Reverse in Situ Hybridization of DNA Probes of Abnormal Chromosomes in Diagnostics of Chromosomal Pathologies

The results of analysis of congenital chromosomal pathologies and chromosomal rearrangements upon the occurrence of haematological diseases, which was involved constructing DNA libraries of abnormal chromosomes and subsequent reverse CISS hybridization have been considered. High effectiveness of this approach for analysis of chromosomal translocations, deletions of chromosomal regions, minor additional chromosomes, and large marker chromosomes with complex organization was shown. The possibility of implementation of this approach and its large-scale application in medical and genetic studies of congenital developmental pathologies and chromosomal diagnostics of haematological diseases has been discussed.     

Applications of nanoparticles in biology and medicine

Nanomaterials are at the leading edge of the rapidly developing field of nanotechnology. Their unique size-dependent properties make these materials superior and indispensable in many areas of human activity. This brief review tries to summarise the most recent developments in the field of applied nanomaterials, in particular their application in biology and medicine, and discusses their commercialisation prospects.     

Roles of adeno-associated virus Rep protein and human chromosome 19 in site-specific recombination

Adeno-associated virus type 2 (AAV) is the only known eucaryotic virus capable of targeted integration in human cells. AAV integrates preferentially into human chromosome (ch) 19q13.3qter. The nonstructural proteins of AAV-2, Rep78 and Rep68, are essential for targeted integration. Rep78 and Rep68 are multifunctional proteins with diverse biochemical activities, including site-specific binding to AAV and ch-19 target sequences, helicase activity, and strand-specific, site-specific endonuclease activities. Both a Rep DNA binding element (RBE) and a nicking site essential for AAV replication present within the viral terminal repeats are also located on ch-19. Recently, identical RBE sequences have been identified at other locations in the human genome. This fact raises numerous questions concerning AAV targeted integration; specifically, how many RBE sequences are in the human genome? How does Rep discriminate between these and the ch-19 RBE sequence? Does Rep interact with all sites and, if so, how is targeted integration within a fixed time frame facilitated? To better characterize the role of Rep in targeted integration, we established a Rep-dependent filter DNA binding assay using a highly purified Rep-68 fusion protein. Electron microscopy (EM) analysis was also performed to determine the characteristics of the Rep-RBE interaction. Our results determined that the Rep affinity for ch-19 is not distinct compared to other RBEs in the human genome when utilizing naked DNA. In fact, a minimum-binding site (GAGYGAGC) efficiently associated with Rep, suggesting that as many as 2 × 10⁵ sites may exist. In addition, such sites also exist frequently in nonprimate mammalian genomes, although AAV integrates site specifically into primate genomes. EM analysis demonstrated that only one Rep-DNA complex was formed on ch-19 target DNA. Surprisingly, identically sized complexes were observed on all substrates containing a RBE sequence, but never on DNA lacking an RBE. Rep-DNA complexes involved a multimeric protein structure that spanned ca. 60 bp. Immunoprecipitation of AAV latently infected cells determined that 1,000 to 4,000 copies of Rep78 and Rep68 protein are expressed per cell. Comparison of the Rep association constant with those of established DNA binding proteins indicates that sufficient molecules of Rep are present to interact with all potential RBE sites. Moreover, Rep expression in the absence of AAV cis-acting substrate resulted in Rep-dependent amplification and rearrangement of the target sequence in ch-19. This result suggests that this locus is a hot spot for Rep-dependent recombination. Finally, we engineered mice to carry a single 2.7-kb human ch-19 insertion containing the AAV ch-19 target locus. Using cells derived from these mice, we demonstrated that this sequence was sufficient for site-specific recombination after infection with transducing vectors expressing Rep. This result indicates that any host factors required for targeting are conserved between human and mouse. Furthermore, the human ch-19 cis sequences and chromatin structure required for site-specific recombination are contained within this fragment. Overall, these results indicate that the specificity of targeted recombination to human ch-19 is not dictated by differential Rep affinities for RBE sites. Instead, specificity is likely dictated by human ch-19 sequences that serve as a Rep protein-mediated origin of replication, thus facilitating viral targeting through Rep-Rep interactions and host enzymes, resulting in site-specific recombination. Control of specificity is clearly dictated by the ch-19 sequences, since transfer of these sequences into the mouse genome are sufficient to achieve Rep-dependent site-specific integration.Adeno-associated virus type 2 (AAV) contains a single-stranded DNA genome of approximately 4.7 kb (50) and is a member of the Parvoviridae family (3). AAV is unique among other eucaryotic DNA viruses in that it utilizes a biphasic lifecycle to persist in nature. In the presence of a helper virus, adenovirus (Ad) or herpesvirus, AAV will undergo a productive infection. In the absence of a helper virus, AAV will integrate preferentially (>70%) into chromosome (ch) 19q13.3qter (3, 35). The ability of this nonpathogenic DNA virus, or virus-derived vector systems, to integrate site specifically have made it an attractive candidate vector for human gene therapy (45).The AAV genome consists of two open reading frames (ORFs), which comprise the rep and cap genes, and 145-bp inverted terminal repeats (ITRs), which serve as the origins of replication (3, 35). The left ORF of AAV encodes four nonstructural proteins, Rep78, Rep68, Rep52, and Rep40. Extensive characterization of Rep78 and Rep68 in vitro has identified