Yana S. Kovacheva scite author profile

Many proteins that interact with DNA perform or enhance their specific functions by binding simultaneously to multiple target sites, thereby inducing a loop in the DNA. The dynamics and energies involved in this loop formation influence the reaction mechanism. Tethered particle motion has proven a powerful technique to study in real time protein-induced DNA looping dynamics while minimally perturbing the DNA–protein interactions. In addition, it permits many single-molecule experiments to be performed in parallel. Using as a model system the tetrameric Type II restriction enzyme SfiI, that binds two copies of its recognition site, we show here that we can determine the DNA–protein association and dissociation steps as well as the actual process of protein-induced loop capture and release on a single DNA molecule. The result of these experiments is a quantitative reaction scheme for DNA looping by SfiI that is rigorously compared to detailed biochemical studies of SfiI looping dynamics. We also present novel methods for data analysis and compare and discuss these with existing methods. The general applicability of the introduced techniques will further enhance tethered particle motion as a tool to follow DNA–protein dynamics in real time.

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A Switch in the Mechanism of Communication between the Two DNA-Binding Sites in the SfiI Restriction Endonuclease

Bellamy

Milsom

Kovacheva

et al. 2007

Journal of Molecular Biology

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While many Type II restriction enzymes are dimers with a single DNA-binding cleft between the subunits, SfiI is a tetramer of identical subunits. Two of its subunits (a dimeric unit) create one DNA-binding cleft, and the other two create a second cleft on the opposite side of the protein. The two clefts bind specific DNA cooperatively to give a complex of SfiI with two recognition sites. This complex is responsible for essentially all of the DNA-cleavage reactions by SfiI: virtually none is due to the complex with one site. The communication between the DNA-binding clefts was examined by disrupting one of the very few polar interactions in the otherwise hydrophobic interface between the dimeric units: a tyrosine hydroxyl was removed by mutation to phenylalanine. The mutant protein remained tetrameric in solution and could bind two DNA sites. But instead of being activated by binding two sites, like wild-type SfiI, it showed maximal activity when bound to a single site and had a lower activity when bound to two sites. This interaction across the dimer interface thus enforces in wild-type SfiI a cooperative transition between inactive and active states in both dimers, but without this interaction as in the mutant protein, a single dimer can undergo the transition to give a stable intermediate with one inactive dimer and one active dimer.

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Differences between Ca 2+ and Mg 2+ in DNA binding and release by the SfiI restriction endonuclease: implications for DNA looping

Bellamy¹,

Kovacheva²,

Zulkipli³

et al. 2009

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Many enzymes acting on DNA require Mg2+ ions not only for catalysis but also to bind DNA. Binding studies often employ Ca2+ as a substitute for Mg2+, to promote DNA binding whilst disallowing catalysis. The SfiI endonuclease requires divalent metal ions to bind DNA but, in contrast to many systems where Ca2+ mimics Mg2+, Ca2+ causes SfiI to bind DNA almost irreversibly. Equilibrium binding by wild-type SfiI cannot be conducted with Mg2+ present as the DNA is cleaved so, to study the effect of Mg2+ on DNA binding, two catalytically-inactive mutants were constructed. The mutants bound DNA in the presence of either Ca2+ or Mg2+ but, unlike wild-type SfiI with Ca2+, the binding was reversible. With both mutants, dissociation was slow with Ca2+ but was in one case much faster with Mg2+. Hence, Ca2+ can affect DNA binding differently from Mg2+. Moreover, SfiI is an archetypal system for DNA looping; on DNA with two recognition sites, it binds to both sites and loops out the intervening DNA. While the dynamics of looping cannot be measured with wild-type SfiI and Ca2+, it becomes accessible with the mutant and Mg2+.

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The role of phosphate groups in the VS ribozyme-substrate interaction

Kovacheva¹

2004

Nucleic Acids Research

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The VS ribozyme trans-cleavage substrate interacts with the catalytic RNA via tertiary interactions. To study the role of phosphate groups in the ribozyme-substrate interaction, 18 modified substrates were synthesized, where an epimeric phosphorothioate replaces one of the phosphate diester linkages. Sites in the stem-loop substrate where phosphorothioate substitution impaired reaction cluster in two regions. The first site is the scissile phosphate diester linkage and nucleotides downstream of this and the second site is within the loop region. The addition of manganese ions caused recovery of the rate of reaction for phosphorothioate substitutions between A621 and A622 and U631 and C632, suggesting that these two phosphate groups may serve as ligands for two metal ions. In contrast, significant manganese rescue was not observed for the scissile phosphate diester linkage implying that electrophilic catalysis by metal ions is unlikely to contribute to VS ribozyme catalysis. In addition, an increase in the reaction rate of the unmodified VS ribozyme was observed when a mixture of magnesium and manganese ions acted as the cofactor. One possible explanation for this effect is that the cleavage reaction of the VS ribozyme is rate limited by a metal dependent docking of the substrate on the ribozyme.

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The Impact of Bending and Twisting Rigidity of DNA on Protein Induced Looping Dynamics

Laurens

Pernstich

Catto

et al. 2009

Biophysical Journal

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Nano-sized fullerene aggregates can enter cells and alter their functions, but the mechanisms of cell damage is unclear. In our previous work [1] we used coarsegrained molecular dynamics simulations to characterize the thermodynamics and kinetics of permeation of fullerene clusters through a model membrane. We also showed that high fullerene concentrations induce changes in the structural and elastic properties of the lipid bilayer, but these are not sufficient to cause a direct mechanical damage to the membrane. Now we explore the effect of fullerene on model membranes including an ion channel protein, Kv1.2, using computer simulations with both a coarse-grained and an atomistic representation. We also investigate the effects of a naturally abundant organic compound, gallic acid, on fullerene-membrane interactions. Recent work [2] has shown that gallic acid-coated fullerenes cause cell contraction. We use computer simulations to describe possible mechanisms of cell damage.[1] Wong-ekkabut et al., Nature Nanotech (2008), 3, 363. [2] Salonen et al., Small, in press.

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Yana S. Kovacheva

Dissecting protein-induced DNA looping dynamics in real time

A Switch in the Mechanism of Communication between the Two DNA-Binding Sites in the SfiI Restriction Endonuclease

Differences between Ca 2+ and Mg 2+ in DNA binding and release by the SfiI restriction endonuclease: implications for DNA looping

The role of phosphate groups in the VS ribozyme-substrate interaction

The Impact of Bending and Twisting Rigidity of DNA on Protein Induced Looping Dynamics

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