64 Hoogsteen or not Hoogsteen? Iodine-125 radioprobing of the p53-induced DNA deformations

Radioprobing is suitable for tracing the DNA and RNA trajectories in nucleoprotein complexes in solution. The method is based on the analysis of the single-strand breaks produced by decay of iodine-125 incorporated in the C5 position of cytosine (Karamychev et al., 1999, 2012). Here, we used radioprobing to study the conformation of DNA in complex with the DNA binding domain (DBD) of the tumor-suppressor protein p53. Two recently crystallized DNA-p53 DBD complexes have different conformations of the CATG motifs: one with the Hoogsteen A:T pairs (Kitayner et al., 2010) and the other with the Watson–Crick pairs (Chen et al., 2010). The two complexes differ in the sequence of the central YYY|RRR junction: the first one has the C|G step and the second has the T|A step. Thus, it is interesting to apply the radioprobing method to the two DNA sequences used in crystallography to see if the local changes (T|A to C|G) in the center of the p53 response element would produce significant distortions in the CATG motifs. To this aim, the iodine-containing cytosine was incorporated in the duplexes containing p53-binding sites, in one of the two CATG motifs and the frequencies of DNA breaks were analyzed. Frequencies of breaks are negatively correlated with the iodine–sugar distances, thus, one can evaluate the changes in these distances upon DNA binding to a protein. The radioprobing distances obtained for both DNA sequences proved to be consistent with the Watson–Crick structure observed by Chen et al. (2010). We did not find any evidence of the Hoogsteen A:T base pair formation in the DNA-p53 DBD complexes in solution using our radioprobing method. The most significant changes in the break frequency distributions were detected in the central segment of the p53 binding site, YYY|RRR, which are consistent with an increase in DNA twisting in this region and local DNA bending and sliding (Nagaich et al., 1999). We interpret these p53-induced DNA deformations in the context of p53 binding to nucleosomal DNA (Sahu et al., 2010).     

An intron binding protein is required for transformation ability of p53.

Regulatory elements in intron sequences have been identified for several eukaryotic genes. The fourth intron of p53 is known to increase expression of p53 in a position dependent manner. We asked whether p53 intron 4 sequences interacted with DNA binding proteins to exact their effect. Three overlapping DNA fragments spanning the 5' end of p53 intron 4 were determined to specifically interact with protein in nuclear extracts from several cell lines by band shift analysis. Methylation interference experiments were used to identify purine residues involved in this protein-DNA interaction. Two G nucleotides were identified at intron 4 positions 33 and 44 and these were replaced by T and C, respectively. These two single base pair substitutions in the intron resulted in 1) lack of protein binding and 2) decreased expression of p53 as measured by a transformation assay. Thus the binding of protein to p53 intron 4 was shown to have functional significance. These experiments demonstrated a specific protein binding region in the 5' end of intron 4 critical for p53 expression and distinct from those elements already known to be involved in splicing.     

Molecular structure and flanking nucleotide sequences of the natural chicken ovomucoid gene

Five independent clones containing the natural chicken ovomucoid gene have been isolated from a chicken gene library. One of these clones, CL21, contains the complete ovomucoid gene and includes more than 3 kb of DNA sequences flanking both termini of the gene. Restriction endonuclease mapping, electron microscopy and direct DNA sequencing analyses of this clone have revealed that the ovomucoid gene is 5.6 kb long and codes for a messenger RNA of 821 nucleotides. The structural gene sequence coding Ifor the mature messenger RNA is split into at least eight segments by a minimum of seven intervening sequences of various sizes. The shortest structural gene segment is only 20 nucleotides long. All seven intervening sequences are located within the peptide coding region of the gene, and the sequences at the 5' and 3' untranslated regions of the mRNA are not interrupted by intervening sequences. The DNA sequences of the regions flanking the 5' and 3' termini of the gene have been determined. Thirty nucleotides before the start of the messenger RNA coding sequence is the heptanucleotide TATATAT, which is also present in a similar location relative to the chicken ovalbumin gene and other unique sequence eucaryotic genes. This sequence resembles that of the Pribnow box in procaryotic genes where a promoter function has been implicated. Seven nucleotides past the 3' end of the gene is the tetranucleotide TTGT, a sequence found to be present at identical locations as either TTTT or TTGT in other eucaryotic genes that have been sequenced. These conserved DNA sequences flanking eucaryotic genes may serve some regulator function in the expression of these genes.     

