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DNA polymerase

January 01, 1970

A DNA polymerase is a member of a family of enzymes that catalyze the synthesis of DNA molecules from nucleoside triphosphates, the molecular precursors of DNA. These enzymes are essential for DNA replication and usually work in groups to create two identical DNA duplexes from a single original DNA duplex. During this process, DNA polymerase "reads" the existing DNA strands to create two new strands that match the existing ones.[1][2][3][4][5][6] These enzymes catalyze the chemical reaction

DNA-directed DNA polymerase
3D structure of the DNA-binding helix-turn-helix motifs in human DNA polymerase beta (based on PDB file 7ICG)
Identifiers
EC no.2.7.7.7
CAS no.9012-90-2
Databases
IntEnzIntEnz view
BRENDABRENDA entry
ExPASyNiceZyme view
KEGGKEGG entry
MetaCycmetabolic pathway
PRIAMprofile
PDB structuresRCSB PDB PDBe PDBsum
Gene OntologyAmiGO / QuickGO
Search
PMCarticles
PubMedarticles
NCBIproteins
deoxynucleoside triphosphate + DNAnpyrophosphate + DNAn+1.

DNA polymerase adds nucleotides to the three prime (3')-end of a DNA strand, one nucleotide at a time. Every time a cell divides, DNA polymerases are required to duplicate the cell's DNA, so that a copy of the original DNA molecule can be passed to each daughter cell. In this way, genetic information is passed down from generation to generation.

Before replication can take place, an enzyme called helicase unwinds the DNA molecule from its tightly woven form, in the process breaking the hydrogen bonds between the nucleotide bases. This opens up or "unzips" the double-stranded DNA to give two single strands of DNA that can be used as templates for replication in the above reaction.

History edit

In 1956, Arthur Kornberg and colleagues discovered DNA polymerase I (Pol I), in Escherichia coli. They described the DNA replication process by which DNA polymerase copies the base sequence of a template DNA strand. Kornberg was later awarded the Nobel Prize in Physiology or Medicine in 1959 for this work.[7] DNA polymerase II was discovered by Thomas Kornberg (the son of Arthur Kornberg) and Malcolm E. Gefter in 1970 while further elucidating the role of Pol I in E. coli DNA replication.[8] Three more DNA polymerases have been found in E. coli, including DNA polymerase III (discovered in the 1970s) and DNA polymerases IV and V (discovered in 1999).[9]

Function edit

 
DNA polymerase moves along the old strand in the 3'–5' direction, creating a new strand having a 5'–3' direction.
 
DNA polymerase with proofreading ability

The main function of DNA polymerase is to synthesize DNA from deoxyribonucleotides, the building blocks of DNA. The DNA copies are created by the pairing of nucleotides to bases present on each strand of the original DNA molecule. This pairing always occurs in specific combinations, with cytosine along with guanine, and thymine along with adenine, forming two separate pairs, respectively. By contrast, RNA polymerases synthesize RNA from ribonucleotides from either RNA or DNA.[citation needed]

When synthesizing new DNA, DNA polymerase can add free nucleotides only to the 3' end of the newly forming strand. This results in elongation of the newly forming strand in a 5'–3' direction.[citation needed]

It is important to note that the directionality of the newly forming strand (the daughter strand) is opposite to the direction in which DNA polymerase moves along the template strand. Since DNA polymerase requires a free 3' OH group for initiation of synthesis, it can synthesize in only one direction by extending the 3' end of the preexisting nucleotide chain. Hence, DNA polymerase moves along the template strand in a 3'–5' direction, and the daughter strand is formed in a 5'–3' direction. This difference enables the resultant double-strand DNA formed to be composed of two DNA strands that are antiparallel to each other.[citation needed]

The function of DNA polymerase is not quite perfect, with the enzyme making about one mistake for every billion base pairs copied. Error correction is a property of some, but not all DNA polymerases. This process corrects mistakes in newly synthesized DNA. When an incorrect base pair is recognized, DNA polymerase moves backwards by one base pair of DNA. The 3'–5' exonuclease activity of the enzyme allows the incorrect base pair to be excised (this activity is known as proofreading). Following base excision, the polymerase can re-insert the correct base and replication can continue forwards. This preserves the integrity of the original DNA strand that is passed onto the daughter cells.

Fidelity is very important in DNA replication. Mismatches in DNA base pairing can potentially result in dysfunctional proteins and could lead to cancer. Many DNA polymerases contain an exonuclease domain, which acts in detecting base pair mismatches and further performs in the removal of the incorrect nucleotide to be replaced by the correct one.[10] The shape and the interactions accommodating the Watson and Crick base pair are what primarily contribute to the detection or error. Hydrogen bonds play a key role in base pair binding and interaction. The loss of an interaction, which occurs at a mismatch, is said to trigger a shift in the balance, for the binding of the template-primer, from the polymerase, to the exonuclease domain. In addition, an incorporation of a wrong nucleotide causes a retard in DNA polymerization. This delay gives time for the DNA to be switched from the polymerase site to the exonuclease site. Different conformational changes and loss of interaction occur at different mismatches. In a purine:pyrimidine mismatch there is a displacement of the pyrimidine towards the major groove and the purine towards the minor groove. Relative to the shape of DNA polymerase's binding pocket, steric clashes occur between the purine and residues in the minor groove, and important van der Waals and electrostatic interactions are lost by the pyrimidine.[11] Pyrimidine:pyrimidine and purine:purine mismatches present less notable changes since the bases are displaced towards the major groove, and less steric hindrance is experienced. However, although the different mismatches result in different steric properties, DNA polymerase is still able to detect and differentiate them so uniformly and maintain fidelity in DNA replication.[12] DNA polymerization is also critical for many mutagenesis processes and is widely employed in biotechnologies.

Structure edit

The known DNA polymerases have highly conserved structure, which means that their overall catalytic subunits vary very little from species to species, independent of their domain structures. Conserved structures usually indicate important, irreplaceable functions of the cell, the maintenance of which provides evolutionary advantages. The shape can be described as resembling a right hand with thumb, finger, and palm domains. The palm domain appears to function in catalyzing the transfer of phosphoryl groups in the phosphoryl transfer reaction. DNA is bound to the palm when the enzyme is active. This reaction is believed to be catalyzed by a two-metal-ion mechanism. The finger domain functions to bind the nucleoside triphosphates with the template base. The thumb domain plays a potential role n the processivity, translocation, and positioning of the DNA.[13]

Processivity edit

DNA polymerase's rapid catalysis due to its processie nature. Processivity is a characteristic of enzymes that function on polymeric substrates. In the case of DNA polymerase, the degree of processivity refers to the average number of nucleotides added each time the enzyme binds a template. The average DNA polymerase requires about one second locating and binding a primer/template junction. Once it is bound, a nonprocessive DNA polymerase adds nucleotides at a rate of one nucleotide per second.[14]: 207–208  Processive DNA polymerases, however, add multiple nucleotides per second, drastically increasing the rate of DNA synthesis. The degree of processivity is directly proportional to the rate of DNA synthesis. The rate of DNA synthesis in a living cell was first determined as the rate of phage T4 DNA elongation in phage infected E. coli. During the period of exponential DNA increase at 37 °C, the rate was 749 nucleotides per second.[15]

