spn-A/rad51 mutant exhibits enhanced genomic damage, cell death and low temperature sensitivity in somatic tissues.

Homologous recombination (HR) is one of the key pathways to repair double-strand breaks (DSBs). Rad51 serves an important function of catalysing strand exchange between two homologous sequences in the HR pathway. In higher organisms, rad51 function is indispensable with its absence leading to early embryonic lethality, thus precluding any mechanistic probing of the system. In contrast, the absence of Drosophila rad51 (spn-A/rad51) has been associated with defects in the germline, without any reported detrimental consequences to Drosophila somatic tissues. In this study, we have performed a systematic analysis of developmental defects in somatic tissues of spn-A mutant flies by using genetic complementation between multiple spn-A alleles. Our current study, for the first time, uncovers a requirement for spn-A in somatic tissue maintenance during both larval and pupal stages. Also, we show that spn-A mutant exhibits patterning defects in abdominal cuticle in the stripes and bristles, while there appear to be only subtle defects in the adult wing and eye. Interestingly, spn-A mutant shows a discernible phenotype of low temperature sensitivity, suggesting a role of spn-A in temperature sensitive cellular processes. In summary, our study describes the important role played by spn-A/rad51 in Drosophila somatic tissues.

GTP binding leads to narrowing of the conformer population while preserving the structure of the RNA aptamer: a site-specific time-resolved fluorescence dynamics study.

In this study, we employed a combination of steady-state and time-resolved fluorescence spectroscopy and studied the site-specific dynamics in a GTP aptamer using 2-aminopurine as a fluorescent probe. We compared the dynamics of the GTP-bound aptamer with that of the free aptamer as well as when it is denatured. GTP binding leads to an overall compaction of structure in the aptamer. The general pattern of fluorescence lifetimes and correlation times scanned across several locations in the aptamer does not seem to change following GTP binding. However, a remarkable narrowing of the lifetime distribution of the aptamer ensues following its compaction by GTP binding. Interestingly, such a "conformational narrowing" is evident from the lifetime readouts of the nucleotide belonging to the stem as well as the "bulge" part of the aptamer, independent of whether it is directly interacting with GTP. Taken together, these results underscore the importance of an overall intrinsic structure associated with the free aptamer that is further modulated following GTP binding. This work provides strong support for the "conformational selection" hypothesis of ligand binding.

Effect of intense, ultrashort laser pulses on DNA plasmids in their native state: strand breakages induced by in situ electrons and radicals.

Single strand breaks are induced in DNA plasmids, pBR322 and pUC19, in aqueous media exposed to strong fields generated using ultrashort laser pulses (820 nm wavelength, 45 fs pulse duration, 1 kHz repetition rate) at intensities of 1-12 TW cm(-2). The strong fields generate, in situ, electrons and radicals that induce transformation of supercoiled DNA into relaxed DNA, the extent of which is quantified. Introduction of electron and radical scavengers inhibits DNA damage; results indicate that OH radicals are the primary (but not sole) cause of DNA damage.

Site-specific dynamics in TAT triplex DNA as revealed by time-domain fluorescence of 2-aminopurine.

Triple helices of DNA are finding increasing level of applications in several areas, including antigene therapy and gene regulation. We have probed site-specific dynamic aspects of TAT triple helices of DNA by using steady-state and time-domain fluorescence of 2-aminopurine (2-AP), a fluorescent analog of adenine. TAT triplexes were formed from repeats of adenine and thymine with 2-AP incorporated at various locations in the polyadenine strand. We find an overall decrease in the level of near-neighbor base-stacking interaction in the TAT triplex when compared to AT duplex as reported by fluorescence decay kinetics of 2-AP. More strikingly, we have observed a stark asymmetry in both the level of base stacking and motional dynamics of the bases in the two ends of TAT triplexes, namely, the 5' end having a higher level of base stacking and segmental dynamics when compared to the 3' end. The possible implications of this asymmetry, which reflects the asymmetry in the strength of Hoogstein base-pairing with the 3' end having stronger Hoogstein pairing when compared to the 5' end, is discussed.

How specific is the first recognition step of homologous recombination?

The Escherichia coli RecA protein promotes homologous recognition in base triplets via non-Watson-Crick bonds that differ from those formed nonenzymically from DNA consisting of runs of purines or pyrimidines. Base substitutions reveal recognition to be permissive, consistent with a search for homology that achieves speed at the cost of precision.

