File - layfieldsci.com

... 3. What is the difference between a biotic and an abiotic factor? Give an example of each. Biotic – Living – Predators thin herd of deer, Abiotic – Non-Living – Natural Disaster (tornado) wipes out herd of deer. 4. Give an example of a predator-prey relationship. LION eats WILDEBEEST! 5. What level ...

Cells and energy - whsbaumanbiology

... 4.2 Overview of photosynthesis • Identify the reactants, products, and basic functions of photosynthesis. ...

Cellular Energy PPT

... – energy from NADH is used to split pyruvate into an alcohol and carbon dioxide – NADH is changed back into NAD+ – NAD+ is recycled to glycolysis ...

Cellular Respiration

... Cellular Respiration Cellular Energy •The Stages of Cellular Respiration Cellular respiration has two stages. •Glycolysis The first stage of cellular respiration is called glycolysis. •Aerobic and Anaerobic Respiration The second stage of cellular respiration is either aerobic respiration (in the p ...

Organic Compounds

... cyanides, carbonates and bicarbonates of metal ions, and a few others. There are many organic compounds and the large number is possible because of carbon’s ability to form strong covalent bonds to each other in addition to holding the atoms of other nonmetals strongly. The properties of carbon also ...

Chapter 6 Cellular Respiration

... • A cellular respiration equation is helpful to show the changes in hydrogen atom distribution. • Glucose – loses its hydrogen atoms and (consists of 1 proton and 1 electron) – becomes oxidized to CO2. ...

Biology I Chapter 2, Section 2 Nutrition and Energy Flow Ecologists

... 2. Eat other heterotrophs (lions kill and eat only other animals carnivores). 3. Scavengers do not kill for food but scavenge and eat animals that have already died (vultures). What would our ecosystems be like without scavengers? ...

BCPS Biology Reteaching Guide Ecology Vocab Card Definitions

... Biology Reteaching Resource ...

Document

... 1. What leaf structure allows for gas exchange? a. chloroplast c. inner membrane b. stomata d. chlorophyll 2. What is the source of oxygen that is released from plant cells as a result of photosynthesis? a. carbon dioxide c. glucose b. ATP d. water ...

PS 3 Answers

... [Sorry, but T/F question iv is a short answer really. My mistake. Anyway, if QH2 is made either from succinate or NADH oxidation it will, of course, have the same redox potential. The production of QH2 via Complex I pumps 4 net protons to the intermembrane space, but the same is not true for oxidati ...

Key - Elder Ecology LEQ Ecological Organization 1. Distinguish if

... Bacteria perform actions that are able to transform nitrogen gas into a usable form; nitrogen-fixing bacteria convert nitrogen gas into ammonia, then nitrite, and then nitrate, which plants can use. ...

2.2 WATER POLLUTION Definition: Any alteration in physical

... Sewage is a liquid waste, which includes human and house-hold waste waters, industrial wastes, ground wastes, street washings and storm waters. Sewage, besides about 99.9 percent water contains organic and inorganic matter in dissolved, suspension and colloidal states. Aerobic and anaerobic decompos ...

Energy and Respiration

... anaerobic respiration two molecules of ATP (energy) are produced. for every molecule of glucose used in the reaction. Likewise for lactate fermentation 2 molecules of ATP are produced for every molecule of glucose ...

Chapter 9: Cellular Respiration, Harvesting Chemical Energy

... ATP synthase is a protein complex that populates the inner membrane of the mitochondrion o It uses the movement of H+ ions in order to fuel the synthesis of ATP ATP Synthase is composed of four parts, each made up of multiple polypeptide o A rotor, knob, internal rob, and stator. Hydrogen ions flow ...

Chapter 9 Marine Ecology

MEMBRANE-BOUND ELECTRON TRANSFER AND ATP

... But, it can be converted from one form into another ...

Oxidative Phosphorylation

... Oxidative Phosphorylation • H+ transport results in an electrochemical gradient • Proton motive force: energy released by flow of H+ down its gradient is used for ATP synthesis • ATP synthase: H+ channel that couples energy from H+ flow with ATP synthesis ...

second exam2

... fatty acids involved contributes to this difference? The same chemical features present in lipids are also important in determining membrane fluidity. ...

Notes-Cellular Respiration

... • cellular respiration is the only way to continue generating a supply of ATP. • intense exercise, a person will huff and puff for several minutes in order to pay back the built-up ...

