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A review of the structure and function of a living cell: Computer scientists and Biologists collaborated, using the latest scientific data, to put together a movie of the inside of a living cell: http://www.studiodaily.com/main/technique/tprojects/6850.html OK, now that we know the structures and functions inside different types of cells, now we need to know: What makes up those cellular structures?? Carbohydrates, lipids, proteins, and nucleic acids… all surrounded by water! Before we can understand how these molecules work together to build a cell, we need to understand some basic chemistry… Chapter 2 Essential Chemistry for Biology The Flow of Matter… Wait a minute, WHAT is MATTER? – Matter is anything that occupies space and has mass. – Matter is found on the Earth in three physical states: •Solid •Liquid •Gas – Matter is composed of chemical elements. • There are 92 naturally occurring elements on Earth. – All the elements are listed in the periodic table. Twenty-five elements are essential to life • Four of these make up about 96% of the weight of the human body. • Trace elements occur in smaller amounts. Check out: http://www.chem4kids.com/files/atom_intro.html Each Element consists of one type of Atom – Atoms are composed of subatomic particles. • A proton is positively charged. • An electron is negatively charged. • A neutron is electrically neutral. Example: a helium atom Electron Arrangement and the Chemical Properties of Atoms – Electrons determine how an atom behaves when it encounters other atoms. Copyright © 2007 Pearson Education Inc., publishing as Pearson Benjamin Cummings –Electrons orbit the nucleus of an atom in specific electron shells. •The number of electrons in the outermost shell determines the chemical properties of an atom. Chemical Bonds – Chemical reactions enable atoms to give up or acquire electrons in order to complete their outer shells. • These interactions usually result in atoms staying close together. • The atoms are held together by chemical bonds. – Three main types of chemical bonds: • Ionic bonds • Covalent bonds • Hydrogen bonds Stronger bonds Weaker bonds Ionic Bonds – When an atom loses or gains electrons, it becomes electrically charged. • Charged atoms are called ions. • Ionic bonds are formed between oppositely charged ions. Covalent Bonds – A covalent bond forms when two atoms share one or more pairs of outer-shell electrons. What happens when the electrons in a covalent bond are shared unequally? – Water is a compound in which the electrons in its covalent bonds are shared unequally. • Oxygen is greedy for electrons and keeps their negative charge closer to itself. • This causes it to be a polar molecule, one with opposite charges on opposite ends. + - Covalent bonds where electrons are shared unequally Hydrogen Bonds – The polarity of water results in weak electrical attractions between neighboring water molecules called hydrogen bonds. Covalent bond with unequally shared electrons Chemical Reactions – Cells constantly rearrange molecules by breaking and forming chemical bonds. • These processes are called chemical reactions. – Chemical reactions cannot create or destroy matter, • They only rearrange it. Water and Life – Life on Earth began in water and evolved there for 3 billion years. • Modern life still remains tied to water. • Your cells are composed of 70%–95% water. – The abundance of water is a major reason Earth is habitable. Water’s Life-Supporting Properties – The polarity of water molecules and the hydrogen bonding that results explain most of water’s life-supporting properties: • • • • Water’s cohesive nature Water’s ability to moderate temperature Floating ice Versatility of water as a solvent The Cohesion of Water – Water molecules stick together as a result of hydrogen bonding. • This is called cohesion. • Cohesion is vital for water transport in plants. – Surface tension is the measure of how difficult it is to stretch or break the surface of a liquid. • Hydrogen bonds give water an unusually high surface tension due to cohesion. How Water Moderates Temperature – Because of hydrogen bonding, water has a strong resistance to temperature change. – Heat and temperature are related, but different. • Heat is an amount of energy. This energy causes movement of atoms and molecules. • Temperature measures this movement of the atoms and molecules. http://sv.berkeley.edu/chemicalinteractions/menu.html – Water can absorb and store large amounts of heat while only changing a few degrees in temperature. – Water can moderate temperatures. • Earth’s giant water supply causes temperatures to stay within limits that permit life. • Evaporative cooling removes heat from the Earth and from organisms. The Biological Significance of Ice Floating – When water molecules get cold, they move apart, forming ice. • A chunk of ice has fewer molecules than an equal volume of liquid water. – The density of ice is lower than liquid water. Ice Floats! – Since ice floats, ponds, lakes, and even the oceans do not freeze solid. • Marine life could not survive if bodies of water froze solid. http://majorlycool.com/category/animals/blogid/1 Water as