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LESSON 2.5 WORKBOOK Blood glucose in sleep, a 5 mile
... During exercise the rate of the citric acid cycle can’t always keep up with the amount of glucose that is being supplied to the muscles. This is because the citric acid cycle requires oxygen to be delivered from the lungs via the blood. During anaerobic exercise like running or dancing you breathe h ...
... During exercise the rate of the citric acid cycle can’t always keep up with the amount of glucose that is being supplied to the muscles. This is because the citric acid cycle requires oxygen to be delivered from the lungs via the blood. During anaerobic exercise like running or dancing you breathe h ...
REVIEW CHAPTER 4 and 5
... Denaturing in proteins is due to the disruption of peptide bonds False; 1° remains intact but hydrogen bonds, ionic bonds and disulfide bridges in 2° & 3°are disrupted ...
... Denaturing in proteins is due to the disruption of peptide bonds False; 1° remains intact but hydrogen bonds, ionic bonds and disulfide bridges in 2° & 3°are disrupted ...
glucose, amino acids, and fatty acids
... In stage l, metabolic fuels are hydrolyzed in the gastrointestinal tract to a diverse set of monomeric building blocks (glucose, amino acids, and fatty acids) and absorbed. In stage 2, the building blocks are degraded by various pathways in tissues to a common metabolic intermediate, acetyl-CoA. ...
... In stage l, metabolic fuels are hydrolyzed in the gastrointestinal tract to a diverse set of monomeric building blocks (glucose, amino acids, and fatty acids) and absorbed. In stage 2, the building blocks are degraded by various pathways in tissues to a common metabolic intermediate, acetyl-CoA. ...
Lecture_5_Control_of_glycolysis
... Exercise training also stimulates HIF-1, which enhances the ability to generate ATP anaerobically and stimulates new blood vessel growth. ...
... Exercise training also stimulates HIF-1, which enhances the ability to generate ATP anaerobically and stimulates new blood vessel growth. ...
CH 9 Study Guide
... And who carries the energy for them to the next step? ATP and NADPH 6. In the second step of photosynthesis (the calvin cycle): A. What powers this reaction? Carbon dioxide and water B. What is happening in the dark reaction? using energy from ATP and NADPH to create glucose C. Where does it occur? ...
... And who carries the energy for them to the next step? ATP and NADPH 6. In the second step of photosynthesis (the calvin cycle): A. What powers this reaction? Carbon dioxide and water B. What is happening in the dark reaction? using energy from ATP and NADPH to create glucose C. Where does it occur? ...
1 Respiration efficiency Respiration summary
... Glycogen is phosphorylised rather than hydrolysed (to glucose), saving the energy required for the first glucose phosphorylation Synthesis of glycogen from glucose 6-phosphate is mediated by uridine diphosphate (a close relation of the nucleotide uracil) Costs 1 ATP per glucose 6-p to incorporate. N ...
... Glycogen is phosphorylised rather than hydrolysed (to glucose), saving the energy required for the first glucose phosphorylation Synthesis of glycogen from glucose 6-phosphate is mediated by uridine diphosphate (a close relation of the nucleotide uracil) Costs 1 ATP per glucose 6-p to incorporate. N ...
Cellular respiration
... 8. Chemical reactions of citric acid cycle produces CO2, ATP, and NADPH. 9. Kreb’s cycle is the reason for the carbon dioxide you exhale. 10. Kreb’s cycle is used to convert any molecule into another molecule. 11. Kreb’s cycle is involved in anabolizing and catabolizing proteins, fats, carbohydrates ...
... 8. Chemical reactions of citric acid cycle produces CO2, ATP, and NADPH. 9. Kreb’s cycle is the reason for the carbon dioxide you exhale. 10. Kreb’s cycle is used to convert any molecule into another molecule. 11. Kreb’s cycle is involved in anabolizing and catabolizing proteins, fats, carbohydrates ...
AP bio summer answers
... B. portions of eukaryotic DNA which cannot be transcribed have been_____ C. enzyme that catalyzes the elongation of repetitive DNA at the end of a chromosome; often this enzyme is highly active in cancerous cells D. gene that can trigger cancerous growth E. hormone (protein) that regulates the cell ...
... B. portions of eukaryotic DNA which cannot be transcribed have been_____ C. enzyme that catalyzes the elongation of repetitive DNA at the end of a chromosome; often this enzyme is highly active in cancerous cells D. gene that can trigger cancerous growth E. hormone (protein) that regulates the cell ...
Chapter 24 - Metabolism
... high-energy phosphate group is transferred directly from a molecule to ADP to make ATP For example, when the energy stored on a highenergy phosphate group on creatine phosphate is transferred to ADP to make ATP in skeletal ...
... high-energy phosphate group is transferred directly from a molecule to ADP to make ATP For example, when the energy stored on a highenergy phosphate group on creatine phosphate is transferred to ADP to make ATP in skeletal ...
Cellular respiration
... 3. The stomata allows water into the leaves. 4. The guard cells open and close the stomata at the most opportune times of day for the plant. 5. Plants produce glucose during photosynthesis. ...
... 3. The stomata allows water into the leaves. 4. The guard cells open and close the stomata at the most opportune times of day for the plant. 5. Plants produce glucose during photosynthesis. ...
Marvelous Macromolecules - Pregitzersninjascienceclasses
... Small units that join together to make polymers Connected by covalent bonds using a condensation (dehydration) reaction One monomer gives a hydroxyl group, the other gives a hydrogen to form water Process requires ENERGY and ENZYMES ...
