E.coli MukB protein involved in chromosome partition forms a homodimer with a rod-and-hinge structure having DNA binding and ATP/GTP binding activities.

mukB mutants of Escherichia coli are defective in the correct partitioning of replicated chromosomes. This results in the appearance of normal-sized anucleate (chromosome-less) cells during cell proliferation. Based on the nucleotide sequence of the mukB gene, the MukB protein of 177 kDa was predicted to be a filamentous protein with globular domains at the ends, and also having DNA binding and nucleotide binding abilities. Here we present evidence that the purified MukB protein possesses these characteristics. MukB forms a homodimer with a rod-and-hinge structure having a pair of large, C-terminal globular domains at one end and a pair of small, N-terminal globular domains at the opposite end; it tends to bend at a middle hinge site of the rod section. Chromatography in a DNA-cellulose column and the gel retardation assay revealed that MukB possesses DNA binding activity. Photoaffinity cross-linking experiments showed that MukB binds to ATP and GTP in the presence of Zn2+. Throughout the purification steps, acyl carrier protein was co-purified with MukB.     

DNA reshaping by MukB. Right-handed knotting, left-handed supercoiling

MukB is a bacterial SMC (structural maintenance of chromosome) protein required for faithful chromosome segregation in Escherichia coli. We report here that purified MukB introduces right-handed knots into DNA in the presence of type-2 topoisomerase, indicating that the protein promotes intramolecular DNA condensation. The pattern of generated knots suggests that MukB, similar to eukaryotic condensins, stabilizes large right-handed DNA loops. In contrast to eukaryotic condensins, however, the net supercoiling stabilized by MukB was negative. Furthermore, DNA reshaping by MukB did not require ATP. These data establish that bacterial condensins alter the shape of double-stranded DNA in vitro and lend support to the notions that the right-handed knotting is the most conserved biochemical property of condensins. Finally, we found that MukB can be eluted from a heparin column in two distinct forms, one of which is inert in DNA binding or reshaping. Furthermore, we find that the activity of MukB is reversibly attenuated during chromatographic separation. Thus, MukB has a unique set of topological properties, compared with other SMC proteins, and is likely to exist in two different conformations.     

Structural basis for the MukB‐topoisomerase IV interaction and its functional implications in vivo

Chromosome partitioning in Escherichia coli is assisted by two interacting proteins, topoisomerase (topo) IV and MukB. MukB stimulates the relaxation of negative supercoils by topo IV; to understand the mechanism of their action and to define this functional interplay, we determined the crystal structure of a minimal MukB–topo IV complex to 2.3 Å resolution. The structure shows that the so‐called ‘hinge’ region of MukB forms a heterotetrameric assembly with a C‐terminal DNA binding domain (CTD) on topo IV's ParC subunit. Biochemical studies show that the hinge stimulates topo IV by competing for a site on the CTD that normally represses activity on negatively supercoiled DNA, while complementation tests using mutants implicated in the interaction reveal that the cellular dependency on topo IV derives from a joint need for both strand passage and MukB binding. Interestingly, the configuration of the MukB·topo IV complex sterically disfavours intradimeric interactions, indicating that the proteins may form oligomeric arrays with one another, and suggesting a framework by which MukB and topo IV may collaborate during daughter chromosome disentanglement.     

Antagonistic interactions of kleisins and DNA with bacterial Condensin MukB

MukBEF is a bacterial SMC (structural maintenance of chromosome) complex required for faithful chromosome segregation in Escherichia coli. The SMC subunit of the complex, MukB, promotes DNA condensation in vitro and in vivo; however, all three subunits are required for the function of MukBEF. We report here that MukEF disrupts MukB x DNA complex. Preassembled MukBEF was inert in DNA binding or reshaping. Similarly, the association of MukEF with DNA-bound MukB served to displace MukB from DNA. When purified from cells, MukBEF existed as a mixture of MukEF-saturated and unsaturated complexes. The holoenzyme was unstable and could only bind DNA upon dissociation of MukEF. The DNA reshaping properties of unsaturated MukBEF were identical to those of MukB. Furthermore, the unsaturated MukBEF was stable and proficient in DNA binding. These results support the view that kleisins are not directly involved in DNA binding but rather bridge distant DNA-bound MukBs.     

