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===Base modifications===
===Base modifications===
{{further|[[DNA methylation]]}}
{{further|[[DNA methylation]]}}
The expression of genes is influenced by the [[chromatin]] structure of a chromosome, and regions of [[heterochromatin]] (with little or no gene expression) correlate with the [[methylation]] of [[cytosine]]. For example, cytosine methylation, to produce [[5-Methylcytosine|5-methylcytosine]], is important for [[X-inactivation|X-chromosome inactivation]].<ref>{{cite journal | author = Klose R, Bird A | title = Genomic DNA methylation: the mark and its mediators | journal = Trends Biochem Sci | volume = 31 |  pages = 89–97 | year = 2006 | id = PMID 16403636}}</ref> These structural changes to the DNA are one type of [[epigenetic]] change that can alter chromatin structure and are inheritable. The hallmark of such changes are that gene expression is changed without any changes to the primary DNA sequence.<ref>{{cite journal| title=Perceptions of epigenetics| author=Adrian Bird| journal=Nature| volume=447| pages=396-398| year=2007}}</ref>
The expression of genes is influenced by the [[chromatin]] structure of a chromosome, and regions of [[heterochromatin]] (with little or no gene expression) correlate with the [[methylation]] of [[cytosine]]. For example, cytosine methylation, to produce [[5-Methylcytosine|5-methylcytosine]], is important for [[X-inactivation|X-chromosome inactivation]].<ref>{{cite journal | author = Klose R, Bird A | title = Genomic DNA methylation: the mark and its mediators | journal = Trends Biochem Sci | volume = 31 |  pages = 89–97 | year = 2006 | id = PMID 16403636}}</ref> These structural changes to the DNA are one type of [[epigenetic]] change that can alter chromatin structure and are inheritable. The hallmark of such changes are that gene expression is changed without any changes to the primary DNA sequence.<ref>{{cite journal| title=Perceptions of epigenetics| author=Adrian Bird| journal=Nature| volume=447| pages=396-398| year=2007}} PMID 17522671</ref>


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.<ref>{{cite journal | author = Bird A | title = DNA methylation patterns and epigenetic memory | journal = Genes Dev | volume = 16 | pages = 6–21 | year = 2002 | id = PMID 11782440}}</ref> Despite the biological role of 5-methylcytosine, it is susceptible to spontaneous [[deamination]] to leave the thymine base, and methylated cytosines are therefore [[mutation]] 'hotspots'.<ref>{{cite journal | author = Walsh C, Xu G | title = Cytosine methylation and DNA repair | journal = Curr Top Microbiol Immunol | volume = 301 | pages = 283–315 | year = | id = PMID 16570853}}</ref> Other base modifications include adenine methylation in bacteria and the [[glycosylation]] of uracil to produce the "J-base" in [[kinetoplastid]]s.<ref>{{cite journal | author = Ratel D ''et al.''| title = N6-methyladenine: the other methylated base of DNA | journal = Bioessays | volume = 28 | pages = 309–15 | year = 2006 | id = PMID 16479578}}</ref><ref>{{cite journal | author = Gommers-Ampt J ''et al.''| title = beta-D-glucosyl-hydroxymethyluracil: a novel modified base present in the DNA of the parasitic protozoan T. brucei | journal = Cell | volume = 75 | pages = 1129–36 | year = 1993 | id = PMID 8261512}}</ref>
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.<ref>{{cite journal | author = Bird A | title = DNA methylation patterns and epigenetic memory | journal = Genes Dev | volume = 16 | pages = 6–21 | year = 2002 | id = PMID 11782440}}</ref> Despite the biological role of 5-methylcytosine, it is susceptible to spontaneous [[deamination]] to leave the thymine base, and methylated cytosines are therefore [[mutation]] 'hotspots'.<ref>{{cite journal | author = Walsh C, Xu G | title = Cytosine methylation and DNA repair | journal = Curr Top Microbiol Immunol | volume = 301 | pages = 283–315 | year = | id = PMID 16570853}}</ref> Other base modifications include adenine methylation in bacteria and the [[glycosylation]] of uracil to produce the "J-base" in [[kinetoplastid]]s.<ref>{{cite journal | author = Ratel D ''et al.''| title = N6-methyladenine: the other methylated base of DNA | journal = Bioessays | volume = 28 | pages = 309–15 | year = 2006 | id = PMID 16479578}}</ref><ref>{{cite journal | author = Gommers-Ampt J ''et al.''| title = beta-D-glucosyl-hydroxymethyluracil: a novel modified base present in the DNA of the parasitic protozoan T. brucei | journal = Cell | volume = 75 | pages = 1129–36 | year = 1993 | id = PMID 8261512}}</ref>

Revision as of 12:39, 2 July 2007

Three-dimensional model of the structure of part of a DNA double helix.

