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Lecture 3: Chemistry of Life Lecture 3: Chemistry of Life Goals: 1. Sprint through General Chemistry 2. Whisper past Organic Chemistry 3. Approach Biochemistry cautiously 4. Apply chemistry overview and relate biological chemistry to this course and your life in general Key Terms: Charge, proton, neutron, electron, radioisotope, tracer, chemical bonds a)ionic, b)covalent, c)hydrogen, atom, molecule, pH scale, buffer, basic, acidic, hydrophobic, hydrophillic, acidosis, alkalosis, solute, polar, non-polar. http://pearl1.lanl.gov/periodic/default.htm http://www.chemsoc.org/viselements/pages/pertable_fla.htm Elements • Fundamental forms of matter • Can’t be broken apart by normal means • 92 occur naturally on Earth Less than 12 occur on the exam Most Common Elements in Living Organisms CHON Carbon Hydrogen Oxygen Nitrogen What Are Atoms? • Smallest particles that retain properties of an element • Made up of subatomic particles: – Protons (+) – Electrons (-) – Neutrons (no charge) Hydrogen and Helium Atoms electron proton neutron HYDROGEN HELIUM Fig. 2.3, p. 22 Atomic Number • Number of protons • All atoms of the same element have the same atomic number • Atomic number of hydrogen = 1 • Atomic number of carbon = 6 Mass Number Number of protons + Number of neutrons Isotopes vary in mass number (not atomic number or they would be something else) Atomic Mass Isotopes Radioisotopes • Atoms of an element with different numbers of neutrons (different mass numbers) • Carbon 12 has 6 protons, 6 neutrons • Carbon 14 has 6 protons, 8 neutrons • Have an unstable nucleus that emits energy and particles • Radioactive decay transforms radioisotope into a different element • Decay occurs at a fixed rate Radioisotopes as Tracers • Example: Tracer Drug Study – How long does a drug stay in the patient? – Determine dose guidelines • Compound synthesized with a radioisotope • Emissions from the tracer can be detected with special devices – Track levels in the blood, urine and feces • Following movement of tracers is useful in many areas of biology High Sensitivity Very Low Dose Other Uses of Radioisotopes • Drive artificial pacemakers • Biomedical Imaging – Thyroid and bone scans • Radiation therapy Emissions from some radioisotopes can destroy cells. Some radioisotopes are used to kill small cancers. What Determines Whether Atoms Will Interact? The most general of General Chemistry Electrons • Carry a negative charge • Repel one another • Are attracted to protons in the nucleus • Move in orbitals - volumes of space that surround the nucleus y Z X When all p orbitals are full Electron Orbitals • Orbitals can hold up to two electrons • Atoms differ in the number of occupied orbitals • Orbitals closest to nucleus are lower energy and are filled first Shell Model • First shell – Lowest energy – Holds 1 orbital with up to 2 electrons • Second shell – 4 orbitals hold up to 8 electrons CALCIUM 20p+ , 20e- Electron Vacancies • Unfilled shells make atoms likely to react • Hydrogen, carbon, oxygen, and nitrogen all have vacancies in their outer shells CARBON 6p+ , 6e- NITROGEN 7p+ , 7e- HYDROGEN 1p+ , 1e- Chemical Bonds, Molecules, & Compounds • Bond is union between electron structures of atoms • Atoms bond to form molecules • Molecules may contain atoms of only one element - O2 • Molecules of compounds contain more than one element - H2O Only a few atoms, even fewer Chemical Bonds Ionic bonds Between metallic and non metallic atoms Easily dissolved by water Covalent Share at least one pair of electrons Polar and non-polar bonds Tight (high energy) bond Hydrogen bonds A hydrogen between atoms Not so tight (low energy) bond: 1/10th covalent 1. Ionic Bonding • One atom loses electrons, becomes positively charged ion • Another atom gains these electrons, becomes negatively charged ion • Charge difference attracts the two ions to each other Ion Formation • Atom has equal number of electrons and protons - no net charge • Atom loses electron(s), becomes positively charged ion • Atom gains electron(s), becomes negatively charged ion Formation of NaCl • Sodium atom (Na) – Outer shell has one electron • Chlorine atom (Cl) – Outer shell has seven electrons • Na transfers electron to Cl forming Na+ and Cl• Ions remain together as NaCl Formation of NaCl 7mm electron transfer SODIUM ATOM 11 p+ 11 e- CHLORINE ATOM 17 p+ 17 e- SODIUM ION 11 p+ 10 e- CHLORINE ION 17 p+ 18 eFig. 2.10a, p. 26 2. Covalent Bonding Atoms share a pair or pairs of