Chapter 7

1. Chapter 7 Cell Structure

2. The Discovery of Cells • Microscope observations of organisms led to the discovery of the basic characteristics common to all living things. • Scientists first discovered cells in the 1600s using crude microscopes. • Observations made by scientists using more powerful microscopes in the 1800s led to the formation of the cell theory.

3. Cell Theory • All living things are made up of one or more cells • Cells are the basic units of structure and function in organisms • All cells arise from existing cells

4. Looking at Cells • Cells vary greatly in their size and shape. • A cell’s shape reflects its function. • Cell size is limited by a cell’s surface area-to-volume ratio. • Cells can be branched, flat, round, or rectangular.

5. Looking at Cells, continued • All substances that enter or leave a cell must cross the surface of the cell. • A cell’s ability to move substances across its surface can be estimated by finding its surface area-to-volume ratio. • Cells with greater surface area-to-volume ratios can exchange substances more efficiently.

6. Looking at Cells, continued • When comparing cells of the same shape, small cells have greater surface area-to-volume ratios than large cells. • So, small cells function more efficiently than large cells.

7. Cell Features • All cells share common structural features, including • cell membrane • cytoplasm • ribosomes • DNA.

8. The cell membrane is the outer layer that covers a cell’s surface and acts as a barrier between the outside environment and the inside of the cell. • The cytoplasm is the region of the cell within the cell membrane. The cytoplasm includes the fluid inside the cell called the cytosol.

9. Cell Features, continued • A ribosome is a cellular structure that makes proteins. • The DNA of a cell provides instructions for making proteins, regulates cellular activities, and enables cells to reproduce.

10. Features of Prokaryotic and Eukaryotic Cells

11. Cell Features, continued Features of Prokaryotic Cells • A prokaryote is an organism made of a single prokaryotic cell. • Prokaryotic cells do not have a nucleus or other internal compartments. • The genetic material of a prokaryotic cell is a single loop of DNA. • For millions of years, prokaryotes were the only organisms on Earth.

13. Cell Features, continued Features of Eukaryotic Cells • A eukaryote is an organism made up of one or more eukaryotic cells. • All multicellular organisms are made of eukaryotic cells. • The DNA of a eukaryotic cell is found in an internal compartment of the cell called the nucleus. • All eukaryotic cells have membrane-bound organelles. • Anorganelle is a small structure found in the cytoplasm that carries out specific activities inside the cell.

15. Cell Features, continued • Each organelle in a eukaryotic cell performs distinct functions. • The complex organization of eukaryotic cells enables them to carry out more specialized functions than prokaryotic cells.

16. REVIEW • List the three parts of the cell theory • Describe the importance of a cell’s surface area-to-volume ratio • Compare the structure of a eukaryotic cell with that of a prokaryotic cell

17. The Framework of the Cell • Eukaryotic cells have an intricate network of protein fibers called the cytoskeleton which provides the interior framework of the cell. • The cytoskeleton helps the cell move, keep its shape, and organize its parts. • There are three different kinds of cytoskeleton fibers: microfilaments, microtubules, and intermediate fibers.

19. Directing Cellular Activity • DNA contains instructions for making proteins which control most of the activity of the cell. • The DNA of eukaryotic cells is stored in the nucleus. • DNA instructions are copied as RNA messages, which leave the nucleus • In the cytoplasm, ribosomes use the RNA messages to assemble proteins.

20. Directing Cellular Activity, continued Nucleus • A double membrane called the nuclear envelope surrounds the nucleus. • Nuclear pores located on the nuclear envelope act as channels to allow certain molecules to move in and out of the nucleus. • The nucleolus is a structure within the nucleus where ribosome parts are made. • These ribosome parts are transported out of the nucleus into the cytoplasm where they are assembled to form a complete ribosome.

22. Directing Cellular Activity, continued Ribosomes • Each ribosome in a cell is made of RNA and many different proteins. • Ribosomes that are suspended in the cytosol are called “free”ribosomes. • Free ribosomes make proteins that remain inside the cell.

23. Directing Cellular Activity, continued Ribosomes • Ribosomes that are attached to the membrane of another organelle are called “bound” ribosomes. • Bound ribosomes make proteins that are exported from the cell. • Ribosomes can switch between being bound or free, depending on what proteins the cell needs to make.

24. Protein Processing • Some proteins that a cell manufactures are needed outside the cell that makes them. • Proteins that are sent outside the cell are packaged in vesicles. • Vesiclesare small, membrane-bound sacs that enclose the proteins and keep them separate from the rest of the cytoplasm. • The endoplasmic reticulum and Golgi apparatus are organelles involved in preparing proteins for extracellular export.

26. Protein Processing, continued Endoplasmic Reticulum • The endoplasmic reticulum, or ER, is an extensive system of internal membranes that moves proteins and other substances through the cell. • The membranes of the ER are connected to the outer membrane of the nuclear envelope. • The endoplasmic reticulum is divided into two portions: rough ER and smooth ER.

27. Endoplasmic Reticulum (ER)

28. Protein Processing, continued Endoplasmic Reticulum • The portion of the ER with attached ribosomes is called rough ER because it has a rough appearance when viewed with an electron microscope. • The portion of the ER with no attached ribosomes is called smooth ER because it has a smooth appearance when viewed with an electron microscope. • The ribosomes on the rough ER make proteins that are packaged into vesicles. • Enzymes of the smooth ER make lipids and break down toxic substances.

