Mechanism of DNA-binding loss upon single-point mutation in p53

Over 50% of all human cancers involve p53 mutations, which occur mostly in the sequence-specific DNA-binding central domain (p53c), yielding little/non-detectable affinity to the DNA consensus site. Despite our current understanding of protein-DNA recognition, the mechanism(s) underlying the loss in protein-DNA binding affinity/specificity upon single-point mutation are not well understood. Our goal is to identify the common factors governing the DNA-binding loss of p53c upon substitution of Arg 273 to His or Cys, which are abundant in human tumours. By computing the free energies of wild-type and mutant p53c binding to DNA and decomposing them into contributions from individual residues, the DNA-binding loss upon charge/noncharge-conserving mutation of Arg 273 was attributed not only to the loss of DNA phosphate contacts, but also to longer-range structural changes caused by the loss of the Asp 281 salt-bridge. The results herein and in previous works suggest that Asp 281 plays a critical role in the sequence-specific DNA-binding function of p53c by (i) orienting Arg 273 and Arg 280 in an optimal position to interact with the phosphate and base groups of the consensus DNA, respectively, and (ii) helping to maintain the proper DNA-binding protein conformation.     

Mechanism of DNA-binding loss upon single-point mutation in p53

Over 50% of all human cancers involve p53 mutations,which occur mostly in the sequence-specific DNA-binding central domain (p53c), yielding little/non-detectable af?nity to the DNA consensus site. Despite our current understanding of protein-DNA recognition,the mechanism(s) underlying the loss in protein-DNA binding afnity/ specificity upon single-point mutation are not well understood. Our goal is to identify the common factors governing the DNA-binding loss of p53c upon substitution of Arg 273 to His or Cys,which are abundant in human tumours. By computing the free energies of wild-type and mutant p53c binding to DNA and decomposing them into contributions from individual residues, the DNA-binding loss upon charge/noncharge -conserving mutation of Arg 273 was attributed not only to the loss of DNA phosphate contacts, but also to longer-range structural changes caused by the loss of the Asp 281 salt-bridge. The results herein and in previous works suggest that Asp 281 plays a critical role in the sequence-specific DNA-binding function of p53c by (i)orienting Arg 273 and Arg 280 in an optimal position to interact with the phosphate and base groups of the consensus DNA, respectively, and (ii) helping to maintain the proper DNA-binding protein conformation.     

DNA-binding activity of amino-terminal domains of the Bacillus subtilis AbrB protein

Two truncated variants of AbrB, comprising either its first 53 (AbrBN53) or first 55 (AbrBN55) amino acid residues, were constructed and purified. Noncovalently linked homodimers of the truncated variants exhibited very weak DNA-binding activity. Cross-linking AbrBN55 dimers into tetramers and higher-order multimers (via disulfide bonding between penultimate cysteine residues) resulted in proteins having DNA-binding affinity comparable to and DNA-binding specificity identical to those of intact, wild-type AbrB. These results indicate that the DNA recognition and specificity determinants of AbrB binding lie solely within its N-terminal amino acid sequence.     

Characterization of DNA-binding activity in the N-terminal domain of the DNA methyltransferase Dnmt3a

The Dnmt3a gene, which encodes de novo-type DNA methyltransferase, encodes two isoforms, full-length Dnmt3a and Dnmt3a2, which lacks the N-terminal 219 amino acid residues. We found that Dnmt3a showed higher DNA-binding and DNA-methylation activities than Dnmt3a2. The N-terminal sequence from residues 1 to 211 was able to bind to DNA, but could not distinguish methylated and unmethylated CpG. Its binding to DNA was inhibited by a major groove binder. Four basic amino acid residues, Lys51, Lys53, Arg177 and Arg179, in the N-terminal region were crucial for the DNA-binding activity. The ectopically expressed N-terminal sequence (residues 1-211) was localized in nuclei, whereas that harbouring mutations at the four basic amino acid residues was also detected in the cytoplasm. The DNA-methylation activity of Dnmt3a with the mutations was suppressed under physiological salt conditions, which is similar that of Dnmt3a2. In addition, ectopically expressed Dnmt3a with mutations, as well as Dnmt3a2, could not be retained efficiently in nuclei on salt extraction. We conclude that the DNA-binding activity of the N-terminal domain contributes to the DNA-methyltransferase activity via anchoring of the whole molecule to DNA under physiological salt conditions.     

