Chapter 4 A Tour of the Cell AP Biology Mrs. Gionta SC9 The Microscopic World of Cells • • • • Cells are marvels of complexity Trillions of cell in human body Many specialized types Main tool for exploration--Microscope Microscopes as Windows on the World of Cells • Light Microscope (LM) – Visible light projected through specimen – Lenses enlarge the image and project to eye – View living cells • Magnification – Increase in size, depends on lens • Resolving Power – Clarity of magnified image • Electron Microscope (EM) beam of electrons – Scanning Electron Microscope (SEM) • View cell surfaces – Transmission Electron Microscope (TEM) • View internal structures Microscopes as Windows on the World of Cells Microscopes as Windows on the World of Cells The 2 Major Categories of Cells The countless cells on earth fall into two categories: • Prokaryotic cells — Bacteria and Archaea • Eukaryotic cells — plants, fungi, and animals All cells have several basic features. • They are all bound by a thin plasma membrane. • All cells have DNA and ribosomes, tiny structures that build proteins The 2 Major Categories of Cells Prokaryotic and eukaryotic cells have important differences. Prokaryotic cells are older than eukaryotic cells. • Prokaryotes appeared about 3.5 billion years ago. • Eukaryotes appeared about 2.1 billion years ago. Prokaryotes • • • • Are smaller than eukaryotic cells Lack internal structures surrounded by membranes Lack a nucleus Have a rigid cell wall Idealized Prokaryotic Cell The 2 Major Categories of Cells Eukaryotes • Only eukaryotic cells have organelles, membranebound structures that perform specific functions. • The most important organelle is the nucleus, which houses most of a eukaryotic cell’s DNA. Idealized Eukaryotic Cell Overview of Eukaryotic Cells • Eukaryotic cells are fundamentally similar. • The region between the nucleus and plasma membrane is the cytoplasm. • The cytoplasm consists of various organelles suspended in fluid. • Unlike animal cells, plant cells have • Protective cell walls • Chloroplasts, which convert light energy to the chemical energy of food Membrane Structure • Separates living cell from nonliving surroundings • Regulates traffic of chemicals in and out of cell • Key to how it works is the structure Plasma Membrane: Lipids & Proteins • Phospholipids – Related to dietary fats – Only 2 fatty acid tails not 3 • hydrophobic – Phosphate group in 3rd position • Charged, hydrophilic • Phopholipid bilayer – 2-layered membrane – Proteins embedded in bilayer • Regulate traffic Plasma Membrane: Lipids & Proteins • Fluid Mosaic – Not static (fluid) – Diverse proteins (mosaic) – Phospholipids and proteins free to drift about in the plane of the membrane • Illness can result if membrane is compromised – Superbugs: staphylococcus aureus – MRSA – Flesh eating disease!! Cell Surfaces • Plant cells have rigid cell wall surrounding plasma membrane – – – – Made of cellulose Protect the cells Maintain cell shapes Keep cells from absorbing too much water • Cells connected via channels through cell walls – Join cytoplasm of each cell to neighbor – Allow water and small molecules to move between cells Cell Surfaces • Animal cells lack cell wall – Extracellular matrix • Sticky coating to hold cells together • Protects and supports cells • Cells junctions – Connect cells togther – Allow cells in tissue to function in coordinated way Genetic Control of Cell • Nucleus chief of the cell – Genes store information necessary to produce proteins – Proteins do most of the work of the cell Structure and Function of Nucleus • Nuclear Envelope – Double membrane that surrounds nucleus – Similar in structure to plasma membrane – Pores allow transfer of materials • Nucleolus – Prominent structure – Where ribosomes are made • Chromatin – Fibers formed from long DNA and associated proteins • Chromosome – One chromatin fiber The nucleus DNA, chromatin and chromosomes Ribosomes • Responsible for protein synthesis • In eukaryotic cells, ribosomes make in nucleus and transported into cytoplasm – Suspended in fluid making proteins that remain in fluid – Attached to outside of endoplasmic reticulum, making proteins incorporated into membranes or secreted by cell How DNA Directs Protein Production • DNA programs protein production in cytoplasm via mRNA • mRNA exits through pores in nuclear envelope, travels to cytoplasm, and binds to ribosomes • As ribosomes move along mRNA, genetic message translated into protein with specific amino acid sequence. How DNA Directs Protein Production DNA RNA Protein The Endomembrane System • Cytoplasm of eukaryotic cells partitioned by organelle membranes • Some are connected – Directly by membranes – Indirectly by transfer of membrane segments • Together form endomembrane system – Includes nuclear envelope, endoplasmic reticulum, Golgi apparatus, lysosomes and vacuoles Endoplasmic Reticulum (ER) • Main functioning facility in cell • Rough ER – Ribosomes stud the surface – Produce membrane and secretory proteins (i.e. salivary glands) – Products transferred via transport vesicles • Smooth ER – Lacks ribosomes on surface – Synthesis of lipids (steroids) – Helps liver detoxify drugs Endoplasmic Reticulum (ER) The Golgi Apparatus • Refinery, warehouse and shipping center • Products made in ER reach Golgi in transport vehicles • Receiving dock and shipping dock • Modifications by enzymes as products move from receiving to shipping – Phosphate groups added as tags for different destinations The Golgi Apparatus Lysosomes • Sac of digestive enzymes (animal cells) • • • • Proteins Polysaccharides Fats Nucleic acids • Develop from vesicles budding from Golgi • Food vacuoles – fuse with lysosomes, exposing food to enzymes for digestion – Small molecules from digestion leave the lysosome and nourish the cell. • Breakdown damaged organelles • Sculpturing feature – Digest webbing between fingers and toes Lysosomes Vacuoles • Sacs that bud from ER, Golgi or plasma membranes • Variety of size and function – Contractile vacuoles of protists pump out excess water in the cell. – Central vacuoles of plants • Store nutrients • Absorb water • May contain pigments or poisons Vacuoles Review of Endomembrane System Chloroplasts and Mitochondria • Energy Conversion • Cellular power stations Chloroplasts • Photosynthetic cells of plants and algae • 3 compartments – Space between membranes that surround chloroplast – Stroma: thick fluid – Network of disks and tubes • Grana: interconnected stacks of disks • Solar power pack Chloroplasts Mitochondria • Site of cellular respiration – Harvest E from food MQ and converts to ATP • Found in all eukaryotic cells • Structure – Enveloped by 2 membranes filled with matrix – Inner membrane has several infoldings (cristae) • Contain DNA that encodes their own protein Mitochondria The Cytoskeleton • Network of fibers extending throughout cytoplasm • Skeleton and muscles – Support and movement Maintaining Cell Shape • Series of fibers – Microtubules • Straight hollow tubes composed of proteins • Guide movement of chromosomes when cells divide – Intermediate filaments and Microfilaments • Both thinner and solid • Anchorage and reinforcement for organelles • Dynamic cytoskeleton (amoeboid movements) Maintaining Cell Shape Cilia and Flagella • Mobile appendages • Aid in movement • Flagella – Generally occur singly – Propel cell – Undulating whiplike motion • Cilia – Shorter and more numerous than flagella – Promote movement by back and forth motion – Some function to move fluid over tissue surfaces Cilia and Flagella