Exploring polyps to colon carcinoma voyage: can blocking the crossroad halt the sequence?

Colorectal cancer is an important public health concern leading to significant cancer associate mortality. A vast majority of colon cancer arises from polyp which later follows adenoma, adenocarcinoma, and carcinoma sequence. This whole process takes several years to complete and recent genomic and proteomic technologies are identifying several targets involved in each step of polyp to carcinoma transformation in a large number of studies. Current text presents interaction network of targets involved in polyp to carcinoma transformation. In addition, important targets involved in each step according to network biological parameters are also presented. The functional overrepresentation analysis of each step targets and common top biological processes and pathways involved in carcinoma indicate several insights about this whole mechanism. Interaction networks indicate TP53, AKT1, GAPDH, INS, EGFR, and ALB as the most important targets commonly involved in polyp to carcinoma sequence. Though several important pathways are known to be involved in CRC, the central common involvement of PI3K-AKT indicates its potential for devising CRC management strategies. The common and central targets and pathways involved in polyp to carcinoma progression can shed light on its mechanism and potential management strategies. The data-driven approach aims to add valuable inputs to the mechanism of the years-long polyp-carcinoma sequence.

Timed GDNF gene therapy using an immune-evasive gene switch promotes long distance axon regeneration.

Neurosurgical repair in patients with proximal nerve lesions results in unsatisfactory recovery of function. Gene therapy for neurotrophic factors is a powerful strategy to promote axon regeneration. Glial cell line-derived neurotrophic factor (GDNF) gene therapy promotes motor neuron survival and axon outgrowth; however, uncontrolled delivery of GDNF results in axon entrapment. We report that time-restricted GDNF expression (1 month) using an immune-evasive doxycycline-inducible gene switch attenuated local axon entrapment in avulsed reimplanted ventral spinal roots, was sufficient to promote long-term motor neuron survival (24 weeks) and facilitated the recovery of compound muscle action potentials by 8 weeks. These improvements were associated with an increase in long-distance regeneration of motor axons. In contrast, persistent GDNF expression impaired axon regeneration by inducing axon entrapment. These findings demonstrate that timed expression can resolve the deleterious effect of uncontrolled growth factor delivery and shows that inducible growth factor gene therapy can be employed to enhance the efficacy of axon regeneration after neurosurgical repair of a proximal nerve lesion in rats. This preclinical study is an important step in the ongoing development of a neurotrophic factor gene therapy for patients with severe proximal nerve lesions.

Drastic stabilization of parallel DNA hybridizations by a polylysine comb-type copolymer with hydrophilic graft chain.

Electrostatic interactions play a major role in protein-DNA interactions. As a model system of a cationic protein, herein we focused on a comb-type copolymer of a polycation backbone and dextran side chains, poly(L-lysine)-graft-dextran (PLL-g-Dex), which has been reported to form soluble interpolyelectrolyte complexes with DNA strands. We investigated the effects of PLL-g-Dex on the conformation and thermodynamics of DNA oligonucleotides forming various secondary structures. Thermodynamic analysis of the DNA structures showed that the parallel conformations involved in both DNA duplexes and triplexes were significantly and specifically stabilized by PLL-g-Dex. On the basis of thermodynamic parameters, it was further possible to design DNA switches that undergo structural transition responding to PLL-g-Dex from an antiparallel duplex to a parallel triplex even with mismatches in the third strand hybridization. These results suggest that polycationic molecules are able to induce structural polymorphism of DNA oligonucleotides, because of the conformation-selective stabilization effects.

A switch between cytoprotective and cytotoxic autophagy in the radiosensitization of breast tumor cells by chloroquine and vitamin D.