Recognition of DNA by p53 core domain and location of intermolecular contacts of cooperative binding

We present an analysis by NMR of a 58 kDa complex of the core domain of the tumour suppressor p53 with DNA that complements and extends the crystal structure analysis. Binding of specific DNA caused significant chemical shifts of residues on the DNA-binding interface that translated into the beta-sheet of the protein. Binding of non-specific DNA caused weak but qualitatively the same shifts, corresponding to weaker binding interactions. The observed chemical shift differences correlate with frequency of cancer-inducing mutations, suggesting that the affected residues contribute to the stability of p53 core domain-DNA complex. We also identified two affected regions on the surface of the protein: helix 1 (residues V173-C182) plus G244 and residues L114-T118, which may represent a dimerisation interface.     

Identification of simian virus 40 T-antigen residues important for specific and nonspecific binding to DNA and for helicase activity.

We have previously identified three regions (called elements) in the DNA-binding domain of simian virus 40 large tumor (T) antigen which are critical for binding of the protein to the recognition pentanucleotides GAGGC at the viral replication origin. These are elements A (residues 147 to 159), B1 (185 to 187), and B2 (203 to 207). In this study, we generated mutants of simian virus 40 in order to make single-point substitution mutations at nearly every site in these three elements. Each mutation was tested for its effect on virus replication, and T antigen was produced from all replication-negative mutants. The mutant proteins were assayed for binding to several different DNA substrates and for helicase activity. We found that within each element, mutations at some sites had major effects on DNA binding while mutations at other sites had moderate, mild, or minimal effects, suggesting that some residues are more important than others in mediating DNA binding. Furthermore, we provide evidence that certain residues in elements A and B2 (Ala-149, Phe-159, and His-203) participate in nonspecific double-stranded and helicase substrate (single-stranded) DNA binding while others (Ser-147, Ser-152, Asn-153, Thr-155, Arg-204, Val-205, and Ala-207) are involved in sequence-specific binding at the origin. The residues in element B1 (primarily Ser-185 and His-187) take part only in nonspecific DNA binding. The amino acids important for nonspecific DNA binding are also required for helicase activity, and we hypothesize that they make contact with the sugar-phosphate backbone of DNA. On the other hand, those involved in sequence-specific binding are not needed for helicase activity. Finally, our analysis showed that three residues (Asn-153 and Thr-155 in element A and Arg-204 in element B2) may be the most important for sequence-specific binding. They are likely to make direct or indirect contacts with the pentanucleotide sequences at the origin.     

Demonstration of the functional role of conserved Glu-Arg residues in the Staphylococcus aureus ferrichrome transporter

The features that govern the interaction of ligand binding proteins with membrane permeases of cognate ABC transporters are largely unknown. Using sequence alignments and structural modeling based on the structure of the Escherichia coli BtuCD vitamin B₁₂ transporter, we identified six conserved basic residues in the permease, comprised of FhuB and FhuG proteins, in the ferrichrome transporter of Staphylococcus aureus. Using alanine-scanning mutagenesis we demonstrate that two of these residues, FhuB Arg-71 and FhuG Arg-61, play a more dominant role in transporter function than FhuB Arg-74 and Arg-311, and FhuG Arg-64 and Lys-306. Moreover, we show that at positions 71 and 61 in FhuB and FhuG, respectively, arginine cannot be substituted for lysine without loss of transporter function. Previously, our laboratory demonstrated the importance of conserved acidic residues in the ferrichrome binding protein, FhuD2. Taken together, these results support the hypothesis that Glu-Arg salt bridges are critical for the interaction of the ligand binding protein with the transmembrane domains FhuB and FhuG. This hypothesis was further studied by “charge swapping” experiments whereby we constructed a S. aureus strain expressing FhuD2 with conserved residues Glu-97 and Glu-231 replaced by Arg and FhuB and FhuG with conserved basic residues Arg-71 and Arg-61, respectively, replaced by Glu. A strain containing this combination of substitutions restored partial function to the ferrichrome transporter. The results provide a direct demonstration of the functional importance of conserved basic residues on the extracellular surface of the ferrichrome permease in the Gram-positive bacterium S. aureus.     