Deoxyribonucleic acid (DNA) is a very large biological molecule that is vital in providing information for the development and reproduction of living things. Yet, every living organism has its own DNA sequence that is like a unique barcode or fingerprint. This inheritable variation in DNA is the single most important factor driving evolutionary change over many generations of organisms. But, beyond these general descriptive characteristics, what "exactly" is DNA? What are the precise physical attributes of this molecule that make its role so centrally imposing in understanding organic life?

DNA is a long polymer of simple units called nucleotides, held together by a sugar phosphate backbone. Attached to each sugar molecule is a molecule of one of four bases; adenine (A), thymine (T), guanine (G) or cytosine (C), and the order of these bases on the DNA strand encodes information. In most organisms, DNA is a double-helix (or duplex molecule) consisting of two complementary DNA strands coiled around each other, and held together by hydrogen bonds between bases. Because of the chemical nature of these bases, adenine always pairs with thymine and guanine always pairs with cytosine. This complementarity forms the basis of semi-conservative DNA replication - it makes it possible for the large DNA molecule to be copied relatively simply, while accurately preserving its information content in both daughter copies.

The entire DNA sequence of an organism is called its genome. In animals and plants, most DNA is stored inside the cell nucleus. In bacteria, there is no nuclear membrane around the DNA which is in a region called the nucleoid. Some organelles in eukaryotic cells, namely mitochondria and chloroplasts, have their own DNA with a similar organisation to bacterial DNA. Viruses have a single type of nucleic acid, either DNA or RNA, directly encased in a protein coat (although some viruses have, additionally, an outer lipid envelope).

Overview of biological functions

DNA contains the genetic information that is the basis for living functions including growth, reproduction and evolution. This information is held in segments of the duplex strands of DNA that are called genes that may span in size from scores of DNA base-pairs to many thousands of base-pairs. DNA usually occurs as linear chromosomes in eukaryotes, and circular chromosomes in prokaryotes. Prokaryote organisms such as common bacteria often posses small optional chromosomes called plasmids. The set of chromosomes in a cell makes up its genome; the human genome has about three billion base pairs of DNA arranged into 46 chromosomes.[1]

There are many interactions that happen between DNA and other molecules to coordinate its functions. When cells divide, the genetic information must be duplicated to produce two daughter copies of DNA in a process called DNA replication. When a cell uses the information in a gene, the DNA sequence is copied into a complementary single strand of RNA in a process called transcription. Of the transcribed sequences, some are used to directly make a matching protein sequence by a process called translation ( meaning translation from a nucleic acid polymer to an amino acid polymer). The other transcribed RNA sequences may have regulatory, structural or catalytic roles. This article introduces some of the functions and interactions that characterize the DNA molecules in cells, and touches on some of the more technological uses for this molecule.

Genes

Our understanding of the various ways in which genes play a role in cells has been continually revised throughout the history of genetics, starting from abstract concepts of inheritable particles whose composition was unknown. This ongoing refinement has led to several modern different definitions of a gene. One of the most straightforward of these is to define a gene as simply a segment of DNA that is transcribed into RNA - that is - the gene is a unit of transcription. This definition encompasses genes for non-translated RNAs, such as ribosomal RNA (rRNA) and transfer RNA (tRNA), as well as messenger RNA (mRNA) which is used for encoding the sequences of proteins.

A second approach is to define a gene as a region of DNA that encodes a single polypeptide. By this definition, any particular mRNA transcription unit can cover more than one gene, and thus a mRNA can carry regions encoding one or more polypeptides. Such a multi-genic transcription unit is called an operon.

Other definitions include consideration of genes as units of biological function. This gene definition can include sites on DNA that are not transcribed, such as DNA sites at which regulatory and catalytically active proteins concerned with gene regulation and expression are located. Examples of such sites (loci, sing. locus) are promoters and operators. (Locus is a genetic term very similar in meaning to gene, and which refers to a site or region on a chromosome concerned with a particular function or trait.)

Genomes

Further information: Cell nucleus, Gene, Non-coding DNA, Genomics, Mitochondrial DNA

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.[2] The DNA is usually in linear chromosomes in eukaryotes, and circular chromosomes in prokaryotes. The human genome has about three billion base pairs of DNA arranged into 46 chromosomes.[1]

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.[3] The non-coding elements have been coined by the term "junk DNA" since they were thought to have no function, although, some non-coding DNA sequences are known to play a structural role in chromosomes. Telomeres and centromeres typically contain few genes, but are important for the function and stability of chromosomes.[4][5] An abundant form of non-coding DNA in humans are pseudogenes, which are copies of genes that have been disabled by mutation;[6] these are usually just molecular 'fossils', but they can provide the raw genetic material for creating new genes.[7]

A recent challenge to the long-standing view that the human genome consists of a relatively small set of discrete genes, along with a vast amount of "junk DNA" comes from the ENCyclopedia Of DNA Elements (ENCODE) consortium.[8] [9] Their survey of the human genome shows that most of the DNA is transcribed into molecules of RNA. This broad pattern of transcription was unexpected but whether these transcribed, but not translated, elements have any biological function is not yet clear[9].

Replication

Further information: DNA replication, Replication of a circular bacterial chromosome
DNA-replication illustrated by the bacterial replication fork. The helix unwinds and both strands replicate simultaneously, during the unwinding process. The [[leading strand]] replicates continuously from 3' end of existing strand, with newest end of forming strand facing into replication fork. The [[lagging strand]] replicates by a series of fragments (Okazaki fragments placed end-to-end, with newest ends of fragments facing away from fork; the Okazaki fragments are later joined together by an enzyme called DNA ligase. During replication, DNA polymerase III proofreads for mismatched bases

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, which 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, other mechanisms are used to copy the antiparallel strands of the double helix.[10] In this way, the base on the old strand dictates which base appears on the new strand, and the cell (usually) ends up with a perfect copy of its DNA. However, occasionally mistakes (called mutations) occur, generating the genetic variation that is the basis for evolutionary change.

Despite the apparent simplicity of DNA replication, the duplication of DNA before cell division requires a complex and efficient set of catalytically active proteins, each dedicated to one of the several different tasks needed to replicate this large molecule in an orderly and precise fashion. Further capacity for DNA replication with substantial rearrangement (which has major implications for understanding mechanisms of molecular evolution, is provided by mechanisms for DNA movement, inversion, and duplication, illustrated by various mobile DNAs such as transposons and proviruses.

Transcription and translation

Further information: Genetic code, Transcription (genetics), Protein biosynthesis

Within many genes, the nucleotides define a messenger RNA (mRNA) which is used to define a protein sequence. This relationship is possible due to the genetic code in the nucleic acid sequence that is then translated to the amino-acid sequence. The genetic code consists of three-letter 'words' called codons formed from a sequence of three nucleotides (For mRNA, ACU, CAG and UUU are examples).

In transcription, the codons of a gene are copied into mRNA by RNA polymerase. This RNA copy is then decoded by a ribosome that reads the RNA sequence by base-pairing the mRNA to a specific aminoacyl-tRNA; an amino acid carried by a transfer RNA (tRNA). As there are four bases in three-letter combinations, there are 64 possible codons, and these encode the twenty standard amino acids. Most amino acids, therefore, have more than one possible codon. There is one start codon (AUG, that also encodes for methinone) and three 'stop' or 'nonsense' codons (UAA, UGA and UAG) that signify the end of the coding region.

Regulation of gene expression

Further information: Regulation of gene expression

The topic of how genes are regulated - how they are turned on or off - is an important part of modern biology, and research continually yields surprising insights into how phenotypic traits and biological adaptations are determined genetically.

In the 1950's, investigations of the bacterium Escherichia coli led to the recognition that the region upstream of a transcribed region provides a place for the enzyme RNA polymerase to attach to DNA and commence transcription of RNA in 5' to 3' direction of nucleic acid chain extension. The site at which this occurs came to be called the promoter. Other regulatory proteins (such as repressors) were recognized to influence initiation of transcription at promoters by binding to a region near to or overlapping the promoter, called the operator. In these early years of modern genetics, emphasis was given to transcriptional regulation as an important and common means of modulating gene expression, but today we realize that there are a wide range of mechanisms by which the expression of mRNA and proteins can be modulated by both external and internal signals in cells.

Physical and chemical properties

The two strands of DNA are held together by hydrogen bonds between bases. The sugars in the backbone are shown in light blue.

DNA is a long polymer made from repeating units called nucleotides (a nucleotide is a base linked to a sugar and one or more phosphate groups)[11][12] The DNA chain is 22 to 26 angstroms wide (2.2 to 2.6 nanometers) [13] The nucleotides are very small (just 3.3 angstroms long), but DNA polymers can contain millions of them: the DNA strand in the largest human chromosome (Chromosome 1) has 220 million base pairs.[14]

In living organisms, DNA does not usually exist as a single molecule, but as a tightly-associated pair of molecules.[15][16] These two long strands are entwined in the shape of a double helix. DNA can thus be thought of as an anti-parallel double helix. The nucleotide repeats contain both the backbone of the molecule, which holds the chain together, and a base, which interacts with the other DNA strand in the helix. If many nucleotides are linked together, as in DNA, the polymer is referred to as a polynucleotide.[17]

The backbone of the DNA strand has alternating phosphate and sugar residues[18]: the sugar is the pentose (five carbon) sugar 2-deoxyribose. The sugars are joined together by phosphate groups that form phosphodiester bonds between the third and fifth carbon atoms in the sugar rings. These asymmetric bonds mean that 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 a strand of DNA bases are referred to as the 5' (five prime) and 3' (three prime) ends. One of the major differences between DNA and RNA is the sugar: 2-deoxyribose is replaced by ribose in RNA.[16]

The DNA double helix is held together by hydrogen bonds between the bases attached to the two strands. The four bases in DNA are adenine (A), cytosine (C), guanine (G) and thymine (T), and these bases are attached to the sugar/phosphate to form the complete nucleotide. Adenine and guanine are fused five- and six-membered heterocyclic compounds called purines, while cytosine and thymine are six-membered rings called pyrimidines.[17] A fifth pyrimidine base, uracil (U), replaces thymine in RNA and differs from thymine in lacking a methyl group on its ring. Uracil is normally only found in DNA as a breakdown product of cytosine, but bacterial viruses such as phage PBS1 contain uracil in its DNA.[19] In contrast, following synthesis of certain RNA molecules, a significant number of uracils are converted to thymines by the enzymatic addition of the missing methyl group. This occurs mostly on structural and enzymatic RNAs like tRNAs and ribosomal RNA.[20]

The double helix is a right-handed spiral. As the DNA strands wind around each other, gaps between each set of phosphate backbones reveal the sides of the bases inside (see animation). There are two of these grooves twisting around the surface of the double helix: the major groove is 22 Å wide and the minor groove is 12 Å wide.[21] The edges of the bases are more accessible in the major groove, so 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.[22]

Base pairing

Further information: Base pair

Each type of base on one strand of DNA forms a bond with just one type of base on the other strand. This is called complementary base pairing. Purines form hydrogen bonds to pyrimidines, with A bonding only to T, and C bonding only to G. This arrangement of two nucleotides joined together across the double helix is called a base pair. In a double helix, the two strands are also held together by forces generated by the hydrophobic effect and by a nucleic-acid-specific variation of pi stacking, which are not influenced by the sequence of the DNA.[23] As hydrogen bonds are not covalent, they can be broken and rejoined relatively easily. The two strands of DNA in a double helix can thus be pulled apart like a zipper, either by a mechanical force or high temperature.[24] 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.[11] Kornberg considered the introduction of the concept of complementarity as the most important feature of the duplex model for DNA structure.

The two types of base pairs form different numbers of hydrogen bonds; AT forms two hydrogen bonds, and GC forms three, so the GC base-pair is stronger than the AT pair. Thus, long DNA helices with a high GC content have strongly interacting strands, while short helices with high AT content have weakly interacting strands.[25] Parts of the DNA double helix that need to separate easily tend to have a high AT content, making the strands easier to pull apart.[26] 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 shape, but some conformations are more stable than others. The base pairing, or lack of it, can create various topologies at the DNA end. These can be exploited in biotechnology.

Sense and antisense

Further information: Sense (molecular biology)

DNA is copied into RNA by RNA polymerase enzymes that only work in the 5' to 3' direction. [27] A DNA sequence is called "sense" if its sequence is copied by these enzymes and then translated into protein. The sequence on the opposite strand is complementary to the sense sequence and is called the "antisense" sequence. Sense and antisense sequences can exist on the same strand of DNA. In both prokaryotes and eukaryotes, antisense sequences are transcribed [28], and one proposal is that antisense RNAs are involved in regulating gene expression through RNA-RNA base pairing.[29]. (See Micro RNA, RNA interference, sRNA.)

