Monthly Archives: April 2016

Plant Reproduction

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Powerpoint: Plant Reproduction Trends

  • Define Alternation of Generation
  • Describe the evolutionary trends of plant reproduction

One of the signature features of plants is that they reproduce via alternation of generations. Alternation of generations happen when in one complete life cycle, both asexual and sexual reproduction occurs. This is also accompanied by both haploid and diploid life stages.

In most plant life cycles (other than unicellular algae), there will be multicellular haploid and diploid stages.

We call the multicellular diploid stage the sporophyte. In ferns, gymnosperms and flowering plants, the sporophyte stages are the obvious stages. For example, the fern and trees are the sporophyte stage.

The purpose of the sporophyte:

  • To produce spores via meiosis
    • The spores, unlike the diploid multicellular stage are haploid 
  • To help the plant to disperse

The haploid spores will then duplicate to become the haploid, multicellular gametophyte.

The purpose of the gametophyte:

  • To produce gametes (eggs and sperm) by mitosis
  • These gametes can then be used for sexual reproduction.
  • Sexual reproduction creates new combinations of genes that may produce new traits better suited to the environment. They also provide a better chance at least some may survive.

When the haploid gametes (N) fuse, they create a single diploid (2N) cell called a zygote. This zygote will then duplicate and become a multicellular diploid organism: the sporophyte.

Vascular Tissue

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Learning Objectives

  • Identify the functions of vascular tissue (xylem and phloem)
  • Identify the plant groups that have vascular tissue
  • Identify some of the structures (stomata and root cortex) that facilitate water uptake
  • Describe the three forces that move water up the xylem

Powerpoint: Vascular Tissue

Because land plants no longer live in an aquatic environment where nutrients, water and nutrients are easily accessible from the environment, land plants must develop some structures that help to conduct all these essential ingredients. One of these evolutionary breakthroughs is vascular tissue.

Vascular tissue are specialized tissues in plants that help to conduct water, nutrients and sugars around to the parts of the plant that need it. They exist in ferns, gymnosperms and angiosperms. There are two types of vascular tissue:

Xylem

  • Carry water and nutrients
  • Carry their material upwards from the ground to the leaves of the plant
  • Made up of tracheid cells that have died

Phloem

  • Carry sugars
  • Carry their material downwards and upwards, though mainly downward, from the leaves to the rest of the plant
  • Made up of live cells with interconnected cytoplasm

 

But how does water move up into the plant though? Remember, water has no obligation to just move into the plant, so what mechanism do plants have to “suck” water into themselves?

There are three mechanisms that help with that:

  1. Capillary Action
  2. Root Pressure
  3. Transpiration

Capillary action: because water molecules are polar, each single water molecule is attracted to other water molecules. This creates cohesive forces between water molecules and other surfaces that cause water to be rise upwards in narrow spaces. However, because capillary action itself is a weak force, it alone cannot account for how water is able to move up plants.

Root Pressure: Roots also help water to move into the xylem by uptake of nutrients. First of all, let’s backtrack and think about osmosis.

Osmosis dictates that water will always move towards areas of higher solute concentration. Remember, solutes are anything, particles, that are dissolved in water. Concentration is not how much particles there are in the water, but more like how tightly the water are packed together. Therefore, in a beaker, with a semipermeable membrane where only water can go through, water will travel towards the area where the particles are more packed together.

To remember this, imagine that these solute particles were people packed in a room. Water will always travel towards the area where people are more packed together. This provides them with more room to move around in.

 

Roots take advantage of osmosis by moving nutrients into itself. While the cortex cells of roots cannot actively move water into its tissues, it can actively take in nutrients from its surroundings. By collecting nutrients, it creates a higher concentration of nutrients inside itself. Because of osmosis, the water will then naturally flow into the roots and into the xylem.

The rushing of water into the roots creates what is called root pressure. But even this is not enough to move water all the way up into a tall tree. There must be something else that moves water.

 

Transpiration: When you breathe out on a cold day, you’ll notice that a mist escapes into the air. This is the water particles from your breathe evaporating.

Did you know plants can do this too? Of course they don’t breathe the same way that people do, but they do have pores that expel water. These little pores are called stomata. They are like little holes on the underside of leaves. When they open and close, they take in carbon dioxide, and expel water to evaporation.

When the water evaporates off of leaves through the stomata, water will be pulled up from the soil, like drinking from a cup of water through a straw.

