Gene

Genes are special pieces of material inside every living thing that help decide what that thing will be like. They are made of tiny building blocks called nucleotides, arranged in long chains. These chains are found in DNA, which is like a recipe book for life.

There are two main ways scientists think about genes. One way is about how traits are passed from parents to children, called the Mendelian gene. The other way looks at genes as specific pieces of DNA that can make molecules, either directly or by making proteins that do the work in our cells.

Genes help decide many things about an organism, like its shape, color, or even how it grows. Sometimes, small changes called mutations can happen in genes. These changes create different versions of a gene, called alleles, which can give people or other living things slightly different traits. Over time, these differences help populations change and evolve through natural selection and genetic drift.

Chromosome

(10⁷ - 10¹⁰ bp)

DNA

Gene

(10³ - 10⁶ bp )

Function

A chromosome and its packaged long strand of DNA unraveled. The DNA's base pairs encode genes, which provide functions. A human DNA can have up to 500 million base pairs with thousands of genes.

Definitions

The word "gene" can mean two different things.

The Mendelian gene is the classic idea of a gene. It is something that passes traits from parents to children. It helps explain how traits like eye colour or height are inherited.

The molecular gene is the idea most scientists use today. It describes a piece of DNA that makes a special kind of molecule called RNA. Some of these genes make proteins, which are tiny workers inside our cells. Others make RNA molecules that help in important jobs but do not make proteins.

Scientists have many ways to describe what a gene is. But all agree that a gene is a piece of DNA that makes something useful for the cell.

History

Main article: History of genetics

Discovery of discrete inherited units

A scientist named Gregor Mendel found that traits pass from parents to children in special ways. He studied pea plants and saw that features like flower color followed patterns. Even though he didn't use the word "gene," Mendel showed that traits come from small units that stay the same for many generations.

Gregor Mendel

Before Mendel, people thought traits just mixed together. But Mendel's work showed that traits can be strong or hidden and don't always blend. Later, scientists used his ideas, and in 1909, they made the term "gene" to describe these tiny units of heredity.

Discovery of DNA

In the 1900s, scientists learned that a substance called DNA holds the instructions for genes. They found out DNA's shape and how it makes copies of itself. Experiments proved that genes are small pieces of DNA, each with a special job.

Modern synthesis and its successors

Main article: Modern synthesis (20th century)

Later scientists mixed Mendel's ideas with how animals and plants change over time. They showed that genes help species evolve and develop. New ways to study DNA helped us learn how life changed over millions of years.

Molecular basis

Main article: DNA

Most living things store their genes in DNA, a special molecule. DNA is made of small parts called nucleotides. These have a sugar, a phosphate group, and one of four bases: adenine, cytosine, guanine, and thymine.

DNA strands twist together to form a shape like a spiral staircase, called a double helix. The bases pair up: adenine with thymine, and guanine with cytosine. This helps DNA copy itself accurately.

Genes in DNA can be read to make RNA, another molecule. Some genes help build proteins, tiny workers inside cells. Each protein is made from three nucleotides called a codon. The same rules, called the genetic code, are used by almost all living things to decide which protein each codon makes.

Genes are found on structures called chromosomes. A chromosome is a long piece of DNA that can hold thousands of genes. In most cells, chromosomes are inside a special area called the nucleus. They are wrapped around proteins called histones, which help control which genes are active.

Some simple cells have their genes on a single round chromosome. More complex cells, like those in humans, usually have many chromosomes. Even small parts of cells, called organelles, can have their own small chromosomes.

Recently, scientists found that much of the DNA in complex cells does not make proteins but may still have important jobs we are learning about. This used to be called “junk DNA,” but we now know it might do important things.

DNA

Micrographic karyogram of human male, showing 23 pairs of chromosomes. The largest chromosomes are around 10 times the size of the smallest.

Chromosomes

Schematic karyogram of a human, with annotated bands and sub-bands. It shows dark and white regions on G banding. It shows 22 homologous chromosomes, both the male (XY) and female (XX) versions of the sex chromosome (bottom right), as well as the mitochondrial genome (at bottom left). Further information: Karyotype

Structure and function

Genes are the tiny parts that help decide how living things look and act. They are made of special molecules called DNA.

Some genes make proteins, which are like tiny workers inside cells. Others make types of RNA that help in many ways. All genes have parts that control when and how they work, like switches that turn them on or off. These parts help the cell use the gene properly to make what it needs.

Gene expression

All living things need to read the information stored in DNA to make proteins. This happens in two main steps. First, the DNA is copied into a type of RNA called messenger RNA (mRNA). Second, the mRNA is used to build the protein. This whole process is called gene expression.

The order of nucleotides in DNA tells cells which building blocks, called amino acids, to use when making a protein. Special groups of three nucleotides, called codons, match up with specific amino acids.

During the first step, called transcription, an enzyme makes a matching RNA copy of the DNA. The RNA copy then gets changed a little before it moves out to where proteins are built.

The second step, called translation, uses the RNA copy as a guide to link together amino acids into a chain, forming a protein. Special helpers called ribosomes and another type of RNA called transfer RNA work together to match the correct amino acids to the instructions in the RNA.

Cells can control when and how much of each protein they make. This helps them use energy wisely and respond to changes inside and outside the cell.

Inheritance

Main articles: Mendelian inheritance and Heredity

Living things get their genes from their parents. For example, plants that can only make one type of flower will pass that trait to their offspring. Animals that can make two types of flowers, one from each parent, will have a mix of traits.

Genes are like instructions that tell our bodies how to grow and look. Some genes are strong and always show up, while others are hidden unless both parents pass the same gene to their child. This is why some children look more like one parent and sometimes get traits from both.

Genome

The genome is all the genetic material in an organism. It includes genes and other parts that do not make proteins. The size of a genome and the number of genes it has can vary a lot between different living things. Very small genomes are found in viruses, while plants like rice can have very large genomes with thousands of genes.

Scientists have been studying how many genes humans have. Early guesses were around 30,000, but newer studies show that humans likely have about 19,000 genes that make proteins. There are also many genes that do not make proteins, but the exact number is still being studied. Some genes are very important for an organism to survive, and these are called essential genes.

Genetic engineering

Genetic engineering is a way to change the genes inside living things. Scientists use special tools to add, remove, or change genes in plants, animals, and even tiny cells like bacteria. These tools help them fix broken genes or add new ones.

We use genetic engineering in many ways. It helps farmers grow better crops, lets scientists study how genes work, and can help doctors treat some sicknesses. It’s a very important tool in science today!