The MukB-topoisomerase IV interaction mutually suppresses their catalytic activities

The bacterial condensin MukB and the cellular chromosomal decatenase, topoisomerase IV interact and this interaction is required for proper condensation and topological ordering of the chromosome. Here, we show that Topo IV stimulates MukB DNA condensation by stabilizing loops in DNA: MukB alone can condense nicked plasmid DNA into a protein–DNA complex that has greater electrophoretic mobility than that of the DNA alone, but both MukB and Topo IV are required for a similar condensation of a linear DNA representing long stretches of the chromosome. Remarkably, we show that rather than MukB stimulating the decatenase activity of Topo IV, as has been argued previously, in stoichiometric complexes of the two enzymes each inhibits the activity of the other: the ParC subunit of Topo IV inhibits the MukF-stimulated ATPase activity of MukB and MukB inhibits both DNA crossover trapping and DNA cleavage by Topo IV. These observations suggest that when in complex on the DNA, Topo IV inhibits the motor function of MukB and the two proteins provide a stable scaffold for chromosomal DNA condensation.     

Distribution of the Escherichia coli structural maintenance of chromosomes (SMC)-like protein MukB in the cell

Fluorescent polyclonal antibodies specific for MukB have been used to study its localization in Escherichia coli. In wild-type cells, the MukB protein appeared as a limited number of oblong shapes embracing the nucleoid. MukB remained associated with the nucleoid in the absence of DNA replication. The centre of gravity of the dispersed MukB signal initially localized near mid-cell, but moved to approximately quarter positions well before the termination of DNA replication and its subsequent reinitiation. Because MukB had been reported to bind to FtsZ and to its eukaryotic homologue tubulin in vitro, cells were co-labelled with MukB- and FtsZ-specific fluorophores. No co-localization of MukB with polymerized FtsZ (the FtsZ ring) was observed at any time during the cell cycle. A possible role for MukB in preventing premature FtsZ polymerization and in DNA folding that might assist DNA segregation is discussed.     

DNA sliding and loop formation by E. coli SMC complex: MukBEF

SMC (structural maintenance of chromosomes) complexes share conserved architectures and function in chromosome maintenance via an unknown mechanism. Here we have used single-molecule techniques to study MukBEF, the SMC complex in Escherichia coli. Real-time movies show MukB alone can compact DNA and ATP inhibits DNA compaction by MukB. We observed that DNA unidirectionally slides through MukB, potentially by a ratchet mechanism, and the sliding speed depends on the elastic energy stored in the DNA. MukE, MukF and ATP binding stabilize MukB and DNA interaction, and ATP hydrolysis regulates the loading/unloading of MukBEF from DNA. Our data suggests a new model for how MukBEF organizes the bacterial chromosome in vivo; and this model will be relevant for other SMC proteins.     

The MukB-ParC Interaction Affects the Intramolecular,Not Intermolecular,Activities of Topoisomerase IV

Proper chromosome organization is accomplished through binding of proteins such as condensins that shape the DNA and by modulation of chromosome topology by the action of topoisomerases. We found that the interaction between MukB, the bacterial condensin, and ParC, a subunit of topoisomerase IV, enhanced relaxation of negatively supercoiled DNA and knotting by topoisomerase IV, which are intramolecular DNA rearrangements but not decatenation of multiply linked DNA dimers, which is an intermolecular DNA rearrangement required for proper segregation of daughter chromosomes. MukB DNA binding and a specific chiral arrangement of the DNA was required for topoisomerase IV stimulation because relaxation of positively supercoiled DNA was unaffected. This effect could be attributed to a more effective topological reconfiguration of the negatively supercoiled compared with positively supercoiled DNA by MukB. These data suggest that the MukB-ParC interaction may play a role in chromosome organization rather than in separation of daughter chromosomes.     

Mutational analysis of MukE reveals its role in focal subcellular localization of MukBEF

Bacterial condensin MukBEF is essential for global folding of the Escherichia coli chromosome. MukB, a SMC (structural maintenance of chromosome) protein, comprises the core of this complex and is responsible for its ATP‐modulated DNA binding and reshaping activities. MukF serves as a kleisin that modulates MukB–DNA interactions and links MukBs into macromolecular assemblies. Little is known about the function of MukE. Using random mutagenesis, we generated six loss‐of‐function point mutations in MukE. The surface mutations clustered in two places. One of them was at or close to the interface with MukF while the other was away from the known interactions of the protein. All loss‐of‐function mutations affected focal localization of MukBEF in live cells. In vitro, however, only some of them interfered with the assembly of MukBEF into a complex or the ability of MukEF to disrupt MukB–DNA interactions. Moreover, some MukE mutants were able to join intracellular foci formed by endogenous MukBEF and most of the mutants were efficiently incorporated into MukBEF even in the presence of endogenous MukE. These data reveal that focal localization of MukBEF involves other activities besides DNA binding and that MukE plays a central role in them.     

