The role of confinement and corona crystallinity on the bending modulus of copolymer micelles measured directly by AFM flexural tests.

We present an approach which makes it possible to directly determine the bending modulus of single elongated block copolymer micelles. This is done by forming arrays of suspended micelles onto microfabricated substrates and by performing three-point bending flexural tests, using an atomic force microscope, on their suspended portions. By coupling the direct atomic force microscopy measurements with differential scanning calorimetry data, we show that the presence of a crystalline corona strongly increases the modulus of the copolymer elongated micelles. This large increase suggests that crystallites in the corona are larger and more uniformly oriented due to confinement effects. Our findings together with this hypothesis open new interesting avenues for the preparation of core-templated polymer fibres with enhanced mechanical properties.

Affordable techniques for fabricating large array of functional nanowires: From DNA to micellar systems.

Large arrays of aligned DNA and polymeric nanowires ranging from 20 to 100 nm in diameter are fabricated by de-wetting of patterned surfaces. Compared to other nanofabrication techniques, our approach is robust, fast and low cost. In addition, arrays of functionalized nanowires for bio/chemical applications can be simply produced at large scale.

Systemic delivery of triplex-forming PNA and donor DNA by nanoparticles mediates site-specific genome editing of human hematopoietic cells in vivo.

In vivo delivery is a major barrier to the use of molecular tools for gene modification. Here we demonstrate site-specific gene editing of human cells in vivo in hematopoietic stem cell-engrafted NOD.Cg-Prkdc(scid)IL2rγ(tm1Wjl) (abbreviated NOD-scid IL2rγ(null)) mice, using biodegradable nanoparticles loaded with triplex-forming peptide nucleic acids (PNAs) and single-stranded donor DNA molecules. In vitro screening showed greater efficacy of nanoparticles containing PNAs/DNAs together over PNA-alone or DNA-alone. Intravenous injection of particles containing PNAs/DNAs produced modification of the human CCR5 gene in hematolymphoid cells in the mice, with modification confirmed at the genomic DNA, mRNA and functional levels. Deep sequencing revealed in vivo modification of the CCR5 gene at frequencies of 0.43% in hematopoietic cells in the spleen and 0.05% in the bone marrow: off-target modification in the partially homologous CCR2 gene was two orders of magnitude lower. We also induced specific modification in the ß-globin gene using nanoparticles carrying ß-globin-targeted PNAs/DNAs, demonstrating this method's versatility. In vivo testing in an enhanced green fluorescent protein-ß-globin reporter mouse showed greater activity of nanoparticles containing PNAs/DNAs together over DNA only. Direct in vivo gene modification, such as we demonstrate here, would allow for gene therapy in systemic diseases or in cells that cannot be manipulated ex vivo.

Repression of RAD51 gene expression by E2F4/p130 complexes in hypoxia.

We and others have shown that the dysregulation of DNA repair pathways can contribute to the phenomenon of hypoxia-induced genetic instability within the tumor microenvironment. Several studies have revealed that the recombinational repair genes, RAD51 and BRCA1, and the DNA mismatch repair genes, MLH1 and MSH2, are decreased in expression in response to hypoxic stress, prompting interest in elucidating the mechanistic basis for these responses. Here we report that the downregulation of RAD51 by hypoxia is specifically mediated by repressive E2F4/p130 complexes that bind to a single E2F site in the proximal promoter of the gene. Intriguingly, this E2F site is conserved in the promoter of the BRCA1 gene, which is also regulated by a similar mechanism in hypoxia. Mechanistically, we have found that hypoxia induces substantial p130 dephosphorylation and nuclear accumulation, leading to the formation of E2F4/p130 complexes and increased occupancy of E2F4 and p130 at the RAD51 and BRCA1 promoters. These findings reveal a coordinated transcriptional program mediated by the formation of repressive E2F4/p130 complexes that represents an integral response to hypoxic stress. In addition, this co-regulation of key factors within the homology-dependent DNA repair pathway provides a further basis for understanding genetic instability in tumors and may guide the design of new therapeutic strategies for cancer.

Genomic instability in cancer.

Solid tumours have abnormal, deficient vascular and lymphatic systems. As a result, perfusion within these malignancies is inadequate and chaotic, and the cancers contain regions that are transiently and chronically exposed to low pH, severe hypoxia and nutrient deprivation. These microenvironmental inadequacies are present from the earliest point in the development of solid tumours, and are fully established while the neoplasms are still microscopic. Exposures to acidic and hypoxic environments have been shown to produce a wide range of cytogenetic changes. These include increases in mutation frequencies; deficits in DNA repair; DNA overreplication and gene amplification; the induction of chromosomal fragile sites, triggering genomic rearrangements; and changes in gene expression. Moreover, exposure of cells to adverse microenvironments such as those in solid tumours selects for cells which have defects in the structure or expression of the genes that normally regulate cell proliferation. The genetic changes and selection pressures induced by hypoxia may be critical in causing the development of the genomic instability and genetic heterogeneity which is characteristic of solid tumours and in fostering the evolution of relatively benign cell populations in solid tumours to increasingly malignant, increasingly aggressive phenotypes.

Triplex forming oligonucleotides: sequence-specific tools for gene targeting.

Sequence-specificity is the key to effective genetic targeting. With specificity, targeted genes can be manipulated in multiple ways; without it, gene therapy agents become loose canons within cells. Triplex forming oligonucleotides (TFOs) bind in the major groove of duplex DNA with high specificity and affinity. Because of these characteristics, TFOs have been proposed as homing devices for genetic manipulation in vivo. Here we review work demonstrating the ability of TFOs and related molecules to alter gene expression and mediate genome modification in mammalian cells. Recent studies have established that TFOs can mediate targeted gene knock out in mice, laying the foundation for the potential application of these molecules in human gene therapy.

Chromosome targeting at short polypurine sites by cationic triplex-forming oligonucleotides.

Triplex-forming oligonucleotides (TFOs) bind specifically to duplex DNA and provide a strategy for site-directed modification of genomic DNA. Recently we demonstrated TFO-mediated targeted gene knockout following systemic administration in animals. However, a limitation to this approach is the requirement for a polypurine tract (typically 15-30 base pairs (bp)) in the target DNA to afford high affinity third strand binding, thus restricting the number of sites available for effective targeting. To overcome this limitation, we have investigated the ability of chemically modified TFOs to target a short (10 bp) site in a chromosomal locus in mouse cells and induce site-specific mutations. We report that replacement of the phosphodiester backbone with cationic phosphoramidate linkages, either N,N-diethylethylenediamine or N,N-dimethylaminopropylamine, in a 10-nucleotide, psoralen-conjugated TFO confers substantial increases in binding affinity in vitro and is required to achieve targeted modification of a chromosomal reporter gene in mammalian cells. The triplex-directed, site-specific induction of mutagenesis in the chromosomal target was charge- and modification-dependent, with the activity of N,N-diethylethylenediamine > N,N-dimethylaminopropylamine phosphodiester, resulting in 10-, 6-, and <2-fold induction of target gene mutagenesis, respectively. Similarly, N,N-diethylethylenediamine and N,N-dimethylaminopropylamine TFOs were found to enhance targeting at a 16-bp G:C bp-rich target site in a chromatinized episomal target in monkey COS cells, although this longer site was also targetable by a phosphodiester TFO. These results indicate that replacement of phosphodiester bonds with positively charged N,N-diethylethylenediamine linkages enhances intracellular activity and allows targeting of relatively short polypurine sites, thereby substantially expanding the number of potential triplex target sites in the genome.

Gene targeting via triple-helix formation.

