All cells within an organism contain the same set of genetic instructions called the genome. What drives the unique characteristics of different cells, is reading only certain sections of these instructions. The areas of the genome which are needed are silenced in the differentiation process.

Single-celled organisms perform all of their basic functions within a single cell. For maximum efficiency in each process, a unique cellular structure and machinery are needed. No one cell can provide optimal circumstances for all functions.

In single-celled organisms, the relatively inefficient operations performed by a single cell may be adequate, but this falls short in multicellular organisms. Each cell in a multicellular organism, from a mushroom to a human being, becomes specialised in several ways to fulfill a specific role. And the adaptations these acquire guarantee that they are as effective as possible in performing their functions.

Fig. 1 - Stem cells differentiate into specialized cells that perform specific roles.

Cell Differentiation and Specialisation

Cell specialisation is the process by which cells differentiate and specialise in performing their role in a tissue, organ, and, eventually, the body. Specialised cells have distinct shapes and subcellular structures that aid in their roles.

Specialisation is an essential process in the growth and maturation of embryos. During the early stages of development, the zygote goes through several mitotic divisions, resulting in a group of cells commonly referred to as embryonic stem cells. These stem cells mature and differentiate, turning into specialised cells.

The Process of Cell Differentiation

Stem cells and specialised cells have identical genetic content. While stem cells retain the ability to express every one of their genes, specialised cells lose this ability. They can only express genes that are essential for viability and function.

Regulation of gene expression drives cell differentiation. When cells express certain genes that define a specific type of cell, we say the cell has differentiated. Once a cell has differentiated, it only expresses the genes that code for the proteins that are unique to that kind of cell. Factors involved in transcription and translation determine which genes remain active and which are silenced.

The Difference Between Cell Differentiation and Cell Division

Cell differentiation is the process through which cells specialise to perform their roles. A cell will express particular genes to differentiate. Once a cell is determined and has become specialised, it loses the ability to divide via mitosis. New cells generated by mitosis of stem cells may transform into specialised cells.

Living organisms are constantly in need of developing new cells to replace old, damaged, or dead cells.

Examples of Cell Differentiation

There are many different cells within the body which can be used as examples for cell differentiation. Below are some, in both animals and plants, that we will take a closer look at.

Red Blood Cells

Muscle Cells

Muscles are essential tissues in animals that enable movement. Three main types of muscles are found: cardiac, skeletal, and smooth.

• Cardiac muscle cells are located in the heart and, by autonomous contracting, pump blood around the body.

• Skeletal muscles are attached to bones via tendons and move the limbs and other skeletal structures under voluntary control.

• Smooth muscles line the walls of blood vessels and the gastrointestinal (GI) tract and contract under the autonomous nervous system to regulate blood pressure and the flow of food in the GI tract.

Cells from these three types of muscles share several adaptions for their roles. These are:

1. The ability to contract and forcefully shorten. This contracting ability is enabled by the protein filaments called actin and myosin that slide over each other, contracting the cell.

2. Responding to signals from the nervous system and neurons.

3. Extensibility, which is the ability to stretch or extend.

4. The elastic ability to return to its resting length following extension or contraction.

5. Containing a large number of mitochondria, the cell's powerhouse, to provide the energy needed for contraction.

Root Hair Cells

Root hair cells, located in plant roots, are special cells that absorb water and minerals from the soil. They possess large numbers of mitochondria and many cellular extensions that give them a large surface area. These adaptations enable root hair cells to absorb nutrients efficiently, even against their concentration gradient.

Fig. 2 - Root hair cells have long extensions and many mitochondria. These adaptations enable these cells to efficiently absorb water and minerals from the soil.

Xylem and Phloem Cells

Xylem cells are specialised dead cells in plants that transport water up from the roots through the stem and deliver it to the leaves. These cells are hollow and have an elongated shape, forming tubes called xylem. Their lack of organelles or cytoplasm allows water to flow through them freely.

In contrast to xylem cells, phloem cells are living cells that transport the sugars made in photosynthesis from the leaves to all parts of the plant. Phloem cells consist of connecting sieve cells stacked on top of each other. These sieve cells share a highly perforated sieve plate to aid the movement of material from cell to cell. These living cells have limited cytoplasm and no nucleus to maximise their transporting ability.

Fig. 3 - Xylem and phloem cells are specialized transporting cells in plants. Dead xylem cells transport water up from the root, while phloem cells move sugars from leaves to all parts of the plant.