DNA H form requires a homopurine-homopyrimidine mirror repeat

Regular homopurine-homopyrimidine tracts, (dG-dA)n(dT-dC)n and (dG)n(dC)n, undergo a superhelix-induced, strongly pH-dependent, structural transition into a novel DNA conformation, the H form. We have suggested that the H form can arise in any homopurine-homopyrimidine mirror repeat (H palindrome). We have now tested this prediction using a tailored series of plasmids carrying the inserts AAGGGAGAAXGGGGTATAGGGGYAAGAGGGAA, where X and Y may be either A or G, and subject them to two-dimensional gel electrophoresis. In support of our hypothesis, the inserts exhibited facile transitions into the H form for X = Y = G, or X = Y = A, whereas the transition was much more difficult or impossible for the two non-palindromes (X = A, Y = G or X = G, Y = A). We present evidence that the H form is the structural basis for S1-nuclease hypersensitivity.

Conformational properties of dinucleoside monophosphates in solution: dipurines and dipyrimidines

In order to obtain information about the conformational features in a polyribonucleotide at the nearest neighbor level, detailed nuclear magnetic resonance studies of the dinucleoside monophosphates ApA, ApG, GpA, UpU, CpC, UpC, and CpU were undertaken. Proton spectra were recorded at 100, 220, 270, or 300 MHz for D2O solutions, 0.01-0.03 M, pD 7.4 at 20+/-2 degrees C. Spectra of ApA, ApG, UpU, and UpC were also recorded in the temperature range of 70-90 degrees C. Unambiguous signal assignments of all proton resonances were made with the aid of selectively deuterated dimers. Complete, accurate sets of nuclear magnetic resonance (NMR) parameters were derived for each nucleotidyl unit by simulation-iteration methods. A complete set of chemical shift and coupling constant data was also obtained for all the constituent monomeric units at a concentration and ionization state comparable to that of the dimers. Conformational properties were evaluated quantitatively for most of the bonds in the dinucleoside monophosphates using procedures developed in earlier studies. All of the dimers have a flexible conformational framework in aqueous solution. While flexibility is allowed and alternate conformations are accessible, these molecules nevertheless attempt to achieve conformational identity by showing preferences--sometimes overwhelming preferences--for certain orientations. Thus the ribose rings exist as equilibrium mixtures of C2'-endo in equilibrium C3'-endo conformers with a bias for the C3'-endo pucker in most cases. The C4'-C5' bonds of both nucleotidyl units show significant preference (70-85%) for a gg conformation. Similarly, the dominant conformer (80-90%) about C5'-O5' is g'g'. Even though an unambiguous determination of the orientation about C3'-O3' cannot be made, there is suggestive evidence that the orientation of the 3' phosphate group is coupled to the ribose conformational equilibrium and it is likely that a 3Eg- in equilibrium 2Eg+ equilibrium exists with a bias for the 3Eg- coupled conformation in which the H3'-C3'-O3'-P dihedral angle is about 34-38 degrees. The individual nucleotidyl units in the dimers differ in several key ways from corresponding monomer conformations. Specifically, the ribose equilibrium C2'-endo in equilibrium C3'-endo shifts in favor of C3'-endo upon dimerization, the only exception being UpU. The C4'-C5' and C5'-O5' bonding network in the dimer forms a stable conformational unit and no correlation exists in the dimers between the conformational preference of this fragment and ribose conformer population. The temperature data for the dimers and dimerization data clearly indicate that the transition C2'-endo leads to C3'-endo is directly related to XCN changes brought about by dimerization and stacking...

