Mismatch repair in methylated DNA. Structure and activity of the mismatch-specific thymine glycosylase domain of methyl-CpG-binding protein MBD4

MBD4 is a member of the methyl-CpG-binding protein family. It contains two DNA binding domains, an amino-proximal methyl-CpG binding domain (MBD) and a C-terminal mismatch-specific glycosylase domain. Limited in vitro proteolysis of mouse MBD4 yields two stable fragments: a 139-residue fragment including the MBD, and the other 155-residue fragment including the glycosylase domain. Here we show that the latter fragment is active as a glycosylase on a DNA duplex containing a G:T mismatch within a CpG sequence context. The crystal structure confirmed the C-terminal domain is a member of the helix-hairpin-helix DNA glycosylase superfamily. The MBD4 active site is situated in a cleft that likely orients and binds DNA. Modeling studies suggest the mismatched target nucleotide will be flipped out into the active site where candidate residues for catalysis and substrate specificity are present.     

Solution structure and intramolecular exchange of methyl-cytosine binding domain protein 4 (MBD4) on DNA suggests a mechanism to scan for mCpG/TpG mismatches

Unlike other members of the methyl-cytosine binding domain (MBD) family, MBD4 serves as a potent DNA glycosylase in DNA mismatch repair specifically targeting ^mCpG/TpG mismatches arising from spontaneous deamination of methyl-cytosine. The protein contains an N-terminal MBD (MBD4_MBD) and a C-terminal glycosylase domain (MBD4_GD) separated by a long linker. This arrangement suggests that the MBD4_MBD either directly augments enzymatic catalysis by the MBD4_GD or targets the protein to regions enriched for ^mCpG/TpG mismatches. Here we present structural and dynamic studies of MBD4_MBD bound to dsDNA. We show that MBD4_MBD binds with a modest preference for^mCpG as compared to mismatch, unmethylated and hydroxymethylated DNA. We find that while MBD4_MBD exhibits slow exchange between molecules of DNA (intermolecular exchange), the domain exhibits fast exchange between two sites in the same molecule of dsDNA (intramolecular exchange). Introducing a single-strand defect between binding sites does not greatly reduce the intramolecular exchange rate, consistent with a local hopping mechanism for moving along the DNA. These results support a model in which the MBD4_MBD4 targets the intact protein to ^mCpG islands and promotes scanning by rapidly exchanging between successive ^mCpG sites which facilitates repair of nearby ^mCpG/TpG mismatches by the glycosylase domain.     

DNA binding restricts the intrinsic conformational flexibility of methyl CpG binding protein 2 (MeCP2)

Mass spectrometry-based hydrogen/deuterium exchange (H/DX) has been used to define the polypeptide backbone dynamics of full-length methyl CpG binding protein 2 (MeCP2) when free in solution and when bound to unmethylated and methylated DNA. Essentially the entire MeCP2 polypeptide chain underwent H/DX at rates faster than could be measured (i.e. complete exchange in ≤10 s), with the exception of the methyl DNA binding domain (MBD). Even the H/DX of the MBD was rapid compared with that of a typical globular protein. Thus, there is no single tertiary structure of MeCP2. Rather, the full-length protein rapidly samples many different conformations when free in solution. When MeCP2 binds to unmethylated DNA, H/DX is slowed several orders of magnitude throughout the MBD. Binding of MeCP2 to methylated DNA led to additional minor H/DX protection, and only locally within the N-terminal portion of the MBD. H/DX also was used to examine the structural dynamics of the isolated MBD carrying three frequent mutations associated with Rett syndrome. The effects of the mutations ranged from very little (R106W) to a substantial increase in conformational sampling (F155S). Our H/DX results have yielded fine resolution mapping of the structure of full-length MeCP2 in the absence and presence of DNA, provided a biochemical basis for understanding MeCP2 function in normal cells, and predicted potential approaches for the treatment of a subset of RTT cases caused by point mutations that destabilize the MBD.     

Crystal structure of the mismatch-specific thymine glycosylase domain of human methyl-CpG-binding protein MBD4

Methyl-CpG (mCpG) binding domain protein 4 (MBD4) is a member of mammalian DNA glycosylase superfamily. It contains an amino-proximal methyl-CpG binding domain (MBD) and a C-terminal mismatch-specific glycosylase domain, which is an important molecule believed to be involved in maintaining of genome stability. Herein, we determined the crystal structure of C-terminal glycosylase domain of human MBD4. And the structural alignments of other helix-hairpin-helix (HhH) DNA glycosylases show that the human MBD4 glycosylase domain has the similar active site and the catalytic mechanisms as others. But the different residues in the N-terminal of domain result in the change of charge distribution on the surface of the protein, which suggest the different roles that may relate some diseases.     