the following biochemical activities, DNA binding (18, 19), site-specific and strand-specific endonuclease activities (17, 19), and DNA-RNA and DNA-DNA helicase activities (17, 19, 59), all of which appear to be necessary for viral replication (15, 53). More importantly, Rep78 and Rep68 are required for mediating targeted integration (2, 43, 47, 51, 60).Though site-specific integration is dependent upon either of the two large Rep proteins, the AAV ITRs are the only cis elements required for integration (34, 44, 61). In the absence of Rep proteins, the virus will still integrate through the ITR sequence but randomly into the host genome (21, 56, 61). Although integration in the absence of the Rep proteins is random, virus-cell junctions are nearly identical to junctions formed during targeted integration (DNA microhomology at junctions, specific deletions of the ITR sequences, rearrangement of the chromosome locus, and head-to-tail virus concatemers) (41, 62). In fact, in vitro integration products generated using cellular extracts produced identical type junctions, demonstrating the essential role the ITRs play in viral integration (62). From this analysis, Yang et al. (62) concluded that both random and targeted integration are dependent upon a cellular recombination pathway, with the role of Rep facilitating integration at ch-19. To help account for AAV targeting, a nearly identical Rep binding element (RBE) and a nicking site (trs) to that present on the AAV ITR was identified on the ch19.13.3qter AAV integration sequence (23–25, 43, 46, 54, 57). It was also demonstrated that Rep68 could mediate complex formation between the AAV ITR and the ch-19 integration site in vitro (57). This led to a hypothesis that AAV may target integration by Rep-mediated complex formation between the AAV ITR and the ch19 integration site. However, since this observation subsequent data has demonstrated that Rep can bind to degenerate RBE sequences, (5, 32). In fact, computer analysis identified at least 15 genomic genes which contained RBE sites that bound to AAV Rep protein in vitro, all more efficient than the ch-19 sequence (58). These data raise the question as to how Rep can target ch-19 among other RBE sequences. Using an Epstein-Barr virus (EBV)-based shuttle vector system carrying sequences from ch-19, Linden et al. demonstrated that the trs site was also critical for AAV site-specific integration (29, 30). When the trs site was not present, targeting was lost, even though the RBE was present. The present study suggested that both sequences were essential for site-specific integration (the RBE and the trs sequences). The probability of identifying a RBE with the correct proximity of a trs site would suggest a frequency of <6 × 10⁻¹¹/genome, thereby defining a unique sequence in the human genome (54). While these studies identify ch-19 cis elements required for AAV targeted integration and suggest why this reaction is specific, how Rep carries out this reaction remains unclear.Critical to any model of AAV Rep-mediated targeted integration is the ability to recognize the ch-19 target sequence among other potential RBE sequences. Though Rep can bind many degenerate sequences, the actual definition of what constitutes an RBE is somewhat unclear. Random oligonucleotide selection demonstrated that the RBE could be defined as an 8-bp sequence: 5′-GAGYGAGC-3′ (5). However, it was shown by methylation interference assays that the RBE was an 18-bp core sequence and that any mutation within this sequence would significantly affect Rep binding (42). Also, the report by Wonderling and Owens (58) demonstrated that the RBE oligonucleotides derived from the BLAST search contained mutations in this 18-bp core sequence but still bound better to the MBP-Rep68 than to the ch-19 RBE. Depending on the definition of an AAV RBE, the copy number present in the human genome (GAGYGAGC = 200,000 copies/genome, whereas 18-bp core = 1 copy/genome) could significantly impact the ability of Rep to identify its target locus.Based on the above information, the number of RBE sequences in the human genome, how Rep discriminates between these and the ch-19 target locus RBE sequence, and how Rep interacts with all sites and still facilitates targeted integration within a fixed time frame become of significant importance. In this study, we evaluated the role of alternative RBEs in the human genome and how these sequences might impact the ability of Rep to target the locus on ch-19. Using a filter-binding assay and a highly purified source of Rep68 protein, we established that genomic DNA will compete efficiently against a ch-19 target sequences. In this assay, a minimum Rep binding site of 8-bp in the context of large DNA fragments demonstrated competition, suggesting that as many as 200,000 potential binding sites may exist in the human genome. Filter-binding analysis of genomic DNA successfully retained ch-19 target sequences, as well as a cellular RBE identified by BLAST analysis, corroborating the competition results. Electron microscopy (EM) analysis was utilized to distinguish possible differences between Rep protein DNA interaction with ch-19 RBE compared to a minimum 8-bp RBE sequence. Identical multimeric Rep protein DNA complexes, which spanned about 60 bp, assembled on ch-19 target DNA, as well as a minimum RBE site, but never on heterologous DNA lacking these sequences. At a high Rep concentration, protein DNA looping structures were detected, but no evidence for paranemic structures were observed. In vivo analysis of Rep protein levels in a latent infection demonstrated approximately 1 to 4,000 copies/cell. Analysis of Rep expression in non-virus-infected cells demonstrated DNA rearrangement of the ch-19 target sequence, suggesting that this locus is a hot spot for Rep-induced DNA amplification and rearrangement that most likely influences AAV targeted integration. Finally, generation of an animal model carrying the human ch-19 sequence at the mouse hypoxanthine phosphoribosyltransferase (HPRT) locus facilitated AAV Rep-mediated targeted integration and corroborates the importance of the ch-19 RBE-trs sequence.     

