Section 9–2 The Krebs Cycle and Electron Transport (pages 226–232)

... cycle for? The chain uses the electrons to convert ADP into ATP. 16. How does the location of the electron transport chain differ in eukaryotes and prokaryotes? In eukaryotes, the chain is composed of a series of proteins located in the inner membrane of the mitochondrion. In prokaryotes, the chain ...

Cellular Energy

... Occurs in the cytoplasm of cells • Glucose is converted into pyruvate producing a small amount of ATP. • (Remember glucose is an energy source.) • If there is not enough glucose for glycolysis, then lipids can be used. (ex. fats = energy storage) • This is what happens when we diet. ...

Catabolism

... parts: catabolism and anabolism. • Catabolism: larger and more complex molecules are broken down into smaller, simpler molecules with the release of energy. • Anabolism: the synthesis of complex molecules from simpler ones with the input of energy. ...

Chapter 8 - South Sevier High School

... a. NADH gives up its electrons and becomes NAD+; the next carrier then gains electrons and is thereby reduced. b. At each sequential redox reaction, energy is released to form ATP molecules. c. Some of the protein carriers are cytochrome molecules, complex carbon rings with a heme (iron) group in th ...

Team Hockey: Glucose and ATP

... • Most of ATP produced in this step (up to 34). • About 17 NADH (from Citric Acid Cycle) made into 2 ATP each, producing around 34 ATP. ...

Cellular respiration

...  ATP and citrate (from the citric acid cycle) are inhibitors.  This is a specific example of negative ...

Option C: Cells & Energy

... acquired from the surroundings into forms usable for cellular work. • BOTH: a) enclosed by double membranes which are NOT part of endomembrane system b) contain ribosomes and some DNA that programs a small portion of their own protein synthesis c) are semiautonomous organelles that grow and reproduc ...

Name Date Period Chapter 9: Cellular Respiration: Harvesting

... 3. What is the summary equation for cellular respiration and what is the free energy change in this process? ...

i. introduction to metabolism and catabolism

... b) Characteristics (1) Dissimilative, exergonic, and oxidative 3. Anabolism a) Energy requiring process which build larger molecules (cell constituents) from smaller molecules (biosynthetic pathways) b) Characteristics c) ...

File

... 3. In mammals, which of the following substances is produced in a muscle that operates anaerobically?   (A) Acetyl CoA (C) NADPH (B) Citrate  (D) Lactate Answer = D 4. Production of ATP occurs in all of the following processes EXCEPT   (A) glycolysis  (B) electron transport system and chemiosmosis ( ...

Mader/Biology, 11/e – Chapter Outline

... consists of carriers that pass electrons successively from one to another. 2. NADH and FADH2 carry the electrons to the electron transport system. 3. Members of the Chain a. NADH gives up its electrons and becomes NAD+; the next carrier then gains electrons and is thereby reduced. b. At each sequent ...

Answers to study guide

... 3phosphates that are like a tightly wound spring and when that last phosphate is released energy is released to do cell work, ATP must be produced form the breakdown of food. 14. Define calories and kilocalories as units of energy and how they are calculated. unit of measurement – the amount of ener ...

Cellular Respiration

... First, each plant part takes care of its own gas-exchange needs. There is very little transport of gases from one plant part to another. Second, plants do not present great demands for gas exchange. Roots, stems and leaves respire at rates far lower than animals do. Only during photosynthesis are l ...

enzymes - JonesHonorsBioGreen

... Citric Acid / Krebs Cycle – Page 97 ETC (Oxidative Phosphorylation)- Page 98 Fermentation – Page 101 Full sheet or Half sheet drawings – IN COLOR ...

Cell ENERGY & ENZYMES

... Citric Acid / Krebs Cycle – Page 97 ETC (Oxidative Phosphorylation)- Page 98 Fermentation – Page 101 Full sheet or Half sheet drawings – IN COLOR ...

A) Choose the correct answer: B)Complete: 1) L

... 2) ATP production by ATP synthase is due to: (a) Rotation of F1 subunit. (b) flow of protons through γ subunit (c) flow of hydrogen ions through the multiple C- protein subunits. (d) Proton translocation to intermembrane space 3) The following are considered as standard conditions for a given reacti ...

