Molecules of Life – Biomolecules
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Transcript of Molecules of Life – Biomolecules
Molecules of Life – Biomolecules
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What Do These Pictures Have in Common?
gov.mb.ca
k8science.org
gsbs.utmb.edunuclearfamilywarhead.com
Brain Tissue
learn.genetics.utah.edu
Protein Structure –
the correct protein
structure is important for
normal function
new-science-press.com
Prions
stanford.edu
Dr. Stanley Prusiner.cmu.edu
Why Is Carbon So Important?Organic/Inorganic Molecules
• Organic vs. Inorganic in Chemistry– Organic refers to molecules containing a
carbon skeleton– Inorganic refers to carbon dioxide and all
molecules without carbon
Carbon’s Versatility
• Carbon atoms are versatile and can form up to four bonds (single, double, or triple) and rings
• Functional Groups in organic molecules confer chemical reactivity and other characteristics– Determines how that molecule will function
(For ex. whether it is polar [charged] or nonpolar [uncharged])
Common Elements Found in Living Organisms
• Carbon (C)• Hydrogen (H)• Nitrogen (N)• Oxygen (O)• Phosphorous (P)
Organic Molecule Synthesis
• Biomolecules are polymers (chains) of subunits called monomers
Dehydration Synthesis
• Monomers are joined together through dehydration synthesis– An H and an OH are removed, resulting in the
loss of a water molecule (H2O)
Hyrolysis
• Polymers are broken apart through hydrolysis (“water cutting”)– Water is broken into H and OH and used to
break the bond between monomers
Biological Molecules
• All biological molecules fall into one of four categories– Carbohydrates– Lipids– Proteins– Nucleic Acids
1. Carbohydrates
• Carbohydrate composition– Made of C, H, and O in the ratio of 1:2:1
• Construction– Simple or single sugars are
monosaccharides– Two linked monosaccharides are
disaccharides– Long chains of monosaccharides are
polysaccharides
Carbohydrates
• Carbohydrates are important energy sources for most organisms
Monosaccharides
• Basic monosaccharide structure– Backbone of 3-7 carbon atoms– Many –OH and –H functional groups– Usually found in a ring form in cells
• Example monosaccharides– Glucose (C6H12O6): the most common
Monosaccharides
• Fate of monosaccharides inside a cell– Some broken down to free their chemical
energy– Some are linked together by dehydration
synthesis for storage
Disaccharides
• Disaccharides are two-part sugars– Sucrose (table sugar) = glucose + fructose– Lactose (milk sugar) = glucose + galactose– Maltose (malt sugar)= glucose + glucose
Polysaccharides Used For Energy Storage
• Monosaccharides are linked together to form chains (polysaccharides)
• Storage polysaccharides– Starch (polymer of glucose)
• Formed in roots and seeds as a form of glucose storage
– Glycogen (polymer of glucose)• Found in liver and muscles
Polysaccharides Used For Structural Support
• Structural polysaccharides– Cellulose (polymer of glucose)– Found in the cell walls of plants
• Indigestible for most animals due to orientation of bonds between glucoses
nsf.gov
Polysaccharides Used For Structural Support
• Structural polysaccharides continued– Chitin (polymer of modified glucose units)
• Found in the outer coverings of insects, crabs, and spiders
• Found in the cell walls of many fungi
2. Lipids
• All lipids contain large chains of nonpolar hydrocarbons (a chain of carbon atoms w/hydrogen atoms attached)
• Most lipids are hydrophobic (don’t like water) and water insoluble (don’t dissolve in water)
• Lipids are diverse in structure and serve in a variety of functions– Energy storage– Waterproofing– Membranes in cells– Hormones
3 Groups of Lipids• 1. Oils, fats, and waxes• 2. Phospholipids• 3. Steroids
Oils, Fats, and Waxes
• Made of only C, H, and O
• Made of one or more fatty acid subunits– Long chains of C and H with a carboxylic acid
group (-COOH) at one end
• Fats and oils – Formed by dehydration synthesis
Oils and Fats
• Fats and oils used for long-term energy storage– Fats and oils possess a high density of stored
chemical energy
Oils and Fats
• Fat solidity is due to single or double carbon bonds– Fats that are solid at room temperature are
saturated (carbon chain has as many hydrogen atoms as possible, and mostly or all C-C single bonds), e.g. beef fat
Oils and Fats• Fat solidity is due to single or double carbon
bonds (continued)– Fats that are liquid at room temperature are
unsaturated (fewer hydrogen atoms, many C=C double bonds), e.g. corn oil
Waxes
• Composed of long hydrocarbon chains and are strongly hydrophobic
• Highly saturated and solid at room temperature
• Form waterproof coatings
• Used to build honeycomb structures
Phospholipids• Form plasma membranes around all cells • Phospholipids have hydrophobic and
hydrophilic portions– Polar functional groups are water soluble– Nonpolar fatty acid “tails” are water insoluble
Steroids
• Steroids are composed of four carbon rings fused together
• Examples of steroids– Cholesterol
• Found in membranes of animal cells– Male and female sex hormones
3. Proteins
• Proteins have a variety of functions– Enzymes catalyze (speed up) reactions– Structural proteins (e.g. collagen) provide
support
Amino Acids
• Proteins are formed from chains of amino acids (monomers)
– There are 20 amino acids that make up proteins of living things.
Amino Acids
• All amino acids have similar structure– Central carbon atom bonded to four different
functional groups• 1. An amino group (-NH2) • 2. A carboxylic acid group (-COOH)• 3. A hydrogen (H)• 4. All have a variable “R” group
– Some R groups are hydrophobic– Some are hydrophilic– Cysteine R groups can form disulfide bridges
Amino Acids
• The sequence of amino acids in a protein dictates its function
Dehydration Synthesis
• Amino acids are joined to form chains by dehydration synthesis– An amino group reacts with a carboxyl group,
and water is lost
Dehydration Synthesis
• Resultant covalent bond is a peptide bond
• A chain of two amino acids or a short amino acid chain is called a peptide
• Long chains of amino acids are known as polypeptides or just proteins
Three Dimensional Structures
• The type, position, and number of amino acids determine the structure and function of a protein
– Precise positioning of amino acid R groups leads to bonds that determine structure
– Disruption of these bonds leads to denatured proteins and loss of function• For ex. If you expose a protein to high temperatures,
it will cause the protein to unfold, in other words, to denature.
4.Nucleic Acids
• Nucleotides are the monomers of nucleic acid chains
• All nucleotides are made of three parts– Phosphate group – Five-carbon sugar– Nitrogen-containing base
Molecules of Heredity• Two types of nucleotides
– Ribonucleotides (A, G, C, and U) found in RNA• A = adenine• G = guanine• C = cytosine• U = uracil
– Deoxyribonucleotides (A, G, C, and T) found in DNA• A = adenine• G = guanine• C = cytosine• T = thymine
Molecules of Heredity
• Two types of polymers (chains) of nucleic acids
– DNA (deoxyribonucleic acid) found in chromosomes • Carries genetic information needed for protein
construction
– RNA (ribonucleic acid) • Copies of DNA used directly in protein construction
One nucleotide
Molecules of Heredity
• Each DNA molecule consists of two chains of nucleotides that form a double helix
• The nucleotides on opposing strands form hydrogen bonds, linking the two strands
• RNA is copied from DNA in the nucleus– That information is used to synthesize proteins
in the cell’s cytoplasm
The End