Everything about Dna totally explained
Deoxyribonucleic acid (
DNA) is a
nucleic acid that contains the
genetic instructions used in the
development and functioning of all known
living organisms and some
viruses. The main role of DNA
molecules is the long-term storage of
information. DNA is often compared to a set of
blueprints or a recipe, since it contains the instructions needed to construct other components of
cells, such as
proteins and
RNA molecules. The DNA segments that carry this genetic information are called
genes, but other DNA sequences have structural purposes, or are involved in regulating the use of this genetic information.
Chemically, DNA is a long
polymer of simple units called
nucleotides, with a backbone made of sugars and phosphate groups joined by
ester bonds. Attached to each sugar is one of four types of molecules called
bases. It is the sequence of these four bases along the backbone that encodes information. This information is read using the
genetic code, which specifies the sequence of the
amino acids within proteins. The code is read by copying stretches of DNA into the related nucleic acid RNA, in a process called
transcription.
Within cells, DNA is organized into structures called
chromosomes. These chromosomes are duplicated before cells
divide, in a process called
DNA replication.
Eukaryotic organisms (
animals,
plants, and
fungi) store their DNA inside the
cell nucleus, while in
prokaryotes (
bacteria and
archae) it's found in the cell's
cytoplasm. Within the chromosomes,
chromatin proteins such as
histones compact and organize DNA. These compact structures guide the interactions between DNA and other proteins, helping control which parts of the DNA are transcribed.
Physical and chemical properties
DNA is a long
polymer made from repeating units called
nucleotides. The DNA chain is 22 to 26
Ångströms wide (2.2 to 2.6
nanometres), and one nucleotide unit is 3.3 Å (0.33 nm) long. Although each individual repeating unit is very small, DNA polymers can be enormous molecules containing millions of nucleotides. For instance, the largest human chromosome, chromosome number 1, is approximately 220 million
base pairs long.
In living organisms, DNA doesn't usually exist as a single molecule, but instead as a tightly-associated pair of molecules. These two long strands entwine like vines, in the shape of a
double helix. The nucleotide repeats contain both the segment of the backbone of the molecule, which holds the chain together, and a base, which interacts with the other DNA strand in the helix. In general, a base linked to a sugar is called a
nucleoside and a base linked to a sugar and one or more phosphate groups is called a
nucleotide. If multiple nucleotides are linked together, as in DNA, this polymer is called a
polynucleotide.
The backbone of the DNA strand is made from alternating
phosphate and
sugar residues. The sugar in DNA is 2-deoxyribose, which is a
pentose (five-
carbon) sugar. The sugars are joined together by phosphate groups that form
phosphodiester bonds between the third and fifth carbon
atoms of adjacent sugar rings. These asymmetric
bonds mean a strand of DNA has a direction. In a double helix the direction of the nucleotides in one strand is opposite to their direction in the other strand. This arrangement of DNA strands is called antiparallel. The asymmetric ends of DNA strands are referred to as the
5′ (
five prime) and
3′ (
three prime) ends, with the 5' end being that with a terminal phosphate group and the 3' end that with a terminal hydroxyl group. One of the major differences between DNA and RNA is the sugar, with 2-deoxyribose being replaced by the alternative pentose sugar
ribose in RNA.]]
The double helix is a right-handed spiral. As the DNA strands wind around each other, they leave gaps between each set of phosphate backbones, revealing the sides of the bases inside (see animation). There are two of these grooves twisting around the surface of the double helix: one groove, the major groove, is 22 Å wide and the other, the minor groove, is 12 Å wide. The narrowness of the minor groove means that the edges of the bases are more accessible in the major groove. As a result, proteins like
transcription factors that can bind to specific sequences in double-stranded DNA usually make contacts to the sides of the bases exposed in the major groove.