electrons to fill outermost shell •Single covalent bond H2 Single bond •Double covalent bond O2 Double bond •Triple covalent bond N2 Triple bond Two Flavors of Covalent Bonds Non-polar Covalent Polar Covalent • Atoms share electrons equally • Nuclei of atoms have same number of protons • Example: Hydrogen gas (H-H) • Number of protons in nuclei of participating atoms is NOT equal • Molecule held together by polar covalent bonds has no NET charge • Electrons spend more time near nucleus with most protons – Example: Water – Electrons more attracted to O nucleus than to H nuclei Polar Covalent Bonds + slight negative charge at this end KEEP YOUR EYE ON THE ELECTRONS O H H molecule has no net charge ( + and - balance each other) slight positive charge at this end Hydrogen Bonding A bond by Hydrogen between two atoms • Important for O and N • Lets two electronegative atoms interact – The H gives one a net + and the other one that is still – is attracted to it. • The H proton becomes “naked” because its electron gets pulled away. Hydrogen bond figure KEEP YOUR EYE ON THE ELECTRONS Like Charge Atoms Repel Each Other - - - + - Covalent Bond Hydrogen Bond Opposite Charge Atoms Attract Each Other Examples of Hydrogen Bonds one large molecule another large molecule a large molecule twisted back on itself Properties of Water •Polarity •Temperature-Stabilizing •Cohesive •Solvent Water Is a Polar Covalent Molecule • Molecule has no net charge • Oxygen end has a slight negative charge • Hydrogen end has a slight positive charge O H H Liquid Water H + + _ O H + H + + _ O H + Hydrophilic & Hydrophobic Substances • Hydrophilic substances – Polar – Hydrogen bond with water – Example: sugar • Hydrophobic substances – Non-polar – Repelled by water – Example: oil Temperature-Stabilizing Effects • Water absorbs a lot more heat than other liquids, such as oil, before its temperature rises. • Why? • Heat is Vibration! – Molecules with lots of vibrational energy feel hot. • Much of the added energy disrupts hydrogen bonding rather than increasing the movement of molecules Evaporation of Water • Large energy input can cause individual molecules of water to break free into air • As molecules break free, they carry away some energy (lower temperature) • Evaporative water loss is used by mammals to lower body temperature Why Ice Floats • In ice, hydrogen bonds lock molecules in a lattice • Water molecules in lattice are spaced farther apart then those in liquid water • Ice is less dense than water Water Cohesion • Hydrogen bonding holds molecules in liquid water together • Creates surface tension • Allows water to move as continuous column upward through stems of plants Water Is a Good Solvent • Ions and polar molecules dissolve easily in water • When solute dissolves, water molecules cluster around its ions or molecules and keep them separated Water as a solvent: Spheres of Hydration – – + + + + Na+ – – – – – – – – – + + + + + Cl– + + + + + + + + + Fig. 2.16, p. 29 Water • Solvent- polar – Keeps ions in solution – Doesn’t dissolve membranes • Heat management – Loosing heat – Holding heat – Density Changes If it wasn’t ugly enough already: Hydrogen Ions: + H • Unbound protons • Have important biological effects • Form when water ionizes The pH Scale • Measures H+ concentration of fluid • Change of 1 on scale means 10X change in H+ concentration Highest H+ Lowest H+ 0---------------------7-------------------14 Acidic Neutral Basic Examples of pH Pure water is neutral with pH of 7.0 Acidic Basic (Alkaline) Acids & Bases • Acids – Donate H+ when dissolved in water – Acidic solutions have pH < 7 • Bases – Accept H+ when dissolved in water – Acidic solutions have pH > 7 Buffers Minimize shifts in pH Carbonic Acid-Bicarbonate Buffer System • When blood pH rises, carbonic acid dissociates to form bicarbonate and H+ H2C03 -----> HC03- + H+ • When blood pH drops, bicarbonate binds H+ to form carbonic acid HC03- + H+ -----> H2C03 Acidosis- too much CO2 in blood Alkalosis- blood pH too low Lecture 2: Chemistry of Life Part 2 Feeling a little burnt out? Demonstration of Chemical Bonds Tests: 1. Water as a solvent 2. Bond strength Predictions: Covalent bonds Ionic bonds Hydrogen bonds Hydrophilic interactions Hydrophobic interactions Hydrogen Bonds Aliphatic Resin, PVA and Elmer Why does glue work? 1. Mechanical component 2. Chemical component Process 1. Infiltrate wood fibers 2. Allow tight contact 3. Remove water (solvent) Demonstration of Hydrogen bond strength Hydrogen Bonds Aliphatic