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Even though eukaryotic cells are at the centre of human life and are more complex in comparison with prokaryotic cells, they are the minority. However, the intricacy of their structure and the complexity of their communication makes them extremely interesting for scientists, students and the general population at large. In this article, we'll delve into the world of eukaryotic cells and discover what makes them so special. So buckle up and get ready to be amazed!
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Jetzt kostenlos anmeldenEven though eukaryotic cells are at the centre of human life and are more complex in comparison with prokaryotic cells, they are the minority. However, the intricacy of their structure and the complexity of their communication makes them extremely interesting for scientists, students and the general population at large. In this article, we'll delve into the world of eukaryotic cells and discover what makes them so special. So buckle up and get ready to be amazed!
Specialised eukaryotic cells - muscle cell structure and function
A eukaryotic cell is a compartmentalised cell that contains membrane-bound organelles. The organelle that differentiates it the most from prokaryotes and is considered a key feature of eukaryotic cells is the nucleus.
There are four main types of eukaryotic cells: plant, animal, fungi and protozoan cells. In this article, we will mainly cover animal and plant cells. Unlike prokaryotes which do not have a nucleus, all eukaryotes have a nucleus.
Eukaryotic cells are quite varied: for starters, there are four main types of eukaryotic cells, each with particular characteristics that make them different from the rest. If we focus only on animal cells, the variety just increases: neurones, muscle cells, and skin cells, are all part of the same main group but they are all extremely different in shape and the location and proportion of organelles.
However, we've included the general diagram for an animal and a plant eukaryotic cell to help you understand the main components of eukaryotic cells.
Eukaryotic cells are extremely different from one another. Depending on the type (animal, plant, fungal or protozoan cell) and the specific function, they can have different organelles, or a different distribution or proportion of them. However, there are some key components that are shared by all or most eukaryotic cells:
Nucleus: The nucleus is a membrane-bound organelle that houses the cell's genetic material, the DNA. It serves as the "brain" of the cell, directing its activities and ensuring the proper functioning of the cell.
Mitochondria: These organelles are known as the "powerhouses" of the cell because they generate the energy needed for cellular activities.
The endomembrane system: from the nucleus to the plasma membrane, the membranes of the cell organelles are all connected. The nuclear membrane is directly connected to the endoplasmic reticulum (ER), involved in the synthesis, folding, and modification of proteins. The ER in turn connects with the Golgi apparatus by the exchange of vesicles, and the Golgi apparatus sends some vesicles to the plasma membrane too, to secrete substances or to regenerate parts of the plasma membrane.
Ribosomes: ribosomes are the protein producers of the cells, and prokaryotes also have them. They are not membrane-bound.
Peroxisomes: Peroxisomes are vesicles that contain enzymes that detoxify harmful substances and reactive oxygen species.
Cytoskeleton: the cytoskeleton is a complex and interconnected protein structure that gives the cell structural support, helps with transporting molecules and vesicles around the cell and is needed for cell motility. Prokaryotes also have a cytoskeleton, but it's much less complex that the eukaryotic version.
Cell wall: animal cells do not have a cell wall, but plant, fungal and protozoan cells do. In each case, they are made of a different substance. Plants' cell wall is made of cellulose, while fungal ones are made of chitin. The protozoan cell wall can be made of either molecule, and some protozoans have no cell wall at all.
Each type of eukaryotic cell can have a different combination of organelles or cellular structures, as represented in the following diagrams:
As mentioned, the main differences between eukaryotic cells and prokaryotic cells are that eukaryotes have a nucleus. Instead of a nucleus, prokaryotes have loose chromosomes that contain DNA information that are floating in the cytoplasm.
Bacteria and other cells can also contain plasmids - small, circular DNA. Interestingly, these are separate from the main prokaryotic chromosome and will replicate independently. Almost like a mind of its own! Plasmids often provide a genetic advantage and rarely have essential genes - this is where antibiotic resistance can occur. In addition, cells can exchange these plasmids via bacterial conjugation. Prokaryotes are "smart" with their adaptations.
