Cell - Definition, Functions, Types and Examples | Biology Dictionary (2024)

Cell Definition

Cells are the basic unit of life. In the modern world, they are the smallest known world that performs all of life’s functions. All living organisms are either single cells, or are multicellular organisms composed of many cells working together.

Cells are the smallest known unit that can accomplish all of these functions. Defining characteristics that allow a cell to perform these functions include:

  • A cell membrane that keeps the chemical reactions of life together.
  • At least one chromosome, composed of genetic material that contain the cell’s “blueprints” and “software.”
  • Cytoplasm – the fluid inside the cell, in which the chemical processes of life occur.

Below we will discuss the functions that cells must fulfill in order to facilitate life, and how they fulfill these functions.

Function of Cells

Scientists define seven functions that must be fulfilled by a living organism. These are:

  1. A living thing must respond to changes in its environment.
  2. A living thing must grow and develop across its lifespan.
  3. A living thing must be able to reproduce, or make copies of itself.
  4. A living thing must have metabolism.
  5. A living thing must maintain homeostasis, or keep its internal environment the same regardless of outside changes.
  6. A living thing must be made of cells.
  7. A living thing must pass on traits to its offspring.

It is the biology of cells which enables living things to perform all of these functions. Below, we discuss how they make the functions of life possible.

How Cells Work

In order to accomplish them, they must have:

  • A cell membrane that separates the inside of the cell from the outside. By concentrating the chemical reactions of life inside a small area within a membrane, cells allow the reactions of life to proceed much faster than they otherwise would.
  • Genetic material which is capable of passing on traits to the cell’s offspring. In order to reproduce, organisms must ensure that their offspring have all the information that they need to be able to carry out all the functions of life.All modern cells accomplish this using DNA, whose base-pairing properties allow cells to make accurate copies of a cell’s “blueprints” and “operating system.” Some scientists think that the first cells might have used RNA instead.
  • Proteins that perform a wide variety of structural, metabolic, and reproductive functions.
    There are countless different functions that cells must perform to obtain energy and reproduce.
    Depending on the cell, examples of these functions can include photosynthesis, breaking down sugar, locomotion, copying its own DNA, allowing certain substances to pass through the cell membrane while keeping others out, etc.
    Proteins are made of amino acids, which are like the “Legos” of biochemistry. Amino acids come in different sizes, different shapes, and with different properties such as polarity, ionic charge, and hydrophobicity.
    By putting amino acids together based on the instructions in their genetic material, cells can create biochemical machinery to perform almost any function.
    Some scientists think that the first cells might have used RNA to accomplish some vital functions, and then moved to much more versatile amino acids to do the job as the result of a mutation.

The different cell types we will discuss below have different ways of accomplishing these functions.

Cell Types

Because of the millions of diverse species of life on Earth, which grow and change gradually over time, there are countless differences between the countless extant types of cells.

However, here we will look at the two major types of cells, and two important sub-categories of each.

Prokaryotes

Prokaryotes are the simpler and older of the two major types of cells. Prokaryotes are single-celled organisms. Bacteria and archaebacteria are examples of prokaryotic cells.

Prokaryotic cells have a cell membrane, and one or more layers of additional protection from the outside environment. Many prokaryotes have a cell membrane made of phospholipids, enclosed by a cell wall made of a rigid sugar. The cell wall may be enclosed by another thick “capsule” made of sugars.

Many prokaryotic cells also have cilia, tails, or other ways in which the cell can control its movement.

These characteristics, as well as the cell wall and capsule, reflect the fact that prokaryotic cells are going it alone in the environment. They are not part of a multicellular organism, which might have whole layers of cells devoted to protecting other cells from the environment, or to creating motion.

Prokaryotic cells have a single chromosome which contains all of the cell’s essential hereditary material and operating instructions. This single chromosome is usually round. There is no nucleus, or any other internal membranes or organelles. The chromosome just floats in the cell’s cytoplasm.

