Topoisomerase

Topoisomerases are enzymes that participate in the overwinding or underwinding of DNA. The winding problem of DNA arises due to the intertwined nature of its double-helical structure. During DNA replication and transcription, DNA becomes overwound ahead of a replication fork. If left unabated, this torsion would eventually stop the ability of DNA or RNA polymerases involved in these processes to continue down the DNA strand.

In order to prevent and correct these types of topological problems caused by the double helix, topoisomerases bind to double-stranded DNA and cut the phosphate backbone of either one or both the DNA strands. This intermediate break allows the DNA to be untangled or unwound, and, at the end of these processes, the DNA backbone is resealed again. Since the overall chemical composition and connectivity of the DNA do not change, the tangled and untangled DNAs are chemical isomers, differing only in their global topology, thus the name for these enzymes. Topoisomerases are isomerase enzymes that act on the topology of DNA.^[1]

Bacterial topoisomerase and human topoisomerase proceed via the same mechanism for replication and transcription.

Discovery

James C. Wang was the first to discover a topoisomerase when he identified E. coli topoisomerase I. Topo EC-codes are as follows: type I, EC 5.99.1.2; type II: EC 5.99.1.3. His discovery was made in the 1970s.

Function

The double-helical configuration that DNA strands naturally reside, makes them difficult to separate and yet they must be separated by helicase enzymes, if other enzymes are to transcribe the sequences that encode proteins, or if chromosomes are to be replicated. In so-called circular DNA, in which double-helical DNA is bent around and joined in a circle, the two strands are topologically linked, or knotted. Otherwise identical loops of DNA, having different numbers of twists, are topoisomers, and cannot be interconverted by any process that does not involve the breaking of DNA strands. Topoisomerases catalyze and guide the unknotting or unkinking of DNA^[2] by creating transient breaks in the DNA using a conserved tyrosine as the catalytic residue.^[1]

The insertion of (viral) DNA into chromosomes and other forms of recombination can also require the action of topoisomerases.

Clinical significance

Topological problems

There are three main types of topology:

Outside of the essential processes of replication or transcription, DNA must be kept as compact as possible, and these three states help this cause. However, when transcription or replication occurs, DNA must be free, and these states seriously hinder the processes. In addition, during replication, the newly replicated duplex of DNA and the original duplex of DNA become intertwined and must be completely separated in order to ensure genomic integrity as a cell divides. As a transcription bubble proceeds, DNA ahead of the transcription fork becomes overwound, or positively supercoiled, while DNA behind the transcription bubble becomes underwound, or negatively supercoiled. As replication occurs, DNA ahead of the replication bubble becomes positively supercoiled, while DNA behind the replication fork becomes entangled forming precatenanes. One of the most essential topological problems occurs at the very end of replication, when daughter chromosomes must be fully disentangled before mitosis occurs. Topoisomerase IIA plays an essential role in resolving these topological problems.

Classes

Topoisomerases can fix these topological problems and are separated into two types depending on the number of strands cut in one round of action:^[3] Both these classes of enzyme utilize a conserved tyrosine. However these enzymes are structurally and mechanistically different. For a video of this process click here.

A type I topoisomerase cuts one strand of a DNA double helix, relaxation occurs, and then the cut strand is re-ligated. Cutting one strand allows the part of the molecule on one side of the cut to rotate around the uncut strand, thereby reducing stress from too much or too little twist in the helix. Such stress is introduced when the DNA strand is "supercoiled" or uncoiled to or from higher orders of coiling. Type I topoisomerases do not require ATP for hydrolysis are subdivided into three subclasses:
- Type IA topoisomerases, which share many structural and mechanistic features with the type II topoisomerases. Examples of type IA topoisomerases include prokaryotic Topoisomerase I and and III, eukaryotic Topoisomerase IIIα and Topoisomerase IIIβ and Reverse Gyrase. Like type II topoisomerases, type IA topoisomerases form a covalent intermediate with the 5' end of DNA.
- Type IB topoisomerases, which utilize a controlled rotary mechanism. Examples of Type IB topoisomerases include Eukaryotic and eukaryal viral Topoisomerase I. In the past, type IB topoisomerases were referred to as eukaryotic topoisomerase I, but IB topoisomerases are present in all three domains of life. Type IB topoisomerases form a covalent intermediate with the 3' end of DNA.
- Type IC topoisomerase (also called Topoisomerase V) has been identified.^[4] While it is structurally unique from type IA and IB topoisomerases, It shares a similar mechanism with type IB topoisomerase.
A type II topoisomerase cuts both strands of one DNA double helix, passes another unbroken DNA helix through it, and then re-ligate the cut strands. Type II topisomerases utilize ATP hydrolysis and are subdivided into two subclasses which possess similar structure and mechanisms:
- Type IIA topoisomerases which include eukaryotic and eukaryal viral Topoisomerase IIα and Topoisomerase IIβ, bacterial gyrase, and topoisomerase IV.
- Type IIB topoisomerases, which include Topoisomerase VI found in archaea.

Topoisomerase^[5]	Subfamily Type	Function	Multimericity	Metal Dependence	ATP Dependence	Single-or Double-Stranded Cleavage?	Cleavage Polarity	Change In Link Number (L)
Topoisomerase I (E. coli)	Type IA	Removes (-), but not (+) supercoils	Monomer	Yes (Mg²⁺)	No	SS	5'	±1
Topoisomerase III (E. coli)		Removes (-), but not (+) supercoils; Overlaping function with Topoisomerase IV
Topoisomerase IIIα (H. sapiens)		Removes (-), but not (+) supercoils; Assists in the unlinking of precatenanes in cellular DNA replication; Can catalyze the knotting, unknotting, and interlinking of single-stranded circles as well as the knotting, unknotting, catenation, and decatenation of gapped or nicked duplex DNA circles.
Topoisomerase IIIβ (H. sapiens)		Unknown function
Reverse DNA Gyrase (E. coli)		Removes (-), but not (+) supercoils	Heterodimer
Reverse DNA Gyrase (Archaea)		Removes (-), but not (+) supercoils	Heterodimer
Topoisomerase I (H. sapiens)	Type IB	Remove (+) and (-) supercoils; Relaxes compensatory (-) supercoils; Generates right-handed solenoidal supercoils; Supports fork movement during replication; Thought to be similar in structure to tyrosine recombinases.	Monomer	No	No	SS	3'	±1
Topoisomerase V (Archaea)^[6]	Type IC	Relaxes (+) and (-) supercoils. Involved in DNA repair	Monomer	No	No	SS	3'	±1
Topoisomerase II / DNA Gyrase (E. coli)	Type IIA	Generates (-) supercoils (the only topoisomerase known to do this)	Heterotetramer	Yes (Mg²⁺)	Yes	DS	5'	±2
Topoisomerase IV (E. coli)		Relaxes (-) supercoils; Role in decatenation	Heterotetramer
Topoisomerase IIα (H. sapiens)		Essential; Unlinks interwined daughter duplexes in replication; Contributes to DNA relaxation during transcription	Heterodimer
Topoisomerase IIβ (H. sapiens)		Role in suppressing recombination or supporting transcription in neurons	Heterodimer
Topoisomerase VI (Archaea)	Type IIB	Relaxes (+) and (-) supercoils; Responsible for decatenating replication intermediates; May be exclusive to the archaea.	Heterotetramer	Yes (Mg²⁺)	Yes	DS	5'	±2

Both type I and type II topoisomerases change the linking number (L) of DNA. Type IA topoisomerases change the linking number by one, type IB and type IC topoisomerases change the linking number by any integer, whereas type IIA and type IIB topoisomerases change the linking number by two.

References

1 2 Champoux JJ (2001). "DNA topoisomerases: structure, function, and mechanism". Annu. Rev. Biochem. 70: 369–413. doi:10.1146/annurev.biochem.70.1.369. PMID 11395412.
↑ C.Michael Hogan. 2010. Deoxyribonucleic acid. Encyclopedia of Earth. National Council for Science and the Environment. eds. S.Draggan and C.Cleveland. Washington DC
↑ Wang JC (April 1991). "DNA topoisomerases: why so many?". J. Biol. Chem. 266 (11): 6659–62. PMID 1849888.
↑ "Structural studies of type I topoisomerases". Nucleic Acids Researcj. 37(3): 693–701. 2009.
↑ Champoux, James (2001). "DNA Topoisomerases: Structure, Function, and Mechanism". Annual Review of Biochemistry. 70: 369-413.
↑ "Structural studies of type I topoisomerases". Nucleic Acids Research. 37(3): 693–701. 2009.

