Chemical Principles and Biomolecules (Chapter 2) Lecture Materials for Amy Warenda Czura, Ph.D. Suffolk County Community College Eastern Campus

Chemical Principles and Biomolecules (Chapter 2) Lecture Materials for Amy Warenda Czura, Ph.D. Suffolk County Community College Eastern Campus Primary Source for figures and content: Tortora, G.J. Microbiology An Introduction 8th, 9th, 10th ed. San Francisco: Pearson Benjamin Cummings, 2004, 2007, 2010. Amy Warenda Czura, Ph.D. 1 SCCC BIO244 Chapter 2 Lecture Slides

Chemistry = the study of atoms and molecules -All matter is composed of atoms -Atoms bond together to form molecules Atom = smallest unit of matter (Matter = anything with mass &takes up space) -consists of 3 types of subatomic particles: 1. protons (p): + charge, in nucleus 2. neutrons (n): neutral, in nucleus 3. electrons (e`): - charge, around nucleus Amy Warenda Czura, Ph.D. 2 SCCC BIO244 Chapter 2 Lecture Slides

Atomic number = number of p in the nucleus Atomic Mass = total number of p + n Chemical element = all atoms with same # of protons that behave the same way. -92 naturally occurring elements -only 26 commonly found in living things Most abundant in life: Symbol Atomic # Mass Hydrogen H 1 1 Carbon C 6 12 Nitrogen N 7 14 Oxygen O 8 16 Isotope = atoms with same # of protons but different numbers of neutrons. e.g. oxygen 3 isotopes in nature. 16 O (8p, 8n) (99.76% of all) 17 O (8p, 9n) 18 O (8p, 10n) Amy Warenda Czura, Ph.D. 3 SCCC BIO244 Chapter 2 Lecture Slides

Electron Configurations -electrons organized into 18e 8e shells around the nucleus -shells = regions 2e 8e corresponding to different energy levels -innermost shell can hold up to 2 e` -2 nd and 3 rd : 8 e` each -4 th, 5 th, 6 th : 18 e` each -shells are filled from inside to outside Atoms have the same number of electrons as they do protons (neutral charge) Valence shell = outer most electron shell (atoms want this shell to be full) Valence = combining capacity/bonding capacity; the number of extra or missing electrons in the outer most shell Amy Warenda Czura, Ph.D. 4 SCCC BIO244 Chapter 2 Lecture Slides

e.g. Mg atomic #12 electron shells: 2, 8, 2 2 extra electrons O atomic #8 electron shells: 2, 6 needs 2 electrons -atoms with outer shells more than half full want to take electrons to make a full valence shell -atoms with outer shells more than half empty want to give away electrons to drop to lower full shell -atoms with full valence shells are inert -a gain/loss of electrons results in the atom no longer being neutral: Ion = atom with unequal numbers of protons and electrons -cation = positive charge, more p than e` -anion = negative charge, more e` than p Amy Warenda Czura, Ph.D. 5 SCCC BIO244 Chapter 2 Lecture Slides

Molecules any two or more atoms held together by attractive forces called chemical bonds Compound a molecule that contains at least two different kinds of atoms chemically bonded e.g. O 2 = molecule H 2O = molecule and compound Types of Chemical Bonds 1. Ionic Bonds -electrons are gained or lost, and equal but oppositely charged ions attract each other e.g. Na atomic #11: e` 2:8:1 Cl atomic # 17: e` 2:8:7 -Na donates 1 e` to Cl -both now have full valence but unequal charge (Na + & Cl - ) Amy Warenda Czura, Ph.D. 6 SCCC BIO244 Chapter 2 Lecture Slides

-resulting ions attracted forming an ionic bond -create the new molecule NaCl 2. Covalent Bonds -atoms share one or more pairs of electrons -these bonds are stronger and more common in living organisms than ionic bonds -shared e` orbit nuclei of both atoms simultaneously Amy Warenda Czura, Ph.D. 7 SCCC BIO244 Chapter 2 Lecture Slides

single covalent bond = one pair e` shared e.g. H 2 or CH 4 double covalent bond = 2 pair e` shared e.g. O 2 triple covalent bond = 3 pair e` shared e.g. N 2 Nonpolar covalent bond = equal sharing of e` Polar covalent bond = one atom shares e` more of the time, causes one side of molecule to be + and other to be - (common with H bonded to O or N) Amy Warenda Czura, Ph.D. 8 SCCC BIO244 Chapter 2 Lecture Slides