30. Protein Processing, continued Golgi Apparatus • The Golgi apparatus is a set of flattened, membrane-bound sacs. • The Golgi apparatus helps modify, sort, and package cell products for distribution.

31. Golgi apparatus

32. Protein Processing, continued Making and Exporting Proteins • The ribosomes located on the rough ER make proteins which then cross into the membranes of the ER. • The ER membrane then pinches off and forms a vesicle around the proteins. • Vesicles transport the proteins from the rough ER to the Golgi apparatus, where they are modified by enzymes and repackaged in new vesicles. • These new vesicles transport the modified proteins to the cell membrane to be released outside the cell.

34. Storage and Maintenance Lysosomes • Vesicles help maintain homeostasis by storing and releasing a variety of substances as the cell needs them. • A lysosome is a vesicle produced by the Golgi apparatus that contains enzymes that break down large molecules. • Lysosomes recycle old or damaged organelles and digest food particles to provide nutrients for the cell.

35. Storage and Maintenance, continued Vacuoles • A vacuole is a fluid-filled vesicle found in the cytoplasm of many plant cells. • Plant cells contain a large compartment called the central vacuole, which stores water, ions, nutrients, and wastes. • When water fills the central vacuole, the cell becomes rigid, allowing the plant to stand up. • When the vacuole loses water, the cell shrinks, and the plant wilts.

37. Storage and Maintenance, continued Other Vacuoles • Some protists have contractile vacuoles which pump excess water out of the cell in order to control the concentration of salts and other substances. • A food vacuole is another type of vacuole. • It is formed when the cell membrane surrounds food particles outside the cell and pinches off to form a vesicle inside the cell.

38. Energy Production • Cells need a constant source of energy. • The energy for cellular functions is produced by chemical reactions that occur in the mitochondria and chloroplasts. • In both organelles, chemical reactions produce adenosine triphosphate (ATP), the form of energy that fuels almost all cell processes.

39. Energy Production, continued Chloroplasts • A chloroplast is an organelle found in plant and algae cells that uses light energy to make carbohydrates from carbon dioxide and water. • Chloroplasts are surrounded by two membranes and have several stacks of flattened sacs where energy production takes place.

40. Energy Production, continued Mitochondria • Mitochondria are cell organelles that use energy from organic compounds to make ATP. • Most of the ATP needed by a cell is produced inside mitochondria. • Both animal and plant cells contain mitochondria. • A smooth outer membrane and a folded inner membrane surround a mitochondrion. • ATP is produced by enzymes on the folds of the inner membrane.

41. Mitochondrion

42. REVIEW • Trace a protein’s path through the cell, from assembly to export • Contrast vesicle and vacuoles • Compare the role of mitochondria and chloroplasts • Which organelle produced proteins that are exported from the cell? • Nucleolus • Rough ER • Free ribosome • Bound ribosome

43. Diversity in Cells • Both prokaryotic and eukaryotic cells can have a variety of shapes and structures. • The function of a cell is determined by its shape and the organelles found in the cell. • The different organelles and features of cells enable organisms to function in unique ways in different environments.

44. Diversity in Cells, continued Diversity in Prokaryotes • Prokaryotes can vary in shape, the way they obtain and use energy, and their ability to move. • Many prokaryotes have a flagellum, a long, hair-like structure that grows out of the cell and enables the cell to move through its environment. • Prokaryotes may also havepili, short outgrowths that allow the cell to attach to surfaces or other cells.

45. Diversity in Cells, continued Eukaryotic Cell Specialization • Eukaryotic cells can vary in shape and external features. • Depending on their function, eukaryotic cells can also vary in their internal organelles. • For example, muscle cells, which use large amounts of energy, contain many mitochondria. • Animal and plant cells are two types of eukaryotic cells. • Both have many of the same organelles, but plant cells also have chloroplasts, a large central vacuole, and a cell wall.

46. Levels of Organization • Plants and animals have many highly specialized cells that are arranged into tissues, organs, and organ systems. • A tissue is a distinct group of similar cells that perform a common function. • An organ is a collection of tissues that work together to form a structure which performs a specific function. • An organ system is composed of a group of organs that work together to perform major body functions.

47. Body Types • Unicellular organisms can thrive independently or live together in groups. • Cells that are permanently associated but do not work together or integrate cell activities are called colonial organisms. • A multicellular organism is composed of many individual, permanently associated cells that coordinate their activities with each other. • True multicellularity occurs only in eukaryotes.

48. Body Types, continued • In a multicellular body, cells are interdependent. • Distinct types of cells have specialized functions to help the organism survive. • The individual cells in a multicellular organism cannot survive alone and are dependent on the other cells of the organism.

49. Must multicellular organisms begin as a single cell, which divides to form more cells. • These cells then grow and become specialized in a process called differentiation.

50. Review • Propose why muscle cells have more mitochondria than other kinds of eukaryotic cells do • List the four features that prokaryotic and eukaryotic cells have in common • Which specialized structures allow prokaryotes to move quickly through their environment? • Pili • Nuclei • Flagella • mitochondria