DNA polymerase's ability to slide along the DNA template allows increased processivity. There is a dramatic increase in processivity at the replication fork. This increase is facilitated by the DNA polymerase's association with proteins known as the sliding DNA clamp. The clamps are multiple protein subunits associated in the shape of a ring. Using the hydrolysis of ATP, a class of proteins known as the sliding clamp loading proteins open up the ring structure of the sliding DNA clamps allowing binding to and release from the DNA strand. Protein–protein interaction with the clamp prevents DNA polymerase from diffusing from the DNA template, thereby ensuring that the enzyme binds the same primer/template junction and continues replication.[14]: 207–208  DNA polymerase changes conformation, increasing affinity to the clamp when associated with it and decreasing affinity when it completes the replication of a stretch of DNA to allow release from the clamp.[citation needed]

DNA polymerase processivity has been studied with in vitro single-molecule experiments (namely, optical tweezers and magnetic tweezers) have revealed the synergies between DNA polymerases and other molecules of the replisome (helicases and SSBs) and with the DNA replication fork.[16] These results have led to the development of synergetic kinetic models for DNA replication describing the resulting DNA polymerase processivity increase.[16]

Variation across species edit

DNA polymerase family A
 
c:o6-methyl-guanine pair in the polymerase-2 basepair position
Identifiers
SymbolDNA_pol_A
PfamPF00476
InterProIPR001098
SMART-
PROSITEPDOC00412
SCOP21dpi / SCOPe / SUPFAM
Available protein structures:
Pfam  structures / ECOD  
PDBRCSB PDB; PDBe; PDBj
PDBsumstructure summary
DNA polymerase family B
 
crystal structure of rb69 gp43 in complex with dna containing thymine glycol
Identifiers
SymbolDNA_pol_B
PfamPF00136
Pfam clanCL0194
InterProIPR006134
PROSITEPDOC00107
SCOP21noy / SCOPe / SUPFAM
Available protein structures:
Pfam  structures / ECOD  
PDBRCSB PDB; PDBe; PDBj
PDBsumstructure summary
DNA polymerase type B, organellar and viral
 
phi29 dna polymerase, orthorhombic crystal form, ssdna complex
Identifiers
SymbolDNA_pol_B_2
PfamPF03175
Pfam clanCL0194
InterProIPR004868
Available protein structures:
Pfam  structures / ECOD  
PDBRCSB PDB; PDBe; PDBj
PDBsumstructure summary

Based on sequence homology, DNA polymerases can be further subdivided into seven different families: A, B, C, D, X, Y, and RT.

Some viruses also encode special DNA polymerases, such as Hepatitis B virus DNA polymerase. These may selectively replicate viral DNA through a variety of mechanisms. Retroviruses encode an unusual DNA polymerase called reverse transcriptase, which is an RNA-dependent DNA polymerase (RdDp). It polymerizes DNA from a template of RNA.

Family[17] Types of DNA polymerase Taxa Examples Feature
A Replicative and Repair Polymerases Eukaryotic and Prokaryotic T7 DNA polymerase, Pol I, Pol γ, θ, and ν Two exonuclease domains (3'-5' and 5'-3')
B Replicative and Repair Polymerases Eukaryotic and Prokaryotic Pol II, Pol B, Pol ζ, Pol α, δ, and ε 3'-5 exonuclease (proofreading); some viral polymerases use protein primers
C Replicative Polymerases Prokaryotic Pol III 3'-5 exonuclease (proofreading)
D Replicative Polymerases Euryarchaeota PolD (DP1/DP2 heterodimer)[18] No "hand" feature, double barrel RNA polymerase-like; 3'-5 exonuclease (proofreading)
X Replicative and Repair Polymerases Eukaryotic Pol β, Pol σ, Pol λ, Pol μ, and terminal deoxynucleotidyl transferase template optional; 5' phosphatase (only Pol β); weak "hand" feature
Y Replicative and Repair Polymerases Eukaryotic and Prokaryotic Pol ι, Pol κ, Pol η,[19] Pol IV, and Pol V Translesion synthesis[20]
RT Replicative and Repair Polymerases Viruses, Retroviruses, and Eukaryotic Telomerase, Hepatitis B virus RNA-dependent

Prokaryotic polymerase edit

Prokaryotic polymerases exist in two forms: core polymerase and holoenzyme. Core polymerase synthesizes DNA from the DNA template but it cannot initiate the synthesis alone or accurately. Holoenzyme accurately initiates synthesis.

Pol I edit

Prokaryotic family A polymerases include the DNA polymerase I (Pol I) enzyme, which is encoded by the polA gene and ubiquitous among prokaryotes. This repair polymerase is involved in excision repair with both 3'–5' and 5'–3' exonuclease activity and processing of Okazaki fragments generated during lagging strand synthesis.[21] Pol I is the most abundant polymerase, accounting for >95% of polymerase activity in E. coli; yet cells lacking Pol I have been found suggesting Pol I activity can be replaced by the other four polymerases. Pol I adds ~15-20 nucleotides per second, thus showing poor processivity. Instead, Pol I starts adding nucleotides at the RNA primer:template junction known as the origin of replication (ori). Approximately 400 bp downstream from the origin, the Pol III holoenzyme is assembled and takes over replication at a highly processive speed and nature.[22]

Taq polymerase is a heat-stable enzyme of this family that lacks proofreading ability.[23]

Pol II edit

DNA polymerase II is a family B polymerase encoded by the polB gene. Pol II has 3'–5' exonuclease activity and participates in DNA repair, replication restart to bypass lesions, and its cell presence can jump from ~30-50 copies per cell to ~200–300 during SOS induction. Pol II is also thought to be a backup to Pol III as it can interact with holoenzyme proteins and assume a high level of processivity. The main role of Pol II is thought to be the ability to direct polymerase activity at the replication fork and help stalled Pol III bypass terminal mismatches.[24]

Pfu DNA polymerase is a heat-stable enzyme of this family found in the hyperthermophilic archaeon Pyrococcus furiosus.[25] Detailed classification divides family B in archaea into B1, B2, B3, in which B2 is a group of pseudoenzymes. Pfu belongs to family B3. Others PolBs found in archaea are part of "Casposons", Cas1-dependent transposons.[26] Some viruses (including Φ29 DNA polymerase) and mitochondrial plasmids carry polB as well.[27]

Pol III edit

DNA polymerase III holoenzyme is the primary enzyme involved in DNA replication in E. coli and belongs to family C polymerases. It consists of three assemblies: the pol III core, the beta sliding clamp processivity factor, and the clamp-loading complex. The core consists of three subunits: α, the polymerase activity hub, ɛ, exonucleolytic proofreader, and θ, which may act as a stabilizer for ɛ. The beta sliding clamp processivity factor is also present in duplicate, one for each core, to create a clamp that encloses DNA allowing for high processivity.[28] The third assembly is a seven-subunit (τ2γδδχψ) clamp loader complex.

The old textbook "trombone model" depicts an elongation complex with two equivalents of the core enzyme at each replication fork (RF), one for each strand, the lagging and leading.[24] However, recent evidence from single-molecule studies indicates an average of three stoichiometric equivalents of core enzyme at each RF for both Pol III and its counterpart in B. subtilis, PolC.[29] In-cell fluorescent microscopy has revealed that leading strand synthesis may not be completely continuous, and Pol III* (i.e., the holoenzyme α, ε, τ, δ and χ subunits without the ß2 sliding clamp) has a high frequency of dissociation from active RFs.[30] In these studies, the replication fork turnover rate was about 10s for Pol III*, 47s for the ß2 sliding clamp, and 15m for the DnaB helicase. This suggests that the DnaB helicase may remain stably associated at RFs and serve as a nucleation point for the competent holoenzyme. In vitro single-molecule studies have shown that Pol III* has a high rate of RF turnover when in excess, but remains stably associated with replication forks when concentration is limiting.[30] Another single-molecule study showed that DnaB helicase activity and strand elongation can proceed with decoupled, stochastic kinetics.[30]

Pol IV edit

In E. coli, DNA polymerase IV (Pol IV) is an error-prone DNA polymerase involved in non-targeted mutagenesis.[31] Pol IV is a Family Y polymerase expressed by the dinB gene that is switched on via SOS induction caused by stalled polymerases at the replication fork. During SOS induction, Pol IV production is increased tenfold and one of the functions during this time is to interfere with Pol III holoenzyme processivity. This creates a checkpoint, stops replication, and allows time to repair DNA lesions via the appropriate repair pathway.[32] Another function of Pol IV is to perform translesion synthesis at the stalled replication fork like, for example, bypassing N2-deoxyguanine adducts at a faster rate than transversing undamaged DNA. Cells lacking the dinB gene have a higher rate of mutagenesis caused by DNA damaging agents.[33]

Pol V edit

DNA polymerase V (Pol V) is a Y-family DNA polymerase that is involved in SOS response and translesion synthesis DNA repair mechanisms.[34] Transcription of Pol V via the umuDC genes is highly regulated to produce only Pol V when damaged DNA is present in the cell generating an SOS response. Stalled polymerases causes RecA to bind to the ssDNA, which causes the LexA protein to autodigest. LexA then loses its ability to repress the transcription of the umuDC operon. The same RecA-ssDNA nucleoprotein posttranslationally modifies the UmuD protein into UmuD' protein. UmuD and UmuD' form a heterodimer that interacts with UmuC, which in turn activates umuC's polymerase catalytic activity on damaged DNA.[35] In E. coli, a polymerase "tool belt" model for switching pol III with pol IV at a stalled replication fork, where both polymerases bind simultaneously to the β-clamp, has been proposed.[36] However, the involvement of more than one TLS polymerase working in succession to bypass a lesion has not yet been shown in E. coli. Moreover, Pol IV can catalyze both insertion and extension with high efficiency, whereas pol V is considered the major SOS TLS polymerase. One example is the bypass of intra strand guanine thymine cross-link where it was shown on the basis of the difference in the mutational signatures of the two polymerases, that pol IV and pol V compete for TLS of the intra-strand crosslink.[36]

Family D edit

 
Structures of archaeal polD and eukaryotic Polα. Not only is the general topology conserved, the two also share a bifunctional primase-and-PCNA-binding PIP-box sequence on the C-terminus, similar to both eukaryotic Polα and Polε.[37]

In 1998, the family D of DNA polymerase was discovered in Pyrococcus furiosus and Methanococcus jannaschii.[38] The PolD complex is a heterodimer of two chains, each encoded by DP1 (small proofreading) and DP2 (large catalytic). Unlike other DNA polymerases, the structure and mechanism of the DP2 catalytic core resemble that of multi-subunit RNA polymerases. The DP1-DP2 interface resembles that of Eukaryotic Class B polymerase zinc finger and its small subunit.[18] DP1, a Mre11-like exonuclease,[39] is likely the precursor of small subunit of Pol α and ε, providing proofreading capabilities now lost in Eukaryotes.[26] Its N-terminal HSH domain is similar to AAA proteins, especially Pol III subunit δ and RuvB, in structure.[40] DP2 has a Class II KH domain.[18] Pyrococcus abyssi polD is more heat-stable and more accurate than Taq polymerase, but has not yet been commercialized.[41] It has been proposed that family D DNA polymerase was the first to evolve in cellular organisms and that the replicative polymerase of the Last Universal Cellular Ancestor (LUCA) belonged to family D.[42]

Eukaryotic DNA polymerase edit

Polymerases β, λ, σ, μ (beta, lambda, sigma, mu) and TdT edit

Family X polymerases contain the well-known eukaryotic polymerase pol β (beta), as well as other eukaryotic polymerases such as Pol σ (sigma), Pol λ (lambda), Pol μ (mu), and Terminal deoxynucleotidyl transferase (TdT). Family X polymerases are found mainly in vertebrates, and a few are found in plants and fungi. These polymerases have highly conserved regions that include two helix-hairpin-helix motifs that are imperative in the DNA-polymerase interactions. One motif is located in the 8 kDa domain that interacts with downstream DNA and one motif is located in the thumb domain that interacts with the primer strand. Pol β, encoded by POLB gene, is required for short-patch base excision repair, a DNA repair pathway that is essential for repairing alkylated or oxidized bases as well as abasic sites. Pol λ and Pol μ, encoded by the POLL and POLM genes respectively, are involved in non-homologous end-joining, a mechanism for rejoining DNA double-strand breaks due to hydrogen peroxide and ionizing radiation, respectively. TdT is expressed only in lymphoid tissue, and adds "n nucleotides" to double-strand breaks formed during V(D)J recombination to promote immunological diversity.[43]

Polymerases α, δ and ε (alpha, delta, and epsilon) edit

Pol α (alpha), Pol δ (delta), and Pol ε (epsilon) are members of Family B Polymerases and are the main polymerases involved with nuclear DNA replication. Pol α complex (pol α-DNA primase complex) consists of four subunits: the catalytic subunit POLA1, the regulatory subunit POLA2, and the small and the large primase subunits PRIM1 and PRIM2 respectively. Once primase has created the RNA primer, Pol α starts replication elongating the primer with ~20 nucleotides.[44] Due to its high processivity, Pol δ takes over the leading and lagging strand synthesis from Pol α.[14]: 218–219  Pol δ is expressed by genes POLD1, creating the catalytic subunit, POLD2, POLD3, and POLD4 creating the other subunits that interact with Proliferating Cell Nuclear Antigen (PCNA), which is a DNA clamp that allows Pol δ to possess processivity.[45] Pol ε is encoded by the POLE1, the catalytic subunit, POLE2, and POLE3 gene. It has been reported that the function of Pol ε is to extend the leading strand during replication,[46][47] while Pol δ primarily replicates the lagging strand; however, recent evidence suggested that Pol δ might have a role in replicating the leading strand of DNA as well.[48] Pol ε's C-terminus "polymerase relic" region, despite being unnecessary for polymerase activity,[49] is thought to be essential to cell vitality. The C-terminus region is thought to provide a checkpoint before entering anaphase, provide stability to the holoenzyme, and add proteins to the holoenzyme necessary for initiation of replication.[50] Pol ε has a larger "palm" domain that provides high processivity independently of PCNA.[49]

Compared to other Family B polymerases, the DEDD exonuclease family responsible for proofreading is inactivated in Pol α.[26] Pol ε is unique in that it has two zinc finger domains and an inactive copy of another family B polymerase in its C-terminal. The presence of this zinc finger has implications in the origins of Eukaryota, which in this case is placed into the Asgard group with archaeal B3 polymerase.[51]

Polymerases η, ι and κ (eta, iota, and kappa) edit

Pol η (eta), Pol ι (iota), and Pol κ (kappa), are Family Y DNA polymerases involved in the DNA repair by translation synthesis and encoded by genes POLH, POLI, and POLK respectively. Members of Family Y have five common motifs to aid in binding the substrate and primer terminus and they all include the typical right hand thumb, palm and finger domains with added domains like little finger (LF), polymerase-associated domain (PAD), or wrist. The active site, however, differs between family members due to the different lesions being repaired. Polymerases in Family Y are low-fidelity polymerases, but have been proven to do more good than harm as mutations that affect the polymerase can cause various diseases, such as skin cancer and Xeroderma Pigmentosum Variant (XPS). The importance of these polymerases is evidenced by the fact that gene encoding DNA polymerase η is referred as XPV, because loss of this gene results in the disease Xeroderma Pigmentosum Variant. Pol η is particularly important for allowing accurate translesion synthesis of DNA damage resulting from ultraviolet radiation. The functionality of Pol κ is not completely understood, but researchers have found two probable functions. Pol κ is thought to act as an extender or an inserter of a specific base at certain DNA lesions. All three translesion synthesis polymerases, along with Rev1, are recruited to damaged lesions via stalled replicative DNA polymerases. There are two pathways of damage repair leading researchers to conclude that the chosen pathway depends on which strand contains the damage, the leading or lagging strand.[52]

Polymerases Rev1 and ζ (zeta) edit

Pol ζ another B family polymerase, is made of two subunits Rev3, the catalytic subunit, and Rev7 (MAD2L2), which increases the catalytic function of the polymerase, and is involved in translesion synthesis. Pol ζ lacks 3' to 5' exonuclease activity, is unique in that it can extend primers with terminal mismatches. Rev1 has three regions of interest in the BRCT domain, ubiquitin-binding domain, and C-terminal domain and has dCMP transferase ability, which adds deoxycytidine opposite lesions that would stall replicative polymerases Pol δ and Pol ε. These stalled polymerases activate ubiquitin complexes that in turn disassociate replication polymerases and recruit Pol ζ and Rev1. Together Pol ζ and Rev1 add deoxycytidine and Pol ζ extends past the lesion. Through a yet undetermined process, Pol ζ disassociates and replication polymerases reassociate and continue replication. Pol ζ and Rev1 are not required for replication, but loss of REV3 gene in budding yeast can cause increased sensitivity to DNA-damaging agents due to collapse of replication forks where replication polymerases have stalled.[53]

Telomerase edit

Telomerase is a ribonucleoprotein which functions to replicate ends of linear chromosomes since normal DNA polymerase cannot replicate the ends, or telomeres. The single-strand 3' overhang of the double-strand chromosome with the sequence 5'-TTAGGG-3' recruits telomerase. Telomerase acts like other DNA polymerases by extending the 3' end, but, unlike other DNA polymerases, telomerase does not require a template. The TERT subunit, an example of a reverse transcriptase, uses the RNA subunit to form the primer–template junction that allows telomerase to extend the 3' end of chromosome ends. The gradual decrease in size of telomeres as the result of many replications over a lifetime are thought to be associated with the effects of aging.[14]: 248–249 

Polymerases γ, θ and ν (gamma, theta and nu) edit

Further information: DNA polymerase nu

Pol γ (gamma), Pol θ (theta), and Pol ν (nu) are Family A polymerases. Pol γ, encoded by the POLG gene, was long thought to be the only mitochondrial polymerase. However, recent research shows that at least Pol β (beta), a Family X polymerase, is also present in mitochondria.[54][55] Any mutation that leads to limited or non-functioning Pol γ has a significant effect on mtDNA and is the most common cause of autosomal inherited mitochondrial disorders.[56] Pol γ contains a C-terminus polymerase domain and an N-terminus 3'–5' exonuclease domain that are connected via the linker region, which binds the accessory subunit. The accessory subunit binds DNA and is required for processivity of Pol γ. Point mutation A467T in the linker region is responsible for more than one-third of all Pol γ-associated mitochondrial disorders.[57] While many homologs of Pol θ, encoded by the POLQ gene, are found in eukaryotes, its function is not clearly understood. The sequence of amino acids in the C-terminus is what classifies Pol θ as Family A polymerase, although the error rate for Pol θ is more closely related to Family Y polymerases. Pol θ extends mismatched primer termini and can bypass abasic sites by adding a nucleotide. It also has Deoxyribophosphodiesterase (dRPase) activity in the polymerase domain and can show ATPase activity in close proximity to ssDNA.[58] Pol ν (nu) is considered to be the least effective of the polymerase enzymes.[59] However, DNA polymerase nu plays an active role in homology repair during cellular responses to crosslinks, fulfilling its role in a complex with helicase.[59]

Plants use two Family A polymerases to copy both the mitochondrial and plastid genomes. They are more similar to bacterial Pol I than they are to mammalian Pol γ.[60]

Reverse transcriptase edit

Retroviruses encode an unusual DNA polymerase called reverse transcriptase, which is an RNA-dependent DNA polymerase (RdDp) that synthesizes DNA from a template of RNA. The reverse transcriptase family contain both DNA polymerase functionality and RNase H functionality, which degrades RNA base-paired to DNA. An example of a retrovirus is HIV.[14] Reverse transcriptase is commonly employed in amplification of RNA for research purposes. Using an RNA template, PCR can utilize reverse transcriptase, creating a DNA template. This new DNA template can then be used for typical PCR amplification. The products of such an experiment are thus amplified PCR products from RNA.[9]

Each HIV retrovirus particle contains two RNA genomes, but, after an infection, each virus generates only one provirus.[61] After infection, reverse transcription is accompanied by template switching between the two genome copies (copy choice recombination).[61] From 5 to 14 recombination events per genome occur at each replication cycle.[62] Template switching (recombination) appears to be necessary for maintaining genome integrity and as a repair mechanism for salvaging damaged genomes.[63][61]

Bacteriophage T4 DNA polymerase edit

Bacteriophage (phage) T4 encodes a DNA polymerase that catalyzes DNA synthesis in a 5' to 3' direction.[64] The phage polymerase also has an exonuclease activity that acts in a 3' to 5' direction,[65] and this activity is employed in the proofreading and editing of newly inserted bases.[66] A phage mutant with a temperature sensitive DNA polymerase, when grown at permissive temperatures, was observed to undergo recombination at frequencies that are about two-fold higher than that of wild-type phage.[67]

It was proposed that a mutational alteration in the phage DNA polymerase can stimulate template strand switching (copy choice recombination) during replication.[67]

See also edit

References edit

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  2. ^ Falaschi A, Kornberg A (April 1966). "Biochemical studies of bacterial sporulation. II. Deoxy- ribonucleic acid polymerase in spores of Bacillus subtilis". The Journal of Biological Chemistry. 241 (7): 1478–1482. doi:10.1016/S0021-9258(18)96736-0. PMID 4957767.
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Further reading edit

  • Burgers PM, Koonin EV, Bruford E, Blanco L, Burtis KC, Christman MF, et al. (November 2001). "Eukaryotic DNA polymerases: proposal for a revised nomenclature". The Journal of Biological Chemistry. 276 (47): 43487–43490. doi:10.1074/jbc.R100056200. hdl:10261/338658. PMID 11579108.

External links edit

 
Wikimedia Commons has media related to DNA polymerases.
  • DNA+polymerases at the U.S. National Library of Medicine Medical Subject Headings (MeSH)
  • PDB Molecule of the Month DNA polymerase
  • , Ohio State University, July 25, 2006.
  • A great animation of DNA Polymerase from WEHI at 1:45 minutes in 2014-12-05 at the Wayback Machine
  • 3D macromolecular structures of DNA polymerase from the EM Data Bank(EMDB)

January 01, 1970
polymerase, member, family, enzymes, that, catalyze, synthesis, molecules, from, nucleoside, triphosphates, molecular, precursors, these, enzymes, essential, replication, usually, work, groups, create, identical, duplexes, from, single, original, duplex, durin. A DNA polymerase is a member of a family of enzymes that catalyze the synthesis of DNA molecules from nucleoside triphosphates the molecular precursors of DNA These enzymes are essential for DNA replication and usually work in groups to create two identical DNA duplexes from a single original DNA duplex During this process DNA polymerase reads the existing DNA strands to create two new strands that match the existing ones 1 2 3 4 5 6 These enzymes catalyze the chemical reactionDNA directed DNA polymerase3D structure of the DNA binding helix turn helix motifs in human DNA polymerase beta based on PDB file 7ICG IdentifiersEC no 2 7 7 7CAS no 9012 90 2DatabasesIntEnzIntEnz viewBRENDABRENDA entryExPASyNiceZyme viewKEGGKEGG entryMetaCycmetabolic pathwayPRIAMprofilePDB structuresRCSB PDB PDBe PDBsumGene OntologyAmiGO QuickGOSearchPMCarticlesPubMedarticlesNCBIproteins deoxynucleoside triphosphate DNAn pyrophosphate DNAn 1 DNA polymerase adds nucleotides to the three prime 3 end of a DNA strand one nucleotide at a time Every time a cell divides DNA polymerases are required to duplicate the cell s DNA so that a copy of the original DNA molecule can be passed to each daughter cell In this way genetic information is passed down from generation to generation Before replication can take place an enzyme called helicase unwinds the DNA molecule from its tightly woven form in the process breaking the hydrogen bonds between the nucleotide bases This opens up or unzips the double stranded DNA to give two single strands of DNA that can be used as templates for replication in the above reaction Contents 1 History 2 Function 2 1 Structure 2 2 Processivity 3 Variation across species 3 1 Prokaryotic polymerase 3 1 1 Pol I 3 1 2 Pol II 3 1 3 Pol III 3 1 4 Pol IV 3 1 5 Pol V 3 1 6 Family D 3 2 Eukaryotic DNA polymerase 3 2 1 Polymerases b l s m beta lambda sigma mu and TdT 3 2 2 Polymerases a d and e alpha delta and epsilon 3 2 3 Polymerases h i and k eta iota and kappa 3 2 4 Polymerases Rev1 and z zeta 3 2 5 Telomerase 3 2 6 Polymerases g 8 and n gamma theta and nu 3 2 7 Reverse transcriptase 3 3 Bacteriophage T4 DNA polymerase 4 See also 5 References 6 Further reading 7 External linksHistory editIn 1956 Arthur Kornberg and colleagues discovered DNA polymerase I Pol I in Escherichia coli They described the DNA replication process by which DNA polymerase copies the base sequence of a template DNA strand Kornberg was later awarded the Nobel Prize in Physiology or Medicine in 1959 for this work 7 DNA polymerase II was discovered by Thomas Kornberg the son of Arthur Kornberg and Malcolm E Gefter in 1970 while further elucidating the role of Pol I in E coli DNA replication 8 Three more DNA polymerases have been found in E coli including DNA polymerase III discovered in the 1970s and DNA polymerases IV and V discovered in 1999 9 Function edit nbsp DNA polymerase moves along the old strand in the 3 5 direction creating a new strand having a 5 3 direction nbsp DNA polymerase with proofreading ability The main function of DNA polymerase is to synthesize DNA from deoxyribonucleotides the building blocks of DNA The DNA copies are created by the pairing of nucleotides to bases present on each strand of the original DNA molecule This pairing always occurs in specific combinations with cytosine along with guanine and thymine along with adenine forming two separate pairs respectively By contrast RNA polymerases synthesize RNA from ribonucleotides from either RNA or DNA citation needed When synthesizing new DNA DNA polymerase can add free nucleotides only to the 3 end of the newly forming strand This results in elongation of the newly forming strand in a 5 3 direction citation needed It is important to note that the directionality of the newly forming strand the daughter strand is opposite to the direction in which DNA polymerase moves along the template strand Since DNA polymerase requires a free 3 OH group for initiation of synthesis it can synthesize in only one direction by extending the 3 end of the preexisting nucleotide chain Hence DNA polymerase moves along the template strand in a 3 5 direction and the daughter strand is formed in a 5 3 direction This difference enables the resultant double strand DNA formed to be composed of two DNA strands that are antiparallel to each other citation needed The function of DNA polymerase is not quite perfect with the enzyme making about one mistake for every billion base pairs copied Error correction is a property of some but not all DNA polymerases This process corrects mistakes in newly synthesized DNA When an incorrect base pair is recognized DNA polymerase moves backwards by one base pair of DNA The 3 5 exonuclease activity of the enzyme allows the incorrect base pair to be excised this activity is known as proofreading Following base excision the polymerase can re insert the correct base and replication can continue forwards This preserves the integrity of the original DNA strand that is passed onto the daughter cells Fidelity is very important in DNA replication Mismatches in DNA base pairing can potentially result in dysfunctional proteins and could lead to cancer Many DNA polymerases contain an exonuclease domain which acts in detecting base pair mismatches and further performs in the removal of the incorrect nucleotide to be replaced by the correct one 10 The shape and the interactions accommodating the Watson and Crick base pair are what primarily contribute to the detection or error Hydrogen bonds play a key role in base pair binding and interaction The loss of an interaction which occurs at a mismatch is said to trigger a shift in the balance for the binding of the template primer from the polymerase to the exonuclease domain In addition an incorporation of a wrong nucleotide causes a retard in DNA polymerization This delay gives time for the DNA to be switched from the polymerase site to the exonuclease site Different conformational changes and loss of interaction occur at different mismatches In a purine pyrimidine mismatch there is a displacement of the pyrimidine towards the major groove and the purine towards the minor groove Relative to the shape of DNA polymerase s binding pocket steric clashes occur between the purine and residues in the minor groove and important van der Waals and electrostatic interactions are lost by the pyrimidine 11 Pyrimidine pyrimidine and purine purine mismatches present less notable changes since the bases are displaced towards the major groove and less steric hindrance is experienced However although the different mismatches result in different steric properties DNA polymerase is still able to detect and differentiate them so uniformly and maintain fidelity in DNA replication 12 DNA polymerization is also critical for many mutagenesis processes and is widely employed in biotechnologies Structure edit The known DNA polymerases have highly conserved structure which means that their overall catalytic subunits vary very little from species to species independent of their domain structures Conserved structures usually indicate important irreplaceable functions of the cell the maintenance of which provides evolutionary advantages The shape can be described as resembling a right hand with thumb finger and palm domains The palm domain appears to function in catalyzing the transfer of phosphoryl groups in the phosphoryl transfer reaction DNA is bound to the palm when the enzyme is active This reaction is believed to be catalyzed by a two metal ion mechanism The finger domain functions to bind the nucleoside triphosphates with the template base The thumb domain plays a potential role n the processivity translocation and positioning of the DNA 13 Processivity edit DNA polymerase s rapid catalysis due to its processie nature Processivity is a characteristic of enzymes that function on polymeric substrates In the case of DNA polymerase the degree of processivity refers to the average number of nucleotides added each time the enzyme binds a template The average DNA polymerase requires about one second locating and binding a primer template junction Once it is bound a nonprocessive DNA polymerase adds nucleotides at a rate of one nucleotide per second 14 207 208 Processive DNA polymerases however add multiple nucleotides per second drastically increasing the rate of DNA synthesis The degree of processivity is directly proportional to the rate of DNA synthesis The rate of DNA synthesis in a living cell was first determined as the rate of phage T4 DNA elongation in phage infected E coli During the period of exponential DNA increase at 37 C the rate was 749 nucleotides per second 15 DNA polymerase s ability to slide along the DNA template allows increased processivity There is a dramatic increase in processivity at the replication fork This increase is facilitated by the DNA polymerase s association with proteins known as the sliding DNA clamp The clamps are multiple protein subunits associated in the shape of a ring Using the hydrolysis of ATP a class of proteins known as the sliding clamp loading proteins open up the ring structure of the sliding DNA clamps allowing binding to and release from the DNA strand Protein protein interaction with the clamp prevents DNA polymerase from diffusing from the DNA template thereby ensuring that the enzyme binds the same primer template junction and continues replication 14 207 208 DNA polymerase changes conformation increasing affinity to the clamp when associated with it and decreasing affinity when it completes the replication of a stretch of DNA to allow release from the clamp citation needed DNA polymerase processivity has been studied with in vitro single molecule experiments namely optical tweezers and magnetic tweezers have revealed the synergies between DNA polymerases and other molecules of the replisome helicases and SSBs and with the DNA replication fork 16 These results have led to the development of synergetic kinetic models for DNA replication describing the resulting DNA polymerase processivity increase 16 Variation across species editDNA polymerase family A nbsp c o6 methyl guanine pair in the polymerase 2 basepair positionIdentifiersSymbolDNA pol APfamPF00476InterProIPR001098SMART PROSITEPDOC00412SCOP21dpi SCOPe SUPFAMAvailable protein structures Pfam structures ECOD PDBRCSB PDB PDBe PDBjPDBsumstructure summary DNA polymerase family B nbsp crystal structure of rb69 gp43 in complex with dna containing thymine glycolIdentifiersSymbolDNA pol BPfamPF00136Pfam clanCL0194InterProIPR006134PROSITEPDOC00107SCOP21noy SCOPe SUPFAMAvailable protein structures Pfam structures ECOD PDBRCSB PDB PDBe PDBjPDBsumstructure summary DNA polymerase type B organellar and viral nbsp phi29 dna polymerase orthorhombic crystal form ssdna complexIdentifiersSymbolDNA pol B 2PfamPF03175Pfam clanCL0194InterProIPR004868Available protein structures Pfam structures ECOD PDBRCSB PDB PDBe PDBjPDBsumstructure summary Based on sequence homology DNA polymerases can be further subdivided into seven different families A B C D X Y and RT Some viruses also encode special DNA polymerases such as Hepatitis B virus DNA polymerase These may selectively replicate viral DNA through a variety of mechanisms Retroviruses encode an unusual DNA polymerase called reverse transcriptase which is an RNA dependent DNA polymerase RdDp It polymerizes DNA from a template of RNA Family 17 Types of DNA polymerase Taxa Examples Feature A Replicative and Repair Polymerases Eukaryotic and Prokaryotic T7 DNA polymerase Pol I Pol g 8 and n Two exonuclease domains 3 5 and 5 3 B Replicative and Repair Polymerases Eukaryotic and Prokaryotic Pol II Pol B Pol z Pol a d and e 3 5 exonuclease proofreading some viral polymerases use protein primers C Replicative Polymerases Prokaryotic Pol III 3 5 exonuclease proofreading D Replicative Polymerases Euryarchaeota PolD DP1 DP2 heterodimer 18 No hand feature double barrel RNA polymerase like 3 5 exonuclease proofreading X Replicative and Repair Polymerases Eukaryotic Pol b Pol s Pol l Pol m and terminal deoxynucleotidyl transferase template optional 5 phosphatase only Pol b weak hand feature Y Replicative and Repair Polymerases Eukaryotic and Prokaryotic Pol i Pol k Pol h 19 Pol IV and Pol V Translesion synthesis 20 RT Replicative and Repair Polymerases Viruses Retroviruses and Eukaryotic Telomerase Hepatitis B virus RNA dependent Prokaryotic polymerase edit Prokaryotic polymerases exist in two forms core polymerase and holoenzyme Core polymerase synthesizes DNA from the DNA template but it cannot initiate the synthesis alone or accurately Holoenzyme accurately initiates synthesis Pol I edit Prokaryotic family A polymerases include the DNA polymerase I Pol I enzyme which is encoded by the polA gene and ubiquitous among prokaryotes This repair polymerase is involved in excision repair with both 3 5 and 5 3 exonuclease activity and processing of Okazaki fragments generated during lagging strand synthesis 21 Pol I is the most abundant polymerase accounting for gt 95 of polymerase activity in E coli yet cells lacking Pol I have been found suggesting Pol I activity can be replaced by the other four polymerases Pol I adds 15 20 nucleotides per second thus showing poor processivity Instead Pol I starts adding nucleotides at the RNA primer template junction known as the origin of replication ori Approximately 400 bp downstream from the origin the Pol III holoenzyme is assembled and takes over replication at a highly processive speed and nature 22 Taq polymerase is a heat stable enzyme of this family that lacks proofreading ability 23 Pol II edit DNA polymerase II is a family B polymerase encoded by the polB gene Pol II has 3 5 exonuclease activity and participates in DNA repair replication restart to bypass lesions and its cell presence can jump from 30 50 copies per cell to 200 300 during SOS induction Pol II is also thought to be a backup to Pol III as it can interact with holoenzyme proteins and assume a high level of processivity The main role of Pol II is thought to be the ability to direct polymerase activity at the replication fork and help stalled Pol III bypass terminal mismatches 24 Pfu DNA polymerase is a heat stable enzyme of this family found in the hyperthermophilic archaeon Pyrococcus furiosus 25 Detailed classification divides family B in archaea into B1 B2 B3 in which B2 is a group of pseudoenzymes Pfu belongs to family B3 Others PolBs found in archaea are part of Casposons Cas1 dependent transposons 26 Some viruses including F29 DNA polymerase and mitochondrial plasmids carry polB as well 27 Pol III edit DNA polymerase III holoenzyme is the primary enzyme involved in DNA replication in E coli and belongs to family C polymerases It consists of three assemblies the pol III core the beta sliding clamp processivity factor and the clamp loading complex The core consists of three subunits a the polymerase activity hub ɛ exonucleolytic proofreader and 8 which may act as a stabilizer for ɛ The beta sliding clamp processivity factor is also present in duplicate one for each core to create a clamp that encloses DNA allowing for high processivity 28 The third assembly is a seven subunit t2gdd xps clamp loader complex The old textbook trombone model depicts an elongation complex with two equivalents of the core enzyme at each replication fork RF one for each strand the lagging and leading 24 However recent evidence from single molecule studies indicates an average of three stoichiometric equivalents of core enzyme at each RF for both Pol III and its counterpart in B subtilis PolC 29 In cell fluorescent microscopy has revealed that leading strand synthesis may not be completely continuous and Pol III i e the holoenzyme a e t d and x subunits without the ss2 sliding clamp has a high frequency of dissociation from active RFs 30 In these studies the replication fork turnover rate was about 10s for Pol III 47s for the ss2 sliding clamp and 15m for the DnaB helicase This suggests that the DnaB helicase may remain stably associated at RFs and serve as a nucleation point for the competent holoenzyme In vitro single molecule studies have shown that Pol III has a high rate of RF turnover when in excess but remains stably associated with replication forks when concentration is limiting 30 Another single molecule study showed that DnaB helicase activity and strand elongation can proceed with decoupled stochastic kinetics 30 Pol IV edit In E coli DNA polymerase IV Pol IV is an error prone DNA polymerase involved in non targeted mutagenesis 31 Pol IV is a Family Y polymerase expressed by the dinB gene that is switched on via SOS induction caused by stalled polymerases at the replication fork During SOS induction Pol IV production is increased tenfold and one of the functions during this time is to interfere with Pol III holoenzyme processivity This creates a checkpoint stops replication and allows time to repair DNA lesions via the appropriate repair pathway 32 Another function of Pol IV is to perform translesion synthesis at the stalled replication fork like for example bypassing N2 deoxyguanine adducts at a faster rate than transversing undamaged DNA Cells lacking the dinB gene have a higher rate of mutagenesis caused by DNA damaging agents 33 Pol V edit DNA polymerase V Pol V is a Y family DNA polymerase that is involved in SOS response and translesion synthesis DNA repair mechanisms 34 Transcription of Pol V via the umuDC genes is highly regulated to produce only Pol V when damaged DNA is present in the cell generating an SOS response Stalled polymerases causes RecA to bind to the ssDNA which causes the LexA protein to autodigest LexA then loses its ability to repress the transcription of the umuDC operon The same RecA ssDNA nucleoprotein posttranslationally modifies the UmuD protein into UmuD protein UmuD and UmuD form a heterodimer that interacts with UmuC which in turn activates umuC s polymerase catalytic activity on damaged DNA 35 In E coli a polymerase tool belt model for switching pol III with pol IV at a stalled replication fork where both polymerases bind simultaneously to the b clamp has been proposed 36 However the involvement of more than one TLS polymerase working in succession to bypass a lesion has not yet been shown in E coli Moreover Pol IV can catalyze both insertion and extension with high efficiency whereas pol V is considered the major SOS TLS polymerase One example is the bypass of intra strand guanine thymine cross link where it was shown on the basis of the difference in the mutational signatures of the two polymerases that pol IV and pol V compete for TLS of the intra strand crosslink 36 Family D edit nbsp Structures of archaeal polD and eukaryotic Pola Not only is the general topology conserved the two also share a bifunctional primase and PCNA binding PIP box sequence on the C terminus similar to both eukaryotic Pola and Pole 37 In 1998 the family D of DNA polymerase was discovered in Pyrococcus furiosus and Methanococcus jannaschii 38 The PolD complex is a heterodimer of two chains each encoded by DP1 small proofreading and DP2 large catalytic Unlike other DNA polymerases the structure and mechanism of the DP2 catalytic core resemble that of multi subunit RNA polymerases The DP1 DP2 interface resembles that of Eukaryotic Class B polymerase zinc finger and its small subunit 18 DP1 a Mre11 like exonuclease 39 is likely the precursor of small subunit of Pol a and e providing proofreading capabilities now lost in Eukaryotes 26 Its N terminal HSH domain is similar to AAA proteins especially Pol III subunit d and RuvB in structure 40 DP2 has a Class II KH domain 18 Pyrococcus abyssi polD is more heat stable and more accurate than Taq polymerase but has not yet been commercialized 41 It has been proposed that family D DNA polymerase was the first to evolve in cellular organisms and that the replicative polymerase of the Last Universal Cellular Ancestor LUCA belonged to family D 42 Eukaryotic DNA polymerase edit Polymerases b l s m beta lambda sigma mu and TdT edit Family X polymerases contain the well known eukaryotic polymerase pol b beta as well as other eukaryotic polymerases such as Pol s sigma Pol l lambda Pol m mu and Terminal deoxynucleotidyl transferase TdT Family X polymerases are found mainly in vertebrates and a few are found in plants and fungi These polymerases have highly conserved regions that include two helix hairpin helix motifs that are imperative in the DNA polymerase interactions One motif is located in the 8 kDa domain that interacts with downstream DNA and one motif is located in the thumb domain that interacts with the primer strand Pol b encoded by POLB gene is required for short patch base excision repair a DNA repair pathway that is essential for repairing alkylated or oxidized bases as well as abasic sites Pol l and Pol m encoded by the POLL and POLM genes respectively are involved in non homologous end joining a mechanism for rejoining DNA double strand breaks due to hydrogen peroxide and ionizing radiation respectively TdT is expressed only in lymphoid tissue and adds n nucleotides to double strand breaks formed during V D J recombination to promote immunological diversity 43 Polymerases a d and e alpha delta and epsilon edit Pol a alpha Pol d delta and Pol e epsilon are members of Family B Polymerases and are the main polymerases involved with nuclear DNA replication Pol a complex pol a DNA primase complex consists of four subunits the catalytic subunit POLA1 the regulatory subunit POLA2 and the small and the large primase subunits PRIM1 and PRIM2 respectively Once primase has created the RNA primer Pol a starts replication elongating the primer with 20 nucleotides 44 Due to its high processivity Pol d takes over the leading and lagging strand synthesis from Pol a 14 218 219 Pol d is expressed by genes POLD1 creating the catalytic subunit POLD2 POLD3 and POLD4 creating the other subunits that interact with Proliferating Cell Nuclear Antigen PCNA which is a DNA clamp that allows Pol d to possess processivity 45 Pol e is encoded by the POLE1 the catalytic subunit POLE2 and POLE3 gene It has been reported that the function of Pol e is to extend the leading strand during replication 46 47 while Pol d primarily replicates the lagging strand however recent evidence suggested that Pol d might have a role in replicating the leading strand of DNA as well 48 Pol e s C terminus polymerase relic region despite being unnecessary for polymerase activity 49 is thought to be essential to cell vitality The C terminus region is thought to provide a checkpoint before entering anaphase provide stability to the holoenzyme and add proteins to the holoenzyme necessary for initiation of replication 50 Pol e has a larger palm domain that provides high processivity independently of PCNA 49 Compared to other Family B polymerases the DEDD exonuclease family responsible for proofreading is inactivated in Pol a 26 Pol e is unique in that it has two zinc finger domains and an inactive copy of another family B polymerase in its C terminal The presence of this zinc finger has implications in the origins of Eukaryota which in this case is placed into the Asgard group with archaeal B3 polymerase 51 Polymerases h i and k eta iota and kappa edit Pol h eta Pol i iota and Pol k kappa are Family Y DNA polymerases involved in the DNA repair by translation synthesis and encoded by genes POLH POLI and POLK respectively Members of Family Y have five common motifs to aid in binding the substrate and primer terminus and they all include the typical right hand thumb palm and finger domains with added domains like little finger LF polymerase associated domain PAD or wrist The active site however differs between family members due to the different lesions being repaired Polymerases in Family Y are low fidelity polymerases but have been proven to do more good than harm as mutations that affect the polymerase can cause various diseases such as skin cancer and Xeroderma Pigmentosum Variant XPS The importance of these polymerases is evidenced by the fact that gene encoding DNA polymerase h is referred as XPV because loss of this gene results in the disease Xeroderma Pigmentosum Variant Pol h is particularly important for allowing accurate translesion synthesis of DNA damage resulting from ultraviolet radiation The functionality of Pol k is not completely understood but researchers have