3. Hydrogen Bonds -result from polar covalent bonds -when H is bound to a large atom like O or N the large atoms takes the electrons more time setting up a slightly positive charge on the hydrogen side of the molecule and negative on oxygen or nitrogen side. -the + H gets attracted to the - O or N in another molecule creating a weak bond between molecules -H-bonds too weak to form molecules -act as bridges between existing molecules or within large molecules Amy Warenda Czura, Ph.D. 9 SCCC BIO244 Chapter 2 Lecture Slides

Chemical Reactions: -making or breaking bonds input material = reactant (or substrate) resulting material = product -takes energy to make a bond, release energy when breaking a bond Endergonic reaction absorbs more energy than it releases (feels cold) Exergonic reaction releases more energy than it absorbs (feels hot) 3 types of reactions common to living cells: 1. Synthesis reactions = form new bonds A + B AB (anabolic reaction) 2. Decomposition reactions = break bonds AB A + B (catabolic reaction) 3. Exchange reactions = original bonds are broken and new bonds are formed AB + CD AD + BC Amy Warenda Czura, Ph.D. 10 SCCC BIO244 Chapter 2 Lecture Slides

Activation energy = amount of energy needed to disrupt the stable electron configuration of any molecule or atom so it reacts Reaction rate = frequency of interactions containing sufficient energy to bring about a reaction (can be increased by heat, pressure, or concentration of reactants) Catalyst = substance that can speed a chemical reaction without being permanently altered or consumed Enzyme = biological catalyst -acts on a specific substance = substrate -binds substrate at the active site on enzyme -catalyzes only one reaction e.g. sucrase: sucrose glucose + fructose -an enzyme lowers the activation energy of the reaction by orienting the substrate in a way to increase the probability of a reaction Amy Warenda Czura, Ph.D. 11 SCCC BIO244 Chapter 2 Lecture Slides

*enzymes function to speed up reactions at temperatures compatible with life Important Biological Molecules 1. Inorganic molecules: -lack C and H chains -often formed by ionic bonds, but not always e.g. H 2 O, O 2, CO 2, salts, acids, bases 2. Organic molecules -based on C and H chains -structurally complex -typically formed by covalent bonds e.g. sugars, amino acids, vitamins, etc. Important Inorganic Molecules A. Water -most common, most important to life -polar molecule Amy Warenda Czura, Ph.D. 12 SCCC BIO244 Chapter 2 Lecture Slides

-Water important because of its properties: 1. H-bonding resists rapid temp change -each H 2 O can bond with 4 others -high boiling point -low freezing point -liquid at temps compatible with life 2. Good solvent -polar and ionic substances dissociate easily in water to form solutions Amy Warenda Czura, Ph.D. 13 SCCC BIO244 Chapter 2 Lecture Slides

3. Chemical reactivity -polarity allows it to serve as reactant in many reactions: Hydrolysis: decomposition using water AB + H 2 O AOH + BH Condensation/ Dehydration synthesis: synthesis using water AOH + BH AB + H 2 O B. Acids, Bases, Salts Acid = substance that dissociates into H + and anions (proton donor) Base = substance that dissociates into OH - and cations (proton acceptor) Salt = substance that dissociates into cations and anions that are not H + or OH - Amy Warenda Czura, Ph.D. 14 SCCC BIO244 Chapter 2 Lecture Slides

Maintaining a normal range of H + and OH - ions is necessary for most biological processes ph = logarithmic expression of amount of H + in solutions -stands for potential of hydrogen -Log scale = 10 fold change -ph calculated as log 10 [H + ] in moles/liter (scale 0-14) Acidic solution = more H + than OH - ph below 7 Basic/Alkaline solution = more OH - than H + ph above 7 Pure H 2 O has equal H + and OH - neutral solution ph of 7 Amy Warenda Czura, Ph.D. 15 SCCC BIO244 Chapter 2 Lecture Slides

-buffers are used in living things to absorb H + ions released during metabolism to keep the ph from changing -most organisms grow best around neutral ph Organic Molecules -carbon based molecules -produced by living things -C, atomic # 6, can participate in up to 4 covalent bonds -allows formation of large molecules with other atoms: H, O, N, S, P, etc. Classes of Organic Molecules 1. Carbohydrates -sugars & starches -composed of C:H:O in 1:2:1 ratio -necessary for DNA, cell walls, amino acids, nutrient reserves Amy Warenda Czura, Ph.D. 16 SCCC BIO244 Chapter 2 Lecture Slides

3 groups based on complexity of structure: monosaccharide = simple sugar disaccharide = 2 bonded simple sugars polysaccharide = 3 or more bonded sugars (chemical reactions in biological systems usually involve water: hydrolysis or dehydration synthesis) 2. Lipids -fats and waxes -composed of C, H, O but usually O < C -function in energy storage, cell membranes, cell walls Amy Warenda Czura, Ph.D. 17 SCCC BIO244 Chapter 2 Lecture Slides

