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Chapter 4: Nutrition and Media 第四章:微生物营养和陪养基 The whole of nature, as has been said, is a conjugation of the verb to eat, in the active and passive. - William Ralph Inge Content • • • Nutrient requirement for microorganism Transferring of substance into cells Different medium for specific purpose Nutrition营养 • Nutrition 营养(作用) include: – Substance 物质 – Energy 能量 • – Nutrient 营养(物): Substance of nutritional values Nutritional requirements at elementary level在元素水平上的营养需求 • Revealed by cell's elemental composition – Macro-: C, H, O, N, S. P, K, Mg, Fe, Ca – Micro-: Mn, Zn, Ni, Co钴, Cu, Mo钼 • • Forms: Water, inorganic ions无机离子, small molecules, and macromolecules Either a structural or functional role Major elements, their sources and functions in bacterial cells Nutrient Requirements of Microbes微生物的六种营养要素 • • • • • • Carbon source 碳源 Nitrogen source 氮源 Energy 能量 Growth factor 生长因子 Inorganic substance 无机物 Water 水 1. Carbon Sources 碳源 • Carbon requirements: – A wide range, may also be energy source – Organic carbon, CO2 or CO, methane甲烷 • Heterotrophs 异养生物: organic carbon • Autotrophs 自养生物: CO2 as primary or sole carbon source Nutrient Requirements of Microbes Carbohydrate Catabolism 碳水化合物分解代谢 • • Carbohydrates oxidized as their primary source of energy 糖类作为主要能源 Glucose: most common energy source葡萄糖是最普遍的能源 – Respiration 呼吸作用 – Fermentation 发酵作用 2. ENERGY 能量 • • Light (the sun or lamps) Inorganic substances • Sulfur 硫, CO or ammonia 氨 • • Preformed organic matter Sugar, protein, fats etc. Energy Sources for Bacterial Growth • All living organisms require energy source – Phototrophs光能自养菌: radiant energy (light) – Heterotrophs 异养生物 = chemo(hetero)trophs 化能异养: use (oxidize) organic carbon form – Lithotrophs 无机营养生物= chemoautotrophs 化能自养: oxidize inorganic compounds 4 major nutritional types of procaryotes on the basis of carbon and energy sources 原核生物的四种营养类型 4 major nutritional types of procaryotes on the basis of carbon and energy sources 原核生物的四种营养类型 CRITICAL THINKING QUESTION • How would you go about isolating a microbe that used gasoline 汽油 for a food? Exxon Valdez Oil Spill • Approximately 11 million gallons of oil were spilled into the waters of Prince William Sound during the 1989 Exxon Valdez Oil Spill Prince – William Sound Oil Spill Recovery Institute MEOR Microbial enhanced oil recovery (MEOR) • In situ generation of CO2 for pressure and solubilization增溶 • microbial production of organic acids • • • • • conversion of hydrocarbons to lower MW production of surface active agents encouragement of consolidation凝固 of oil to droplets enzymatic modification of hydrocarbons viscosity improvement 3. NITROGEN Source 氮源 • N2, ammonia 氨, nitrate/nitrite 硝酸盐, or a nitrogenous 含氮的 organic compound (protein or nucleic acid) • Classification based on AA requirement – Amino-acid-autotrophs氨基酸自养生物:SCP – Amino-acid-heterotrophs 氨基酸异养生物 4. Inorganic Compounds 无机物 • Large amount: 10-3~10-4mol/L – P. S. K, Mg, Ca, Na, Fe • TRACE metals 微量金属: 10-6~10-8mol/L, – required by some enzymes – Include: Cu, Zn 锌, Co钴, Mn, Mo • E.g. K2HPO4, MgSO4: – supply 4 elements of greatest amount 5. Growth factors 生长因子 • Definition: Small amounts of certain essential organic compounds unable to be synthesized • Required to fulfill specific roles in metabolism • Results from either a blocked or missing metabolic pathway 起因于阻断或丢 失的代谢途径 – Auxoautotrophs 生长因子自养型微生物 – e.g E. coli – Auxoheterotrophs 生长因子异养型微生物: – e.g. Lactobacillus乳酸杆菌 Categories of Growth Factors • Purines and pyrimidines 嘌呤与嘧啶: • synthesis of nucleic acids (DNA and RNA) • Amino acids 氨基酸: • synthesis of proteins • Vitamins 维生素: • as coenzymes and functional groups of certain enzymes Question? Why are amino acid, purines, and pyrimidines often