Crystal structure of the N-terminal domain of MukB: a protein involved in chromosome partitioning.

BACKGROUND: The 170 kDa protein MukB has been implicated in ATP-dependent chromosome partitioning during cell division in Escherichia coli. MukB shares its dimeric structure and domain architecture with the ubiquitous family of SMC (structural maintenance of chromosomes) proteins that facilitate similar functions. The N-terminal domain of MukB carries a putative Walker A nucleotide-binding region and the C-terminal domain has been shown to bind to DNA. Mutant phenotypes and a domain arrangement similar to motor proteins that move on microtubules led to the suggestion that MukB might be a motor protein acting on DNA. RESULTS: We have cloned, overexpressed and crystallized a 26 kDa protein consisting of 227 N-terminal residues of MukB from E. coli. The structure has been solved using multiple anomalous dispersion and has been refined to 2.2 A resolution. The N-terminal domain of MukB has a mixed alpha/beta fold with a central six-stranded antiparallel beta sheet. The putative nucleotide-binding loop, which is part of an unexpected helix-loop-helix motif, is exposed on the surface and no nucleotide-binding pocket could be detected. CONCLUSIONS: The N-terminal domain of MukB has no similarity to the kinesin family of motor proteins or to any other nucleotide-binding protein. Together with the finding of the exposed Walker A motif this observation supports a model in which the N- and C-terminal domains come together in the dimer of MukB to form the active site. Conserved residues on one side of the molecule delineate a region of the N-terminal domain that is likely to interact with the C-terminal domain.     

Nucleotide-dependent interaction of the N-terminal domain of MukB with microtubules

The MukB protein from Escherichia coli has a domain structure that is reminiscent of the eukaryotic motor proteins kinesin and myosin: N-terminal globular domains, a region of coiled-coil, and a specialised C-terminal domain. Sequence alignment of the N-terminal domain of MukB with the kinesin motor domain indicated an approximately 22% sequence identity. These observations raised the possibility that MukB might be a prokaryotic motor protein and, due to the sequence homology shared with kinesin, might bind to microtubules (Mts). We found that a construct encoding the first 342 residues of MukB (Muk342) binds specifically to Mts and shares a number of properties with the motor domain of kinesin. Visualisation of the Muk342 decorated Mt complexes using negative stain electron microscopy indicated that the Muk342 smoothly decorates the outside of Mts. Biochemical data demonstrate that Muk342 decorates Mts with a binding stoichiometry of one Muk342 monomer per tubulin monomer. These findings strongly suggest that MukB has a role in force generation and that it is a prokaryotic homologue of kinesin and myosin.     

Mechanics of DNA bridging by bacterial condensin MukBEF in vitro and in singulo

Structural maintenance of chromosome (SMC) proteins comprise the core of several specialized complexes that stabilize the global architecture of the chromosomes by dynamically linking distant DNA fragments. This reaction however remains poorly understood giving rise to numerous proposed mechanisms of the proteins. Using two novel assays, we investigated real‐time formation of DNA bridges by bacterial condensin MukBEF. We report that MukBEF can efficiently bridge two DNAs and that this reaction involves multiple steps. The reaction begins with the formation of a stable MukB–DNA complex, which can further capture another protein‐free DNA fragment. The initial tether is unstable but is quickly strengthened by additional MukBs. DNA bridging is modulated but is not strictly dependent on ATP and MukEF. The reaction revealed high preference for right‐handed DNA crossings indicating that bridging involves physical association of MukB with both DNAs. Our data establish a comprehensive view of DNA bridging by MukBEF, which could explain how SMCs establish both intra‐ and interchromosomal links inside the cell and indicate that DNA binding and bridging could be separately regulated.     

SMC proteins in bacteria: condensation motors for chromosome segregation?

SMC proteins are a ubiquitous protein family, present in almost all organisms so far analysed except for a few bacteria. They function in chromosome condensation, segregation, cohesion, and DNA recombination repair in eukaryotes, and can introduce positive writhe into DNA in vitro. SMC proteins and the structurally homologous MukB protein are unusual ATPases that form antiparallel dimers, with long coiled coil segments separating globular ends capable of binding DNA. Recently, SMC proteins have been shown to be essential for chromosome condensation, segregation and cell cycle progression in bacteria. Identification of a suppressor mutation for MukB in topoisomerase I in Escherichia coli suggests that SMC proteins are involved in negative DNA supercoiling in vivo, and by this means organize and compact chromosomes. A model is discussed in which bacterial SMC proteins act after an initial separation of replicated chromosome origins into the future daughter cell, separating sister chromatids by condensing replicated DNA strands within both cell halves. This would be analogous to a pulling of DNA strands into opposite cell halves by a condensation mechanism exerted at two specialised subregions in the cell.     

