Respiration

... the Krebs cycle as shown. In the Krebs cycle, there are: 1. Decarboxylation 2. Dehydrogenation 3. Formation of ATP. All the above processes take place in the matrix of mitochondrion. ...

PowerPoint - Michigan State University

... Electrons • Carry a negative charge • Repel one another • Are attracted to protons in the nucleus • Move in orbitals - volumes of space that surround the nucleus Electron Vacancies • Unfilled shells make atoms likely to react • Hydrogen, carbon, oxygen, and nitrogen all have vacancies in their outer ...

MMG 301, Lecture 19 Fermentation

... 1. What is Fermentation? 2. What do we mean by Substrate Level Phosphorylation (SLP)? 3. What is the best-known fermentation pathway? 4. What are other types of fermentations? 5. How do I calculate the available energy? Overview of Fermentation Key features: Electrons exit the substrate via a carrie ...

aerobic respiration

... relative to oxygen of the electron transport chain. The solid blue circles are electron carrier molecules, and the light blue ovals represent protein complexes. From an energy standpoint, are these reactions endergonic or exergonic? a. ...

General Chemistry 110 Quiz 1

... produces NADPH C. produces precursors for nucleotide synthesis D. A and B above E. B and C above ...

Slide 1

... organic fuels to oxygen  Enzymes are necessary to oxidize glucose and other foods – The enzyme that removes hydrogen from an organic molecule is called dehydrogenase – Dehydrogenase requires a coenzyme called NAD+ (nicotinamide adenine dinucleotide) to shuttle electrons – NAD+ can become reduced wh ...

Student notes in ppt

... The amount of energy available from a coupled redox reaction is defined as Eº’ By convention, the Eº' of a coupled redox reaction is determined by subtracting the Eº' of the oxidant (e- acceptor) from the Eº' of the reductant (e- donor) using the following equation: Eº' = (Eº'e- acceptor) - (Eº' ...

Chapter 7

... other molecules that function as a lightgathering antenna. – Chlorophyll molecules absorb photons. • Electrons in the pigment gain energy. • As the electrons fall back to their ground state, energy is released as heat or light. Laura Coronado ...

Lone pairs

... Atomic radius increase as you move right to left. ...

Cellular Respiration: Harvesting Chemical Energy

... from NADH and FADH2 to form ATP. Function: Convert NADH and FADH2 into ATP. Location: Mitochondria cristae. ...

Cellular Respiration - Ursuline High School

... from NADH and FADH2 to form ATP. Function: Convert NADH and FADH2 into ATP. Location: Mitochondria cristae. ...

Cellular Respiration

...  In the Krebs cycle, the pyruvate is converted to acetyl-CoA, which is broken down to form CO2, ATP, NADH, and FADH2.  One ATP is produced for each pyruvate.  CO2 is a byproduct.  why we breathe out carbon dioxide! ...

Respiration

... krebs cycle) are stored in the matrix 1. NADH releases protons and electrons on the matrix side A. Protons are pumped into the intermembrance space B. Electrons are transported across the membrane using ubiquinone (coenzyme Q) and cytochrome C ...

adjusting the conditions inside when the outside conditions change

... 8. In stage 2, a large amount of ATP is made if __________________ is present. 9. If oxygen is present, it is called ________________ ___________________. 10. Where does this process occur in eukaryotic cells? ___________________ 11. Where does this process occur in prokaryotic cells? ______________ ...

2.1 Carbohydrates - SandyBiology1-2

... A monomer is a molecule that is able to bond in long chains. Polymer means many monomers. Polymers are also known as macromolecules or large-sized molecules. ...

Generation of Biochemical Energy

... Step 3: Citric acid cycle Within the mitochondria the acetyl group carbon atoms are oxidized to the CO2 that we exhale. Most of the energy released in the oxidation leaves the citric acid cycle in the chemical bonds of reduced coenzymes (NADH. FADH2). Some energy also leaves the cycle stored in the ...

Chapter 6

... photophosphorylation (in photosynthesis) and oxidative phosphorylation (in respiration) are very similar. In both cases, energy is used to pump hydrogen ions across a membrane, building up a gradient for them. They are then allowed to diffuse back down this gradient through ATPases, which make ATP. ...

