Last Tuesday in lab we studied about exploring the stomatal complexes of monocot leaf vs dicot leaf. We also learned about the internal structures of different leaves as well as their primary functions such as photosynthesis and transpiration. Stomatal Complexes of Monocot vs. Dicot Wheat cat grass is known Tritium vulgare, is monocot plant. Stomata of the wheat "cat-grass" (Tritium vulgare) consist of four cells, two guard cells and two subsidiary cells. The guard cells are specialized cells in the epidermis of leaves, stems and other organs that are used to control gas exchange. They are produced in pairs with a gap between them that form a stomatal pore. Broad bean is known Vicia faba, which is the dicot plant. Stomata plays a vital role in openings in the epidermal layer that allow for the exchange of gases. They allow for a plant to balance water inside and outside the cells. Guard cells allow for the opening or closing of the stomata with the internal hormone stimuli as well as external environmental factors. Pavement cells are simple cells with no real functions other than protecting the cells below them. Moreover, they help decrease water loss, and maintain an internal temperature. The most significant difference between the stomata of the monocots and the dicots is the shape of the guard cells. The monocot leaf has the narrow, dumbbell-shaped guard cells; whereas the dicot leaf has the pair-of-sausage shaped guard cells. Moreover, the monocot has the guard cells arranged in regular arrays, but the dicot has different paving. The monocot has stomata on both the upper and lower surface of the leaf. However, the dicot has stomata on the lower surface. Cross-Section of Corn Leaf (Zea mays) Corn leaf (Zea mays) is monocot, has parallel veins. Moreover, spongy mesophyll is composed of parenchyma cells that contain chloroplast for photosynthesis. It also has air spaces for gas exchange and produces carbohydrates by photosynthesis. The upper and lower epidermis protect the leaf from water, sealing water inside and preventing parasite's attack. Xylem transports water into the leaf while phloem begins the sugar transport down to the roots. Veins is consisted of xylem and phloem, and a surrounding bundle sheath. The internal structures of the monocot plants compared to the dicot plants made me surprised because I've always thought that their insides looks the same. However, there is a big difference. Guard cells of the monocot are narrow, dumbbell-shaped; but they are crazy-paving arrangement in the dicot. Stomata are located on both the upper and lower surface of the monocot leaf; whereas they are located only on the lower surface of the dicot leaf. During the lab, I felt difficulties in doing the cross-section of corn leaf because it needs a good skill technique to cut the cross-section. Finally, TA help me to finish the slide; the one I got that make me happy.
Submitted by Quyen Ta
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Oh man finally, I'm off of work. Now I can go to class and sit, I'm so tired of standing. Today's been a long day but now I have botany class! So here we are at lab and today's focus is about recognizing the tissues within stems and their functions, exploring the diversity of plant stems from different habitats, and seeing the difference between a monocot and a dicot plant. We did multiple cross sections of different types of plants. Let me tell you what! Cross sections are not easy. In order to get the best possible result you need to be able to cut the stem very thin. The problem for me is that my hand shakes too much, so it took me a couple tries to get a perfect cross section. One of my best cross sections is the broad bean stem, which can be seen in figure 1. This image was prepared and stained with Toluidine Blue O (TBO), and that's the reason we are able to see different colors and easily distinguish the different structures in this plant stem. The obvious thing you can notice between Figure 1 and Figure 2 is the complexity of a dicot structure. A distinct separation, that looks like a river that cuts through the forest, is called procambium. This separates the pith and the cortex of the stem. Not only that, comparing Figure 1 to Figure 2, their vascular bundle is very different from each other. In figure 1 you can see a separation between the xylem, which is responsible for transporting water and minerals, and the phloem, which is responsible for transporting food to the rest of the plant. But in figure 2 you can see that they're really close together, almost as if they were one. Now if we look closely at figure 1, you can see a blue stain on top of the phloem. That's what they call sclerenchyma, and we were told in class that this acts as a helmet and protects the phloem .
Now lets look at aquatic plants: Figure 3: These are images of a waterweed (Elodea). This is a cross section of its stem, and was stained with TBO. This image was taken under a compound microscope at about 40x. The second image is a zoomed in version of the first image. (Prepared and photographed by Taylor) The plant structure in land plants compared to aquatic plants is very interesting. I've always thought that since they are all plants, their insides looks the same. I'm obviously wrong. There is a big difference. In aquatic plants I was able to learn that they contain these huge, easily seen air spaces throughout the stem called aerenchyma. Looking at figure 3 above, you can see what I am talking about. These air spaces are very important to aquatic plants because it provides buoyancy and it allows easier circulation of gases. Now after this lab I should be an expert at distinguishing the aquatic plants and terrestrial plants just by looking at their cross sections. Author: John P.
In this week’s lab, we examined a celery (Apium graveolens)! A celery has many nutritional benefits. It contains antioxidants and beneficial enzymes, in addition to vitamins and minerals such as vitamin K, vitamin C, potassium, folate and vitamin B6. Within the celery stalk contains a left structure called a petiole. A petiole is a small stalk that attaches to the the leaf blade of the plant to the steam. Unstained cross section of celery petiole. (400x) Ground tissues in celery petiole
This is a photo of that vasular bundles, phloem and xylem taken at 100x magnification Lesson of the day! From this lab, I learned that parachyma cells are very easy to locate because they are most abundant in a cell. For some reason, I had a more difficult time locating the vascular bundles. I really enjoyed this lab and can't wait to see what else we get to see!
-Mylinh Nguyen |
AuthorContent is created by students participating in the Plant Structure course at Oregon State University for Winter 2017. Archives
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