The human protein translin specifically binds single-stranded microsatellite repeats, d(GT)n, and G-strand telomeric repeats, d(TTAGGG)n: a study of the binding parameters

We have previously identified in human fibroblasts a multisubunit protein (designated PGB) that specifically bound single-stranded G-rich microsatellite DNA sequences. PGB was later found to be identical, or closely related to translin, an octameric protein that bound single-stranded DNA consisting of sequences flanking chromosomal translocations. Here, we report that recombinant translin binds single-stranded microsatellite repeats, d(GT)n, and G-strand telomeric repeats, d(TTAGGG)n, with higher affinities (Kdis approximately = 2 nM and Kdis approximately = 12.5 nM, respectively, in 100 mM NaCl and 25 degrees C) than the affinity with which it binds a prototypical sequence flanking translocation sites (Kdis approximately = 23 nM). Translin also binds d(GT)n and d(TTAGGG)n overhangs linked to double-stranded DNA with equilibrium constants in the nanomolar range. Formation of DNA quadruplexes by the d(TTAGGG)n repeats inhibits their binding to translin. A further study of the binding parameters revealed that the minimal length of d(GT)n and d(TTAGGG)n oligonucleotides that a translin octamer can bind is 11 nucleotides, but that such oligonucleotides containing up to 30 nucleotides can bind only a single translin octamer. However, the oligonucleotides d(GT)27 and d(TTAGGG)9 bind two octamers with negative cooperativity. Translin does not detectably bind single-stranded d(GT)n sequences embedded within double-stranded DNA. Based on our data, we propose that translin might be involved in the control of recombination at d(GT)n.d(AC)n microsatellites and in telomere maintenance.     

RecA independent recombination of poly[d(GT)-d(CA)] in pBR322.

Short sequence tracts composed of alternating guanosine and thymidine nucleotide residues poly[d(GT)-d(CA)] carried in a derivative of pBR322 were recombinogenic in a recA host. Recombination brought about by poly[d(GT)-d(CA)] tracts displayed two interesting properties: (i) the reaction was quasi-sequence-specific in that while recombination usually occurred between two poly[d(GT)-d(CA)] tracts, recombination also occurred between sequences bordering the dinucleotide repeats. (ii) recombination was enhanced when two poly[d(GT)-d(CA)] tracts were clustered within 250 base pairs of each other, but not when the repeats were separated by 3 kilobase pairs. The mechanism by which poly[d(GT)-d(CA)] stimulated recombination remains to be determined, but the behavior of these sequences is consistent with the idea that general recombination in E. coli may involve formation of Z-DNA.     

Recombination between poly[d(GT).d(CA)] sequences in simian virus 40-infected cultured cells.

CVI cells were transfected with oversized simian virus 40 (SV40) genomes that could be reduced to packageable size by alternative homologous recombination pathways involving either two polydeoxyguanylic-thymidylic acid X polydeoxycytidylic-adenylic acid (poly[d(GT).d(CA)]; abbreviated hereafter as poly(GT)] tracts or two tracts of homologous SV40 sequence. Plaque-forming viruses rescued by this procedure were found to contain genomes formed by homologous and nonhomologous recombination events. Half of the viable viral DNA molecules recovered were the result of recombination between two tracts of poly(GT). Approximately 20% of the rescued viral genomes were produced by homologous recombination between tracts of SV40 DNA. Nonhomologous recombination involving SV40 sequences was also a major pathway of deletion, producing ca. 30% of the viral plaques. Tracts of poly(GT) generated by recombination were variable in length, suggesting that recombination between poly(GT) tracts was usually unequal. On a per-nucleotide basis, poly(GT) recombination occurred eight times more frequently than did recombination between homologous SV40 DNA. This eightfold difference is the maximum recombinatory enhancement attributable to poly(GT) sequences. Although DNA sequence analysis showed that tracts of poly(GT) generated by recombination retained the alternating G-T repeat motif throughout their length, the contribution of the nonhomologous pathway to poly(GT) recombination cannot be ruled out, and the relative proclivity of a given length of d(GT).d(CA) sequence to undergo homologous recombination is probably less than eight times greater than that of an SV40 sequence of the same length.     

