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Biology 1309 Prokaryotes 1 Topics Topics – Characteristics (comparison) – Cell Shapes, Arrangement, and Sizes – Classification – Nutrition 2 1 Remember the 3 Domains? • The Domains: – Archae – Bacteria – Eukaryotes • Characteristics include – – – – Ribosomes Membrane lipids tRNA antibiotics 3 Comparison (Pro vs. Eu) • No nuclear membrane • 0.2-2.0 um • No membraned organelles • Simple flagella, 2 proteins • Glycocalyx: capsule or slime layes • True nucleus • 10-100 um • Organelles (lysosomes, Golgi, ER, etc) • Complex flagella, microtubules • Possibly in those w/o cell wall 4 2 Comparison (cont.) • Complex cell wall (incl. • Simple cell wall, if peptidoglycan) present • Plasma membrane: • Plasma membrane: few if any sterols, no sterols and carbos carbos • No cytoskeleton or • Cytoskeleton, cyto cyto streaming streaming 5 Comparison (cont...) • Small Ribosomes- 70S • DNA: Single, circular, no histones • Binary fission • Recombination: no meiosis, fragment transfer only • Large ribosomes - 80S + 70S in organelles • DNA: Multiple, linear, w/ histones • Mitosis • Recombination: meiosis 6 3 7 Bacteria • • • • • • No membrane bounded organelles Peptidoglycans Antibiotic sensitivity Binary fission No Histones 70S ribosome 8 4 The Amazing Flagella: Three main parts of the flagella include the basal body, hook, and filament. Details of the basal body in gram negative cell 9 Different arrangements of flagella exist for different species. Some flagella arrangements. 10 5 Prokaryotic Sex! Pili enable conjugation, the transfer of DNA, from one bacterial cell to another. Three bacteria in the process of conjugating 11 Glycocalyx • Capsule – Protects bacteria from immune cells (sticky) • Slime layer – Enable attachment and aggregation of bacterial cells – loosely bound to the cell – associated with the formation of biofilms (eg. on teeth) 12 6 The capsule is tightly bound to the cell, and is associated with pathogenic bacteria. Capsule = halo Center = bacterial cell Encapsulated bacteria 13 Bacterial Cell envelope • Cell wall – Gram-positive – Gram-negative 14 7 Cell wall • Gram positive cell wall (+ Purple) – Thick peptidoglycan (PG) layer – Acidic polysaccharides – Teichoic acid and lipoteichoic acid • Gram-negative cell wall (- Pink) – – – – Thin PG layer Outer membrane Lipid polysaccharide Porins 15 Classification • • • • Phenotypic methods (biochemical + staining) Molecular methods (sequencing) Taxonomic scheme Unique groups 16 8 Archaea bacteria • Associated with extreme environments • Contain unique cell walls • Contain unique internal structures 17 The Hot Geysers in Yellowstone! 18 9 Archae • Lack peptidoglycans • Inhabit extreme environments – CH4 – Halophiles – Thermophiles • No Antibiotic sensitivity (!) • 70S ribosomes 19 Prokaryotic Nutrition 20 10 Nutrition: Sources of essential nutrients • Required for metabolism and growth – Carbon source – Energy source 21 Defined by Carbon Source • Heterotroph (depends on other life forms) – Organic molecules – Ex. Sugars, proteins, lipids • Autotroph (self-feeders) – Inorganic molecules – Ex. CO2 22 11 Growth factors • Essential organic nutrients • Not synthesized by the microbe, and must be supplemented • Ex. Amino acids, vitamins 23 Energy Source Types • Chemoheterotrophs • Photoautotrophs • Chemoautotrophs 24 12 Chemoheterotrophs • Derive both carbon and energy from organic compounds – Saprobic • decomposers of plant litter, animal matter, and dead microbes – Parasitic • Live in or on the body of a host 25 Photoautotroph • Derive their energy from sunlight • Transform light rays into chemical energy • Primary producers of organic matter for heterotrophs • Primary producers of oxygen • Ex. Algae, plants, some bacteria 26 13 Chemo organic autotrophs • Two types – Chemo organic autotroph • Derives their energy from organic compounds and their carbon source from inorganic compounds – Lithoautotrophs • Neither sunlight nor organics used, rather it relies totally on inorganics 27 Saprobe mode of action Extracellular digestion in a saprobe with a cell wall. 28 14 Nutritional categories summary (based on carbon and energy source) 29 4 Transport mechanisms • • • • Osmosis Diffusion Active transport Endocytosis 30 15 Osmosis • Diffusion of water through a permeable but selective membrane • Water moves toward the higher solute concentrated areas – Isotonic – Hypotonic – Hypertonic 31 Diffusion • Net molecule movement from high concentration area to low concentration area • No energy is expended (passive) • Concentration gradient and permeability affect movement 32 16 Facilitated diffusion • Transport of polar molecules and ions across the membrane • No energy is expended (passive) • Carrier protein facilitates the binding and transport – Specificity – Saturation – Competition 33 Active transport • Transport of molecules against a gradient • Requires energy (active) • Ex. Permeases and protein pumps transport sugars, amino acids, organic acids, phosphates and metal ions. • Ex. Group translocation transports and modifies specific sugars 34 17 Endocytosis • Substances are taken, but are not transported through the membrane. • Requires energy (active) • Common for eucaryotes • Ex. Phagocytosis, pinocytosis 35 18