Genome Damage Sensing Leads to Tissue Homeostasis in Drosophila.

DNA repair is a critical cellular process required for the maintenance of genomic integrity. It is now well appreciated that cells employ several DNA repair pathways to take care of distinct types of DNA damage. It is also well known that a cascade of signals namely DNA damage response or DDR is activated in response to DNA damage which comprise cellular responses, such as cell cycle arrest, DNA repair and cell death, if the damage is irreparable. There is also emerging literature suggesting a cross-talk between DNA damage signaling and several signaling networks within a cell. Moreover, cell death players themselves are also well known to engage in processes outside their canonical function of apoptosis. This chapter attempts to build a link between DNA damage, DDR and signaling from the studies mainly conducted in mammals and Drosophila model systems, with a special emphasis on their relevance in overall tissue homeostasis and development.

Human RAD52 protein regulates homologous recombination and checkpoint function in BRCA2 deficient cells.

Cancer cells exhibit HR defects, increased proliferation and checkpoint aberrations. Tumour suppressor proteins, BRCA2 and p53 counteract such aberrant proliferation by checkpoint regulation. Intriguingly, chemo-resistant cancer cells, exhibiting mutated BRCA2 and p53 protein survive even with increased DNA damage accumulation. Such cancer cells show upregulation of RAD52 tumour suppressor protein implying that RAD52 might be providing survival advantage to cancer cells. To understand this paradoxical condition of a tumour suppressor protein facilitating cancer cell survival, in the current study, we investigate the role of RAD52 overexpression in BRCA2 deficient cells. We provide evidence that RAD52 protein alleviates HR inhibition imposed by p53 in BRCA2 deficient cells. In addition, we study the role of RAD52 protein during short replication stress in BRCA2 deficient cells. BRCA2 deficient cells exhibit excessive origin firing and checkpoint evasion in the presence of prevailing DNA damage. Interestingly, overexpression of RAD52 rescues the excessive origin firing and checkpoint defects observed in BRCA2 deficient cells, indicating RAD52 protein compensates for the loss of BRCA2 function. We show that RAD52 protein, just as BRCA2, interacts with pCHK1 checkpoint protein and helps maintain the checkpoint control in BRCA2 deficient cells during DNA damage response.

Site-specific dynamics of strands in ss- and dsDNA as revealed by time-domain fluorescence of 2-aminopurine.

It is well recognized that structure and dynamics of DNA strands guide proteins toward their cognate sites in DNA. While the dynamics is controlled primarily by the nucleotide sequence, the context of a particular sequence in relation to an open end could also play a significant role. In this work we have used the fluorescent analogue of adenine, 2-aminopurine (2-AP), to extract information on site-specific dynamics of DNA strands associated with 30-70 nucleotides length. Measurement of fluorescence lifetime and anisotropy decay kinetics in various types of DNA strands in which 2-AP was located in specific positions revealed novel insights into the dynamics of strands. We find that in single-stranded (ss) DNA, the extent of motional dynamics of the bases falls off sharply from the very end toward the middle of the strand. In contrast, the flexibility of the backbone decreases more gradually in the same direction. In double-stranded (ds) DNA, the level of base-pair fraying increases toward the ends in a graded manner. Surprisingly, the same is countered by the presence of ss-overhangs emanating from dsDNA ends. Moreover, the extent of concerted motion of bases in duplex DNA increased from the end to the middle of the duplex, a result which is both striking and counterintuitive. Most surprisingly, the two complementary strands of a duplex that were unequal in length exhibited differential dynamics: the longer one with overhangs showed a distinctly higher level of flexibility than the recessed shorter strand in the same duplex. All these results, taken together, provoke newer insights in our understanding of how different bases in DNA strands are endowed with specific dynamic properties as a function of their positions. These properties are likely to be used in facilitating specific recognitions of DNA bases by proteins during various DNA-protein interaction systems.

ATP-hydrolysis-dependent conformational switch modulates the stability of MutS-mismatch complexes.