Common examples of lipids: A. Glycerides = glycerol + fatty acids (C + H hydrocarbon chain) triglyceride = fat Amy Warenda Czura, Ph.D. 18 SCCC BIO244 Chapter 2 Lecture Slides

B. Phospholipids = glyceride + phosphate group attached to the glycerol Bipolar molecule: Hydrophilic head group (phosphate+ glycerol) Hydrophobic tail group (hydrocarbon chains) -make up bilayer cell membranes Amy Warenda Czura, Ph.D. 19 SCCC BIO244 Chapter 2 Lecture Slides

C. Steroids / Sterols: carbon rings -eukaryotes and mycoplasmas in cell membranes 3. Proteins -most abundant organic molecules in cells -composed of C, H, O, N, sometimes S -essential to cell structure and function: -enzymes (all chemical reactions) -toxins -transport and movement -structure -regulation Amy Warenda Czura, Ph.D. 20 SCCC BIO244 Chapter 2 Lecture Slides

-constructed from amino acids: Amino acid structure: -central carbon -carboxyl group (COOH) -amino group (NH 2 ) -H -R group = unique side chain 20 different amino acids: vary on nature of R group Amy Warenda Czura, Ph.D. 21 SCCC BIO244 Chapter 2 Lecture Slides

Amy Warenda Czura, Ph.D. 22 SCCC BIO244 Chapter 2 Lecture Slides

-proteins formed from long strings of peptide bonded amino acids: -amino group of one bound to carboxyl group of next via dehydration synthesis (resulting bond = peptide bond) -chain of peptide bonded amino acids = polypeptide protein -proteins only work if folded correctly Levels of protein organization: 1. Primary structure = unique sequence of amino acids dictated by the DNA, linear order of amino acids Amy Warenda Czura, Ph.D. 23 SCCC BIO244 Chapter 2 Lecture Slides

2. Secondary structure = local twisting and folding of polypeptide due to H-bonds, creates α-helices and β-pleated sheets 3. Tertiary structure = global folding due to chemical interactions between R-groups (H-bonds, ionic bonds, disulfide links, hydrophobic interactions, etc.) If a protein consists of a single polypeptide it will be complete at this stage. If it requires multiple polypeptides ---> Amy Warenda Czura, Ph.D. 24 SCCC BIO244 Chapter 2 Lecture Slides

4. Quaternary structure = aggregation of 2 or more polypeptide chains Denaturation = loss of protein shape due to unfavorable temp, ph, salinity, etc. Loss of native conformation, protein no longer functional Amy Warenda Czura, Ph.D. 25 SCCC BIO244 Chapter 2 Lecture Slides

Conjugated proteins = combinations of amino acids with other components (organic or inorganic) e.g. glycoprotein: protein with a carbohydrate attached 4. Nucleic Acids -2 types : deoxyribonucleic acid (DNA) ribonucleic acid (RNA) -composed of nucleotides, each has 3 parts: -nitrogen containing base -pentose sugar (ribose or deoxyribose) -phosphate group -nucleotides are linked together: sugar of one to phosphate of next creating a linear backbone with the bases hanging off the side Amy Warenda Czura, Ph.D. 26 SCCC BIO244 Chapter 2 Lecture Slides

Nitrogenous bases: Purines: Adenine (A) Guanine (G) Pyrimidines: Cytosine (C) Thymine (T) Uracil (U) DNA -double helix: 2 strands intertwined -backbone = alternating dexoyribose sugar and phosphate -held together by H-bonds between bases: A to T (two H-bonds) G to C (three H-bonds) (no U) Amy Warenda Czura, Ph.D. 27 SCCC BIO244 Chapter 2 Lecture Slides

-DNA contains genes -genes = specific order of bases on a strand of DNA that encodes RNA which usually encodes a protein Amy Warenda Czura, Ph.D. 28 SCCC BIO244 Chapter 2 Lecture Slides

RNA -single stranded linear molecule -backbone = ribose & phosphate -bases = A, U, G, C (no T) -3 types: 1. mrna = template for a protein 2. rrna = forms ribosomes: factory for protein synthesis 3. trna = carrier to bring amino acids to the ribosome High Energy Molecules -ATP = adenosine triphosphate: adenine + ribose + 3 phosphate groups Amy Warenda Czura, Ph.D. 29 SCCC BIO244 Chapter 2 Lecture Slides

-hydrolysis of 3rd phosphate bond releases energy for use by cell ATP ADP + P + free energy -when cell has extra energy, phosphate is bonded to ADP to store energy as ATP Amy Warenda Czura, Ph.D. 30 SCCC BIO244 Chapter 2 Lecture Slides