Eukaryotes also have extra DNA apart from the one contained in the nucleus: mitochondria and chloroplasts, for example, have their own genetic material.
Bacterial conjugation: DNA plasmids are transferred between two bacteria via a pilus (hair-like appendage). This is called horizontal gene transfer because it happens between cells that do not have a mother-daughter relationship.
Below you will find a table showing the main differences between eukaryotic and prokaryotic cells, also known as the ultrastructure or the composition of eukaryotic cells.
Prokaryotic cells | Eukaryotic cells | |
Size | 1-2 μm | Up to 100 μm |
Compartmentalisation | No | Yes - the compartments of the eukaryotic cell are built by plasma membrane |
DNA | Circular, in the cytoplasm, no histones | Linear, in the nucleus, packed with histones |
Nucleus | No | Yes |
Other membrane-bound organelles | No | Yes |
Plastids | No | Yes |
Plasmids | Yes | No |
Cell division | Binary fission | Mitosis and meiosis |
Cell wall | Peptidoglycan (bacteria) | Cellulose (plant cells), chitin (funga cells). Animal cells don't have a cell wall. |
Plastids and plasmids are very different things: plastids are membrane-bound organelles, the most known of which are chloroplasts (the ones in charge of photosynthesis). Plasmids are, as mentioned above, circular DNA that contain prokaryotic genes that give bacteria some kind of evolutionary advantage.
Because the presence of the nucleus is the most important difference between eukaryotic and prokaryotic cells, we'll have a closer look at this crucial organelle.
The cell nucleus is a membrane-bound organelle that stores the cell's DNA and controls the cell's activities. The nucleus is enclosed by a double nuclear membrane, continuous with the endoplasmic reticulum.
The parts of the nucleus are:
The nucleus is usually one of the most prominent features in eukaryotic cells. The vacuole in plants is usually bigger, but there are multiple stainings that are designed to detect the nucleus.
Even though we are insisting that all eukaryotic cells have a nucleus, you should remember that erythrocytes do not have a nucleus, since they lose it during their maturation. However, they are still considered eukaryotic cells.
For example, DAPI (4',6-diamidino-2-phenylindole) is a fluorescent dye that binds to DNA. When looked at under the microscope with fluorescent light, the DAPI dye emits blue light that can be caught by the human eye, so we can see the nucleus in blue.
The size of eukaryotic cells varies quite a bit. Eukaryotic cells are usually bigger than prokaryotic cells, ranging from 10–100 µm, making them up to 1000 times bigger than prokaryotic cells. When referencing cell size, we are referring to the diameter. Animal cells are usually up to 30 µm, while plant cells can reach 100 µm.
The shape of eukaryotic cells varies immensely. Generic animal cells are typically depicted as round. However, we know that the membrane around animal cells is fluid and mostly made of phospholipids, meaning that the shape of the animal cell is irregular, and usually adapted to its function: neurones and muscle cells have particular shapes to aid their role in the body.
On the other hand, a plant cell has a more restricted shape similar to a cube/rectangle due to the presence of a cell wall.
The definition for eukaryotic cells (cells that have a defined nucleus) is so general, that as you can imagine there are plenty of examples of eukaryotic cells. We can use these examples to better understand the variability of eukaryotic cells, and how the function of a cell influences the location and presence of organelles. Here are some broad cell type categories to illustrate how cell shape can vary:
Let's compare the types of muscle cells to explain how function conditions the structure and organelles present in a cell.
Muscle cells are, as the name indicates, cells that form the muscle fibres of our body. There are three types of muscle cells:
Skeletal muscle cells: these are the type of muscle cells that are responsible for voluntary movement and are attached to the bones of the skeleton. Skeletal muscle cells are long and cylindrical in shape and contain multiple nuclei. Skeletal cells are striated.
Smooth muscle cells: these muscle cells are found in the walls of internal organs, such as the stomach and intestines and are responsible for involuntary movement. Involuntary movement means that you don't realise or consciously order a part of your body to move, but it's still moving. For example, the intestines make wave-like movements to move the food down the digestive tract, known as peristalsis. Smooth muscle cells are spindle-shaped and contain a single nucleus.