Resin, PVA and Elmer • Bond Strength: – 3,500 pounds per square inch • Hydrogen bonds form between the wood and glue as the water leaves • Conclusion: Organic Compounds • Hydrogen and other elements covalently bonded to carbon • Major Classes of Biological Molecules – Carbohydrates – Lipids – Proteins – Nucleic Acids Carbon’s Bonding Behavior • Outer shell of carbon has 4 electrons; can hold 8 • Each carbon atom can form covalent bonds with up to four atoms Bonding Arrangements • Carbon atoms can form chains or rings • Other atoms project from the carbon backbone Functional Groups • Atoms or clusters of atoms that are covalently bonded to carbon backbone • Give organic compounds their different properties Examples of Functional Groups Hydroxyl group - OH Alcohol Amino group - NH3+ Dead things Carboxyl group - COOH Acids Sulfhydryl group - SH Internal bonds Phosphate group - PO3- On and off switch Types of Reactions Functional group transfer Electron transfer Rearrangement x Condensation Cleavage Hydrolysis Condensation Reactions • Form polymers from subunits • Enzymes remove -OH from one molecule, H from another, form bond between two molecules • Discarded atoms can join to form water Condensation -ie. Water condenses on the inside of my window when the air conditioner is on full blast Or.. Water forms …. Hydrolysis • A type of cleavage reaction • Breaks polymers into smaller units • Enzymes split molecules into two or more parts • An OH group and an H atom derived from water are attached at exposed sites HYDROLYSIS Carbohydrates Monosaccharides (simple sugars) Oligosaccharides (short-chain carbohydrates) Polysaccharides (complex carbohydrates) Monosaccharides • Simplest carbohydrates • Most are sweet tasting, water soluble • Most have 5- or 6-carbon backbone Glucose (6 C) Fructose (6 C) Ribose (5 C) Deoxyribose (5 C) Two Monosaccharides glucose fructose Disaccharides • Type of oligosaccharide • Two monosaccharides covalently bonded • Formed by condensation reaction glucose fructose + H2O sucrose Polysaccharides • Straight or branched chains of many sugar monomers • Most common are composed entirely of glucose – Cellulose – Starch (such as amylose) – Glycogen Cellulose & Starch • Differ in bonding patterns between monomers (type of linkage) • Cellulose - tough, indigestible, structural material in plants • Starch - easily digested, storage form in plants Cellulose and Starch Changes in bonds result in: -different interactions -different structures -different physical properties Glycogen • Sugar storage form in animals • Large stores in muscle and liver cells • When blood sugar decreases, liver cells degrade glycogen, release glucose Chitin • Polysaccharide • Nitrogen-containing groups attached to glucose monomers • Found in insects, worms, and fungi (not humans) • Structural material for hard parts of invertebrates, cell walls of many fungi Lipids • Most include fatty acids – Fats – Phospholipids – Waxes • Sterols and their derivatives have no fatty acids • Tend to be insoluble in water Fatty Acids • Carboxyl group (-COOH) at one end • Carbon backbone (up to 36 C atoms) – Saturated - Single bonds between carbons – Unsaturated - One or more double bonds Three Fatty Acids stearic acid oleic acid Lard Olive linolenic acid Flax Fats • Fatty acid(s) attached to glycerol • Triglycerides are most common Phospholipids • Main components of cell membranes Sterols and Derivatives • No fatty acids • Rigid backbone of four fused-together carbon rings • Cholesterol - most common type in animals Waxes • Long-chain fatty acids linked to long chain alcohols or carbon rings • Firm consistency, repel water • Important in water-proofing • Size matters Polyunsaturated Fatty Acids Omega-3 •Omega-6 fatty acids are the predominant polyunsaturated fatty acids (PUFAs) in the Western diet. •The omega-6 and omega-3 fatty acids are metabolically distinct and have opposing physiologic functions. Omega-6 •The increased omega-6/omega-3 ratio in Western diets most likely contributes to an increased incidence of heart disease and inflammatory disorders. •Omega-3 PUFAs suppress cell mediated immune responses and reduce inflammation Lipids in Cell Signaling •Bioactive Lipids •Made in all cells •Short range signaling •Eicosanoids? •Prostaglandins •Inflammation and Pain Perception •Kidney Function •Bone Development •Reproductive Process •Commercially Important •$4 BILLION/ Year spend on drugs to inhibit prostaglandin synthesis •Vioxx, Celebrex, Ibuprofen, Asprin PGE2 Amino Acid