DNA binding proteins of rat thigh muscle: Purification and characterization of an endonuclease

Two major DNA binding proteins of molecular weights 34,000 and 38,000 have been identified in the 30,000 g supernatant (S-30) fraction of rat thigh muscle extracts. The presence of 38 KD DNA binding protein in the muscle S-30 could be demonstrated only if Triton X-100 treated extracts were used for Afinity chromatography suggesting that this protein may be a membrane associated DNA binding protein. The 38 KD DNA binding protein differed from the 34 KD DNA binding protein also in its chromatographic behaviour in DE-52 columns in which the 38 KD protein was retained, while the 34 KD protein came out in the flow-through in an electrophoretically pure form. The 34 KD DNA binding protein can also be purified by precipitation with MgCl₂. Incubation of 0 15 M NaCl eluates (containing the 38 KD and/or 34 KD DNA binding protein) in the presence of 100 mM Mg²⁺ resulted in the specific precipitation of the 34 KD protein. Prolonged incubation (30 days) of the 0.15 M NaCl eluates containing the two DNA binding proteins at 4°C led to the preferential degradation of the 34 KD DNA binding protein. Nitrocellulose filter binding assays indicated selective binding of purified 34 KD protein to ss DNA. Purified 34 KD DNA binding protein cleaved pBR 322 supercoiled DNA, and electrophoresis of the cleavage products in agarose gels revealed a major DNA band corresponding to the circular form of DNA.     

Rice proteins that bind single-stranded G-rich telomere DNA

In this work, we have identified and characterized proteins in rice nuclear extracts that specifically bind the single-stranded G-rich telomere sequence. Three types of specific DNA-protein complexes (I, II, and III) were identified by gel retardation assays using synthetic telomere substrates consisting of two or more single-stranded TTTAGGG repeats and rice nuclear extracts. Since each complex has a unique biochemical property and differs in electrophoretic mobility, at least three different proteins interact with the G-rich telomere sequences. These proteins are called rice G-rich telomere binding protein (RGBP) and none of them show binding affinity to double-stranded telomere repeats or single-stranded C-rich sequence. Changing one or two G's to C's in the TTTAGGG repeats abolishes binding activity. RGBPs have a greatly reduced affinity for human and Tetrahymena telomeric sequence and do not efficiently bind the cognate G-rich telomere RNA sequence UUUAGGG. Like other telomere binding proteins, RGBPs are resistant to high salt concentrations. RNase sensitivity of the DNA-protein interactions was tested to investigate whether an RNA component mediates the telomeric DNA-protein interaction. In this assay, we observed a novel complex (complex III) in gel retardation assays which did not alter the mobilities or the band intensities of the two pre-existing complexes (I and II). The complex III, in addition to binding to telomeric sequences, has a binding affinity to rice nuclear RNA, whereas two other complexes have a binding affinity to only single-stranded G-rich telomere DNA. Taken together, these studies suggest that RGBPs are new types of telomere-binding proteins that bind in vitro to single-stranded G-rich telomere DNA in the angiosperms.     

ATP Binding, ATP Hydrolysis, and Protein Dimerization Are Required for RecF to Catalyze an Early Step in the Processing and Recovery of Replication Forks Disrupted by DNA Damage

In Escherichia coli, the recovery of replication following disruption by UV-induced DNA damage requires the RecF protein and occurs through a process that involves stabilization of replication fork DNA, resection of nascent DNA to allow the offending lesion to be repaired, and reestablishment of a productive replisome on the DNA. RecF forms a homodimer and contains an ATP binding cassette ATPase domain that is conserved among eukaryotic SMC (structural maintenance of chromosome) proteins, including cohesin, condensin, and Rad50. Here, we investigated the functions of RecF dimerization, ATP binding, and ATP hydrolysis in the progressive steps involved in recovering DNA synthesis following disruption by DNA damage. RecF point mutations with altered biochemical properties were constructed in the chromosome. We observed that protein dimerization, ATP binding, and ATP hydrolysis were essential for maintaining and processing the arrested replication fork, as well as for restoring DNA synthesis. In contrast, stabilization of the RecF protein dimer partially protected the DNA at the arrested fork from degradation, although overall processing and recovery remained severely impaired.