metabolism 8.1 worksheet
... 8.1.U4 Metabolic pathways can be controlled by end-product inhibition. 15. Explain the role of end-product inhibition as a method of controlling metabolic pathways. Include the role of allosteric sites. ...
... 8.1.U4 Metabolic pathways can be controlled by end-product inhibition. 15. Explain the role of end-product inhibition as a method of controlling metabolic pathways. Include the role of allosteric sites. ...
Biochemistry Test Review Guide
... 34. Draw the general structure of an amino acid. Label: amino group, carboxyl group and R group. 35. What is the significance of the R group of an amino acid? 36. Draw the synthesis of a protein circling the formation of the peptide bond. 37. What is a chemical reaction and what are the two componen ...
... 34. Draw the general structure of an amino acid. Label: amino group, carboxyl group and R group. 35. What is the significance of the R group of an amino acid? 36. Draw the synthesis of a protein circling the formation of the peptide bond. 37. What is a chemical reaction and what are the two componen ...
Mock exam preparation chapters 1-8
... activity, surface area and transport system. Know the different structure and functions of veins, arteries and capillaries. Interpret graphs detailing blood pressure in different parts of the mamalian circulatory system. Know the composition of blood, lymph and tissue fluid, and how the concentratio ...
... activity, surface area and transport system. Know the different structure and functions of veins, arteries and capillaries. Interpret graphs detailing blood pressure in different parts of the mamalian circulatory system. Know the composition of blood, lymph and tissue fluid, and how the concentratio ...
Biology Nutrition and Digestion Revision
... • Chemical digestion: Chemicals called enzymes breakdown large, insoluble food into smaller, soluble food that can be absorbed into the blood. Enzymes • Enzymes are chemicals that speed up reactions in your body such as the breakdown of food (digestion). • There are different types of enzymes for ea ...
... • Chemical digestion: Chemicals called enzymes breakdown large, insoluble food into smaller, soluble food that can be absorbed into the blood. Enzymes • Enzymes are chemicals that speed up reactions in your body such as the breakdown of food (digestion). • There are different types of enzymes for ea ...
Molecular Biology and Chemistry - Systems Biology Research Group
... within the cell, and cell recognition; it also provides a passage way for certain molecules and a stable site for binding and catalysis of enzymes [7]. The components that give the membrane its architecture and uid characteristics are the phospholipid bilayers. The phospholipid bilayer that makes u ...
... within the cell, and cell recognition; it also provides a passage way for certain molecules and a stable site for binding and catalysis of enzymes [7]. The components that give the membrane its architecture and uid characteristics are the phospholipid bilayers. The phospholipid bilayer that makes u ...
1 Irreversible Enzyme Inhibition Affinity labels for studying enzyme
... • DFP reacts with the active site serine (Ser-195) of chymotrypsin to form DFP-chymotrypsin • Such organophosphorous inhibitors are used as insecticides or for enzyme research • These inhibitors are toxic because they inhibit acetylcholinesterase (a serine protease that hydrolyzes the neurotransmitt ...
... • DFP reacts with the active site serine (Ser-195) of chymotrypsin to form DFP-chymotrypsin • Such organophosphorous inhibitors are used as insecticides or for enzyme research • These inhibitors are toxic because they inhibit acetylcholinesterase (a serine protease that hydrolyzes the neurotransmitt ...
The Structure and Function of Macromolecules
... They hope to be able to take any amino acid sequence and produce a computer generation of the folded protein ...
... They hope to be able to take any amino acid sequence and produce a computer generation of the folded protein ...
Addition of the following reactions responsible for the synthesis of
... a. phosphatidate, old: C1836H3398O400P50, new: C1682H3116O413P50 b. phosphatidylglycerol, old: C1986H3748O500P50, new: C1832H3466O513P50 c. phosphatidylserine, old: C1986H3698N50O500P50, new: C1832H3416N50O513P50 d. CDP-diacylglycerol, old: C2286H3998N150O750P100, new: C2132H3716N150O763P100 e. card ...