 

 

Plants General

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Powerpoint: Plants General

Learning Objectives

  • Identify the distinguishing characteristics of plants
  • Describe the evolutionary trend of plants from water to land
  • Describe the challenges of life on land
  • Identify the structures designed for life on land and which plants developed them
  • Explain how these structures help to meet the challenges of life on land

Members of Kingdom Plantae share the following characteristics: 

All members of Kingdom plantae are eukaryotic, which means plant cells have membrane bound nuclei and organelles.

Photosynthetic autotrophs 

Mostly multicellular

Cell walls made out of cellulose

Reproduce in a process known as alternation of generations (reproduce sexually and asexually) – Mistake in the powerpoint, plant life cycles include both an asexual and sexual stage of sexual reproduction.

Evolutionary Trend Amongst Plants

Kingdom Plantae is an extremely diverse kingdom, with many phyla and classes. Nevertheless, evolutionary trends exist to unify the groups. One of them is the movement of plants from a water environment to one on land. To explore this evolutionary trend, we will be focusing on five groups of plants.

Chlorophyta (Green algae)
Bryophyta (mosses, hornworts and liverworts)
Pteropsida (ferns)
Gymnosperms (focusing on coniferae)
Angiospermae (flowering plants)

But why would it be beneficial for plants to colonize the land in the first place? One of the reasons may be that the land has more direct sunlight. Perhaps at the time, the land was less competitive and provided new niches for plants.

Nevertheless, regardless of where plants live, they must have access  to the following: sunlight, water, nutreints, gas exchange, and a means for reproducing. Plants on a land or in a water environment will, however, have different means and difficulties of getting these necessary things.

Water Land
Sunlight Sunlight weaker in water Sunlight is stronger on land
Water Plenty of water Danger of drying out
Nutrients Bathed in Nutrients

All cells can obtain nutrients

 Access from soil only
Gas Exchange Diffuse into and out of water Diffuse into and out of air, but with danger of drying out
Reproduction Swimming gametes Dependence on standing water, wind, or animals

As we can see from the graph above, land plants have greater access to sunlight, but must meet the challenges of life on land, such as access to water, nutrients and new means for reproduction.

To meet these challenges, some land plants have developed structures.

1.Cuticle – a waxy outer layer on leaves that prevent water loss. It is usually found on the upper side of leaves.

2.Vascular Tissue – tube system in plants that help with transporting water, nutrients and the products of photosynthesis (sugars) around the plant.

3.Pollen Grain – The male reproductive structure of some land plants. It contains the sperm of the plant and is carried by wind or animals and allows for reproduction without water.

4.Seeds – seeds are a protective casing with nutrients that protect the embryo of a developing plant. It allows the plant to develop without the danger of drying out, allowing plants to develop in drier environments than ferns, algae or moss.

5.Fruits and Flowers – Flowers hold the reproductive structures of angiosperms (flowering plants). They often offer a nectar reward for animals, who will then go to other flowers and pollinate it. This allows a higher chance the pollen will actually reach its target (the female reproductive structure).

Flowers contain the seeds of angiosperms. Some are very well developed to provide a reward for animals that eat it, who will then travel and disperse the seed elsewhere along with their fecal matter.

  Algae Moss Ferns Conifers (Gymnosperms) Angiosperms
Cuticle

 

 

     Yes Yes Yes
Vascular Tissue

 

     Yes Yes Yes
Pollen Grain

 

 

       Yes Yes
Seed coat

 

 

       Yes Yes
Fruits and Flowers

 

         Yes

 

 

 

Compare and Contrast Essay

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Essay Outline

Sample Essay 

Forgetting or Remembering: Recovery from Trauma in “The Watch” and “I Lost My Talk”

How does someone recover after a traumatizing incident? Should one try to forget, or should they forgive? In “The Watch”, the protagonist suffers the traumatizing experience of losing his family and friends during World War II. In “I Lost My Talk”, the protagonist suffers the loss of her language and culture. In both pieces, the protagonists suffer extreme oppression and must find ways to recover from their trauma. In “The Watch” the protagonist chooses to try to forget his past, whereas in “I Lost My Talk”, the protagonist chooses to heal by recovering her culture and language.

