Plant and animal cells, along with fungi and protists cells, present all the typical features of eukaryotic cells. However, plants have some exclusive organelles and structures related to their physiology and ecology. For example, unlike animals, plants cannot move and have specialized organelles that help them produce their own food. Have you ever wondered where the crunchiness of celery, carrots, or apples come from? In the following, you will learn that and much more.
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Jetzt kostenlos anmeldenPlant and animal cells, along with fungi and protists cells, present all the typical features of eukaryotic cells. However, plants have some exclusive organelles and structures related to their physiology and ecology. For example, unlike animals, plants cannot move and have specialized organelles that help them produce their own food. Have you ever wondered where the crunchiness of celery, carrots, or apples come from? In the following, you will learn that and much more.
Plants have all the typical features of eukaryotic cells: plasma membrane, cytoplasm, nucleus, ribosomes, mitochondria, endoplasmic reticulum, Golgi apparatus, vesicles, and cytoskeleton.
You can go over our Eukaryotic Cells article for a quick review of the table comparing animal and plant cells.
Despite all these common components, plant and animal cells have some exclusive organelles that differentiate them:
Figure 1 below shows a generalized plant cell with its characteristic organelles and structures labeled, highlighting the organelles exclusively found in plant cells:
We will discuss the structure and function of vacuoles, plastids, and the cell wall. Technically, a cell wall is not an organelle, but we include it here as it is an important and distinctive structure in plant cells.
Vacuoles are abundant in plants and fungi, and have diverse functions. They are membranous sacs, similar to vesicles in structure, and sometimes these terms are used interchangeably. In general, vacuoles are larger (they are formed by the fusion of several vesicles) and can persist longer than vesicles. The bilayer membrane that delimits a vacuole is called the tonoplast. Vacuoles are mainly formed by the fusion of vesicles from the trans side of the Golgi apparatus (the one facing the plasma membrane) and are, therefore, part of the endomembrane system.
Depending on the tissue or organ, they will perform different functions and a cell can have several vacuoles with different functions:
Some protists form food vacuoles through phagocytosis, and others that live in freshwater have contractile vacuoles to expel the excess of water.
Plastids are a group of organelles that produce and store nutritious molecules and pigments (molecules that absorb visible light at specific waves) in plant and algae cells (Figure 2). They are present in the cytoplasm of different types of cells, surrounded by a double phospholipid bilayer membrane, and have their own DNA. They have specialized tasks depending on the cell function. They are very versatile and can change functions during cell life and some have specialized functions. We focus on three main groups of plastids:
Chloroplasts structure and function, and their origin, are described in more detail in the Mitochondria and Chloroplasts article.
Figure 2: A) Photosynthetic cells containing numerous oval-shaped chloroplasts. B) Amyloplasts containing starch granules.
Plant cells, along with fungi and some protists cells, have an external cell wall covering their plasma membrane (Figure 3). This wall protects the cell, gives structural support, and maintains the shape of the cell, thus preventing excess water uptake. In plants, the wall is made up of polysaccharides and glycoproteins. The exact composition of the wall depends on the plant species and the type of cell, but the main component is the polysaccharide cellulose (made up of glucose forming long, straight chains of up to 500 molecules). Other polysaccharides found in cell walls are hemicellulose and pectin.
Structurally, the cell wall is composed of cellulose fibers and hemicellulose molecules embedded in a pectin matrix. The different types of plant cells can be identified by the characteristics of their cell wall.
Cell walls from adjacent cells are glued by another layer of pectin (sticky polysaccharides, like the ones we eat in jelly) called the middle lamella. The components of the wall can be replaced if degraded or during cell growth. In some cells, the wall can become completely rigid when its composition changes and the cell stops growing.
The cell wall is responsible for the rigidity of plants and for keeping them upright. This results from the hydrostatic pressure from the central vacuole against the wall, as mentioned above. This is, in part, what gives them their crunchiness when we eat celery or a carrot, for example.
Plant cells still need to communicate with each other, even with a stiff cell wall. Channels called plasmodesmata allow direct communication between the cytoplasm of neighboring cells (Figure 4). The plasma membrane between neighboring cells is continuous along these channels, thus cells are not completely separated by their plasma membranes.
