Interaction of Individual Structural Domains of hnRNP LL with the BCL2 Promoter i-Motif DNA.

The recently discovered role of the BCL2 (B-cell lymphoma 2 gene) promoter i-motif DNA in modulation of gene expression via interaction with the ribonucleoprotein hnRNP L-like (hnRNP LL) has prompted a more detailed study of the nature of this protein-DNA interaction. The RNA recognition motifs (RRMs) of hnRNP LL were expressed individually, and both RRM1 and RRM2 were found to bind efficiently to the BCL2 i-motif DNA, as well as being critical for transcriptional activation, whereas RRM3-4 bound only weakly to this DNA. Binding was followed by unfolding of the DNA as monitored by changes in the CD spectrum. Mutational analysis of the i-motif DNA revealed that binding involved primarily the lateral loops of the i-motif. The kinetics of binding of the DNA with RRM1 was explored by recording CD spectra at predetermined times following admixture of the protein and DNA. The change in molar ellipticity was readily apparent after 30 s and largely complete within 1 min. A more detailed view of protein-DNA interaction was obtained by introducing the fluorescence donor 6-CNTrp in RRM1 at position 137, and the acceptor 4-aminobenzo[g]quinazoline-2-one (Cf) in lieu of cytidine22 in the i-motif DNA. The course of binding of the two species was monitored by FRET, which reflected a steady increase in energy transfer over a period of several minutes. The FRET signal could be diminished by the further addition of (unlabeled) RRM2, no doubt reflecting competition for binding to the i-motif DNA. These experiments using the individual RRM domains from hnRNP LL confirm the role of this transcription factor in activation of BCL2 transcription via the i-motif in the promoter element.

Cyanotryptophans as Novel Fluorescent Probes for Studying Protein Conformational Changes and DNA-Protein Interaction.

Described herein are the syntheses and photophysical characterization of three novel cyanotryptophans, and their efficient incorporation into proteins as fluorescent probes. Photophysical characteristics indicated that each was significantly brighter and red-shifted in fluorescence emission relative to tryptophan. Each analogue was used to activate a suppressor tRNA transcript and was incorporated with good efficiency into two different positions (Trp22 and Trp74) of Escherichia coli dihydrofolate reductase (ecDHFR). The Trp analogues could be monitored selectively in the presence of multiple native Trp residues in DHFR. 6-CNTrp (A) formed an efficient Förster resonance energy transfer (FRET) pair with l-(7-hydroxycoumarin-4-yl)ethylglycine (HCO, D) at position 17. Further, 6-CNTrp (A) was incorporated into two DNA binding proteins, including the Klenow fragment of DNA polymerase I and an RNA recognition motif (RRM2) of heterogeneous nuclear ribonucleoprotein L-like (hnRNP LL). Using these proteins, we demonstrated the use of FRET involving A as a fluorescence donor and benzo[g]quinazoline-2,4-(1H,3H)-dione 2'-deoxyriboside (Tf) or 4-aminobenzo[g]quinazoline-2-one 2'-deoxyriboside (Cf) as fluorescent acceptors to study the binding interaction of the Klenow fragment with duplex DNA oligomers (labeled with Tf), or the domain-specific association between hnRNP LL and the BCL2 i-motif DNA (labeled with Cf). Thus, the non-natural amino acid could be used as a FRET partner for studying protein-nucleic acid interactions. Together, these findings demonstrate the potential utility of 6-CNTrp (A) as a fluorescence donor for the study of protein conformational events.

Differential nuclease sensitivity profiling of chromatin reveals biochemical footprints coupled to gene expression and functional DNA elements in maize.

The eukaryotic genome is organized into nucleosomes, the fundamental units of chromatin. The positions of nucleosomes on DNA regulate protein-DNA interactions and in turn influence DNA-templated events. Despite the increasing number of genome-wide maps of nucleosome position, how global changes in gene expression relate to changes in nucleosome position is poorly understood. We show that in nucleosome occupancy mapping experiments in maize (Zea mays), particular genomic regions are highly susceptible to variation introduced by differences in the extent to which chromatin is digested with micrococcal nuclease (MNase). We exploited this digestion-linked variation to identify protein footprints that are hypersensitive to MNase digestion, an approach we term differential nuclease sensitivity profiling (DNS-chip). Hypersensitive footprints were enriched at the 5' and 3' ends of genes, associated with gene expression levels, and significantly overlapped with conserved noncoding sequences and the binding sites of the transcription factor KNOTTED1. We also found that the tissue-specific regulation of gene expression was linked to tissue-specific hypersensitive footprints. These results reveal biochemical features of nucleosome organization that correlate with gene expression levels and colocalize with functional DNA elements. This approach to chromatin profiling should be broadly applicable to other species and should shed light on the relationships among chromatin organization, protein-DNA interactions, and genome regulation.

