Nuclease

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Depiction of the restriction enzyme (endonuclease) HindIII cleaving a double-stranded DNA molecule at a valid restriction site (5'-A|AGCTT-3'). HindIII Restriction site and sticky ends vector.svg
Depiction of the restriction enzyme (endonuclease) HindIII cleaving a double-stranded DNA molecule at a valid restriction site (5'–A|AGCTT–3').

In biochemistry, a nuclease (also archaically known as nucleodepolymerase or polynucleotidase) is an enzyme capable of cleaving the phosphodiester bonds that link nucleotides together to form nucleic acids. Nucleases variously affect single and double stranded breaks in their target molecules. In living organisms, they are essential machinery for many aspects of DNA repair. Defects in certain nucleases can cause genetic instability or immunodeficiency. [1] Nucleases are also extensively used in molecular cloning. [2]

Contents

There are two primary classifications based on the locus of activity. Exonucleases digest nucleic acids from the ends. Endonucleases act on regions in the middle of target molecules. They are further subcategorized as deoxyribonucleases and ribonucleases. The former acts on DNA, the latter on RNA. [2]

History

In the late 1960s, scientists Stuart Linn and Werner Arber isolated examples of the two types of enzymes responsible for phage growth restriction in Escherichia coli (E. coli) bacteria. [3] [4] One of these enzymes added a methyl group to the DNA, generating methylated DNA, while the other cleaved unmethylated DNA at a wide variety of locations along the length of the molecule. The first type of enzyme was called a "methylase" and the other a "restriction nuclease". These enzymatic tools were important to scientists who were gathering the tools needed to "cut and paste" DNA molecules. What was then needed was a tool that would cut DNA at specific sites, rather than at random sites along the length of the molecule, so that scientists could cut DNA molecules in a predictable and reproducible way.

An important development came when H.O. Smith, K.W. Wilcox, and T.J. Kelly, working at Johns Hopkins University in 1968, isolated and characterized the first restriction nuclease whose functioning depended on a specific DNA nucleotide sequence. Working with Haemophilus influenzae bacteria, this group isolated an enzyme, called HindII, that always cut DNA molecules at a particular point within a specific sequence of six base pairs. They found that the HindII enzyme always cuts directly in the center of this sequence (between the 3rd and 4th base pairs).

Numerical Classification System

Most nucleases are classified by the Enzyme Commission number of the "Nomenclature Committee of the International Union of Biochemistry and Molecular Biology" as hydrolases (EC-number 3). The nucleases belong just like phosphodiesterase, lipase and phosphatase to the esterases (EC-number 3.1), a subgroup of the hydrolases. The esterases to which nucleases belong are classified with the EC-numbers 3.1.11 - EC-number 3.1.31.

Structure

Nuclease primary structure is by and large poorly conserved and minimally conserved at active sites, the surfaces of which primarily comprise acidic and basic amino acid residues. Nucleases can be classified into folding families. [5]

Crystal structure of EcoRV in complex with DNA. EcoRV structure.png
Crystal structure of EcoRV in complex with DNA.

Site recognition

A nuclease must associate with a nucleic acid before it can cleave the molecule. That entails a degree of recognition. Nucleases variously employ both nonspecific and specific associations in their modes of recognition and binding. Both modes play important roles in living organisms, especially in DNA repair. [7]

Nonspecific endonucleases involved in DNA repair can scan DNA for target sequences or damage. Such a nuclease diffuses along DNA until it encounters a target, upon which the residues of its active site interact with the chemical groups of the DNA. In the case of endonucleases such as EcoRV, BamHI, and PvuII, this nonspecific binding involves electrostatic interactions between minimal surface area of the protein and the DNA. This weak association leaves the overall shape of the DNA undeformed, remaining in B-form. [7]

A site-specific nuclease forms far stronger associations by contrast. It draws DNA into the deep groove of its DNA-binding domain. This results in significant deformation of the DNA tertiary structure and is accomplished with a surfaces rich in basic (positively charged) residues. It engages in extensive electrostatic interaction with the DNA. [7]

Some nucleases involved in DNA repair exhibit partial sequence-specificity. However most are nonspecific, instead recognizing structural abnormalities produced in the DNA backbone by base pair mismatches. [7]

Structure specific nuclease

For details see flap endonuclease.

Sequence specific nuclease

EnzymeSourceRecognition SequenceCut
HindII Haemophilus influenzae

5'–GTYRAC–3'
3'–CARYTG–5'

5'–GTYRAC–3'
3'–CARYTG–5'

R = A or G; Y = C or T

There are more than 900 restriction enzymes, some sequence specific and some not, have been isolated from over 230 strains of bacteria since the initial discovery of HindII. These restriction enzymes generally have names that reflect their originThe first letter of the name comes from the genus and the second two letters come from the species of the prokaryotic cell from which they were isolated. For example, EcoRI comes from Escherichia coli RY13 bacteria, while HindII comes from Haemophilus influenzae strain Rd. Numbers following the nuclease names indicate the order in which the enzymes were isolated from single strains of bacteria: EcoRI, EcoRII.

Endonucleases

A restriction endonuclease functions by "scanning" the length of a DNA molecule. Once it encounters its particular specific recognition sequence, it will bind to the DNA molecule and makes one cut in each of the two sugar-phosphate backbones. The positions of these two cuts, both in relation to each other, and to the recognition sequence itself, are determined by the identity of the restriction endonuclease. Different endonucleases yield different sets of cuts, but one endonuclease will always cut a particular base sequence the same way, no matter what DNA molecule it is acting on. Once the cuts have been made, the DNA molecule will break into fragments.

Staggered cutting

Not all restriction endonucleases cut symmetrically and leave blunt ends like HindII described above. Many endonucleases cleave the DNA backbones in positions that are not directly opposite each other, creating overhangs. For example, the nuclease EcoRI has the recognition sequence 5'—GAATTC—3'.

EnzymeSourceRecognition SequenceCut
HindIII Haemophilus influenzae
5'–AAGCTT–3'
3'–TTCGAA–5'
5'–AAGCTT–3'
3'–TTCGAA–5'
EcoRI Escherichia coli
5'–GAATTC-3'
3'–CTTAAG–5'
5'–GAATTC–3'
3'–CTTAAG–5'
BamHI Bacillus amyloliquefaciens
5'–GGATCC–3'
3'–CCTAGG–5'
5'–GGATCC–3'
3'–CCTAGG–5'

When the enzyme encounters this sequence, it cleaves each backbone between the G and the closest A base residues. Once the cuts have been made, the resulting fragments are held together only by the relatively weak hydrogen bonds that hold the complementary bases to each other. The weakness of these bonds allows the DNA fragments to separate from each other. Each resulting fragment has a protruding 5' end composed of unpaired bases. Other enzymes create cuts in the DNA backbone which result in protruding 3' ends. Protruding endsboth 3' and 5'are sometimes called "sticky ends" because they tend to bond with complementary sequences of bases. In other words, if an unpaired length of bases 5'—AATT—3' encounters another unpaired length with the sequence 3'—TTAA—5' they will bond to each otherthey are "sticky" for each other. Ligase enzyme is then used to join the phosphate backbones of the two molecules. The cellular origin, or even the species origin, of the sticky ends does not affect their stickiness. Any pair of complementary sequences will tend to bond, even if one of the sequences comes from a length of human DNA, and the other comes from a length of bacterial DNA. In fact, it is this quality of stickiness that allows production of recombinant DNA molecules, molecules which are composed of DNA from different sources, and which has given birth to the genetic engineering technology.

Role in nature

DNA repair

With all cells depending on DNA as the medium of genetic information, genetic quality control is an essential function of all organisms. DNA replication is an error prone process, and DNA molecules themselves are vulnerable to modification by many metabolic and environmental stressors. Ubiquitous examples include reactive oxygen species, near ultraviolet, and ionizing radiation. Many nucleases participate in DNA repair by recognizing damage sites and cleaving them from the surrounding DNA. These enzymes function independently or in complexes. Most nucleases involved in DNA repair are not sequence-specific. They recognize damage sites through deformation of double stranded DNA (dsDNA) secondary structure. [5]

Replication proofreading

During DNA replication, DNA polymerases elongate new strands of DNA against complementary template strands. Most DNA polymerases comprise two different enzymatic domains: a polymerase and a proofreading exonuclease. The polymerase elongates the new strand in the 5' → 3' direction. The exonuclease removes erroneous nucleotides from the same strand in the 3’ → 5’ direction. This exonuclease activity is essential for a DNA polymerase's ability to proofread. Deletions inactivating or removing these nucleases increase rates of mutation and mortality in affected microbes and cancer in mice. [8]

Halted replication fork

Many forms of DNA damage stop progression of the replication fork, causing the DNA polymerases and associated machinery to abandon the fork. It must then be processed by fork-specific proteins. The most notable is MUS81. Deletions of which causes UV or methylation damage sensitivity in yeast, in addition to meiotic defects. [5]

Okazaki fragment processing

A ubiquitous task in cells is the removal of Okazaki fragment RNA primers from replication. Most such primers are excised from newly synthesized lagging strand DNA by endonucleases of the family RNase H. In eukaryotes and in archaea, the flap endonuclease FEN1 also participates in the processing of Okazaki fragments. [5]

Mismatch repair

DNA mismatch repair in any given organism is effected by a suite of mismatch-specific endonucleases. In prokaryotes, this role is primarily filled by MutSLH and very short patch repair (VSP repair) associated proteins.

The MutSLH system (comprising MutS, MutL, and MutH) corrects point mutations and small turns. MutS recognizes and binds to mismatches, where it recruits MutL and MutH. MutL mediates the interaction between MutS and MutH, and enhances the endonucleasic activity of the latter. MutH recognizes hemimethylated 5'—GATC—3' sites and cleaves next to the G of the non-methylated strand (the more recently synthesized strand).

VSP repair is initiated by the endonuclease Vsr. It corrects a specific T/G mismatch caused by the spontaneous deamination of methylated cytosines to thymines. Vsr recognizes the sequence 5'—CT WGG—3', where it nicks the DNA strand on the 5' side of the mismatched thymine (underlined in the previous sequence). One of the exonucleases RecJ, ExoVII, or ExoI then degrades the site before DNA polymerase resynthesizes the gap in the strand. [5]

Base excision repair

AP site formation is a common occurrence in dsDNA. It is the result of spontaneous hydrolysis and the activity of DNA glycosylases as an intermediary step in base excision repair. These AP sites are removed by AP endonucleases, which effect single strand breaks around the site. [5]

Nucleotide excision repair

Nucleotide excision repair, not to be confused with base excision repair, involves the removal and replacement of damaged nucleotides. Instances of crosslinking, adducts, and lesions (generated by ultraviolet light or reactive oxygen species) can trigger this repair pathway. Short stretches of single stranded DNA containing such damaged nucleotide are removed from duplex DNA by separate endonucleases effecting nicks upstream and downstream of the damage. Deletions or mutations which affect these nucleases instigate increased sensitivity to ultraviolet damage and carcinogenesis. Such abnormalities can even impinge neural development.

In bacteria, both cuts executed by the UvrB-UvrC complex. In budding yeast, Rad2 and the Rad1-Rad10 complex make the 5' and 3' cuts, respectively. In mammals, the homologs XPG and XPF-ERCC1 affect the same respective nicks. [9]

Double-strand break repair

Double-strand breaks, both intentional and unintentional, regularly occur in cells. Unintentional breaks are commonly generated by ionizing radiation, various exogenous and endogenous chemical agents, and halted replication forks. Intentional breaks are generated as intermediaries in meiosis and V(D)J recombination, which are primarily repaired through homologous recombination and non-homologous end joining. Both cases require the ends in double strand breaks be processed by nucleases before repair can take place. One such nuclease is Mre11 complexed with Rad50. Mutations of Mre11 can precipitate ataxia-telangiectasia-like disorder. [9]

V(D)J recombination involves opening stem-loops structures associated with double-strand breaks and subsequently joining both ends. The Artemis-DNAPKcs complex participates in this reaction. Although Artemis exhibits 5' → 3' ssDNA exonuclease activity when alone, its complexing with DNA-PKcs allows for endonucleasic processing of the stem-loops. Defects of either protein confers severe immunodeficiency. [9]

Homologous recombination, on the other hand, involves two homologous DNA duplexes connected by D-loops or Holliday junctions. In bacteria, endonucleases like RuvC resolve Holliday junctions into two separate dsDNAs by cleaving the junctions at two symmetrical sites near the junction centre. In eukaryotes, FEN1, XPF-ERCC1, and MUS81 cleave the D-loops, and Cce1/Ydc2 processes Holliday junctions in mitochondria. [9]

Meganucleases

The frequency at which a particular nuclease will cut a given DNA molecule depends on the complexity of the DNA and the length of the nuclease's recognition sequence; due to the statistical likelihood of finding the bases in a particular order by chance, a longer recognition sequence will result in less frequent digestion. For example, a given four-base sequence (corresponding to the recognition site for a hypothetical nuclease) would be predicted to occur every 256 base pairs on average (where 4^4=256), but any given six-base sequence would be expected to occur once every 4,096 base pairs on average (4^6=4096).

One unique family of nucleases is the meganucleases, which are characterized by having larger, and therefore less common, recognition sequences consisting of 12 to 40 base pairs. These nucleases are particularly useful for genetic engineering and Genome engineering applications in complex organisms such as plants and mammals, where typically larger genomes (numbering in the billions of base pairs) would result in frequent and deleterious site-specific digestion using traditional nucleases.

See also

Related Research Articles

<span class="mw-page-title-main">Primer (molecular biology)</span> Short strand of RNA or DNA that serves as a starting point for DNA synthesis

A primer is a short, single-stranded nucleic acid used by all living organisms in the initiation of DNA synthesis. A synthetic primer may also be referred to as an oligo, short for oligonucleotide. DNA polymerase enzymes are only capable of adding nucleotides to the 3’-end of an existing nucleic acid, requiring a primer be bound to the template before DNA polymerase can begin a complementary strand. DNA polymerase adds nucleotides after binding to the RNA primer and synthesizes the whole strand. Later, the RNA strands must be removed accurately and replace them with DNA nucleotides forming a gap region known as a nick that is filled in using an enzyme called ligase. The removal process of the RNA primer requires several enzymes, such as Fen1, Lig1, and others that work in coordination with DNA polymerase, to ensure the removal of the RNA nucleotides and the addition of DNA nucleotides. Living organisms use solely RNA primers, while laboratory techniques in biochemistry and molecular biology that require in vitro DNA synthesis usually use DNA primers, since they are more temperature stable. Primers can be designed in laboratory for specific reactions such as polymerase chain reaction (PCR). When designing PCR primers, there are specific measures that must be taken into consideration, like the melting temperature of the primers and the annealing temperature of the reaction itself. Moreover, the DNA binding sequence of the primer in vitro has to be specifically chosen, which is done using a method called basic local alignment search tool (BLAST) that scans the DNA and finds specific and unique regions for the primer to bind.

A restriction enzyme, restriction endonuclease, REase, ENase orrestrictase is an enzyme that cleaves DNA into fragments at or near specific recognition sites within molecules known as restriction sites. Restriction enzymes are one class of the broader endonuclease group of enzymes. Restriction enzymes are commonly classified into five types, which differ in their structure and whether they cut their DNA substrate at their recognition site, or if the recognition and cleavage sites are separate from one another. To cut DNA, all restriction enzymes make two incisions, once through each sugar-phosphate backbone of the DNA double helix.

<span class="mw-page-title-main">Okazaki fragments</span> Parts of lagging strand in DNA replication

Okazaki fragments are short sequences of DNA nucleotides which are synthesized discontinuously and later linked together by the enzyme DNA ligase to create the lagging strand during DNA replication. They were discovered in the 1960s by the Japanese molecular biologists Reiji and Tsuneko Okazaki, along with the help of some of their colleagues.

A cDNA library is a combination of cloned cDNA fragments inserted into a collection of host cells, which constitute some portion of the transcriptome of the organism and are stored as a "library". cDNA is produced from fully transcribed mRNA found in the nucleus and therefore contains only the expressed genes of an organism. Similarly, tissue-specific cDNA libraries can be produced. In eukaryotic cells the mature mRNA is already spliced, hence the cDNA produced lacks introns and can be readily expressed in a bacterial cell. While information in cDNA libraries is a powerful and useful tool since gene products are easily identified, the libraries lack information about enhancers, introns, and other regulatory elements found in a genomic DNA library.

In molecular biology, endonucleases are enzymes that cleave the phosphodiester bond within a polynucleotide chain. Some, such as deoxyribonuclease I, cut DNA relatively nonspecifically, while many, typically called restriction endonucleases or restriction enzymes, cleave only at very specific nucleotide sequences. Endonucleases differ from exonucleases, which cleave the ends of recognition sequences instead of the middle (endo) portion. Some enzymes known as "exo-endonucleases", however, are not limited to either nuclease function, displaying qualities that are both endo- and exo-like. Evidence suggests that endonuclease activity experiences a lag compared to exonuclease activity.

<span class="mw-page-title-main">Exonuclease</span> Class of enzymes; type of nuclease

Exonucleases are enzymes that work by cleaving nucleotides one at a time from the end (exo) of a polynucleotide chain. A hydrolyzing reaction that breaks phosphodiester bonds at either the 3′ or the 5′ end occurs. Its close relative is the endonuclease, which cleaves phosphodiester bonds in the middle (endo) of a polynucleotide chain. Eukaryotes and prokaryotes have three types of exonucleases involved in the normal turnover of mRNA: 5′ to 3′ exonuclease (Xrn1), which is a dependent decapping protein; 3′ to 5′ exonuclease, an independent protein; and poly(A)-specific 3′ to 5′ exonuclease.

<span class="mw-page-title-main">DNA mismatch repair</span> System for fixing base errors of DNA replication

DNA mismatch repair (MMR) is a system for recognizing and repairing erroneous insertion, deletion, and mis-incorporation of bases that can arise during DNA replication and recombination, as well as repairing some forms of DNA damage.

A nick is a discontinuity in a double stranded DNA molecule where there is no phosphodiester bond between adjacent nucleotides of one strand typically through damage or enzyme action. Nicks allow DNA strands to untwist during replication, and are also thought to play a role in the DNA mismatch repair mechanisms that fix errors on both the leading and lagging daughter strands.

<span class="mw-page-title-main">Restriction fragment</span>

A restriction fragment is a DNA fragment resulting from the cutting of a DNA strand by a restriction enzyme, a process called restriction. Each restriction enzyme is highly specific, recognising a particular short DNA sequence, or restriction site, and cutting both DNA strands at specific points within this site. Most restriction sites are palindromic,, and are four to eight nucleotides long. Many cuts are made by one restriction enzyme because of the chance repetition of these sequences in a long DNA molecule, yielding a set of restriction fragments. A particular DNA molecule will always yield the same set of restriction fragments when exposed to the same restriction enzyme. Restriction fragments can be analyzed using techniques such as gel electrophoresis or used in recombinant DNA technology.

<span class="mw-page-title-main">AP endonuclease</span> Enzyme involved in DNA repair

Apurinic/apyrimidinic (AP) endonuclease is an enzyme that is involved in the DNA base excision repair pathway (BER). Its main role in the repair of damaged or mismatched nucleotides in DNA is to create a nick in the phosphodiester backbone of the AP site created when DNA glycosylase removes the damaged base.