Tricarboxylic Acid Cycle (TCA), Krebs Cycle

... The inner mitochondrial membrane is impermeable to the most charged and hydrophilic substances. However it contains numerous transport proteins that permit the passage of specific molecules. 1- ATP-ADP transport, see oxid-phospho, Transporter for ADP & Pi from cytosol into mitochondria by specialize ...

electron transport chain

... • Any chemical interferring with the exchange of electrons and protons between cytochrome oxidase and oxygen will halt the electron transport chain function and will cause respiration to stop. ...

Metabolism II

... Electrons flow from carriers with more negative E0 to carriers with more positive E0 ...

Mock Exam 2 BY 123 - Cusic Supplemental Instruction

... 23. What class of enzyme is responsible for moving phosphate groups? a. Kinase b. Isomerase c. Dehydrogenase d. None of the above 24. What class of enzyme is responsible for the movement of electrons? a. Kinase b. Isomerase c. Dehydrogenase d. None of the above 25. What is reduced in the photosynth ...

2chap9guidedreadingVideo

... 4. In cellular respiration, what is being oxidized and what is being reduced? HINT: In organic chemistry the electrons in redox reactions are usually between C and H so if a carbon compound has H in it, it is reduced and has potential energy. ...

BioH_Cellular Respiration

... Each protein in the chain has a higher attraction for electrons than the one before it, causing electrons to be pulled “down” the chain. The last protein of the chain passes its electrons to oxygen, which also picks up a pair of H+ from the surroundings to form water (oxygen is the “final electron a ...

Content of phloem and xylem exudates

... Electron transport in chloroplasts and mitochondia generates ATP in the same way. H+ are transported out of the stroma/matrix by during electron transport and H+ flow back into the stroma/matrix through the ATP synthase and generates ATP in the stroma matrix. In chloroplasts the thylakoid lumen is ...

Sucrose is used for respiration, storage or construction. Plants

... H+ are transported out of the stroma/matrix by during electron transport and H+ flow back into the stroma/matrix through the ATP synthase and generates ATP in the ...

Chem*3560 Lecture 29: Membrane Transport and metabolism

... muscle or used for fatty acid biosynthesis in adipose tissue. After exposure to insulin, Vmax for glucose uptake goes up 10-12 fold, while KM stays constant. When insulin levels decline, the glucose transport rate decreases to the original value over about 2 h. Changes in Vmax often reflect change i ...

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Mitochondrion

The mitochondrion (plural mitochondria) is a double membrane-bound organelle found in most eukaryotic cells. The word mitochondrion comes from the Greek μίτος, mitos, i.e. ""thread"", and χονδρίον, chondrion, i.e. ""granule"" or ""grain-like"".Mitochondria range from 0.5 to 1.0 μm in diameter. A considerable variation can be seen in the structure and size of this organelle. Unless specifically stained, they are not visible. These structures are described as ""the powerhouse of the cell"" because they generate most of the cell's supply of adenosine triphosphate (ATP), used as a source of chemical energy. In addition to supplying cellular energy, mitochondria are involved in other tasks, such as signaling, cellular differentiation, and cell death, as well as maintaining control of the cell cycle and cell growth. Mitochondria have been implicated in several human diseases, including mitochondrial disorders, cardiac dysfunction, and heart failure. A recent University of California study including ten children diagnosed with severe autism suggests that autism may be correlated with mitochondrial defects as well.Several characteristics make mitochondria unique. The number of mitochondria in a cell can vary widely by organism, tissue, and cell type. For instance, red blood cells have no mitochondria, whereas liver cells can have more than 2000. The organelle is composed of compartments that carry out specialized functions. These compartments or regions include the outer membrane, the intermembrane space, the inner membrane, and the cristae and matrix. Mitochondrial proteins vary depending on the tissue and the species. In humans, 615 distinct types of protein have been identified from cardiac mitochondria, whereas in rats, 940 proteins have been reported. The mitochondrial proteome is thought to be dynamically regulated. Although most of a cell's DNA is contained in the cell nucleus, the mitochondrion has its own independent genome. Further, its DNA shows substantial similarity to bacterial genomes.

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Mitochondrion