Isolation and characterization of cDNA clones encoding the Drosophila homolog of the HMG-box SSRP family that recognizes specific DNA structures

Ultrasensitive Change in Nucleosome Binding by Multiple Phosphorylations to the Intrinsically Disordered Region of the Histone Chaperone FACT

Facilitates chromatin transcription (FACT) is a histone chaperone that functions as a nucleosome remodeler and a chaperone. The two subunits of FACT, Spt16 and SSRP1, mediate multiple interactions between the subunits and components of the nucleosome. Among the interactions, the role of the DNA-binding domain in SSRP1 has not been characterized. We reported previously that the DNA-binding domain in Drosophila SSRP1 (dSSRP1) has multiple casein kinase II phosphorylation sites, and the DNA binding affinity of the domain changes sigmoidally in response to the degree of phosphorylation ("ultrasensitive response"). In this report, we explored the molecular mechanisms for the ultrasensitive response of the DNA-binding domain in dSSRP1 using the shortest fragment (AB-HMG, residues 434-624) responsible for nucleosome binding. AB-HMG contains two intrinsically disordered (ID) regions: the N-terminal part rich in acidic residues (AID) and the C-terminal part rich in basic residues (BID) followed by the HMG box. NMR and coarse-grained molecular dynamics simulations revealed a phosphorylation-dependent change in intramolecular contacts between the AID and BID-HMG, which is mediated by a hinge bending motion of AB-HMG to enable the ultrasensitive response. Ultrasensitivity generates two distinct forms of dSSRP1, which are high- and low-affinity nucleosome-binding forms. Drosophila FACT (dFACT) switches function according to the degree of phosphorylation of the AID in dSSRP1. We propose that dFACT in various phosphorylation states functions cooperatively to facilitate gene regulation in the context of the chromatin.

Repurposing quinacrine for treatment-refractory cancer

Quinacrine, also known as mepacrine, has originally been used as an antimalarial drug for close to a century, but was recently rediscovered as an anticancer agent. The mechanisms of anticancer effects of quinacrine are not well understood. The anticancer potential of quinacrine was discovered in a screen for small molecule activators of p53, and was specifically shown to inhibit NFκB suppression of p53. However, quinacrine can cause cell death in cells that lack p53 or have p53 mutations, which is a common occurrence in many malignant tumors including high grade serous ovarian cancer. Recent reports suggest quinacrine may inhibit cancer cell growth through multiple mechanisms including regulating autophagy, FACT (facilitates chromatin transcription) chromatin trapping, and the DNA repair process. Additional reports also suggest quinacrine is effective against chemoresistant gynecologic cancer. In this review, we discuss anticancer effects of quinacrine and potential mechanisms of action with a specific focus on gynecologic and breast cancer where treatment-refractory tumors are associated with increased mortality rates. Repurposing quinacrine as an anticancer agent appears to be a promising strategy based on its ability to target multiple pathways, its selectivity against cancer cells, and the synergistic cytotoxicity when combined with other anticancer agents with limited side effects and good tolerability profile.

Structure and function of the histone chaperone FACT - Resolving FACTual issues

FAcilitates Chromatin Transcription (FACT) has been considered essential for transcription through chromatin mostly based on cell-free experiments. However, FACT inactivation in cells does not cause a significant reduction in transcription. Moreover, not all mammalian cells require FACT for viability. Here we synthesize information from different organisms to reveal the core function(s) of FACT and propose a model that reconciles the cell-free and cell-based observations. We describe FACT structure and nucleosomal interactions, and their roles in FACT-dependent transcription, replication and repair. The variable requirements for FACT among different tumor and non-tumor cells suggest that various FACT-dependent processes have significantly different levels of relative importance in different eukaryotic cells. We propose that the stability of chromatin, which might vary among different cell types, dictates these diverse requirements for FACT to support cell viability. Since tumor cells are among the most sensitive to FACT inhibition, this vulnerability could be exploited for cancer treatment.