Additional genetic traits and information might be contained in other gene units within the cytoplasm, called “plasmids,” but these are usually genes that are passed back and forth by prokaryotes though the process of “horizontal gene transfer,” which is when one cell gives genetic material to another. Plasmids contain non-essential DNA that the cell can live without, and which is not necessarily passed on to offspring.

When a prokaryotic cell is ready to reproduce, it makes a copy of its single chromosome. Then the cell splits in half, apportioning one copy of its chromosome and a random assortment of plasmids to each daughter cell.

There are two major types of prokaryotes known to scientists to date: archaebacteria, which are a very old lineage of life with some biochemical differences from bacteria and eukaryotes, and bacteria, sometimes called “eubacteria,” or “true bacteria” to differentiate them from archaebacteria.

Bacteria are thought to be more “modern” descendants of archaebacteria.

Both families have “bacteria” in the name because the differences between them were not understood prior to the invention of modern biochemical and genetic analysis techniques.

When scientists began to examine the biochemistry and genetics of prokaryotes in detail, they discovered these two very different groups, who probably have different relationships to eukaryotes and different evolutionary histories!

Some scientists think that eukaryotes like humans are more closely related to bacteria, since eukaryotes have similar cell membrane chemistry to bacteria. Others think that archaebacteria are more closely related to us eukaryotes, since they use similar proteins to reproduce their chromosomes.

Still others think that we might be descended from both – that eukaryotic cells might have come into existence when archaebacteria started living inside of a bacterial cell, or vice versa! This would explain how we have important genetic and chemical attributes of both, and why we have multiple internal compartments such as the nucleus, chloroplasts, and mitochondria!

Eukaryotes

Eukaryotic cells are thought to be the most modern major cell type. All multicellular organisms, including you, your cat, and your houseplants, are eukaryotes. Eukaryotic cells seem to have “learned” to work together to create multicellular organisms, while prokaryotes seem unable to do this.

Eukaryotic cells usually have more than one chromosome, which contains large amounts of genetic information. Within the body of a multicellular organism, different genes within these chromosomes may be switched “on” and “off,” allowing for cells that have different traits and perform different functions within the same organism.

Eukaryotic cells also have one or more internal membranes, which has led scientists to the conclusion that eukaryotic cells likely evolved when one or more types of prokaryote began living in symbiotic relationships inside of other cells.

Organelles with interior membranes found in eukaryotic cells typically include:

  • For animal cells – Mitochondria, which liberate the energy from sugar and turn it into ATP in an extremely efficient way.
    Mitochondria even have their own DNA, separate from the cells’ nuclear DNA, which gives further support for the theory that they used to be independent bacteria.
  • For plant cells – Chloroplasts, which perform photosynthesis, making ATP and sugar from sunlight and air.
    Chloroplasts also have their own DNA, suggesting that they may have originated as photosynthetic bacteria.
  • Nucleus – In eukaryotic cells, the nucleus contains the essential DNA blueprints and operating instructions for the cell.
    The nuclear envelope is thought to provide an extra layer of protection for the DNA against toxins or invaders which might damage it.
    It is unknown whether the nucleus might also have been an endosymbiotic prokaryote at one time, or whether its membrane simply evolved as an extra layer of protection for the cell’s DNA.
  • Endoplasmic reticulum – This complex internal membrane is a major site of protein creation for cells. The evolutionary origin of the endoplasmic reticulum is not known.
  • Golgi apparatus – This internal membrane complex can be thought of like the endoplasmic reticulum’s “post office.” It receives proteins from the ER, packages and “labels” them by attaching sugars as needed, and then ships them off to their final destinations!
  • Others – Many eukaryotic cells can create temporary internal membrane “sacs,” called “vacuoles,” to store waste, or to package important materials.
    Some cells, for example have special vacuoles called “lysosomes” which are full of corrosive substances and digestive enzymes. Cells simply dump their “trash” into lysosomes, where the harsh environment breaks them down into simpler components that can be re-used!

Examples of Cells

Archaebacteria

As mentioned above, archaebacteria are a very old form of prokaryotic cells. Biologists actually put them in their own “domain” of life, separate from other bacteria.