Hydration changes accompanying the binding of minor groove ligands with DNA

4',6-diamidino-2-phenylindole (DAPI), netropsin, and pentamidine are minor groove binders that have terminal -C(NH2)2+ groups. The hydration changes that accompany their binding to the minor groove of the (AATT)2 sequence have been studied using the osmotic stress technique with fluorescence spectroscopy. The affinity of DAPI for the binding site decreases with the increasing osmolality of the solution, resulting in acquisition of 35+/-1 waters upon binding. A competition fluorescence assay was utilized to measure the binding constants and hydration changes of the other two ligands, using the DNA-DAPI complex as the fluorescence reporter. Upon their association to the (AATT)2 binding site, netropsin and pentamidine acquire 26+/-3 and 34+/-2 additional waters of hydration, respectively. The hydration changes are discussed in the context of the terminal functional groups of the ligands and conformational changes in the DNA.     

Adipokinetic hormone counteracts oxidative stress elicited in insects by hydrogen peroxide: in vivo and in vitro study

The role of adipokinetic hormone (AKH) in counteracting oxidative stress elicited in the insect body is studied in response to exogenously applied hydrogen peroxide, an important metabolite of oxidative processes. In vivo experiments reveal that the injection of hydrogen peroxide (8 µmol) into the haemocoel of the firebug, Pyrrhocoris apterus L. (Heteroptera: Pyrrhocoridae) increases the level of AKH by 2.8‐fold in the central nervous system (CNS) and by 3.8‐fold in the haemolymph. The injection of hydrogen peroxide also increases the mortality of experimental insects, whereas co‐injection of hydrogen peroxide with Pyrap‐AKH (40 pmol) reduces mortality to almost control levels. Importantly, an increase in haemolymph protein carbonyl levels (i.e. an oxidative stress biomarker) elicited by hydrogen peroxide is decreased by 3.6‐fold to control levels when hydrogen peroxide is co‐injected with Pyrap‐AKH. Similar results are obtained using in vitro experiments. Oxidative stress biomarkers such as malondialdehyde and protein carbonyls are significantly enhanced upon exposure of the isolated CNS to hydrogen peroxide in vitro, whereas co‐treatment of the CNS with hydrogen peroxide and Pyrap‐AKH reduces levels significantly. Moreover, a marked decrease in catalase activity compared with controls is recorded when the CNS is incubated with hydrogen peroxide. Incubation of the CNS with hydrogen peroxide and Pyrap‐AKH together curbs the negative effect on catalase activity. Taken together, the results of the present study provide strong support for the recently published data on the feedback regulation between oxidative stressors and AKH action, and implicate AKH in counteracting oxidative stress. The in vitro experiments should facilitate research on the mode of action of AKH in relation to oxidative stress, and could help clarify the key pathways involved in this process.     

Sequence length dictates repeated CAG folding in three-way junctions

The etiology of a large class of inherited neurological diseases is founded on hairpin structures adopted by repeated DNA sequences, and this folding is determined by base sequence and DNA context. Using single substitutions of adenine with 2-aminopurine, we show that intrastrand folding in repeated CAG trinucleotides is also determined by the number of repeats. This isomeric analogue has a fluorescence quantum yield that varies strongly with solvent exposure, thereby distinguishing particular DNA motifs. Prior studies demonstrated that (CAG)(8) alone favors a stem-loop hairpin, yet the same sequence adopts an open loop conformation in a three-way junction. This comparison suggests that repeat folding is disrupted by base pairing in the duplex arms and by purine-purine mismatches in the repeat stem. However, these perturbations are overcome in longer CAG repeats, as demonstrated by studies of isolated and integrated forms of (CAG)(15). The oligonucleotide alone forms a symmetrically folded hairpin with looplike properties exhibited by the relatively high emission intensities from a modification in the central eighth repeat and with stemlike properties evident from the relatively low emission intensities from peripheral modifications. Significantly, these hairpin properties are retained when (CAG)(15) is integrated into a duplex. Intrastrand folding by (CAG)(15) in the three-way junction contrasts with the open loop adopted by (CAG)(8) in the analogous context. This distinction suggests that cooperative interactions in longer repeat tracts overwhelm perturbations to reassert the natural folding propensity. Given that anomalously long repeats are the genetic basis of a large class of inherited neurological diseases, studies with (CAG)-based three-way junctions suggest that their secondary structure is a key factor in the length-dependent manifestation and progression of such diseases.     

