A bcl-2/IgH antisense transcript deregulates bcl-2 gene expression in human follicular lymphoma t(14;18) cell lines.

The 14;18 chromosome translocation, characteristic of most human follicular B-cell lymphomas, juxtaposes the bcl-2 gene with the IgH locus, creating a bcl-2/IgH hybrid gene. By mechanisms that are still under investigation, this event increases the cellular levels of the bcl-2 mRNA and thereby induces an overproduction of the antiapoptotic BCL-2 protein which is likely responsible for neoplastic transformation. In an effort to identify potential upregulators of bcl-2 activity in t(14;18) cells, we found, by strand-specific RT-PCR, a bcl-2 antisense transcript that is present in the t(14;18) DOHH2 and SU-DHL-4 but not in the t(14;18)-negative Raji and Jurkat lymphoid cell lines, and thus appears to be dependent on the bcl-2/IgH fusion. This antisense transcript is a hybrid bc1-2/IgH RNA, that originates in the IgH locus, encompasses the t(14;18) fusion site and spans at least the complete 3' UTR region of the bcl-2 mRNA. To achieve some insight into its biological function, we treated the t(14;18) DOHH2 cell line with oligonucleotides (ODNs) by specifically targeting the bc1-2/IgH antisense strand. These ODNs lowered bcl-2 gene expression, inhibited neoplastic cell growth by inducing apoptosis. We would like to propose the hypothesis that the bc1-2/IgH antisense transcript may contribute, by an unknown mechanism, to upregulation of bcl-2 gene expression in t(14;18) cells. The possibility has been considered that the hybrid antisense transcript mask AU-rich motifs present in the 3' UTR of the bcl-2 mRNA characterized in other genes as mRNA destabilizing elements.

Antisense oligonucleotide drug design.

Maneuvering single gene expression is not only an optimal way to study gene function but also an ambitious goal, which will lead to the treatment of a variety of human diseases whose main pathogenetic event is a genetic alteration. The recent efforts focusing on the genome project have led to array based, high throughput, gene expression analysis techniques that allow the study of complex molecular networks. Combining these powerful new technologies with modulation of gene expressions is making it possible to unravel complex molecular networks or, vice versa, to find new gene products responsible for pathological conditions on which exogenous modulation can be productive. Efficient and specific modulation of gene expression can be obtained either by producing transgenic or gene knockout organisms or cells (gene targeting), or by treating organisms or cells with short synthetic nucleic acid segments in antisense orientation with respect to the targeted mRNAs (mRNA targeting by antisense strategy). While genome manipulation is a time consuming and expensive approach, requiring invasive intervention, the "antisense strategy" is characterized by high flexibility resulting from safeness, specificity, reversibility, modulability, and low cost. The rationale of the antisense strategy is that, once one gene sequence is known, its expression can be silenced by application of synthetic single-strand nucleic acid segments (oligonucleotides) whose sequence is in antisense orientation compared to the targeted mRNA. Recently, this "informational" strategy has been boosted by the discovery of the RNA interference: a natural mechanism by which cells are thought to fight detrimental exogenous viruses and endogenous transposons. Despite promising futures, antisense-based therapeutics are far from being an established reality. This review analyses the recent improvements in antisense-based gene expression modulation, focuses on the treatment of diseases in the light of the past, and provides our personal findings on this topic.

The mechanisms of apoptosis in biology and medicine: a new focus for ophthalmology.

Defects in apoptosis (programmed cell death) have recently emerged as being closely involved in the pathogenesis of most ocular diseases and, therefore, apoptosis is now a topic of exponential interest in ophthalmology. This review summarizes recent works on mechanisms of apoptosis, from its initiation and modulation to the switching-on of its execution machinery. Interactions of cell death with cell division programs to orchestrate ontogenesis, aging, and adult life and their alterations in human diseases are pointed out. Two main apoptotic signaling pathways are identified: a death receptor-dependent (extrinsic) pathway and a mitochondrion-dependent (intrinsic) pathway. Mitochondrion harbors both antiapoptotic (Bcl-2, Bcl-XL) and apoptotic factors (Smac/Diablo, Apaf-1, cytochrome c). Its permeability transition pore (mPTP) is the main trigger of cell suicide. The process of mPTP opening, in association with extrusion to cytoplasm of a variety of apoptotic factors, is shown. Cytochrome c is one of these apoptotic factors. When expelled to cytoplasm, this double-faced respiratory chain component assembles with two other modules, Apaf-1 and procaspase 9, to form a protein complex--the apoptosome--that starts apoptosis execution. Another respiratory chain component, the CoQ10, is believed to counteract mPTP opening. What makes apoptosis particularly exciting for medicine is that its dysfunctions play a central role in the pathogenesis of several human diseases. For instance, excesses of apoptosis lead to cell loss that accompanies neurodegenerative diseases, whereas genetically determined defects of apoptosis lead to the deregulated cell proliferation typical of cancer. A variety of ophthalmologic diseases, such as post-keratectomy haze, corneal lesions, cataract, glaucoma, senile maculopathies, and genetic ocular pathologies, that underlie apoptosis dysfunctions are treated in detail in the other reviews of this issue.