(dT-dC)n and (dG-dA)n tracts arrest single stranded DNA replication in vitro.

Previous in vivo studies have indicated that (dT-dC)n.(dG-dA)n tracts (referred to here as (TC)n.(GA)n), which are widely dispersed in vertebrate genomes, may serve as pause or arrest signals for DNA replication and amplification. To determine whether these repeat elements act as stop signals for DNA replication in vitro, single stranded DNAs including (TC)n or (GA)n tracts of various lengths, were prepared by cloning such tracts into phage M13 vectors, and were replicated with the Klenow fragment of the E. coli DNA polymerase I, or with the calf thymus DNA polymerase alpha, by extension of an M13 primer. Gel electrophoresis of the reaction products revealed that the replication was specifically arrested around the middle of both (TC)n and (GA)n tracts of n greater than or equal to 16. However, whereas in the (TC)n tracts the arrests were less prominent at pH = 8.0 than at pH = 6.5-7.5, and were completely eliminated at pH = 8.5, the arrests in the (GA)n tracts were stronger at the higher pH values. These results, and previous data, suggest that the arrests were caused by formation of unusual DNA structures, possibly triple helices between partially replicated (TC)n or (GA)n tracts, and unreplicated portions of these sequences.     

Informativeness of human (dC-dA)n.(dG-dT)n polymorphisms

Abundant human interspersed repetitive DNA sequences of the form (dC-dA)n.(dG-dT)n have been shown to exhibit length polymorphisms. Examination of over 100 human (dC-dA)n.(dG-dT)n sequences revealed that the sequences differed from each other both in numbers of repeats and in repeat sequence type. Using a set of precise classification rules, the sequences were divided into three categories: perfect repeat sequences without interruptions in the runs of CA or GT dinucleotides (64% of total), imperfect repeat sequences with one or more interruptions in the run of repeats (25%), and compound repeat sequences with adjacent tandem simple repeats of a different sequence (11%). Informativeness of (dC-dA)n.(dG-dT)n markers in the perfect sequence category was found to increase with increasing average numbers of repeats. PIC values ranged from 0 at about 10 or fewer repeats to above 0.8 for sequences with about 24 or more repeats. (dC-dA)n.(dG-dT)n polymorphisms in the imperfect sequence category showed lower informativeness than expected on the basis of the total numbers of repeats. The longest run of uninterrupted CA or GT repeats was found to be the best predictor of informativeness of (dC-dA)n.(dG-dT)n polymorphisms regardless of the repeat sequence category.     

Isolation, cloning and characterisation of motifs containing (GA/TC)n repeats isolated from vetch, Vicia bithynica

Microsatellites are widely distributed in plant genomes and comprise unstable regions that undergo mutational changes at rates much greater than that observed for non-repetitive sequences. They demonstrate intrinsic genetic instability, manifested as frequent length changes due to insertions or deletions of repeat units. Detailed analysis of 1600 clones containing genomic sequences of Vicia bithynica revealed the presence of microsatellite repeats in its genome. Based on the screening of a partial DNA library of plasmids, 13 clones harbouring (GA/TC)n tracts of various lengths of repeated motif were identified for further analysis of their internal sequence organization. Sequence analyses revealed the precise length, number of repeats, interruptions within tracts, as well as sequence composition flanking the repeat motifs. Representative plasmids containing different lengths of (GA/TC)n embedded in their original flanking sequence were used to investigate the genetic stability of the repeats. In the study presented herein, we employed a well characterised and tractable bacterial genetic system. Recultivations of Escherichia coli harbouring plasmids containing (GA/TC)n inserts demonstrated that the genetic instability of (GA/TC)n microsatellites depends highly on their length (number of repeats). These observations are in agreement with similar studies performed on repetitive sequences from humans and other organisms.     