Calcitriol or 1,25-dihydroxyvitamin D3, the hormonally active form of vitamin D, as well as vitamin D analogs, has been shown to increase sensitivity to ionizing radiation in breast tumor cells. The current studies indicate that the combination of 1,25-dihydroxyvitamin D3 with radiation appears to kill p53 wild-type, estrogen receptor-positive ZR-75-1 breast tumor cells through autophagy. Minimal apoptosis was observed based on cell morphology by DAPI and TUNEL staining, annexin/PI analysis, caspase-3, and PARP cleavage as well as cell cycle analysis. Induction of autophagy was indicated by increased acridine orange staining, RFP-LC3 redistribution, and detection of autophagic vesicles by electron microscopy, while autophagic flux was monitored based on p62 degradation. The autophagy inhibitors, chloroquine and bafilomycin A1, as well as genetic suppression of the autophagic signaling proteins Atg5 or Atg 7 attenuated the impact of the combination treatment of 1,25 D3 with radiation. In contrast to autophagy mediating the effects of the combination treatment, the autophagy induced by radiation alone was apparently cytoprotective in that either pharmacological or genetic inhibition increased sensitivity to radiation. These studies support the potential utility of vitamin D for improving the impact of radiation for breast cancer therapy, support the feasibility of combining chloroquine with radiation for the treatment of breast cancer, and demonstrate the existence of an "autophagic switch" from cytoprotective autophagy with radiation alone to cytotoxic autophagy with the 1,25 D3-radiation combination.

A bistable switch underlying B-cell differentiation and its disruption by the environmental contaminant 2,3,7,8-tetrachlorodibenzo-p-dioxin.

The differentiation of B cells into antibody-secreting plasma cells upon antigen stimulation, a crucial step in the humoral immune response, is disrupted by 2,3,7,8-tetrachlorodibenzo-p-dioxin (TCDD). Several key regulatory proteins in the B-cell transcriptional network have been identified, with two coupled mutually repressive feedback loops among the three transcription factors B-cell lymphoma 6 (Bcl-6), B lymphocyte-induced maturation protein 1(Blimp-1), and paired box 5 (Pax5) forming the core of the network. However, the precise mechanisms underlying B-cell differentiation and its disruption by TCDD are not fully understood. Here we show with a computational systems biology model that coupling of the two feedback loops at the Blimp-1 node, through parallel inhibition of Blimp-1 gene activation by Bcl-6 and repression of Blimp-1 gene deactivation by Pax5, can generate a bistable switch capable of directing B cells to differentiate into plasma cells. We also use bifurcation analysis to propose that TCDD may suppress the B-cell to plasma cell differentiation process by raising the threshold dose of antigens such as lipopolysaccharide required to trigger the bistable switch. Our model further predicts that high doses of TCDD may render the switch reversible, thus causing plasma cells to lose immune function and dedifferentiate to a B cell-like state. The immunotoxic implications of these predictions are twofold. First, TCDD and related compounds would disrupt the initiation of the humoral immune response by reducing the proportion of B cells that respond to antigen and differentiate into antibody-secreting plasma cells. Second, TCDD may also disrupt the maintenance of the immune response by depleting the pool of available plasma cells through dedifferentiation.

The saving switch.

The epigenome consists of a system of chemical tags that attach to our DNA and its associated molecules, switching genes on and off. But the system is not without glitches-and scientists think that the misplacement of these tags can cause disease. This idea has led to new drugs that aim to correct gene activity (and obliterate disease) by altering the proteins around which DNA winds. Cassandra Willyard examines whether this approach will unlock the long-awaited promise of epigenetic therapy.

Probing the control elements of the CYP1A1 switching module in H4IIE hepatoma cells.

Previous research from our laboratory has shown a switch-like response to PCB 126 mediated CYP1A1 induction in primary rat hepatocytes and in H4IIE rat hepatoma cells. On a single cell level, cells appear to be either "on" or "off" for CYP1A1 induction at a given dose; some cells never respond to PCB 126. These cells represent a non-responding population. Cells that are switched "on" by PCB 126 display varying levels of induction, much like the dimmer on a light switch. The goal of the present research is to begin to uncover the mechanism for this switch-like response to CYP1A1 induction in H4IIE rat hepatoma cells. The AhR pathway is modulated by multiple co-activators and by phosphorylation. This research focuses on the phosphorylation cascades initiated by PCB 126 and the role they play in CYP1A1 induction. Our research reveals a likely role for protein kinase C (PKC) in this switch response. Inhibition of PKC by H-7 dramatically reduced the percent of cells that express CYP1A1 in response to PCB 126 treatment, as determined by flow cytometry. The effect of H-7 was concentration dependent, decreasing the number of cells expressing CYP1A1 rather than decreasing the level of CYP1A1 in all cells. This finding provides further evidence for the switch-like behavior of CYP1A1 induction and implicates PKC in this response to PCB126. The protein kinase inhibitor, HA-1004, had only a minor effect on CYP1A1 induction. A high-throughput immunoblot screen for 40 proteins revealed the regulation of several proteins/phosphoproteins by PCB 126. Most importantly, two proteins containing phosphoserine/phoshothreonine residues were increased by PCB126 treatment. However, PKC translocation studies and activity studies failed to verify that PCB126 activates PKC. It is possible that constitutive PKC activity is sufficient to maintain phosphorylation of critical components of the AhR pathway. Immunoblotting studies showed that MAP kinases ERK and JNK are not activated by PCB 126 in H4IIE cells and the ERK inhibitor U0126 did not impair CYP1A1 induction. Additional studies are planned to further investigate the role of PKC in the switch-like response to PCB 126.

