Local mobility of nucleic acids as determined from crystallographic data. III. A daunomycin-DNA complex

The local mobility of the complex between the anti-tumor drug daunomycin and a DNA hexanucleotide duplex of sequence d(CpGpTpApCpG)2 has been determined by anisotropic refinement of single crystal X-ray diffraction data of 1.2 A resolution (1 A = 0.1 nm). The directions and amplitudes of the local motion indicate that changes in mobility of DNA due to daunomycin binding are primarily limited to the residues forming the intercalation site and do not propagate to the neighboring residues. The intercalated daunomycin ring system (aglycone) is rigidly fixed in the base stack, apparently serving as an anchor for the amino sugar segment of the drug which is one of the most mobile regions of the entire complex. The high flexibility of this amino sugar may be important for inhibition of replication and transcription not only by sterically blocking the minor groove, but also by allowing nonproductive interactions to be formed with various polymerases or other DNA-binding proteins. The crystallographic model is improved sufficiently by the rigid group anisotropic refinement to allow additional bound water molecules to be located.

Identification of homologous pairing and strand-exchange activity from a human tumor cell line based on Z-DNA affinity chromatography

An enzymatic activity that catalyzes ATP-dependent homologous pairing and strand exchange of duplex linear DNA and single-stranded circular DNA has been purified several thousand-fold from a human leukemic T-lymphoblast cell line. The activity was identified after chromatography of nuclear proteins on a Z-DNA column matrix. The reaction was shown to transfer the complementary single strand from a donor duplex linear substrate to a viral circular single-stranded acceptor beginning at the 5' end and proceeding in the 3' direction (5'----3'). Products of the strand-transfer reaction were characterized by electron microscopy. A 74-kDa protein was identified as the major ATP-binding peptide in active strand transferase fractions. The protein preparation described in this report binds more strongly to Z-DNA than to B-DNA.

A bifurcated hydrogen-bonded conformation in the d(A.T) base pairs of the DNA dodecamer d(CGCAAATTTGCG) and its complex with distamycin

The crystal structures of d(CGCA3T3GCG) complex to the antitumor drug distamycin and the DNA fragment alone were solved by x-ray diffraction at 2.2 and 2.5 A resolution, respectively. The drug lies in the narrow minor groove near the center of the B-DNA fragment covering 5 of the 6 A.T base pairs. It is bound to the DNA by hydrogen bonding, van der Waals, and electrostatic interactions. In addition, the DNA was found to have an unusual conformation in the (dA)3.(dT)3 regions. These base pairs have a high positive propeller twist so that in the major groove the adenine amino group is located intermediate between the carbonyl O-4 groups of two adjacent thymines of the opposite strand, making bifurcated hydrogen bonds to the two thymine residues. This suggests a model to explain the unusual properties of poly-(dA).poly(dT) in which a modified B conformation is associated with a large propeller twist of the bases and a set of continuous bifurcating hydrogen bonds along the major groove, which may provide incremental stability to these segments. In addition, shorter segments of (dA)3-6.(dT)3-6 may have this conformation in the midst of B-DNA and stabilize bends in the DNA that may be associated with stacking on one of the high propeller-twisted bases at the ends of these segments.

The crystal structure of d(CCCCGGGG): a new A-form variant with an extended backbone conformation

The crystal structure of d(CCCCGGGG) has been determined at a resolution of 2.25 A. The oligomers crystallize as A-DNA duplexes occupying crystallographic two-fold axes. The backbone conformation is, in general, similar to that observed in previously reported crystal structures of A-DNA fragments, except for the central linkage, where it adopts an extended structure resulting from all trans conformation at the P-O5'-C5'-C4' bonds. This type of conformation facilitates interstrand stacking between the guanines at the C-G site. The local helix twist at this step is very small (25 degrees) compared to an overall average of 33.5 degrees. The unique structure of the C-G base-pair step, namely the extended backbone and the distinct stacking geometry, may be an important feature in the recognition mechanism between double-stranded DNA molecules and restriction endonucleases such as Msp I, which cuts the sequence CCGG very specifically with a rate unaffected by neighboring base pairs.