Role of Chromatin Damage and Chromatin Trapping of FACT in Mediating the Anticancer Cytotoxicity of DNA-Binding Small-Molecule Drugs

Precisely how DNA-targeting chemotherapeutic drugs trigger cancer cell death remains unclear, as it is difficult to separate direct DNA damage from other effects in cells. Recent work on curaxins, a class of small-molecule drugs with broad anticancer activity, shows that they interfere with histone-DNA interactions and destabilize nucleosomes without causing detectable DNA damage. Chromatin damage caused by curaxins is sensed by the histone chaperone FACT, which binds unfolded nucleosomes becoming trapped in chromatin. In this study, we investigated whether classical DNA-targeting chemotherapeutic drugs also similarly disturbed chromatin to cause chromatin trapping of FACT (c-trapping). Drugs that directly bound DNA induced both chromatin damage and c-trapping. However, chromatin damage occurred irrespective of direct DNA damage and was dependent on how a drug bound DNA, specifically, in the way it bound chromatinized DNA in cells. FACT was sensitive to a plethora of nucleosome perturbations induced by DNA-binding small molecules, including displacement of the linker histone, eviction of core histones, and accumulation of negative supercoiling. Strikingly, we found that the cytotoxicity of DNA-binding small molecules correlated with their ability to cause chromatin damage, not DNA damage. Our results suggest implications for the development of chromatin-damaging agents as selective anticancer drugs.Significance: These provocative results suggest that the anticancer efficacy of traditional DNA-targeting chemotherapeutic drugs may be based in large part on chromatin damage rather than direct DNA damage. Cancer Res; 78(6); 1431-43. ©2018 AACR.

FACT is a sensor of DNA torsional stress in eukaryotic cells

Transitions of B-DNA to alternative DNA structures (ADS) can be triggered by negative torsional strain, which occurs during replication and transcription, and may lead to genomic instability. However, how ADS are recognized in cells is unclear. We found that the binding of candidate anticancer drug, curaxin, to cellular DNA results in uncoiling of nucleosomal DNA, accumulation of negative supercoiling and conversion of multiple regions of genomic DNA into left-handed Z-form. Histone chaperone FACT binds rapidly to the same regions via the SSRP1 subunit in curaxin-treated cells. In vitro binding of purified SSRP1 or its isolated CID domain to a methylated DNA fragment containing alternating purine/pyrimidines, which is prone to Z-DNA transition, is much stronger than to other types of DNA. We propose that FACT can recognize and bind Z-DNA or DNA in transition from a B to Z form. Binding of FACT to these genomic regions triggers a p53 response. Furthermore, FACT has been shown to bind to other types of ADS through a different structural domain, which also leads to p53 activation. Thus, we propose that FACT acts as a sensor of ADS formation in cells. Recognition of ADS by FACT followed by a p53 response may explain the role of FACT in DNA damage prevention.

SSRP1 Cooperates with PARP and XRCC1 to Facilitate Single-Strand DNA Break Repair by Chromatin Priming

DNA single-strand breaks (SSB) are the most common form of DNA damage, requiring repair processes that to initiate must overcome chromatin barriers. The FACT complex comprised of the SSRP1 and SPT16 proteins is important for maintaining chromatin integrity, with SSRP1 acting as an histone H2A/H2B chaperone in chromatin disassembly during DNA transcription, replication, and repair. In this study, we show that SSRP1, but not SPT16, is critical for cell survival after ionizing radiation or methyl methanesulfonate-induced single-strand DNA damage. SSRP1 is recruited to SSB in a PARP-dependent manner and retained at DNA damage sites by N-terminal interactions with the DNA repair protein XRCC1. Mutational analyses showed how SSRP1 function is essential for chromatin decondensation and histone H2B exchange at sites of DNA strand breaks, which are both critical to prime chromatin for efficient SSB repair and cell survival. By establishing how SSRP1 facilitates SSB repair, our findings provide a mechanistic rationale to target SSRP1 as a general approach to selectively attack cancer cells. Cancer Res; 77(10); 2674-85. ©2017 AACR.