growth factors, whereas glucose is usually not? Nutritional types of major organisms 主要生物体的营养类型 • Eukaryotes 真核生物: – Photoautotrophic 光能自养(e.g. plants & algae) – heterotrophic 异养 (e.g. animals, protozoa原生动物, fungi) • Lithotrophy无机自养: – unique to procaryotes • Photoheterotrophy光能异养: – common in purple & green bacteria, only a few eukaryotic algae – Phototrophy 光能营养: not found in Archaea Different nutritional requirements • Vastly different nutritional requirements – E. coli: capable of synthesizing all organic compounds it needs – Leuconostoc mesenteroides 肠膜明串珠菌: need many externally provided organic compounds - extremely fastidious (nutritionally demanding) Fastidious orgnisms 需要复杂营养的生物体 • Require PREFORMED organic molecules like vitamins, AA, nucleic acids, carbohydrates; • In general pathogens need more PREFORMED organic molecules than non-pathogens • A simple rule of thumb: – "if humans can use something for food, many microbes will also love it". - humans are fastidious. – The reverse is not always true CRITICAL THINKING QUESTION • Why does it make sense from a nutritional standpoint 营养观点 that most pathogens are nutritionally fastidious? Nutrient Transportation 营养物质进入细胞方式 • Cytoplasmic membrane: selective transportation – Proteins in the membrane: • typically span the whole membrane, contacting with the outside environment and cytoplasm. • often require the expenditure of energy Four basic types of transport systems 四种传输方式 • • Simple (passive) Diffusion 单纯 (被动) 运输 Facilitated Diffusion 促进扩散 • • Group Translocation 基团转移 Active Transport 主动运输 Passive diffusion 单纯 (被动)扩散 • • • • Directed by laws of simple diffusion. • • • • Involves a protein to transport – specific No transport protein involved Nonspecific, energy is not required A concentration gradient not be generated. Figure 8.9 The diffusion of solutes across membranes Figure 8.11 The water balance of living cells shriveled shrink lysed Facilitated Diffusion 促进扩散 Solutes: not concentrated against gradient Energy: not required Not widely used in prokaryotes Figure 8.13 One model for facilitated diffusion Passive & Facilitated Diffusion Membrane-spanning transporters 穿膜运输蛋白 • In prokaryotes, membrane-spanning transporters typically contain 12 alpha helices that align with each other in a circle to form a channel through the membrane. 原核生物 的穿膜运输蛋白由12个螺旋形成穿膜的通道 Three individual transporters Group translocation 基团转位 • • • • Protein-substrate: chemical modification • Target NOT altered & accumulation of target occurs – inside conc. > external conc. • • Proteins: molecular pumps against a concentration gradient No actual concentration takes place Most requires energy. Catabolic pathways sometime use – Efficient: bring substrate into the cell and begin the breakdown process PEP glucose Mechanism of the phosphotransferase system Active transport 主动运输 Energy source: ATP or proton motive force (PMF) Figure An electrogenic pump Figure Cotransport Simple transporter: Lac permease Figure The sodium-potassium pump: a specific case of active transport Removal of phospho-head groups of membrane lipids immobilizes voltage sensors of K+ channels • Nature 451, 826-829 (14 February 2008) Figure Review: passive and active transport compared Summary of bacterial transport systems Discussion? • Why do microorganisms normally take up nutrients using transport proteins? What advantage is active transport compared to facilitated diffusion? 