Ycs4 Subunit of Saccharomyces cerevisiae Condensin Binds DNA and Modulates the Enzyme Turnover

Condensins play a key role in higher order chromosome organization. In budding yeast Saccharomyces cerevisiae, a condensin complex consists of five subunits: two conserved structural maintenance of chromosome subunits, Smc2 and Smc4, a kleisin Brn1, and two HEAT repeat subunits, Ycg1, which possesses a DNA binding activity, and Ycs4, which can transiently associate with Smc4 and thereby disrupt its association with the Smc2 head. We characterized here DNA binding activity of the non-SMC subunits using an agnostic, model-independent approach. To this end, we mapped the DNA interface of the complex using sulfo-NHS biotin labeling. Besides the known site on Ycg1, we found a patch of lysines at the C-terminal domain of Ycs4 that were protected from biotinylation in the presence of DNA. Point mutations at the predicted protein-DNA interface reduced both Ycs4 binding to DNA and the DNA stimulated ATPase activity of the reconstituted condensin, whereas overproduction of the mutant Ycs4 was detrimental for yeast viability. Notably, the DNA binding site on Ycs4 partially overlapped with its interface with SMC4, revealing an intricate interplay between DNA binding, engagement of the Smc2-Smc4 heads, and ATP hydrolysis and suggesting a mechanism for ATP-modulated loading and translocation of condensins on DNA.

Small Molecule Condensin Inhibitors

Condensins play a unique role in orchestrating the global folding of the chromosome, an essential cellular process, and contribute to human disease and bacterial pathogenicity. As such, they represent an attractive and as yet untapped target for diverse therapeutic interventions. We describe here the discovery of small molecule inhibitors of the Escherichia coli condensin MukBEF. Pilot screening of a small diversity set revealed five compounds that inhibit the MukBEF pathway, two of which, Michellamine B and NSC260594, affected MukB directly. Computer-assisted docking suggested plausible binding sites for the two compounds in the hinge and head domains of MukB, and both binding sites were experimentally validated using mutational analysis and inspection of NSC260594 analogs. These results outline a strategy for the discovery of condensin inhibitors, identify druggable binding sites on the protein, and describe two small molecule inhibitors of condensins.

Biochemical Analysis of Bacterial Condensins

Condensins help establish compactness of bacterial chromosomes and assist in their segregation during cell growth and division. They act as elaborate macromolecular machines that organize the chromosome on a global scale and link it to the pan-cell dynamics. The mechanism of condensins in its entirety is yet to be elucidated. However, many aspects of condensin activity have been recuperated in vitro. This report described purification of the Escherichia coli condensin MukBEF, its reassembly from purified components, and reconstitution of DNA supercoiling and DNA bridging activities of the complex.

MukBEF, a chromosomal organizer

Global folding of bacterial chromosome requires the activity of condensins. These highly conserved proteins are involved in various aspects of higher-order chromatin dynamics in a diverse range of organisms. Two distinct superfamilies of condensins have been identified in bacteria. The SMC-ScpAB proteins bear significant homology to eukaryotic condensins and cohesins and are found in most of the presently sequenced bacteria. This review focuses on the MukBEF/MksBEF superfamily, which is broadly distributed across diverse bacteria and is characterized by low sequence conservation. The prototypical member of this superfamily, the Escherichia coli condensin MukBEF, continues to provide critical insights into the mechanism of the proteins. MukBEF acts as a complex molecular machine that assists in chromosome segregation and global organization. The review focuses on the mechanistic analysis of DNA organization by MukBEF with emphasis on its involvement in the formation of chromatin scaffold and plausible other roles in chromosome segregation.

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.

