Summary of Biochemical Tests for Pathogen Diagnosis

## Introduction Biomolecules are the chemical building blocks of life. Carbohydrates, proteins, and nucleic acids perform structural, catalytic, informational, and energy-storage roles in cells. Polymer chemistry describes how living systems assemble and disassemble large molecules from smaller repeating units. This material explains the core concepts a student needs to understand biomolecules and polymer formation and breakdown. ## Key concepts at a glance - **Monomers** are single, small units that can join to form larger molecules. - **Polymers** are chains or networks of repeating monomers. - **Functional groups** are specific groupings of atoms attached to a carbon backbone that determine chemical behavior. - Cells assemble polymers by **dehydration synthesis** and break them down by **hydrolysis**. ## Functional groups: what makes organic molecules unique > **Definition:** Functional groups are specific atoms or clusters of atoms attached to a carbon skeleton that impart characteristic chemical properties to the molecule. Common functional groups to remember: - Hydroxyl (–OH) - Carbonyl (C=O) - Carboxyl (–COOH) - Amino (–NH2) - Phosphate (–PO4) - Sulfhydryl (–SH) Practical example: The difference between ethanol and ethanoic acid is the functional group: ethanol has a hydroxyl group (–OH) while ethanoic acid has a carboxyl group (–COOH), which makes it acidic. ## Monomers and polymers: building blocks and assemblies > **Definition:** A monomer is a single small molecule that can be covalently linked to other monomers to form a polymer. A polymer is a larger molecule composed of many repeating monomer units. - Carbohydrate monomers: **monosaccharides** (e.g., glucose, fructose) - Protein monomers: **amino acids** (20 common types in proteins) - Nucleic acid monomers: **nucleotides** (base + sugar + phosphate) Table: Monomers vs Polymers | Biomolecule type | Monomer | Typical polymer | Main roles | |---|---:|---|---| | Carbohydrate | monosaccharide (glucose) | polysaccharide (starch, glycogen, cellulose) | energy storage, structure | | Protein | amino acid | polypeptide / protein | enzymes, structure, transport, signaling | | Nucleic acid | nucleotide | DNA, RNA | genetic information storage and transfer | Did you know that glucose, fructose, and galactose all have the same chemical formula but different structures and properties? ## Making and breaking polymers > **Definition:** Dehydration synthesis (condensation) joins monomers by removing water; hydrolysis breaks polymers by adding water. 1. Dehydration synthesis: - Two monomers join and release one molecule of water. - Example: Two glucose molecules form maltose + water. - Biological role: Polymer formation during biosynthesis (e.g., forming proteins, polysaccharides). 2. Hydrolysis: - A water molecule is used to cleave the bond between monomers. - Example: Digestive enzymes break starch into glucose units by hydrolysis. - Biological role: Recycling of biomolecules and release of energy. Simple schematic (words): Monomer + Monomer --(dehydration synthesis)--> Polymer + H2O. Polymer + H2O --(hydrolysis)--> Monomer + Monomer. Fun fact: Enzymes speed up both dehydration synthesis and hydrolysis in cells so metabolism can proceed efficiently. ## Proteins: sequence, structure, function > **Definition:** Proteins are polymers of amino acids linked by peptide bonds; their sequence determines three-dimensional structure and function. - Levels of structure: 1. Primary: amino acid sequence 2. Secondary: local folding such as alpha helix and beta sheet (stabilized by hydrogen bonds) 3. Tertiary: overall 3D fold (hydrophobic interactions, ionic bonds, disulfide bridges) 4. Quaternary: assembly of multiple polypeptide subunits Practical example: Hemoglobin has a quaternary structure of four subunits that cooperatively transport oxygen. ## Carbohydrates: forms and functions - Monosaccharides: single sugars (e.g., glucose) - Disaccharides: