Polyamines interact with DNA as molecular aggregates.

New compounds, named nuclear aggregates of polyamines, having a molecular mass of 8000, 4800 and < 1000 Da, were found in the nuclear extracts of several replicating cells. Their molecular structure is based on the formation of ionic bonds between polyamine ammonium and phosphate groups. The production of the 4800 Da compound, resulting from the aggregation of five or more < 1000 Da units, was increased in Caco-2 cells treated with the mitogen gastrin. Dissolving single polyamines in phosphate buffer resulted in the in vitro aggregation of polyamines with the formation of compounds with molecular masses identical to those of natural aggregates. After the interaction of the 4800 Da molecular aggregate with the genomic DNA at 37 degrees C, both the absorbance of DNA in phosphate buffer and the DNA mobility in agarose gel increased greatly. Furthermore, these compounds were able to protect the genomic DNA from digestion by DNase I, a phosphodiesterasic endonuclease. Our data indicate that the nuclear aggregate of polyamines interacts with DNA phosphate groups and influence, more efficaciously than single polyamines, both the conformation and the protection of the DNA.     

Nuclear aggregates of polyamines

Nuclear aggregates of polyamines (NAPs) are cyclic supramolecular compounds made of polyamines and phosphate groups. Three different aggregates, s-NAP, m-NAP and l-NAP, with a molecular weight of 1035, 5175 and 9552 Da, respectively, are described. These molecules interact with genomic DNA. In consequence of this interaction, NAPs not only protect DNA from nucleases with extraordinarily greater efficiency than single polyamines (spermine, spermidine and putrescine), but also induce noticeable changes in DNA condensation status, as shown by temperature-dependent modifications of DNA electrophoretic properties. The biochemical characterization of these compounds has allowed the definition of a structural model for each NAP. According to this model, five s-NAPs assemble together to form a m-NAP unit. We hypothesize that the complexation of s-NAP into m-NAP favours the transition to Z-DNA through the progressive widening of DNA strands and the exposure of bases. We propose that NAPs, by wrapping the DNA helixes, form supramolecular tunnel-like structures that confer efficient protection without affecting DNA elasticity.     

DNA is wrapped by the nuclear aggregates of polyamines: the imaging evidence

In the cell nucleus, putrescine, spermidine, and spermine self-assemble with phosphate ions to generate three forms of compounds, named nuclear aggregates of polyamines (NAPs), which may interact with DNA. In an in vitro setting mimicking the cell nucleus milieu, this molecular aggregation occurs within well-defined ratios. Structural and functional analogies exist between the in vitro NAPs (ivNAPs) and their extractive homologues. The present Article reports images of ivNAPs at different resolution levels. Independent of the DNA template, ivNAPs become hierarchically stacked to produce ultimately macroscopic filamentous structures. The ivNAP-DNA complexes arranged in long and repetitive structures that displayed the self-similar features of natural fractals when dehydrated onto glass slides. Atomic force microscopy showed that ivNAPs have a cyclic structure and dispose around the DNA in a tube-like arrangement. Overall, the images indicate that these aggregates envelope the genomic DNA, thus proving that NAPs play a crucial role in DNA compaction and functioning.     

DNA and nuclear aggregates of polyamines

Polyamines (PAs) are linear polycations that are involved in many biological functions. Putrescine, spermidine and spermine are highly represented in the nucleus of eukaryotic cells and have been the subject of decades of extensive research. Nevertheless, their capability to modulate the structure and functions of DNA has not been fully elucidated. We found that polyamines self-assemble with phosphate ions in the cell nucleus and generate three forms of compounds referred to as Nuclear Aggregates of Polyamines (NAPs), which interact with genomic DNA. In an in vitro setting that mimics the nuclear environment, the assembly of PAs occurs within well-defined ratios, independent of the presence of the DNA template. Strict structural and functional analogies exist between the in vitro NAPs (ivNAPs) and their cellular homologues. Atomic force microscopy showed that ivNAPs, as theoretically predicted, have a cyclic structure, and in the presence of DNA, they form a tube-like arrangement around the double helix. Features of the interaction between ivNAPs and genomic DNA provide evidence for the decisive role of "natural" NAPs in regulating important aspects of DNA physiology, such as conformation, protection and packaging, thus suggesting a new vision of the functions that PAs accomplish in the cell nucleus.     