Many DNA sequences in prokaryotes and eukaryotes, and more in plasmids and viruses, have overlapping genes which may both occur in the same direction, on the same strand (parallel) or in opposite directions, on opposite strands (antiparallel), blurring the distinction between sense and antisense strands.[30][31] In these cases, some DNA sequences do double duty, encoding one protein when read 5′ to 3′ along one strand, and a second protein when read in the opposite direction (still 5′ to 3′) along the other strand. In bacteria, this overlap may be involved in regulating gene transcription,[31] while in viruses, overlapping genes increase the amount of information that can be encoded within the small viral genome.[32] Another way of reducing genome size is seen in some viruses that contain linear or circular single-stranded DNA as their genetic material.[33][34]

Supercoiling

Further information: DNA supercoil

DNA can be twisted like a rope in a process called DNA supercoiling. In its "relaxed" state, a DNA 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.[35] 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 are 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 is 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.[36]

Alternative double-helical structures

Further information: Mechanical properties of DNA

DNA exists in several possible conformations, including: A-DNA, B-DNA, C-DNA, D-DNA,[37] E-DNA,[38] H-DNA,[39] L-DNA,[37] and Z-DNA.[18][40] However, only A-DNA, B-DNA, and Z-DNA are thought to occur naturally in biological systems. The DNA conformation depends on the DNA sequence, the amount and direction of supercoiling, chemical modifications of the bases, and also solution conditions, such as the concentration of metal ions.[41] Of these three conformations, the "B" form 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 and wide minor groove and a narrower and deeper major groove; this form occurs 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.[42][43] Segments of DNA where the bases have been 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.[44] These unusual structures can be recognized by specific Z-DNA binding proteins and may be involved in regulating transcription.[45]

Quadruplex structures

At the ends of the linear chromosomes are specialized regions called telomeres. These allow the cell to replicate chromosome ends using the enzyme telomerase, as normal DNA polymerases working on the lagging strand cannot copy the extreme 3' ends of their DNA templates.[46] Without telomeres, a chromosome would become shorter each time it was replicated. These specialized 'caps' also help to protect the DNA ends from exonucleases 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 that contain several thousand repeats of a TTAGGG sequence.[4] These sequences may stabilize chromosome ends by forming unusual quadruplex structures. Here, four guanine bases form a flat plate, throughhydrogen bonding, and these plates then stack on top of each other to form a stable quadruplex.[47] Other structures can also be formed, and the central set of four bases can come from either one folded strand, or several different parallel strands, each contributing one base to the central structure.

Telomeres also form large loop structures called 'telomere loops', or 'T-loops'. Here, the single-stranded DNA curls around in a circle stabilized by telomere-binding proteins.[48]

Chemical modifications

Base modifications

Further information: DNA methylation

The expression of genes is influenced by the chromatin structure of a chromosome, and regions of heterochromatin (with little or no gene expression) correlate with the methylation of cytosine. For example, cytosine methylation, to produce 5-methylcytosine, is important for X-chromosome inactivation.[49] These structural changes to the DNA are one type of epigenetic change that can alter chromatin structure and are inheritable. The hallmark of such changes are that gene expression is changed without any changes to the primary DNA sequence.[50]

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.[51] Despite the biological role of 5-methylcytosine, it is susceptible to spontaneous deamination to leave the thymine base, and methylated cytosines are therefore mutation 'hotspots'.[52] Other base modifications include adenine methylation in bacteria and the glycosylation of uracil to produce the "J-base" in kinetoplastids.[53][54]

DNA damage and mutations

Further information: Mutation

DNA can be damaged by many different agents. Mutagens are agents which can produce genetic mutations - these are alterations of one DNA base to another base. Examples of mutagens include oxidizing agents, alkylating agents and also high-energy electromagnetic radiation such as ultraviolet light and x-rays. Lesions of DNA, in which residues are changed to a structure that is not a normal feature of DNA, are distinct from mutations. However, damaged DNA can give rise to mutations, and indeed, some DNA repair processes are error prone and thus themselves generate mutations.

Ultraviolet radiation damages DNA mostly by producing thymine dimers, which are cross-links between adjacent pyrimidine bases in a DNA strand.[55] On the other hand, oxidants such as free radicals or hydrogen peroxide produce several forms of damage, including base modifications, particularly of guanosine, as well as double-strand breaks.[56] It has been estimated that in each human cell, about 500 bases suffer oxidative damage per day.[57][58] Of these oxidative lesions, the most damaging are double-strand breaks, as they can produce point mutations, insertions and deletions from the DNA sequence, as well as chromosomal translocations.[59]

Many mutagens intercalate into the space between two adjacent base pairs. These are mostly polycyclic, aromatic, and planar molecules and include ethidium, proflavin, daunomycin, doxorubicin and thalidomide. DNA intercalators are used in chemotherapy to inhibit DNA replication in rapidly-growing cancer cells.[60] For an intercalator to fit between base pairs, the bases must separate, distorting the DNA strand by unwinding of the double helix. These structural modifications inhibit transcription and replication processes, causing both toxicity and mutations. As a result, DNA intercalators are often carcinogens. Nevertheless, because they can inhibit DNA transcription and replication, they are also used in chemotherapy to suppress rapidly-growing cancer cells.[60]

Interactions with proteins

All of the functions of DNA depend on its interactions with proteins. These protein interactions can either be non-specific, or the protein can only bind to a particular DNA sequence. Some 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

Nucleosome 2.jpg
Nucleosome (opposites attracts).JPG
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).