Site-Specific Recognition of a 70-Base-Pair Element Containing d(GA)n Repeats Mediates bithoraxoid Polycomb Group Response Element-Dependent Silencing

Polycomb group proteins act through Polycomb group response elements (PREs) to maintain silencing at homeotic loci. The minimal 1.5-kb bithoraxoid (bxd) PRE contains a region required for pairing-sensitive repression and flanking regions required for maintenance of embryonic silencing. Little is known about the identity of specific sequences necessary for function of the flanking regions. Using gel mobility shift analysis, we identify DNA binding activities that interact specifically with a multipartite 70-bp fragment (MHS-70) downstream of the pairing-sensitive sequence. Deletion of MHS-70 in the context of a 5.1-kb bxd Polycomb group response element derepresses maintenance of silencing in embryos. A partially purified binding activity requires multiple, nonoverlapping d(GA)(3) repeats for MHS-70 binding in vitro. Mutation of d(GA)(3) repeats within MHS-70 in the context of the 5.1-kb bxd PRE destabilizes maintenance of silencing in a subset of cells in vivo but gives weaker derepression than deletion of MHS-70. These results suggest that d(GA)(3) repeats are important for silencing but that other sequences within MHS-70 also contribute to silencing. Antibody supershift assays and Western analyses show that distinct isoforms of Polyhomeotic and two proteins that recognize d(GA)(3) repeats, the TRL/GAGA factor and Pipsqueak (Psq), are present in the MHS-70 binding activity. Mutations in Trl and psq enhance homeotic phenotypes of ph, indicating that TRL/GAGA factor and Psq are enhancers of Polycomb which have sequence-specific DNA binding activity. These studies demonstrate that site-specific recognition of the bxd PRE by d(GA)(n) repeat binding activities mediates PcG-dependent silencing.     

Conformational changes induced in the human protein translin and in the single-stranded oligodeoxynucleotides d(GT)(12) and d(TTAGGG)(5) upon binding of these oligodeoxynucleotides by translin

Translin is a human single-stranded DNA and RNA binding protein that has been highly conserved in eukaryotic evolution. It consists of eight subunits having a highly helical secondary structure that assemble into a ring. The DNA and the RNA are bound inside the ring. Recently, some of us demonstrated that the human translin specifically binds the single-stranded microsatellite repeats, d(GT)(n), the human telomeric repeats, d(TTAGGG)(n), and the Tetrahymena telomeric repeats, d(GGGGTT)(n). These data suggested that translin might be involved in recombination at d(GT)(n).d(AC)(n) microsatellites and in telomere metabolism. Other data indicated that translin might stimulate binding of telomerase to single-stranded telomeric overhangs by unwinding secondary structures formed by the telomeric repeats. Here we present a circular dichroism (CD) analysis of complexes formed between the human translin and the microsatellite and telomeric oligodeoxynucleotides d(GT)(12) and d(TTAGGG)(5). We report that conformational changes occur in both the translin and the oligodeoxynucleotides upon formation of the complexes. In translin octamers bound to the oligodeoxynucleotide d(GT)(12), the fraction of alpha-helices decreases from approximately 67% to approximately 50%, while the fraction of turns and of the unordered structure increases from approximately 11% to approximately 17% and from approximately 19% to approximately 24%, respectively. In the bound oligodeoxynucleotide d(GT)(12), we observed CD shifts which are consistent with a decrease of base stacking and a putative anti-syn switch of some guanines. The oligodeoxynucleotide d(TTAGGG)(5) formed intramolecular quadruplexes under the conditions of our assays and translin was found to unfold the quadruplexes into structures consisting of a single hairpin and three unwound single-stranded d(TTAGGG) repeats. We suggest that such unfolding could account for the stimulation of telomerase activity by translin mentioned above.     

On the question of DNA bending: two-dimensional NMR studies on d(GTTTTAAAAC)2 in solution