Nuclear aggregates of polyamines in a radiation-induced DNA damage model

Polyamines (PA) are believed to protect DNA minimizing the effect of radiation damage either by inducing DNA compaction and aggregation or acting as scavengers of free radicals. Using an in vitro pDNA double strand breakage assay based on gel electrophoretic mobility, we compared the protective capability of PA against γ-radiation with that of compounds generated by the supramolecular self-assembly of nuclear polyamines and phosphates, named Nuclear Aggregates of Polyamines (NAPs). Both unassembled PA and in vitro produced NAPs (ivNAPs) were ineffective in conferring pDNA protection at the sub-mM concentration. Single PA showed an appreciable protective effect only at high (mM) concentrations. However, concentrations of spermine (4+) within a critical range (0.481 mM) induced pDNA precipitation, an event that was not observed with NAPs–pDNA interaction. We conclude that the interaction of individual PA is ineffective to assure DNA protection, simultaneously preserving the flexibility and charge density of the double strand. Furthermore, data obtained by testing polyamine and ivNAPS with the current radiation-induced DNA damage model support the concept that PA-phosphate aggregates are the only forms through which PA interact with DNA.     

Analysis of chromatin in limited numbers of cells: a PCR-SSCP based assay of allele-specific nuclease sensitivity.

Chromatin can be analysed by assaying its sensitivity to DNase I or other nucleases in purified nuclei. Usually, this is performed by Southern analysis of genomic DNA extracted from nuclease-treated nuclei, a methodology that requires many cells. Applying restriction fragment length polymorphisms (RFLPs), this methodology has been used for parental allele-specific chromatin studies on imprinted mammalian genes. However, such allelic studies are limited by the availability of suitable RFLPs. We therefore developed an alternative, PCR and single strand conformation polymorphism (SSCP)-based assay with which allelic sensitivity to nucleases can be determined in virtually all localised regions that have nucleotide polymorphisms. We also demonstrate that analysis of DNase I sensitivity can be performed on permeabilised cells. Combining the two approaches, in the imprinted mouse U2af1-rs1 gene we analysed parental allele-specific chromatin conformation in limited numbers of cultured cells. We also applied the PCR-SSCP approach to assay allelic DNA methylation at specific restriction enzyme sites. In summary, we developed an allele-specific assay that should be useful for biochemical and developmental investigation of chromatin, in particular for studies on genomic imprinting and X-chromosome inactivation.     

NapM,a new nucleoid‐associated protein,broadly regulates gene expression and affects mycobacterial resistance to anti‐tuberculosis drugs

Nucleoid‐associated proteins (NAPs) play important roles in the global organization of bacterial chromosomes. However, potential NAPs and their functions are barely characterized in mycobacteria. In this study, NapM, an alkaline protein, functions as a new NAP. NapM is conserved in all of the sequenced mycobacterial genomes, and can recognize DNA in a length‐dependent but sequence‐independent manner. It prefers AT‐rich DNA and binds to the major groove. NapM possesses a clear DNA‐bridging function, and can protect DNA from DNase I digestion. NapM globally regulates the expression of more than 150 genes and the resistance of Mycobacterium smegmatis to two anti‐tuberculosis drugs, namely, rifampicin and ethambutol. An ABC transporter operon was found to be specifically responsible for the napM‐dependent ethambutol resistance of M. smegmatis. NapM also presents a similar regulation of anti‐tuberculosis drug resistance in M. tuberculosis. These results suggest that NapM is a new member of the mycobacterial NAP family. Our findings expand the range of identified NAPs and improve the understanding on the relationship between NAPs with antibiotic resistance in mycobacteria.     

Identification and purification of DBF-A, a double-stranded DNA-binding protein from Saccharomyces cerevisiae.

Using oligonucleotide affinity chromatography with DNase I footprinting as an assay we have looked for proteins that interact with sequence elements within the yeast origin of replication, autonomously replicating sequence 1 (ARS1). In this work we describe a protein that binds with high affinity to DNA but displays only moderate sequence specificity. It is eluted at 0.7 M salt from an ARS1 oligonucleotide column. Footprinting analysis on ARS1 at a high protein concentration revealed at least three sites of protection flanking element A and its repeats. Element A itself is rendered hypersensitive to DNase I digestion upon protein binding. This pattern is also observed for the H4 and HMR-E ARSs, suggesting that the protein alters the DNA conformation at element A and its repeats. The affinity-purified fraction is also capable of supercoiling a relaxed, covalently closed plasmid in the presence of topoisomerase. Highly purified preparations of the protein are enriched in an 18-kDa polypeptide which can be renatured from a denaturing gel and shown to bind ARS1 DNA. We have designated this protein DBF-A, DNA-binding factor A.     

Conformational modification of serpins transforms leukocyte elastase inhibitor into an endonuclease involved in apoptosis

The best-characterized biochemical feature of apoptosis is degradation of genomic DNA into oligonucleosomes. The endonuclease responsible for DNA degradation in caspase-dependent apoptosis is caspase-activated DNase. In caspase-independent apoptosis, different endonucleases may be activated according to the cell line and the original insult. Among the known effectors of caspase-independent cell death, L-DNase II (LEI [leukocyte elastase inhibitor]-derived DNase II) has been previously characterized by our laboratory. We have thus shown that this endonuclease derives from the serpin superfamily member LEI by posttranslational modification (A. Torriglia, P. Perani, J. Y. Brossas, E. Chaudun, J. Treton, Y. Courtois, and M. F. Counis, Mol. Cell. Biol. 18:3612-3619, 1998). In this work, we assessed the molecular mechanism involved in the change in the enzymatic activity of this molecule from an antiprotease to an endonuclease. We report that the cleavage of LEI by elastase at its reactive center loop abolishes its antiprotease activity and leads to a conformational modification that exposes an endonuclease active site and a nuclear localization signal. This represents a novel molecular mechanism for a complete functional conversion induced by changing the conformation of a serpin. We also show that this molecular transformation affects cellular fate and that both endonuclease activity and nuclear translocation of L-DNase II are needed to induce cell death.     

The N-terminal fragment of gelsolin inhibits the interaction of DNase I with isolated actin, but not with the cofilin-actin complex

Apoptosis is essential in embryonic development, clonal selection of cells of the immune system and in the prevention of cancer. Apoptotic cells display characteristic changes in morphology that precede the eventual fragmentation of nuclear DNA resulting in cell death. Current evidence implicates DNase I as responsible for hydrolysis of DNA during apoptosis. In vivo, it is likely that cytoplasmic actin binds and inhibits the enzymatic activity and nuclear translocation of DNase I and that disruption of the actin-DNase I complex results in activation of DNase I. In this report we demonstrate that the N-terminal fragment of gelsolin (N-gelsolin) disrupts the actin-DNase I interaction. This provides a molecular mechanism for the role of the N-gelsolin in regulating DNase I activity. We also show that cofilin stabilises the actin-DNase I complex by forming a ternary complex that prevents N-gelsolin from releasing DNase I from actin. We suggest that both cofilin and gelsolin are essential in modulating the release of DNase I from actin.     