5 min each Manner to cultivate bacteria 细菌培养方式 • Liquid media 液体培养基: – used for growth of pure batch cultures 纯批量培养物生长: fermentation industry 发酵工业 • Solidified media 固化培养基:1~2% agar – Isolation of pure cultures 纯培养物分离 – Estimate viable bacterial populations 测活菌数 • Semisolid medium半固体培养基: 0.5% agar Culture Medium • Function: – Isolation & maintenance of pure cultures 纯培养的分离和保存 – Identification 鉴定细菌 • Example – Basal medium 基底培养基 – Minimal medium – NNN medium with blood含琼脂、盐及兔血的培养基for trypanosoma锥虫属 Principles of medium design and selection 培养基设计与选择的原则 • Objective 目的明确 – Bacterial mass or metabolism products? • Balanced nutrition 营养协调 – Ten-time-rule: H2O > C+energy > N source > P, S > K,Mg > growth factor • Appropriate physical & chemical condition – pH: • Bacteria: 7.0 ~ 8.0; Acetenomycets: 7.5 ~ 8.5 • Yeast: 3.8 ~ 6.0; Mould: 4.0 ~ 5.8 Osmotic pressure & aw: optimal aw 0.6~0.998 – • Economic 经济节约 Agar琼脂 - the usual gelling agent胶凝剂 • For solid or semisolid medium • A hydrocolloid水状胶体derived from red algae • Unique physical properties: – melts at 100 degrees – remains liquid until cooled to 45C at which it gels – Not metabolized by most bacteria – relatively inert – simply holds (gels) nutrients in aquaeous solution. – Nontoxic to most organisms Categories of Culture medium based on the composition 培养基分类 • Chemically-defined(synthetic)medium组合培养基 – Exact chemical composition is known – For growing fastidious organisms & nutritional requirements • Complex (undefined) medium天然复合培养基 – Composition is not known – contain biological origin (blood, milk, yeast or beef extract) - full range of growth factors – For most bacteria and fungi • Semi-defined medium 半组合培养基 A chemically-defined medium for growth of heterotrophic bacterium (pH 7.0) 异养菌 Defined enrichment medium富集培养基 for Thiobacillus硫杆菌属thiooxidans, a lithoautotrophic bacterium (pH 3.0) 无机自养菌 Complex medium for the growth of fastidious bacteria (pH 6.6) Medium for some specific bacteria • Pathogenic bacteria of animals: – complex medium复合培养基 • A few fastidious pathogens – Treponema pallidum 梅毒螺旋体, Mycobacterium leprae 麻风分支杆菌: artificial culture media & conditions not been established. Selective Media 选择型培养基 • Inhibits some bacteria while selecting others • Example: Brilliant Green Agar 碱性亮绿琼脂 – Dyes: inhibit the growth of Gram (+) – Selects for G (-) bacteria: most G.I. Tract infections Examples of Selective Media • EMB (Eosin Methylene Blue 伊红美兰培养基) – Dyes inhibit Gram (+) bacteria – Selects Gram (-) bacteria, especially E. coli – G.I. Tract infections caused by Gram (-) 深紫色,绿色金属闪光 Differential Media 鉴别培养基 • • Differentiates different organisms growing on the same plate Example: Blood Agar Plates (TSA with 5% sheep blood) 血琼脂平板 – differentiate different types of Streptococci 链球菌 Differential Media 鉴别培养基 for Hemolytic Streptococci 溶血链球菌 • Blood agar plates (TSA 大豆胰蛋白胨琼脂 with 5% sheep blood) 血琼脂平板 • lysis of RBC’s or not – Alpha: Incomplete lysis – Beta: Complete lysis – Gamma: No lysis Selective and Differential Media (I) 选择和鉴别培养基 • Mannitol Salt Agar 甘露醇盐琼脂 – Identify Staphylococcus aureus 金黄色葡萄球菌 – High salt conc. (7.5%) inhibits most bacteria – Sugar: Mannitol – pH indicator (→yellow when acid) Selective & Differential Media (II) • MacConkey’s Agar – used to identify Salmonella 沙门菌: pH Indicator – Bile salts 胆盐 & crystal violet: inhibits G+ – Lactose 乳糖 • Many Gram (-) enteric小肠的 non-pathogenic bacteria can ferment lactose, Salmonella can not Differentiation of C. diphtheriae 白喉杆菌 Selective enrichment medium for extreme halophiles 耐盐性生物富集培养基 (pH 7.4) TYPES OF CULTURE MEDIA Critical Thinking • You have two microorganisms that grow well in nutrient agar. Does that mean they would both grow well in the same minimal medium? Why? Key Points • Six major types of nutrients for microorganism 六大营养要素 • Four major nutritional types of procaryotes on the basis of carbon and energy • • • • sources Growth factor and its major categories Four basic types of nutrient transport systems Difference between synthetic medium and complex medium 合成与天然培养 基的区别 Application of selective medium and differential medium 选择与鉴别培养基的 应用