Probing the Dynamic Distribution of Bound States for Methylcytosine-binding Domains on DNA

Although highly homologous to other methylcytosine-binding domain (MBD) proteins, MBD3 does not selectively bind methylated DNA, and thus the functional role of MBD3 remains in question. To explore the structural basis of its binding properties and potential function, we characterized the solution structure and binding distribution of the MBD3 MBD on hydroxymethylated, methylated, and unmethylated DNA. The overall fold of this domain is very similar to other MBDs, yet a key loop involved in DNA binding is more disordered than previously observed. Specific recognition of methylated DNA constrains the structure of this loop and results in large chemical shift changes in NMR spectra. Based on these spectral changes, we show that MBD3 preferentially localizes to methylated and, to a lesser degree, unmethylated cytosine-guanosine dinucleotides (CpGs), yet does not distinguish between hydroxymethylated and unmethylated sites. Measuring residual dipolar couplings for the different bound states clearly shows that the MBD3 structure does not change between methylation-specific and nonspecific binding modes. Furthermore, residual dipolar couplings measured for MBD3 bound to methylated DNA can be described by a linear combination of those for the methylation and nonspecific binding modes, confirming the preferential localization to methylated sites. The highly homologous MBD2 protein shows similar but much stronger localization to methylated as well as unmethylated CpGs. Together, these data establish the structural basis for the relative distribution of MBD2 and MBD3 on genomic DNA and their observed occupancy at active and inactive CpG-rich promoters.     

A novel RNA binding surface of the TAM domain of TIP5/BAZ2A mediates epigenetic regulation of rRNA genes

The chromatin remodeling complex NoRC, comprising the subunits SNF2h and TIP5/BAZ2A, mediates heterochromatin formation at major clusters of repetitive elements, including rRNA genes, centromeres and telomeres. Association with chromatin requires the interaction of the TAM (TIP5/ARBP/MBD) domain of TIP5 with noncoding RNA, which targets NoRC to specific genomic loci. Here, we show that the NMR structure of the TAM domain of TIP5 resembles the fold of the MBD domain, found in methyl-CpG binding proteins. However, the TAM domain exhibits an extended MBD fold with unique C-terminal extensions that constitute a novel surface for RNA binding. Mutation of critical amino acids within this surface abolishes RNA binding in vitro and in vivo. Our results explain the distinct binding specificities of TAM and MBD domains to RNA and methylated DNA, respectively, and reveal structural features for the interaction of NoRC with non-coding RNA.     

Stable binding of recA protein to duplex DNA. Unraveling a paradox

recA protein binding to duplex DNA is a complicated, multistep process. The final product of this process is a stably bound complex of recA protein and extensively unwound double-stranded DNA. recA monomers within the complex hydrolyze ATP with an apparent kcat of approximately 19-22 min-1. Once the final binding state is achieved, binding and ATP hydrolysis by this complex becomes pH independent. The weak binding of recA protein to duplex DNA reported in previous studies does not, therefore, reflect an intrinsically unfavorable binding equilibrium. Instead, this apparent weak binding reflects a slow step in the association pathway. The rate-limiting step in this process involves the initiation rather than the propagation of DNA binding and unwinding. This step exhibits no dependence on recA protein concentration at pH 7.5. Extension or propagation of the recA filament is fast relative to the overall process. Initiation of binding is pH dependent and represents a prominent kinetic barrier at pH 7.5. ATP hydrolysis occurs only after the duplex DNA is unwound. The binding density of recA protein on double-stranded DNA is approximately one monomer/4 base pairs. A model for this process is presented. These results provide an explanation for several paradoxical observations about recA protein-promoted DNA strand exchange. In particular, they demonstrate that there is no thermodynamic requirement for dissociation of recA protein from the heteroduplex DNA product of strand exchange.     

Dissection of the methyl-CpG binding domain from the chromosomal protein MeCP2.

MeCP2 is a chromosomal protein which binds to DNA that is methylated at CpG. In situ immunofluorescence in mouse cells has shown that the protein is most concentrated in pericentromeric heterochromatin, suggesting that MeCP2 may play a role in the formation of inert chromatin. Here we have isolated a minimal methyl-CpG binding domain (MBD) from MeCP2. MBD is 85 amino acids in length, and binds exclusively to DNA that contains one or more symmetrically methylated CpGs. MBD has negligable non-specific affinity for DNA, confirming that non-specific and methyl-CpG specific binding domains of MeCP2 are distinct. In vitro footprinting indicates that MBD binding can protect a 12 nucleotide region surrounding a methyl-CpG pair, with an approximate dissociation constant of 10(-9) M.