Base pairing
Each type of base on one strand forms a bond with just one type of base on the other strand. This is called complementary
base pairing. Here, purines form
hydrogen bonds to pyrimidines, with A bonding only to T, and C bonding only to G. This arrangement of two nucleotides binding together across the double helix is called a base pair. The double helix is also stabilized by the
hydrophobic effect and
pi stacking, which are not influenced by the sequence of the DNA. As hydrogen bonds are not
covalent, they can be broken and rejoined relatively easily. The two strands of DNA in a double helix can therefore be pulled apart like a zipper, either by a mechanical force or high
temperature. As a result of this complementarity, all the information in the double-stranded sequence of a DNA helix is duplicated on each strand, which is vital in DNA replication. Indeed, this reversible and specific interaction between complementary base pairs is critical for all the functions of DNA in living organisms. In biology, parts of the DNA double helix that need to separate easily, such as the TATAAT
Pribnow box in some
promoters, tend to have a high AT content, making the strands easier to pull apart. In the laboratory, the strength of this interaction can be measured by finding the temperature required to break the hydrogen bonds, their
melting temperature (also called
Tm value). When all the base pairs in a DNA double helix melt, the strands separate and exist in solution as two entirely independent molecules. These single-stranded DNA molecules have no single common shape, but some conformations are more stable than others.
Sense and antisense
A DNA sequence is called "sense" if its sequence is the same as that of a
messenger RNA copy that's translated into protein. The sequence on the opposite strand is called the "antisense" sequence. Both sense and antisense sequences can exist on different parts of the same strand of DNA (for example both strands contain both sense and antisense sequences). In both prokaryotes and eukaryotes, antisense RNA sequences are produced, but the functions of these RNAs are not entirely clear. One proposal is that antisense RNAs are involved in regulating
gene expression through RNA-RNA base pairing.
A few DNA sequences in prokaryotes and eukaryotes, and more in
plasmids and
viruses, blur the distinction between sense and antisense strands by having overlapping genes. In these cases, some DNA sequences do double duty, encoding one protein when read along one strand, and a second protein when read in the opposite direction along the other strand. In
bacteria, this overlap may be involved in the regulation of gene transcription, while in viruses, overlapping genes increase the amount of information that can be encoded within the small viral genome.
Supercoiling
DNA can be twisted like a rope in a process called
DNA supercoiling. With DNA in its "relaxed" state, a strand usually circles the axis of the double helix once every 10.4 base pairs, but if the DNA is twisted the strands become more tightly or more loosely wound. If the DNA is twisted in the direction of the helix, this is positive supercoiling, and the bases are held more tightly together. If they're twisted in the opposite direction, this is negative supercoiling, and the bases come apart more easily. In nature, most DNA has slight negative supercoiling that's introduced by
enzymes called
topoisomerases. These enzymes are also needed to relieve the twisting stresses introduced into DNA strands during processes such as
transcription and
DNA replication.
Alternative double-helical structures
DNA exists in many possible
conformations. Of these three conformations, the "B" form described above is most common under the conditions found in cells. The two alternative double-helical forms of DNA differ in their geometry and dimensions.
The A form is a wider right-handed spiral, with a shallow, wide minor groove and a narrower, deeper major groove. The A form occurs under non-physiological conditions in dehydrated samples of DNA, while in the cell it may be produced in hybrid pairings of DNA and RNA strands, as well as in enzyme-DNA complexes. Segments of DNA where the bases have been chemically-modified by
methylation may undergo a larger change in conformation and adopt the
Z form. Here, the strands turn about the helical axis in a left-handed spiral, the opposite of the more common B form. These unusual structures can be recognized by specific Z-DNA binding proteins and may be involved in the regulation of transcription.
Quadruplex structures
telomeres. The main function of these regions is to allow the cell to replicate chromosome ends using the enzyme
telomerase, as the enzymes that normally replicate DNA can't copy the extreme 3′ ends of chromosomes. These specialized chromosome caps also help protect the DNA ends, and stop the
DNA repair systems in the cell from treating them as damage to be corrected. In human cells, telomeres are usually lengths of single-stranded DNA containing several thousand repeats of a simple TTAGGG sequence.
These guanine-rich sequences may stabilize chromosome ends by forming structures of stacked sets of four-base units, rather than the usual base pairs found in other DNA molecules. Here, four guanine bases form a flat plate and these flat four-base units then stack on top of each other, to form a stable
G-quadruplex structure. These structures are stabilized by hydrogen bonding between the edges of the bases and
chelation of a metal ion in the centre of each four-base unit. Other structures can also be formed, with the central set of four bases coming from either a single strand folded around the bases, or several different parallel strands, each contributing one base to the central structure.