Crystal Structure of Human SSRP1 Middle Domain Reveals a Role in DNA Binding

SSRP1 is a subunit of the FACT complex, an important histone chaperone required for transcriptional regulation, DNA replication and damage repair. SSRP1 also plays important roles in transcriptional regulation independent of Spt16 and interacts with other proteins. Here, we report the crystal structure of the middle domain of SSRP1. It consists of tandem pleckstrin homology (PH) domains. These domains differ from the typical PH domain in that PH1 domain has an extra conserved βαβ topology. SSRP1 contains the well-characterized DNA-binding HMG-1 domain. Our studies revealed that SSRP1-M can also participate in DNA binding, and that this binding involves one positively charged patch on the surface of the structure. In addition, SSRP1-M did not bind to histones, which was assessed through pull-down assays. This aspect makes the protein different from other related proteins adopting the double PH domain structure. Our studies facilitate the understanding of SSRP1 and provide insights into the molecular mechanisms of interaction with DNA and histones of the FACT complex.

Incorporation of DUF/FACT into chromatin enhances the accessibility of nucleosomal DNA

DNA unwinding factor (DUF) was discovered as an essential DNA replication factor in Xenopus egg extracts. DUF consists of an HMG protein and a homolog of Cdc68p/Spt16p, and has the capability of unwinding dsDNA. Here we have examined the interaction of DUF with chromatin. DUF was incorporated into chromatin assembled from sperm heads and from plasmid DNA in egg extracts. It was revealed that the chromatin assembled in egg extracts immunodepleted of DUF is less sensitive to micrococcal nuclease (NNase) digestion than that assembled in control extracts, indicating that chromatin containing DUF has more decompact structure than that without DUF. Also we found that DUF has a high affinity for core histones in vitro. We suggest that the function of DUF may be to make the chromatin structure accessible to replication factors.

Cisplatin: from DNA damage to cancer chemotherapy

Cisplatin [cis-DDP, cis-diamminedichloroplatinum(II)] is a potent anticancer drug that has been used successfully to treat tumors of the head, neck, lungs, and genitourinary tract. The biological activity of cisplatin was discovered serendipitously more than 30 years ago, and since that time research efforts have focused on elucidating its mechanism of action. The present review provides a historical perspective of our attempts to understand this complex phenomenon and the results of recent work that guides our current activities in this field. Continued efforts to understand the mechanism of genotoxicity of cisplatin are expected to lead to the discovery of new drugs and combinations for the improvement of cancer chemotherapy.

Interaction of FACT, SSRP1, and the high mobility group (HMG) domain of SSRP1 with DNA damaged by the anticancer drug cisplatin

The structure-specific recognition protein SSRP1, initially isolated from expression screening of a human B-cell cDNA library for proteins that bind to cisplatin (cis-diamminedichloroplatinum(II))-modified DNA, contains a single DNA-binding high mobility group (HMG) domain. Human SSRP1 purifies as a heterodimer of SSRP1 and Spt16 (FACT) that alleviates the nucleosomal block to transcription elongation by RNAPII in vitro. The affinity and specificity of FACT, SSRP1, and the isolated HMG domain of SSRP1 for cisplatin-damaged DNA were investigated by gel mobility shift assays. FACT exhibits both affinity and specificity for DNA damaged globally with cisplatin compared with unmodified DNA or DNA damaged globally with the clinically ineffective trans-DDP isomer. FACT binds the major 1,2-d(GpG) intrastrand cisplatin adduct, but its isolated SSRP1 subunit fails to form discrete, high affinity complexes with cisplatin-modified DNA under similar conditions. These results suggest that Spt16 primes SSRP1 for cisplatin-damaged DNA recognition by unveiling its HMG domain. As expected, the isolated HMG domain of SSRP1 is sufficient for specific binding to cisplatin-damaged DNA and binds the major cisplatin 1,2-d(GpG) intrastrand cross-link. The affinity and specificity of FACT for cisplatin-modified DNA, as well as its importance for transcription of chromatin, suggests that the interaction of FACT and cisplatin-damaged DNA may be crucial to the anticancer mechanism of cisplatin.

Recognition of cisplatin adducts by cellular proteins

Cisplatin is a widely used chemotherapeutic agent. It reacts with nucleophilic bases in DNA and forms 1,2-d(ApG), 1,2-d(GpG) and 1,3-d(GpTpG) intrastrand crosslinks, interstrand crosslinks and monofunctional adducts. The presence of these adducts in DNA is through to be responsible for the therapeutic efficacy of cisplatin. The exact signal transduction pathway that leads to cell cycle arrest and cell death following treatment with the drug is not known but cell death is believed to be mediated by the recognition of the adducts by cellular proteins. Here we describe the structural information available for cisplatin and related platinum adducts, the interactions of the adducts with cellular proteins and the implications of these interactions for cell survival.