It is very well documented that the presence of an An.Tn tract causes intrinsic DNA bending. Hagerman demonstrated that the sequence in which the An.Tn tracts are joined plays a very crucial role in determining DNA bending. For example, Hagerman showed that the polymer with a repeat of d(GA4T4C)n greater than or equal to 10 is bent but the polymer with a repeat of d(GT4A4C)n greater than or equal to 10 is not bent [Hagerman, P. J. (1986) Nature (London) 326, 720-722]. Earlier we have shown that the decamer repeat d(GA4T4C)2 is itself bent with a finite structural discontinuity at the A----T sequence [Sarma, M. H., Gupta, G., & Sarma, R. H. (1988) Biochemistry 27, 3423-3432]. In the present article, we summarize our studies on the decamer repeat d(GT4A4C)2 structure in solution. By employment of 1D and 2D 1H NMR studies at 500 MHz a complete sequential assignment has been made for the exchangeable and nonexchangeable protons belonging to the ten nucleotides. NOESY data were collected for d(GT4A4C)2 at 17 degrees C in D2O for three mixing times, 150, 100, and 50 ms. A quantitative NOESY simulation technique was employed to arrive at a structural model of d(GT4A4C)2 in solution. Our detailed analyses revealed the following structural features: (i) The duplex adopts the gross morphology of a B-DNA. (ii) All the A.T pairs are propeller twisted (less than or equal to -15 degrees). (iii) Although both A and T nucleotides belong to the C2'-endo,anticonformational domain, there is a mild variation in the actual conformation of the A and T residues. (iv) Even though there is a subtle conformational difference in the A and T nucleotides, two structural frames of T4.A4 segments are joined at the T----A sequence in such a way that there is no finite discontinuity at the junction; i.e., two neighboring frames exactly coincide at the T----A junction. Thus, our studies on d(GA4T4C)2 (Sarma et al., 1988) and on d(GT4A4C)2 (this article) reveal the structural peculiarity of the An.Tn tract and the effect of A----T/T----A sequence in causing DNA bending.     

Recognition of base pair inversions in duplex by chimeric (alpha,beta) triplex-forming oligonucleotides

DNA recognition by triplex-forming oligonucleotides (TFOs) is usually limited by homopurine-homopyrimidine sequence in duplexes. Modifications of the third strand may overcome this limitation. Chimeric alpha-beta TFOs are expected to form triplex DNA upon binding to non-regular sequence duplexes. In the present study we describe binding properties of chimeric alpha-beta oligodeoxynucleotides in the respect to short DNA duplexes with one, three, and five base pair inversions. Non-natural chimeric TFO's contained alpha-thymidine residues inside (GT) or (GA) core sequences. Modified residues were addressed to AT/TA inversions in duplexes. It was found in the non-denaturing gel-electrophoresis experiments that single or five adjacent base pair inversions in duplexes may be recognized by chimeric alpha-beta TFO's at 10 degrees C and pH 7.8. Three dispersed base pair inversions in the double stranded DNA prevented triplex formation by either (GT) or (GA) chimeras. Estimation of thermal stability of chimeric alpha-beta triplexes showed decrease in T(m) values as compared with unmodified complexes.     

The effect of zinc on the secondary structure of d(GA.TC)n DNA sequences of different length: a model for the formation *H-DNA.

Alternating d(GA.TC)n DNA sequences are known to undergo transition to *H-DNA in the presence of zinc. Here, the effect of zinc on the secondary DNA structure of d(GA.TC)n sequences of different length (n = 5, 8, 10 and 19) was determined. Short d(GA.TC)n sequences form *H-DNA with a higher difficulty than longer ones. At bacterial negative superhelical density (- sigma = 0.05), zinc still induces transition to the *H-DNA conformation at a d(GA.TC)10 sequence but shorter sequences do not form *H-DNA. Transition to *H-DNA at a d(GA.TC)8 sequence is observed under conditions which destabilize the DNA double helix such as high negative supercoiling or low ionic strength. Our results indicate that a first step in the transition to *H-DNA is the formation of a denaturation bubble at the centre of the repeated DNA sequence, suggesting that the primary role of zinc is to induce a local denaturation of the DNA double helix. Subsequently, zinc might also participate in the stabilization of the altered DNA conformation through its direct interaction with the bases. Based on these results a model for the formation of *H-DNA is proposed.     