Within chromosomes, DNA is held in complexes between DNA and 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 many types of proteins are involved.[61] The histones form a disk-shaped complex called a nucleosome which contains two complete turns of double-stranded DNA wrapped around its surface. These 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.[62] Chemical modifications of these basic amino acid residues include methylation, phosphorylation and acetylation. [63] 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.[64] Other non-specific DNA-binding proteins found in chromatin include the high-mobility group proteins, which bind preferentially to bent or distorted DNA.[65] These proteins are important in bending arrays of nucleosomes and arranging them into more complex chromatin structures.[66]

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.[67] These binding proteins seem to stabilize single-stranded DNA and protect it from forming stem loops or being degraded by nucleases.

Other proteins bind to particular DNA sequences. The most intensively studied of these are the transcription factors; these proteins control gene transcription. Each of these proteins binds 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. Some 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.[68] Other transcription factors can bind enzymes that modify the histones at the promoter, this will change the accessibility of the DNA template to the polymerase.[69]

As these DNA targets can occur throughout an organism's genome, changes in the activity of one type of transcription factor in a given cell can affect the expression of many genes in that cell.[70] 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.[22]

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 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.[71] 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, using the energy from either adenosine triphosphate or nicotinamide adenine dinucleotide. 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.[72]

Topoisomerases and helicases

Topoisomerase activities illustrated with on covalently closed circular DNA. Topisomerase enzymes can form supercoils in DNA, and can interconvert covalently closed circular DNA and their catenated forms.

Topoisomerases are enzymes with both nuclease and ligase activity, and they can change the amount of supercoiling in DNA. Some of these enzymes work by cutting the DNA helix and allowing one section to rotate; the enzyme then seals the DNA break.[73] Other types of these enzymes can cut one DNA helix and then pass a second strand of DNA through this break, before rejoining the helix.[74] Topoisomerases are required for many processes involving DNA, such as DNA replication and transcription.[36]

Helicases are proteins that are a type of molecular motor. They use the chemical energy in nucleoside triphosphates (predominantly ATP) to break hydrogen bonds between bases and unwind the DNA double helix into single strands.[75] These enzymes are essential for most processes where enzymes need to access the DNA bases.

Polymerases

Polymerases are enzymes that synthesise polynucleotide chains from nucleoside triphosphates. They add nucleotides onto the 3′ hydroxyl group of the previous nucleotide in the DNA strand, so all polymerases work in a 5′ to 3′ direction.[27] In the active site of these enzymes, the nucleoside triphosphate substrate base-pairs to a single-stranded polynucleotide template: this allows polymerases to synthesise the complementary strand of this template accurately. Polymerases are classified according to the type of template that they use.

In DNA replication, a DNA polymerase makes a copy of a DNA sequence. Accuracy is very important for this, so many polymerases have a proofreading activity: they can recognizes the occasional mistakes that can occur in the synthesis reaction. In particular, these enzymes detect the lack of base pairing between mismatched nucleotides. If a mismatch is detected, a 3′ to 5′ exonuclease activity is activated and the incorrect base is removed.[76] 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.[77]

RNA-dependent DNA polymerases copy the sequence of an RNA strand into DNA. One example is reverse transcriptase, which is a viral enzyme involved in the infection of cells by retroviruses; another example is telomerase, which is required for the replication of telomeres.[78][46] Telomerase is an unusual polymerase because it contains its own RNA template as part of its structure.[79]

Transcription is carried out by a DNA-dependent RNA polymerase that copies the sequence of a DNA strand into RNA. To begin transcribing a gene, the RNA polymerase binds to a promoter and separates the DNA strands. It then copies the gene sequence into a mRNA transcript until it reaches a region of DNA called the terminator, where it halts and detaches from the DNA. RNA polymerase II, which transcribes most of the genes in the human genome, operates as part of a large protein complex with multiple regulatory and accessory subunits.[80]