A short DNA sequence confers strong bleomycin binding to hairpin DNAs.

Bleomycins A5 and B2 were used to study the structural features in hairpin DNAs conducive to strong BLM-DNA interaction. Two members of a 10-hairpin DNA library previously found to bind most tightly to these BLMs were subsequently noted to share the sequence 5'-ACGC (complementary strand sequence 5'-GCGT). Each underwent double-strand cleavage at five sites within, or near, an eight base pair region of the DNA duplex which had been randomized to create the original library. A new hairpin DNA library was selected based on affinity for immobilized Fe(III)·BLM A5. Two of the 30 newly identified DNAs also contained the sequence 5'-ACGC/5'-GCGT. These DNAs bound to the Fe(II)·BLMs more tightly than any DNA characterized previously. Surface plasmon resonance confirmed tight Fe(III)·BLM B2 binding and gave an excellent fit for a 1:1 binding model, implying the absence of significant secondary binding sites. Fe(II)·BLM A5 was used to assess sites of double-strand DNA cleavage. Both hairpin DNAs underwent double-strand cleavage at five sites within or near the original randomized eight base region. For DNA 12, four of the five double-strand cleavages involved independent single-strand cleavage reactions; DNA 13 underwent double-strand DNA cleavage by independent single-strand cleavages at all five sites. DNA 14, which bound Fe·BLM poorly, was converted to a strong binder (DNA 15) by insertion of the sequence 5'-ACGC/5'-GCGT. These findings reinforce the idea that tighter DNA binding by Fe·BLM leads to increased double-strand cleavage by a novel mechanism and identify a specific DNA motif conducive to strong BLM binding and cleavage.

DNA methylation reduces binding and cleavage by bleomycin.

In a recent study, we described the enhanced double-strand cleavage of hairpin DNAs by Fe·bleomycin (Fe·BLM) that accompanies increasingly strong binding of this antitumor agent and suggested that this effect may be relevant to the mechanism by which BLM mediates its antitumor effects. Because the DNA in tumor cells is known to be hypomethylated on cytidine relative to that in normal cells, it seemed of interest to study the possible effects of methylation status on BLM-induced double-strand DNA cleavage. Three hairpin DNAs found to bind strongly to bleomycin, and their methylated counterparts, were used to study the effect of methylation on bleomycin-induced DNA degradation. Under conditions of limited DNA cleavage, there was a significant overall decrease in the cleavage of methylated hairpin DNAs. Cytidine methylation was found to result in decreased BLM-induced cleavage at the site of methylation and to result in enhanced cleavage at adjacent nonmethylated sites. For two of the three hairpin DNAs studied, methylation was accompanied by a dramatic decrease in the binding affinity for Fe·BLM, suggesting the likelihood of diminished double-strand cleavage. The source of the persistent binding of BLM by the third hairpin DNA was identified. Also identified was the probable molecular mechanism for diminished binding and cleavage of the methylated DNAs by BLM. The possible implications of these findings for the antitumor selectivity of bleomycin are discussed.

The dynamic character of the BCL2 promoter i-motif provides a mechanism for modulation of gene expression by compounds that bind selectively to the alternative DNA hairpin structure.

It is generally accepted that DNA predominantly exists in duplex form in cells. However, under torsional stress imposed by active transcription, DNA can assume nonduplex structures. The BCL2 promoter region forms two different secondary DNA structures on opposite strands called the G-quadruplex and the i-motif. The i-motif is a highly dynamic structure that exists in equilibrium with a flexible hairpin species. Here we identify a pregnanol derivative and a class of piperidine derivatives that differentially modulate gene expression by stabilizing either the i-motif or the flexible hairpin species. Stabilization of the i-motif structure results in significant upregulation of the BCL2 gene and associated protein expression; in contrast, stabilization of the flexible hairpin species lowers BCL2 levels. The BCL2 levels reduced by the hairpin-binding compound led to chemosensitization to etoposide in both in vitro and in vivo models. Furthermore, we show antagonism between the two classes of compounds in solution and in cells. For the first time, our results demonstrate the principle of small molecule targeting of i-motif structures in vitro and in vivo to modulate gene expression.