In addition to these stacked structures, telomeres also form large loop structures called telomere loops, or T-loops. Here, the single-stranded DNA curls around in a long circle stabilized by telomere-binding proteins. At the very end of the T-loop, the single-stranded telomere DNA is held onto a region of double-stranded DNA by the telomere strand disrupting the double-helical DNA and base pairing to one of the two strands. This
triple-stranded structure is called a displacement loop or
D-loop. The average level of methylation varies between organisms, with
Caenorhabditis elegans lacking cytosine methylation, while
vertebrates show higher levels, with up to 1% of their DNA containing 5-methylcytosine. Despite the biological role of 5-methylcytosine it can
deaminate to leave a thymine base, methylated cytosines are therefore particularly prone to
mutations. Other base modifications include adenine methylation in bacteria and the
glycosylation of uracil to produce the "J-base" in
kinetoplastids.
DNA damage
DNA can be damaged by many different sorts of
mutagens, which are agents that change the DNA sequence. These agents include
oxidizing agents,
alkylating agents and also high-energy
electromagnetic radiation such as
ultraviolet light and
X-rays. The type of DNA damage produced depends on the type of mutagen. For example, UV light mostly damages DNA by producing
thymine dimers, which are cross-links between adjacent pyrimidine bases in a DNA strand. On the other hand, oxidants such as
free radicals or
hydrogen peroxide produce multiple forms of damage, including base modifications, particularly of guanosine, as well as double-strand breaks. It has been estimated that in each human cell, about 500 bases suffer oxidative damage per day. Of these oxidative lesions, the most dangerous are double-strand breaks, as these are difficult to repair and can produce
point mutations,
insertions and
deletions from the DNA sequence, as well as
chromosomal translocations.
Many mutagens
intercalate into the space between two adjacent base pairs. Intercalators are mostly
aromatic and planar molecules, and include
ethidium,
daunomycin,
doxorubicin and
thalidomide. In order for an intercalator to fit between base pairs, the bases must separate, distorting the DNA strands by unwinding of the double helix. These structural changes inhibit both transcription and DNA replication, causing toxicity and mutations. As a result, DNA intercalators are often
carcinogens, with
benzopyrene diol epoxide,
acridines,
aflatoxin and
ethidium bromide being well-known examples. Nevertheless, due to their properties of inhibiting DNA transcription and replication, they're also used in
chemotherapy to inhibit rapidly-growing
cancer cells.
Overview of biological functions
DNA usually occurs as linear
chromosomes in eukaryotes, and circular chromosomes in prokaryotes. The set of chromosomes in a cell makes up its
genome; the
human genome has approximately 3 billion base pairs of DNA arranged into 46 chromosomes. The information carried by DNA is held in the
sequence of pieces of DNA called
genes.
Transmission of genetic information in genes is achieved via complementary base pairing. For example, in transcription, when a cell uses the information in a gene, the DNA sequence is copied into a complementary RNA sequence through the attraction between the DNA and the correct RNA nucleotides. Usually, this RNA copy is then used to make a matching protein sequence in a process called
translation which depends on the same interaction between RNA nucleotides. Alternatively, a cell may simply copy its genetic information in a process called DNA replication. The details of these functions are covered in other articles; here we focus on the interactions between DNA and other molecules that mediate the function of the genome.
Genes and genomes
Genomic DNA is located in the
cell nucleus of eukaryotes, as well as small amounts in
mitochondria and
chloroplasts. In prokaryotes, the DNA is held within an irregularly shaped body in the cytoplasm called the
nucleoid. The genetic information in a genome is held within genes, and the complete set of this information in an organism is called its
genotype. A gene is a unit of
heredity and is a region of DNA that influences a particular characteristic in an organism. Genes contain an
open reading frame that can be transcribed, as well as
regulatory sequences such as
promoters and
enhancers, which control the transcription of the open reading frame.