Site-directed mutagenesis study on DNA binding regions of the mouse homologue of Suppressor of Hairless, RBP-J kappa.

To map regions important for DNA binding of the mouse homologue of Suppressor of Hairless or RBP-J kappa protein, mutated mouse RBP-J kappa cDNAs were made by insertion of oligonucleotide linkers or base replacement. DNA binding assays using the mutated proteins expressed in COS cells showed that various mutations between 218 Arg and 227 Arg decreased the DNA binding activity drastically. The DNA binding activity was not affected by amino acid replacements within the integrase motif of the RBP-J kappa protein (230His-269His). Replacements between 291Arg and 323Tyr affected the DNA binding activity slightly but reproducibly. These results indicate that the region encompassing 218Arg-227Arg is critical for the DNA binding activity of RBP-J kappa. This region did not show any significant homology to motifs or domains of the previously described DNA binding proteins. Using a truncation mutant protein RBP-J kappa was shown to associate with DNA as a monomer.     

Important role of arginine 129 in heparin-binding site of antithrombin III. Identification of a novel mutation arginine 129 to glutamine

An hereditary abnormal antithrombin III (ATIII Geneva) with defective heparin cofactor activity was characterized by DNA single strand amplification and subsequent direct sequencing. ATIII Geneva was found to have a G to A transition in Exon IIIa leading to an Arg-129 to Gln mutation. This amino acid is part of the ATIII region comprising residues 114-154, which contains the highest proportion of basic residues (Arg or Lys), and is known from chemical modification studies to be involved in heparin binding. The variant protein did not bind heparin-Sepharose and was isolated from the propositus plasma by immunoaffinity chromatography. High affinity (for ATIII) heparin had only a minimal effect on thrombin and activated factor X inhibition by the purified abnormal ATIII. Taken together, these results demonstrate an important role for Arg-129 in the binding and interaction of ATIII with heparin of high affinity. We propose that a cooperation between Lys-125, Arg-129, Lys-136, and Arg-47 exposed at the surface of the inhibitor allows the binding of the essential pentasaccharide domain of heparin which is specific for the ATIII interaction.     

Mutational analysis of the nucleoid-associated protein HBsu of Bacillus subtilis

The essential nucleoid-associated protein HBsu of Bacillus subtilis comprises 92 residues, 20% of which are basic amino acids. To investigate the role of the residues located within the DNA-binding arm, the arginine residues R58 and R61 were changed to leucine, while lysine residues K80 and K86 were replaced by alanine. All altered proteins exhibited a reduction in DNA binding capacity, ranging from 10% to 30% of HBsu wild type DNA-binding ability. To investigate the physiological effect of these mutations in B. subtilis, the indigenous hbs gene was replaced by the mutated genes. B. subtilis strain PK20, which carries the HBsu mutation R58L which exhibits the lowest DNA binding ability in vitro, showed the strongest retardation of growth compared to the wild type. Furthermore, PK20 cells displayed an increased rate of cell lysis, diminished sporulation efficiency and a reduced level of negatively supercoiled DNA. These observations suggest that the DNA binding ability of HBsu DNA is important for growth and differentiation and influences DNA topology.     

