Ch. 7 Cellular Respiration
... own food. heterotroph 3. ____________ an organism that gets its food from another source cellular respiration 4. ____________ the process by which cells make ATP by breaking down organic compounds. ...
... own food. heterotroph 3. ____________ an organism that gets its food from another source cellular respiration 4. ____________ the process by which cells make ATP by breaking down organic compounds. ...
Cell Respiration Notes Kelly
... Each NADH makes 3 ATP (drops its electrons at top of ETC; hits all 3 proton pumps) Each FADH2 makes 2 ATP (drops its electrons at Q; skips 1st proton pump; so makes less ATP) Electrons passing down ETC provide energy for pumping H + ions into INTERMEMBRANE SPACE Final electron acceptor at end of ETC ...
... Each NADH makes 3 ATP (drops its electrons at top of ETC; hits all 3 proton pumps) Each FADH2 makes 2 ATP (drops its electrons at Q; skips 1st proton pump; so makes less ATP) Electrons passing down ETC provide energy for pumping H + ions into INTERMEMBRANE SPACE Final electron acceptor at end of ETC ...
Cell Respiration Notes
... Each NADH makes 3 ATP (drops its electrons at top of ETC; hits all 3 proton pumps) Each FADH2 makes 2 ATP (drops its electrons at Q; skips 1st proton pump; so makes less ATP) Electrons passing down ETC provide energy for pumping H + ions into INTERMEMBRANE SPACE Final electron acceptor at end of ETC ...
... Each NADH makes 3 ATP (drops its electrons at top of ETC; hits all 3 proton pumps) Each FADH2 makes 2 ATP (drops its electrons at Q; skips 1st proton pump; so makes less ATP) Electrons passing down ETC provide energy for pumping H + ions into INTERMEMBRANE SPACE Final electron acceptor at end of ETC ...
Chapter 2 - Jenksps.org
... Symbiosis means ________________________. Three kinds of symbiosis are ...
... Symbiosis means ________________________. Three kinds of symbiosis are ...
Cell Respiration Flow Chart
... Step 5.T he final process of cellular respiration takes place on the inner membrane of the mitochondria. This inner membrane is much larger than the mitochondria’s outer membrane. In mitochondria that are in the liver, the inner membrane is nearly five times the area of the outer membrane. In mit ...
... Step 5.T he final process of cellular respiration takes place on the inner membrane of the mitochondria. This inner membrane is much larger than the mitochondria’s outer membrane. In mitochondria that are in the liver, the inner membrane is nearly five times the area of the outer membrane. In mit ...
Name CELLULAR RESPIRATION URL: http:://www.2.nl.edu/jste
... How long does each turn of the cycle take? Make sure you can account for the “in’s and out’s) on the summary table for the Citric Acid Cycle. ...
... How long does each turn of the cycle take? Make sure you can account for the “in’s and out’s) on the summary table for the Citric Acid Cycle. ...
Major roles of Organisms in ecosystems
... How does each organism fit so precisely into the scheme of things? The process that leads to such a close fit is known as NATURAL SELECTION. The mechanisms of natural selection are: Genes, Populations and Species Genes are distinct pieces of DNA that determine the characteristics that an individual ...
... How does each organism fit so precisely into the scheme of things? The process that leads to such a close fit is known as NATURAL SELECTION. The mechanisms of natural selection are: Genes, Populations and Species Genes are distinct pieces of DNA that determine the characteristics that an individual ...
Adenosine Triphosphate (ATP)
... 2. In photosynthesis, light energy is converted into ___________ energy. This is called ___________________. 3. In what organelle does photosynthesis occur? 4. On what part of the chloroplast does the light dependant reaction take place? What are the four products of the reaction? 5. What is another ...
... 2. In photosynthesis, light energy is converted into ___________ energy. This is called ___________________. 3. In what organelle does photosynthesis occur? 4. On what part of the chloroplast does the light dependant reaction take place? What are the four products of the reaction? 5. What is another ...
Chapter 6 How Cells Harvest Chemical Energy Overview All living
... them to generate large amounts of ATP. Take a good look at Figure 6.10. Notice that the NADH and FADH2 molecules enter the inner compartment of the mitochondria and release electrons. Once the electrons are handed off to the integral proteins, we regenerate NAD+ and FAD+, which will then return to t ...
... them to generate large amounts of ATP. Take a good look at Figure 6.10. Notice that the NADH and FADH2 molecules enter the inner compartment of the mitochondria and release electrons. Once the electrons are handed off to the integral proteins, we regenerate NAD+ and FAD+, which will then return to t ...
Metabolism of fats and proteins
... Follow one glucose molecule through glycolysis, the Krebs cycle, and the electron transport chain. Calculate: ...
... Follow one glucose molecule through glycolysis, the Krebs cycle, and the electron transport chain. Calculate: ...
Packet 7: Biochemistry
... while needing less energy (these types of proteins are known as ENZYMES) Allows for large or charged particles to cross into a cell through the cell ...