Alternating purine-pyrimidine tracts may promote chromosomal translocations seen in a variety of human lymphoid tumours

Chromosomal abnormalities which are prevalent in human lymphoid tumours are believed to be involved in tumour pathogenesis and their formation may be the result of erroneous activity by the V-D-J recombinase. Frequently, recombinase accessibility is provided by prior transcription of the chromosomal regions involved. However, this may not always be so and in those cases DNA structural features must be involved. Here we examine the breakpoints of three different tumour-specific translocations in the proximity of which we can detect no transcription; two of the translocations involve regions of chromosome 11, (t[11;14] [p13;q11] and t[11;14] [q13;q32]), and the third is a newly described translocation, t[7;10] [q35;q24], involving the T cell receptor beta-gene on chromosome 7. In each case, a purine--pyrimidine tract (potential Z-DNA) occurs near the translocation breakpoints. Four independent tumours with translocation t[11;14] [p13;q11] reveal a 2 kb breakpoint cluster region at 11p13 with an adjacent potential Z-DNA region of 62 bp in length; the analogous purine--pyrimidine tract at 10q24 is 32 bp long. The purine--pyrimidine tract at the 11q13 chromosome breakpoint, however, is very large as it covers approximately 800 bp. The position, surrounding sequence and potential Z-DNA tract of the human 11p13 TALLber is conserved in rodents. These results suggest that the purine--pyrimidine tracts, presumably in the Z-DNA form, can influence chromatin structure giving access for recombinase-mediated translocations. Such putative alterations of chromatin organization are supported by the observation of DNase I hypersensitive sites near to translocation breakpoints on 10q24 and 11p13.

Nucleotide sequence of the BALB/c mouse beta-globin complex

The nucleotide sequence of 55,856 base-pairs containing all seven beta-globin homologous structures from chromosome 7 of the BALB/c mouse is reported. This sequence links together previously published sequences of the beta-globin genes, pseudogenes and repetitive elements. Using low stringency computer searches, we found no additional beta-globin homologous sequences, but did find many more long interspersed repetitive sequences (L1) than predicted by hybridization. L1 is a major component of the mouse beta-globin complex with at least 15 elements comprising about 22% of the reported sequence. Most open reading frames greater than 300 base-pairs in the cluster overlap with L1 repeats or globin genes. Polypurine, polypyrimidine and alternating purine/pyrimidine tracts are not evenly dispersed throughout the complex, but they do not appear to be excluded from or restricted to particular regions. Several regions of intergenic homology were detected in dot-plot comparisons of the mouse sequence with itself and with the human beta-globin sequence. The significance of these homologies is unclear, but these regions are candidates for further study in functional assays in erythroid cell lines or transgenic animals.

An endonuclease for depurinated DNA in Escherichia coli B

Escherichia coli B cells contain an endonuclease which hydrolyzes apurinic sites in DNA. The enzyme has been demonstrated in vitro by the action of E. coli B41 proteins on depurinated DNA. This endonuclease probably plays a role in the molecular mechanism of the delayed inactivation of the T7 coliphage treated by monofunctional alkylating agents, which has been shown to be dependent on depurination; this endonuclease could also be a repair enzyme necessary for the first step of the repair of DNA containing apurinic sites.

The DNA guanyl radical: kinetics and mechanisms of generation and repair

The one-electron oxidation of DNA bases and single-stranded DNA was studied by pulse radiolysis of aqueous solutions from pH 7-7.4 at 20 degrees C. Thallic ions, Tl(II), were found to rapidly oxidize the purine nucleotides, deoxyguanosine 5'-monophosphate, k[Tl(II) + dGMP2-] = 3.4.10(9) M-1.s-1, and deoxyadenosine 5'-monophosphate, k[Tl(II) + dAMP2-] = 1.3.10(8) M-1.s-1. The reactivities of Tl(II) ions with model pyrimidine DNA bases, 1-methylcytosine and 1-methylthymine, were too low to be measured by pulse radiolysis, k less than 10(7) M-1.s-1. The Tl(II)-mediated oxidation of ssDNA, k = 2.8.10(8) M-1.s-1, produces DNA-guanyl radical, DNA-G.(-H), exclusively. The DNA-guanyl radical is found to be a potent oxidant in neutral media, E7 = 1.04 +/- 0.05 V. It rapidly oxidizes the aromatic amino acids in glycyl-tryptophan and tyrosine methyl ester, k = 3.6.10(7) M-1.s-1 and k = 1.7.10(8) M-1.s-1, respectively. These electron transfer processes indicate that a positive 'hole' may be transferred from DNA to a DNA-associated protein. The positive 'hole' in DNA can also be repaired by antioxidants, which are electron donors. The chemical repair of the DNA-guanyl radical by negatively charged antioxidants is slower than that by positively charged and neutral antioxidants.