... Small units that join together to make polymers Connected by covalent bonds using a condensation (dehydration) reaction One monomer gives a hydroxyl group, the other gives a hydrogen to form water Process requires ENERGY and ENZYMES ...
Chapter 9 - Cellular Respiration
... A. fermentation – partial degradation of sugars without oxygen (anaerobic respiration_ B. Aerobic respiration – oxygen is consumed as reactant along with organic fuel (glucose) C. Cellular respiration is the enzymatic breakdown of glucose (C6H12O6) in the presence of oxygen (O2) to produce cellular ...
... A. fermentation – partial degradation of sugars without oxygen (anaerobic respiration_ B. Aerobic respiration – oxygen is consumed as reactant along with organic fuel (glucose) C. Cellular respiration is the enzymatic breakdown of glucose (C6H12O6) in the presence of oxygen (O2) to produce cellular ...
Unit 1.1 Molecules.pps
... It has a high latent heat of vaporisation – so animals use water to cool themselves It is less dense as a solid (ice)… … and ice is a poor conductor Water is a good solvent It ...
... It has a high latent heat of vaporisation – so animals use water to cool themselves It is less dense as a solid (ice)… … and ice is a poor conductor Water is a good solvent It ...
lecture1
... anaerobic, pyruvate is reduced by NADH to lactate. Since 2 molecules of triose P are formed per mole of glucose, 2 moles of ...
... anaerobic, pyruvate is reduced by NADH to lactate. Since 2 molecules of triose P are formed per mole of glucose, 2 moles of ...
document
... Are there any positive uses for steroid? Which are those? How the use of steroids may influence a person social, physical and mental wellbeing? ...
... Are there any positive uses for steroid? Which are those? How the use of steroids may influence a person social, physical and mental wellbeing? ...
NORMAL NUTRITION NURP 102 ANDERSON
... A diet should be high in carbohydrate, low in fat and adequate in protein Carbohydrate: 60% Fat: 30% or less Protein: 12-15% (15% is probably best) ...
... A diet should be high in carbohydrate, low in fat and adequate in protein Carbohydrate: 60% Fat: 30% or less Protein: 12-15% (15% is probably best) ...
Chapter 16 Glycolysis Control of glycolytic pathway
... ATP inhibits phosphofructokinase (PFK), pyruvate kinase, and hexokinase. Glucose 6-phosphate is converted into glycogen During exercise (right), the decrease in the ATP/AMP ratio resulting from muscle contraction activates phosphofructokinase and hence glycolysis. The flux down the pathway is increa ...
... ATP inhibits phosphofructokinase (PFK), pyruvate kinase, and hexokinase. Glucose 6-phosphate is converted into glycogen During exercise (right), the decrease in the ATP/AMP ratio resulting from muscle contraction activates phosphofructokinase and hence glycolysis. The flux down the pathway is increa ...
• Sources of glucose • Phases of glucose homeostasis • Hormones
... • Sources of glucose is Dietary sources & Metabolic sources (via gluconeogenesis). In Phase I Glucose is mainly supplied by dietary CHOs (exogenous) and • Gluconeogenesis is inhibited in this phase. Phase II Major sources of blood glucose is Glycogenolysis and gluconeogenesis. • InPhase III starts w ...
... • Sources of glucose is Dietary sources & Metabolic sources (via gluconeogenesis). In Phase I Glucose is mainly supplied by dietary CHOs (exogenous) and • Gluconeogenesis is inhibited in this phase. Phase II Major sources of blood glucose is Glycogenolysis and gluconeogenesis. • InPhase III starts w ...
Bio-Macromolecules Worksheet.doc
... Carbohydrates are sugars, starches, and glycogen which are used for short and long term energy storage in cells and structural molecules in cell walls and exoskeletons. Carbohydrates are made of only carbon, hydrogen, and oxygen (CHO). They are found in bread, potatoes, pasta, and fruits. Carbohydra ...
... Carbohydrates are sugars, starches, and glycogen which are used for short and long term energy storage in cells and structural molecules in cell walls and exoskeletons. Carbohydrates are made of only carbon, hydrogen, and oxygen (CHO). They are found in bread, potatoes, pasta, and fruits. Carbohydra ...
What is Ketosis
... OOC-CH2-C-CH3 O CO2 NADH + H+ NAD+ CH3-C-CH3 OOC-CH2-CH-CH3 O Acetone OH -hydroxybutyrate ...
... OOC-CH2-C-CH3 O CO2 NADH + H+ NAD+ CH3-C-CH3 OOC-CH2-CH-CH3 O Acetone OH -hydroxybutyrate ...
Glucose
![](https://commons.wikimedia.org/wiki/Special:FilePath/Alpha-D-glucopyranose-2D-skeletal.png?width=300)
Glucose is a sugar with the molecular formula C6H12O6. The name ""glucose"" (/ˈɡluːkoʊs/) comes from the Greek word γλευκος, meaning ""sweet wine, must"". The suffix ""-ose"" is a chemical classifier, denoting a carbohydrate. It is also known as dextrose or grape sugar. With 6 carbon atoms, it is classed as a hexose, a sub-category of monosaccharides. α-D-glucose is one of the 16 aldose stereoisomers. The D-isomer (D-glucose) occurs widely in nature, but the L-isomer (L-glucose) does not. Glucose is made during photosynthesis from water and carbon dioxide, using energy from sunlight. The reverse of the photosynthesis reaction, which releases this energy, is a very important source of power for cellular respiration. Glucose is stored as a polymer, in plants as starch and in animals as glycogen.