A report on a recent workshop entitled "Gene-Targeted Drugs: Function and Delivery" conveys a justified optimism for the eventual feasibility and therapeutic benefit of gene-targeting strategies. Although multiple approaches are being explored, this chapter focuses primarily on the uses of triplex-forming oligonucleotides (TFOs). TFOs are molecules that bind in the major groove of duplex DNA and by so doing can produce triplex structures. They bind to the purine-rich strand of the duplex through Hoogsteen or reverse Hoogsteen hydrogen bonding. They exist in two sequence motifs, either pyrimidine or purine. Improvements in delivery of these TFOs are reducing the quantities required for an effective intracellular concentration. New TFO chemistries are increasing the half-life of these oligos and expanding the range of sequences that can be targeted. Alone or conjugated to active molecules, TFOs have proven to be versatile agents both in vitro and in vivo. Foremost, TFOs have been employed in antigene strategies as an alternative to antisense technology. Conversely, they are also being investigated as possible upregulators of transcription. TFOs have also been shown to produce mutagenic events, even in the absence of tethered mutagens. TFOs can increase rates of recombination between homologous sequences in close proximity. Directed sequence changes leading to gene correction have been achieved through the use of TFOs. Because it is theorized that these modifications are due to the instigation of DNA repair mechanisms, an important area of TFO research is the study of triple-helix recognition and repair.

Hypermutability to ionizing radiation in mismatch repair-deficient, Pms2 knockout mice.

DNA mismatch repair (MMR) has been shown to play a role in the cytotoxicity of ionizing radiation (IR), as cell lines established from MMR-deficient mice exhibit higher clonogenic survival after IR than do cell lines from wild-type littermates. To test whether this tolerance phenotype would render MMR-deficient animals hypermutable to IR, we compared IR mutagenesis of Pms2-deficient versus wild-type transgenic mice carrying a lambda shuttle vector for mutation detection. In Pms2 nullizygous animals, the mutation frequency in the supFG1 reporter gene was increased from 210 x 10(-5) in untreated animals to 734 x 10(-5) after 6 Gy of IR (an increase of 524 mutants per 10(5)), whereas the frequency in wild-type mice increased from 1.9 x 10(-5) to 10.2 x 10(-5) (an increase of only 8.3 mutants per 10(5)). Similarly, when the lambda cII gene was used as a reporter, the mutation frequency in nullizygous mice was increased from 16.3 x 10(-5) to 42.3 x 10(-5) after IR (an increase of 26.0 x 10(-5)), whereas the frequency in wild-type mice increased from 2.4 x 10(-5) to 9.4 x 10(-5) (an increase of only 7.0 x 10(-5)). The pattern of IR-induced mutations in the MMR-deficient animals was notable for single bp deletions and insertions in mononucleotide repeat sequences, along with a slight increase in transversions. Overall, these results suggest that MMR-deficiency confers hypermutability to IR, and that much of this hypermutability can be attributed to induced instability of simple sequence repeats. Hence, MMR influences not only the survival but also the mutability of cells in response to IR.

Anterior and posterior allografts in symptomatic thoracolumbar deformity.

The radiographic and clinical results of 105 patients with symptomatic spinal deformities were categorized retrospectively based on surgical approach and type of bone autograft or allograft used for each patient's fusion surgery into seven different groups and compared with one another. The three bone autograft control groups were posterior autograft only (n = 20), anterior autograft only (n = 6), and combined anterior and posterior autograft (n = 12). The allograft groups were posterior morcellized allograft (n = 7), posterior morcellized allograft and anterior autograft (n = 11), anterior structural interbody allografts and posterior mixture of allograft and autograft (n = 37), and anterior strut allograft with posterior mixture of allograft and autograft (n = 12). Radiographs revealed high pseudoarthrosis rates for adults with a posterior-only allograft and with anterior strut allografts spanning four or more levels. Results of the self-assessment outcomes questionnaire, at a mean follow-up period of 52 months, revealed less pain and improved cosmesis for all groups, and improved function in patients who had undergone combined anteroposterior fusion. The authors conclude that posterior cancellous allograft is a poor substitute for autograft bone and that strut allografts spanning more than four levels require technique modifications to enhance their effectiveness. In general, anterior structural allografts are effective in maintaining correction, result in fusion rates comparable to those of autografts, and correlate to improved outcomes.

Triplex-induced recombination in human cell-free extracts. Dependence on XPA and HsRad51.