DNA-interactions and nuclear localisation of the chromosomal HMG domain protein SSRP1 from maize

The structure-specific recognition protein 1 (SSRP1) is a member of the protein family containing a high mobility group (HMG) domain DNA-binding motif. We have functionally characterised the 71.4 kDa Zm-SSRP1 protein from maize. The chromatin-associated Zm-SSRP1 is detected by immunoblot analysis in maize leaves, kernels and suspension culture cells, but not in roots. Mediated by its HMG domain, recombinant Zm-SSRP1 interacts structure-specifically with supercoiled DNA and DNA minicircles when compared with linear DNA. In linear duplex DNA, the protein does not recognise a specific sequence, but it binds preferentially to sequences containing the deformable dinucleotide TG, as demonstrated by a random oligonucleotide selection experiment. Zm-SSRP1 modulates DNA structure by bending the target sequence, since it promotes the circularisation of short DNA fragments in the presence of DNA ligase. Moreover, Zm-SSRP1 facilitates the formation of nucleoprotein structures, as measured using the bacterial site-specific beta-mediated recombination reaction. Analysis of the subcellular localisation of various SSRP1-GFP fusions revealed that, in contrast to HMG domain transcription factors, the nuclear localisation sequence of Zm-SSRP1 is situated within a 20-amino acid residue region adjacent to the HMG domain rather than within the DNA-binding domain. The results are discussed in the context of the likely function of SSRP1 proteins in transcription and replication.

DSP1 gene of Drosophila melanogaster encodes an HMG-domain protein that plays multiple roles in development

DSP1 is an HMG-box containing protein of Drosophila melanogaster which was first identified as a co-repressor of the Dorsal protein. Recently, the analysis of the structure of the gene has led us to propose that DSP1 is the Drosophila equivalent of the ubiquitous vertebrate HMG 1/2 proteins. In the present paper, the patterns of expression of DSP1 protein and RNA in adult flies and during development are reported. In the adults DSP1 protein is located in nurse cells of ovaries and in brain. During eggs development uniform expression of DSP1 protein persists until the end of germband retraction. At later stages, expression is restricted to the ventral nerve chord and brain. Using P-element mutagenesis, we have isolated a mutant deficient in DSP1 functions. Genetic studies of this mutant show that DSP1 protein is essential for the growth and the development of Drosophila. In addition to be a co-repressor of the transcriptional activator Dorsal our results provide compelling evidence that DSP1 is a regulator involved in several pathways necessary for the development of the fly.

A single d(GpG) cisplatin adduct on the estrogen response element decreases the binding of the estrogen receptor

Both cisplatin and the estrogen receptor (ER) are known to bend DNA. The influence of the bending of sequences by the d(GpG)cisPt adduct binding of ER to estrogen response element (ERE)-like sequences was examined. Three ERE-like oligonucleotides with different affinities for ER and which include a GG in the linker sequence were designed in order to form a single central d(GpG)cisPt adduct. Using electrophoretic mobility shift assay and Scatchard analysis, it was shown that the presence of a single d(GpG)cisPt adduct in the linker sequence decreases the ER affinity for DNA. These results do not support a critical role of a DNA bend in the initial recognition of ERE by ER. Then, the platination of DNA outside of the ERE half-sites decreases the interaction of ER with ERE.

The HMG protein T160 colocalizes with DNA replication foci and is down-regulated during cell differentiation

The high mobility group protein T160, the murine homolog of the human structure-specific recognition protein 1, was first supposed to be involved in the process of V-(D)-J recombination, since it could bind to recombination signal sequence probes. We have recently cloned T160 by using an unrelated DNA probe and shown that it binds to either cruciform or linear DNA with no sequence specificity. In this work, we performed a detailed analysis of T160 expression and immunolocalization. We show that T160 is a phosphoprotein broadly conserved from yeast to mammals, with a high level of expression in all the cell lines tested and in tissues containing a high degree of proliferating cells. Indirect immunofluorescence analysis by confocal laser microscopy revealed that T160 distribution in the cell nucleus is not uniform, and focus-like staining was observed. Cell cycle studies by BrdU incorporation suggest that the appearance of T160 nuclear foci is specific of mid to late S phase. Furthermore, while T160 expression does not change during the cell cycle, it is dramatically down-regulated when cells begin to differentiate, as highlighted in C2C12 myoblasts and myotubes. The disappearance of T160 nuclear staining in multinucleated myotubes is shown. Taken together, these data suggest that its function may be less specific than V-(D)-J recombination and more related to some cellular basic process, such as DNA replication or repair.