Novel gene switches for targeted and timed expression of proteins of interest.

This article reports on the construction and analysis in vitro and in vivo of novel gene switches that can be used to achieve spatial as well as temporal control over the expression of a transgene of interest. The switches are expected to be functional in virtually any tissue and cell type. They consist of (a) a foreign or modified transactivator expressed under the dual control of a promoter or promoter cassette that is responsive to heat and the transactivator and (b) a promoter responsive to the transactivator for controlling the transgene of interest. A preferred gene switch of this type incorporated a mifepristone-dependent transactivator. This gene switch could be activated by a transient heat treatment in the presence of mifepristone. Activity increased with the intensity of the activating heat treatment and was found to persist for more than 6 days. The gene switch was essentially inactive prior to an activating heat treatment, in the absence or presence of mifepristone. Activated gene switch could be silenced by removal/withdrawal of mifepristone.

Spatiotemporal gene expression targeting with the TARGET and gene-switch systems in Drosophila.

Targeted gene expression has become a standard technique for the study of biological questions in Drosophila. Until recently, transgene expression could be targeted in the dimension of either time or space, but not both. Several new systems have recently been developed to direct transgene expression simultaneously in both time and space. We describe here two such systems that we developed in our laboratory. The first system provides a general method for temporal and regional gene expression targeting (TARGET) with the conventional GAL4-upstream activator sequence (UAS) system and a temperature-sensitive GAL80 molecule, which represses GAL4 transcriptional activity at permissive temperatures. The second system, termed Gene-Switch, is based on a GAL4-progesterone receptor chimera that is hormone-inducible. We have used both systems for simultaneous spatial and temporal rescue of memory dysfunction in the rutabaga (rut) memory mutant of Drosophila. In this protocol, we provide guidelines for the use of these two novel systems, which should have general utility in studying Drosophila biology and in using the fly as a model for human disease.

Dissection of the switch between genes for replication and transfer of promiscuous plasmid RK2: basis of the dominance of trfAp over trbAp and specificity for KorA in controlling the switch.

The trfA and trb operons of broad host range plasmid RK2 are required for replication and conjugative transfer, respectively. Transcription of the trb operon can be initiated at one of two promoters: trbAp or trbBp. trbBp provides a burst of trb transcription on first entry into the cell. trbAp appears to be responsible for steady-state transcription of the trb operon as well as trbA, encoding a repressor which helps to shut down trbBp. The promoters trfAp and trbAp are arranged as face-to-face divergent promoters. trfAp is very strong and shuts off trbAp activity until trfAp is inhibited by KorA, one of the plasmid-encoded global regulators. Although trfAp is also repressed by KorB, a second global regulator encoded along with KorA in the central control operon, trbAp activation only occurs when KorA is present. KorB did not activate trbAp and indeed had a significant inhibitory effect on KorA activation. In vitro trfAp binds RNA polymerease (RNAP) approximately ten times more strongly than trbAp. Comparison of single and multiple rounds of in vitro run-off transcription suggested that the inhibitory effect of trfAp is due to elongating transcription complexes. In vitro studies with purified KorA and KorB on RNAP binding, isomerization and in vitro transcription suggested that both proteins can displace RNAP from trfAp, but that once open complexes have formed at either promoter they have a good chance of generating a transcript even if they encounter an opposing RNAP. In vivo KorB repressed trbAp even when trbAp was derepressed by a trfAp-1 mutation, removing the need for KorA. This suggested that KorB not only fails to derepress but actually represses trbAp despite the KorB operator being located 90 bp downstream of the transcription start point (tsp). By contrast KorA still activated trbAp when the two promoters were moved further apart or were brought so close that RNAP binding to the two promoters was mutually exclusive. Thus, KorA plays the dominant role in achieving the balance of expression of genes for alternate modes of plasmid propagation but its action is modulated by KorB.