... a. phosphatidate, old: C1836H3398O400P50, new: C1682H3116O413P50 b. phosphatidylglycerol, old: C1986H3748O500P50, new: C1832H3466O513P50 c. phosphatidylserine, old: C1986H3698N50O500P50, new: C1832H3416N50O513P50 d. CDP-diacylglycerol, old: C2286H3998N150O750P100, new: C2132H3716N150O763P100 e. card ...
Lecture notes Chapter 22-23
... OH groups of hydroxyproline and hydroxylysine, there is less hydrogen bonding between collagen fibrils. As a person ages, additional cross-links form between the fibrils, which make collagen less elastic. Bones, cartilage, and tendons become more brittle, and wrinkles are seen as the skin loses ela ...
... OH groups of hydroxyproline and hydroxylysine, there is less hydrogen bonding between collagen fibrils. As a person ages, additional cross-links form between the fibrils, which make collagen less elastic. Bones, cartilage, and tendons become more brittle, and wrinkles are seen as the skin loses ela ...
Biochemistry - Ursuline High School
... Starch - a polymer of a-glucose molecules, principle energy storage molecules in plants Glycogen - a polymer of a-glucose molecules, principle energy storage molecules in animals, stored in the liver and muscles cells Cellulose - a polymer of b-glucose molecules, principle structural molecules in pl ...
... Starch - a polymer of a-glucose molecules, principle energy storage molecules in plants Glycogen - a polymer of a-glucose molecules, principle energy storage molecules in animals, stored in the liver and muscles cells Cellulose - a polymer of b-glucose molecules, principle structural molecules in pl ...
Biology 1408 - Lone Star College
... 8) Which organelle is most likely the most abundant organelle in muscle cells? A) Golgi complexes B) mitochondria C) lysosomes D) plastids E) smooth ER ...
... 8) Which organelle is most likely the most abundant organelle in muscle cells? A) Golgi complexes B) mitochondria C) lysosomes D) plastids E) smooth ER ...
Quiz - Columbus Labs
... Action at "another site" Enzymes situated at key steps in metabolic pathways are modulated by allosteric effectors These effectors are usually produced elsewhere in the pathway Effectors may be feed-forward activators or feedback inhibitors Kinetics are sigmoid ("S-shaped") ...
... Action at "another site" Enzymes situated at key steps in metabolic pathways are modulated by allosteric effectors These effectors are usually produced elsewhere in the pathway Effectors may be feed-forward activators or feedback inhibitors Kinetics are sigmoid ("S-shaped") ...
8)Discuss the roles of cofactors and coenzymes in enzyme activity.
... General features of enzymes: 1) Most of the enzymes are proteins, however, recent work has shown that there are RNA molecules which show catalytic activity (RNA enzymes) 2) Enzymes increase the rate of reactions but do not influence the equilibrium. 3) Enzymes exhibit high degree of specificity for ...
... General features of enzymes: 1) Most of the enzymes are proteins, however, recent work has shown that there are RNA molecules which show catalytic activity (RNA enzymes) 2) Enzymes increase the rate of reactions but do not influence the equilibrium. 3) Enzymes exhibit high degree of specificity for ...
metabolic regulation
... increased the efficiency with which the enzyme bound more substrate. [See Enzymes Lecture 4 for details of the models] ...
... increased the efficiency with which the enzyme bound more substrate. [See Enzymes Lecture 4 for details of the models] ...
SECTION 2 - CELL FUNCTION AND BIOCHEMICAL MEASUREMENT
... substrate into product per minute under standardized conditions. To assay the enzyme activity, the appropriate cofactors or coenzymes must be provided, the pH and temperature must be standardized, and the concentration of the substrate must be very large relative to the concentration of the enzyme. ...
... substrate into product per minute under standardized conditions. To assay the enzyme activity, the appropriate cofactors or coenzymes must be provided, the pH and temperature must be standardized, and the concentration of the substrate must be very large relative to the concentration of the enzyme. ...
SECTION 2 - CELL FUNCTION AND BIOCHEMICAL MEASUREMENT
... substrate into product per minute under standardized conditions. To assay the enzyme activity, the appropriate cofactors or coenzymes must be provided, the pH and temperature must be standardized, and the concentration of the substrate must be very large relative to the concentration of the enzyme. ...
... substrate into product per minute under standardized conditions. To assay the enzyme activity, the appropriate cofactors or coenzymes must be provided, the pH and temperature must be standardized, and the concentration of the substrate must be very large relative to the concentration of the enzyme. ...