Proteins that specifically recognize cisplatin-damaged DNA: a clue to anticancer activity of cisplatin

Cisplatin, but not its trans geometric isomer, is a potent anticancer drug whose biological activity is a consequence of the formation of covalent adducts between the platinum compound and certain bases in DNA. Two classes of proteins have recently been identified that bind preferentially to damaged sites: proteins that specifically recognize those sites as a first step in their repair, and those that bind to such sites by virtue of structural similarity between the modified DNA and their own natural binding sites. Both classes of proteins may be involved, perhaps in opposing ways, in the cytotoxic effect of the drug.

The HMG domain protein SSRP1/PREIIBF is involved in activation of the human embryonic beta-like globin gene

The human embryonic beta-like globin (epsilon-globin) gene is expressed in primitive erythroid cells of the yolk sac during the first few weeks of development. We have previously shown that developmental stage-specific expression of the epsilon-globin gene is mediated by multiple positive and negative regulatory elements upstream of the start of transcription. Of particular interest is one positive regulatory element, PRE II, that works together with other elements (PRE I and PRE V) to confer developmental stage- and/or tissue-specific expression on a minimal promoter. An approximately 85- to 90-kDa PRE II binding factor (PREIIBF) was identified in the nuclei of erythroid cells and shown to bind specifically to a novel 19-bp region within PRE II; binding of this protein to PRE II resulted in bending of the target DNA and was required for promoter activation. In this report, we present the cDNA expression cloning of PREIIBF. The cDNA encodes a previously identified member of the HMG domain family of DNA binding proteins termed SSRP1. By a number of biochemical and immunological criteria, recombinant SSRP1 appears to be identical to the PREII binding factor from erythroid nuclei. A hallmark of HMG domain proteins is their ability to bend their target DNAs; therefore, as we speculated previously, DNA bending by SSRP1/PREIIBF may contribute to the mechanism by which PRE II synergizes with other regulatory elements located upstream and downstream. In contrast with reports from other investigators, we demonstrate that SSRP1 binds DNA with clear sequence specificity. Moreover, we show that SSRP1/PREIIBF lacks a classical activation domain but that binding by this protein to PRE II is required for activation of a minimal promoter in stable erythroid cell lines. These studies provide the first evidence that SSRP1 plays a role in transcriptional regulation. SSRP1/PREIIBF may serve an architectural function by helping to coordinate the assembly of a multiprotein complex required for stage-specific regulation of the human epsilon-globin gene.

Decreased expression of the high-mobility group protein T160 by antisense RNA impairs the growth of mouse fibroblasts

The T160 protein belongs to the HMG-1 box protein family and preferentially binds to non-B-DNA conformations with no sequence specificity. Its exact role has yet to be defined, though it seems to participate in processes involving DNA, such as replication, transcription and recombination. We have used an antisense RNA strategy to investigate its role in cell growth and proliferation. T160 expression is strongly suppressed by stable introduction of an antisense construct into NIH3T3 cells, and this decrease is accompanied by substantial changes in the growth properties of the stable transfectants. Impaired growth of T160- cells was mainly related to two mechanisms: i) decreased rates of cell proliferation at normal serum concentration; and ii) occurrence of cell death by apoptosis at low serum concentration, as demonstrated by both flow cytometry and microscopy. The finding that decreased T160 availability affects cell proliferation, provides further evidence of its involvement in a basic cell function, such as DNA replication.

