{"id":189,"date":"2019-06-24T12:38:36","date_gmt":"2019-06-24T16:38:36","guid":{"rendered":"https:\/\/pressbooks.bccampus.ca\/053humanbiology\/chapter\/4-3-variation-in-cells\/"},"modified":"2026-01-15T17:15:29","modified_gmt":"2026-01-15T22:15:29","slug":"4-3-variation-in-cells","status":"publish","type":"chapter","link":"https:\/\/pressbooks.bccampus.ca\/053humanbiology\/chapter\/4-3-variation-in-cells\/","title":{"raw":"4.3\u00a0Variation in Cells","rendered":"4.3\u00a0Variation in Cells"},"content":{"raw":"Created by:\u00a0CK-12\/Adapted by Christine Miller\r\n
\r\n\r\n[caption id=\"attachment_185\" align=\"aligncenter\" width=\"400\"]\"Image Figure 4.3.1 A bacterium attacks a human erythrocyte. Both are cells.<\/em>[\/caption]\r\n

Bacteria\u00a0Attack!<\/h1>\r\n<\/div>\r\nThe colourful image in Figure 4.3.1 shows a bacterial cell (in green) attacking human red blood cells. The bacterium causes a disease called relapsing fever. The bacterial and human cells look very different in size and shape. Although all living cells have certain things in common \u2014 such as a plasma membrane and cytoplasm \u2014 different types of cells, even within the same organism, may have their own unique structures and functions. Cells with different functions generally have different shapes that suit them for their particular job. Cells vary not only in shape, but also in size, as this example shows. In most organisms, however, even the largest cells are no bigger than the period at the end of this sentence. Why are cells so small?\r\n
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Explaining Cell Size<\/h1>\r\n<\/div>\r\nMost organisms, even very large ones, have microscopic cells. Why don't cells get bigger instead of remaining tiny and multiplying? Why aren't you one giant cell rolling around school? What limits cell size?\r\n\r\nOnce you know how a cell functions, the answers to these questions are clear. To carry out life processes, a cell must be able to quickly pass substances in and out of the cell. For example, it must be able to pass\u00a0nutrients\u00a0and oxygen into the cell and waste products out of the cell. Anything that enters or leaves a cell must cross its outer surface. The size of a cell is limited by its need to pass substances across that outer surface.\r\n\r\nLook at the three cubes in Figure 4.3.2. A larger cube has less surface area relative to its volume than a smaller cube. This relationship also applies to cells \u2014 a larger cell has less surface area relative to its volume than a smaller cell. A cell with a larger volume also needs more nutrients and oxygen, and produces more waste. Because all of these substances must pass through the surface of the cell, a cell with a large volume will not have enough surface area to allow it to meet its needs. The <\/span>larger<\/em> the cell is, the <\/span>smaller<\/em> its ratio of surface area to volume, and the more difficult it will be for the cell to get rid of its waste and take in necessary substances. This is what limits the size of the cell.<\/span>\r\n\r\n \r\n\r\n \r\n\r\n \r\n\r\n[caption id=\"attachment_188\" align=\"aligncenter\" width=\"741\"]\"Image Figure 4.3.2 Surface area to volume ratio.<\/em>[\/caption]\r\n\r\n
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Cell Form and Function<\/h1>\r\n<\/div>\r\nCells with different functions often have varying shapes. The cells pictured below (Figure 4.3.3) are just a few examples of the many different shapes that human cells may have. Each type of cell\u00a0 has characteristics that help it do its job. The job of the nerve cell, for example, is to carry messages to other cells. The nerve cell has many long extensions that reach out in all directions, allowing it to pass messages to many other cells at once. Do you see the tail of each tiny sperm cell? Its tail helps a sperm cell \"swim\" through fluids in the female reproductive tract in order to reach an egg cell. The white blood cell has the job of destroying bacteria and other pathogens. It is a large cell that can engulf foreign invaders.\r\n