Structure carboxyl group amino group R group Properties of Amino Acids • Determined by the “R group” • Amino acids may be: – Non-polar – Uncharged, polar – Positively charged, polar – Negatively charged, polar Protein Synthesis • Protein is a chain of amino acids linked by peptide bonds • Peptide bond – Type of covalent bond – Links amino group of one amino acid with carboxyl group of next – Forms through condensation reaction Forming Peptide Bonds Primary Structure • Sequence of amino acids • Unique for each protein • Two linked amino acids = dipeptide • Three or more = polypeptide • Backbone of polypeptide has N atoms: -N-C-C-N-C-C-N-C-C-N- Protein Shapes • Fibrous proteins – Polypeptide chains arranged as strands or sheets • Globular proteins – Polypeptide chains folded into compact, rounded shapes Protein Structure • Primary- just the sequence (1D) • Secondary- interactions on the chain (2D) • Tertiary- interactions between parts of the chain the chain. (3D) • Quaternary- interactions with other chains Primary Structure & Protein Shape • Primary structure influences shape in two main ways: – Allows hydrogen bonds to form between different amino acids along length of chain – Puts R groups in positions that allow them to interact Secondary Structure • Hydrogen bonds form between different parts of polypeptide chain • These bonds give rise to coiled or extended pattern • Helix or pleated sheet Examples of Secondary Structure a-helix b-sheet Tertiary Structure heme group Folding as a result of interactions between R groups coiled and twisted polypeptide chain of one globin molecule Quaternary Structure Some proteins are made up of more than one polypeptide chain Hemoglobin Polypeptides With Attached Organic Compounds Nothing new, just more combinations • Lipoproteins – Proteins combined with cholesterol, triglycerides, phospholipids • Glycoproteins – Proteins combined with oligosaccharides Denaturation • Disruption of three-dimensional shape • Breakage of weak bonds • Causes of denaturation: – pH – Temperature • Destroying protein shape disrupts function A Permanent Wave hair’s cuticle one hair cell bridges broken keratin macrofibril hair wrapped around cuticles coiled keratin polypeptide chain microfibril (three chains coiled into one strand) different bridges form Nucleotide Structure • Sugar – Ribose or deoxyribose • At least one phosphate group • Base – Nitrogen-containing – Single or double ring structure Nucleotide Functions • Energy carriers • Coenzymes • Chemical messengers • Building blocks for nucleic acids Careful: Nucleotide isn’t just DNA or RNA ATP - A Nucleotide base three phosphate groups sugar Nucleic Acids Cytosine Adenine • Composed of nucleotides • Single- or double-stranded • Sugar-phosphate backbone DNA • Double-stranded • Consists of four types of nucleotides • A bound to T • C bound to G RNA • Usually single strands • Four types of nucleotides • Unlike DNA, contains the base uracil in place of thymine • Three types are key players in protein synthesis Natural Toxins • Normal metabolic products of one species that can harm or kill a different species • Natural pesticides – Compounds from tobacco – Compounds from chrysanthemum Synthetic Toxins atrazine DDT malathion Negative Effects of Pesticides • May be toxic to predators that help fight pests • May be active for weeks to years • Can be accidentally inhaled, ingested, or absorbed by humans • Can cause rashes, headaches, allergic reactions Producers Capture Carbon Using photosynthesis, plants and other producers turn carbon dioxide and water into carbon-based compounds Atmospheric Carbon Dioxide • Researchers have studied concentration of CO2 in air since the 1950s • Concentration shifts with season – Declines in spring and summer when producers take up CO2 for photosynthesis CO2 and Global Warming • Seasonal swings in CO2 increasing • Spring decline starting earlier • Temperatures in lower atmosphere increasing • Warming may be promoting increased photosynthesis Humans and Global Warming • Fossil fuels are rich in carbon • Use of fossil fuels releases CO2 into atmosphere • Increased CO2 may contribute to global warming Chemical Benefits and Costs • Understanding of chemistry provides fertilizers, medicines, etc. • Chemical pollutants damage ecosystems Bioremediation Use of living organisms to withdraw harmful substances from the environment Thyroid Scan • Measures health of thyroid by detecting radioactive iodine taken up by thyroid gland normal thyroid enlarged cancerous