Monocotyledons vs. Dicotyledons

Powerpoint: Monocotyledon and Dicotyledon
Lab: Dicotyledon and Monocotyledon Lab

Dicotyledon and monocotyledons are subclasses of class angiospermae (the flowering plants). These two subclasses of plants share the characteristics of flowering plants (flower, seed, fruit, stem, vascular tissue etc.). While they are named after the number of “seed leaves” that sprout from the growing plant (one for monocots and two for dicots), mature plants differ in many other respects (Table 1).

This lab, you will be trying identify several specimens as monocots or dicots based on some of the following characteristics.

Background on Angiosperm Reproduction 

Angiosperm reproduction involves the meeting of sperm and egg. However, an extra step occurs in angiosperms that does not occur in any other plant group: a second sperm fuses with the polar nuclei to form a triploid structure, known as the endosperm (3N).

In most plants, the endosperm provides the “food store” for the developing embryo (2N).

The endosperm also does something very strange, it will give rise to the “seed leaves” known as the cotyledon. Because the endosperm is triploid (3N), the cotyledon is also triploid.

Depending on if there is one triploid seed leaf or two triploid seed leaves, the plant is classified as a “monocotyledon” (“one seed-leaf”) or “dicotyledon” (“two seed leaves”).

However, the cotyledon will eventually wilt away. Then there shall be no signs that indicate whether a plant is a monocot or a dicot right? Thankfully,  not. There are many other signs to indicate whether a plant in its adult stage is a dicot or a monocot. We will be looking at five.

1. Leaves 

monocot vs dicot leaves

The veins of monocot leaves are usually straight and parallel.
The veins of dicot leaves usually form a branching network.

2. Stem and Root  

Stem: (Monocots) The vascular tissues are scattered across the cross section. (Dicots) the vascular tissues are arranged in a ring under the epidermis.

Root: (Monocots) The vascular tissues are arranged in a ring (Dicots) the vascular tissues are bunched together into the center. The xylems are arranged in a tiny “X” in the dead middle.

3. Flowers 

Monocot flowers usually have petals in multiples of 3’s.
Dicot flowers tend to have petals arranged in multiples of 4’s and 5’s.

4. Growth

Monocots stems usually do not grow thicker from year to year.
Dicot stems do usually grow thicker from year to year.

Practice: Try identifying the plants below as dicot or monocot! (Answers below)

A (Tree) 

B (Flower)

C (Blade of Grass)

D (Palm Leaf)

E (Fern)

 F (carrot cross section)

 G (Celery Cross section)

Monocotyledon and Dicotyledon (Answers to Practice)

 

Ferns

Block A (Alex, Brenda and Julia) 

Presentation: Ferns
Jeopardy Game: Jeopardy

Block C (Riley, Meaghen, Maya, Brittney, Paisley and Sierra)  

Presentation: Fern Structure and Functions (Block C)
Review Sheet with Answers: Fern Review Sheet Questions answers.

Pteropsida (Ferns) (Summary) 

Pteropsida, the ferns, are one of the first plants to have developed vascular tissue (xylem and phloem). Plants with vascular tissue are part of phylum Tracheophyta. These vascular tissue allow water, nutrients and sugars to be transported around the plant, allowing the plant to grow away from water and grow taller. Therefore, plants with vascular tissue are considered “true” land plants. However, as we will see, ferns are still somewhat dependent on water, as they still require water for reproduction. 

Structure and Function 

  

  • Frond – the visible part of the plant, the leaves. Note that unlike in algae and moss, these fronds are considered true leaves, since they have vascular tissue
  • Rhizome – creeping underground stems. (Note: RHIZOMES ARE NOT THE ROOTS OF FERNS) they are stems, their job is to anchor the fern to the ground.
  • Roots – true roots. For water and nutrient absorption.
  • Cuticle – a waxy layer on the top of leaves that help it to retain water
  • Vascular Tissue 
    • Xylem – transports water and nutrients upwards
    • Phloem – transports sugars up and down to everywhere the plant needs to go
  • Sorus (pl. Sori) – dots found on the underside of fronds. They are defined as a cluster of many many sporangia (sing. sporangium). These sporangia produce spores

Sori on the underside of the fern.

Fern Reproduction 

  1. The prothallus is the gametophyte (haploid, multicellular) stage of the fern life cycle. It is very small and rarely seen. On the underside, are the
    • Antheridium: produces sperm cells (N)
    • Archegonium: produces egg cells (N)
  2. Egg (N) fuses with sperm (N), creating zygote (2N). The zygote develops into multicellular embryo (2N), which then develops into the sporophyte. The sporophyte stage is the stage which we think of as “ferns”
  3. Sporophyte (2N) contains Sori, on its underside, which are clusters of sporangia.
  4. Each sporangium is responsible for producing spores via meiosis. The spores are therefore haploid.
  5.  The spores (N) develop into the haploid multicellular gametophyte: the prothallus.

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