1 / 80

Biochemistry

Biochemistry. Wait, Chemistry?? I thought I was in Biology. What does Biochemistry mean? Why do we need to understand Biochemistry?. Americans consume an average of 140 pounds of sugar per person per year. Uses of Organic Molecules.

rowa
Download Presentation

Biochemistry

An Image/Link below is provided (as is) to download presentation Download Policy: Content on the Website is provided to you AS IS for your information and personal use and may not be sold / licensed / shared on other websites without getting consent from its author. Content is provided to you AS IS for your information and personal use only. Download presentation by click this link. While downloading, if for some reason you are not able to download a presentation, the publisher may have deleted the file from their server. During download, if you can't get a presentation, the file might be deleted by the publisher.

E N D

Presentation Transcript

  1. Biochemistry

  2. Wait, Chemistry?? I thought I was in Biology

  3. What does Biochemistry mean? • Why do we need to understand Biochemistry?

  4. Americans consume an average of 140 pounds of sugar per person per year Uses of Organic Molecules Cellulose, found in plant cell walls, is the most abundant organic compound on Earth

  5. Uses of Organic Molecules • A typical cell in your body has about 2 meters of DNA A typical cow produces over 200 pounds of methane gas each year

  6. About 60-90 percent of an organism is water Water Water is used in most reactions in the body Water is called the universal solvent

  7. Water Properties • Polarity Cohesiveness Adhesiveness Surface Tension

  8. Carbon-based Molecules • Although a cell is mostly water, the rest of the cell consists mostly of carbon-based molecules Organic chemistry is the study of carbon compounds

  9. Carbon is a Versatile Atom • It has four electrons in an outer shell that holds eight Carbon can share its electrons with other atoms to form up to four covalent bonds

  10. Hydrocarbons • The simplest carbon compounds … Contain only carbon & hydrogen atoms

  11. Carbon can use its bonds to:: • Attach to other carbons – they can be straight, unbranched or branched chains or ring structures.

  12. Large Hydrocarbons: • Are the main molecules in the gasoline we burn in our cars The hydrocarbons of fat molecules provide energy for our bodies

  13. Shape of Organic Molecules • Each type of organic molecule has a unique three-dimensional shape The shape determines its function in an organism

  14. Functional Groups are: • Groups of atoms that give properties to the compounds to which they attach Lost Electrons Gained Electrons

  15. Common Functional Groups

  16. Giant Molecules - Polymers • Large molecules are called polymers Polymers are built from smaller molecules called monomers Biologists call them macromolecules

  17. Examples of Polymers • Proteins Lipids Carbohydrates Nucleic Acids

  18. Most Macromolecules are Polymers • Polymers are made by stringing together many smaller molecules called monomers Nucleic Acid Monomer

  19. Linking Monomers Cells link monomers by a processcalled condensation or dehydration synthesis (removing a molecule of water) Remove H H2O Forms Remove OH This process joins two sugar monomers to make a double sugar

  20. Breaking Down Polymers • Cells break down macromolecules by a process called hydrolysis (adding a molecule of water) Water added to split a double sugar

  21. Macromolecules in Organisms • There are four categories of large molecules in cells: Carbohydrates Lipids Proteins Nucleic Acids

  22. Carbohydrates • Carbohydrates include: • Small sugar molecules in soft drinks • Long starch molecules in pasta and potatoes

  23. Monosaccharides: • Called simple sugars Include glucose, fructose, & galactose Have the same chemical, but different structural formulas C6H12O6

  24. Monosaccharides • Glucose is found in sports drinks Fructose is found in fruits Honey contains both glucose & fructose Galactose is called “milk sugar” -OSE ending means SUGAR

  25. Isomers • Glucose & fructose are isomers because they’re structures are different, but their chemical formulas are the same

  26. Rings • In aqueous (watery) solutions, monosaccharides form ring structures

  27. Cellular Fuel • Monosaccharides are the main fuel that cells use for cellular work ATP

  28. Disaccharides • A disaccharide is a double sugar They’re made by joining two monosaccharides Involves removing a water molecule (condensation) Bond called a GLYCOSIDIC bond

  29. Disaccharides • Common disaccharides include: • Sucrose (table sugar) • Lactose (Milk Sugar) • Maltose (Grain sugar)

  30. Disaccharides • Sucrose is composed of glucose + fructose Maltose is composed of 2 glucose molecules Lactose is made of galactose + glucose GLUCOSE

  31. Polysaccharides • Complex carbohydrates Composed of many sugar monomers linked together Polymers of monosaccharide chains

  32. Examples of Polysaccharides Glucose Monomer Starch Glycogen Cellulose

  33. Starch • Starch is an example of a polysaccharide in plants Plant cells store starch for energy Potatoes and grains are major sources of starch in the human diet

  34. Glycogen • Glycogen is an example of a polysaccharide in animals Animals store excess sugar in the form of glycogen Glycogen is similar in structure to starch because BOTH are made of glucose monomers

  35. Cellulose • Cellulose is the most abundant organic compound on Earth It forms cable-like fibrils in the tough walls that enclose plants It is a major component of wood It is also known as dietary fiber

  36. Cellulose SUGARS

  37. Dietary Cellulose • Most animals cannot derive nutrition from fiber They have bacteria in their digestive tracts that can break down cellulose

  38. Sugars in Water • Simple sugars and double sugars dissolve readily in water WATER MOLECULE They are hydrophilic, or “water-loving” -OH groups make them water soluble SUGAR MOLECULE

  39. Lipids • Lipids are hydrophobic –”water fearing” Do NOT mix with water Includes fats, waxes, steroids, & oils FAT MOLECULE

  40. Function of Lipids • Fats store energy, help to insulate the body, and cushion and protect organs

  41. Types of Fatty Acids • Unsaturated fatty acids have less than the maximum number of hydrogens bonded to the carbons (a double bond between carbons) Saturated fatty acids have the maximum number of hydrogens bonded to the carbons (all single bonds between carbons)

  42. Types of Fatty Acids Single Bonds in Carbon chain Double bond in carbon chain

  43. Triglyceride • Monomer of lipids Composed of Glycerol & 3 fatty acid chains Glycerol forms the “backbone” of the fat Organic Alcohol (-OL ending)

  44. Triglyceride Fatty Acid Chains Glycerol

  45. Fats in Organisms • Most animal fats have a high proportion of saturated fatty acids & exist as solids at room temperature (butter, margarine, shortening)

  46. Fats in Organisms • Most plant oils tend to be low in saturated fatty acids & exist as liquids at room temperature (oils)

  47. Fats • Dietary fat consists largely of the molecule triglyceride composed of glycerol and three fatty acid chains Fatty Acid Chain Glycerol Condensation links the fatty acids to Glycerol

  48. Lipids & Cell Membranes • Cell membranes are made of lipids called phospholipids • Phospholipids have a head that is polar & attract water (hydrophilic) • Phospholipids also have 2tails that are nonpolar and do not attract water (hydrophobic)

  49. Steroids • The carbon skeleton of steroids is bent to form 4 fused rings Cholesterol Cholesterol is the “base steroid” from which your body produces other steroids Estrogen Testosterone Estrogen & testosterone are also steroids

  50. Synthetic Anabolic Steroids • They are variants of testosterone Some athletes use them to build up their muscles quickly They can pose serious health risks

More Related