Genetic recombination

Further information: Genetic recombination

A DNA helix does not usually interact with other segments of DNA, and in human cells the different chromosomes even occupy different regions of the nucleus called "chromosome territories".[81] This physical separation of 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. Recombination is when two DNA helices break, swap a section and then rejoin. In eukaryotes, this usually occurs during meiosis, when two chromatids are paired together in the center of the cell. This 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.[82] Genetic recombination can also be involved in DNA repair, particularly in the cell's response to double-strand breaks.[83] The most common form of recombination is homologous recombination, where the two chromosomes involved share very similar sequences. However, recombination can also damage cells, as it can produce chromosomal translocations and genetic abnormalities. Recombination reactions are catalyzed by recombinases[84], these enzymes have a DNA-dependent ATPase activity and catalyze strand exchange between participating DNA molecules. First, the recombinase creates a nick in one strand of a DNA double helix, allowing the nicked strand to pull apart from its complementary strand and anneal to one strand of the double helix on the opposite chromatid. A second nick allows the strand in the second chromatid to pull apart and anneal to the strand in the first helix, forming a structure known as a cross-strand exchange or a Holliday junction. The Holliday junction is a tetrahedral junction structure which can be moved along the pair of chromosomes, swapping one strand for another. The recombination is then halted by cleavage of the junction and re-ligation of the released DNA.[85]

DNA and molecular evolution

Further information: Molecular evolution, Phylogenetics

As well as being susceptible to largely random mutations that affect a single base, some regions of DNA are specialised to undergo dramatic, rapid, non-random rearrangements, or to undergo more subtle changes at a high frequency so that the expression of a gene is dramatically altered. Such rearrangements include various versions of site-specific recombination. This depends on enzymes that recognise particular sites on DNA and create novel structures such as insertions, deletions and inversions. For instance, DNA regions in the small genome of the bacterial virus P1 can invert, enabling different versions of tail fibers to be expressed in different viruses. Similarly, site-specific recombinase enzymes are responsible for mating type variation in yeast, and for flagellum type (phase) changes in the bacterium Salmonella enterica Typhimurium.

More subtle mutations can occur in micro-satellite repeats (also called homopolymeric tracts of DNA). An example of such a structure are short DNA intervals where the same base is tandemly repeated, as in 5'-gcAAAAAAAAAAAttg-3', or a dinucleotide or even a triplet as in 5'- ATGATGATGATGATGATGATG-3'. DNA polymerase III is prone to make 'stuttering errors' at such repeats. As a consequence, change in repeat number occur quite often during cell replication, and when they appear at a position where the spacing of nucleotide residues is critical for gene function, they can cause changes to the phenotype.

The stomach ulcer bacterium Helicobacter pylori is a good example of how homopolymeric tracts can enable quasi-directed evolution of particular genes. H. pylori possesses 46 genes that contain homopolymeric runs of nucleotides or dinucleotide repeats that are prone to frequent length changes as a consequence of stuttering of DNA plymerase during replication. These changes can lead to frequent reversible inactivation of these genes, or to changed gene transcription if the repeat is located in a regulatory sequence. This generates highly diverse populations of H. pylori in an individual human host, and helps the bacterium evade the human immune system.[86]

Triplet repeats behave similarly, but are particularly suited to evolution of proteins with differing characteristics. In the clock-like period gene of the fruit fly, which influences the frequency of its love-song, triplet repeats 'fine tune' an insect's clock in response different environmental temperatures. Triplet repeats are widely distributed in genomes, and their high frequency of mutation is responsible for several genetically determined disorders in humans.

Christopher Wills discusses the evolutionary significance of these concepts in The Runaway Brain: The Evolution of Human Uniqueness ISBN 0-00-654672-2 (1995).

Uses in technology

Forensics

Forensic scientists can use DNA in blood, semen, skin, saliva or hair to match samples collected at a crime scene to samples taken from possible suspects. 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 very reliable for identifying the source of a sample,[87] but identification can be complicated if the samples that are collected include DNA from several people.[88] DNA profiling was developed in 1984 by British geneticist Sir Alec Jeffreys,[89] and first used in forensic science to convict Colin Pitchfork in the 1988 Enderby murders case.[90] 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.[91]

Bioinformatics

Further information: Bioinformatics

Bioinformatics involves the analysis of DNA sequence data. The development of techniques to store and search DNA sequences has led to many applications in computer science, including string searching algorithms, machine learning and database theory.[92] String- searching or 'matchingalgorithms, which identify a given sequence of letters inside a larger sequence of letters, are used to search for specific sequences of nucleotides. The related problem of sequence alignment aims to identify homologous sequences and to find the specific mutations that make them distinct. These techniques are used in studying phylogenetic relationships and protein function.[93] 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 patterns that are characteristically associated with protein- or RNA-coding genes can be identified by gene finding algorithms, allowing researchers to predict the presence of particular gene products in an organism.[94]