Changes in ascorbic acid content and ascorbate peroxidase activity during the development of Acetabularia mediterranea

We cloned ras-related sequences from goldfish genomic libraries constructed as recombinants using the lambda phage. Restriction enzyme mapping of the clones obtained revealed three kinds of ras-related sequences among approximately 350,000 genomic clones. One of these clones was partially sequenced. Comparison with the nucleotide sequences of mammalian ras genes showed that the determined sequences covered the predicted amino acid coding regions and parts of the intervening regions. The predicted amino acid sequences of the cloned ras-related goldfish gene suggested that the coding region is localized separately in DNA, and that its exon-intron boundaries are exactly the same as those of corresponding mammalian genes. The nucleotide and amino acid sequences of the goldfish ras-related gene may have extensive homologies to mammalian p 21 protein. Among the three mammalian ras proteins, the predicted amino acid sequence of the sequenced ras-related goldfish clone is most closely homologous (96%) to the Kirsten ras protein. Differences in the predicted amino acid sequence were greatest in the sequence predicted from the fourth exon; fewer differences were found in the sequence from the third exon, and only slight or no differences were found in the sequence predicted for the first and second exons. The 12th and 61st amino acids from the N-terminal of the protein, which are thought to be critical positions for GTP binding and catalysis, are both conserved in the goldfish protein.(ABSTRACT TRUNCATED AT 250 WORDS)     

Efficient specific DNA binding by p53 requires both its central and C-terminal domains as revealed by studies with high-mobility group 1 protein

The nonhistone chromosomal protein high-mobility group 1 protein (HMG-1/HMGB1) can serve as an activator of p53 sequence-specific DNA binding (L. Jayaraman, N. C. Moorthy, K. G. Murthy, J. L. Manley, M. Bustin, and C. Prives, Genes Dev. 12:462-472, 1998). HMGB1 is capable of interacting with DNA in a non-sequence-specific manner and causes a significant bend in the DNA helix. Since p53 requires a significant bend in the target site, we examined whether DNA bending by HMGB1 may be involved in its enhancement of p53 sequence-specific binding. Accordingly, a 66-bp oligonucleonucleotide containing a p53 binding site was locked in a bent conformation by ligating its ends to form a microcircle. Indeed, p53 had a dramatically greater affinity for the microcircle than for the linear 66-bp DNA. Moreover, HMGB1 augmented binding to the linear DNA but not to the microcircle, suggesting that HMGB1 works by providing prebent DNA to p53. p53 contains a central core sequence-specific DNA binding region and a C-terminal region that recognizes various forms of DNA non-sequence specifically. The p53 C terminus has also been shown to serve as an autoinhibitor of core-DNA interactions. Remarkably, although the p53 C terminus inhibited p53 binding to the linear DNA, it was required for the increased affinity of p53 for the microcircle. Thus, depending on the DNA structure, the p53 C terminus can serve as a negative or a positive regulator of p53 binding to the same sequence and length of DNA. We propose that both DNA binding domains of p53 cooperate to recognize sequence and structure in genomic DNA and that HMGB1 can help to provide the optimal DNA structure for p53.     

Searching for target sequences by p53 protein is influenced by DNA length

One of the most important functions of the tumor suppressor p53 protein is its sequence-specific binding to DNA. Using a competition assay on agarose gels we found that the p53 consensus sequences in longer DNA fragments are better targets than the same sequences in shorter DNAs. Semi-quantitative evaluation of the competition experiments showed a correlation between the relative p53-DNA binding and the DNA lengths. Our results are consistent with a model of the p53-DNA interactions involving one-dimensional migration of the p53 protein along the DNA for distances of about 1000 bp while searching for its target sites. Positioning of the p53 target in the DNA fragment did not substantially affect the apparent p53-DNA binding, suggesting that p53 can slide along the DNA in a bi-directional manner. In contrast to full-length p53, the isolated core domain did not show any significant correlation between sequence-specific DNA binding and fragment length.     