In “The Watch”, the protagonist is reunited with a gold watch that symbolizes his past, which he re-buries in an effort to leave the past behind and move on. Throughout the story, it is implied that the watch holds great significance to the protagonist. When he unearths it after twenty years, he states, “could this thing … be my gift … my past” (Wiesel, 4). This statement suggests that the watch is a “memory of the past”, a symbol of the way things were (pg. 4). However, like his past has been damaged by the loss of family and friends from war, the watch has likewise lost its luster: it has become “unrecognizable [and] revolting” (pg. 4). Perhaps not wanting to be reminded of his past, the protagonist chooses to rebury the watch, and his past with it. In doing so, he hopes to provide “an epilogue to [his] childhood”, and closure to his trauma.

In contrast, the protagonist in “I Lost My Talk” tries to recover her memories of the past. Like in “The Watch”, the protagonist of “I Lost My Talk” suffered horrific trauma, but at the hands of the Canadian colonial society. Due to the time spent in residential schools, her language and culture had become a “scrambled ballad” (Joe, 9). In other words, she can no longer express herself in accordance to her culture. However, instead of abandoning her past, she decides to reclaim it. In contrast to the aggression of the colonial society as her language and culture are “snatched away” (Joe, 5), the protagonist “gently…offer[s] her hand” to try to recover her language and culture. In doing so, she hopes to recover a vital part of herself, such that she can “teach you about [herself]” (Joe, 15).

In conclusion, there are multiple ways to recover from a traumatizing event. In “The Watch” the protagonist chooses to try to forget his past and move forward in life, whereas in “I Lost My Talk”, the protagonist tries to recover her culture and language, to reclaim a vital part of her identity. Regardless of whether one chooses to forget or remember trauma bravely, recovery from trauma is clearly a difficult, but necessary process.

 

 

 

Fungi Phyla

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Powerpoint All Fungi Phyla

1. Oomycota The Protist-like Fungi

Oomycota are represented by organisms such as water molds and potato blight. They are closely related to the plant-like protists myxomycota. Both are multi-nucleate (they do not have cross walls, so the nuclei are floating freely in the mycelia).

  • Unlike most other Fungi, Oomycota cell walls are made out of cellulose, not chitin
  • They are capable of Asexual and sexual reproduction
  • They are the only ones to produce motile spores

2. Zygomycota The common molds

Zygomycota are represented by organisms such as black bread mold.

Their are three types of mycelia which serve different functions in:

  • Sporangiophores mycelia that stick straight up into the air. Their job is to hold the sporangia (the black ball of spores) up into the air
  • Stolon mycelia that travel along sideways, their job is to meet with another organism, where they can then exchange genetic information
  • Rhizoids mycelia that penetrate the surface of whatever the mold is growing on top of. Their function is to secrete enzymes to break down the food and absorb it.
  • Like Oomycota, they have no cross walls in their mycelia, therefore, they are multi-nucleate
  • Both asexual and sexual reproduction occur
  • Haploid in most life stages
  • Diploid zygospore (a zygospore is a structure that is created when two stolons meet, where genetic information is combined)

3. Ascomycota The sac fungi

Ascomycota are represented by organisms such as morel, cup fungi, yeast and cordyceps. They are named for the tiny sac like structures in their reproductive parts, called “ascus”.

  • Ascus – tiny sacs where haploid spores are produced for sexual reproduction
  • Ascospores – the tiny spores produced by sexual reproduction

Ascomycota are also capable of asexual repdocution. They have different structures for this:

  • Conidium – structure where spores are produced via mitosis. These spores have not been combined with another organism, which means they are genetically identical to the parent.
  • Condiospores – spores produced by asexual reproduction

4. Basidomycota The club fungi

Almost any of the organisms we think of as “mushrooms” belong to this phylum. For example: ling zhi, honey mushroom, fly agaric, white puffball, coral fungus and portobello mushrooms all belong to this phylum.

Most members in this phyla produces very elaborate reproductive structures. On the underside of mushrooms, are gills which contain many millions of basidia. These basidia produce basidiospores.

Basidia start out as dikaryotic cells (where two haploid nuclei exist in one cell; N+N). These two nuclei exist separately, originating from different organisms. Eventually the two nuclei will fuse to form a true diploid cell (2N). These diploid cells will then undergo meiosis to create haploid cells (N). These haploid cells are the spores, called basidiospores.

5. Deuteromycota The imperfect fungi

Deuteromycota is the miscellaneous pile of the kingdom. Any fungi that do not fit in the other four are placed in this phylum. However, they do share one trait in common: members of Deuteromycota do not have a sexual life cycle.

Examples of Deuteromycota include such things as Penicillium and Athlete’s foot.