Molecular cloning

Further information: Molecular cloning,Genomics

The small chromosomes of bacteria have proved extraordinarily useful for analysing genetic mechanisms and genome structure in a many organisms, including humans. This utility arose because of several important discoveries made by microbiologists in the 1950-70's, that provided new laboratory tools for directly manipulating genes. The principal laboratory tools and techniques discovered in this period were:

  • Compact circular plasmid molecules such as ColE1 that were relatively easy to extract and purify from bacterial cells, and when inserted back inside living bacterial cells could serve as genetically stable carriers (vectors) of novel DNA fragments. These vectors were propagated in bacterial cell lines termed "clones". Since each plasmid vector in these clones carried a single DNA molecular fragment, these could be considered to be 'molecular clones'.
  • Convenient methods for extracting plasmid DNA from cells, physical analysis of this DNA, and reinsertion of circular plasmid DNA back inside living cells. The main method for DNA re-insertion is termed DNA transformation - that is, direct uptake of naked DNA molecules by cells. One technique that assisted DNA transformation was the use of selectable genetic markers, and plasmid-borne bacterial antibiotic resistance provided such markers in the form of traits like ampicillin resistance and tetracycline resistance.
  • Restriction endonucleases such as the enzymes EcoRI or HindIII, were found to be useful for specifically digesting DNA at particular sites e.g. EcoRI or HindIII sites, and creation of novel combinations of DNA fragments in the laboratory.
  • Restriction enzymes enabled re-annealing different DNA fragments, such as circular plasmid DNA which had been linearised at a single EcoRI restriction endonuclease target site together with another fragment, say an EcoRI generated fragment of a human chromosome. By sealing together two such fragments with the enzyme DNA ligase, novel hybrid-plasmid molecules could be created in which "foreign" DNA inserts were carried in a chimeric or hybrid plasmid, often called a recombinant DNA molecule.

After the mid-1970's, re-insertion of such recombinant DNA plasmids into living bacterial cells, such as those of Escherichia coli opened up many new approaches in biotechnology. These allowed the manufacture of human polypeptide hormones such as insulin in microbial cell-based protein factories. When combined with other genetic techniques, this field of "recombinant DNA technology" opened up the possibility of decoding the gene sequence of whole genomes. This latter area is now usually referred to as genomics, and includes the Human Genome Project.

DNA and computation

Further information: DNA computing

DNA was first used in computing to solve a small version of the directed Hamiltonian path problem, an NP-complete problem.[95] DNA computing is advantageous over electronic computers in power use, space use, and efficiency, due to its ability to compute in a highly parallel fashion (see parallel computing). A number of other problems, including simulation of various abstract machines, the boolean satisfiability problem, and the bounded version of the travelling salesman problem, have since been analysed using DNA computing.[96] Due to its compactness, DNA also has a theoretical role in cryptography, where in particular it allows unbreakable one-time pads to be efficiently constructed and used.[97]

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Further reading

  • Clayton J, Dennis C (Eds) 50 Years of DNA, Palgrave MacMillan Press, 2003. ISBN 1403914796
  • Judson, Horace Freeland. The Eighth Day of Creation: Makers of the Revolution in Biology, Cold Spring Harbor Laboratory Press, 1996. ISBN 0879694785
  • Olby, Robert. The Path to The Double Helix: Discovery of DNA, first published in October 1974 by MacMillan, with foreword by Francis Crick; ISBN 0486681173; the definitive DNA textbook, revised in 1994, with a 9 page postscript.
  • Ridley, Matt. Francis Crick: Discoverer of the Genetic Code (Eminent Lives) first published in June 2006 in the USA by Harper Collins; 192 pp, ISBN 006082333X
  • Rose, Steven and Mileusnic, Radmilla. The Chemistry of Life, Penguin, ISBN 0140272739 .
  • Watson, James D. and Francis H.C. Crick. (1953) A structure for Deoxyribose Nucleic Acid (PDF). Nature 171, 737–8
  • Watson, James D and Berry, Andrew DNA: The Secret of Life ISBN 0375415467
  • Watson, James D. The Double Helix: A Personal Account of the Discovery of the Structure of DNA. Penguin Books, 2Rev edition 1999, ISBN 0140268774

See Also on Citizendium

External links