected ants for berries and eat them. Parasite eggs passed in the bird's feces are subsequently collected by foraging Cephalotes atratus and are fed to their larvae, thus completing the life cycle of Myrmeconema neotropicum.[14]
Colorized electron micrograph of soybean cyst nematode (Heterodera sp.) and egg
Plant parasitic nematodes include several groups causing severe crop losses. The most common genera are Aphelenchoides (), Ditylenchus, Globodera (potato cyst nematodes), Heterodera (soybean cyst nematodes), , Meloidogyne (root-knot nematodes), , Pratylenchus (lesion nematodes), and Xiphinema (dagger nematodes). Several phytoparasitic nematode species cause histological damages to roots, including the formation of visible galls (e.g. by root-knot nematodes), which are useful characters for their diagnostic in the field. Some nematode species transmit plant viruses through their feeding activity on roots. One of them is Xiphinema index, vector of GFLV (Grapevine Fanleaf Virus), an important disease of grapes.
Other nematodes attack bark and forest trees. The most important representative of this group is Bursaphelenchus xylophilus, the pine wood nematode, present in Asia and America and recently discovered in Europe.
[edit] Agriculture and horticulture
Depending on the species, a nematode may be beneficial or detrimental to plant health.
From agricultural and horticulture perspectives, there are two categories of nematode: predatory ones, which will kill garden pests like cutworms, and pest nematodes, like the root-knot nematode, which attack plants and those that act as vectors spreading plant viruses between crop plants.
Predatory nematodes can be bred by soaking a specific recipe of leaves and other detritus in water, in a dark, cool place, and can even be purchased as an organic form of pest control.
Rotations of plants with nematode resistant species or varieties is one means of managing parasitic nematode infestations. For example, marigolds, grown over one or more seasons (the effect is cumulative), can be used to control nematodes.[15] Another is treatment with natural antagonists such as the fungus gliocladium roseum. Chitosan is a natural biocontrol that elicits plant defense responses to destroy parasitic cyst nematodes on roots of sobyean, corn, sugar beets, potatoes and tomatoes without harming beneficial nematodes in the soil.[16] Furthermore soil steaming is an efficient method to kill nematodes before planting crop.
CSIRO has found[17] that there was 13- to 14-fold reduction of nematode population densities in plots having Indian mustard (Brassica juncea) green manure or seed meal in the soil.
Hundreds of Caenorhabditis elegans were featured in a research project on NASA's STS-107 space mission (which ended in the Space Shuttle Columbia Disaster).[18]
500,000? species

111. Phylum Nematoda

112. Phylum Annelida Class Oligochaeta Class Polychaeta Class Hirudinea
earthworms
marine worms
leaches

113. Hawaii Fan worms (feather duster) Spaghetti worms
Sabellastarte sanctijosephi
Lanice conchilega
Christmas tree worm
Fireworm
Eurythoe complanata
Spirobranchus giganteus

114. Phylum Mollusca More than 500,000 known species Class Polyplacophora
Gastropoda
Class
Bivalvia
Class
Cephalopoda
chitons
Snails
nudibranchs
Squid
Octopus
Cuttlefish
Nautilus
clams
More than 500,000 known species

115. Phylum Mollusca Well developed circulatory system
Nervous system with brain
Some with good eyes

116. Body Plan Three main parts: Muscular foot- for movement
Visceral mass- contains most of the internal organs
Mantle cavity- houses gills

117. Generalized Mollusc Anatomy
mantle
visceral mass
foot

118. Feeding Types
Grazers (radula- scraping tongue)
Filter feeding
Egg eaters
Active predation

119. Subclass Opithistobranchia
Class Gastropoda
Subclass Opithistobranchia
Spanish Dancer (nudibranch)
& egg mass

120. Subclass Prosobranchia
Class Gastropoda
Subclass Prosobranchia
Cone shell
Opihi
Cowery
Triton’s trumpet
periwinkle

121. Class Polyplacophora
Chitins

122. Class Bivalvia

123. Class Cephalopoda
Day octopus

124. Class
Cephalopoda

125. Octopus Intelligence

126. Mimic octopus from Indonesia
flatfish
Sea snake
lionfish

127. Blue-ringed octopus Highly venomous
                                     
The brilliantly colored blue ringed octopus (Hapalochlaena lunulata) hunts using a venom so powerful it can kill a human
Highly venomous