Prevention of corneal keratocyte apoptosis after argon fluoride excimer laser irradiation with the free radical scavenger ubiquinone Q10.

PURPOSE: To assess in vitro the potential of the free radical scavenger ubiquinone Q10 in preventing keratocyte apoptosis after argon fluoride (ArF) excimer laser irradiation. METHODS: Cultured rabbit keratocytes were irradiated at very low single-pulse laser fluences. The cumulative effects generated by three total fluence doses between 12 and 45 mJ/cm2, representative of single-pulse subablative doses during photorefractive keratectomy (PRK) in humans, were evaluated. We employed the following parameters to compare pretreated (10 microM ubiquinone Q10) and untreated samples: 1) number and morphology of living cells by Trypan blue test and ultramicroscopy, respectively; 2) level of free-radical formation assessed by malonaldehyde quantitation; 3) cellular energy level evaluated by ATP assay. RESULTS: Excimer laser irradiation kills cultured keratocytes by inducing apoptosis. The effect increases with the cumulative fluence dose. In the samples pretreated with ubiquinone Q10 there were significantly fewer cumulative apoptotic events than in the untreated ones. Quantitative analysis of malonaldehyde cellular levels suggested this protective action of ubiquinone Q10 was connected with its ability to scavenge laser-generated free radicals. ATP assay also confirmed that it raised cellular energy levels. CONCLUSIONS: The treatment of corneal keratocytes with relatively low concentrations of ubiquinone Q10 can prevent apoptosis after ArF excimer laser irradiation. If these findings are confirmed on human keratocytes this treatment could be usefully exploited in the PRK surgical procedure. That might lead to a reduction in the occurrence of haze and curvature regression triggered by programmed cell death.

BCL-2 regulation targeting the AU-rich domain.

In an effort to identify potential upregulators of bcl-2 activity in t(14;18) follicular B lymphoma cells, we detected a hybrid bcl-2/IgH RNA transcribed in antisense orientation. This antisense transcript may contribute to upregulation of bcl-2 expression in t(14;18) cells, overlapping AU-rich motifs present in the 3'-untranslated region of bcl-2 mRNA. We have studied the enzymatic efficiency of a ribozyme directed towards the bcl-2 AU-rich region in a cell-free system determining its kinetic parameters.

Induction of apoptosis and mitosis inhibition by degraded DNA lipotransfection mimicking genotoxic drug effects.

Genotoxic damage induces cell cycle arrest and/or apoptosis by activation of p53 oncosuppressor protein. A number of anticancer drugs are genotoxic and their damaging effect upon cells is mediated by this mechanism. Microinjection of defined DNA species directly into nucleus has been reported previously to activate p53 and inhibit cell cycle. Here, we demonstrate that simple addition of heterogeneous degraded DNA to cultured cells (Rat-1 fibroblasts) in combination with lipotransfecting agent DOTAP leads to apoptosis induction and mitosis inhibition by a molecular mechanism which mimics that of the cellular response to genotoxic anticancer agents. Indeed, both cellular effects induced by lipotransfected degraded DNA (essentially, heterogeneous small DNA fragments) are associated to p53 activation and modulated by two apoptosis-related genes, such as bcl-2 and c-myc, which also modulate the apoptotic threshold to anticancer agents. Here we raise the hypothesis of exogenous DNA segment lipotransfection as possible new tool for anticancer therapy.

The antisense bcl-2-IgH transcript is an optimal target for synthetic oligonucleotides.