Antigelling and antisickling bisphenyl oligopeptides and peptide analogues have similar structural features

Single-crystal X-ray diffraction was used to determine the three-dimensional structures of two antigelling oligopeptides, L-lysyl-L-phenylalanyl-L-phenylalanine and L-phenylalanylglycylglycyl-D-phenylalanine, and two antisickling peptide analogues, L-phenylalanine benzyl ester and N-phenylacetyl-L-phenylalanine. Although these bisphenyl compounds are chemically quite different from one another, they demonstrate unusual structural similarities: The molecules have compact conformations in which the two phenyl rings are positioned approximately 5 A apart with interplanar angles approaching 90 degrees, thereby making intramolecular edge-to-face interactions. In addition, the polar atoms, nitrogen and oxygen, are in close proximity without forming intramolecular hydrogen bonds. The relative spatial distribution of polar and nonpolar atoms renders the structures compact and amphipathic. The intramolecular edge-to-face interaction between two aromatic rings, which brings a hydrogen atom with relative positive charge near the pi-electron cloud with relative negative charge, is enthalpically favorable and maintains the molecules in a compact and amphipathic conformation. Nonbonded potential energy calculations were used to characterize the energetics of the aromatic-aromatic interaction, and they showed that the observed geometry is stabilized enthalpically by a favorable interaction on the order of -1 to -2 kcal/mol. Structural differences between the two antisickling and the two antigelling agents suggest that molecular volume limits red cell membrane passage. These data provide a molecular structural framework from which to design and synthesize amphipathic bisphenyl compounds that both bind to deoxy sickle cell hemoglobin and cross the erythrocyte membrane.

Signal sequence of human preproparathyroid hormone is inactive in yeast

The biosynthesis of human preproparathyroid hormone (hpreproPTH) and the processing to mature parathyroid hormone (hPTH) was investigated in yeast. Cells were transformed with a plasmid that carried a fusion gene made of the yeast pyruvate kinase promoter, complementary DNA (cDNA) encoding a slightly modified form of hpreproPTH and the transcription termination signal from yeast triosephosphate-isomerase. In transformed yeast cells we identified a protein that was recognized by a PTH antiserum and, on gel electrophoresis, comigrated with hpreproPTH marker. The amino-terminal sequence of the protein was consistent with that of hpreproPTH, indicating that the hormone precursor is not processed. It was localized inside the cell, when analyzed in pulse-chase experiments by trypsin accessibility in intact and lysed spheroplasts. In contrast, when mRNA from these yeast cells and from human parathyroid tissue was translated into preproPTH in a reticulocyte lysate supplemented with canine pancreatic microsomes, the preproPTHs from both mRNAs were transported and cleaved with identical efficiencies. We conclude that hpreproPTH is synthesized in yeast but not recognized and processed like a precursor of a secreted protein by the yeast secretory apparatus.

(dC-dA)n.(dG-dT)n sequences have evolutionarily conserved chromosomal locations in Drosophila with implications for roles in chromosome structure and function

In situ hybridization of (dC-dA)n.(dG-dT)n to the polytene chromosomes of Drosophila melanogaster reveals a clearly non-random distribution of chromosomal sites for this sequence. Sites are distributed over most euchromatic regions but the density of sites along the X chromosome is significantly higher than the density over the autosomes. All autosomes show approximately equal levels of hybridization except chromosome 4 which has no detectable stretches of (dC-dA)n.(dG-dT)n. Another striking feature is the lack of hybridization of the beta-heterochromatin of the chromocenter. The specific sites are conserved between different strains of D. melanogaster. The same overall chromosomal pattern of hybridization is seen for the other Drosophila species studied, including D. simulans, a sibling species with a much lower content of middle repetitive DNA, and D. virilis, a distantly related species. The evolutionary conservation of the distribution of (dC-dA)n.(dG-dT)n suggests that these sequences are of functional importance. The distribution patterns seen for D. pseudoobscura and D. miranda raise interesting speculations about function. In these species a chromosome equivalent to an autosomal arm of D. melanogaster has been translocated onto the X chromosome and acquired dosage compensation. In each species the new arm of the X also has a higher density of (dC-dA)n.(dG-dT)n similar to that seen on other X chromosomes. In addition to correlations with dosage compensation, the depletion of (dC-dA)n.(dG-dT)n in beta-heterochromatin and chromosome 4 may also be related to the fact that these regions do not normally undergo meiotic recombination.

