in the presence of oxygen

... • ATP synthase rotates and adds a phosphate group to ADP to make ATP. ...

Animation

... outline glycolysis to pyruvate with the yield of ATP and reduced NAD+ ...

The Four Groups of Biologically Important Compounds

... nitrogen & usually sulfur ...

Study Guide Cellular Respiration

... 35. The Link Reaction: Each of 2 Pyruvic Acid molecule must change to Acetic Acid (2C) which join CoA to form Acetyl CoA 36. Pyruvic Acid (3C) + CoA + NAD  Acetyl CoA (2C) + NADH + CO2 37. Krebs Cycle or Citric Acid Cycle: All the enzymes for Citric Acid Cycle are present in inner chamber of Mitoch ...

Cellular Respiration

... to NADH, forming lactate as an end product, with no release of CO2 Lactic acid fermentation by some fungi and bacteria is used to make cheese and yogurt Human muscle cells use lactic acid fermentation to generate ATP when O2 is scarce ...

Summary for Chapter 7 – Metabolism: Transformations

... other monosaccharides), glycerol, fatty acids, and amino acids. Aided by enzymes and coenzymes, the cells use these products of digestion to build more complex compounds (anabolism) or break them down further to release energy (catabolism). High-energy compounds such as ATP may capture the energy re ...

October Syllabus

... pathways. Provide a biological example for each. Describe the forms of energy found in an apple as it grows on a tree, then falls and is digested by someone who eats it. ...

Metabolic Diversity

... established between inside and outside the cell ...

1 Cellular Respiration: Harvesting Chemical Energy Introduction

Molecular Madness

... on which shuttle transports electrons from NADH in cytosol ...

File

... After 10seconds of intensive exercise creatine phosphate store is depleted and if the intensive exercise continues the cells start to respire anaerobically because they do not receive an adequate supply of oxygen from the blood for aerobic respiration During Anaerobic Respiration, the only stage of ...

4.6 Fermentation

... respiration through glycolysis and fermentation. • Fermentation- the process in which electrons are removed from NADH to create NAD+ molecules – Does not make ATP – Instead, the purpose of fermentation is to allow glycolysis to continue ...

Matching review Connect with lines

... Matching review Connect with lines Water Carbon dioxide Oxygen PGAL NADP NAD+ FAD Glucose ...

Introduction to Physiology: The Cell and General Physiology

... • The glucose is released and taken up by the active muscle. Copyright © 2006 by Elsevier, Inc. ...

ATP - Coach Blair`s Biology Website

... • Energy is the ability to move or change matter (light, heat, chemical, electrical, etc.) • Energy can be stored or released by chemical reactions. • Energy from the sunlight flows through living systems, from autotrophs to heterotrophs. • Cellular respiration and photosynthesis form a cycle becaus ...

ADP, ATP and Cellular Respiration Powerpoint

... STEP 1 Glycolysis Glycolysis is takes place in the cytosol of cells in all living organisms.  This pathway can function with or without the presence of oxygen.  process converts one molecule of glucose into two molecules of pyruvate (pyruvic acid), ...

Cellular respiration

... Explain how photosynthesis and cellular respiration are necessary to provide energy that is required to sustain your life Explain why breathing is necessary to support cellular respiration Describe how cellular respiration produces energy that can be stored in ATP Explain why ATP is required for hum ...

Gas Exchange

... moist integument, do not have specialized gas exchange structures nor do they require a circulatory system to transport oxygen. In some, such as nemertean worms a circulatory system exists that functions to carry nutrients from the gut to other tissues. • Larger organisms and organisms living in low ...

PowerPoint Presentation - Chapter 9 Cellular Respiration

... Cellular respiration does not oxidize glucose in a single step that transfers all the hydrogen in the fuel to oxygen at one time. ...

McLovin`s Wisdom #1 – The Kidney, Diabetes Type 1 DM Type 2

... Overall: glucose  10 NADH + 2FADH2 + 4ATP/GTP Some of the NADH were produced in the first part of glycolysis (cytoplasm), so need to be moved to the mitochondria (malate/aspartate and glycerol-3-P shuttles), to feed into the electron transport chain. Malate/aspartate = heart and liver. GAP shuttle ...

Gluconeogenesis: Objectives

... 9. Describe why the glycerol-moiety of triglycerides and not the evennumbered fatty acids can be converted to glucose. Name the first glycolytic intermediate formed from glycerol. (see pg. 16) a. The essence of this question is based in the number of carbons. Glycerol comes from the breakdown of tri ...

Chapter 15 Review Worksheet and Key

... Amylopectin contains α-(1 → 6) glycosidic bonds. Amylose does not. ...

Chapter 15 Cori and Alanine Cycles: Cori Cycle: Occurs between

PDF 2/page

... Oxygen has a higher affinity for electrons than glucose and the various electron carriers (e.g. NADH). ...

CH 2. CELLULAR RESPIRATION

... In other words, the combustion of one molecule of glucose yields 36 molecules of ATP along with carbon dioxide and water as by-products. Since the activation energy needed for the combustion of glucose is quite high, each step in cellular respiration is catalyzed by specific enzymes that lower the a ...

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Glycolysis

Glycolysis (from glycose, an older term for glucose + -lysis degradation) is the metabolic pathway that converts glucose C6H12O6, into pyruvate, CH3COCOO− + H+. The free energy released in this process is used to form the high-energy compounds ATP (adenosine triphosphate) and NADH (reduced nicotinamide adenine dinucleotide).Glycolysis is a determined sequence of ten enzyme-catalyzed reactions. The intermediates provide entry points to glycolysis. For example, most monosaccharides, such as fructose and galactose, can be converted to one of these intermediates. The intermediates may also be directly useful. For example, the intermediate dihydroxyacetone phosphate (DHAP) is a source of the glycerol that combines with fatty acids to form fat.Glycolysis is an oxygen independent metabolic pathway, meaning that it does not use molecular oxygen (i.e. atmospheric oxygen) for any of its reactions. However the products of glycolysis (pyruvate and NADH + H+) are sometimes disposed of using atmospheric oxygen. When molecular oxygen is used in the disposal of the products of glycolysis the process is usually referred to as aerobic, whereas if the disposal uses no oxygen the process is said to be anaerobic. Thus, glycolysis occurs, with variations, in nearly all organisms, both aerobic and anaerobic. The wide occurrence of glycolysis indicates that it is one of the most ancient metabolic pathways. Indeed, the reactions that constitute glycolysis and its parallel pathway, the pentose phosphate pathway, occur metal-catalyzed under the oxygen-free conditions of the Archean oceans, also in the absence of enzymes. Glycolysis could thus have originated from chemical constraints of the prebiotic world.Glycolysis occurs in most organisms in the cytosol of the cell. The most common type of glycolysis is the Embden–Meyerhof–Parnas (EMP pathway), which was discovered by Gustav Embden, Otto Meyerhof, and Jakub Karol Parnas. Glycolysis also refers to other pathways, such as the Entner–Doudoroff pathway and various heterofermentative and homofermentative pathways. However, the discussion here will be limited to the Embden–Meyerhof–Parnas pathway.The entire glycolysis pathway can be separated into two phases: The Preparatory Phase – in which ATP is consumed and is hence also known as the investment phase The Pay Off Phase – in which ATP is produced.↑ ↑ 2.0 2.1 ↑ ↑ ↑ ↑ ↑ ↑

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Glycolysis