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Biodiversity: Animals | Grade 11 Life Sciences
★ Grade 11 Life Sciences ★
Animal Diversity
From a sponge that has no organs, to a whale that thinks and communicates — the animal kingdom spans an almost unbelievable range of complexity. Yet every animal, from the simplest to the most complex, shares a common ancestor and a set of features that unite them as a kingdom.
What is an Animal · Invertebrates · Vertebrates · SA Animals · Conservation · Quiz
What Is an Animal?
Kingdom Animalia
🐾 Defining the Animal Kingdom
All animals share a set of defining characteristics: they are multicellular eukaryotes, they are heterotrophic (cannot make their own food — must eat other organisms), they lack cell walls, most can move at some stage of their life, most reproduce sexually, and most undergo a distinct embryonic stage of development. Animals are divided into two major groups: invertebrates (no backbone — about 97% of all animal species) and vertebrates (have a backbone — about 3% of animal species but the group most familiar to us).
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Key Characteristics
How Animals Are Classified
Body symmetry, number of tissue layers, presence of a coelom, and presence of a backbone are the key classification criteria.
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Feature
Description
Examples
Body symmetry
Asymmetrical — no plane of symmetry (sponges). Radial — multiple planes through central axis (jellyfish, sea stars). Bilateral — single plane divides into mirror halves; associated with cephalisation (head development) and active movement
Sponges (no true layers), jellyfish (2), insects/vertebrates (3)
Body cavity (coelom)
Acoelomate — no body cavity (flatworms). Pseudocoelomate — false coelom not fully lined by mesoderm (roundworms). Coelomate — true body cavity fully lined by mesoderm; allows organ specialisation and movement
Invertebrates are animals without a vertebral column (backbone). They include everything from simple sponges and jellyfish to highly complex insects and octopuses. Invertebrates make up approximately 97% of all described animal species — insects alone account for over a million described species. They are critical to virtually every ecosystem: as pollinators, decomposers, prey items, and regulators of plant populations.
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Porifera
Sponges. No tissues, no symmetry, sessile filter feeders. Water flows through pores.
This is a very common exam question. Insects: 6 legs, 3 body regions (head/thorax/abdomen), antennae, usually wings. Arachnids: 8 legs, 2 body regions (cephalothorax/abdomen), NO antennae, NO wings. Spiders, scorpions, ticks = arachnids. Ants, bees, beetles, butterflies = insects. A spider is NOT an insect — it has 8 legs not 6.
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Annelida in Detail
The Earthworm — A Model Invertebrate
Earthworms are a classic exam specimen. Know every organ system and its function.
Simple brain; each segment has own nerve ganglion — segments can respond somewhat independently
Vertebrates
The Backboned Animals
🦴 Five Classes — One Shared Ancestor
Vertebrates are chordates with a vertebral column (backbone). Despite making up only about 3% of animal species, they include the largest, fastest, most intelligent, and most studied animals on Earth. All vertebrates share: a bony or cartilaginous endoskeleton, a backbone of vertebrae protecting the spinal cord, a skull protecting the brain, a closed circulatory system with a chambered heart, and well-developed sensory organs. They are classified into five major classes: fish, amphibians, reptiles, birds, and mammals.
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Complete Reference
The Five Vertebrate Classes Compared
Skin, temperature regulation, heart chambers, fertilisation, and development — know all five classes across all criteria.