Triple helix-forming oligonucleotides (TFOs) can bind to polypurine/polypyrimidine regions in DNA in a sequence-specific manner. Triple helix formation has been shown to stimulate recombination in mammalian cells in both episomal and chromosomal targets containing direct repeat sequences. Bifunctional oligonucleotides consisting of a recombination donor domain tethered to a TFO domain were found to mediate site-specific recombination in an intracellular SV40 vector target. To elucidate the mechanism of triplex-induced recombination, we have examined the ability of intermolecular triplexes to provoke recombination within plasmid substrates in human cell-free extracts. An assay for reversion of a point mutation in the supFG1 gene in the plasmid pSupFG1/G144C was established in which recombination in the extracts was detected upon transformation into indicator bacteria. A bifunctional oligonucleotide containing a 30-nucleotide TFO domain linked to a 40-nucleotide donor domain was found to mediate gene correction in vitro at a frequency of 46 x 10(-)5, at least 20-fold above background and over 4-fold greater than the donor segment alone. Physical linkage of the TFO to the donor was unnecessary, as co-mixture of separate TFO and donor segments also yielded elevated gene correction frequencies. When the recombination and repair proteins HsRad51 and XPA were depleted from the extracts using specific antibodies, the triplex-induced recombination was diminished, but was either partially or completely restored upon supplementation with the purified HsRad51 or XPA proteins, respectively. These results establish that triplex-induced, intermolecular recombination between plasmid targets and short fragments of homologous DNA can be detected in human cell extracts and that this process is dependent on both XPA and HsRad51.

ATM-dependent expression of the insulin-like growth factor-I receptor in a pathway regulating radiation response.

The ATM gene is mutated in the syndrome of ataxia telangiectasia (AT), associated with neurologic dysfunction, growth abnormalities, and extreme radiosensitivity. Insulin-like growth factor-I receptor (IGF-IR) is a cell surface receptor with tyrosine kinase activity that can mediate mitogenesis, cell transformation, and inhibition of apoptosis. We report here that AT cells express low levels of IGF-IR and show decreased IGF-IR promoter activity compared with wild-type cells. Complementation of AT cells with the ATM cDNA results in increased IGF-IR promoter activity and elevated IGF-IR levels, whereas expression in wild-type cells of a dominant negative fragment of ATM specifically reduces IGF-IR expression, results consistent with a role for ATM in regulating IGF-IR expression at the level of transcription. When expression of IGF-IR cDNA is forced in AT cells via a heterologous viral promoter, near normal radioresistance is conferred on the cells. Conversely, in ATM cells complemented with the ATM cDNA, specific inhibition of the IGF-IR pathway prevents correction of the radiosensitivity. Taken together, these results establish a fundamental link between ATM function and IGF-IR expression and suggest that reduced expression of IGF-IR contributes to the radiosensitivity of AT cells. In addition, because IGF-I plays a major role in human growth and metabolism and serves as a survival and differentiation factor for developing neuronal tissue, these results may provide a basis for understanding other aspects of the AT syndrome, including the growth abnormalities, insulin resistance, and neurodegeneration.

Directed gene modification via triple helix formation.

The ability to selectively target mammalian genes and disrupt or restore their function would represent an important advance in gene therapy. Mutation of a single nucleotide can often result in a non-functional gene product. Reversion of defective genes to their correct sequences could lead to permanent cures for patients with many genetic diseases. Molecules such as triplex forming oligonucleotides (TFOs) and peptide nucleic acids (PNAs) are currently being employed to bind to double-stranded DNA. Efficient targeting of genomic DNA with these molecules will be the initial step in gene modification.

In vivo evaluation of calcium sulfate as a bone graft substitute for lumbar spinal fusion.