Saccharomyces cerevisiae Apn1 mutation affecting stable protein expression mimics catalytic activity impairment: Implications for assessing DNA repair capacity in humans

Apurinic/apyrimidinic (AP) endonucleases play a major role in the repair of AP sites, oxidative damage and alkylation damage in DNA. We employed Saccharomyces cerevisiae in an unbiased forward genetic screen to identify amino acid substitutions in the major yeast AP endonuclease, Apn1, that impair cellular DNA repair capacity by conferring sensitivity to the DNA alkylating agent methyl methanesulfonate. We report here the identification and characterization of the Apn1 V156E amino acid substitution mutant through biochemical and functional analysis. We found that steady state levels of Apn1 V156E were substantially decreased compared to wild type protein, and that this decrease was due to more rapid degradation of mutant protein compared to wild type. Based on homology to E. coli endonuclease IV and computational modeling, we predicted that V156E impairs catalytic ability. However, overexpression of mutant protein restored DNA repair activity in vitro and in vivo. Thus, the V156E substitution decreases DNA repair capacity by an unanticipated mechanism via increased degradation of mutant protein, leading to substantially reduced cellular levels. Our study provides evidence that the V156 residue plays a critical role in Apn1 structural integrity, but is not involved in catalytic activity. These results have important implications for elucidating structure-function relationships for the endonuclease IV family of proteins, and for employing simple eukaryotic model systems to understand how structural defects in the major human AP endonuclease APE1 may contribute to disease etiology.     

Reduced levels of DNA polymerase delta induce chromosome fragile site instability in yeast

Specific regions of genomes (fragile sites) are hot spots for the chromosome rearrangements that are associated with many types of cancer cells. Understanding the molecular mechanisms regulating the stability of chromosome fragile sites, therefore, has important implications in cancer biology. We previously identified two chromosome fragile sites in Saccharomyces cerevisiae that were induced in response to the reduced expression of Pol1p, the catalytic subunit of DNA polymerase α. In the study presented here, we show that reduced levels of Pol3p, the catalytic subunit of DNA polymerase δ, induce instability at these same sites and lead to the generation of a variety of chromosomal aberrations. These findings demonstrate that a change in the stoichiometry of replicative DNA polymerases results in recombinogenic DNA lesions, presumably double-strand DNA breaks.     

Antimicrobial peptides containing arginine

Tetradecapeptides (RLARLAR)₂, D-(RLARLAR)₂, (RLARLAA)₂, and (RLGRLGR)₂ were synthesized by a solid phase method using Fmoc-amino acids. The antibacterial activity of the synthesized peptides was studied against Escherichia coli cells. The minimum inhibitory concentration (MIC) was, correspondingly, 3, 1, 3, and 12 M, which is comparable with MIC of such natural antimicrobial peptides as temporin, magainin, and dermaseptin. It was found that all of the synthesized peptides have no effect on human erythrocytes and rat thymocytes. The peptides form -helices in 30% trifluoroethanol and in 2.5 mM SDS, which have amphipathic structure.     

Organization of fusicoccin receptor in higher plant plasma membrane: relationship between affinity and molecular mass

Higher plant plasma membranes carry receptors of different affinity for the phytotoxin fusicoccin. Reception of fusicoccin involves proteins belonging to the highly conserved 14-3-3 family, but the complete structure of the fusicoccin receptor (FCR) is unknown. Using radiation inactivation analysis, we estimated the molecular masses of low-affinity and high-affinity FCR at 63 +/- 7 and 130 +/- 15 kD, respectively. The dose dependences of receptor inactivation indicate that microsomal specimens contain "silent" FCRs of 420 +/- 90 kD in amounts commensurate with that of the active FCRs. Both low- and high-affinity FCRs are inactivated by hydrolytic enzymes from the outer surface of the plasma membrane, and impairment of protoplast integrity causes an irreversible transition of the low-affinity binding site into the high-affinity one. A scheme is proposed for the organization of different types of FCR in the plasma membrane, implying that the membrane affinity for fusicoccin reflects the interaction between proteins in the FCR complex.