Metabolism II

... In total: 7 + 24 = 31 NADH corresponds to 31 x 2,5 = 77,5 ATP 7 + 8 = 15 FADH2 corresponds to 15 x 1,5 = 22,5 ATP 8 GTP corresponds to 8 ATP Summarised: 8 + 77,5 + 22,5 = 108 ATP Two ATP are used during the initial activation of the fatty acid The total ATP-yield will be 106 ...

Chapter 7

... these organisms need to rely on food for the making of energy (ATP) use oxygen and the molecules in food to make the food ...

Chapter 6 and 17 notes

... ATP: Useable form of energy Glycolysis: first step in aerobic or anaerobic respiration. Anaerobic: without oxygen Aerobic: with oxygen Oxidation: Reaction when an atom or molecule loses electrons Reduction: Reaction when an atom or molecule gains electrons, Fermentation: Glycolysis is followed by th ...

Notes

... Which one is darker? Why do you think there is that difference? ...

Bacterial Physiology and Metabolism

... sulfur bacteria inhabit the sediments of upwelling areas characterized by high sediment concentrations of soluble sulfide, and low levels of dissolved oxygen. The ecological implication of nitrate ammonification is that nitrogen is conserved within the ecosystem. Thiomargarita namibiensis is another ...

Chapter 5 Control of Microbial growth

... • Sterilization- the process of removing completely all microorganisms on or in a product • Sterile item- is free of microbes including endospores and viruses. • Disinfection- the removal of most or all pathogens on or in a material. Generally implies the use of an antimicrobial chemical. ...

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Microbial metabolism

Microbial metabolism is the means by which a microbe obtains the energy and nutrients (e.g. carbon) it needs to live and reproduce. Microbes use many different types of metabolic strategies and species can often be differentiated from each other based on metabolic characteristics. The specific metabolic properties of a microbe are the major factors in determining that microbe’s ecological niche, and often allow for that microbe to be useful in industrial processes or responsible for biogeochemical cycles.== Types of microbial metabolism ==All microbial metabolisms can be arranged according to three principles:1. How the organism obtains carbon for synthesising cell mass: autotrophic – carbon is obtained from carbon dioxide (CO2) heterotrophic – carbon is obtained from organic compounds mixotrophic – carbon is obtained from both organic compounds and by fixing carbon dioxide2. How the organism obtains reducing equivalents used either in energy conservation or in biosynthetic reactions: lithotrophic – reducing equivalents are obtained from inorganic compounds organotrophic – reducing equivalents are obtained from organic compounds3. How the organism obtains energy for living and growing: chemotrophic – energy is obtained from external chemical compounds phototrophic – energy is obtained from lightIn practice, these terms are almost freely combined. Typical examples are as follows: chemolithoautotrophs obtain energy from the oxidation of inorganic compounds and carbon from the fixation of carbon dioxide. Examples: Nitrifying bacteria, Sulfur-oxidizing bacteria, Iron-oxidizing bacteria, Knallgas-bacteria photolithoautotrophs obtain energy from light and carbon from the fixation of carbon dioxide, using reducing equivalents from inorganic compounds. Examples: Cyanobacteria (water (H2O) as reducing equivalent donor), Chlorobiaceae, Chromatiaceae (hydrogen sulfide (H2S) as reducing equivalent donor), Chloroflexus (hydrogen (H2) as reducing equivalent donor) chemolithoheterotrophs obtain energy from the oxidation of inorganic compounds, but cannot fix carbon dioxide (CO2). Examples: some Thiobacilus, some Beggiatoa, some Nitrobacter spp., Wolinella (with H2 as reducing equivalent donor), some Knallgas-bacteria, some sulfate-reducing bacteria chemoorganoheterotrophs obtain energy, carbon, and reducing equivalents for biosynthetic reactions from organic compounds. Examples: most bacteria, e. g. Escherichia coli, Bacillus spp., Actinobacteria photoorganoheterotrophs obtain energy from light, carbon and reducing equivalents for biosynthetic reactions from organic compounds. Some species are strictly heterotrophic, many others can also fix carbon dioxide and are mixotrophic. Examples: Rhodobacter, Rhodopseudomonas, Rhodospirillum, Rhodomicrobium, Rhodocyclus, Heliobacterium, Chloroflexus (alternatively to photolithoautotrophy with hydrogen)

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Microbial metabolism