- University of California
... the steps in the reaction catalyzed by the enzyme associated tightly with subtilisin and formed a complex that identified the amino acids involved in its catalysis. Such analogues of intermediates in enzymatic reactions are now widely used as highly specific drugs by the pharmaceutical industry. The ...
... the steps in the reaction catalyzed by the enzyme associated tightly with subtilisin and formed a complex that identified the amino acids involved in its catalysis. Such analogues of intermediates in enzymatic reactions are now widely used as highly specific drugs by the pharmaceutical industry. The ...
Chapter 12-1 Part 2
... transformation occurred (mouse alive or dead?) 5. Bacteria Extract + DNA destroying enzymes = transformation DID NOT OCCUR (mouse alive or dead?) ...
... transformation occurred (mouse alive or dead?) 5. Bacteria Extract + DNA destroying enzymes = transformation DID NOT OCCUR (mouse alive or dead?) ...
STARVE-FEED CYCLE 1) WELL-FED STATE (food intake
... 4) change in the cellular level of a key enzyme (longer time adaptive mechanism) • change in the rate of synthesis or degradation of the enzyme - hormonal and nutritional factors • well-fed state: the liver improves its capacity to synthesize fat • fasting: ↓ in quantity of lipogenetic enzymes; enzy ...
... 4) change in the cellular level of a key enzyme (longer time adaptive mechanism) • change in the rate of synthesis or degradation of the enzyme - hormonal and nutritional factors • well-fed state: the liver improves its capacity to synthesize fat • fasting: ↓ in quantity of lipogenetic enzymes; enzy ...
Digestion Powerpoint - School
... containing identical molecules, in protein these molecules are different. Protein is made up of chains of amino acids. There are over 20 different kinds of amino acid. Protein is used to allow the body to grow and to repair the body. ...
... containing identical molecules, in protein these molecules are different. Protein is made up of chains of amino acids. There are over 20 different kinds of amino acid. Protein is used to allow the body to grow and to repair the body. ...
Chirality in Chemistry
... Examples of secondary structures can be found here. Why does the shape of this secondary structure matter? As enzymes, the biological catalysts which allow our cells to work, are made of proteins, the shape of the secondary structure is important in how they can function. Enzymes work through a “lo ...
... Examples of secondary structures can be found here. Why does the shape of this secondary structure matter? As enzymes, the biological catalysts which allow our cells to work, are made of proteins, the shape of the secondary structure is important in how they can function. Enzymes work through a “lo ...
Enzyme
Enzymes /ˈɛnzaɪmz/ are macromolecular biological catalysts. Enzymes accelerate, or catalyze, chemical reactions. The molecules at the beginning of the process are called substrates and the enzyme converts these into different molecules, called products. Almost all metabolic processes in the cell need enzymes in order to occur at rates fast enough to sustain life. The set of enzymes made in a cell determines which metabolic pathways occur in that cell. The study of enzymes is called enzymology.Enzymes are known to catalyze more than 5,000 biochemical reaction types. Most enzymes are proteins, although a few are catalytic RNA molecules. Enzymes' specificity comes from their unique three-dimensional structures.Like all catalysts, enzymes increase the rate of a reaction by lowering its activation energy. Some enzymes can make their conversion of substrate to product occur many millions of times faster. An extreme example is orotidine 5'-phosphate decarboxylase, which allows a reaction that would otherwise take millions of years to occur in milliseconds. Chemically, enzymes are like any catalyst and are not consumed in chemical reactions, nor do they alter the equilibrium of a reaction. Enzymes differ from most other catalysts by being much more specific. Enzyme activity can be affected by other molecules: inhibitors are molecules that decrease enzyme activity, and activators are molecules that increase activity. Many drugs and poisons are enzyme inhibitors. An enzyme's activity decreases markedly outside its optimal temperature and pH.Some enzymes are used commercially, for example, in the synthesis of antibiotics. Some household products use enzymes to speed up chemical reactions: enzymes in biological washing powders break down protein, starch or fat stains on clothes, and enzymes in meat tenderizer break down proteins into smaller molecules, making the meat easier to chew.