Cyclosporin A inhibits early mRNA expression of G0/G1 switch gene 2 (G0S2) in cultured human blood mononuclear cells.

Cyclosporin A (CsA) may achieve its immunosuppressive effects by inhibiting the calcium- and calmodulin-dependent phosphatase calcineurin which is required for activation of target genes by members of the NFAT (nuclear factor of activated T cells) transcription factor family. Among these target genes is the gene encoding interleukin-2 (IL2), a cytokine facilitating progression through the G1 phase of the cell cycle. However, IL2 does not reverse CsA inhibition, suggesting that at least one other NFAT-sensitive gene may be involved. The human G0/G1 switch gene, G0S2, has potential NFAT-binding sites in the 5' flank and encodes a small basic potential phosphoprotein of unknown function. Using a sensitive, reverse transcription-polymerase chain reaction (RT-PCR) assay, G0S2 mRNA levels were assayed in cultured blood mononuclear cells. Freshly isolated cells contain high levels of G0S2 mRNA which rapidly decline. This "spontaneous stimulation" is also noted with some other G0S genes and has been attributed to some aspect of the isolation procedure. In cells that have been preincubated to lower mRNA levels, there is a transient increase in G0S2 mRNA, peaking between 1-2 h, in response to Concanavalin-A (ConA), or to the combination of phorbol ester (TPA), and the calcium ionophore, ionomycin. Both these responses are inhibited by CsA. Our results suggest that G0S2 expression is required to commit cells to enter the G1 phase of the cell cycle, and that, while not excluding other possible targets, early inhibition of G0S2 expression by CsA may be important in achieving immunosuppression. G0S2 may be of value as a reporter gene for analyzing the mechanism of action of CsA and its influence on the positive and negative selection of lymphocytes in response to self and not-self antigens.

Hemoglobin switching and its clinical implications.

Advances in the field of hemoglobin switching provide an excellent example of how the investigation of a biologic phenomenon may lead to the development of novel approaches for the treatment of disease. In patients with beta thalassemia and sickle cell disease, transcription switches from a normal gamma-globin gene, in the fetal stage of development, to an abnormal beta-globin gene, in the adult. Manipulations designed to achieve normal globin synthesis in patients with these disorders involve either a reversal of switching, with reestablishment of fetal hemoglobin synthesis, or the introduction of a normal exogenous globin gene to compensate for the defective endogenous gene. In this review we summarize how recent progress in understanding globin gene regulation has led to therapeutic interventions now under clinical investigation.

Analysis of DNA repair pathways of Schizosaccharomyces pombe by means of swi-rad double mutants.

In Schizosaccharomyces pombe 11 different switching genes (swi1 to swi10 and rad22) are known which are involved in mating-type (MT) switching. Mutations in swi5, swi9, swi10 and rad22 also cause an increased radiation sensitivity. We tested whether the survival of these mutants after UV irradiation is influenced by caffeine. We included rad1 and rad13 mutants in our experiments which do not affect MT switching. Several double and triple mutants were constructed. We were able to assign the switching genes to different repair pathways: swi9 and swi10 are involved in excision repair, rad22 has a function in recombination repair, while swi5 appears to be involved in a hitherto unknown pathway. This 'swi5 pathway' is stimulated (!) by caffeine. Previously it was found that the swi5 mutation also reduces meiotic recombination. As to rad genes, we found a few inconsistencies with previous reports in the literature.

Biased distribution of recombination sites within S regions upon immunoglobulin class switch recombination induced by transforming growth factor beta and lipopolysaccharide.