Key ways in which archaebacteria differ from other bacteria include:

  • Their cell membranes, which are made of a type of lipid not found in either bacteria or eukaryotic cell membranes.
  • Their DNA replication enzymes, which are more similar to those of eukaryotes than those of bacteria, suggesting that bacteria and archae are only distantly related, and archaebacteria may actually be more closely related to us than to modern bacteria.
  • Some archaebacteria have the ability to produce methane, which is a metabolic process not found in any bacteria or any eukaryotes.

Archaebacteria’s unique chemical attributes allow them to live in extreme environments, such as superheated water, extremely salty water, and some environments which are toxic to all other life forms.

Scientists became very excited in recent years at the discovery of Lokiarchaeota – a type of archaebacteria which shares many genes with eukaryotes that had never before been found in prokaryotic cells!

It is now thought that Lokiarchaeota may be our closest living relative in the prokaryotic world.

Bacteria

You are most likely familiar with the type of bacteria that can make you sick. Indeed, common pathogens like Streptococcus and Staphylococcus are prokaryotic bacterial cells.

But there are also many types of helpful bacteria – including those that break down dead waste to turn useless materials into fertile soil, and bacteria that live in our own digestive tract and help us digest food.

Bacterial cells can commonly be found living in symbiotic relationships with multicellular organisms like ourselves, in the soil, and anywhere else that’s not too extreme for them to live!

Plant Cells

Plant cells are eukaryotic cells that are part of multicellular, photosynthetic organisms.

Plants cells have chloroplast organelles, which contain pigments that absorb photons of light and harvest the energy of those photons.

Chloroplasts have the remarkable ability to turn light energy into cellular fuel, and use this energy to take carbon dioxide from the air and turn it into sugars that can be used by living things as fuel or building material.

In addition to having chloroplasts, plant cells also typically have a cell wall made of a rigid sugars, to enable plant tissues to maintain their upright structures such as leaves, stems, and tree trunks.

Plant cells also have the usual eukaryotic organelles including a nucleus, endoplasmic reticulum, and Golgi apparatus.

Animal Cells

For this exercise, let’s look at a type of animal cell that is of great importance to you: your own liver cell.

Like all animal cells, it has mitochondria which perform cellular respiration, turning oxygen and sugar into large amounts of ATP to power cellular functions.

It also has the same organelles as most animal cells: a nucleus, endoplasmic reticulum, Golgi apparatus, etc..

But as part of a multicellular organism, your liver cell also expresses unique genes, which give it unique traits and abilities.

Liver cells in particular contain enzymes that break down many toxins, which is what allows the liver to purify your blood and break down dangerous bodily waste.

The liver cell is an excellent example of how multicellular organisms can be more efficient by having different cell types work together.

Your body could not survive without liver cells to break down certain toxins and waste products, but the liver cell itself could not survive without nerve and muscle cells that help you find food, and a digestive tract to break down that food into easily digestible sugars.

And all of these cell types contain the information to make all the other cell types! It’s simply a matter of which genes are switched “on” or “off” during development.

  • Epigenetics – The process by which genes are turned “on” or “off” by adding or removing chemical groups from parts of the chromosome.
  • Eukaryotes – Complex cells with multiple chromosomes and internal organelles such as mitochondria, chloroplasts, and nuclei.
  • Prokaryote – Single-celled organisms with a simple structure, typically having one chromosome and no internal organelles.

Quiz

1. Which of the following is NOT an essential function that all living things must perform?
A. A living thing must reproduce.
B. A living thing must be able to maintain its internal environment, regardless of external changes.
C. A living thing must respond to changes in its environment.
D. None of the above.

Answer to Question #1

D is correct. All of the above are essential functions of life!

2. Which of the following is NOT a type of prokaryotic cell?
A. Archaebacteria
B. Staphylococcus bacteria
C. Streptococcus bacteria
D. Liver cell

Answer to Question #2

D is correct. Liver cells are eukaryotic cells, like all cells from multicellular organisms!

