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KEY CONCEPT Carbon-based molecules are the foundation of life.

KEY CONCEPT Carbon-based molecules are the foundation of life. Carbon atoms have unique bonding properties. Carbon forms covalent bonds with up to four other atoms, including other carbon atoms. Carbon-based molecules have three general types of structures. straight chain branched chain ring.

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KEY CONCEPT Carbon-based molecules are the foundation of life.

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  1. KEY CONCEPTCarbon-based molecules are the foundation of life.

  2. Carbon atoms have unique bonding properties. • Carbon forms covalent bonds with up to four other atoms, including other carbon atoms. • Carbon-based molecules have three general types of structures. • straight chain • branched chain • ring

  3. Many carbon-based molecules are made of many small subunits bonded together. • Monomers are the individual subunits. • Polymers are made of many monomers.

  4. Four main types of carbon-based molecules are found in living things. • Carbohydrates are made of carbon, hydrogen, and oxygen.

  5. Four main types of carbon-based molecules are found in living things. • Carbohydrates are made of carbon, hydrogen, and oxygen. • Carbohydrates include sugars and starches. • Monosaccharides are simple sugars. • Polysaccharides include starches, cellulose, and glycogen.

  6. Polymer (starch) Starch is a polymer of glucose monomers that often has a branched structure. Polymer (cellulose) Cellulose is a polymer of glucose monomers that has a straight, rigid structure monomer • Carbohydrates can be broken down to provide energy for cells. • Some carbohydrates are part of cell structure.

  7. Triglyceride • Lipids are nonpolar molecules that include fats, oils, and cholesterol. • Many contain carbon chains called fatty acids. • Fats and oils contain fatty acids bonded to glycerol.

  8. Lipids have several different functions. • broken down as a source of energy • make up cell membranes • used to make hormones

  9. Fats and oils have different types of fatty acids. • saturated fatty acids • unsaturated fatty acids

  10. Phospholipid • Phospholipids make up all cell membranes. • Polar phosphate “head” • Nonpolar fatty acid “tails”

  11. Proteins are polymers of amino acid monomers. • Twenty different amino acids are used to build proteins in organisms.

  12. Proteins are polymers of amino acid monomers. • Amino acids differ in side groups, or R groups. • Twenty different amino acids are used to build proteins in organisms.

  13. Proteins are polymers of amino acid monomers. • Amino acids are linked by peptide bonds. • Twenty different amino acids are used to build proteins in organisms. • Amino acids differ in side groups, or R groups.

  14. hydrogen bond Hemoglobin • Proteins differ in the number and order of amino acids. • Amino acids interact to give a protein its shape. • Incorrect amino acids change a protein’s structure and function.

  15. Nucleic acids are polymers of monomers called nucleotides.

  16. nitrogen-containing molecule,called a base A phosphate group deoxyribose (sugar) • Nucleic acids are polymers of monomers called nucleotides. • Nucleotides are made of a sugar, phosphate group, and a nitrogen base.

  17. DNA RNA • Nucleic acids are polymers of monomers called nucleotides. • DNA stores genetic information. • Nucleotides are made of a sugar, phosphate group, and a nitrogen base. • RNA builds proteins.

  18. KEY CONCEPT Life depends on chemical reactions.

  19. Bonds break and form during chemical reactions. • Chemical reactions change substances into different ones by breaking and forming chemical bonds. • Reactants are changed during a chemical reaction. • Products are made by a chemical reaction.

  20. Bond energy is the amount of energy that breaks a bond. • Energy is added to break bonds. • Energy is released when bonds form. • A reaction is at equilibrium when reactants and products form at the same rate. CO2 + H2O H2CO3

  21. Chemical reactions release or absorb energy. • Activation energy is the amount of energy that needs to be absorbed to start a chemical reaction.

  22. Exothermic reactions release more energy than they absorb. • Reactants have higher bond energies than products. • Excess energy is released by the reaction.

  23. Endothermic reactions absorb more energy than they release. • Reactants have lower bond energies than products. • Energy is absorbed by the reaction to make up the difference.

  24. KEY CONCEPTEnzymes are catalysts for chemical reactions in living things.

  25. A catalyst lowers activation energy. • Catalysts are substances that speed up chemical reactions. • decrease activation energy • increase reaction rate

  26. Enzymes allow chemical reactions to occur under tightly controlled conditions. • Enzymes are catalysts in living things. • Enzymes are needed for almost all processes. • Most enzymes are proteins.

  27. Disruptions in homeostasis can prevent enzymes from functioning. • Enzymes function best in a small range of conditions. • Changes in temperature and pH can break hydrogen bonds. • An enzyme’s function depends on its structure.

  28. substrates (reactants) enzyme Substrates bind to anenzyme at certain places called active sites. • An enzyme’s structure allows only certain reactants to bind to the enzyme. • substrates • active site

  29. Substrates bind to anenzyme at certain places called active sites. The enzyme bringssubstrates together and weakens their bonds. The catalyzed reaction formsa product that is releasedfrom the enzyme. • The lock-and-key model helps illustrate how enzymes function. • substrates brought together • bonds in substrates weakened

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