pro amino crème
... pro amino crème for younger, healthier looking skin Designed to enhance barrier function by restoring free water levels and natural lipids, pro amino crème aims to maintain a balanced, youthful complexion. pro amino crème has been formulated with the eight essential amino acids, proteins and vitamin ...
... pro amino crème for younger, healthier looking skin Designed to enhance barrier function by restoring free water levels and natural lipids, pro amino crème aims to maintain a balanced, youthful complexion. pro amino crème has been formulated with the eight essential amino acids, proteins and vitamin ...
Protein Structure Activity
... Proteins are ubiquitous in organisms. That means they are everywhere! (There’s even a protein called ubiquitin, and it’s in all cells and controls who “lives” and who “dies” among all the proteins in the cell.) All proteins have two things in common: They are all made of chains of building blocks ...
... Proteins are ubiquitous in organisms. That means they are everywhere! (There’s even a protein called ubiquitin, and it’s in all cells and controls who “lives” and who “dies” among all the proteins in the cell.) All proteins have two things in common: They are all made of chains of building blocks ...
View/Open - Technical University of Mombasa
... 16. Which of the following is not a coenzyme? a) NAD b) COA c) FAD d) None of the above 17. An example of a lyase is? a) Glutamine synthetase b) Fumarase c) Cholinesteraise d) Amylase 18. The following are examples of sterols. Which one is not ? a) Prostaglandins b) Ergasterol c) Lonasteroal d) Chol ...
... 16. Which of the following is not a coenzyme? a) NAD b) COA c) FAD d) None of the above 17. An example of a lyase is? a) Glutamine synthetase b) Fumarase c) Cholinesteraise d) Amylase 18. The following are examples of sterols. Which one is not ? a) Prostaglandins b) Ergasterol c) Lonasteroal d) Chol ...
Biotechnology Unit 3: DNA to Proteins Essential Cell Biology
... iii. The two most common folding patterns are the α-helix (alpha helix) and the β-sheet (beta sheet) 1. Both of these patterns are common in most proteins and they are both the result of hydrogen bonds between the backbone molecules and not the side chains 2. An α-helix is caused by a single polypep ...
... iii. The two most common folding patterns are the α-helix (alpha helix) and the β-sheet (beta sheet) 1. Both of these patterns are common in most proteins and they are both the result of hydrogen bonds between the backbone molecules and not the side chains 2. An α-helix is caused by a single polypep ...
2.1 i. Explain the difference between atomic number and mass
... Explain the difference between atomic number and mass number Define an isotope. Give one example What is a radioactive isotope? What uses to humans have for radiation at both high and low levels? What is the difference between a molecule and a compound? Explain ionic bonding. Draw a Lewis diagr ...
... Explain the difference between atomic number and mass number Define an isotope. Give one example What is a radioactive isotope? What uses to humans have for radiation at both high and low levels? What is the difference between a molecule and a compound? Explain ionic bonding. Draw a Lewis diagr ...
Carbohydrates
... nitrogen = very little electronegativity = non-polar. 1 gram of fat stores twice as much energy than 1 gram of polysaccharide (Carb). WHY? Covalent bonds of long Hydrocarbon chains,…lots of energy in those long chains! Harder to break all those H-C bonds (vs. bonds in carbs that have oxygen at t ...
... nitrogen = very little electronegativity = non-polar. 1 gram of fat stores twice as much energy than 1 gram of polysaccharide (Carb). WHY? Covalent bonds of long Hydrocarbon chains,…lots of energy in those long chains! Harder to break all those H-C bonds (vs. bonds in carbs that have oxygen at t ...
Chemistry-Chapter 2 Lecture Notes Page
... - Ribose (5-carbon ring), Glucose (6-carbon ring), Fructose, Galactose Disaccharides - 2 monosaccharides joined by dehydration synthesis (Glucose X 2 = Maltose) Polysaccharides - Long chain monosaccharides (complex carbs) - Glycogen is a polymer of glucose ...