128. Phylum Arthropoda

129. Phylogeny of Arthropods
Arthropoda
Annelids
(worms)
Onychophorans
(worms w/legs)
Chelicerates
(spiders)
Crustaceans
(lobsters)
Insects
(butterflies)
Trilobites
(extinct)
Worm-like
Ancestor

130. Phylum Arthropoda Insects, crabs, spiders, barnacles
Most species; 80% are insects
Hard chitin exoskeleton (must shed to grow)
Circulatory system with blood, heart
10,000,000? species

131. Trilobites
Existed mya

132. Chelicerates
Horseshoe crab
Pycnogonida

133. Crustacea
brine shrimp
ostracod
copepods
mantis shrimps
barnacles

134. Crustacea Yellow spotted guard crab Hawaiian cleaner shrimp
Spiny lobster
Anemone carrying hermit crab
Banded coral shrimp

135. Phylum Echinodermata Class Astroidae Class Ophiuroidae Class
Echinoidae
Class
Holothuroidae
Sea stars
Brittle stars
Sea urchins
Sea cucumbers
Class
Crinoidae
Crinoids

136. Phylum Echinodermata No circulatory system No respiratory system
Excretion (N elimination) by diffusion
Simple nervous system, no brain
Water-vascular system

137. Phylum Echinodermata Water Vascular System
Tube feet & associated plumbing
Used for walking, clinging to substrate & holding food

138. Class Echinoidea: sea urchins
Slate pencil urchin
Collector urchin
Echinometra mathaei
Echinothrix calamaris
Colobocentrotus atratus

139. Class Holothuroidea: Sea Cucumbers
Polyplectana kerfersteninii
Holothuria atra

140. Class Asteroidea: Sea Stars
Linckia sp.
Acanthaster planci

141. Class Ophiuroidea: Brittle Stars

142. Class Crinoidea: Feather Stars

143. Classification Phylum Chordata Subphylum Urochordata Subphylum
Cephalochordata
Subphylum
Vertebrata
lancets
Agnathans
Fish
Sharks
tetrapods
tunicates