B-X transition in synthetic and natural (dA-dT)n.(dA-dT)n sequences

AB-X transition of polyh(dA-dT).poly(dA-dT) was observed to occur in methanol-water mixtures with methanol concentrations higher than 50% in the presence of a specific combination of monovalent and divalent cations. In the presence of Na+, divalent cations induce denaturation of poly(dA-dT).poly(dA-dT) accompanied by condensation and/or aggregation, and effect similar to that observed previously with random sequence DNA (Votavová, Kucerová, Felsberg and Sponar, J. Biomol. Struct. Dyn. 4,477-489, 1986). In the presence of Cs+ cations a B-X transition was induced by addition of Ca2+ or Mn2+ but not Mg2+ or Ni2+ ions. Circular dichroism and ultraviolet spectroscopy demonstrate that the X conformation is a double stranded form of poly(dA-dT).poly(dA-dT) belonging presumably to the B family which, however has an altered base stacking. The X conformation of poly(dA-dT).poly(dA-dT) found in methanol-water mixtures is a condensed and/or aggregated form. In contrast, the X conformation characterized by similar CD spectra observed in high salt concentrations is not aggregated up to a concentration of 6 M CsF. In methanol-water mixtures (A+T)-rich bacterial DNA behaves essentially as a random sequence DNA revealing no detectable amount of the X form. On the other hand crab (Cancer pagurus) satellite and crab non-satellite DNAs containing varying amounts of (dA-dT)n.(dA-dT)n sequences were shown to undergo a B-X transition, at least partly, in both methanol-water mixtures and 6 M CsF solutions.     

Alternating d(GA)n DNA sequences form antiparallel stranded homoduplexes stabilized by the formation of G.A base pairs.

Alternating d(GA)n DNA sequences form antiparallel stranded homoduplexes which are stabilized by the formation of G.A pairs. Three base pairings are known to occur between adenine and guanine: AH+ (anti).G(syn), A(anti).G(anti) and A(syn).G(anti). Protonation of the adenine residues is not involved in the stabilization of this structure, since it is observed at any pH value from 8.3 to 4.5; at pH < or = 4.0 antiparallel stranded d(GA.GA) DNA is destabilized. The results reported in this paper strongly suggest that antiparallel stranded d(GA.GA) homoduplexes are stabilized by the formation of alternating A(anti).G(anti) and G(anti).A(syn) pairs. In this structure, all guanine residues are in the anti conformation with their N7 position freely accessible to DMS methylation. On the other hand, adenines in one strand adopt the anti conformation, with their N7 position also free for reaction, while those of the opposite strand are in the syn conformation, with their N7 position hydrogen bonded to the guanine N1 group of the opposite strand. A regular right-handed helix can be generated using alternating G(anti).A(syn) and A(anti).G(anti) pairs.     

In vivo assessment of the Z-DNA-forming potential of d(CA.GT)n and d(CG.GC)n sequences cloned into SV40 minichromosomes

Alternating repeated d(CA.GT)n and d(CG.GC)n sequences constitute a significant proportion of the simple repeating elements found in eukaryotic genomic DNA. These sequences are known to form left-handed Z-DNA in vitro. In this paper, we have addressed the question of the in vivo determination of the Z-DNA-forming potential of such sequences in eukaryotic chromatin. For this purpose, we have investigated the ability of a d(CA.GT)30 sequence and a d(CG.GC)5 sequence to form left-handed Z-DNA when cloned into simian virus 40 (SV40) minichromosomes at two different positions: the TaqI site, which occurs in the intron of the T-antigen gene, and the HpaII site, which is located in the late promoter region within the SV40 control region. Formation of Z-DNA at the inserted repeated sequences was analyzed through the change in DNA linkage associated with the B to Z transition. Our results indicate that regardless of: (1) the site of insertion (either TaqI or HpaII), (2) the precise moment of the viral lytic cycle (from 12 h to 48 h postinfection) and (3) the condition of incorporation of the SV40 recombinants to the host cells (either as minichromosomes or as naked DNA, relaxed or negatively supercoiled), neither the d(CA.GT)30 nor the d(CG.GC)5 sequence are stable in the left-handed Z-DNA conformation in the SV40 minichromosome. The biological relevance of these results is discussed.     

