Identification of an AUUUA-specific messenger RNA binding protein.

An important control point in gene expression is at the level of messenger RNA (mRNA) stability. The mRNAs of certain regulatory cellular proteins such as oncogenes, cytokines, lymphokines, and transcriptional activators are extremely labile. These messages share a common AUUUA pentamer in their 3' untranslated region, which confers cytoplasmic instability. A cytosolic protein was identified that binds specifically to RNA molecules containing four reiterations of the AUUUA structural element. This protein consists of three subunits and binds rapidly to AUUUA-containing RNA. Such protein-RNA complexes are resistant to the actions of denaturing and reducing agents, demonstrating very stable binding. The time course, stability, and specificity of the protein-AUUUA interaction suggests the possibility that the formation of this complex may target susceptible mRNA for rapid cytoplasmic degradation.

The 5'-untranslated region of GM-CSF mRNA suppresses translational repression mediated by the 3' adenosine-uridine-rich element and the poly(A) tail.

Granulocyte-macrophage colony stimulating factor (GM-CSF) mRNA levels are controlled post-transcriptionally by the 3'-untranslated region (UTR) adenosine-uridine-rich element (ARE). In untransformed, resting cells, the ARE targets GM-CSF mRNA for rapid degradation, thereby significantly suppressing protein expression. We used a rabbit reticulocyte lysate (RRL) cell-free system to examine translational regulation of GM-CSF expression. We uncoupled decay rates from rates of translation by programming the RRL with an excess of mRNAs. Capped, full-length, polyadenyl-ated human GM-CSF mRNA (full-length 5'-UTR AUUUA+A90) and an ARE-modified version (full-length 5'-UTR AUGUA+A90) produced identical amounts of protein. When the 5'-UTR was replaced with an irrelevant synthetic leader sequence (syn 5'-UTR), translation of syn 5'-UTR AUUUA+A90 mRNA was suppressed by >20-fold. Mutation of the ARE or removal of the poly(A) tail relieved this inhibition. Thus, in the absence of a native 5'-UTR, the ARE and poly(A) tail act in concert to block GM-CSF mRNA translation. Substitutions of different regions of the native 5'-UTR revealed that the entire sequence was essential in maintaining the highest rates of translation. However, shorter 10-12 nt contiguous 5'-UTR regions supported 50-60% of maximum translation. The 5'-UTR is highly conserved, suggesting similar regulation in multiple species and in these studies was the dominant element regulating GM-CSF mRNA translation, overriding the inhibitory effects of the ARE and the poly(A) tail.

Regulation of eukaryotic messenger RNA turnover.

We have demonstrated the existence of multiple mRNA binding proteins that interact specifically with defined regions in posttranscriptionally regulated mRNAs. These domains appear to be destabilizers whose function can be attenuated by the interaction with the specific binding proteins. Thus, the ability to alter mRNA decay rates on demand, given different environmental or intracellular conditions, appears to be mediated by controlling the localization, activity, and overall function of the cognate binding protein. Based on our limited experience, we predict that most, if not all, of similarly regulated mRNAs will ultimately be found to interact with regulatory mRNA binding proteins. Under conditions whereby the mRNA binding proteins are constitutively active (e.g., tumor cell lines), abnormal mRNA decay will result, with accumulation and overtranslation. Such appears to be the case for cytokines and possibly amyloid protein precursor mRNAs in cancer and Alzheimer's disease, respectively. Conversely, mutagenesis of these critical 3' untranslated region elements will likely have comparable deleterious effects on the regulation of gene expression. To the extent that such derangements exist in human disease, attention to understanding the mechanistic detail at this level may provide insights into the development of appropriate therapeutics or treatment strategies.

Post-transcriptional regulation of the p53 tumor suppressor gene during growth-induction of human peripheral blood mononuclear cells.