144. Chordate Characteristics

146. Subphylum
Urochordata
tunicate
                                                                           

147. Subphylum
Urochordata
tunicate

148. Subphylum
Cephalochordata
lancet

149. Subphylum
Cephalochordata
lancet
                                                                                          

150. Hagfish Class Agnatha Subphylum Vertebrata What do they do?
For a long time, people thought of hagfish as scavengers and parasites, probably due to their habit or burrowing into dead or dying animals and eating them from the inside out. In fact, most of their diet is made up of marine worms and other invertebrates. Scientists used to think the hagfish looked primitive as a result of the loss of characteristics often associated with being a parasite. Now common belief is that hagfish just haven't needed to change for the last couple of hundred million years. Now that's a successful body plan and lifestyle!
Another ability that had won fame for hagfish is the mass amounts of slime almost instantly secreted as a defense mechanism. Where are they found?
Hagfish can be found in the chilly waters of the antitropical north and south. They tend to live on and in muddy sea floors in very dense groups (up to 15,000 in an area). Because females tend to produce large eggs in small numbers, their population sizes suggest a low death rate.
One very useful trick hagfish have developed is the ability to tie themselves in knots, and be able to slide in and out of this knot. This can be used to escape predators, to clean themselves of slime, and to work their way into a carcass. This picture shows: A) knotting; this movement is used to clean slime off the body; B) escaping from capture using knotting, a very powerful motion; C) pulling on food by knotting They can also sneeze to unclog their nostrils of their own slime. Hagfish don't really have jaws. Instead they have two pairs of rasps on top of a tongue. They pull meat into their mouths with the tongue, then tear it off the prey with the rasps. Newly hatched hagfish look just like the adults, but have both male and female sex organs. When they mature, they will be either male or female, but have the ability to change from one to the other if the population structure demands it.
Although hagfish have a partial skull, they have no back bone, so are not true vertebrates. What skeleton they do have is made of cartilage.
How are they used by people?
Yes, humans will find a way to exploit even these seemingly useless and repulsive animals.
In Korea, almost 5 million pounds of hagfish meat are consumed each year. Hagfish skin is processed into "eelskin" boots, bags, wallets, purses, and other products. Overfishing in Asia has decimated their local hagfish stocks, so the Asian hagfish fishery has turned its eyes towards North America, where these "slime eels" are considered a worthless bycatch. It could mean a boost of over $2 million to the local fisheries, but care must be taken not to damage these stocks as well. Hagfish may not be pretty in most people's eyes, but they serve a purpose and are slow to reproduce. It would take them a long time to recover from over-harvesting. Who can tell what removing them from the local food web would do?
Phylogenetics amongst species (for hard core scientists):
There are about 20 species of hagfish divided into four genera (Myxine, Neomyxine, Paramyxine, and Eptatretus). These four groups make a sort of evolutionary continuum with regards to external traits. For example, the Myxine and Neomyxine are considered more advanced than the latter two for several reasons:
They have a single pair of common external gill openings. The latter two have two minute separate gill openings (considered primitive). Paramyxine's openings are closer together than Eptatretus' so Paramyxine is considered more closely related to the first two. The eyes in Myxine and Neomyxine are smaller than those of the other two, suggesting a less primitive condition by an adaptation to the dark environment favoured my hagfish.
Hagfish

151. Subphylum
Vertebrata
Class Agnatha
lamprey

152. Class Chondrichthyes Characteristics Sharks, skates, rays, chimera
Posses jaws with teeth, cartilaginous skeleton, paired fins
Scales (denticles) have same origin and composition as teeth
Possesses 5-7 gills
Spiral valve intestine
Ureoosmotic strategy
Lateral line
No swim bladder
Heterocercal tail
Relatively unchanged (480 mybp)

153. Subphylum
Vertebrata
Class Chondrichthyes

154. Characteristics Class Osteichthyes
Posses jaws with teeth, bony skeleton, paired fins
4 paired gill arches covered by operculum
Intestine- simple, no spiral valve
Swim bladder
Lateral line
Homocercal tail
Scales- cycloid, ctenoid

155. Class Osteichthyes
680 species of fish in the islands' waters.
About 30% of these fish are endemic to the area .

156. White mouthed morey Achilles tang trumpetfish Domino damsel
Trigger (Humu)
White mouthed
morey
Porcupine
Dwarf moray
Achilles tang
trumpetfish

157. Returns to water to breed Metamorphosis Some toxic
Class Amphibia
Characteristics
Cold blooded
Returns to water to breed
Metamorphosis
Some toxic
Estivation-dry and hot
Hibernation- cold
3,500 species

158. Class Amphibia
Rana cancrivora

159. 3 chambered heart (except crocks)
Class Reptilia
Characteristics
Cold blooded
Have scales
Amniotic egg
Dry skin
3 chambered heart (except crocks)
6,500 species

160. Class Reptilia Saltwater crocodile Marine iguana Marine turtle
Sea snake

161. Warm blooded Feathers and wings Hollow bones Horny bill
Class Aves
Characteristics
Warm blooded
Feathers and wings
Hollow bones
Horny bill
Lungs have air sacks
Hard egg shell