KEY

... Scientists are trying to determine the function of an organelle in a plant cell. They observe that water and carbon dioxide enter the organelle, and oxygen and glucose exit the organelle. This organelle is most likely ...

III. 5 Test Fotosíntesi

... 34) Of the following, what do both mitochondria and chloroplasts have in common? A) thylakoid membranes B) chemiosmosis C) ATP synthase D) B and C only E) A, B, and C Topic: Concept 10.2 Skill: Knowledge ...

How plants make their food

... PHOTOSYNTHESIS is one of the most important biological process on earth! · Provides the oxygen (O2) we breathe · Consumes extra Carbon Dioxide CO2 · Makes Plant Food · Gives US food! ...

thermodynamics

... into cells and into particular parts of cells, must be characterized numerically. ...

6-Respiratory-chain

... 2. The electrons obtained with the hydrogen are passed down a cascade of carrier molecules located in complexes I–IV, then transferred to O2 3. Powered by electron transport, complexes I, III, and IV expel protons across the inner mitochondrial membrane 4. The expelled protons reenter the mitochondr ...

Chapter 6

... Electron-Transport System ...

Energy Production

... Metabolic systems that supply energy for the body: 1) Aerobic metabolism: dependent on oxygen. 2) Anaerobic metabolism: independent of oxygen. The use of which systems depend on: 1) Duration. 2) Intensity. 3) Type of physical activity. Adenosine Triphosphate (ATP): It is an energy-rich compound that ...

effective nuclear charge

... Al atom = 1s22s22p63s23p1 Al+3 ion = 1s22s22p6 Fe atom = 1s22s22p63s23p64s23d6 Fe+2 ion = 1s22s22p63s23p63d6 Fe+3 ion = 1s22s22p63s23p63d5 Cu atom = 1s22s22p63s23p64s13d10 Cu+1 ion = 1s22s22p63s23p63d10 ...

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Light-dependent reactions

In photosynthesis, the light-dependent reactions take place on the thylakoid membranes. The inside of the thylakoid membrane is called the lumen, and outside the thylakoid membrane is the stroma, where the light-independent reactions take place. The thylakoid membrane contains some integral membrane protein complexes that catalyze the light reactions. There are four major protein complexes in the thylakoid membrane: Photosystem II (PSII), Cytochrome b6f complex, Photosystem I (PSI), and ATP synthase. These four complexes work together to ultimately create the products ATP and NADPH.[.The two photosystems absorb light energy through pigments - primarily the chlorophylls, which are responsible for the green color of leaves. The light-dependent reactions begin in photosystem II. When a chlorophyll a molecule within the reaction center of PSII absorbs a photon, an electron in this molecule attains a higher energy level. Because this state of an electron is very unstable, the electron is transferred from one to another molecule creating a chain of redox reactions, called an electron transport chain (ETC). The electron flow goes from PSII to cytochrome b6f to PSI. In PSI, the electron gets the energy from another photon. The final electron acceptor is NADP. In oxygenic photosynthesis, the first electron donor is water, creating oxygen as a waste product. In anoxygenic photosynthesis various electron donors are used.Cytochrome b6f and ATP synthase work together to create ATP. This process is called photophosphorylation, which occurs in two different ways. In non-cyclic photophosphorylation, cytochrome b6f uses the energy of electrons from PSII to pump protons from the stroma to the lumen. The proton gradient across the thylakoid membrane creates a proton-motive force, used by ATP synthase to form ATP. In cyclic photophosphorylation, cytochrome b6f uses the energy of electrons from not only PSII but also PSI to create more ATP and to stop the production of NADPH. Cyclic phosphorylation is important to create ATP and maintain NADPH in the right proportion for the light-independent reactions.The net-reaction of all light-dependent reactions in oxygenic photosynthesis is:2H2O + 2NADP+ + 3ADP + 3Pi → O2 + 2NADPH + 3ATPThe two photosystems are protein complexes that absorb photons and are able to use this energy to create an electron transport chain. Photosystem I and II are very similar in structure and function. They use special proteins, called light-harvesting complexes, to absorb the photons with very high effectiveness. If a special pigment molecule in a photosynthetic reaction center absorbs a photon, an electron in this pigment attains the excited state and then is transferred to another molecule in the reaction center. This reaction, called photoinduced charge separation, is the start of the electron flow and is unique because it transforms light energy into chemical forms.

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Light-dependent reactions