In many
species, only a small fraction of the total sequence of the
genome encodes protein. For example, only about 1.5% of the human genome consists of protein-coding
exons, with over 50% of human DNA consisting of non-coding
repetitive sequences. The reasons for the presence of so much
non-coding DNA in eukaryotic genomes and the extraordinary differences in
genome size, or
C-value, among species represent a long-standing puzzle known as the "
C-value enigma." However, DNA sequences that don't code protein may still encode functional
non-coding RNA molecules, which are involved in the regulation of gene expression.
Some non-coding DNA sequences play structural roles in chromosomes.
Telomeres and
centromeres typically contain few genes, but are important for the function and stability of chromosomes. An abundant form of non-coding DNA in humans are
pseudogenes, which are copies of genes that have been disabled by mutation. These sequences are usually just molecular
fossils, although they can occasionally serve as raw genetic material for the creation of new genes through the process of
gene duplication and
divergence.
Transcription and translation
A gene is a sequence of DNA that contains genetic information and can influence the
phenotype of an organism. Within a gene, the sequence of bases along a DNA strand defines a
messenger RNA sequence, which then defines one or more protein sequences. The relationship between the nucleotide sequences of genes and the
amino-acid sequences of proteins is determined by the rules of
translation, known collectively as the
genetic code. The genetic code consists of three-letter 'words' called
codons formed from a sequence of three nucleotides (for example ACT, CAG, TTT).
In transcription, the codons of a gene are copied into messenger RNA by
RNA polymerase. This RNA copy is then decoded by a
ribosome that reads the RNA sequence by base-pairing the messenger RNA to
transfer RNA, which carries amino acids. Since there are 4 bases in 3-letter combinations, there are 64 possible codons (
combinations). These encode the twenty
standard amino acids, giving most amino acids more than one possible codon. There are also three 'stop' or 'nonsense' codons signifying the end of the coding region; these are the TAA, TGA and TAG codons.
Replication
Cell division is essential for an organism to grow, but when a cell divides it must replicate the DNA in its genome so that the two daughter cells have the same genetic information as their parent. The double-stranded structure of DNA provides a simple mechanism for
DNA replication. Here, the two strands are separated and then each strand's complementary DNA sequence is recreated by an
enzyme called
DNA polymerase. This enzyme makes the complementary strand by finding the correct base through complementary base pairing, and bonding it onto the original strand. As DNA polymerases can only extend a DNA strand in a 5′ to 3′ direction, different mechanisms are used to copy the antiparallel strands of the double helix. In this way, the base on the old strand dictates which base appears on the new strand, and the cell ends up with a perfect copy of its DNA.
Interactions with proteins
All the functions of DNA depend on interactions with proteins. These protein interactions can be non-specific, or the protein can bind specifically to a single DNA sequence. Enzymes can also bind to DNA and of these, the polymerases that copy the DNA base sequence in transcription and DNA replication are particularly important.
DNA-binding proteins
Interaction of DNA with
histones (shown in white, top). These proteins' basic amino acids (below left, blue) bind to the acidic phosphate groups on DNA (below right, red).
Structural proteins that bind DNA are well-understood examples of non-specific DNA-protein interactions. Within chromosomes, DNA is held in complexes with structural proteins. These proteins organize the DNA into a compact structure called
chromatin. In eukaryotes this structure involves DNA binding to a complex of small basic proteins called
histones, while in prokaryotes multiple types of proteins are involved. The histones form a disk-shaped complex called a
nucleosome, which contains two complete turns of double-stranded DNA wrapped around its surface. These non-specific interactions are formed through basic residues in the histones making
ionic bonds to the acidic sugar-phosphate backbone of the DNA, and are therefore largely independent of the base sequence. Chemical modifications of these basic amino acid residues include
methylation,
phosphorylation and
acetylation. These chemical changes alter the strength of the interaction between the DNA and the histones, making the DNA more or less accessible to
transcription factors and changing the rate of transcription. Other non-specific DNA-binding proteins found in chromatin include the high-mobility group proteins, which bind preferentially to bent or distorted DNA. These proteins are important in bending arrays of nucleosomes and arranging them into more complex chromatin structures.