A new family of bacterial condensins

Condensins play a central role in global chromatin organization. In bacteria, two families of condensins have been identified, the MukBEF and SMC-ScpAB complexes. Only one of the two complexes is usually found in a given species, giving rise to a paradigm that a single condensin organizes bacterial chromosomes. Using sequence analysis, we identified a third family of condensins, MksBEF (MukBEF-like SMC proteins), which is broadly present in diverse bacteria. The proteins appear distantly related to MukBEF, have a similar operon organization and similar predicted secondary structures albeit with notably shorter coiled-coils. All three subunits of MksBEF exhibit significant sequence variation and can be divided into a series of overlapping subfamilies. MksBEF often coexists with the SMC-ScpAB, MukBEF and, sometimes, other MksBEFs. In Pseudomonas aeruginosa, both SMC and MksB contribute to faithful chromosome partitioning, with their inactivation leading to increased frequencies of anucleate cells. Moreover, MksBEF can complement anucleate cell formation in SMC-deficient cells. Purified PaMksB showed activities typical for condensins including ATP-modulated DNA binding and condensation. Notably, DNA binding by MksB is negatively regulated by ATP, which sets it apart from other known SMC proteins. Thus, several specialized condensins might be involved in organization of bacterial chromosomes.

MukB acts as a macromolecular clamp in DNA condensation

Correct folding of the chromosome into its highly ordered structure requires the action of condensins. The multisubunit condensins are highly conserved from bacteria to humans, and at their core they contain the characteristic V-shaped dimer of structural maintenance of chromosome proteins. The mechanism of DNA rearrangements by condensins remains unclear. Using magnetic tweezers, we show that bacterial condensin MukB acts as an ATP-modulated macromolecular assemblage in DNA condensation. Condensation occurs in a highly cooperative manner, resulting in the formation of force-resilient clusters. ATP regulates nucleation but not propagation of the clusters and seems to play a structural role. MukB clusters can further interact with each other, thereby bringing distant DNA segments together. The resulting activity has not previously been described among DNA-remodeling machines and may explain how the protein can organize the global structure of the chromosome.

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.

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.

Extended conformation of mammalian translation elongation factor 1A in solution

The conformation of mammalian elongation factor eEF1A in solution was examined by the small angle neutron scattering and scanning microcalorimetry. We have found that in contrast to the bacterial analogue the eEF1A molecule has no fixed rigid structure in solution. The radius of gyration of the eEF1A molecule (5.2 nm) is much greater than that of prokaryotic EF1A. The specific heat of denaturation is considerably lower for eEF1A than for EF1A, suggesting that the eEF1A conformation is significantly more disordered. Despite its flexible conformation, eEF1A is found to be highly active in different functional tests. According to the neutron scattering data, eEF1A becomes much more compact in the complex with uncharged tRNA. The absence of a rigid structure and the possibility of large conformational change upon interaction with a partner molecule could be important for eEF1A functioning in channeled protein synthesis and/or for the well-known capability of the protein to interact with different ligands besides the translational components.

Novel complexes of mammalian translation elongation factor eEF1A.GDP with uncharged tRNA and aminoacyl-tRNA synthetase. Implications for tRNA channeling

Multimolecular complexes involving the eukaryotic elongation factor 1A (eEF1A) have been suggested to play an important role in the channeling (vectorial transfer) of tRNA during protein synthesis [Negrutskii, B.S. & El'skaya, A.V. (1998) Prog. Nucleic Acids Res. Mol. Biol. 60, 47-78]. Recently we have demonstrated that besides performing its canonical function of forming a ternary complex with GTP and aminoacyl-tRNA, the mammalian eEF1A can produce a noncanonical ternary complex with GDP and uncharged tRNA [Petrushenko, Z.M., Negrutskii, B.S., Ladokhin, A.S., Budkevich, T.V., Shalak, V.F. & El'skaya, A.V. (1997) FEBS Lett. 407, 13-17]. The [eEF1A.GDP.tRNA] complex has been hypothesized to interact with aminoacyl-tRNA synthetase (ARS) resulting in a quaternary complex where uncharged tRNA is transferred to the enzyme for aminoacylation. Here we present the data on association of the [eEF1A.GDP.tRNA] complex with phenylalanyl-tRNA synthetase (PheRS), e.g. the formation of the above quaternary complex detected by the gel-retardation and surface plasmon resonance techniques. To estimate the stability of the novel ternary and quaternary complexes of eEF1A the fluorescence method and BIAcore analysis were used. The dissociation constants for the [eEF1A.GDP.tRNA] and [eEF1A.GDP.tRNAPhe.PheRS] complexes were found to be 20 nm and 9 nm, respectively. We also revealed a direct interaction of PheRS with eEF1A in the absence of tRNAPhe (Kd = 21 nm). However, the addition of tRNAPhe accelerated eEF1A.GDP binding to the enzyme. A possible role of these stable novel ternary and quaternary complexes of eEF1A.GDP with tRNA and ARS in the channeled elongation cycle is discussed.