Analysis of a drosophila tRNA gene cluster: two tRNALeu genes contain intervening sequences

A recombinant DNA phage containing a cluster of Drosophila melanogaster tRNA genes has been isolated and analyzed. The insert of this phage has been mapped by in situ hybridization to chromosomal region 50AB, a known tRNA site. Nucleotide sequencing of the entire Drosophila tRNA coding region reveals seven tRNA genes spanning 2.5 kb of chromosomal DNA. This cluster is separated from other tRNA regions on the chromosome by at least 2.7 kb on one side, and 9.6 kb on the other. Two tRNA genes are nearly identical and contain intervening sequences of length 38 and 45 bases, respectively, in the anticodon loop. These two genes are assigned to be tRNALeu genes because of significant sequence homology with yeast tRNA3Leu, and secondary structure homology with yeast tRNA3Leu intervening sequence. In addition, an 8 base sequence (AAAAUCUU) is conserved in the same location in the intervening sequences of Drosophila tRNALeu genes and a yeast tRNA3Leu gene. Similar sequenes occur in all other tRNAs containing intervening sequences. The remaining five genes are identical tRNAIle genes, which are also identical to a tRNAIle gene from chromosomal region 42A. The 5' flanking regions are only weakly homologous, but each set of isoacceptors contains short regions of strong homology approximately 20 nucleotides preceding the tRNA coding sequences: GCNTTTTG preceding tRNAIle genes; and GANTTTGG preceding tRNALeu genes. The genes are irregularly distributed on both DNA strands; spacing regions are divergent in sequence and length.     

Complete nucleotide sequence of mouse immunoglobulin mu gene and comparison with other immunoglobulin heavy chain genes

We have determined the complete nucleotides sequence (2168 bases) of the immunoglobulin mu gene cloned from newborn mouse DNA. The cloned 13kb fragment contained the entire constant region gene sequence that is interrupted by three intervening sequences at the junction of domains as previously shown in the gamma 1, gamma 2 b and alpha genes. The amino acid sequence predicted by the nucleotide sequence agrees with that of the mu chain secreted by a myeloma MOPC104E except for 8 residues out of 448 residues. The homologous domains of the mu, gamma 1 and gamma 2b genes are more similar to each other than the different domains of the mu genes are. The result implicates that the class of the immunoglobulin heavy chain genes diverged after the heavy chain genes established the multi-domain structure. The short intervening sequences of the mu and gamma genes are more conserved than the coding sequences except for the COOH-terminal domains. The results implicate that the nucleotide sequence of the intervening sequence is under selective pressure, possibly to maintain a secondary structure of the nuclear RNA to be spliced.     

Structure of the rat prolactin gene

The organization and sequence of the rat preprolactin gene has been investigated. Analysis of two different plasmids containing pituitary cDNA inserts has provided the complete 681-nucleotide coding sequence of preprolactin as well as 17 nucleotides preceding the initiation codon and 90 nucleotides following the termination codon. Digestion of rat chromosomal DNA with the restriction endonuclease Eco RI followed by size fractionation and hybridization to a labeled prolactin cDNA probe has demonstrated that prolactin genomic sequences are located on 6.0-, 3.9-, and 2.9-kilobase fragments. The 6.0- and 3.9-kilobase fragments were isolated from a library of cloned rat DNA fragments. The sequence of more than 1800 nucleotides of the cloned DNA has been determined. The sequenced region contains coding regions of 180 and 189 nucleotides which specify the COOH-terminal 123 amino acids of the 227-amino-acid sequence of rat preprolactin. These coding regions are separated by an intervening sequence of 597 nucleotides. At least one other large intervening sequence separates this region from the region coding for the NH2-terminal portion of preprolactin. Hybridization experiments suggested that the intervening sequences of the rat prolactin gene contain DNA sequences which are repeated elsewhere in the rat genome.