103 Probing DNA shape and methylation state on a genomic scale with DNase I

DNA binding proteins find their cognate sequences within genomic DNA through recognition of specific chemical and structural features. Here, we demonstrate that high-resolution DNase I cleavage profiles can provide detailed information about the shape and chemical modification status of genomic DNA. Analyzing millions of DNA-backbone hydrolysis events on naked genomic DNA, we show that the intrinsic rate of cleavage by DNase I closely tracks the width of the minor groove. Integration of these DNase I cleavage data with bisulfite sequencing data for the same cell type genome reveals that the cleavage directly adjacent to CpG dinucleotides is enhanced at least eight-fold by cytosine methylation. This phenomenon we show is attributable to methylation-induced narrowing of the minor groove. Furthermore, we demonstrate that it enables simultaneous mapping of DNase I hypersensitivity and regional DNA methylation levels using dense in vivo cleavage data. Taken together, our results suggest a general mechanism through which CpG methylation can modulate protein–DNA interaction strength via the remodeling of DNA shape.     

Functional characterization of DNase X, a novel endonuclease expressed in muscle cells

The activation of endonucleases resulting in the degradation of genomic DNA is one of the most characteristic changes in apoptosis. Here, we report the characterization of a novel endonuclease, termed DNase X due to its X-chromosomal localization. The active nuclease is a 35 kDa protein with 39% identity to DNase I. When incubated with isolated nuclei, recombinant DNase X was capable of triggering DNA degradation at internucleosomal sites. Similarly to DNase I, the nuclease activity of DNase X was dependent on Ca(2+) and Mg(2+) and inhibited by Zn(2+) ions or chelators of bivalent cations. Overexpression of DNase X caused internucleosomal DNA degradation and induction of cell death associated with increased caspase activation. Despite the presence of two potential caspase cleavage sites, DNase X was processed neither in vitro nor in vivo by different caspases. Interestingly, after initiation of apoptosis DNase X was translocated from the cytoplasm to the nuclear compartment and aggregated as a detergent-insoluble complex. Abundant expression of DNase X mRNA was detected in heart and skeletal muscle cells, suggesting that DNase X may be involved in apoptotic or other biological events in muscle tissues.     

A novel nucleoid-associated protein of Mycobacterium tuberculosis is a sequence homolog of GroEL

The Mycobacterium tuberculosis genome sequence reveals remarkable absence of many nucleoid-associated proteins (NAPs), such as HNS, Hfq or DPS. In order to characterize the nucleoids of M. tuberculosis, we have attempted to identify NAPs, and report an interesting finding that a chaperonin-homolog, GroEL1, is nucleoid associated. We report that M. tuberculosis GroEL1 binds DNA with low specificity but high affinity, suggesting that it might have naturally evolved to bind DNA. We are able to demonstrate that GroEL1 can effectively function as a DNA-protecting agent against DNase I or hydroxyl-radicals. Moreover, Atomic Force Microscopic studies reveal that GroEL1 can condense a large DNA into a compact structure. We also provide in vivo evidences that include presence of GroEL1 in purified nucleoids, in vivo crosslinking followed by Southern hybridizations and immunofluorescence imaging in M. tuberculosis confirming that GroEL1: DNA interactions occur in natural biological settings. These findings therefore reveal that M. tuberculosis GroEL1 has evolved to be associated with nucleoids.     

Variegated expression of a globin transgene correlates with chromatin accessibility but not methylation status.

There are now many mammalian examples in which single cell assays of transgene activity have revealed variegated patterns of expression. We have previously reported that transgenes in which globin regulatory elements drive the lacZ reporter gene exhibit variegated expression patterns in mouse erythrocytes, with transgene activity detectable in only a sub-population of circulating erythroid cells. In order to elucidate the molecular mechanism responsible for variegated expression in this system, we have compared the chromatin structure and methylation status of the transgene locus in expressing and non-expressing populations of erythrocytes. We find that there is a difference in the chromatin conformation of the transgene locus between the two states. Relative to active transgenes, transgene loci which have been silenced exhibit a reduced sensitivity to general digestion by DNase I, as well as a failure to establish a transgene-specific DNase I hypersensitive site, suggesting that silenced transgenes are situated within less accessible chromatin structures. Surprisingly, the restrictive chromatin structure observed at silenced transgene loci did not correlate with increased methylation, with transgenes from both active and inactive loci appearing largely unmethylated following analysis with methylation-sensitive restriction enzymes and by sequencing PCR products derived from bisulphite-converted genomic DNA.     