Mung bean nuclease is a nuclease derived from sprouts of the mung bean that removes nucleotides in a step-wise manner from single-stranded DNA molecules (ssDNA) and is used in biotechnological applications to remove such ssDNA from a mixture also containing double-stranded DNA (dsDNA). This enzyme is useful for transcript mapping, removal of single-stranded regions in DNA hybrids or single-stranded overhangs produced by restriction enzymes, etc. It has an activity similar to Nuclease S1, but it has higher specificity for single-stranded molecules.

<span class="mw-page-title-main">Replisome</span> Molecular complex

The replisome is a complex molecular machine that carries out replication of DNA. The replisome first unwinds double stranded DNA into two single strands. For each of the resulting single strands, a new complementary sequence of DNA is synthesized. The total result is formation of two new double stranded DNA sequences that are exact copies of the original double stranded DNA sequence.

<i>Hae</i>III Enzyme

HaeIII is one of many restriction enzymes (endonucleases) a type of prokaryotic DNA that protects organisms from unknown, foreign DNA. It is a restriction enzyme used in molecular biology laboratories. It was the third endonuclease to be isolated from the Haemophilus aegyptius bacteria. The enzyme's recognition site—the place where it cuts DNA molecules—is the GGCC nucleotide sequence which means it cleaves DNA at the site 5′-GG/CC-3. The recognition site is usually around 4-8 bps.This enzyme's gene has been sequenced and cloned. This is done to make DNA fragments in blunt ends. HaeIII is not effective for single stranded DNA cleavage.

SNP genotyping is the measurement of genetic variations of single nucleotide polymorphisms (SNPs) between members of a species. It is a form of genotyping, which is the measurement of more general genetic variation. SNPs are one of the most common types of genetic variation. An SNP is a single base pair mutation at a specific locus, usually consisting of two alleles. SNPs are found to be involved in the etiology of many human diseases and are becoming of particular interest in pharmacogenetics. Because SNPs are conserved during evolution, they have been proposed as markers for use in quantitative trait loci (QTL) analysis and in association studies in place of microsatellites. The use of SNPs is being extended in the HapMap project, which aims to provide the minimal set of SNPs needed to genotype the human genome. SNPs can also provide a genetic fingerprint for use in identity testing. The increase of interest in SNPs has been reflected by the furious development of a diverse range of SNP genotyping methods.

Deoxyribonuclease IV (phage-T4-induced) is catalyzes the degradation nucleotides in DsDNA by attacking the 5'-terminal end.

<i>Bgl</i>II Restriction enzyme

BglII is a type II restriction endonuclease isolated from certain strains of Bacillus globigii.

<span class="mw-page-title-main">Exonuclease 1</span> Protein-coding gene in the species Homo sapiens

Exonuclease 1 is an enzyme that in humans is encoded by the EXO1 gene.

<span class="mw-page-title-main">Very short patch repair</span>

Very short patch (VSP) repair is a DNA repair system that removes GT mismatches created by the deamination of 5-methylcytosine to thymine. This system exists because the glycosylases which normally target deaminated bases cannot target thymine.

DNA ends refer to the properties of the ends of linear DNA molecules, which in molecular biology are described as "sticky" or "blunt" based on the shape of the complementary strands at the terminus. In sticky ends, one strand is longer than the other, such that the longer strand has bases which are left unpaired. In blunt ends, both strands are of equal length – i.e. they end at the same base position, leaving no unpaired bases on either strand.

<span class="mw-page-title-main">Cas9</span> Microbial protein found in Streptococcus pyogenes M1 GAS

Cas9 is a 160 kilodalton protein which plays a vital role in the immunological defense of certain bacteria against DNA viruses and plasmids, and is heavily utilized in genetic engineering applications. Its main function is to cut DNA and thereby alter a cell's genome. The CRISPR-Cas9 genome editing technique was a significant contributor to the Nobel Prize in Chemistry in 2020 being awarded to Emmanuelle Charpentier and Jennifer Doudna.

References

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