NMR studies in the syn-anti dynamic equilibrium in purine nucleosides and nucleotides

The syn in equilibrium anti equilibrium conformation about the glycosidic bond of purine nucleosides and 5'-nucleotides in different solvent systems has been investigated by means of 1H NMR spectroscopy. Quantitative values for the conformer populations were improved, relative to previous results, by a detailed study of, and a resultant derived correction for, the influence of the sugar exocyclic group conformation on the chemical shifts of the sugar ring protons. This was achieved with the aid of nucleosides and nucleotides fixed in the conformations gauche-trans [derivatives of 8,5'-(R)-cyclo] and trans-gauche [derivatives of 8,5'-(S)-cyclo]. The results of 13C NMR confirmed those obtained by 1H NMR. The measured values of the vicinal coupling constants between H-1' and the C-8 and C-4 carbons were employed to evaluate approximately the glycosidic angles chi of the nucleosides in the conformations syn and anti. A critical examination is made of the applicability of relaxation methods, involving analysis of spin-lattice relaxation time of protons (T1) and the Overhauser effect, to determine the conformation of the base about the glycosidic bond; interpretations are provided for the lack of agreement between these methods and those based on chemical shifts in the present study. The foregoing resuls are also applied to an examination of the effect of the conformation of the base about the glycosidic bond on the enzymatic reactions catalyzed by 5'-nucleotidase and adenosine deaminase.

Structural polymorphism of homopurine-homopyrimidine sequences: the secondary DNA structure adopted by a d(GA.CT)22 sequence in the presence of zinc ions

In this paper, we have analysed the conformational behaviour shown by the homopurine--homopyrimidine alternating d(GA.CT)22 sequence cloned into SV40. Our results show that, in the presence of zinc ions, the d(GA.CT)22 sequence adopts an altered secondary DNA structure (*H-DNA) which differs from either B-DNA or H-DNA. Formation of *H-DNA is facilitated by negative supercoiling and does not appear to require base protonation, since it is induced at neutral pH by approximately 0.4 mM ZnCl2. The patterns of OsO4 and DEPC modification obtained in the presence of zinc are compatible with a homopurine--homopurine--homopyridimine triplex, though other structural models for *H-DNA are also possible. The hypersensitivity to S1-cleavage of the d(GA.CT)22 sequence is reinterpreted in terms of the equilibria between the B-, H- and *H-forms of the sequence. These results reveal the high degree of structural polymorphism shown by homopurine-homopyrimidine sequences. Its biological relevance is discussed.

Complete nucleotide sequence of the rabbit beta-like globin gene cluster. Analysis of intergenic sequences and comparison with the human beta-like globin gene cluster

The nucleotide sequence of the entire beta-like globin gene cluster of rabbits has been determined. This sequence of a continuous stretch of 44.5 x 10(3) base-pairs (bp) starts about 6 x 10(3) bp upstream from epsilon (the 5'-most gene) and ends about 12 x 10(3) bp downstream from beta (the 3'-most gene). Analysis of the sequence reveals that: (1) the sequence is relatively A + T rich (about 60%); (2) regions with high G + C content are associated with OcC repeats, a short interspersed repeated DNA in rabbits; (3) the distribution of polypurines, polypyrimidines and alternating purine/pyrimidine tracts is not random within the cluster; (4) most open reading frames are associated with known globin coding regions, OcC repeats or long interspersed repeats (L1 repeats); (5) the most prominent open reading frames are found in the L1 repeats; (6) different strand asymmetries in base composition are associated with embyronic and adult genes as well as the tandem L1 repeats at the 3' end of the cluster; and (7) essentially all the repeats appear to have been inserted by a transposon mechanism. A comparison of the sequence with itself by a dot-plot analysis has revealed nine new members of the OcC family of repeats in addition to the six previously reported. The OcC repeats tend to be clustered, particularly in the epsilon-gamma and gamma-psi delta intergenic regions. Dot-plot comparisons between the rabbit and the human clusters have revealed extensive sequence matches. Homology starts about 6 x 10(3) bp 5' to epsilon or as far upstream as the rabbit sequence is available. It continues throughout the entire cluster and stops about 0.7 x 10(3) bp 3' to beta, at which point several repeats have inserted in both rabbits and humans. Throughout the gene cluster, the homology is interrupted mainly by insertions or deletions in either the rabbit or the human genome. Almost all of the insertions are of known short or long repeated DNAs. The positions of the insertions are different in the two gene clusters, which indicates that both short and long repeats have been transposing throughout the genome for the time since the mammalian radiation. An alignment of rabbit and human sequences allows the calculation of the substitution rate around epsilon. Sequences far removed from the gene are evolving at a rate equivalent to the pseudogene rate, although some short regions show an apparently higher rate.(ABSTRACT TRUNCATED AT 400 WORDS)

