WVU Biology 102 Exam 2 (2/12)

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Created by
Julia Stedman

Cards (88)

  • 3 steps of the synthesis reaction (Calvin cycle)
    Fixation, Sugar formation, and regeneration
  • 4 steps of the photo reaction of photosynthesis
    1. The water splitting photosystems strips water of electrons which are used to replace those lost when sunlight excites electrons in the thylakoid and moves them to the electron accepting molecules.
    2. The electrons that were excited in step 1 pump protons in and out of the thylakoid. This leads to the release of energy from the protons which is used to add a p-group to ADP, creating ATP (the 1st electron transport chain)
    3. Photosystem 1 (the NADPH producing system) takes electrons from inside the thylakoid and donates them.
    4. The 2nd electron transport chain occurs so that electrons are added to NADP + to create the energy carrier NADPH
  • Light independent reactions
    the "synthesis" reaction. Stored energy is used to generate glucose. This does not need light to function and takes place in the stroma.
  • Light dependent reaction
    he "photo" reaction. Sunlight is absorbed by chlorophyll and stored in ATP and NADPH. Light energy is captured and converted into stored chemical energy in the thylakoid which contains chlorophyll.
  • 2 phases of photosynthesis
    The Light dependent "photo" reaction, and the Light independent "synthesis" reaction
  • Replacement electrons
    electrons that come in to replace the ones that are being used in photosynthesis. they come from the break down of water in the water splitting photosystems and from the 1est electron transport chain in photosystem 1.
  • Oxygen in photosynthesis

    It is produced as a byproduct of photosynthesis. Come from the breakdown of water in the water splitting photosystems.
  • Plant biomass
    This does not come from the soil, it comes from the conversion of Carbon Dioxide into carbon based compounds.
  • ATP
    the major energy source for cells that is stored until needed. It decomposes into ADP + P and has potential energy stored in the unstable bonds between phosphates. When the bonds break some energy is released. Because one phosphate group is lost, we now have ADP. ATP is the changed , high energy state. The bond can break and reform easily, thus making them a good choice for energy storage. This is a result of the negative change on the phosphate .
  • Potential energy
    Energy that is stored due to position or composition. In photosynthesis Potential energy is stored in the bonds of ATP before the bonds are broken and the energy is released.
  • Kinetic energy in photosythesis
    Energy of motion. Literally any moving particle or thing. It involves rapidly moving particles. This includes movement of the body, heat, and light. this from the sun is either converted into potential energy and stored in the autotrophs or it is transformed into heat energy.
  • equation for photosynthesis
    6CO2 + 6H2O (sunlight)→ C2H12O + 6O2
  • Photosynthesis
    how autotrophs use sunlight to create energy by converting water and carbon dioxide into energy.
  • 3 ways that plants can obtain energy?
    Through photosynthesis, carnivory, and parasitism.
  • Native Plants
    indigenous plants to a specific area with established animal relationships.They have evolved with pollinators and herbivores that are already here and are therefore typically very successful.
  • Coevolution
    animals evolve alongside the plants so that they can still feed on the plant regardless of defensive chemicals. This results in the plants and herbivores being in an evolutionary battle of sorts where the plants want to defend themselves so they evolve chemicals, but the herbivore wants to eat the plant so they evolve immunity.
  • how chemical defenses can be used for humans
    to make spices, medicines, and pesticides.
  • Chemical defenses
    some plants produce chemicals called defensive compounds that make them toxic or taste bad to animals. Keeps the animals from eating plants due to the threat of illness or chemical deterrent, such as a bad taste or poison. They can be used as a chemical communicator to alert other plants that an herbivore is nearby. This causes the other plants to increase their defensive compounds. Sometimes these chemicals are detected by other animals. It can attract them to the plant to parasitize or predate the herbivore. This helps protect the plant yet again.
  • Physical Defenses
    these are things like thorns, bark, sticky traps. Any aspect of the plant that makes it physically difficult to eat. It prevents animals from eating it due to threat of injury.
  • 2 major
    types of herbivory defense
    Physical defenses and Chemical defenses
  • fruit
    a ripened ovary from a flower that attracts animals to disperse seeds from inside the fleshy material. Some fruits are not fleshy and developed inside the seed pod.
  • floral rewards
    This gives the animal a reason to come to the plant, offering either pollen, nectar, pleasing smells and colors, or a place to hide. This does , however, come at a steep energy cost for the plant.
  • Animals (as a pollination/fertilization/dispersal strategy)
    plant lures in animals to move pollen and for doing so gives the animal a reward or trickery. This strategy increases the chance of the pollen getting to the right place. This utilizes floral reward and gives the animal a reason to visit the flower.
  • Water (as a pollination/fertilization/dispersal strategy)

    this is not very common and is used by plants like Bryophytes. Sperm swims through water to get to the egg.
  • Wind (as a pollination/fertilization/dispersal strategy)

    This requires a huge amount of pollen. These rely mostly on chance, so it is very ineffective.
  • pollination
    The transfer of pollen from the anther of one flower to the stigma of another flower of the same species, plants have several different strategies to achieve this, namely wind, water, and animals.
  • Ovary
    Contains and protects the ovules which when fertilized, the ovules develop into seeds which the is protected when it becomes a fruit. female structure
  • Sepal
    modified leaves
  • Style
    elongated stalk of stigma. A female structure.
  • Filament
    male Structure that supports the stalk of the anther
  • Petals
    modified layers that attract pollinators
  • Anther
    male structure that produces pollen.
  • Stigma
    the sticky tip of the style that catches pollen. A female structure.
  • Eudicots
    One type of Angiosperm. has 2 cotyledons (making it a dicot), leaves that have branched veins, orderly ring of vascular tissue, flowers that part in multiples of 4 or 5, and one large taproot with many small offshoots.
  • Monocots
    One type of Angiosperm. it has one cotyledon, leaves with parallel veining; scattered bundles of vascular tissue in cross tissue, fibrous roots that branch immediately in all directions, and flowers that have petals that part in multiples of 3.
  • Angiosperm
    the most prominent plant type on earth today is this group. These were the final plant group to evolve. They are all flowering plants. There are two groups: the monocots and the eudicots.
  • The most prominent plant type on Earth today
    Angiosperm
  • zygote in gymnosperm reproduction
    When the pollen comes in contact with the female cone and fertilizes the ovule this is formed
  • Female gametes in gymnosperm reproduction
    Egg that turns into the seed. it is haploid.
  • Gymnosperm reproduction steps
    1. Pollen and ovules develop in male and female cones.
    2. Pollen is released and carried by the wind
    3. Some pollen comes in contact with the female cone and fertilizes the ovule.
    4. The fertilized ovule becomes an embryo, that then develops into a seed in the female cone.
    5. Seeds are releases and also dispersed by wind; when they reach the right conditions they germinate to new diploid plants