The high-mobility group protein T160 binds to both linear and cruciform DNA and mediates DNA bending as determined by ring closure

The high-mobility group protein T160 was isolated by screening a phage library from a murine pre-B-cell line L1210. South-Western experiments have previously shown that this protein binds to V-(D)-J recombination signal sequences, suggesting that it may be a sequence-specific DNA-binding protein. However, neither gel-shift nor footprinting analyses have been successfully employed with the T160 protein, despite an extensive effort. In this study, the T160 protein or truncated forms made soluble through denaturing and renaturing cycles in urea were successfully used in gel-shift experiments showing that T160 binds to cruci-form or linear duplex DNA with no apparent sequence specificity. Furthermore, fragments longer than 100 bp efficiently formed covalently closed circular monomers in the presence of T160 and T4 DNA ligase, indicating that the protein is capable of introducing bends into the duplex. Last, tissue distribution by Western blotting analysis showed that the T160 protein is expressed in various murine tissues in addition to those of lymphoid origin. Considering its broad evolutionary conservation (from plants to mammals) also, these results suggest that the functional role of the T160 protein is not limited to V-(D)-J recombination, but might be involved in basic processes such as DNA replication and repairing, where irregular DNA structures are generated and very likely recognized by HMG domain proteins.

The Saccharomyces cerevisiae DNA polymerase alpha catalytic subunit interacts with Cdc68/Spt16 and with Pob3, a protein similar to an HMG1-like protein

We have used DNA polymerase alpha affinity chromatography to identify factors involved in eukaryotic DNA replication in the yeast Saccharomyces cerevisiae. Two proteins that bound to the catalytic subunit of DNA polymerase alpha (Pol1 protein) are encoded by the essential genes CDC68/SPT16 and POB3. The binding of both proteins was enhanced when extracts lacking a previously characterized polymerase binding protein, Ctf4, were used. This finding suggests that Cdc68 and Pob3 may compete with Ctf4 for binding to Pol1. Pol1 and Pob3 were coimmunoprecipitated from whole-cell extracts with antiserum directed against Cdc68, and Pol1 was immunoprecipitated from whole-cell extracts with antiserum directed against the amino terminus of Pob3, suggesting that these proteins may form a complex in vivo. CDC68 also interacted genetically with POL1 and CTF4 mutations; the maximum permissive temperature of double mutants was lower than for any single mutant. Overexpression of Cdc68 in a pol1 mutant strain dramatically decreased cell viability, consistent with the formation or modulation of an essential complex by these proteins in vivo. A mutation in CDC68/SPT16 had previously been shown to cause pleiotropic effects on the regulation of transcription (J. A. Prendergrast et al., Genetics 124:81-90, 1990; E. A. Malone et al., Mol. Cell. Biol. 11:5710-5717, 1991; A. Rowley et al., Mol. Cell. Biol. 11:5718-5726, 1991), with a spectrum of phenotypes similar to those caused by mutations in the genes encoding histone proteins H2A and H2B (Malone et al., Mol. Cell. Biol. 11:5710-5717, 1991). We show that at the nonpermissive temperature, cdc68-1 mutants arrest as unbudded cells with a 1C DNA content, consistent with a possible role for Cdc68 in the prereplicative stage of the cell cycle. The cdc68-1 mutation caused elevated rates of chromosome fragment loss, a phenotype characteristic of genes whose native products are required for normal DNA metabolism. However, this mutation did not affect the rate of loss or recombination for two intact chromosomes, nor did it affect the retention of a low-copy-number plasmid. The previously uncharacterized Pob3 sequence has significant amino acid sequence similarity with an HMG1-like protein from vertebrates. Based on these results and because Cdc68 has been implicated as a regulator of chromatin structure, we postulate that polymerase alpha may interact with these proteins to gain access to its template or to origins of replication in vivo.

The Drosophila DSP1 gene encoding an HMG 1-like protein: genomic organization, evolutionary conservation and expression

The gene that encodes the dorsal switch protein (DSP1) has been isolated from a Drosophila melanogaster cosmid library. It is organized into seven exons and six introns. The relative position of the introns within the region coding for the high mobility group (HMG) domains are identical to those of vertebrate HMG 1/2 genes. The close similarity between DSP1 and HMG 1/2 genes strongly suggests that these genes derived from a common ancestral gene. DSP1 encodes, at least, two distinct mRNAs that differ in the length of their 5'-untranslated region and coding sequence. Detailed sequence analysis shows that alternative splicing of precursor mRNA gives rise to the two isoform mRNAs found in Drosophila cells.