Interaction of a nuclear factor-1-like protein with the regulatory region of the human polyomavirus JC virus

We have initiated a study to identify host proteins which interact with the regulatory region of the human polyomavirus JC (JCV), which is associated with the demyelinating disease, progressive multifocal leukoencephalopathy. We examined the interaction of nuclear proteins prepared from different cell lines with the JCV regulatory region by DNA binding gel retardation assays. Binding was detected with nuclear extracts prepared from human fetal glial cells, glioma cells, and HeLa cells. Little or no binding was detected with nuclear extracts prepared from human embryonic kidney cells. Competitive binding assays suggest that the nuclear factor(s) which interacted with the JCV regulatory region was different from those which interacted with the regulatory region of the closely related polyomavirus SV40. We found three areas in the JCV regulatory region protected from DNase I digestion: site A, located just upstream from the TATA sequence in the first 98-base pair (bp) repeat; site B, located upstream from the TATA sequence in the second 98-bp repeat; and site C, located just following the second 98-bp repeat. There were some differences in the ability of the nuclear factor(s) from the two brain cell lines and HeLa cells to completely protect the nucleotides within the footprint region. The results from the DNase I protective studies and competitive DNA binding studies with specific oligonucleotides, suggest that nuclear factor-1 or a nuclear factor-1-like factor is interacting with all three sites in the JCV regulatory region. In addition, the results suggest that the nuclear factor which interacts with the JCV regulatory region from human brain cell lines is different from the factor found in HeLa cells.     

Endogenous polyamines are intimately associated with highly condensed chromatin in vivo. A fluorescence cytochemical and immunocytochemical study of spermine and spermidine during the cell cycle and in reactivated nuclei

Polyamines are low molecular weight aliphatic polycations essential for cell proliferation and differentiation. By immunocytochemistry, as well as by two independent fluorescence cytochemical methods, we show that polyamines are associated with highly condensed chromatin in nucleated erythrocytes and in metaphase and anaphase chromosomes. In other cells, polyamines mainly occur in cytoplasm. The association between polyamines and DNA in condensed chromatin is so close that DNase treatment is necessary for making polyamines available for reaction with antibodies. Studies of chick/HeLa cell heterokaryons reveal that polyamines disappear from the chick erythrocyte nuclei concomitantly with DNA decondensation and initiation of RNA synthesis. Our data strongly suggest that polyamines are important for chromatin condensation in vivo.     

DNase I sensitive domain of the gene coding for the glycolytic enzyme glyceraldehyde-3-phosphate dehydrogenase

We have cloned a 36-kilobase segment of chicken DNA containing the gene coding for glyceraldehyde-3-phosphate dehydrogenase [GAPDH (EC 1.2.1.12)], a glycolytic enzyme which is expressed constitutively in all cell types. Using defined segments of this cloned DNA as probes, we have determined the DNase I sensitive domain of the GAPDH natural gene in the hen oviduct. When nuclei isolated from hen oviduct were treated with DNase I under conditions known to preferentially degrade actively transcribed genes (i.e., 15-20% of the DNA rendered perchloric acid soluble), a region of approximately 12 kilobase(s) (kb) containing the GAPDH coding sequences and flanking DNA was found to be highly susceptible to digestion by DNase I. Approximately 4 kb downstream from the end of the coding sequences, there was an abrupt transition from the DNase I sensitive or "open" configuration to the resistant or "closed" configuration. The chromatin then remained in a closed conformation for at least 10 kb further downstream. On the 5' side of the gene, the transition from a sensitive to a resistant configuration was located about 4 kb upstream from the gene. In addition, we have localized two repeated sequences in the area of DNA that was cloned. One of these is of the CR1 family of middle repetitive elements. It is located about 18 kb 3' to the gene and as such lies well outside of the DNase I sensitive region which encompasses GAPDH. The other repetitive element is of an uncharacterized family. It is located upstream from the gene and appears to be within a region of transition from the DNase I sensitive to resistant states.