The mismatch repair pathway in Escherichia coli has been extensively studied in vitro as well as in vivo. The molecular mechanisms by which nucleotide cofactors regulate the whole process constitute an area of active debate. Here we demonstrate that nucleotide (ADP or ATP) binding to MutS mediates a switch in protein conformation. However, in MutS that is DNA bound, this switch ensues only with ATP and not with ADP and is similar, irrespective of whether it is bound to a homo- or a heteroduplex. The results envisage a minimal model of three confor-mational states of MutS as reflected in: (i) a specific and highly stable MutS-mismatch complex in the absence of a nucleotide; (ii) a specific but less stable complex in the presence of ATP hydrolysis; and (iii) an irreversibly dissociated complex in the presence of ATP binding (ATPgammaS). Such transitions are of relevance to the protein's function in vivo where it has to first recognize a mismatch, followed by a search for hemimethylated sites.

Incoming nucleotide binds to Klenow ternary complex leading to stable physical sequestration of preceding dNTP on DNA.

Klenow-DNA complex is known to undergo a rate-limiting, protein conformational transition from an 'open' to 'closed' state, upon binding of the 'correct' dNTP at the active site. In the 'closed' state, Mg(2+) mediates a rapid chemical step involving nucleophilic displacement of pyrophosphate by the 3' hydroxyl of the primer terminus. The enzyme returns to the 'open' state upon the release of PPi and translocation permits the next round of reaction. To determine whether Klenow can translocate to the next site on the addition of the next dNTP, without the preceding chemical step, we studied the ternary complex (Klenow-DNA-dNTP) in the absence of Mg(2+). While the ternary complex is proficient in chemical addition of dNTPs in Mg(2+), as revealed by primer extensions, the same in Mg(2+)-deficient conditions lead to non-covalent (physical) sequestration of first two 'correct' dNTPs in the ternary complex. Moreover, the second dNTP traps the first one in the DNA-helix of the ternary complex. Such a dNTP-DNA complex is found to be stable even after the dissociation of KLENOW: This reveals the novel state of the dNTP-DNA complex where the complementary base is stacked in a DNA-helix non-covalently, without the phosphodiester linkage. Further, shuttling of the DNA between the polymerase and the exonuclease site mediates the release of such a DNA complex. Interestingly, Klenow in such a Mg(2+)-deficient ternary complex exhibits a 'closed' conformation.

Fold-back structures at the distal end influence DNA slippage at the proximal end during mononucleotide repeat expansions.

Polymerase slippage during DNA synthesis by the Klenow fragment of DNA polymerase across A, C, G and T repeats (30 bases) has been studied. Within minutes, duplexes that contain only repeats (30 bp) expand dramatically to several hundred base pairs long. Rate comparisons in a repeat duplex when one strand was expanded as against that when both strands were expanded suggest a model of migrating hairpin loops which in the latter case coalesce into a duplex. Moreover, slippage (at the proximal or 3'-end) is subject to positive and negative effects from the 5'-end (distal) of the same strand. Growing T and G strands generate T.A:T and G-G:C motif fold-back structures at the distal end that hamper slippage at the proximal end. On the other hand, growing tails at the distal end upon annealing with excess complementary template accentuates proximal slippage several-fold.

The effects on strand exchange of 5' versus 3' ends of single-stranded DNA in RecA nucleoprotein filaments.

Since the ends of DNA chains are thought to be important in homologous recombination, the way in which RecA protein and similar recombination enzymes process ends is important. We analyzed the effects of ends both on the formation of joints, and the progression of strand exchange. When the only homologous end was provided by a single strand, there was no significant difference between the formation of joints at a 5' end or a 3' end; but in agreement with the report of Konforti & Davis, Escherichia coli single-stranded DNA binding protein (SSB) selectively inhibited the activity of 5' ends. Complete strand exchange, assessed by study of linear single-stranded and double-stranded substrates, took place only in the 5' to 3' direction relative to DNA in the nucleoprotein filament. These observations pose a paradox: in the presence of SSB, of which there are about 800 tetramers per cell, the formation of homologous joints by RecA protein is favored at a 3' end, from which, however, authentic strand exchange appears not to occur. Since observations reported here and elsewhere show that joints have different properties when formed at a 5' versus a 3' end, we suggest that they may be processed differently in vivo.

RecA protein reinitiates strand exchange on isolated protein-free DNA intermediates. An ADP-resistant process.