The unusual structures of the hot-regions flanking large-scale deletions in human mitochondrial DNA

Large-scale deletions of mitochondrial DNA (mtDNA) are common events that have been found to occur in human ageing and in patients with mitochondrial myopathies. The mechanisms by which these deletions occur remain unclear, but several mechanisms have been proposed, such as slipped-mispairing, illegitimate recombination, and oxidative reactions elicited by free radicals. In addition, the DNA topological stress and local DNA structures have been suggested as the important factors in eliciting the recombinational events. Upon examination of 128 breakpoints of human mtDNA deletions that have been published in the past 8 years, we found that these large-scale deletions often occur at some 'hot-regions'. We thus hypothesized that there exist unusual structures in these regions of human mtDNA that are important for eliciting the deletions. To test this hypothesis, we used PCR techniques to amplify the sequences of the so-called hot-regions and analysed the PCR products by two-dimensional gel electrophoresis. We found that the sequences of nucleotide position (np) 5221-5988, np 6928-7493, np 7901-8732 and np 15327-16228 exhibited retarded mobilities like bent DNA structures; np 5989-6750, np 13282-13653 and np 13282-14850 showed increased mobilities like anti-bent DNA structures. Moreover, except for the sequences of np 1175-1766 found in 12 S and 16 S rRNA genes exhibiting abnormal mobility like bent DNA structures, we did not observe significant mobility abnormalities in the np 499-5545 region where deletions rarely occurred. We thus conclude that these hot-regions assume some kinds of unusual DNA structures, which may render these regions more sensitive to the attack of free radicals or serve as recognition motifs for certain recombination machinery that is involved in the large-scale deletions of human mtDNA.

Expression of structure-specific recognition protein mRNA in fetal kidney and Fe-nitrilotriacetate-induced renal carcinoma in the rat

Specific expression of the structure-specific recognition protein (SSRP) gene was investigated in rat fetal, adult, and tumor tissues using a 2.0-kb partial sequence of rat SSRP cDNA isolated from a cDNA library of rat renal cell carcinoma. The results revealed that it was rather specifically expressed in rat fetal kidney and renal cell carcinoma induced by Fenitrilotriacetate, but not in adult kidney, when various organs were tested by Northern blot analysis. In situ hybridization further demonstrated that it was located in the neoplastic cells of renal cell carcinoma and in the epithelial cells of fetal kidney but undetectable in any cells of normal adult kidney. These observations seem to imply the involvement of SSRP gene, which is believed to recognize structural alterations of DNA, in kidney development and carcinogenesis of certain types of kidney cancer.

A cDNA encoding a plant homologue to animal HMG box proteins involved in structure-specific recognition of DNA (SSRP family)

We report a cDNA encoding a 71-kDa protein with a single high-mobility group (HMG) box and two nuclear localization signals from the higher plant Catharanthus roseus (Madagascar periwinkle). The protein had 40% amino acid identity with animal DNA-binding proteins of the SSRP (structure-specific recognition protein) family that recognize bent, unwound DNA structures. Genomic Southern analysis suggested the presence of two genes.

HMG domain proteins induce sharp bends in cisplatin-modified DNA

Circularly permuted linear DNAs of approximately 100 bp were constructed containing the major adduct of the anticancer drug cisplatin, a cis-[Pt(NH3)2[d(GpG)-N7(1),-N7(2)]] intrastrand cross-link, at a specific site. Gel electrophoresis mobility shift assays with these probes were used to investigate the effects of binding of HMG domain proteins to the platinated DNAs. The site-specifically platinated duplexes were recognized by six different HMG domain proteins--HMG1, mtTFA, Ixr1, and HMG domains from HMG1 (domain B), mSRY, and LEF-1--with comparable binding affinities (Kd approximately 10(-6) to 10(-7) M). In the presence of the HMG domain proteins, the platinated DNAs were bent significantly more than in their absence, the values being 86 +/- 2 degrees, 87-90 +/- 5 degrees, and 68 +/- 6 degrees, respectively, for the proteins and 65-74 +/- 4 degrees, approximately 50 degrees, and 72 +/- 6 degrees, respectively, for the domains. The variability in bend angles suggests that, although the HMG domain proteins share a common ability to bend platinated DNA, specific contacts between the proteins and the platinated duplex are different. The assay further revealed the bend loci to be centered quite near the platinum adduct. The methodology employed in the present study should be generally applicable for synthesizing other small, circularly permuted, covalently modified DNAs which cannot otherwise be readily obtained.