A distinct group of DNA-binding proteins are the single-stranded-DNA-binding proteins that specifically bind single-stranded DNA. In humans, replication protein A is the best-characterised member of this family and is essential for most processes where the double helix is separated, including DNA replication, recombination and DNA repair. These binding proteins seem to stabilize single-stranded DNA and protect it from forming
stem-loops or being degraded by
nucleases.
In contrast, other proteins have evolved to specifically bind particular DNA sequences. The most intensively studied of these are the various classes of
transcription factors, which are proteins that regulate transcription. Each one of these proteins bind to one particular set of DNA sequences and thereby activates or inhibits the transcription of genes with these sequences close to their promoters. The transcription factors do this in two ways. Firstly, they can bind the RNA polymerase responsible for transcription, either directly or through other mediator proteins; this locates the polymerase at the promoter and allows it to begin transcription. Alternatively, transcription factors can bind
enzymes that modify the histones at the promoter; this will change the accessibility of the DNA template to the polymerase.
As these DNA targets can occur throughout an organism's genome, changes in the activity of one type of transcription factor can affect thousands of genes. Consequently, these proteins are often the targets of the
signal transduction processes that mediate responses to environmental changes or cellular differentiation and development. The specificity of these transcription factors' interactions with DNA come from the proteins making multiple contacts to the edges of the DNA bases, allowing them to "read" the DNA sequence. Most of these base-interactions are made in the major groove, where the bases are most accessible.
DNA-modifying enzymes
Nucleases and ligases
Nucleases are
enzymes that cut DNA strands by catalyzing the
hydrolysis of the
phosphodiester bonds. Nucleases that hydrolyse nucleotides from the ends of DNA strands are called
exonucleases, while
endonucleases cut within strands. The most frequently-used nucleases in
molecular biology are the
restriction endonucleases, which cut DNA at specific sequences. For instance, the EcoRV enzyme shown to the left recognizes the 6-base sequence 5′-GAT|ATC-3′ and makes a cut at the vertical line. In nature, these enzymes protect
bacteria against
phage infection by digesting the phage DNA when it enters the bacterial cell, acting as part of the
restriction modification system. In technology, these sequence-specific nucleases are used in
molecular cloning and
DNA fingerprinting.
Enzymes called
DNA ligases can rejoin cut or broken DNA strands. Ligases are particularly important in
lagging strand DNA replication, as they join together the short segments of DNA produced at the
replication fork into a complete copy of the DNA template. They are also used in
DNA repair and
genetic recombination. Topoisomerases are required for many processes involving DNA, such as DNA replication and transcription. These enzymes are essential for most processes where enzymes need to access the DNA bases.
Polymerases
Polymerases are
enzymes that synthesize polynucleotide chains from
nucleoside triphosphates. The sequence of their products are copies of existing polynucleotide chains - which are called
templates. These enzymes function by adding nucleotides onto the 3′
hydroxyl group of the previous nucleotide in a DNA strand. Consequently, all polymerases work in a 5′ to 3′ direction. In the
active site of these enzymes, the incoming nucleoside triphosphate base-pairs to the template: this allows polymerases to accurately synthesize the complementary strand of their template. Polymerases are classified according to the type of template that they use.
In DNA replication, a DNA-dependent
DNA polymerase makes a DNA copy of a DNA sequence. Accuracy is vital in this process, so many of these polymerases have a
proofreading activity. Here, the polymerase recognizes the occasional mistakes in the synthesis reaction by the lack of base pairing between the mismatched nucleotides. If a mismatch is detected, a 3′ to 5′
exonuclease activity is activated and the incorrect base removed. In most organisms DNA polymerases function in a large complex called the
replisome that contains multiple accessory subunits, such as the
DNA clamp or
helicases.
RNA-dependent DNA polymerases are a specialized class of polymerases that copy the sequence of an RNA strand into DNA. They include
reverse transcriptase, which is a
viral enzyme involved in the infection of cells by
retroviruses, and
telomerase, which is required for the replication of telomeres.