BACKGROUND CONTEXT: Posterolateral fusions of the lumbar spine have nonunion rates as high as 35%. The availability of autologous bone to promote fusion is limited, particularly for multilevel fusions. Bone substitutes have been proposed to augment or replace autologous bone for spinal surgery. Calcium sulfate offers high porosity, osteoconductivity, and high resorption rate. This material has been used successfully for treatment of long bone defects but has not been investigated as a bone graft substitute for spinal fusions. PURPOSE: To determine whether the use of calcium sulfate granules in conjunction with an implantable electrical stimulator is a safe and effective means of attaining spinal fusion. STUDY DESIGN/SETTING: A rabbit lumbar fusion model was used to assess a calcium sulfate bone graft substitute in combination with electrical stimulation for spinal fusion. METHODS: Thirty-six adult New Zealand White female rabbits were divided into three groups. Each group underwent a single-level (L5-L6) fusion, receiving 3.0 cc calcium sulfate granules with bone marrow aspirate from the iliac crest. Group 1 had no electrical stimulator applied. Groups 2 and 3 received a 40-microA (Group 2) or a 100-microA (Group 3) implantable electrical stimulator. The animals were sacrificed at 8 weeks, and the rabbit spines were subjected to radiographic assessment, manual palpation, and mechanical testing. RESULTS: Two rabbits died postoperatively. The radiographic assessment revealed no fusions occurred at the adjacent nonoperated control levels (L4-L5). There were no fusions observed within Group 1, containing the calcium sulfate and bone marrow aspirate alone. The sites with the implantable stimulators showed a dose-dependent increase in fusion stiffness. However, no fusion mass in Group 2 or 3 was graded as bilaterally complete. CONCLUSION: This study found that calcium sulfate as a bone graft substitute was unsuccessful in promoting spine fusion in a rabbit model. There was radiographic evidence of rapid resorption of the calcium sulfate within 4 weeks after surgery. The use of electrical stimulation created a dose-dependent increase in mechanical competence of the bony mass. However, the addition of direct current (DC) current did not significantly alter fusion rates with calcium sulfate used as the bone graft substitute in this model.

Intracellular generation of single-stranded DNA for chromosomal triplex formation and induced recombination.

Synthetic triple helix-forming oligodeoxyribonucleotides (TFOs) have been used to alter gene expression and to induce targeted genome modification in cells and animals. However, the efficacy of such oligodeoxyribonucleotides (ODNs) depends on efficient intracellular delivery. A novel vector system was tested for the production of single-stranded DNA (ssDNA) to serve as a TFO in mouse cells. Mouse cells carrying a substrate that can report triplex-stimulated intrachromosomal recombination were transfected with a series of ssDNA vectors, and induced recombination was assayed. Transfection with a vector set designed to generate a 34 nt G-rich ssDNA capable of triplex formation at a 30 bp polypurine target site within the reporter substrate yielded recombinants at a frequency of 196 x 10(-6), versus a background frequency of 45 x 10(-6) in mock transfected cells. No induction was seen when a vector set lacking the TFO sequence insert was tested or when the component vectors were transfected individually. Vectors engineered to express a C-rich 34 nt sequence (not expected to form triplex under physiological conditions) had no effect over background. Primer extension analyses on lysates from transfected cells confirmed the production of the intended ssDNAs. These results suggest that ssDNA molecules of a defined sequence can be generated intracellularly using a novel vector system and that such molecules are active in mediating triplex-dependent chromosomal events. The ability to produce active TFOs within cells may provide a new foundation for triplex-based gene targeting strategies.

Specific mutations induced by triplex-forming oligonucleotides in mice.

Triplex-forming oligonucleotides (TFOs) recognize and bind to specific duplex DNA sequences and have been used extensively to modify gene function in cells. Although germ line mutations can be incorporated by means of embryonic stem cell technology, little progress has been made toward introducing mutations in somatic cells of living organisms. Here we demonstrate that TFOs can induce mutations at specific genomic sites in somatic cells of adult mice. Mutation detection was facilitated by the use of transgenic mice bearing chromosomal copies of the supF and cII reporter genes. Mice treated with a supF-targeted TFO displayed about fivefold greater mutation frequencies in the supF gene compared with mice treated with a scrambled sequence control oligomer. No mutagenesis was detected in the control gene (cII) with either oligonucleotide. These results demonstrate that site-specific, TFO-directed genome modification can be accomplished in intact animals.