Transcriptional regulation of the human prointerleukin 1 beta gene

Interleukin 1 (IL 1) is a protein produced by monocytes in response to certain antigens which produces a wide variety of cellular responses in various tissues. We have studied the regulation of the human proIL-1 beta gene in THP-1 human monocytic leukemia cells. Lipopolysaccharide (LPS) induction of this gene results in an immediate and transient increase of message that rapidly falls to a low, but constant, level within 6 hr. This decrease results from a specific repression of transcription by 2 hr after stimulation. Cycloheximide inhibition of new protein synthesis causes a superinduction of IL 1 message, but does not alter the initial kinetics of message production. This presumably delays the synthesis of a labile transcriptional repressor protein and implies that the proIL-1 beta gene is under the control of both a transcriptional activator and a newly synthesized transcriptional repressor. The transient increase in mRNA production and the sustained low-level synthesis beyond the initial transient response suggest that the IL 1 protein itself may act intracellularly in a manner analogous to that described for several proto-oncogenes and cellular competence factors.

Transcriptional regulation of the human prointerleukin 1 beta gene

Interleukin 1 (IL 1) is a protein produced by monocytes in response to certain antigens which produces a wide variety of cellular responses in various tissues. We have studied the regulation of the human proIL-1 beta gene in THP-1 human monocytic leukemia cells. Lipopolysaccharide (LPS) induction of this gene results in an immediate and transient increase of message that rapidly falls to a low, but constant, level within 6 hr. This decrease results from a specific repression of transcription by 2 hr after stimulation. Cycloheximide inhibition of new protein synthesis causes a superinduction of IL 1 message, but does not alter the initial kinetics of message production. This presumably delays the synthesis of a labile transcriptional repressor protein and implies that the proIL-1 beta gene is under the control of both a transcriptional activator and a newly synthesized transcriptional repressor. The transient increase in mRNA production and the sustained low-level synthesis beyond the initial transient response suggest that the IL 1 protein itself may act intracellularly in a manner analogous to that described for several proto-oncogenes and cellular competence factors.

Long-range interactions of multiple DNA structural transitions within a common topological domain

Local DNA conformations that are underwound with respect to the right-handed B form are favored in negatively supercoiled DNA. However, when multiple transitional events co-exist within a common topological domain, they must compete with one another for the available free energy of negative supercoiling. Recently we developed a general theoretical model capable of predicting the behavior at equilibrium of defined sequences in a variety of competitive situations. In the present work we have applied this theory to predict the formation of Z-DNA as a function of superhelicity in stretches of d(CG)m and d(CA)n when they are forced to compete with one another in the same plasmid. The observed behavior of these competing sequences is in close accord with theoretical predictions. These results indicate that sequences separated by large distances can effect the transitional behavior of each other in a complex manner which is independent of the relative orientation of the participating segments. The pattern of transitional events is strongly dependent on levels of DNA supercoiling, ambient conditions and on the nature and number of the sequences involved. Although in the present work we apply the model specifically to the Z-DNA conformational transition, the results of this study may have general relevance to a variety of biological processes in which the helical repeat of DNA is reversibly altered, including the initial steps in transcription, replication and recombination.