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Feature
Fish
Amphibia
Reptilia
Aves (Birds)
Mammalia
Skin
Scales (bony)
Moist, smooth, no scales (permeable)
Dry, waterproof scales (keratin)
Feathers + scales on legs
Hair/fur + skin glands
Temperature
Ectothermic (cold-blooded)
Ectothermic
Ectothermic
Endothermic (warm-blooded)
Endothermic
Heart chambers
2 (1 atrium, 1 ventricle)
3 (2 atria, 1 ventricle)
3 (most) or 4 (crocodilians)
4 (complete separation)
4 (complete separation)
Fertilisation
Mostly external
Mostly external
Internal
Internal
Internal
Development
Eggs in water; no embryo membranes
Eggs in water; larval stage (tadpole → metamorphosis)
Amniotic eggs on land OR live birth
Amniotic eggs (hard-shelled) on land
Mostly live birth; nourished in uterus by placenta (except monotremes)
Breathing
Gills throughout life
Gills (larvae) + lungs + moist skin (adults)
Lungs only
Lungs + air sacs (highly efficient)
Lungs only
Young fed by
Yolk — independent from birth
Yolk — independent from hatching
Yolk — independent from hatching
Parents (most) — altricial or precocial
Mammary glands — milk from mother
SA examples
Yellowfish, sharks, sardines
Platanna, painted reed frog
Nile crocodile, puff adder, leopard tortoise
Ostrich, Cape vulture, African penguin
Elephant, rhino, lion, whale
⚠️ Exam Watch — Ectotherm vs Endotherm
Ectotherm (cold-blooded): body temperature depends on environment; fish, amphibians, reptiles. Advantages: lower energy requirement (don't need to generate own heat); disadvantages: inactive in cold conditions; cannot regulate body temperature independently. Endotherm (warm-blooded): generates own body heat through metabolism; birds and mammals. Advantages: active regardless of temperature; constant enzyme efficiency; disadvantages: requires much more food to maintain body temperature.
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The Transition Group
Amphibians — Between Water and Land
The first vertebrates to colonise land — but never fully independent of water. Their life cycle straddles both worlds.
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🏗️ Key Characteristics
Moist, smooth, scaleless skin — permeable to water AND gases; used for cutaneous respiration
Must keep skin moist — will desiccate in dry air
Ectothermic — body temperature from environment
3-chambered heart (2 atria, 1 ventricle) — some mixing of oxygenated and deoxygenated blood
External fertilisation — eggs laid in water, fertilised by male releasing sperm over eggs
Eggs lack amniotic membranes and shells — must be kept moist (laid in water or damp places)
🔄 Metamorphosis
Tadpole larva hatches from egg — aquatic, gills, no legs, herbivorous
Metamorphosis transforms tadpole into frog/toad: gills → lungs; tail absorbed; legs develop; diet changes to carnivorous
Adult is terrestrial (semi-) but returns to water to breed
SA example: African clawed frog (Xenopus laevis) — was historically used in pregnancy tests; Xenopus females ovulate when injected with pregnant woman's urine (human chorionic gonadotropin)
Amphibians are global bioindicators — their permeable skin makes them highly sensitive to environmental pollution
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Most Advanced Class
Mammals — Hair, Milk & Warm Blood
The three groups of mammals — monotremes, marsupials, and placentals — represent three different reproductive strategies.
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Group
Reproduction
Young Fed by
Examples
Monotremes
Lay eggs (amniotic, leathery); incubate like reptiles
Milk secreted through skin (no nipples)
Platypus, echidna (Australia/New Guinea only)
Marsupials
Very short gestation; tiny, undeveloped young born very early; crawl to pouch
Milk from nipples inside pouch; long pouch development
Kangaroo, koala, wombat, Tasmanian devil; Virginia opossum (Americas)
Placentals (Eutherians)
Long gestation; embryo nourished in uterus by placenta; born well-developed
Milk from nipples; relatively short nursing period in many species
~95% of all mammals: lions, whales, bats, humans, elephants, rhinos
📌 Defining Features of ALL Mammals
Three features define mammals: (1) Hair or fur — for insulation and camouflage; even whales have hair (as embryos or a few bristles). (2) Mammary glands — produce milk to feed young; only females have functional mammary glands. (3) Endothermy — generate own body heat; allows activity in any temperature. Additional shared features: 4-chambered heart (complete separation); diaphragm for breathing; 3 middle ear bones (malleus, incus, stapes); heterodont dentition (different tooth types).