\r\n\r\n[h5p id=\"30\"]\r\n\r\nFigure 4.3.3 Human cells may have many different shapes that help them to do their jobs.<\/em>\r\n\r\n<\/div>\r\n
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Cells With and Without a\u00a0Nucleus<\/h1>\r\n<\/div>\r\nThe\u00a0[pb_glossary id=\"1363\"]nucleus[\/pb_glossary]\u00a0is a basic\u00a0cell structure\u00a0present in many \u2014 but not\u00a0all \u2014<\/em>\u00a0living cells. The\u00a0[pb_glossary id=\"1363\"]nucleus[\/pb_glossary]\u00a0of a cell is a structure in the cytoplasm that is surrounded by a membrane (the nuclear membrane) and contains\u00a0[pb_glossary id=\"1735\"]DNA[\/pb_glossary]. Based on whether or not they have a nucleus, there are two basic types of cells: [pb_glossary id=\"2191\"]prokaryotic[\/pb_glossary] cells and [pb_glossary id=\"1931\"]eukaryotic[\/pb_glossary] cells.\r\n

Prokaryotic Cells<\/h2>\r\n[caption id=\"attachment_188\" align=\"alignright\" width=\"392\"]\"Image Figure 4.3.3 Bacteria are prokaryotes, meaning they do not have a nucleus. Their DNA is contained in a region called the nucleoid.<\/em>[\/caption]\r\n\r\n[pb_glossary id=\"2191\"]Prokaryotic[\/pb_glossary] cells<\/strong> are cells without a nucleus. The [pb_glossary id=\"1735\"]DNA[\/pb_glossary] in prokaryotic cells is in the cytoplasm, rather than enclosed within a nuclear membrane.\u00a0 In addition, these cells are typically smaller than eukaryotic cells and contain fewer organelles.\u00a0 Prokaryotic cells are found in single-celled organisms, such as the bacterium represented by the model in Figure 4.3.3. Organisms with prokaryotic cells are called prokaryotes<\/strong>. They were the first type of organisms to evolve, and they are still the most common organisms today.\r\n
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Eukaryotic Cells<\/h2>\r\n[caption id=\"attachment_188\" align=\"alignnone\" width=\"2500\"]\"Image Figure 4.3.4 Eukaryotic cells, like this animal cell, contain a nucleus and many other membrane-bound organelles.<\/em>[\/caption]\r\n\r\n[pb_glossary id=\"1931\"]Eukaryotic[\/pb_glossary] cells<\/strong> are cells that contain a [pb_glossary id=\"1363\"]nucleus[\/pb_glossary]. A typical eukaryotic cell is represented by the model in Figure 4.3.4. Eukaryotic cells are usually larger than prokaryotic cells. They are found in some single-celled and all multicellular organisms. Organisms with eukaryotic cells are called eukaryotes<\/strong>, and they range from\u00a0fungi\u00a0to\u00a0humans.\r\n\r\nBesides a nucleus, eukaryotic cells also contain other\u00a0organelles. An\u00a0[pb_glossary id=\"1244\"]organelle[\/pb_glossary]<\/strong>\u00a0is a structure within the cytoplasm that performs a specific job in the cell.\u00a0Organelles\u00a0called\u00a0[pb_glossary id=\"1357\"]mitochondria[\/pb_glossary], for example, provide\u00a0[pb_glossary id=\"1342\"]energy[\/pb_glossary]\u00a0to the cell, and organelles called vesicles store substances in the cell. Organelles allow [pb_glossary id=\"1931\"]eukaryotic[\/pb_glossary] cells to carry out more functions than [pb_glossary id=\"2191\"]prokaryotic[\/pb_glossary] cells can.\r\n\r\nInterestingly, scientists think that mitochondria were once free-living prokaryotes that infected (or were engulfed by) larger cells. The two organisms developed a symbiotic relationship that was beneficial to both of them, resulting in the smaller prokaryote becoming an organelle within the larger cell. This is called [pb_glossary id=\"1206\"]endosymbiotic theory<\/strong>[\/pb_glossary], and it is supported by a lot of evidence, including the fact that mitochondria have their own [pb_glossary id=\"1735\"]DNA[\/pb_glossary] separate from the DNA in the nucleus of the eukaryotic cell. Endosymbiotic theory\u00a0will be described in more detail in later sections, and it's also discussed in the video below.\r\n\r\nhttps:\/\/www.youtube.com\/watch?v=FGnS-Xk0ZqU\r\n\r\nEndosymbiotic Theory, Amoeba Sisters, 2017.\r\n
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4.3 Summary<\/h1>\r\n<\/header>\r\n
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