Nuclear magnetic resonance studies of 2'- and 3'-ribonucleotide structures in solution

A systematic 220-MHz proton nuclear magnetic resonance (nmr) study has been made of all common purine and pyrimidine 2'(3')-ribonucleotides in D2O solutions at 20 plus or minus 2 degrees. Spectra for the entire series were measured under similar conditions of concentration, temperature, and ionic strength, thereby facilitating intercomparisons of spectral properties. Spectral assignments were accomplished with the aid of selected 31P-1H decoupling experiments and accurate values of nmr parameters were derived by simulation-iteration procedures. A detailed analysis of the coupling constants and chemical shifts permitted a determination of conformational properties for ribose rings, exocyclic carbinol and phosphate groups, and the orientation of base-ribose rings. Following procedures described elsewhere, an evaluation was made of ribose ring pseudorotational parameters for each 2'(3')-nucleotide. The results show that both the degree of pucker and pseudorotational angle vary only slightly throughout the entire series of molecules, and lie within the ranges found in the crystalline state. Furthermore, the ribose rings are in rapid equilibrium between N type (C(3')-ENDO, C(2')-exo) and S type (C(2')-endo, C(3')-exo) conformers, N forms and is formed by S, with an S type conformer favored in purine 2'(3')-ribonucleotides (-60:40) while pyrimidines exhibit approximately equal compositions. Thus, the phosphate location on the ring has less of an effect on ring properties than the nature of the base ring. An analysis is also reported of rotamer equilibria about C(4')-C(5'), C(2')-O(2'), and C(3')-O(3') bonds. For the former the nmr coupling constant data are consistent with a predominant gg rotamer (-70%) with gt and tg rotamers populated to the extent of -20 and -10%, respectively. No correlation of the type seen for 5'-nucleotides appears to exist between C(4')-C(5') gg population and ribose ring equilibrium composition. For 2'-nucleotides the 31P-H(2') coupling data indicate a preferred C(3')g, C(1')t conformer about C(2')-O(2') in agreement with 13C nmr results. A less definitive rotamer analysis follows from observed J31P,H(3') values, but when these results are combined with relevant chemical shift data for deoxynucleosides and nucleotides the evidence strongly points to essentially free rotation and approximately equal rotamer populations about C(3')-O(3'). Chemical shift differences between purine and pyrimidine 2'(3')-ribonucleotides are qualitatively accounted for by "in-plane" purine diamagnetic anisotropy effects. Also, the greater magnitude for purine deshieldings in 2'(3')-nucleotides relative to 5'-nucleotides is explained by a more favored syn:anti ratio in the former in line with recent nucle

Chemical reactivity of potassium permanganate and diethyl pyrocarbonate with B DNA: specific reactivity with short A-tracts