the Solvent of Life – A solution is a liquid consisting of two or more substances evenly mixed. • The dissolving agent is called the solvent. • The dissolved substance is called the solute. An aqueous solution The slight negative charge of the oxygen in a water molecule attracts it to the positive charge of the Na+ ion. The slight positive charge of the hydrogen atoms in a water molecule attracts them to the negative charge of the Cl- ion. As the water molecules surround the ions of NaCl they become dissolved in the water! An aqueous solution A Group Challenge: • Based on the information of how NaCl becomes dissolved in water, can you figure out: – Why carbohydrates, proteins, and nucleic acids can dissolve in water? – Why lipids (fats and oils) cannot dissolve in water? Acids, Bases, and pH – Acid • A chemical compound that donates H+ ions to solutions. – Base • A compound that accepts H+ ions and removes them from solution. Chapter 3 The Molecules of Life Organic Molecules – A cell is mostly water. • The rest of the cell consists mostly of carbonbased molecules called organic molecules. Carbon Chemistry – 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. Shape defines function! – Each type of organic molecule has a unique three-dimensional shape that defines its function in an organism. • The molecules of your body recognize one another based on their shapes. Giant Molecules from Smaller Building Blocks – On a molecular scale, many of life’s molecules are gigantic. • Biologists call them macromolecules. • Examples: DNA, carbohydrates, proteins – Most macromolecules are polymers. • Polymers are made by stringing together many smaller molecules called monomers. • Cells link monomers by dehydration reactions. Monomer - means “one” unit Monomer - means “one” unit Dimer - means “two” units Monomer - means “one” unit Dimer - means “two” units Polymer - means “many” units – Organisms also have to break down macromolecules. • Cells do this by a process called hydrolysis. Monomer - means “one” unit Dimer - means “two” units Polymer - means “many” units Monomer - means “one” unit Dimer - means “two” units Monomer - means “one” unit Biological Molecules – There are four categories of large molecules in cells: • Carbohydrates • Lipids • Proteins • Nucleic acids Biological Molecules – There are four categories of large molecules in cells: • Carbohydrates • Lipids • Proteins • Nucleic acids Biological Molecules – There are four categories of large molecules in short cells: sugar molecules • Carbohydrates • Lipids • Proteins • Nucleic acids L-O-N-G starch molecules Monosaccharides short sugar molecules – Monosaccharides are simple sugars. • Glucose is found in sports drinks. • Fructose is found in fruit. Monomer - means “one” unit Monosaccharides are the main fuel that cells use to do work. Abbreviated structure OR Disaccharides – A disaccharide is a double sugar. • It is constructed from two monosaccharides. – Disaccharides are joined through a dehydration reaction. Monomer - means “one” unit Dimer - means “two” units – Lactose is another type of disaccharide. • Some people have trouble digesting lactose, a condition called lactose intolerance. – The most common disaccharide is sucrose, common table sugar. • It consists of a glucose linked to a fructose. • Sucrose is extracted from sugar cane and the roots of sugar beets. – The United States is one of the world’s leading markets for sweeteners. • The average American consumes about 64 kg of sugar per year. Polysaccharides Monomer - means “one” unit Dimer - means “two” units Polymer - means “many” units – Complex carbohydrates are called polysaccharides. • They are long chains of sugar units. • They are polymers of monosaccharides . Remember this?? An aqueous solution – Simple sugars and double sugars dissolve readily in water. • They are hydrophilic, or “water-loving.” Slight negative charge of oxygen in water and sugar molecules are attracted to Slight positive charges of hydrogen in water and sugar molecules. Abbreviated structure OR I Love You! Where are carbohydrates in a cell? In the cell wall as cellulose In the cytosol as an energy source In amyloplasts in plants as starch (organelle not shown) Biological Molecules – There are four categories of large molecules in small cells: sugar molecules • Carbohydrates • Lipids • Proteins • Nucleic acids L-O-N-G starch molecules Biological Molecules – There are four categories of large molecules in cells: –fats • Carbohydrates • Lipids –steroids • Proteins • Nucleic acids –Lipids are hydrophobic. •They do not mix with water Fats Functions: energy storage, cushioning, insulation Fats are formed by linking fatty acids onto a glycerol molecule by dehydration reactions – Dietary fat consists largely of the molecule triglyceride. Run Away! • Triglyceride is a combination of glycerol and three fatty acids. No charge! Cannot interact with water! (hydrophobic) – Unsaturated fats • Have less than the maximum number of hydrogens bonded to the carbons. (double and triple bonds) – Saturated fats • Have the maximum number of hydrogens bonded to the carbons. (all single bonds) Saturated Fatty Acids: Too much of a good thing can be bad – Most animal fats have