In most human follicular B cell lymphomas the bcl-2 gene is up-regulated as a result of the t(14;18) chromosomal translocation generating a hybrid bcl-2-IgH mRNA. Recently, we have identified in t(14;18)-positive cells a bcl-2-IgH mRNA in the antisense orientation, putatively responsible for the overexpression of bcl-2. Herein we show that this chimeric antisense transcript is an optimal target for synthetic oligodeoxynucleotides (ODNs). A variety of sense-oriented oligonucleotides have been designed that target the antisense transcript in regions endowed with a sequence specificity presumably restricted to an individual cell line (the bcl-2-IgH fusion regions) or extended to all t(14;18) cells (the ectopic bcl-2 segment upstream from the major breakpoint region and the IgH segment). All sense-oriented ODNs complementary to the antisense transcript induced an early strong inhibition of cell growth and a late fulminant cell death. As expected, the activity of ODNs targeting the fusion region was restricted to each individual cell line, whereas the activity of all ODNs targeting the common bcl-2 and IgH segments was extended to all t(14;18) cell lines tested. These sense ODNs were not effective in untranslocated cell lines. Antisense-oriented ODNs, complementary to the bcl-2-IgH mRNA, and control ODNs (scrambled, inverted, or mismatched) were biologically ineffective. The selectivity and efficacy of all sense ODNs tested provide support for the development of therapeutic ODNs targeting the bcl-2-IgH antisense transcript expressed in human follicular lymphomas.

A conserved AU-rich element in the 3' untranslated region of bcl-2 mRNA is endowed with a destabilizing function that is involved in bcl-2 down-regulation during apoptosis.

The control of mRNA stability is becoming recognized as a crucial point of gene expression regulation. A common element responsible for mRNA decay modulation is the adenine- and uracil-rich element that is found in the 3' untranslated region of numerous mRNAs subjected to fast expression changes in response to various stimuli. Previously we identified a post-transcriptional regulation level for the antiapoptotic bcl-2 gene, which could be involved in t(14;18) lymphoma-associated bcl-2 overexpression. Here we demonstrate that bcl-2 mRNA is endowed with an adenine- and uracil-rich element (ARE) characterized by high evolutionary conservation not only among all chordates examined, but even between chordates and the nematode Caenorhabditis elegans (ced-9 gene). As for other well-established destabilizing AREs, the insertion of the bcl-2 ARE downstream from stable beta-globin mRNA causes an enhanced decay of the beta-globin transcript, which proves its functional role. This possibility is corroborated by the fact that the pathway leading to the modulating activity of bcl-2 ARE is influenced by PKC, since the addition of DAG and TPA markedly attenuated the bcl-2 ARE destabilizing potential. Conversely, it is noteworthy that when C(2)-ceramide is added to the culture medium as the apoptotic agent, the beta-globin transcript harboring the bcl-2 ARE undergoes a dramatic increase in decay. This observation clearly indicates that the destabilizing function of bcl-2 ARE is enhanced by apoptotic stimuli and suggests that this element could be involved in a post-transcriptional mechanism of bcl-2 down-regulation during apoptosis. The half-life of the mRNA of bcl-2 in Jurkat cells is prolonged by PKC stimulation and shortened by C(2)-ceramide addition, strongly supporting the view that bcl-2 mRNA stability plays a physiological role in modulating bcl-2 expression, particularly in its down-regulation during apoptosis. Thus, this element becomes a new candidate for mediating those bcl-2 gene expression changes-from apoptosis-associated down-regulation to tumor-associated overexpression-observed thus far that profoundly influence single cell fate and tissue homeostasis.

Aponecrosis: morphological and biochemical exploration of a syncretic process of cell death sharing apoptosis and necrosis.

A rat fibroblastic cell line (rat-1/myc-ERtrade mark) was treated with different concentration of Antimycin A, a metabolic poison that affects mitochondrial respiratory chain complex III. The modes of cell death were analyzed by time-lapse videomicroscopy, in situ end-labeling (ISEL) technique, and ultrastructural analysis. Intracellular ATP levels were also measured in order to detect whether the energetic stores were determinant for the type of cell death. It was found that while apoptosis was the prevalent cell death in the fibroblasts treated with low doses, 100 or 200 microM Antimycin A, a new type of cell demise that shared dynamic, molecular, and morphological features with both apoptosis and necrosis represents the most common cell death when the cells were exposed to high doses, 300 or 400 microM, of the hypoxic stimulus. This new type of cell death has been chimerically termed aponecrosis. The inhibition of caspase 3, an enzyme critical for the apoptotic DNA degradation, caused a clear shift from aponecrosis to necrosis in the cell culture, suggesting that this new type of cell death could account for an incomplete execution of the apoptotic program and the following degeneration in necrosis. After being treated with higher doses, i.e., 1000 microM Antimycin A, almost all of the cells died by true necrosis. The analysis of the cellular energetic stores showed that the levels of ATP were a primary determinant in directing toward active cell death (apoptosis), aponecrosis, or necrosis. We conclude that chemically induced hypoxia produces different types of cell death depending on the intensity of the insult and on the ATP availability of the cell, and that the classic apoptosis and necrosis may represent only two extremes of a continuum of intermediate forms of cell demise.