162. Class Aves

163. Warm blooded Have fur or hair Suckle young 3 middle ear bones
Class Mammalia
Characteristics
Warm blooded
Have fur or hair
Suckle young
3 middle ear bones
A Guide to characteristics of Class Mammalia
The Class Mammalia is well represented in Southern Africa. There are 293 species of land mammals and 37 species of marine mammals in the Southern African subregion. That is 330 of the around 5000 mammal species found on Earth!
Class Mammalia -- all mammals share three characteristics not found in other animals: 3 middle ear bones; hair; and the production of milk by modified sweat glands called mammary glands.
Mammals hear sounds after they are transmitted from the outside world to their inner ears by a chain of three bones, the malleus, incus, and stapes. Two of these, the malleus and incus, are derived from bones involved in jaw articulation in most other vertebrates.
Mammals have hair. Adults of some species lose most of their hair, but hair is present at least during some phase of the ontogeny of all species. Mammalian hair, made of a protein called keratin, serves at least four functions. First, it slows the exchange of heat with the environment (insulation). Second, specialized hairs (whiskers or "vibrissae") have a sensory function, letting the owner know when it is in contact with an object in its external environment. These hairs are often richly innervated and well-supplied with muscles that control their position. Third, through their color and pattern, hairs affect the appearance of a mammal. They may serve to camouflage, to announce the presence of especially good defense systems (for example, the conspicuous color pattern of a skunk is a warning to predators), or to communicate social information (for example, threats, such as the erect hair on the back of a wolf; sex, such as the different colors of male and female capuchin monkeys; presence of danger, such as the white underside of the tail of a whitetailed deer). Fourth, hair provides some protection, either simply by providing an additional protective layer (against abrasion or sunburn, for example) or by taking on the form of dangerous spines that deter predators (porcupines, spiny rats, others).
Mammals feed their newborn young with milk, a substance rich in fats and protein that is produced by modified sweat glands called mammary glands. These glands, which take a variety of shapes, are usually located on the ventral surface of females along paths that run from the chest region to the groin. They vary in number from two (one right, one left, as in humans) to a dozen or more.
Other characteristics found in most mammals include highly differentiated teeth; teeth are replaced just once during an individual's life (this condition is called diphyodonty, and the first set is called "milk teeth); a lower jaw made up of a single bone, the dentary; four-chambered hearts, a secondary palate separating air and food passages in the mouth; a muscular diaphragm separating thoracic and abdominal cavities; highly developed brain; endothermy and homeothermy; separate sexes with the sex of an embryo being determined by the presence of a Y or 2 X chromosomes; and internal fertilization.
The Class Mammalia includes around 5000 species placed in 26 orders (systematists do not yet agree on the exact number or on how some orders are related to others). Mammals can be found in all continents and seas. In part because of their high metabolic rates (associated with homeothermy and endothermy), they often play an ecological role that seems disproportionately large compared to their numerical abundance.
Subclass Prototheria - Not represented in southern Africa
Order Monotremata -- Monotremes: platypus and echidnas
Subclass Metatheria (marsupials) - Not represented in southern Africa
Order Didelphimorphia
Order Paucituberculata
Order Microbiotheria
Order Dasyuromorphia
Order Peramelemorphia
Order Notoryctemorphia
Order Diprotodontia
Subclass Eutheria (placentals)
Order Insectivora -- Insectivores: shrews, moles, hedgehogs, tenrecs, etc.
Order Macroscelidea -- elephant shrews
Order Scandentia -- tree shrews
Order Dermoptera -- colugos
Order Chiroptera --bats
Order Primates --primates
Order Xenarthra -- edentates; sloths, armadillos and anteaters
Order Pholidota -- pangolins
Order Lagomorpha -- rabbits and pikas
Order Rodentia -- rodents
Order Cetacea -- whales, dolphins, and porpoises
Order Carnivora -- carnivores
Order Tubulidentata -- aardvark
Order Proboscidea -- elephants
Order Hyracoidea -- hyraxes
Order Sirenia -- dugongs and manatees
Order Perissodactyla -- horses, rhinos, tapirs
Order Artiodactyla -- antelope, giraffe, camels, pigs, hippos, etc.

164. Class Mammalia
Whales & Dolphins
Polar bear
Sea otter
Seals & sealions
manatee
Dugong

165. Inquiry What is the difference between a prokaryote and eukaryote?
Which kingdoms are prokaryote and which are eukaryote?
Define a species.
How do fungus feed?
What are some key characteristics of mammals?
Which class of cnideria are true jellyfish?
Name four mollusk classes.