We have characterized extrachromosomal circular DNAs from adult mouse spleen cells that were induced to switch to immunoglobulin A (IgA) with bacterial lipopolysaccharide (LPS) and transforming growth factor beta (TGF-beta), and identified breakpoints of S mu/S gamma 3, S mu/S gamma 2, S mu/S alpha, S gamma 3/S alpha, and S gamma 2/S alpha recombinants. The S mu recombination donor sites clustered in the 3' half of the S mu region, while the S alpha recombination acceptor sites clustered in the 5' half of the S alpha region. In addition, donor and acceptor sites of S gamma regions also clustered in the 3' and 5' parts, respectively. These site preferences are in sharp contrast to the dispersed distribution of S mu/S gamma 1 breakpoints within both S mu and S gamma 1 regions upon IgG1 switch induced by LPS and interleukin 4. Our results support the hypotheses that TGF-beta increases the frequency of switch recombination events to IgA and that the switch recombination to IgA often proceeds by successive recombination of S mu/S gamma and S gamma/S alpha.

Rapid induction of transcription of unrearranged S gamma 1 switch regions in activated murine B cells by interleukin 4.

The distribution of immunoglobulin isotypes in activated B lymphocytes can be modulated by interleukin 4 (IL4), which enhances IgG1 and suppresses IgG3. We show here that IL4 induces transcription of the region 5' adjacent to the s gamma 1 switch region within hours after onset of activation of B cells by bacterial lipopolysaccharide (LPS). Transcripts of 1.7 and 3.2 kb size containing sequences of the region 5' of s gamma 1 are detected. This transcription precedes class switch recombination between s mu and s gamma 1 and reflects the rapid opening of the s gamma 1 region as induced by IL4. This suggests that IL4 directs class switching to IgG1 by opening the s gamma 1 switch region, thus making it accessible for switch recombination.

A genetic switch, based on negative regulation, sharpens stripes in Drosophila embryos.

The pair-rule genes hairy, runt, even-skipped, and fushi tarazu express their mRNAs and proteins in striped patterns in the Drosophila embryo at the blastoderm stage. Previous studies have shown that the generation of these patterns depends upon products of the gap genes and upon interactions between the pair-rule genes themselves. Here we show that blocking protein synthesis induces expression of each of the pair-rule mRNAs in virtually all regions of the embryo. Our observations together with genetic studies carried out in other laboratories suggest that negative feedback between the pair-rule genes plays a key role in striped expression of pair-rule genes. We propose that stable proteins, present in all regions of the embryo, first activate transcription of these pair-rule genes constitutively. Then, various combinations of unstable proteins repress their transcription in a patterned fashion; each stripe of accumulated products of a given pair-rule gene marks a region where it was not repressed. We develop this idea in mathematical form and demonstrate that a network of mutual repression by pair-rule genes can make each blastoderm nucleus into a genetic switch with two stable states. If preexisting gap gene patterns provide initial bias to the blastoderm nuclei, then the "bistable switch behavior" of the nuclei can refine an initially weak spatial bias into a final pattern of sharp stripes.

Butyric acid modulates developmental globin gene switching in man and sheep.

The developmental switch from production of fetal (gamma) to adult (beta) globin occurs on a normally set biologic clock which proceeds even if the adult (beta) globin genes are defective. Preventing or reversing the globin gene switch would be beneficial for subjects with abnormal beta globin genes. We have now identified a class of agents which, when present in elevated plasma concentrations during gestation, appears to inhibit the gamma beta globin gene switch in developing humans. Further investigation has shown that butyric acid and related compounds can increase gamma globin and decrease beta globin expression in erythroid cells cultured from subjects with diseases of abnormal beta globin. Butyrate compounds were therefore infused in an in vivo fetal animal model, and the globin switch was inhibited in most and reversed in some fetal lambs. These data suggest that inhibiting expression of abnormal beta globin genes may be possible in future generations. Histone modification may be a mechanism of action involved. The developmental switch from production of gamma globin to beta globin results in significant morbidity when the beta globin genes are defective. The globin switch has therefore been extensively studied, appearing to be set on a biologic clock and proceeding despite the site of blood production and solely on the basis of gestational age. We previously found that this developmental gene switch is delayed in human fetuses developing in the presence of maternal diabetes. A number of metabolites present in abnormal concentrations in these infants were therefore tested for effects on globin expression.(ABSTRACT TRUNCATED AT 250 WORDS)