Genetic recombination
A DNA helix usually doesn't interact with other segments of DNA, and in human cells the different chromosomes even occupy separate areas in the nucleus called "chromosome territories". This physical separation of different chromosomes is important for the ability of DNA to function as a stable repository for information, as one of the few times chromosomes interact is during
chromosomal crossover when they
recombine. Chromosomal crossover is when two DNA helices break, swap a section and then rejoin.
Recombination allows chromosomes to exchange genetic information and produces new combinations of genes, which increases the efficiency of
natural selection and can be important in the rapid evolution of new proteins. Genetic recombination can also be involved in DNA repair, particularly in the cell's response to double-strand breaks.
The most common form of chromosomal crossover is
homologous recombination, where the two chromosomes involved share very similar sequences. Non-homologous recombination can be damaging to cells, as it can produce
chromosomal translocations and genetic abnormalities. The recombination reaction is catalyzed by enzymes known as
recombinases, such as
RAD51. The first step in recombination is a double-stranded break either caused by an
endonuclease or damage to the DNA. A series of steps catalyzed in part by the recombinase then leads to joining of the two helices by at least one
Holliday junction, in which a segment of a single strand in each helix is annealed to the complementary strand in the other helix. The Holliday junction is a tetrahedral junction structure that can be moved along the pair of chromosomes, swapping one strand for another. The recombination reaction is then halted by cleavage of the junction and re-ligation of the released DNA.
Evolution of DNA metabolism
DNA contains the genetic information that allows all modern living things to function, grow and reproduce. However, it's unclear how long in the 4-billion-year
history of life DNA has performed this function, as it has been proposed that the earliest forms of life may have used RNA as their genetic material. RNA may have acted as the central part of early cell metabolism as it can both transmit genetic information and carry out
catalysis as part of
ribozymes. This ancient
RNA world where nucleic acid would have been used for both catalysis and genetics may have influenced the
evolution of the current genetic code based on four nucleotide bases. This would occur since the number of unique bases in such an organism is a trade-off between a small number of bases increasing replication accuracy and a large number of bases increasing the catalytic efficiency of ribozymes.
Unfortunately, there's no direct evidence of ancient genetic systems, as recovery of DNA from most fossils is impossible. This is because DNA will survive in the environment for less than one million years and slowly degrades into short fragments in solution. Claims for older DNA have been made, most notably a report of the isolation of a viable bacterium from a salt crystal 250-million years old, but these claims are controversial.
Uses in technology
Genetic engineering
Modern
biology and
biochemistry make intensive use of recombinant DNA technology.
Recombinant DNA is a man-made DNA sequence that has been assembled from other DNA sequences. They can be
transformed into organisms in the form of
plasmids or in the appropriate format, by using a
viral vector. The
genetically modified organisms produced can be used to produce products such as recombinant
proteins, used in medical research, or be grown in
agriculture.
Forensics
Forensic scientists can use DNA in
blood,
semen,
skin,
saliva or
hair at a crime scene to identify a perpetrator. This process is called
genetic fingerprinting, or more accurately, DNA profiling. In DNA profiling, the lengths of variable sections of repetitive DNA, such as
short tandem repeats and
minisatellites, are compared between people. This method is usually an extremely reliable technique for identifying a criminal. However, identification can be complicated if the scene is contaminated with DNA from several people. DNA profiling was developed in 1984 by British geneticist Sir
Alec Jeffreys, and first used in forensic science to convict Colin Pitchfork in the 1988
Enderby murders case. People convicted of certain types of crimes may be required to provide a sample of DNA for a database. This has helped investigators solve old cases where only a DNA sample was obtained from the scene. DNA profiling can also be used to identify victims of mass casualty incidents.
Bioinformatics
Bioinformatics involves the manipulation, searching, and
data mining of DNA sequence data. The development of techniques to store and search DNA sequences have led to widely-applied advances in
computer science, especially
string searching algorithms,
machine learning and
database theory. String searching or matching algorithms, which find an occurrence of a sequence of letters inside a larger sequence of letters, were developed to search for specific sequences of nucleotides. In other applications such as
text editors, even simple algorithms for this problem usually suffice, but DNA sequences cause these algorithms to exhibit near-worst-case behaviour due to their small number of distinct characters. The related problem of
sequence alignment aims to identify
homologous sequences and locate the specific
mutations that make them distinct. These techniques, especially
multiple sequence alignment, are used in studying
phylogenetic relationships and protein function. Data sets representing entire genomes' worth of DNA sequences, such as those produced by the
Human Genome Project, are difficult to use without annotations, which label the locations of genes and regulatory elements on each chromosome. Regions of DNA sequence that have the characteristic patterns associated with protein- or RNA-coding genes can be identified by
gene finding algorithms, which allow researchers to predict the presence of particular
gene products in an organism even before they've been isolated experimentally.