All plant cells have a cell wall and the thin middle lamella surrounding them. Plant cells specialized in support, and some involved in sap transport, produce a secondary cell wall that forms the wood in trees and other woody plants. Because of the rigidity of secondary cell walls and the impossibility to communicate, the cells inside die. Thus, the functions of resistance and transport in these cells are only accomplished when they die.
Here, we have referred to plant cell organelles and structures. The term organelle is widely used for almost any cellular structure, and this can be confusing sometimes.
A commonly accepted definition of organelle is a membrane delimited structure with a specific cellular function. Thus, all organelles are cellular structures, but not all cell structures are organelles. Most of the time, being delimited by a membrane seems to be a requirement to consider a cellular structure an organelle.
The cellular structures that are most commonly called organelles are intracellular (they are embedded in the cytosol) and membrane-bounded. So, we would commonly include the following as organelles in a plant cell:
Plant cell structures not delimited by a membrane are usually called structures or components in general, such as:
Thus, cellular structures can be inside or outside of the cell (the plasma membrane is a membrane that delimits the cell, but it is not membrane-bounded itself). The ribosome is typically called an organelle, but some authors are more specific and call them non membrane-bounded organelles.
In summary, depending on the author, the terms organelle and structure are normally interchangeable, and it is ok. The important thing is to know the structure and function of a cellular component and be able to classify them depending on a specific definition.
The table below provides a list of plant cell organelles and structures with a summary of their function:
Table 1: summary of plant cell organelles and structures and their general function.
Feature | General function | |
Nucleus (nuclear membrane, nucleolus, chromosomes) | Encloses the DNA, transcribes the information from DNA to RNA (specifications for protein synthesis), and is involved in ribosome production | |
Plasma membrane | The outer layer that separates the interior of the cell from the exterior, it interacts with internal membranes | |
Cytoplasmic organelles | ||
Ribosomes | Structures that build proteins | |
Endomembrane System
| Endoplasmic reticulum (smooth and rough regions) | Synthesis of proteins and lipids, modification of proteins, generates vesicles for intracellular transportation |
Golgi apparatus | Synthesis, modification, secretion, and packaging of cell products | |
Vacuoles | Diverse functions in storage, macromolecules hydrolysis, waste disposal, plant growth by vacuole enlargement | |
Peroxisomes | Degradation of small organic molecules. Produces hydrogen peroxide as a by-product, converting it into water | |
Mitochondria | Performs cellular respiration, generates most of cellular ATP | |
Chloroplasts | Performs photosynthesis, converting sunlight energy into chemical energy. Belong to a group of organelles called plastids. | |
Cytoskeleton: Microtubules, microfilaments, intermediate filaments, flagella | Structural support, maintains cell’s shape, involved in cell movement and motility (flagella are present in sperm cells of plants, except for conifers and angiosperms). | |
Cell wall | Surrounds the plasma membrane and protects the cell, maintains cell’s shape |
The typical organelles of eukaryotic cells are found in plant cells (plasma membrane, cytoplasm, nucleus, ribosomes, mitochondria, endoplasmic reticulum, Golgi apparatus, vesicles, and cytoskeleton). Besides they have vacuoles, plastids, and cell walls, exclusive of plant cells.
Chloroplasts (plastids in general) and mitochondria contain their own DNA and ribosomes.
Chloroplasts use light energy to produce sugar through photosynthesis in plants.
The central vacuole is the largest organelle in mature plant cells comprising up to 80% of a cell’s volume.
Lysosomes and centrioles are exclusive to animal cells and are absent in plant cells.
What distinctive structure does a plant cell have to avoid excessive uptake of water?
cell wall
Which of the following is the more common component of cell walls?
cellulose
What are plasmodesmata?
channels through the cell wall that allow intercellular communication
How can you know if the cell you are looking at under a microscope belongs to a plant?
absence of centrioles
Where can you find the middle lamella?
surrounding the cell wall
What function is similar in plastids and some vacuoles?
storage of nutritious molecules and pigment
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