Ionizing radiation-induced apoptosis via separate Pms2- and p53-dependent pathways.

The cytotoxicity of ionizing radiation (IR) has been associated with both the p53 pathway and with DNA mismatch repair (MMR). p53 mediates cell cycle arrest and apoptosis in response to X-ray damage, whereas the MMR complex is thought to recognize damaged bases and initiate a signal transduction pathway that can include phosphorylation of p53. To determine whether p53 and MMR mediate X-ray cytotoxicity via the same pathway, mice with targeted disruptions in either the p53 gene or the MutL homologue MMR gene Pms2 were interbred and primary fibroblasts were established from the progeny with genotypes of either wild type, p53 null, Pms2 null, or double null. Cells with either p53 or Pms2 separately disrupted showed reduced levels of apoptosis after IR in comparison with wild type, but the double null cells showed even lower levels, consistent with nonoverlapping roles for p53 and PMS2 in the X-ray response. In transformed cell lines established from the primary cells at early passage, similar differences in the apoptotic response to IR were seen, and clonogenic survival assays following low dose rate IR further showed that nullizygosity for Pms2 confers increased survival on cells in both wild-type and p53 null backgrounds. These results indicate that both p53 and MMR contribute to X-ray-induced apoptosis and that the role of MMR in the cytotoxicity of IR does not depend on p53.

Diminished DNA repair and elevated mutagenesis in mammalian cells exposed to hypoxia and low pH.

The tumor microenvironment is characterized by regions of fluctuating and chronic hypoxia, low pH, and nutrient deprivation. It has been proposed that this unique tissue environment itself may constitute a major cause of the genetic instability seen in cancer. To investigate possible mechanisms by which the tumor microenvironment might contribute to genetic instability, we asked whether the conditions found in solid tumors could influence cellular repair of DNA damage. Using an assay for repair based on host cell reactivation of UV-damaged plasmid DNA, cells exposed to hypoxia and low pH were found to have a diminished capacity for DNA repair compared with control cells grown under standard culture conditions. In addition, cells cultured under hypoxia at pH 6.5 immediately after UV irradiation had elevated levels of induced mutagenesis compared with those maintained in standard growth conditions. Taken together, the results suggest that cellular repair functions may be impaired under the conditions of the tumor microenvironment, causing hypermutability to DNA damage. This alteration in repair capacity may constitute an important mechanism underlying the genetic instability of cancer cells in vivo.

High-frequency intrachromosomal gene conversion induced by triplex-forming oligonucleotides microinjected into mouse cells.

To test the ability of triple helix-forming oligonucleotides (TFOs) to promote recombination within chromosomal sites in mammalian cells, a mouse LTK(-) cell line was established carrying two mutant copies of the herpes simplex virus thymidine kinase (TK) gene as direct repeats in a single chromosomal locus. Recombination between these repeats can produce a functional TK gene and occurs at a spontaneous frequency of 4 x 10(-6) under standard culture conditions. When cells were microinjected with TFOs designed to bind to a 30-bp polypurine site situated between the two TK genes, recombination was observed at frequencies in the range of 1%, 2,500-fold above the background. Recombination was induced efficiently by injection of both psoralen-conjugated TFOs (followed by long-wave UVA light; 1. 2%) and unconjugated TFOs alone (1.0%). Control oligomers of scrambled sequence but identical base composition were ineffective, and no TFO-induced recombination was seen in a control LTK(-) cell line carrying an otherwise identical dual TK gene construct lacking the 30-bp polypurine target site. TFOs transfected with cationic lipids also induced recombinants in a highly sequence-specific manner but were less effective, with induced recombination frequencies of 6- to 7-fold over background. Examination of the TFO-induced recombinants by genomic Southern blotting revealed gene conversion events in which both TK genes were retained, but either the upstream (57%) or the downstream gene (43%) was corrected to wild type. These results suggest that, with efficient intracellular delivery, TFOs may be effective tools to promote site-specific recombination and targeted modification of chromosomal loci.