1 / 22

Biology 12.3 History Life on Earth: Life Invaded the Land

Biology 12.3 History Life on Earth: Life Invaded the Land. Life Invaded the Land. The Ozone Layer:. The sun provides both life-giving light and dangerous ultraviolet radiation. Early in Earth’s history, life formed in the seas where early organisms were shielded from ultraviolet radiation.

torin
Download Presentation

Biology 12.3 History Life on Earth: Life Invaded the Land

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. Biology 12.3 History Life on Earth: Life Invaded the Land Life Invaded the Land

  2. The Ozone Layer: • The sun provides both life-giving light and dangerous ultraviolet radiation. • Early in Earth’s history, life formed in the seas where early organisms were shielded from ultraviolet radiation. • These organisms could not leave the water because the ultraviolet radiation made life on dry ground unsafe.

  3. Formation of The Ozone Layer: • During the Cambrian Period and for millions of years afterwards, organisms did not live on the dry, rocky surface of Earth. • A slow change began to take place 2.5 billion years ago when photosynthesis by cyanobacteria began adding oxygen to Earth’s atmosphere.

  4. Formation of The Ozone Layer: • As oxygen began to reach the upper atmosphere, the sun’s rays caused some of the molecules of oxygen to chemically react and form molecules of ozone.

  5. Formation of The Ozone Layer: • In the upper atmosphere, ozone blocks the ultraviolet radiation of the sun. • After millions of years, enough ozone accumulated to make the Earth’s surface a safe place to live.

  6. Plants and Fungi on Land • The first multicellular organisms to live on land may have been fungi living together with plants and algae. • Such paired organisms were able to live on land because each group possessed a quality needed by the other; a symbiotic relationship. • Plants, which likely evolved from photosynthetic protists, could carry out photosynthesis. • In photosynthesis, plants use the energy from sunlight to make carbohydrates.

  7. Plants and Fungi on Land • Plants cannot, however, harvest needed minerals from bare rock. • In contrast, fungi cannot make nutrients from sunlight but can absorb minerals from bare rock. • Early plants and fungi formed biological (symbiotic) relationships called mycorrhizae which allowed them both to live on the harsh bare rock above water. Example of mushroom mycorrhizae Living off a tree’s roots

  8. Plants and Fungi on Land • Mycorrhizae, which exist today, are symbiotic associations between fungi and the roots of plants. • The fungus provides minerals to the plant, and the plant provides nutrients to the fungus. • This kind of relationship is called mutualism. • Mutualism is a relationship between two species in which both species benefit. • Through mutualism, plants and fungi began living together on the dry surface of land about 430 million years ago. Example of mushroom mycorrhizae Living off a tree’s roots

  9. Arthropods: • By 100 million years after their first union with fungi, plants had covered the Earth’s surface, forming large forests. • These land plants provided a food source for land-dwelling animals. • The first animals to successfully invade land from the sea were arthropods. • An arthropod is a kind of animal with a hard outer skeleton, a segmented body, and paired, jointed limbs. • Examples of arthropods include lobsters, crabs, insects and spiders. Scientists think a kind of scorpion was the first arthropod to live on land.

  10. Arthropods: • A unique kind of terrestrial arthropod, the insect, evolved from the first land dwellers. • Insects have since become the most plentiful and diverse group of animals in Earth’s history. • The success of the insects is probably connected to the their ability to fly. Insects were the first animals to have wings. • Flying allowed insects to efficiently search for food, mates and nesting sites.

  11. Vertebrates: • Avertebrateis an animal with a backbone. • Humans are vertebrates, as are almost all land animals we know of today. • According to fossil records, the first vertebrates were small jawless fishes that evolved in the ocean about 530 million years ago. • Jawed fishes appeared about 430 million years ago and allowed fish to bite and chew food instead of sucking it up. Early jawless fish: first vertebrate 530 Million Years ago First Jawed Fish 430 Million Years Ago

  12. Vertebrates: • As a result of the development of jaws and teeth; jawed fish became efficient predators. • This allowed them to become among the most successful and abundant of sea creatures; ruling the oceans like this for hundreds of millions of years • Fish soon came to be among the most abundant animals on Earth, making up half of all present day vertebrate species.

  13. Amphibians: • The first vertebrates to inhabit land did not come out of the sea until 370 million years ago. • Those first land vertebrates were early amphibians.

  14. Amphibians: • Amphibians are smooth-skinned, four-legged animals that today include frogs, toads, and salamanders. • Several structural changes occurred in amphibians when they adapted to land. • Amphibians developed moist breathing sacs called lungs which allowed them to absorb oxygen from the atmosphere.

  15. Amphibians: • The limbs of amphibians were thought to have derived from the bones of fish fins. • The evolution of a strong support system of bones in the region just behind the head made walking possible. • This system of bones provided a rigid base for the limbs to work against.

  16. Amphibians: • Because of the their strong, flexible internal skeleton, the bodies of vertebrates can be much larger than that of insects. • While amphibians were well adapted to their environment, a new group of animals more suited to a drier environment evolved from them.

  17. Reptiles: • Reptiles evolved from amphibian ancestors about 340 million years ago. • Modern reptiles include snakes, lizards, turtles and crocodiles. • Reptiles are better suited to dry land than amphibians because reptiles watertight skin slows the loss of moisture.

  18. Reptiles: • Reptiles also have a watertight egg. Unlike amphibians, reptiles can lay eggs on dry land. • Amphibians must lay their eggs in water or in very moist soil because their eggs are unable to retain enough water to remain alive.

  19. Mammals and Birds: • Birds hypothetically evolved from feathered dinosaurs during or after the Jurassic period. • Therapsids, reptiles with complex teeth and legs positioned beneath their body, gave rise to mammals about the same time dinosaurs evolved, during the Triassic period. • 65 million years ago, during the 5th mass extinction, most species disappeared forever. All the dinosaurs, except for the ancestors of birds, became extinct. • The smaller reptiles, mammals, and birds survived. Early feathered dinosaur Therapsid

  20. Mammals and Birds: • Although many resources were available to the surviving animals; the world’s climate was no longer largely dry. Things had changed. • Thus, the reptiles advantage in dryer climates was no longer of great importance in survival. • Birds and mammals than became the dominant vertebrates on Earth. Early feathered dinosaur Therapsid

  21. Mammals and Birds: • Both extinction and Continental Drift played important parts in evolution. • Continental Drift is the movement of Earth’s land masses over long periods of time. • Continental Drift resulted in the present day locations of the continents. • This separation and movement of the continents over time helps explain why large numbers of marsupial mammals species are found in both Australia and South America since both were once connected.

More Related