Conformational Changes Induced in the Human Protein Translin and in the Single-stranded Oligodeoxynucleotides d(GT)12 and d(TTAGGG)5 Upon Binding of These Oligodeoxynucleotides by Translin

Abstract

Translin is a human single-stranded DNA and RNA binding protein that has been highly conserved in eukaryotic evolution. It consists of eight subunits having a highly helical secondary structure that assemble into a ring. The DNA and the RNA are bound inside the ring. Recently, some of us demonstrated that the human translin specifically binds the single-stranded microsatellite repeats, d(GT)_n, the human telomeric repeats, d(TTAGGG)_n, and the Tetrahymena telomeric repeats, d(GGGGTT)_n. These data suggested that translin might be involved in recombination at d(GT)_n·d(AC)_n microsatellites and in telomere metabolism [E. Jacob, L. Pucshansky, E. Zeruya, N. Baran, H. Manor. J. Mol. Biol. 344, 939–950 (2004), S. Cohen, E. Jacob, H. Manor. Biochim. Biophys. Acta. 1679, 129–140 (2004)]. Other data indicated that translin might stimulate binding of telomerase to single- stranded telomeric overhangs by unwinding secondary structures formed by the telomeric repeats [S. Cohen, E. Jacob, H. Manor. Biochim. Biophys. Acta. 1679, 129–140 (2004)]. Here we present a circular dichroism (CD) analysis of complexes formed between the human translin and the microsatellite and telomeric oligodeoxynucleotides d(GT) and d(TTAGGG)5. We report that conformational changes occur in both the translin and the oligodeoxynucleotides upon formation of the complexes. In translin octamers bound to the oligodeoxynucleotide d(GT)12, the fraction of a-helices decreases from ～67% to ～50%, while the fraction of turns and of the unordered structure increases from ～11% to ～17% and from ～19% to ～24%, respectively. In the bound oligodeoxynucleotide d(GT), we observed CD shifts which are consistent with a decrease of base stacking and a putative anti-syn switch of some guanines. The oligodeoxynucleotide d(TTAGGG)5 formed intramolecular quadruplexes under the conditions of our assays and translin was found to unfold the quadruplexes into structures consisting of a single hairpin and three unwound single-stranded d(TTAGGG) repeats. We suggest that such unfolding could account for the stimulation of telomerase activity by translin mentioned above.     

A duplex of the oligonucleotides d(GGGGGTTTTT) and d(AAAAACCCCC) forms an A to B conformational junction in concentrated salt solutions

The coexistence of both A form and B form tracts and formation of an A-B junction in the oligomer d(GGGGGTTTTT).d(AAAAACCCCC) in saturated sodium chloride solution have been detected by Raman spectroscopy. The entire duplex adopts the familiar B-form conformation in aqueous solution at low salt concentrations (0.1M NaCl). In 6M NaCl the adoption of an A form is observed within the G,C tract while a B-form is maintained in the A.T tract. The experimental results indicate that two different helical forms can co-exist in a rather short oligonucleotide and that formation of an A-B junction can occur over a fairly small span of bases. This is in agreement with recent rules governing the relation between base sequence and secondary structure of DNA published from this laboratory. The conformational preferences of each of the individual oligomers d(AAAAACCCCC) and d(GGGGGTTTTT) have also been investigated. The oligomer d(AAAAACCCCC) is single stranded but some evidence for base stacking is observed at 2 degrees C. In contrast, a double stranded B-form structure characterized by wobble G-T base pairing is observed for d(GGGGGTTTTT) in 0.1M and 6M NaCl.     

The effect of the simple repeating d(CG.GC)n, d(CA.GT)n, and d(A.T)n DNA sequences on the nucleosomal organization of SV40 minichromosomes.

The effect of several simple repeating DNA sequences--d(CG.GC)5, d(CA.GT)30, and d(A.T)60--on the nucleosomal organization of the SV40 minichromosome is analyzed. These three different sequences were cloned at the Hpa II site of SV40 (position 346) which occurs at the 3' border of the nucleosome-free SV40 control region. Our results show that neither the d(A.T)60 sequence nor the d(CG.GC)5 sequence appear to have any relevant effect on the nucleosomal organization of the region of the minichromosome surrounding the inserted repeated sequence. Both sequences are hypersensitive to micrococcal nuclease cleavage in the minichromosome, indicating that they are not organized into nucleosomes. On the other hand, the d(CA.GT)30 sequence is found organized as nucleosomes and causes the delocation of nucleosomes in the minichromosomal region close to the inserted repeated sequence.