Quantitation of bcl-2 oncogene in cultured lymphoma/leukemia cell lines and in primary leukemia B-cells by a highly sensitive RT-PCR method.

BACKGROUND: The bcl-2 gene, isolated from the t(14;18) chromosomal translocation breakpoint, is able to prevent apoptotic death induced by various stimuli in different tissues. Therefore bcl-2 oncogene expression could be a key parameter for investigating the molecular mechanisms involved in the apoptosis of normal and neoplastic hematopoietic cells. METHODS: In order to evaluate bcl-2 expression in both follicular B-lymphomas carrying or not carrying the 14;18 translocation and in lymphatic leukemias, we optimized an internal standard-based method of reverse transcriptase-polymerase chain reaction (RT-PCR) for the rapid quantitation of bcl-2 mRNA cellular levels. A simple purification of the reverse transcription products resulted in very high PCR efficiency, so that radioactive labelling of the amplification products was avoided. RESULTS: bcl-2 mRNA levels proved to be higher in t(14;18) than in t(14;18) negative cell lines, and higher in primary leukemia pre-B cells than in early-B cells. Tested for sensitivity by identifying minimal residual t(14;18) B cells expressing the bcl-2/IgH gene, this RT-PCR method was able to detect bcl-2/IgH mRNA from just one t(14;18) positive cell out of ten million t(14;18) negative cells. CONCLUSIONS: The RT-PCR method we optimized appears to be suitable for clinical use in both leukemia/lymphoma characterization and in lymphomatous disease follow-up.

Urokinase-dependent angiogenesis in vitro and diacylglycerol production are blocked by antisense oligonucleotides against the urokinase receptor.

The plasminogen activator system is known to play a crucial role in the angiogenesis process by modulating the adhesive properties of endothelial cells to the extracellular matrix and cell-cell interaction. In the present study, we demonstrated that the urokinase-type plasminogen activator (u-PA) induced neovascular growth in the avascular rabbit cornea and dose-dependently promoted growth, chemotaxis, and matrix invasion of cultured endothelial cells. Interaction between u-PA and its receptor appears to be mandatory for the angiogenic effect of u-PA because monoclonal antibodies anti-u-PA and anti-u-PA receptor (u-PAR) blocked the proangiogenic effects of u-PA at the endothelial cell level. We then assessed the signaling pathway activated in endothelial cells by u-PA. u-PAR activation by u-PA produced de novo synthesis of diacylglycerol (DAG) from glucose by a cytochalasin B-inhibitable mechanism, indicating the involvement of a specific glucose transporter (GLUT). Endothelial cells expressed GLUT2, whose activation was tyrosine kinase-dependent and protein kinase C (PKC)-independent. The increase of glucose uptake led to DAG production, which resulted in PKC activation/translocation. Impairment of u-PAR availability by monoclonal antibodies and by antisense oligonucleotides (aODN) against u-PAR mRNA inhibited glucose uptake, DAG neosynthesis, and PKC activation, resulting in the blockade of endothelial cell proliferation, chemotaxis, and chemoinvasion. These data suggest that u-PAR activation consequent to the binding of u-PA can be regarded as an "angiogenic switch" and disclose the possibility that an anti-u-PAR aODN strategy may efficiently target endothelial cell function to control angiogenesis in vivo.

Apoptosis is associated with modifications of bcl-2 mRNA AU-binding proteins.

The expression of genes requiring finely tuned control is regulated by a posttranscriptional mechanism involving mRNA A + U-rich elements (AREs) cooperating with ARE-binding proteins (AUBPs) in modulation of mRNA stability. We reported previously that an ARE in the bcl-2 mRNA 3'-untranslated region (3'-UTR) had destabilizing activity and was involved in bcl-2 downregulation during apoptosis in vitro. Here we demonstrate that the bcl-2 ARE complexes with a number of specific AUBPs, whose pattern undergoes changes following application of apoptotic stimuli. The caspase inhibitor Z-VAD-fmk strongly attenuates both bcl-2 mRNA decay and bcl-2 AUBP pattern changes elicited by apoptotic stimuli, indicating the involvement of bcl-2 AUBPs in bcl-2 mRNA stability control.