Organic Molecules

Organic Molecules Biology

Living matter is made up largely of organic molecules in biology.

Recall that a covalent bond is a Linkage formed between two atoms sharing a pair of valence electrons (or four electrons in its outermost shell).

Organic Molecules Structure

The structure of the carbon skeleton of organic molecules can be ring-shaped, branched, or straight. Organic molecules consist of chains of carbon atoms of various lengths, with many being relatively long, allowing for a large number and variety of compounds.

Organic molecules contain

Organic molecules are made up of carbon and hydrogen atoms, and they might sometimes contain nitrogen (N), oxygen (O), phosphorus (P), and sulfur (S) atoms.

However, keep in mind that while all organic molecules contain carbon, not all molecules containing carbon are organic. For a carbon-containing molecule to be considered organic, its carbon atom must be reduced and not fully oxidized.

• An atom such as carbon or oxygen is said to be reduced if they form covalent bonds with another atom with lower electronegativity.

• An atom is said to be oxidized when it forms a covalent bond with an atom with higher electronegativity.

When an atom is reduced, it gains a majority of the electrons that form the covalent bond, while the oxidized atom gains only a small portion of the electrons.

Functional Groups

In addition to carbon, organic molecules may also contain functional groups. Let's look at its definition.

So, when present in a molecule, a functional group will exhibit its unique chemical behavior! Functional groups have specific names typically incorporated into the names of the compounds that include them.

Notice how formulas contain the symbol R. R stands for "residue," and it represents the other parts of the molecule. In other words, R can represent a single hydrogen atom or many atoms!

Also, notice that some functional groups are made up of just one or two atoms, while others are made up of these simpler functional groups.

Organic Molecules Formula

Organic molecules can be represented through a molecular formula, which indicates what elements and how many atoms of each element are present in a compound.

Molecules can also be represented by their structural formula, which is a graphic illustration of the arrangement of the atoms within the molecule.

There are different types of formulas that chemists can use to show the structure of an organic molecule. Here, we will look at four of them:

• The Lewis structure formula

• The condensed formula

• The bond-line formula

• The dashed-wedged formula

The Lewis structure is a diagram showing how a molecule's atoms are bonded together. In a Lewis structure, valence electrons are represented as dots, while bonds are represented by two dots between bonded atoms or a line. Double bonds are represented by two lines, while triple bonds are represented by three.

A condensed formula consists of elemental symbols, with the order of each element suggesting how they are connected. On the other hand, bond-line formulas consist of bonds and lines, with carbon atoms no longer drawn in and are instead indicated using the ends and bends of the lines.

The Dashed-Wedged line structure is similar to the bond-Line formula, except that the structure of the atoms is also illustrated: dashed lines show atoms and bonds facing away from the viewer, while wedged lines represent bonds and atoms facing the viewer.

Concept of Isomerism in Organic Molecules

It is important for the structure of organic molecules to be adequately represented because different compounds can have the same molecular formula.

Substances with identical molecular formulas but different atom bonding arrangements are called isomers. Chemistry places a great deal of emphasis on the concept of isomerism because the structure of organic molecules structures are often closely linked to their functions.

Large Organic Molecules Examples

Lastly, let's look at some examples of large organic molecules. The four major types of organic molecules that make up Cells and cell structures are:

1. Carbohydrates

2. Proteins

3. Nucleic Acids

4. Lipids

Carbohydrates, Proteins, and Nucleic Acids are polymers, or large complex molecules made up of smaller, identical repeating units called Monomers. These Monomers are typically linked together through dehydration synthesis, a chemical reaction in which monomers bind end to end, resulting in the formation of Water Molecules as a byproduct.

On the other hand, polymers can be broken down into monomers through hydrolysis, where water is split into -OH and H.

Carbohydrates

You've probably encountered the term carbohydrates in the context of food.

Monosaccharides are molecules with the composition [CH₂O]_n, where n is usually 3-6. For example, glucose is a 6-carbon sugar whose chemical formula is C₆H₁₂O₆. Monosaccharides are linked together via glycosidic bonds to form Polysaccharides.

Carbohydrates play an important role in energy storage and structural support in Cells.

Proteins

You've probably also encountered the term protein before, but in biology, it's much more than the stuff bodybuilders use to increase muscle mass!

An amino acid contains an amino group (-NH₂), a carboxyl group (-COOH), and a side chain (called the R group). The amino and carboxyl groups are joined to the central carbon atom of each amino acid molecule. There are 20 different amino acids, each containing a different R group.

Proteins play an essential role in enzymatic activities, cell signaling, and providing structural components that help bind cells into tissues.

Nucleic acids

Next, we have nucleic acids.

Nucleotide monomers are made up of a 5-carbon sugar, a phosphate group, and a nitrogenous base.

Lipids

Lastly, let's look at the definition of Lipids.

Phospholipids, which make up the cell membrane, are an example of lipids. The phospholipid bilayer creates a hydrophobic environment that separates the cytosol's internal aqueous environment from the exterior of the cell. Fats and oils which serve as energy storage are also examples of lipids.