3. Which of the following is NOT a eukaryotic cell organelle?
A. Plasmid
B. Nucleus
C. Mitochondria
D. Chloroplast

Answer to Question #3

B is correct. Plasmids are pieces of DNA that are passed between prokaryotic cells. They are not organelles.

Cell - Definition, Functions, Types and Examples | Biology Dictionary (2024)

FAQs

Cell - Definition, Functions, Types and Examples | Biology Dictionary? ›

A biological cell is a membrane-bound structure that occurs as a functional independent unit of life (such as in unicellular organisms, e.g. bacteria, protozoa, etc.), or as the structural or fundamental unit in a biological tissue specialized to perform a particular function in multicellular organisms (e.g. plants and ...

What is the functions of a cell definition? ›

The essential functions of the cell include: The cell provides support and structure to the body. It facilitates growth by mitosis. It helps in reproduction. Provides energy and allows the transport of substances.

What are the different types of cells and definitions? ›

Cell types. Cells are broadly categorized into two types: eukaryotic cells, which possesses a nucleus, and prokaryotic cells, which lack a nucleus but still has a nucleoid region. Prokaryotes are single-celled organisms, whereas eukaryotes can be either single-celled or multicellular.

What is the definition of a cell and examples? ›

cell, in biology, the basic membrane-bound unit that contains the fundamental molecules of life and of which all living things are composed. A single cell is often a complete organism in itself, such as a bacterium or yeast. Other cells acquire specialized functions as they mature.

What are the 11 functions of a cell? ›

Cells must perform 11 main functions in order to support and maintain life: absorption, digestion, respiration, biosynthesis, excretion, egestion, secretion, movement, irritably, homeostasis, and reproduction.

What are the 8 main functions of a cell? ›

  • A cell performs various activities, which are important for the development and growth of an organism. ...
  • It facilitates growth during mitosis.
  • It provides structure and support.
  • It helps in the generation of energy.
  • It permits the transport of different substances.
  • It helps in the process of reproduction.

How many types of cells are there with examples? ›

Experts estimate that there are around 200 cell types in the human body. Cell types can look different, and carry out distinct roles within the body. For instance, a sperm cell resembles a tadpole, a female egg cell is spherical, and nerve cells are essentially thin tubes.

How do different types of cells have different functions? ›

Cells of various types have different functions because cell structure and function are closely related. It is apparent that a cell that is very thin is not well suited for a protective function. Bone cells do not have an appropriate structure for nerve impulse conduction.

What are the parts of the cell definition? ›

A cell consists of three parts: the cell membrane, the nucleus, and, between the two, the cytoplasm. Within the cytoplasm lie intricate arrangements of fine fibers and hundreds or even thousands of miniscule but distinct structures called organelles.

What are the 4 types of cells and their functions? ›

The Four Main Types of Cells
  • Epithelial Cells. These cells are tightly attached to one another. ...
  • Nerve Cells. These cells are specialized for communication. ...
  • Muscle Cells. These cells are specialized for contraction. ...
  • Connective Tissue Cells.

What is the best cell definition? ›

a cell whose metabolism is used by a virus for growth and reproduction or into which a plasmid is introduced in recombinant DNA experiments; in bioprocessing, the cells engineered and cultured to express a protein of interest are the expression system host cells.

What is the defining definition of a cell? ›

Cells are the basic structures of all living organisms. Cells provide structure for the body, take in nutrients from food and carry out important functions. Cells group together to form tissues, which in turn group together to form organs, such as the heart and brain.

What are 5 life functions of cells? ›

All organisms can perform the five basic life functions: use energy, grow and develop, dispose of waste, respond to the environment, and reproduce.

What are the 5 functions common to all cells? ›

Although there are many specific "jobs" that certain cells are able to do, name five functions common to all cells. Reproduction, Metabolism, Excretion, Growth, Respond to Stimuli.

What are the main parts and functions of a cell? ›

A cell consists of three parts: the cell membrane, the nucleus, and, between the two, the cytoplasm. Within the cytoplasm lie intricate arrangements of fine fibers and hundreds or even thousands of miniscule but distinct structures called organelles.

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