Binding of anti-Z-DNA antibodies to negatively supercoiled SV40 DNA

The binding of anti-Z-DNA antibody preparations to negatively supercoiled, protein-free SC40 DNA was analyzed. Covalent cross-linking with 0.1% glutaraldehyde followed by DNA restriction endonucleolytic fragmentation and nitrocellulose filtration allowed accurate mapping of antibody binding sites. The critical superhelical density necessary to allow antibody binding was -sigma = 0.056. The major region of antibody-DNA interaction was found within an SV40 segment spanning viral map positions 40 to 474. This region coincides with the nucleosome free region in SV40 minichromosomes and harbours the early and late promoter regions including the SV40 enhancer segment. Although it is unknown whether alternative, non-B-DNA conformations are generated in vivo within SV40 minichromosomes our results emphasize the high degree of DNA structural flexibility that can be realized under negative torsional stress.

Interactions between an anthracycline antibiotic and DNA: molecular structure of daunomycin complexed to d(CpGpTpApCpG) at 1.2-A resolution

The crystal structure of a daunomycin-d(CGTACG) complex has been solved by X-ray diffraction analysis and refined to a final R factor of 0.175 at 1.2-A resolution. The crystals are in a tetragonal crystal system with space group P4(1)2(1)2 and cell dimensions of a = b = 27.86 A and c = 52.72 A. The self-complementary DNA forms a six base pair right-handed double helix with two daunomycin molecules intercalated in the d(CpG) sequences at either end of the helix. Daunomycin in the complex has a conformation different from that of daunomycin alone. The daunomycin aglycon chromophore is oriented at right angles to the long dimension of the DNA base pairs, and the cyclohexene ring A rests in the minor groove of the double helix. Substituents on this ring have hydrogen-bonding interactions to the base pairs above and below the intercalation site. O9 hydroxyl group of the daunomycin forms two hydrogen bonds with N3 and N2 of an adjacent guanine base. Two bridging water molecules between the drug and DNA stabilize the complex in the minor groove. In the major groove, a hydrated sodium ion is coordinated to N7 of the terminal guanine and the O4 and O5 of daunomycin with a distorted octahedral geometry. The amino sugar lies in the minor groove without bonding to the DNA. The DNA double helix is distorted with an asymmetrical rearrangement of the backbone conformation surrounding the intercalator drug. The sugar puckers are C1,C2'-endo, G2,C1'-endo, C11,C1'-endo, and G12,C3'-exo. Only the C1 residue has a normal anti-glycosyl torsion angle (chi = -154 degrees), while the other three residues are all in the high anti range (average chi = -86 degrees). This structure allows us to identify three principal functional components of anthracycline antibiotics: the intercalator (rings B-D), the anchoring functions associated with ring A, and the amino sugar. The structure-function relationships of daunomycin binding to DNA as well as other related anticancer drugs are discussed.

The interactions of ruthenium hexaammine with Z-DNA: crystal structure of a Ru(NH3)6+3 salt of d(CGCGCG) at 1.2 A resolution

A crystal of d(CGCGCG) in the Z-DNA lattice was soaked with ruthenium(III) hexaammine and its structure refined at 1.2 A resolution. Three unique metal complexes were found absorbed to each hexamer duplex. In addition, two symmetry-related binding sites were located, yielding a total of five ruthenium complexes bound to each d(CGCGCG) duplex. One unique site and its symmetry related site are nearly identical to the binding site of cobalt(III) hexaammine on Z-DNA. At that position, the metal complex bridges the convex surfaces of two adjacent Z-DNA strands by hydrogen bonds to the N7 and O6 functional groups of the guanine bases. The remaining three ruthenium three ruthenium(III) hexaammine binding sites are not present in the cobalt(III) hexaammine Z-DNA structure. Of these, two are related by symmetry and span the gap between the convex outer surface of one Z-DNA strand and the helical groove crevice of a neighboring strand. The third ruthenium site has no symmetry mate and involves interactions with only the deep groove. In this interaction, the metal complex hydrogen bonds to both the phosphate backbone and to a set of primary shell water molecules that extend the hydrogen bonding potential of the deep groove crevice out to the surface of the molecule. Solution studies comparing the circular dichroism spectra of low salt poly(dG-dC).poly(dG-dC) samples in the presence of ruthenium(III) and cobalt(III) hexammine show that the ruthenium complex does stabilize Z-DNA in solution, but not as effectively as the cobalt analogue. This suggests that some of the interactions available for the larger ruthenium complex may not be important for stabilization of the left-handed DNA conformation.