DNA nanotechnology
DNA nanotechnology uses the unique
molecular recognition properties of DNA and other nucleic acids to create self-assembling branched DNA complexes with useful properties. DNA is thus used as a structural material rather than as a carrier of biological information. This has led to the creation of two-dimensional periodic lattices (both tile-based as well as using the "
DNA origami" method) as well as three-dimensional structures in the shapes of
polyhedra.
Nanomechanical devices and
algorithmic self-assembly have also been demonstrated, and these DNA structures have been used to template the arrangement of other molecules such as
gold nanoparticles and
streptavidin proteins.
History and anthropology
Because DNA collects mutations over time, which are then inherited, it contains historical information and by comparing DNA sequences, geneticists can infer the evolutionary history of organisms, their
phylogeny. This field of phylogenetics is a powerful tool in
evolutionary biology. If DNA sequences within a species are compared,
population geneticists can learn the history of particular populations. This can be used in studies ranging from
ecological genetics to
anthropology; for example, DNA evidence is being used to try to identify the
Ten Lost Tribes of Israel.
DNA has also been used to look at modern family relationships, such as establishing family relationships between the descendants of
Sally Hemings and
Thomas Jefferson. This usage is closely related to the use of DNA in criminal investigations detailed above. Indeed, some criminal investigations have been solved when DNA from crime scenes has matched relatives of the guilty individual.
History of DNA research
Swiss physician
Friedrich Miescher who, in 1869, discovered a microscopic substance in the
pus of discarded surgical bandages. As it resided in the nuclei of cells, he called it "nuclein". In 1919 this discovery was followed by
Phoebus Levene's identification of the base, sugar and phosphate nucleotide unit. Levene suggested that DNA consisted of a string of nucleotide units linked together through the phosphate groups. However, Levene thought the chain was short and the bases repeated in a fixed order. In 1937
William Astbury produced the first
X-ray diffraction patterns that showed that DNA had a regular structure.
In 1928,
Frederick Griffith discovered that
traits of the "smooth" form of the
Pneumococcus could be transferred to the "rough" form of the same bacteria by mixing killed "smooth" bacteria with the live "rough" form. This system provided the first clear suggestion that DNA carried genetic information, when
Oswald Avery, along with coworkers
Colin MacLeod and
Maclyn McCarty, identified DNA as the
transforming principle in 1943. DNA's role in
heredity was confirmed in 1952, when
Alfred Hershey and
Martha Chase in the
Hershey-Chase experiment showed that DNA is the
genetic material of the
T2 phage.
In 1953, based on
X-ray diffraction images taken by
Rosalind Franklin and the information that the bases were paired,
James D. Watson and
Francis Crick suggested Of these,
Franklin and
Raymond Gosling's paper was the first publication of X-ray diffraction data that supported the Watson and Crick model, this issue also contained an article on DNA structure by
Maurice Wilkins and his colleagues. In 1962, after Franklin's death, Watson, Crick, and Wilkins jointly received the
Nobel Prize in
Physiology or Medicine. However, debate continues on who should receive credit for the discovery.
In an influential presentation in 1957, Crick laid out the
"Central Dogma" of molecular biology, which foretold the relationship between DNA, RNA, and proteins, and articulated the "adaptor hypothesis". Final confirmation of the replication mechanism that was implied by the double-helical structure followed in 1958 through the
Meselson-Stahl experiment. Further work by Crick and coworkers showed that the genetic code was based on non-overlapping triplets of bases, called codons, allowing
Har Gobind Khorana,
Robert W. Holley and
Marshall Warren Nirenberg to decipher the genetic code. These findings represent the birth of
molecular biology.
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