... - Ribose (5-carbon ring), Glucose (6-carbon ring), Fructose, Galactose Disaccharides - 2 monosaccharides joined by dehydration synthesis (Glucose X 2 = Maltose) Polysaccharides - Long chain monosaccharides (complex carbs) - Glycogen is a polymer of glucose ...
Bio302 Biochemistry II
... markedly in their activities: an inactive protomer to an active filamentous polymer. Citrate and isocitrate bind to the filamentous form, and palmitoyl-CoA binds preferentially to the protomer. Explain how this property is consistent with the regulatory role of acetyl-coA carboxylase in the biosynth ...
... markedly in their activities: an inactive protomer to an active filamentous polymer. Citrate and isocitrate bind to the filamentous form, and palmitoyl-CoA binds preferentially to the protomer. Explain how this property is consistent with the regulatory role of acetyl-coA carboxylase in the biosynth ...
DNA and RNA
... Adenine, Cytosine and Guanine, but instead of Thymine, it uses another pyrimidine, Uracil. There are three different types of RNA. They all play important roles in protein synthesis. ...
... Adenine, Cytosine and Guanine, but instead of Thymine, it uses another pyrimidine, Uracil. There are three different types of RNA. They all play important roles in protein synthesis. ...
Biol 1020 Ch. 5: types of organic molecules
... pay attention to what makes an R group polar, nonpolar, or ionic (charged) and thus their hydrophobic or hydrophilic nature ...
... pay attention to what makes an R group polar, nonpolar, or ionic (charged) and thus their hydrophobic or hydrophilic nature ...
enzymes are proteins
... 3. Carbon can form single, double, or triple bonds 4. Carbon forms isomers – Isomers are compounds that have the same chemical formula, but different structural formulas • Example: C4H10 ...
... 3. Carbon can form single, double, or triple bonds 4. Carbon forms isomers – Isomers are compounds that have the same chemical formula, but different structural formulas • Example: C4H10 ...
Organic Compounds The Big Four
... • - Highlight the similarities between protein, nucleic acid, lipids and carbohydrates • - Examine amino acid structure and amino acid chains • - Determine the function and shape of proteins and why they are Mr. Swift’s favourite. ...
... • - Highlight the similarities between protein, nucleic acid, lipids and carbohydrates • - Examine amino acid structure and amino acid chains • - Determine the function and shape of proteins and why they are Mr. Swift’s favourite. ...
Learning Standards vocab chemical basis and molecules of life 09
... formed (e.g., sodium atoms lose an electron and chlorine atoms gain an electron, then the charged ions are attracted to each other and form bonds). Explain the meaning of a chemical formula for an ionic array (e.g., NaCl). Give examples to illustrate that molecules are groups of two or more atom ...
... formed (e.g., sodium atoms lose an electron and chlorine atoms gain an electron, then the charged ions are attracted to each other and form bonds). Explain the meaning of a chemical formula for an ionic array (e.g., NaCl). Give examples to illustrate that molecules are groups of two or more atom ...
notes for cell resp - Fullfrontalanatomy.com
... 1. Polysaccharides, lipids and proteins can all be catabolized for energy 2. Many intermediates of cellular respiration can be shuttled to form glycogen, fatty acids, proteins or even nucleotides B. Catabolism and anabolism are integrated 1. Your body tries to be efficient and use these molecules in ...
... 1. Polysaccharides, lipids and proteins can all be catabolized for energy 2. Many intermediates of cellular respiration can be shuttled to form glycogen, fatty acids, proteins or even nucleotides B. Catabolism and anabolism are integrated 1. Your body tries to be efficient and use these molecules in ...
lipid3 - ChemEd DL
... acids are kept happy by secondary structure elements such as helices or sheets. There is almost no free space in the interior of the protein. The various sizes and shapes of the hydrophobic amino acids ensure that every space is filled. As in the interiors of water-soluble proteins, the polar hy ...
... acids are kept happy by secondary structure elements such as helices or sheets. There is almost no free space in the interior of the protein. The various sizes and shapes of the hydrophobic amino acids ensure that every space is filled. As in the interiors of water-soluble proteins, the polar hy ...