A 21.7 kb DNA segment on the left arm of yeast chromosome XIV carries WHI3, GCR2, SPX18, SPX19, an homologue to the heat shock gene SSB1 and 8 new open reading frames of unknown function

We report the amino acid sequence of 13 open reading frames (ORF > 299 bp) located on a 21.7 kb DNA segment from the left arm of chromosome XIV of Saccharomyces cerevisiae. Five open reading frames had been entirely or partially sequenced previously: WHI3, GCR2, SPX19, SPX18 and a heat shock gene similar to SSB1. The products of 8 other ORFs are new putative proteins among which N1394 is probably a membrane protein. N1346 contains a leucine zipper pattern and the corresponding ORF presents an HAP (global regulator of respiratory genes) upstream activating sequence in the promoting region. N1386 shares homologies with the DNA structure-specific recognition protein family SSRPs and the corresponding ORF is preceded by an MCB (MluI cell cycle box) upstream activating factor.

Four distinct and unusual linker proteins in a mitotically dividing nucleus are derived from a 71-kilodalton polyprotein, lack p34cdc2 sites, and contain protein kinase A sites

Tetrahymena thermophila micronuclei contain four linker-associated proteins, alpha, beta, gamma, and delta. Synthetic oligonucleotides based on N-terminal protein sequences of beta and gamma were used to clone the micronuclear linker histone (MLH) gene. The MLH gene is single copy and is transcribed into a 2.4-kb message encoding all four linker-associated proteins. The message is translated into a polypeptide (Mic LH) that is processed at the sequence decreases RTK to give proteins whose amino acid sequences differ markedly from each other, from the sequence of macronuclear H1, and from sequences of typical H1s of other organisms. This represents the first example of multiple chromatin proteins derived from a single polyprotein. The delta protein consists largely of two high-mobility-group (HMG) boxes. An evolutionary analysis of HMG boxes indicates that the delta HMG boxes are similar to the HMG boxes of tsHMG, a protein that appears in elongating mouse spermatids when they condense and cease transcription, suggesting that delta could play a similar role in the micronucleus. The micronucleus divides mitotically, while the macronucleus divides amitotically. Surprisingly, macronuclear H1 but not Mic LH contains sequences resembling p34cdc2 kinase phosphorylation sites, while each of the Mic LH-derived proteins contains a typical protein kinase A phosphorylation site in its carboxy terminus.

Four distinct and unusual linker proteins in a mitotically dividing nucleus are derived from a 71-kilodalton polyprotein, lack p34cdc2 sites, and contain protein kinase A sites

Tetrahymena thermophila micronuclei contain four linker-associated proteins, alpha, beta, gamma, and delta. Synthetic oligonucleotides based on N-terminal protein sequences of beta and gamma were used to clone the micronuclear linker histone (MLH) gene. The MLH gene is single copy and is transcribed into a 2.4-kb message encoding all four linker-associated proteins. The message is translated into a polypeptide (Mic LH) that is processed at the sequence decreases RTK to give proteins whose amino acid sequences differ markedly from each other, from the sequence of macronuclear H1, and from sequences of typical H1s of other organisms. This represents the first example of multiple chromatin proteins derived from a single polyprotein. The delta protein consists largely of two high-mobility-group (HMG) boxes. An evolutionary analysis of HMG boxes indicates that the delta HMG boxes are similar to the HMG boxes of tsHMG, a protein that appears in elongating mouse spermatids when they condense and cease transcription, suggesting that delta could play a similar role in the micronucleus. The micronucleus divides mitotically, while the macronucleus divides amitotically. Surprisingly, macronuclear H1 but not Mic LH contains sequences resembling p34cdc2 kinase phosphorylation sites, while each of the Mic LH-derived proteins contains a typical protein kinase A phosphorylation site in its carboxy terminus.