The observation that living things inherit
traits from their parents has been used since prehistoric times to improve crop plants and animals through
selective breeding. The modern science of genetics, seeking to understand this process, began with the work of the
Augustinian friar
Gregor Mendel in the mid-19th century. , the first
geneticist and
ethologist. His concepts of
selection and
evolution were later formulated in
Charles Darwin's theory of evolution. Prior to Mendel,
Imre Festetics, a
Hungarian noble, who lived in Kőszeg before Mendel, was the first who used the word "genetic" in hereditarian context, and is considered the first geneticist. He described several rules of biological inheritance in his work
The genetic laws of nature (Die genetischen Gesetze der Natur, 1819). In his third law, he developed the basic principles of mutation (he can be considered a forerunner of
Hugo de Vries). Festetics argued that changes observed in the generation of farm animals, plants, and humans are the result of scientific laws. Festetics empirically deduced that organisms inherit their characteristics, not acquire them. He recognized recessive traits and inherent variation by postulating that traits of past generations could reappear later, and organisms could produce progeny with different attributes. These observations represent an important prelude to Mendel's theory of particulate inheritance insofar as it features a transition of heredity from its status as myth to that of a scientific discipline, by providing a fundamental theoretical basis for genetics in the twentieth century. leads to the averaging out of every characteristic, which as the engineer
Fleeming Jenkin pointed out, makes
evolution by
natural selection impossible. Other theories of inheritance preceded Mendel's work. A popular theory during the 19th century, and implied by
Charles Darwin's 1859
On the Origin of Species, was
blending inheritance: the idea that individuals inherit a smooth blend of traits from their parents. Mendel's work provided examples where traits were definitely not blended after hybridization, showing that traits are produced by combinations of distinct genes rather than a continuous blend. Blending of traits in the progeny is now explained by the action of multiple genes with
quantitative effects. Another theory that had some support at that time was the
inheritance of acquired characteristics: the belief that individuals inherit traits strengthened by their parents. This theory (commonly associated with
Jean-Baptiste Lamarck) is now known to be wrong—the experiences of individuals do not affect the genes they pass to their children. Other theories included Darwin's
pangenesis (which had both acquired and inherited aspects) and
Francis Galton's reformulation of pangenesis as both particulate and inherited.
Mendelian genetics of a mutation causing white eyes in
Drosophila led him to the hypothesis that genes are located upon chromosomes. Modern genetics started with Mendel's studies of the nature of inheritance in plants. In his paper "
Versuche über Pflanzenhybriden" ("
Experiments on Plant Hybridization"), presented in 1865 to the
Naturforschender Verein (Society for Research in Nature) in
Brno, Mendel traced the inheritance patterns of certain traits in pea plants and described them mathematically. Although this pattern of inheritance could only be observed for a few traits, Mendel's work suggested that heredity was particulate, not acquired, and that the inheritance patterns of many traits could be explained through simple rules and ratios. The importance of Mendel's work did not gain wide understanding until 1900, after his death, when
Hugo de Vries and other scientists rediscovered his research.
William Bateson, a proponent of Mendel's work, coined the word
genetics in 1905. The adjective
genetic, derived from the Greek word
genesis—γένεσις, "origin", predates the noun and was first used in a biological sense in 1860. Bateson both acted as a mentor and was aided significantly by the work of other scientists from Newnham College at Cambridge, specifically the work of
Becky Saunders,
Nora Darwin Barlow, and
Muriel Wheldale Onslow. Bateson popularized the usage of the word
genetics to describe the study of inheritance in his inaugural address to the Third International Conference on Plant Hybridization in
London in 1906. After the rediscovery of Mendel's work, scientists tried to determine which molecules in the cell were responsible for inheritance. In 1900, Nettie Stevens began studying the
mealworm. Over the next 11 years, she discovered that females only had the X chromosome and males had both X and Y chromosomes. In 1913, his student
Alfred Sturtevant used the phenomenon of
genetic linkage to show that genes are arranged linearly on the chromosome.
Molecular genetics , the molecular basis for
biological inheritance. Each strand of DNA is a chain of
nucleotides, matching each other in the center to form what look like rungs on a twisted ladder. Although genes were known to exist on chromosomes, chromosomes are composed of both
protein and
DNA, and scientists did not know which of the two was responsible for inheritance.
In 1928,
Frederick Griffith discovered the phenomenon of
transformation: dead bacteria could transfer
genetic material to "transform" other still-living bacteria. Sixteen years later, in 1944, the
Avery–MacLeod–McCarty experiment identified DNA as the molecule responsible for transformation. The role of the nucleus as the repository of genetic information in eukaryotes had been established by
Hämmerling in 1943 in his work on the single celled alga
Acetabularia. The
Hershey–Chase experiment in 1952 confirmed that DNA (rather than protein) is the genetic material of the viruses that infect bacteria, providing further evidence that DNA is the molecule responsible for inheritance.
James Watson and
Francis Crick determined the structure of DNA in 1953, using the
X-ray crystallography work of
Rosalind Franklin and
Maurice Wilkins that indicated DNA has a
helical structure (i.e., shaped like a corkscrew). Their double-helix model had two strands of DNA with the nucleotides pointing inward, each matching a complementary nucleotide on the other strand to form what look like rungs on a twisted ladder. This structure showed that genetic information exists in the sequence of nucleotides on each strand of DNA. The structure also suggested a simple method for
replication: if the strands are separated, new partner strands can be reconstructed for each based on the sequence of the old strand. This property is what gives DNA its semi-conservative nature where one strand of new DNA is from an original parent strand. Although the structure of DNA showed how inheritance works, it was still not known how DNA influences the behavior of cells. In the following years, scientists tried to understand how DNA controls the process of
protein production. It was discovered that the cell uses DNA as a template to create matching
messenger RNA, molecules with
nucleotides very similar to DNA. The nucleotide sequence of a messenger RNA is used to create an
amino acid sequence in protein; this translation between nucleotide sequences and amino acid sequences is known as the
genetic code. With the newfound molecular understanding of inheritance came an explosion of research. A notable theory arose from
Tomoko Ohta in 1973 with her amendment to the
neutral theory of molecular evolution through publishing the
nearly neutral theory of molecular evolution. In this theory, Ohta stressed the importance of natural selection and the environment to the rate at which genetic
evolution occurs. One important development was chain-termination
DNA sequencing in 1977 by
Frederick Sanger. This technology allows scientists to read the nucleotide sequence of a DNA molecule. In 1983,
Kary Banks Mullis developed the
polymerase chain reaction, providing a quick way to isolate and amplify a specific section of DNA from a mixture. The efforts of the
Human Genome Project, Department of Energy, NIH, and parallel private efforts by
Celera Genomics led to the sequencing of the
human genome in 2003. == Features of inheritance ==