Efficient homologous pairing de novo of linear duplex DNA with a circular single strand (plus strand) coated with RecA protein requires saturation and extension of the single strand by the protein. However, strand exchange, the transfer of a strand from duplex DNA to the nucleoprotein filament, which follows homologous pairing, does not require the stable binding of RecA protein to single-stranded DNA. When RecA protein was added back to isolated protein-free DNA intermediates in the presence of sufficient ADP to inhibit strongly the binding of RecA protein to single-stranded DNA, strand exchange nonetheless resumed at the original rate and went to completion. Characterization of the protein-free DNA intermediate suggested that it has a special site or region to which RecA protein binds. Part of the nascent displaced plus strand of the deproteinized intermediate was unavailable as a cofactor for the ATPase activity of RecA protein, and about 30% resisted digestion by P1 endonuclease, which acts preferentially on single-stranded DNA. At the completion of strand exchange, when the distal 5' end of the linear minus strand had been fully incorporated into heteroduplex DNA, a nucleoprotein complex remained that contained all three strands of DNA from which the nascent displaced strand dissociated only over the next 50 to 60 minutes. Deproteinization of this intermediate yielded a complex that also contained three strands of DNA in which the nascent displaced strand was partially resistant to both Escherichia coli exonuclease I and P1 endonuclease. The deproteinized complex showed a broad melting transition between 37 degrees C and temperatures high enough to melt duplex DNA. These results show that strand exchange can be subdivided into two stages: (1) the exchange of base-pairs, which creates a new heteroduplex pair in place of a parental pair; and (2) strand separation, which is the physical displacement of the unpaired strand from the nucleoprotein filament. Between the creation of new heteroduplex DNA and the eventual separation of a third strand, there exists an unusual DNA intermediate that may contain three-stranded regions of natural DNA that are several thousand bases in length.

Homologous recognition and triplex formation promoted by RecA protein between duplex oligonucleotides and single-stranded DNA.

RecA protein formed a stable triplex from a 33 bp duplex oligonucleotide and a circular plus strand of M13 DNA when a hairpin connection at the proximal end of the homologous duplex oligonucleotide blocked displacement of the 5' end of its own plus strand. An oligonucleotide with a hairpin connection at the other end yielded five times fewer joints that survived deproteinization, and an ordinary duplex oligonucleotide yielded none. The stability of the three-stranded structure was not attributable to exonucleolytic nibbling of the 3' end of the hairpin oligonucleotide, which could generate a region of stable duplex DNA. In the triplexes, the hairpin duplex became more accessible to copper phenanthroline, exhibited novel sites of cleavage by DNase I, and resisted digestion by Escherichia coli exonuclease I. The enzymatic methylation of only two residues at N-6 adenine and two at N-4 cytosine in the hairpin duplex prior to the pairing reaction lowered the tm of triplexes by 8 deg.C, whereas extensive methylation at N-7 guanine by dimethyl sulfate had no effect. These results are discussed in relation to possible models of triplex DNA.

Resolution of the three-stranded recombination intermediate made by RecA protein. An essential role of ATP hydrolysis.

Previous work has shown that triplex DNA is an intermediate in homologous pairing and strand exchange promoted by RecA protein. Heterology at the proximal end of duplex DNA blocks strand exchange, but triplex joints form nonetheless at the homologous distal end. Experiments on the formation and processing of distal joints revealed that the yield of distal joints depends critically on the concentration of RecA-coated single strands and the adequacy of the ATP-regeneration system, and reflects a steady state. Distal joints reversibly formed and dissociated, as shown by several methods, including a chase with unlabeled duplex DNA. Controls excluded a contribution of exonucleolytic nibbling to the formation of distal joints and the stability of the deproteinized product. RecA protein was bound preferentially by putative triplex sites both in isolated proximal and distal joints. These high affinity sites disappeared from proximal joints as strand exchange progressed, and disappeared from distal joints as the joints dissociated. Dissociation of distal joints under all conditions, however, was completely arrested by the addition of ATP gamma S. Distal triplex joints can be as long as six kilobases. The observed inhibition of the dissociation of such long non-productive triplex intermediates by ATP gamma S leads us to propose that an essential role of ATP hydrolysis in RecA recombinational exchanges may be to ensure that no potentially troublesome triplex DNA remains in the cell.

(1)H, (13)C and (15)N NMR assignments of Mg (2+) bound form of UV inducible transcript protein (UVI31+) from Chlamydomonas reinhardtii.