... while needing less energy (these types of proteins are known as ENZYMES) Allows for large or charged particles to cross into a cell through the cell ...
Cellular Respiration notes Cellular respiration is
... Unit 4: Cellular Respiration notes Cellular respiration is the process by which food is broken down by the body's cells to produce energy in the form of ATP molecules. A. Cellular Respiration Overview: 1. Cellular respiration is carried out by every cell in both plants and animals and is essential f ...
... Unit 4: Cellular Respiration notes Cellular respiration is the process by which food is broken down by the body's cells to produce energy in the form of ATP molecules. A. Cellular Respiration Overview: 1. Cellular respiration is carried out by every cell in both plants and animals and is essential f ...
Chapter 4: Ecosystems and Communities
... the number of organisms that inhabit and area Ex. Biotic: food, predators, prey, autotrophs, competition Abiotic: space, water, sunlight, salt, oxygen, temperature (altitude/latitude) 2. Carrying Capacity: the maximum number of organisms an area can “hold” on a sustained basis Organisms grow expon ...
... the number of organisms that inhabit and area Ex. Biotic: food, predators, prey, autotrophs, competition Abiotic: space, water, sunlight, salt, oxygen, temperature (altitude/latitude) 2. Carrying Capacity: the maximum number of organisms an area can “hold” on a sustained basis Organisms grow expon ...
topics covered during the fall semester ecology
... 9. Know the following terms: Abiotic factors, biotic factors, niche, habitat, population density, immigration, emigration, exponential growth, and logistic growth, and carrying capacity. Again, an ecosystem’s population growth can be limited by Densitydependent factors such as competition, predation ...
... 9. Know the following terms: Abiotic factors, biotic factors, niche, habitat, population density, immigration, emigration, exponential growth, and logistic growth, and carrying capacity. Again, an ecosystem’s population growth can be limited by Densitydependent factors such as competition, predation ...
Respiration II
... Does NADH have more or less potential p energy than NAD+? Explain why or why not. ...
... Does NADH have more or less potential p energy than NAD+? Explain why or why not. ...
energy and ecosystems
... same time that can interbreed with each other e.g. all the people in Shenzhen, the barnacles on a rocky shore A community is made up of all of the different species living in a habitat e.g. all the organisms in a rock pool. An ecosystem is made up of all the living organisms together with all of the ...
... same time that can interbreed with each other e.g. all the people in Shenzhen, the barnacles on a rocky shore A community is made up of all of the different species living in a habitat e.g. all the organisms in a rock pool. An ecosystem is made up of all the living organisms together with all of the ...
Lecture 16
... from the removal of a hydrogen atom with its electron, not just the proton AH2 and A together constitute a conjugate redox pair that can reduce another compound, B, or redox pair (B/BH2) by transfer of hydrogen atoms: AH2 + B A + BH2 ...
... from the removal of a hydrogen atom with its electron, not just the proton AH2 and A together constitute a conjugate redox pair that can reduce another compound, B, or redox pair (B/BH2) by transfer of hydrogen atoms: AH2 + B A + BH2 ...
Ecology and Energy Flow_fill_in
... • Chemosynthesis = When organisms use chemical energy to produce carbohydrates. • Performed by many types of bacteria – Methanogens produce methane. – Halophiles live in high salt water concentrations. – Thermoacidophiles live in acidic, sulfur rich, high temperature environments. ...
... • Chemosynthesis = When organisms use chemical energy to produce carbohydrates. • Performed by many types of bacteria – Methanogens produce methane. – Halophiles live in high salt water concentrations. – Thermoacidophiles live in acidic, sulfur rich, high temperature environments. ...
Ch9CellularRespiration
... • Application: Use of anaerobic cell respiration in yeasts to produce ethanol the reduction of hydrogen carriers, liberating carbon dioxide. and carbon dioxide in baking. • Transfer of electrons between carriers in the electron transport • Application: Lactate production in humans when anaerobic res ...
... • Application: Use of anaerobic cell respiration in yeasts to produce ethanol the reduction of hydrogen carriers, liberating carbon dioxide. and carbon dioxide in baking. • Transfer of electrons between carriers in the electron transport • Application: Lactate production in humans when anaerobic res ...
Ch 9 Power Point - Cellular Respiration
... • Alcohol~ pyruvate to ethanol, CO2, & NAD+ • Lactic acid~ pyruvate to lactate & NAD+ ...
... • Alcohol~ pyruvate to ethanol, CO2, & NAD+ • Lactic acid~ pyruvate to lactate & NAD+ ...
Chapter 6
... from inorganic molecules. Heterotrophs must obtain organic molecules from their environment. 2. What is chemosynthesis? Chemosythesis is a process in which certain autotrophic organisms are able to use the energy of inorganic chemical reactions to allow them to produce organic molecules. 3. How are ...
... from inorganic molecules. Heterotrophs must obtain organic molecules from their environment. 2. What is chemosynthesis? Chemosythesis is a process in which certain autotrophic organisms are able to use the energy of inorganic chemical reactions to allow them to produce organic molecules. 3. How are ...
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)