[Comparative study of the reactability of phosphoric acid residues in tRNA(Ser) and tRNA(Leu) from Thermus thermophilus]

The reactivity of phosphates in the Thermus thermophilus tRNA(Ser) (GCU) and tRNA(Leu) (CAG) was studied using the ethylnitrosourea modification. It was shown that phosphates of nucleotides 58-60 (T loop), 20-22 (D loop), and 48 (at the junction of the variable and T stems) were poorly modified in both tRNAs. The most pronounced differences in the reactivity were observed for phosphates at the junctions of the variable stem with T-stem (47q, 49) and anticodon stem (45). This indicates differences in orientations of the long variable arm relative to the backbone in the tRNAs studied.

Three tRNA binding sites in rabbit liver ribosomes and role of the intrinsic ATPase in 80S ribosomes from higher eukaryotes

Three tRNA binding sites have been found in organisms of all domains (former kingdoms) with only one exception: Four binding sites have been reported for cytoplasmic 80S ribosomes from rabbit liver. Therefore, the issue was reconsidered, and the data revealed that rabbit liver ribosomes contain three tRNA binding sites, underlining the universal character of this ribosomal feature. Furthermore, a first analysis of the role of the ribosome intrinsic ATPase was performed. This ATPase is found in ribosomes of higher eukarya but not in lower eukarya such as yeast or ribosomes of the domains archea and bacteria. The results suggest that the intrinsic ATPase fulfills the same function as the essential third elongation factor EF-3, an ATPase in higher fungi (yeast etc.), that facilitates the release of the deacylated tRNA from the E site.

Evidence for the formation of an unusual ternary complex of rabbit liver EF-1alpha with GDP and deacylated tRNA

Eukaryotic translation elongation factor 1alpha is known to interact in GTP-bound form with aminoacyl-tRNA promoting its binding to the ribosome. In this paper another ternary complex [EF-1alpha*GDP*deacylated tRNA], never considered in widely accepted elongation schemes, is reported for the first time. The formation of this unusual complex, postulated earlier (FEBS Lett. (1996) 382, 18-20), has been detected by four independent methods. [EF-1alpha*GDP]-interacting sites are located in the acceptor stem, TpsiC stem and TpsiC loop of tRNA(Phe) and tRNA(Leu) molecules. Both tRNA and EF-1alpha are found to undergo certain conformational changes during their interaction. The ability of EF-1alpha to form a complex with deacylated tRNA indicates that the factor may perform an important role in tRNA and aminoacyl-tRNA channeling in higher eukaryotic cells.

[Determination of interacting segments of tRNA(Leu) from cow mammary glands with homologous aminoacyl-tRNA-synthetase by a chemical modification method]

The interaction of the cow mammary gland tRNA(IAGLeu), having a long variable loop, with the cognate aminoacyl-tRNA synthetase has been studied by the alkylation with ethylnitrosourea. It was shown that leucyl-tRNA synthetase protects from alkylation 3'-phosphates of the nucleotides 12-13 in D-loop, 23-24 in D-stem and 37-43 in the anticodon arm of tRNA(IAGLeu). All regions of interaction with the aminoacyl-tRNA synthetase are located in the same plane of tRNA whereas the long variable loop is in another plane.

[Determination of phosphate residues participating in the formation of the spatial structure of tRNA- Leu IAG from cow mammary glands]

The phosphates of the tRNA-Leu IAG from cow mammary gland (tRNA which has a long variable loop) participating in the formation of three-dimensional structure were studied by alkylation with ethylnitrosourea and methylnitrosourea. A low degree of modification was observed for the phosphates of the following nucleotides: 7, 8, 9, 10 (at the bend site between the acceptor and D-stem); 18, 19, 20A and 21 in the D-loop; 47H and 49 at the joint of variable and T-stem; 57, 58 and 59 in the T-loop.