found two probable functions Pol k is thought to act as an extender or an inserter of a specific base at certain DNA lesions All three translesion synthesis polymerases along with Rev1 are recruited to damaged lesions via stalled replicative DNA polymerases There are two pathways of damage repair leading researchers to conclude that the chosen pathway depends on which strand contains the damage the leading or lagging strand 52 Polymerases Rev1 and z zeta edit Pol z another B family polymerase is made of two subunits Rev3 the catalytic subunit and Rev7 MAD2L2 which increases the catalytic function of the polymerase and is involved in translesion synthesis Pol z lacks 3 to 5 exonuclease activity is unique in that it can extend primers with terminal mismatches Rev1 has three regions of interest in the BRCT domain ubiquitin binding domain and C terminal domain and has dCMP transferase ability which adds deoxycytidine opposite lesions that would stall replicative polymerases Pol d and Pol e These stalled polymerases activate ubiquitin complexes that in turn disassociate replication polymerases and recruit Pol z and Rev1 Together Pol z and Rev1 add deoxycytidine and Pol z extends past the lesion Through a yet undetermined process Pol z disassociates and replication polymerases reassociate and continue replication Pol z and Rev1 are not required for replication but loss of REV3 gene in budding yeast can cause increased sensitivity to DNA damaging agents due to collapse of replication forks where replication polymerases have stalled 53 Telomerase edit Telomerase is a ribonucleoprotein which functions to replicate ends of linear chromosomes since normal DNA polymerase cannot replicate the ends or telomeres The single strand 3 overhang of the double strand chromosome with the sequence 5 TTAGGG 3 recruits telomerase Telomerase acts like other DNA polymerases by extending the 3 end but unlike other DNA polymerases telomerase does not require a template The TERT subunit an example of a reverse transcriptase uses the RNA subunit to form the primer template junction that allows telomerase to extend the 3 end of chromosome ends The gradual decrease in size of telomeres as the result of many replications over a lifetime are thought to be associated with the effects of aging 14 248 249 Polymerases g 8 and n gamma theta and nu edit Further information DNA polymerase nu Pol g gamma Pol 8 theta and Pol n nu are Family A polymerases Pol g encoded by the POLG gene was long thought to be the only mitochondrial polymerase However recent research shows that at least Pol b beta a Family X polymerase is also present in mitochondria 54 55 Any mutation that leads to limited or non functioning Pol g has a significant effect on mtDNA and is the most common cause of autosomal inherited mitochondrial disorders 56 Pol g contains a C terminus polymerase domain and an N terminus 3 5 exonuclease domain that are connected via the linker region which binds the accessory subunit The accessory subunit binds DNA and is required for processivity of Pol g Point mutation A467T in the linker region is responsible for more than one third of all Pol g associated mitochondrial disorders 57 While many homologs of Pol 8 encoded by the POLQ gene are found in eukaryotes its function is not clearly understood The sequence of amino acids in the C terminus is what classifies Pol 8 as Family A polymerase although the error rate for Pol 8 is more closely related to Family Y polymerases Pol 8 extends mismatched primer termini and can bypass abasic sites by adding a nucleotide It also has Deoxyribophosphodiesterase dRPase activity in the polymerase domain and can show ATPase activity in close proximity to ssDNA 58 Pol n nu is considered to be the least effective of the polymerase enzymes 59 However DNA polymerase nu plays an active role in homology repair during cellular responses to crosslinks fulfilling its role in a complex with helicase 59 Plants use two Family A polymerases to copy both the mitochondrial and plastid genomes They are more similar to bacterial Pol I than they are to mammalian Pol g 60 Reverse transcriptase edit Retroviruses encode an unusual DNA polymerase called reverse transcriptase which is an RNA dependent DNA polymerase RdDp that synthesizes DNA from a template of RNA The reverse transcriptase family contain both DNA polymerase functionality and RNase H functionality which degrades RNA base paired to DNA An example of a retrovirus is HIV 14 Reverse transcriptase is commonly employed in amplification of RNA for research purposes Using an RNA template PCR can utilize reverse transcriptase creating a DNA template This new DNA template can then be used for typical PCR amplification The products of such an experiment are thus amplified PCR products from RNA 9 Each HIV retrovirus particle contains two RNA genomes but after an infection each virus generates only one provirus 61 After infection reverse transcription is accompanied by template switching between the two genome copies copy choice recombination 61 From 5 to 14 recombination events per genome occur at each replication cycle 62 Template switching recombination appears to be necessary for maintaining genome integrity and as a repair mechanism for salvaging damaged genomes 63 61 Bacteriophage T4 DNA polymerase edit Bacteriophage phage T4 encodes a DNA polymerase that catalyzes DNA synthesis in a 5 to 3 direction 64 The phage polymerase also has an exonuclease activity that acts in a 3 to 5 direction 65 and this activity is employed in the proofreading and editing of newly inserted bases 66 A phage mutant with a temperature sensitive DNA polymerase when grown at permissive temperatures was observed to undergo recombination at frequencies that are about two fold higher than that of wild type phage 67 It was proposed that a mutational alteration in the phage DNA polymerase can stimulate template strand switching copy choice recombination during replication 67 See also editBiological machines DNA sequencing Enzyme catalysis Genetic recombination Molecular cloning Polymerase chain reaction Protein domain dynamics Reverse transcription RNA polymerase Taq DNA polymeraseReferences edit Bollum FJ August 1960 Calf thymus polymerase The Journal of Biological Chemistry 235 8 2399 2403 doi 10 1016 S0021 9258 18 64634 4 PMID 13802334 Falaschi A Kornberg A April 1966 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1700865 PMID 1700865 Goulian M Lucas ZJ Kornberg A February 1968 Enzymatic synthesis of deoxyribonucleic acid XXV Purification and properties of deoxyribonucleic acid polymerase induced by infection with phage T4 The Journal of Biological Chemistry 243 3 627 638 doi 10 1016 S0021 9258 18 93650 1 PMID 4866523 Huang WM Lehman IR May 1972 On the exonuclease activity of phage T4 deoxyribonucleic acid polymerase The Journal of Biological Chemistry 247 10 3139 3146 doi 10 1016 S0021 9258 19 45224 1 PMID 4554914 Gillin FD Nossal NG September 1976 Control of mutation frequency by bacteriophage T4 DNA polymerase I The CB120 antimutator DNA polymerase is defective in strand displacement The Journal of Biological Chemistry 251 17 5219 5224 doi 10 1016 S0021 9258 17 33149 6 PMID 956182 a b Bernstein H August 1967 The effect on recombination of mutational defects in the DNA polymerase and deoxycytidylate hydroxymethylase of phage T4D Genetics 56 4 755 769 doi 10 1093 genetics 56 4 755 PMC 1211652 PMID 6061665 Further reading editBurgers PM Koonin EV Bruford E Blanco L Burtis KC Christman MF et al November 2001 Eukaryotic DNA polymerases proposal for a revised nomenclature The Journal of Biological Chemistry 276 47 43487 43490 doi 10 1074 jbc R100056200 hdl 10261 338658 PMID 11579108 External links edit nbsp Wikimedia Commons has media related to DNA polymerases DNA polymerases at the U S National Library of Medicine Medical Subject Headings MeSH PDB Molecule of the Month DNA polymerase Unusual repair mechanism in DNA polymerase lambda Ohio State University July 25 2006 A great animation of DNA Polymerase from WEHI at 1 45 minutes in Archived 2014 12 05 at the Wayback Machine 3D macromolecular structures of DNA polymerase from the EM Data Bank EMDB Portal nbsp Biology Retrieved from https en wikipedia org w index php title DNA polymerase amp oldid 1221223125, wikipedia, wiki, book, books, library,

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