We have examined the reactivity of B DNA with two chemical probes of DNA structure, potassium permanganate (KMnO4; thymine specific) and diethyl pyrocarbonate (DEPC; purine specific, A greater than G). The DNA probed is from the beta-lactamase promoter region of the vector pBR322, and from the 3' noncoding region of a chicken embryonic myosin heavy chain gene. The chemical probes display variable reactivity with the susceptible bases in these fragments, suggesting that modification of these bases by KMnO4 and DEPC is quite sequence dependent. In contrast, these probes react with the short A-tracts present in these DNA fragments in a reproducible fashion, generating two related patterns of reactivity. In the majority of the A-tracts, all but the 3'-terminal thymine are protected from KMnO4 attack, while DEPC reacts significantly with all but the 3'-terminal adenine of the A-tracts. Some A-tracts also display a very high DEPC reactivity at the adenine adjacent to the 3'-terminal unreactive adenine. Little qualitative difference in the KMnO4 reactivity of the A-tracts was found between 12 and 43 degrees C. However, at lower temperatures the elevated KMnO4 reactivity at the 3'-terminal A-tract thymine is sometimes lost. Raising the temperature of the KMnO4 reaction can cause relatively large increases in the reactivity of some single thymines, suggesting that significant local changes in stacking occur at these thymines at elevated temperatures. The data presented suggest that many short A-tracts embedded in long fragments of DNA can assume a number of related structures in solution, each of which possess distinct junctions with the flanking DNA. This result is consistent with high-resolution structural studies on oligonucleotides containing short A-tracts. The relevance of these results to current models of A-tract structure and DNA bending is discussed. Our data also indicate that KMnO4 and DEPC are potentially useful reagents for the study of sequence-dependent variations in B DNA structure.

Positive correlation between DNA polymerase alpha-primase pausing and mutagenesis within polypyrimidine/polypurine microsatellite sequences

Microsatellite DNA sequences are ubiquitous in the human genome, and mutation rates of these repetitive sequences vary with respect to DNA sequence as well as length. We have analyzed polymerase-DNA interactions as a function of microsatellite sequence, using polypyrimidine/polypurine di- and tetranucleotide alleles representative of those found in the human genome. Using an in vitro primer extension assay and the mammalian DNA polymerase alpha-primase complex, we have observed a polymerase termination profile for each microsatellite that is unique to that allele. Interestingly, a periodic termination profile with an interval size (9-11 nucleotides) unrelated to microsatellite unit length was observed for the [TC](20) and [TTCC](9) templates. In contrast, a unit-punctuated polymerase termination profile was found for the longer polypurine templates. We detected strong polymerase pauses within the [TC](20) allele at low reaction pH which were eliminated by the addition of deaza-dGTP, consistent with these specific pauses being a consequence of triplex DNA formation during DNA synthesis. Quantitatively, a strand bias was observed in the primer extension assay, in that polymerase synthesis termination is more intense when the polypurine sequence serves as the template, relative to its complementary polypyrimidine sequence. The HSV-tk forward mutation assay was utilized to determine the corresponding polymerase alpha-primase error frequencies and specificities at the microsatellite alleles. A higher microsatellite polymerase error frequency (50x10(-4) to 60x10(-4)) was measured when polypurine sequences serve as templates for DNA synthesis, relative to the polypyrimidine template (18x10(-4)). Thus, a positive correlation exists between polymerase alpha-primase pausing and mutagenesis within microsatellite DNA alleles.

Activities of adenosine deaminase and 5'-nucleotidase in cancerous and noncancerous human colorectal tissues

In order to characterize human colorectal cancer, much attention has been paid to enzyme studies. However, little is known about the correlation between the levels of key enzymes of purine nucleotide pathway and some clinical and biological indicators of tumor invasiveness and aggressiveness. Adenosine deaminase (ADA) and 5'-nucleotidase (5'-NT) were measured in cancerous and cancer-free adjacent large bowel tissues from 38 patients with colorectal carcinoma. We have analyzed the relationship between the enzyme levels and some clinical and pathological parameters. The enzymes' activities were markedly higher in primary tumors than in corresponding normal mucosae. The ADA level in tumor tissue was significantly correlated with lymph node metastasis, histologic type, tumor location, and patient's age, whereas the 5'-NT level showed a significant correlation with tumor grade and tumor location. ADA activity in tumor tissues was significantly higher in patients whose clinical course remained stable than in those with recurrent diseases. The purine metabolism and salvage pathway activity of purine nucleotides are accelerated in the cancerous human colorectal tissue. Although our findings suggest that these enzymes' activities are most likely related to the same histomorphological architecture of the tumor, the authors believe that long-term follow-up studies are needed to evaluate the prognostic value of purine enzymes for colorectal cancer.