Almost complete sequence specific (1)H, (13)C and (15)N resonance assignments of Mg(2+) bound form of UV inducible transcript protein (UVI31+) from Chlamydomonas reinhardtii are reported, as a prelude to its structural and functional characterization.

Quantitative analysis of chromosome localization in the nucleus.

The spatial organization of the genome within the interphase nucleus is important for mediating genome functions. The radial organization of chromosome territories has been studied traditionally using two-dimensional fluorescence in situ hybridization (FISH) using labeled whole chromosome probes. Information from 2D-FISH images is analyzed quantitatively and is depicted in the form of the spatial distribution of chromosomes territories. However, to the best of our knowledge no open-access tools are available to delineate the position of chromosome territories from 2D-FISH images. In this chapter we present a methodology termed Image Analysis of Chromosomes for computing their localization (IMACULAT). IMACULAT is an open-access, automated tool that partitions the cell nucleus into shells of equal area or volume and computes the spatial distribution of chromosome territories.

Real time fluorescence analysis of the RecA filament: implications of base pair fluidity in repeat realignment.

During recombination, when Escherichia coli RecA mediates annealing across DNA repeats, Watson-Crick chemistry can only specify the complementarity of pairing, but not the most optimal frame of alignment. We describe that although stochastic alignments across poly(dA) and poly(dT) can lead to sub-optimally annealed duplexes containing ssDNA gaps/overhangs, the same are realigned into an optimal frame by a putative motor activity of RecA [Sen et al. (2000) Biochemistry 39, 10196-10206]. In the present study, we analyze the nature of realignment intermediates in real time, by employing a fluorescent probe, 2-aminopurine (2AP), which can not only report the status of RecA on the unstacked duplex, but also the fluidity of bases in such a filament. Although known to display a lower affinity for duplex DNA, RecA seems to remain functionally associated with these sub-optimally aligned repeat duplexes, until the realignment approaches completion. Moreover, a comparison of 2AP fluorescence in repeat versus mixed sequences indicates that bases in a RecA repetitive DNA filament exhibit higher degrees of freedom that might mediate a 'non-planar hydrogen bonding cross talk' across the bases on either strand. We discuss a model to explain the mechanistic basis of realignment and its implications in signaling the end of homology maximization, which triggers RecA fall off.

Non-Watson-Crick base pairs modulate homologous alignments in RecA pairing reactions.

Complementary pairing by RecA was examined in vitro to investigate how homology is deciphered from non-homology. Somewhere in a window of 40-50% sequence complementarity, RecA pairing begins to manifest the specificity of homology. Quantitation reveals a hierarchy among non-Watson-Crick mispairs: RecA reaction treats six out of 12 possible mispairs as good ones and three each of the remaining ones as moderate and bad pairs. The mispairs seem to function as independent pairing units free of sequence context effects. The overall strength of pairing is simply the sum of the constituent units. RecA mediated gradation of mispairs, free of sequence context effects, might offer a general thumb-rule for predicting the pairing strength of any alignment that carries multiple mispairs.

Production of triple-stranded recombination intermediates by RecA protein, in vitro.

During the directional strand exchange that is promoted by RecA protein between linear duplex DNA and circular single-stranded DNA, a triple-stranded DNA intermediate was formed and persisted even after the completion of strand transfer followed by deproteinization. In the deproteinized three-stranded DNA complexes, the sequestered linear third strand resisted digestion by E coli exonuclease I. In relation to polarity of strand exchange which defines the proximal and distal ends of the duplex DNA, when homology was restricted to the distal region of duplex substrate, the joints formed efficiently and were stable even upon complete deproteinization. Enzymatic probing of deproteinized distal joints with nuclease P1 revealed that the joints consist of long three-stranded structures that at neutral pH lack significant single-stranded character in any of the three strands. Instead of circular single-stranded DNA, when a linear single strand is recombined with partially homologous duplex DNA, in the presence of SSB, the formation of homologous joints by RecA protein, is significantly more efficient at distal end than at the proximal. Taken together, these observations suggest that with any single-stranded DNA (circular or linear), RecA protein efficiently promotes the formation of distal joints, from which, however, authentic strand exchange may not occur. Moreover, these joints might represent an intermediate which is trapped into a stable triple stranded state.