a high proportion of saturated fatty acids, which can be unhealthy. • Example: butter – Most plant oils tend to be low in saturated fatty acids. • Example: corn oil WHY are too many saturated fats unhealthy? – Not all fats are unhealthy. • Some fats perform important functions in the body and are essential to a healthy diet. Special Lipid: Phospholipids • Phospholipids form a two-layered membrane, the phospholipid bilayer. Negative charge interacts with water! (hydrophilic) No charge! Cannot interact with water! (hydrophobic) Water! Other Lipids: Steroids – Steroids are very different from fats in structure and function. • The carbon skeleton is bent to form four fused rings. – Cholesterol is the “base steroid” from which your body produces other steroids. • Example: sex hormones Cholesterol is a key component of cellular membranes… – Synthetic anabolic steroids are controversial. • They are variants of testosterone. Where are lipids in a cell? In the smooth ER where lipids are synthesized In the all membranes as phospholipids Triglycerides (Ex: fat in animal cells, seed oils in plant cells) stored in cytoplasm (not shown) Biological Molecules – There are four categories of large molecules in cells: –fats • Carbohydrates • Lipids –steroids • Proteins • Nucleic acids –Lipids are hydrophobic. •They do not mix with water Biological Molecules – There are four categories of large molecules in cells: • Carbohydrates • Lipids • Proteins • Nucleic acids Proteins – A protein is a polymer constructed from amino acid monomers. – Proteins perform most of the tasks the body needs to function. Structural Proteins Receptor Proteins Storage Proteins Enzymes Contractile Proteins Hormonal Proteins Transport Proteins Sensory Proteins Defensive Proteins Gene Regulatory Proteins Structure of an Amino Acid Structure of an Amino Acid Run Away! I Love You! The Monomers: Amino Acids – All proteins are constructed from a common set of 20 kinds of amino acids. – Some fear water (hydrophobic) – Some love water (hydrophilic) Structure gives Function! Proteins as Polymers – Cells link amino acids together by dehydration reactions. • The resulting covalent bond between them is called a peptide bond. – Your body has tens of thousands of different kinds of protein. • The arrangement of amino acids makes each one different. Structure gives Function!! Protein Shape – Proteins have four levels of structure. • • • • Primary Secondary Tertiary Quaternary 1st level 2nd level 3rd level 4th level – Primary structure • The specific sequence of amino acids in a protein – A slight change in the primary structure of a protein affects its ability to function. • The substitution of one amino acid for another in hemoglobin causes sickle-cell disease. Protein Shape – Primary structure held together by covalent bonds – Secondary structure held together by hydrogen bonds A protein’s shape is sensitive to the surrounding environment – Unfavorable temperature and pH changes can cause a protein to unravel and lose its shape. – This happens by disrupting the hydrogen bonds that hold together the shape of a protein. – This is called denaturation. – If the shape unfolds, the function is destroyed… The Plasma Membrane: A Fluid Mosaic of Lipids and Proteins – The membranes of cells are composed mostly of: • Lipids • Proteins Copyright © 2007 Pearson Education, Inc. publishing as Pearson Benjamin Cummings – The lipids belong to a special category called phospholipids. – Phospholipids form a two-layered membrane, the phospholipid bilayer. – Most membranes have specific proteins embedded in the phospholipid bilayer. Membrane phospholipids and proteins can drift about in the plane of the membrane – This behavior leads to the description of a membrane as a fluid mosaic: • Molecules can move freely within the membrane. • A diversity of proteins exists within the membrane. Where are proteins in a cell? Everywhere!! Proteins are enzymes, and structural, transport, receptor, regulatory, contractile proteins, etc, and perform most of the functions of a cell! In the all membranes as integral membrane proteins Biological Molecules – There are four categories of large molecules in cells: • Carbohydrates • Lipids • Proteins • Nucleic acids Biological Molecules – There are four categories of large molecules in cells: • Carbohydrates DNA, deoxyribonucleic acid • Lipids • Proteins • Nucleic acids RNA, ribonucleic acid Nucleic Acids – Nucleic acids are information storage molecules. • They provide the directions for building proteins. Transcription Translation – Nucleic acids are polymers of nucleotides. I Love You! Nucleic acids are hydrophilic! – Each DNA nucleotide has one of the following bases: – Nucleotide monomers are linked into long chains. • These chains are called polynucleotides, or DNA strands. • A sugar-phosphate backbone joins them together. – Two strands of DNA join together to form a double helix. – RNA, ribonucleic acid, is different from DNA. • Its sugar has an extra OH group. • It has the base uracil (U) instead of thymine (T). Where are nucleic acids in a cell? DNA is in the nucleus, mitochondria, and chloroplasts RNA is in the nucleus, mitochondria, chloroplasts, cytosol, and ribosomes!