Human preproparathyroid hormone synthesized in Escherichia coli is transported to the surface of the bacterial inner membrane but not processed to the mature hormone

cDNA encoding human preproPTH (hpreproPTH) was expressed in Escherichia coli to study the processing of the precursor to hPTH and its secretion by the bacterial secretory apparatus. We first constructed hybrid genes that differed randomly in the distance between the E. coli lac promoter's ribosomal binding site and DNA encoding a fusion protein with beta-galactosidase activity and the prepro sequence of hpreproPTH on the aminoterminus. Starting with clones identified as efficient producers of beta-galactosidase on indicator agar plates, the coding sequence for hpreproPTH was reconstituted intact. In a different construction we placed the hpreproPTH coding sequence downstream from the lac promoter at a distance of 12 base pairs from the ribosomal binding site. PTH immunoreactive proteins from multiple clones were identified by protein gel electrophoresis and by protein microsequencing. PTH-related proteins encoded by different plasmids were shown to be hpreproPTH with amino-terminal extensions of either two or four amino acids and as authentic hpreproPTH. Two hPTH fragments, hPTH(3-84) and hPTH(8-84), were also observed. The trypsin accessibility of hpreproPTH and of the two hPTH fragments in pulse-chase, cell-fractionation experiments using intact and lysed spheroplasts lets us conclude that the mammalian signal sequence directs hpreproPTH to the surface of the spheroplast membrane but is not appropriately cleaved by the signal peptidase.

Interactions of quinoxaline antibiotic and DNA: the molecular structure of a triostin A-d(GCGTACGC) complex

The crystal structure of a DNA octamer d(GCGTACGC) complexed to an antitumor antibiotic, triostin A, has been solved and refined to 2.2 A resolution by x-ray diffraction analysis. The antibiotic molecule acts as a true bis intercalator surrounding the d(CpG) sequence at either end of the unwound right-handed DNA double helix. As previously observed in the structure of triostin A-d(CGTACG) complex (A.H.-J. Wang, et. al., Science, 225, 1115-1121 (1984)), the alanine amino acid residues of the drug molecule form sequence-specific hydrogen bonds to guanines in the minor groove. The two central A.T base pairs are in Hoogsteen configuration with adenine in the syn conformation. In addition, the two terminal G.C base pairs flanking the quinoxaline rings are also held together by Hoogsteen base pairing. This is the first observation in an oligonucleotide of. Hoogsteen G.C base pairs where the cytosine is protonated. The principal functional components of a bis-intercalative compound are discussed.

A computer aided thermodynamic approach for predicting the formation of Z-DNA in naturally occurring sequences

The ease with which a particular DNA segment adopts the left-handed Z-conformation depends largely on the sequence and on the degree of negative supercoiling to which it is subjected. We describe a computer program (Z-hunt) that is designed to search long sequences of naturally occurring DNA and retrieve those nucleotide combinations of up to 24 bp in length which show a strong propensity for Z-DNA formation. Incorporated into Z-hunt is a statistical mechanical model based on empirically determined energetic parameters for the B to Z transition accumulated to date. The Z-forming potential of a sequence is assessed by ranking its behavior as a function of negative superhelicity relative to the behavior of similar sized randomly generated nucleotide sequences assembled from over 80,000 combinations. The program makes it possible to compare directly the Z-forming potential of sequences with different base compositions and different sequence lengths. Using Z-hunt, we have analyzed the DNA sequences of the bacteriophage phi X174, plasmid pBR322, the animal virus SV40 and the replicative form of the eukaryotic adenovirus-2. The results are compared with those previously obtained by others from experiments designed to locate Z-DNA forming regions in these sequences using probes which show specificity for the left-handed DNA conformation.

