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Transcript
Cell Structure and Function Chapter 4 Early Discoveries Mid 1600s - Robert Hooke observed and described cells in cork Late 1600s - Antony van Leeuwenhoek observed sperm, microorganisms 1820s - Robert Brown observed and named nucleus in plant cells Developing Cell Theory Matthias Schleiden Theodor Schwann Rudolf Virchow Cell Theory 1) Every organism is composed of one or more cells 2) Cell is smallest unit having properties of life 3) Continuity of life arises from growth and division of single cells Cell Smallest unit of life Can survive on its own or has potential to do so Is highly organized for metabolism Senses and responds to environment Has potential to reproduce Structure of Cells All start out life with: – Plasma membrane – Region where DNA is stored – Cytoplasm Two types: – Prokaryotic – Eukaryotic Lipid Bilayer Main component of cell membranes Gives the membrane its fluid properties Two layers of phospholipids one layer of lipids one layer of lipids Figure 4.3 Page 56 Membrane Proteins Recognition protein Receptor protein extracellular environment lipid bilayer cytoplasm Protein pump across bilayer Protein channel across bilayer Protein pump Figure 4.4 Page 57 Why Are Cells So Small? Surface-to-volume ratio The bigger a cell is, the less surface area there is per unit volume Above a certain size, material cannot be moved in or out of cell fast enough Microscopes Create detailed images of something that is otherwise too small to see Light microscopes – Simple or compound Electron microscopes – Transmission EM or Scanning EM Eukaryotic Cells Have a nucleus and other organelles Eukaryotic organisms – Plants – Animals – Protistans – Fungi Animal Cell Features Plasma membrane Nucleus Ribosomes Endoplasmic reticulum Golgi body Vesicles Mitochondria Cytoskeleton Figure 4.10b Page 61 Plant Cell Features Plasma membrane Nucleus Ribosomes Endoplasmic reticulum Golgi body Vesicles Mitochondria Cytoskeleton Cell wall Central vacuole Chloroplast Figure 4.10a Page 61 Functions of Nucleus Keeps the DNA molecules of eukaryotic cells separated from metabolic machinery of cytoplasm Makes it easier to organize DNA and to copy it before parent cells divide into daughter cells Components of Nucleus nuclear envelope nucleoplasm nucleolus chromatin Figure 4.11b Page 62 Nuclear Envelope Two outer membranes (lipid bilayers) Innermost surface has DNA attachment sites Nuclear pore bilayer facing cytoplasm Nuclear envelope bilayer facing nucleoplasm Figure 4.12b Page 63 Cytomembrane System Group of related organelles in which lipids are assembled and new polypeptide chains are modified Products are sorted and shipped to various destinations Components of Cytomembrane System Endoplasmic reticulum Golgi bodies Vesicles Endoplasmic Reticulum In animal cells, continuous with nuclear membrane Extends throughout cytoplasm Two regions - rough and smooth Golgi Body Puts finishing touches on proteins and lipids that arrive from ER Packages finished material for shipment to final destinations Material arrives and leaves in vesicles budding vesicle Figure 4.15 Page 65 Vesicles Membranous sacs that move through cytoplasm Lysosomes Peroxisomes Mitochondria ATP-producing powerhouses Membranes form two distinct compartments ATP-making machinery embedded in inner mitochondrial membrane Mitochondrial Origins Mitochondria resemble bacteria –Have own DNA, ribosomes –Divide on their own May have evolved from ancient bacteria that were engulfed but not digested Specialized Plant Organelles Plastids Central Vacuole Chloroplasts Convert sunlight energy to ATP through photosynthesis Other Plastids Chromoplasts – No chlorophyll – Abundance of carotenoids – Color fruits and flowers red to yellow Amyloplasts – No pigments – Store starch Cytoskeleton Present in all eukaryotic cells Basis for cell shape and internal organization Allows organelle movement within cells and, in some cases, cell motility Flagella and Cilia microtubule Structures for cell motility 9 + 2 internal structure Figure 4.25 Page 73 dynein Plant Cell Walls Secondary cell wall (3 layers) Primary cell wall Plant Cuticle Cell secretions and waxes accumulate at plant cell surface Semitransparent Restricts water loss Matrixes between Animal Cells Animal cells have no cell walls Some are surrounded by a matrix of cell secretions and other material Prokaryotic Structure pilus cytoplasm with ribosomes DNA flagellum capsule cell plasma wall membrane