Decatenation of DNA circles by FtsK-dependent Xer site-specific recombination

DNA replication results in interlinked (catenated) sister duplex molecules as a consequence of the intertwined helices that comprise duplex DNA. DNA topoisomerases play key roles in decatenation. We demonstrate a novel, efficient and directional decatenation process in vitro, which uses the combination of the Escherichia coli XerCD site-specific recombination system and a protein, FtsK, which facilitates simple synapsis of dif recombination sites during its translocation along DNA. We propose that the FtsK-XerCD recombination machinery, which converts chromosomal dimers to monomers, may also function in vivo in removing the final catenation links remaining upon completion of DNA replication.     

DNA disentangling by type-2 topoisomerases

A type-2 topoisomerase cleaves a DNA strand, passes another through the break, and then rejoins the severed ends. Because it appears that this action is as likely to increase as to decrease entanglements, the question is: how are entanglements removed? We argue that type-2 topoisomerases have evolved to act at "hooked" juxtapositions of strands (where the strands are curved toward each other). This type of juxtaposition is a natural consequence of entangled long strands. Our model accounts for the observed preference for unlinking and unknotting of short DNA plasmids by type-2 topoisomerases and well explains experimental observations.     

DNA topoisomerases.

DNA topoisomerases play an important role in regulating DNA structure, thus affecting many aspects of chromosome function inside cells. Recent progress in this field raises exciting questions regarding the distinct and critical functions of multiple topoisomerases, and the roles of DNA topoisomerases in the processes of chromosome condensation, decondensation, and segregation.     

DNA supercoiling and relaxation by ATP-dependent DNA topoisomerases.

Bacterial DNA gyrase and the eukaryotic type II DNA topoisomerases are ATPases that catalyse the introduction or removal of DNA supercoils and the formation and resolution of DNA knots and catenanes. Gyrase is unique in using ATP to drive the energetically unfavourable negative supercoiling of DNA, an example of mechanochemical coupling: in contrast, eukaryotic topoisomerase II relaxes DNA in an ATP-requiring reaction. In each case, the enzyme-DNA complex acts as a 'gate' mediating the passage of a DNA segment through a transient enzyme-bridged double-strand DNA break. We are using a variety of genetic and enzymic approaches to probe the nature of these complexes and their mechanism of action. Recent studies will be described focusing on the role of DNA wrapping on the A2B2 gyrase complex, subunit activities uncovered by using ATP analogues and the coumarin and quinolone inhibitors, and the identification and functions of discrete subunit domains. Homology between gyrase subunits and the A2 homodimer of eukaryotic topo II suggests functional conservation between these proteins. The role of ATP hydrolysis by these topoisomerases will be discussed in regard to other energy coupling systems.     

DNA topoisomerases and DNA repair

DNA topoisomerases are enzymes that can modify, and may regulate, the topological state of DNA through concerted breaking and rejoining of the DNA strands. They have been believed to be directly involved in DNA excision repair, and perhaps to be required for the control of repair as well. The vicissitudes of this hypothesis provide a noteworthy example of the dangers of interpreting cellular phenomena without genetic information and vice versa.     

The assembly of kinetoplast DNA

The unusual structure of the kinetoplast DNA (kDNA) of trypanosomatids requires unique replication mechanisms. Deciphering the mechanisms that regulate the network assembly has been a challenge for many years. A better understanding of these processes was facilitated by recent studies on the fine structure of resting and replicating kDNA networks. In this review, Joseph Shlomai discusses our current view of the structural and mechanistic aspects of the assembly of kinetoplast DNA.     

Replication of kinetoplast DNA maxicircles

The kinetoplast DNA of Crithidia fasciculata is a massive network composed of thousands of topologically interlocked circles. Most of these circles are minicircles (2.5 kb), and about 50 are maxicircles (37 kb). Previous studies showed that minicircles replicate, after release from the network, via Cairns (theta) intermediates. Here we show that maxicircles replicate, while attached to the network, by an entirely different mechanism involving rolling circle intermediates. After the network-bound maxicircle has finished replication, the branch of the rolling circle is apparently cleaved off to form a linear free maxicircle. A restriction map of the linearized free maxicircles shows that these molecules have unique termini, one of which presumably corresponds to the replication origin.     

Theoretical models of DNA topology simplification by type IIA DNA topoisomerases

It was discovered 12 years ago that type IIA topoisomerases can simplify DNA topology—the steady-state fractions of knots and links created by the enzymes are many times lower than the corresponding equilibrium fractions. Though this property of the enzymes made clear biological sense, it was not clear how small enzymes could selectively change the topology of very large DNA molecules, since topology is a global property and cannot be determined by a local DNA–protein interaction. A few models, suggested to explain the phenomenon, are analyzed in this review. We also consider experimental data that both support and contravene these models.     

Unlinking of supercoiled DNA catenanes by type IIA topoisomerases

It was found recently that DNA catenanes, formed during replication of circular plasmids, become positively (+) supercoiled, and the unlinking of such catenanes by type IIA topoisomerases proceeds much more efficiently than the unlinking of negatively (−) supercoiled catenanes. In an attempt to explain this striking finding we studied, by computer simulation, conformational properties of supercoiled DNA catenanes. Although the simulation showed that conformational properties of (+) and (−) supercoiled replication catenanes are very different, these properties per se do not give any advantage to (+) supercoiled over (−) supercoiled DNA catenanes for unlinking. An advantage became evident, however, when we took into account the established features of the enzymatic reaction catalyzed by the topoisomerases. The enzymes create a sharp DNA bend in the first bound DNA segment and allow for the transport of the second segment only from inside the bend to its outside. We showed that in (−) supercoiled DNA catenanes this protein-bound bent segment becomes nearly inaccessible for segments of the other linked DNA molecule, inhibiting the unlinking.     

Minicircular kinetoplast DNA from Trypanosomatidae

Analysis of primary structure and organization of mitochondrial (kinetoplast) DNA of flagellates occupies a prominent place in the studies of eukaryote mitochondrial genomes, owing to its unusual organization and functioning as well as to the epidemiological role of the Trypanosomatidae family. According to contemporary notions, living zooflagellates are direct descendants of the ancestral forms that gave rise to all eukaryotic kingdoms. Hence, comparative mtDNA studies of recent Trypanosomatidae open broad prospects for phylogenetic reconstructions and analysis of presumable routes of eukaryote evolution. The structure, characteristics, and functions of Trypanosomatidae minicircular kinetoplast DNA are discussed here.