Cardiac muscle cells: cardiac muscle (cardiomyocytes) cells are responsible for heart contraction and blood pumping. They are shorter and thicker than skeletal muscle cells and contain a single, central nucleus. Cardiomyocytes are capable of contracting independently, without the need for neuronal stimulation, although the contraction is still due to changes in membrane polarity. Cardiac muscle is also striated.
Even though they have a lot of differences, muscle cells also share some traits compared to other cell types. They are:
However, their specific function (bone, involuntary or heart movement) conditions the cell's shape and structure.
Skeletal muscle cells are very long compared to other muscle cells because they need that larger length to have enough attachment to the bones they move and to generate the force to pull or push them to allow you to move. Because they are so large, they need several nuclei to swiftly coordinate throughout the cell and contract or relax the striated muscle.
Skeletal and cardiac muscle cells are called "striated" because under the microscope they appear to have stripes. This is because they have sarcomeres which are the basic contractile unit of these cells. Sarcomeres are highly organised protein complexes made of myosin and actin that lengthen and shorten to contract or elongate the muscle cell. When this happens coordinatedly with the cells of a whole muscle, the muscle contracts or relaxes. Sarcomeres are crucial when strong and fast contractions are necessary. Myoglobin is also essential in these two types of cells due to the rate of contraction that is sometimes needed. Myoglobin is an oxygen-bound protein that helps deliver oxygen to the mitochondria within the cells and thus avoids oxygen deprivation when muscles are generating a lot of energy.
Because cardiomyocytes are not as big as skeletal muscle cells, they can have a single nucleus. It is essential that they coordinate perfectly to avoid any issues with the heart's pumping rate, and this is achieved more easily with one nucleus in this case.
Smooth muscle cells, however, don't have sarcomeres, and thus, do not have the striated look under the microscope. They still have an arrangement of filaments that allow them to contract, but their distribution is different. They also do not have myoglobin. Therefore, the contraction speed of smooth muscle is much slower.
We hope that you now understand clearly what a eukaryotic cell is, and how function always determines structure, even at the very basic of biological levels!
A eukaryotic cell is a compartmentalised cell that contains organelles such as a nucleus and mitochondria.
The most important difference between prokaryotes and eukaryotes is that eukaryotes have a nucleus (and other membrane-bound organelles).
Animal, fungal, plant and protozoan cells are all eukaryotic. They, however, have significant differences between each other, like the presence or composition of the cell wall.
Eukaryotic cells can specialise significantly. Each specialised cell has a particular shape and organelle distribution that answers to the function they carry out.
The difference between prokaryotic and eukaryotic cells is that prokaryotes do not have a nucleus or membrane-bound organelles., while eukaryotic cells have a nucleus and membrane-bound organelles.
Eukaryotic cells vary a lot in size, but usually, animal cells are 10-30 micrometres, and plant cells 10-100 micrometres.
Yes all eukaryotic cells have a nucleus, even if they are unicellular organisms, they are still considered eukaryotes if they have a nucleus
A cell with membrane bound organelles and membrane bound organelles. They are more complex than prokaryotic cells. They are most commonly found in multicellular organism, such as plants or animals.
Eukaryotic cells can form multicellular organisms in which the cells adapt to do specific functions.
The four main examples of eukaryotic cells are animal, plant, fungal and protozoan cells. Within those classes, there are many more eukaryotic cell examples like neurones or muscle cells.
What main types of eukaryotic cells are there?
Animal, Plant, Funghi, Protist
What organelle gives eukaryotes their name?
The nucleus
What organelles do plant cells have that animal cells do not?
Chloroplasts, cell wall, center vacuole
What organelle is responsible for photosynthesis?
Chloroplasts
What is the main function of animal vacuoles?
Storage of substances
What are the functions of plant vacuoles?
Regulate PH, control size, control turgor
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