Cell and Genetics PowerPoint
... Structure forms from the Rough endoplasmic reticulum Acid interior Compartmentaliz ed so that it does not rupture At least 40 enzymes that can be found in lysosomes ...
... Structure forms from the Rough endoplasmic reticulum Acid interior Compartmentaliz ed so that it does not rupture At least 40 enzymes that can be found in lysosomes ...
Biology 233
... amino acids absorbed from diet synthesized from carbohydrates, lipids, or other amino acids (essential amino acids – cells cannot synthesize enough, must obtain from diet) USES OF AMINO ACIDS protein synthesis (gene expression) structural proteins – collagen, keratin regulatory proteins – hormones, ...
... amino acids absorbed from diet synthesized from carbohydrates, lipids, or other amino acids (essential amino acids – cells cannot synthesize enough, must obtain from diet) USES OF AMINO ACIDS protein synthesis (gene expression) structural proteins – collagen, keratin regulatory proteins – hormones, ...
Chapter 02 The Chemistry of Biology
... A. nucleotides. B. glycerol and fatty acids. C. monosaccharides. D. phosphate, glycerol, fatty acids. E. amino acids. ...
... A. nucleotides. B. glycerol and fatty acids. C. monosaccharides. D. phosphate, glycerol, fatty acids. E. amino acids. ...
(18 pts) Pyruvate can be converted to a variety of othe
... possible to make those different products from the same starting molecule.) The molecule could undergo any of a variety of different chemical reactions. Each would lead to a different product. Starting with pyruvate, for example, a carbon-carbon bond break would lead to ethanol and carbon dioxide. R ...
... possible to make those different products from the same starting molecule.) The molecule could undergo any of a variety of different chemical reactions. Each would lead to a different product. Starting with pyruvate, for example, a carbon-carbon bond break would lead to ethanol and carbon dioxide. R ...
AP Biology Review – Unit 1
... 8. Name that molecule • Water or H20 • The oxygen molecule in water, however, has a higher electronegativity than the hydrogen molecules. When they combine to form water, the electrons involved are unequally shared, tending to be nearer to the oxygen nucleus because of its greater electronegativity ...
... 8. Name that molecule • Water or H20 • The oxygen molecule in water, however, has a higher electronegativity than the hydrogen molecules. When they combine to form water, the electrons involved are unequally shared, tending to be nearer to the oxygen nucleus because of its greater electronegativity ...
Biochemistry
Biochemistry, sometimes called biological chemistry, is the study of chemical processes within and relating to living organisms. By controlling information flow through biochemical signaling and the flow of chemical energy through metabolism, biochemical processes give rise to the complexity of life. Over the last decades of the 20th century, biochemistry has become so successful at explaining living processes that now almost all areas of the life sciences from botany to medicine to genetics are engaged in biochemical research. Today, the main focus of pure biochemistry is in understanding how biological molecules give rise to the processes that occur within living cells, which in turn relates greatly to the study and understanding of whole organisms.Biochemistry is closely related to molecular biology, the study of the molecular mechanisms by which genetic information encoded in DNA is able to result in the processes of life. Depending on the exact definition of the terms used, molecular biology can be thought of as a branch of biochemistry, or biochemistry as a tool with which to investigate and study molecular biology.Much of biochemistry deals with the structures, functions and interactions of biological macromolecules, such as proteins, nucleic acids, carbohydrates and lipids, which provide the structure of cells and perform many of the functions associated with life. The chemistry of the cell also depends on the reactions of smaller molecules and ions. These can be inorganic, for example water and metal ions, or organic, for example the amino acids which are used to synthesize proteins. The mechanisms by which cells harness energy from their environment via chemical reactions are known as metabolism. The findings of biochemistry are applied primarily in medicine, nutrition, and agriculture. In medicine, biochemists investigate the causes and cures of disease. In nutrition, they study how to maintain health and study the effects of nutritional deficiencies. In agriculture, biochemists investigate soil and fertilizers, and try to discover ways to improve crop cultivation, crop storage and pest control.