Pommier, Yves (May 28, 2010). "DNA topoisomerases and their poisoning by anticancer and antibacterial drugs". Chemistry & Biology. Retrieved May 28, 2010.

External links

DNA Topoisomerases at the US National Library of Medicine Medical Subject Headings (MeSH)

Enzymes

Activity	Active site Binding site Catalytic triad Oxyanion hole Enzyme promiscuity Catalytically perfect enzyme Coenzyme Cofactor Enzyme catalysis Enzyme kinetics Lineweaver–Burk plot Michaelis–Menten kinetics

Regulation	Allosteric regulation Cooperativity Enzyme inhibitor

Classification	EC number Enzyme superfamily Enzyme family List of enzymes

Types	EC1 Oxidoreductases (list) EC2 Transferases (list) EC3 Hydrolases (list) EC4 Lyases (list) EC5 Isomerases (list) EC6 Ligases (list)

Isomerase: topoisomerases (EC 5.99)

5.99.1	Type I topoisomerase Type II topoisomerase gyrase topoisomerase IV

Enzymes

Activity	Active site Binding site Catalytic triad Oxyanion hole Enzyme promiscuity Catalytically perfect enzyme Coenzyme Cofactor Enzyme catalysis Enzyme kinetics Lineweaver–Burk plot Michaelis–Menten kinetics

Regulation	Allosteric regulation Cooperativity Enzyme inhibitor

Classification	EC number Enzyme superfamily Enzyme family List of enzymes

Types	EC1 Oxidoreductases (list) EC2 Transferases (list) EC3 Hydrolases (list) EC4 Lyases (list) EC5 Isomerases (list) EC6 Ligases (list)

DNA replication (comparing Prokaryotic to Eukaryotic)

Initiation

Prokaryotic (initiation)	Pre-replication complex dnaC Cdc6 Helicase dnaA dnaB T7 Primase dnaG

Eukaryotic (preparation in G1 phase)	Pre-replication complex Origin recognition complex ORC1 ORC2 ORC3 ORC4 ORC5 ORC6 Cdc6 Cdt1 Minichromosome maintenance MCM2 MCM3 MCM4 MCM5 MCM6 MCM7 Licensing factor Autonomously replicating sequence Single-strand binding protein SSBP2 SSBP3 SSBP4 RNase H RNASEH1 RNASEH2A Helicase: HFM1 Primase: PRIM1 PRIM2

Both	Origin of replication/Ori/Replicon Replication fork Lagging and leading strands Okazaki fragments Primer

Replication

Prokaryotic (elongation)	DNA polymerase III holoenzyme dnaC dnaE dnaH dnaN dnaQ dnaT dnaX holA holB holC holD holE Replisome DNA ligase DNA clamp Topoisomerase DNA gyrase Prokaryotic DNA polymerase: DNA polymerase I Klenow fragment

Eukaryotic (synthesis in S phase)	Replication factor C RFC1 Flap endonuclease FEN1 Topoisomerase Replication protein A RPA1 Eukaryotic DNA polymerase: alpha POLA1 POLA2 PRIM1 PRIM2 delta POLD1 POLD2 POLD3 POLD4 epsilon POLE POLE2 POLE3 POLE4 DNA clamp PCNA Control of chromosome duplication

Both	Movement: Processivity DNA ligase

Termination

Telomere: Telomerase
- TERT
- TERC
- DKC1

Antigens: Autoantigens

Dehydrogenase	Branched-chain alpha-keto acid dehydrogenase complex Oxoglutarate dehydrogenase Pyruvate dehydrogenase

Transglutaminase	Epidermal transglutaminase Tissue transglutaminase

Nucleoporins	NUP35 NUP37 NUP43 NUP50 NUP54 NUP62 NUP85 NUP88 NUP93 NUP98 NUP107 NUP133 NUP153 NUP155 NUP160 NUP188 NUP210 NUP205 NUP214

Other	Acetylcholine receptor Actin Apolipoprotein H Cardiolipin Centromere Filaggrin (Citrullinate) Gangliosides Sp100 nuclear antigen Thrombin Topoisomerase

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