South African Animal Biodiversity
Hotspot for Vertebrates & Invertebrates
🇿🇦 A Continental Diversity Hotspot
South Africa is one of the world's most biodiverse countries for animals. It contains the African Big Five (lion, elephant, buffalo, leopard, rhinoceros), the world's largest terrestrial bird (ostrich), the world's largest fish (whale shark), the world's tallest animal (giraffe), and extraordinary marine diversity along two different ocean coastlines — the cold Benguela current on the west and the warm Agulhas current on the east. Understanding SA's animals includes knowing the key threats facing them.
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Conservation Crisis
Threatened SA Animals & Why They Matter
Poaching, habitat loss, and human-wildlife conflict are driving SA's iconic species toward extinction.
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Species
Status
Main Threats
Conservation Efforts
White Rhinoceros (Ceratotherium simum)
Near threatened (southern); Critically endangered (northern — functionally extinct)
Poaching for horn (used in traditional Asian medicine); habitat loss
The cold Benguela and warm Agulhas currents create two completely different marine ecosystems — meeting at Cape Point.
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🧊 Benguela Current (West Coast)
Cold, nutrient-rich upwelling current from Antarctica
Brings up phosphates and nitrates from deep ocean → phytoplankton bloom → massive fish stocks
Supports world's most productive fishery per area
Sardines, anchovies, Cape gannets, African penguins, Cape fur seals depend on this productivity
The annual sardine run (Eastern Cape coast) is one of the world's greatest wildlife events
🌊 Agulhas Current (East Coast)
Warm current flowing southwestward along the east coast
Warmer water supports coral reef communities and tropical species
Greater species diversity but lower productivity than Benguela
iSimangaliso Wetland Park (UNESCO World Heritage Site) supports hippos, leatherback turtles, dugongs, sharks, whale sharks, dolphins
Meeting of Agulhas and Benguela at Cape Point creates extraordinary marine diversity
Animal Adaptations
Form Fits Function
🔬 Every Feature Has a Reason
An adaptation is any structural, physiological, or behavioural feature that increases an organism's fitness (ability to survive and reproduce) in its environment. Animal adaptations can be structural (body parts), physiological (internal chemistry), or behavioural (actions). Understanding WHY animals have particular features — and how these features relate to their environment — is a core exam skill.
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Structural Adaptations
Feeding Adaptations — Teeth, Beaks & Limbs
Diet determines anatomy. Compare carnivores, herbivores, and omnivores using teeth, digestive systems, and limb structure.
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Feature
Carnivore (e.g. lion)
Herbivore (e.g. cow)
Reason for Difference
Teeth
Large canines for killing/tearing; sharp carnassial teeth (shearing); reduced molars
No/reduced canines; large flat molars and premolars for grinding; incisors for cropping grass
Meat is soft and requires tearing; plant cell walls require crushing to release cell contents
Jaw movement
Mainly up-down (hinge-like); powerful bite force
Side-to-side (lateral) grinding motion possible
Grinding requires lateral jaw movement which carnivores' jaw joints prevent
Digestive tract
Short intestine — meat is easily digested; quick transit time
Very long intestine; rumen for bacterial fermentation of cellulose; multiple stomach chambers (ruminants)
Cellulose is indigestible without bacterial help; fermentation takes time; more gut area needed for nutrient extraction from low-nutrient plant material
Eyes
Forward-facing — binocular vision, good depth perception for judging distance to prey
Side-facing — wide field of view to spot predators approaching from any direction
Predators need to judge distance accurately; prey animals need maximum visual field for detecting predators
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Physiological Adaptations
Temperature Regulation — Ectotherms vs Endotherms
Behavioural, structural and physiological strategies to maintain body temperature — or cope without doing so.
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🦎 Ectotherm Strategies (e.g. lizards)
Basking — position body at right angle to sun to maximise heat absorption; increases body temperature to activity level
Seeking shade — move to cooler microhabitats when overheating