Crystal structure of a Z-DNA fragment containing thymine/2-aminoadenine base pairs

The Z-DNA structure has been shown to form in two crystals made from self-complementary DNA hexamers d(CGTDCG) and d(CDCGTG) which contain thymine/2-aminoadenine (TD) base pairs. The latter structure has been solved and refined to 1.3 A resolution and it shows only small conformational changes due to the introduction of the TD base pairs in comparison with the structure of d(CG)3. Spectroscopic studies with these compounds demonstrate that DNA molecules containing 2-aminoadenine residues form Z-DNA slightly more easily than do those containing adenine nucleotides, but not as readily as the parent sequence containing only guanine-cytosine base pairs.

Competitive behavior of multiple, discrete B-Z transitions in supercoiled DNA

Conformational transitions in topologically constrained duplex DNA necessarily affect and are affected by other transitional processes throughout the entire molecule. This conformational interdependence of discrete sequences within a given superhelical domain arises through a requisite competition for the free energy of supercoiling. Here we present a generalized statistical mechanical analysis of multiple, competing conformational equilibria in superhelical DNA. This model has been applied, using experimentally determined parameters, to the energetic coupling of two independent B-Z transitions. Specifically, we have monitored the extent of B-Z transition, as a function of negative superhelicity, in topoisomers of a plasmid containing two identical d(C-G)n inserts using two-dimensional gel electrophoresis. The theoretical results were found to be in good agreement with the experimental data, and we have used this model to predict the competitive behavior of B-Z transitions within sequences differing in length and sequence composition. This competition is shown to have a profound effect upon the B-Z equilibria of those sequences analyzed, resulting in a complex modulation in the extent of Z-DNA formation as a function of negative superhelicity. These theoretical and experimental results show that DNA sequences separated by large distances are capable of communicating structural information.

Rate of B to Z structural transition of supercoiled DNA

The forward rate of the B to Z transition induced by negative supercoiling of plasmid DNA containing an alternating C-G sequence has been examined using the binding of Z-DNA-specific antibodies to follow the transition. DNA samples of a plasmid containing a d(pCpG)16 X d(pCpG)16 insert were supercoiled to different extents and appropriate amounts of ethidium were bound to the DNAs to relax them and to keep the alternating C-G sequence in the right-hand helical form. Following the rapid removal of ethidium by passage through a column of cation exchange resin, the DNA becomes negatively supercoiled, which induces the flipping of the helical hand of the C-G insert. The rate of the transition is strongly dependent on the degree of supercoiling. The transition is complete in less than 50 seconds for a DNA with a specific linking difference (superhelical density) sigma of -0.09. For the same DNA, the half-time of the transition is about two minutes at sigma = -0.07 and about a factor of 10 slower at sigma = -0.05.

Expression of biologically active human interleukin 1 subpeptides by transfected simian COS cells

"Interleukin 1" (IL-1) is a term used to describe the family of macrophage-derived proteins that mediate many immune and inflammatory reactions. We have previously described the molecular cloning and sequencing of the cDNA encoding the predominant (neutral) form of human IL-1, which has been designated IL-1 beta. We report here that transfection of simian COS cells with this cDNA clone results in the transcription of IL-1 mRNA and the synthesis of antibody-neutralizable intracellular IL-1 biological activity. In addition, selective deletion of regions of the IL-1 cDNA judged not to be essential for function, on the basis of conserved sequence homology, resulted in localization of a "core" region responsible for a majority of the biological activity. These results permit mapping the active site of IL-1 to a peptide of 6970 molecular weight located within the carboxyl third (between Met-136 and Gln-197) of the IL-1 precursor.