Physical and functional interactions between human mitochondrial single-stranded DNA-binding protein and tumour suppressor p53

Single-stranded DNA-binding proteins (SSB) form a class of proteins that bind preferentially single-stranded DNA with high affinity. They are involved in DNA metabolism in all organisms and serve a vital role in replication, recombination and repair of DNA. In this report, we identify human mitochondrial SSB (HmtSSB) as a novel protein-binding partner of tumour suppressor p53, in mitochondria. It binds to the transactivation domain (residues 1–61) of p53 via an extended binding interface, with dissociation constant of 12.7 (± 0.7) μM. Unlike most binding partners reported to date, HmtSSB interacts with both TAD1 (residues 1–40) and TAD2 (residues 41–61) subdomains of p53. HmtSSB enhances intrinsic 3′-5′ exonuclease activity of p53, particularly in hydrolysing 8-oxo-7,8-dihydro-2′-deoxyguanosine (8-oxodG) present at 3′-end of DNA. Taken together, our data suggest that p53 is involved in DNA repair within mitochondria during oxidative stress. In addition, we characterize HmtSSB binding to ssDNA and p53 N-terminal domain using various biophysical measurements and we propose binding models for both.     

Effects of temperature on the p53-DNA binding interactions and their dynamical behavior: comparing the wild type to the R248Q mutant

Background

The protein p53 plays an active role in the regulation of cell cycle. In about half of human cancers, the protein is inactivated by mutations located primarily in its DNA-binding domain. Interestingly, a number of these mutations possess temperature-induced DNA-binding characteristics. A striking example is the mutation of Arg248 into glutamine or tryptophan. These mutants are defective for binding to DNA at 310 K although they have been shown to bind specifically to several p53 response elements at sub-physiological temperatures (298–306 K).

Methodology/Principal Findings

This important experimental finding motivated us to examine the effects of temperature on the structure and configuration of R248Q mutant and compare it to the wild type protein. Our aim is to determine how and where structural changes of mutant variants take place due to temperature changes. To answer these questions, we compared the mutant to the wild-type proteins from two different aspects. First, we investigated the systems at the atomistic level through their DNA-binding affinity, hydrogen bond networks and spatial distribution of water molecules. Next, we assessed changes in their long-lived conformational motions at the coarse-grained level through the collective dynamics of their side-chain and backbone atoms separately.

Conclusions

The experimentally observed effect of temperature on the DNA-binding properties of p53 is reproduced. Analysis of atomistic and coarse-grained data reveal that changes in binding are determined by a few key residues and provide a rationale for the mutant-loss of binding at physiological temperatures. The findings can potentially enable a rescue strategy for the mutant structure.     

An Escherichia coli DNA topoisomerase I mutant has a compensatory mutation that alters two residues between functional domains of the DNA gyrase A protein.

Nucleotide sequence analysis revealed that the compensatory gyrA mutation in Escherichia coli DM750 affects DNA supercoiling by interchanging the identities of Ala-569 and Thr-586 in the DNA gyrase A subunit. These residues flank Arg-571, a site for trypsin cleavage that splits gyrase A protein between DNA breakage-reunion and DNA-binding domains. The putative interdomain locations of the DM750 mutation and that of E. coli DM800 (in gyrase B protein) suggests that these compensatory mutations may reduce DNA supercoiling activity by altering allosteric interactions in the gyrase complex.     

Mutational analysis of the MutH protein from Escherichia coli

Site-directed mutagenesis was performed on several areas of MutH based on the similarity of MutH and PvuII structural models. The aims were to identify DNA-binding residues; to determine whether MutH has the same mechanism for DNA binding and catalysis as PvuII; and to localize the residues responsible for MutH stimulation by MutL. No DNA-binding residues were identified in the two flexible loop regions of MutH, although similar loops in PvuII are involved in DNA binding. Two histidines in MutH are in a similar position as two histidines (His-84 and His-85) in PvuII that signal for DNA binding and catalysis. These MutH histidines (His-112 and His-115) were changed to alanines, but the mutant proteins had wild-type activity both in vivo and in vitro. The results indicate that the MutH signal for DNA binding and catalysis remains unknown. Instead, a lysine residue (Lys-48) was found in the first flexible loop that functions in catalysis together with the three presumed catalytic amino acids (Asp-70, Glu-77, and Lys-79). Two deletion mutations (MutHDelta224 and MutHDelta214) in the C-terminal end of the protein, localized the MutL stimulation region to five amino acids (Ala-220, Leu-221, Leu-222, Ala-223, and Arg-224).