hapter 11

... – protons transported to periplasmic space rather than inner mitochondrial membrane – can use one carbon molecules instead of glucose ...

Slide 1 - MisterSyracuse.com

... A. It is produced in glycolysis B. It is not needed by the body, so it is simply not absorbed in the lungs C. Three molecules per pyruvate are produced in the Krebs cycle. D. Both B and C. ...

unit 1: introduction to biology

Energy and Metabolism

Document

... i. The energy released by electrons moving down the chain is used to pump H+ from the matrix to the intermembrane space ii. This creates a proton gradient (potential energy) iii. This gradient drives protons back in through a protein called ATPsynthase iv. This creates kinetic energy that ATPsynthas ...

Cellular Respiration PPT

... Another look:  Glycolysis ...

Cell Metabolism

... i. The energy released by electrons moving down the chain is used to pump H+ from the matrix to the intermembrane space ii. This creates a proton gradient (potential energy) iii. This gradient drives protons back in through a protein called ATPsynthase iv. This creates kinetic energy that ATPsynthas ...

Chapter 9 – Cellular Respiration and Fermentation

Cellular Respiration - Home - Mrs. Guida's AP Biology Class

... • Cellular Respiration- the oxidation of organic compounds to extract energy from chemical bonds ...

Lifeline Week 6 Follow-Along Sheet Cellular Respiration

Electron transport chains

Ch. 9 Cellular Respiration

... acids oxidized but nucleic acids are rarely used as a cellular energy source? ...

chapter 23

...  Function of citric acid cycle: generate ATP  So, when the cell needs energy, pyruvate is converted to acetyl-CoA, and the citric acid cycle proceeds.  But when the cell has sufficient energy, there is not much conversion to acetyl-CoA, and the citric acid cycle slows. ...

Energy Releasing Pathways

... stream and is transported to liver where it is converted back into pyruvic acid.  Used to make cheese and yogurt ...

Ch. 9 - Ltcconline.net

... a. all the folds of the christae provide increased surface area 4. electrons arrive having been carried by an NADH molecule. a. Oxygen (O2) is the final electron acceptor b. each Oxygen atom combines with 2 H’s to form H2O 5. Most carrier molecules are in the protein complexes which span the inner m ...

Cellular Respiration: Harvesting Chemical Energy

... High energy product so reacts exergonically Decarboxylation is loss of CO2 ...

AP Biology Chap 9 Reading Guide Cellular Respiration

... is two ____________ carbon compounds termed ___________________ . 14. The ten individual steps of glycolysis can be divided into two stages: energy investment and energy payoff. Label the energy investment stage below; then use Figure 9.9 to find the two specific stages where ATP is used. ...

Redox reaction during glycolysis

... • NADH+H+ supplies pair of H atoms to the first carrier in the chain, with the NAD+ returning to the matrix. • The hydrogen atoms are split, to release two electrons, which pass from carrier in the chain. • Energy is released as the e- pass from carrier to carrier, and three of these use this energy ...

ADP, ATP and Cellular Respiration Powerpoint

... • Process is Exergonic as Highenergy Glucose is broken into CO2 and H2O • Process is also Catabolic because larger Glucose breaks into smaller molecules ...

micro notes chpt. 8

... enter the TCA cycle and yield an abundance of ATP if oxygen is present. If no oxygen is available, pyruvic acid will enter the fermentation pathway and be converted to acids, alcohols, and/or gases but will not yield any ATP, but rather only NADH. ...

Welcome to Jeopardy!!

... What are the Outputs of the Calvin Cycle, and where do these reactions occur? ...

coupling membrane

... NADH and succinate) in citric acid cycle 4) the oxidation of reduced cofactors by oxygen forming water and releasing energy (respiratory electron transfer) ...

Slide 1

... c. only if oxygen is present. d. only if oxygen is absent. ...

A2 Respiration test

... enters the Kreb’s cycle which occurs in the …………………………………………. of the matrix ...

Cellular Biology I

... Cell Energetics Cellular (aerobic) respiration breaks glucose down to carbon dioxide, water, and ENERGY. The ENERGY released is stored in the form of ATP C6H12O6 + 6 O2  6 CO2 + 6 H2O + ATP Carbon-carbon bonds contain energy; when they break, ATP is formed ...

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Electron transport chain

An electron transport chain (ETC) is a series of compounds that transfer electrons from electron donors to electron acceptors via redox reactions, and couples this electron transfer with the transfer of protons (H+ ions) across a membrane. This creates an electrochemical proton gradient that drives ATP synthesis, or the generation of chemical energy in the form of adenosine triphosphate (ATP). The final acceptor of electrons in the electron transport chain is molecular oxygen.Electron transport chains are used for extracting energy via redox reactions from sunlight in photosynthesis or, such as in the case of the oxidation of sugars, cellular respiration. In eukaryotes, an important electron transport chain is found in the inner mitochondrial membrane where it serves as the site of oxidative phosphorylation through the use of ATP synthase. It is also found in the thylakoid membrane of the chloroplast in photosynthetic eukaryotes. In bacteria, the electron transport chain is located in their cell membrane.In chloroplasts, light drives the conversion of water to oxygen and NADP+ to NADPH with transfer of H+ ions across chloroplast membranes. In mitochondria, it is the conversion of oxygen to water, NADH to NAD+ and succinate to fumarate that are required to generate the proton gradient. Electron transport chains are major sites of premature electron leakage to oxygen, generating superoxide and potentially resulting in increased oxidative stress.

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Electron transport chain