Regulation of p53 gene expression at the post-transcriptional level was investigated during growth induction of human peripheral blood mononuclear cells (PBMCs). Freshly isolated PBMCs, which are in the Go phase of the cell cycle, were shown to express low levels of p53 mRNA that was rapidly degraded with a half life of 1 h. The rapid decay of p53 mRNA in quiescent PBMCs was dependent on global protein synthesis as treatment with cycloheximide resulted in stabilization of the p53 message. PBMCs were stimulated to enter the cell cycle by treatment with a combination of the mitogenic lectin phytohemagglutinin (PHA) and phorbol ester (TPA). Progressive stabilization of the p53 message occurred in PBMCs during growth induction. By 24 h of incubation in the presence of PHA and TPA, the half life of p53 mRNA was 6 h and p53 mRNA steady state levels were increased 4.5 to 5.0-fold. p53 protein was not detected in quiescent PBMCs, but was readily detected in PBMCs stimulated for 24 h with PHA and TPA. Stabilization of p53 mRNA was observed in PBMCs treated with either PHA or TPA, but to a lesser degree than when PHA and TPA were used as co-stimulants. These results indicate that differential degradation of p53 messenger RNA occurs in quiescent vs mitogen stimulated PBMCs and suggest that post-transcriptional regulation importantly contributes to increased p53 mRNA steady state levels as PBMCs enter the cell cycle.

Particle-mediated gene transfer of granulocyte-macrophage colony-stimulating factor cDNA to tumor cells: implications for a clinically relevant tumor vaccine.

The necessity for prolonged tissue culture manipulations limits the clinical application of many form of gene therapy in patients with malignancies. We hypothesized that granulocyte-macrophage colony-stimulating factor (GM-CSF) cDNA in a plasmid expression vector could be effectively introduced into resting tumor cells, without the need for tissue culture propagation prior to or following transfection, and that efficient expression of transgenic GM-CSF by the transfected tumor cells would confer an effective immune response against tumors. GM-CSF cDNA in expression vectors was coated onto gold particles and accelerated with a gene gun device into mouse and human tumor cells. Human tumor tissue transfected within 4 hr of surgery produced significant levels of transgenic human GM-CSF protein in vitro. Human GM-CSF was readily detectable in serum and at the injection site following subcutaneous implantation of these transfected tumor cells into nude mice. Transfected and irradiated murine B16 melanoma cells produced > or = 100 ng/ml murine GM-CSF/10(6) cells per 24 hr in vitro for at least 10 days. The antitumor efficacy of this nonviral approach was tested using irradiated B16 tumor cells that were transfected with mGM-CSF cDNA and injected into mice as tumor "vaccine". Subsequent challenge of these mice with nonirradiated, nontransfected B16 tumor cells showed that 58% of the animals wer protected from the tumor by the prior vaccine treatment. In contrast, only 2% of control animals were protected by prior treatment with irradiated B16 cells transfected with the vector containing the luciferase gene. These results suggest that particle-mediated transfection of fresh tumor explants with cytokine cDNA is an effective and clinically attractive approach for cancer therapy.

Minute quantities of granulocyte-macrophage colony-stimulating factor prolong eosinophil survival.

Allergic asthma is characterized by pulmonary infiltration and accumulation of eosinophils, which is enhanced by granulocyte-macrophage colony-stimulating factor (GM-CSF). T cells, fibroblasts, and eosinophils themselves produce GM-CSF, suggesting it functions in the lung microenvironment as a survival factor. However, the amounts and the mechanism by which GM-CSF supports eosinophil survival remain poorly understood. We have previously reported that human peripheral blood eosinophils (PBEo) can be transfected with GM-CSF mRNA using particle-mediated gene transfer (PMGT). Using this technology, GM-CSF mRNA was introduced into resting PBEo, and GM-CSF production and cell survival were assessed. GM-CSF protein was undetectable (< 1 pg/ml) in the supernatant but present intracellularly at very low levels. Unexpectedly, the in vitro survival of transfected PBEo was 4-fold greater than that of controls. Neutralizing anti-GM-CSF but not anti-interleukin-5 (anti-IL-5) antibody added up to 24 h after transfection abolished enhanced survival, demonstrating that the continuous presence of GM-CSF was required. Conditioned medium prepared from transfected PBEo prolonged the survival of naive cells. Comparable survival activity was mimicked by a single dose of 100-500 pg/ml or multiple administrations of 0.1 pg/ml recombinant human GM-CSF (rHuGM-CSF). Survival was completely inhibited by a Jak2 inhibitor, suggesting that GM-CSF-mediated survival involved signaling through the Jak-Stat pathway. Thus, autocrine production of low levels of GM-CSF by a minority of PBEo can block apoptosis of the entire culture by a minute but sustained GM-CSF release.

In vivo particle-mediated cytokine gene transfer into canine oral mucosa and epidermis.

Cytokines can stimulate immune effector cells present within the oral mucosa and epidermis to respond to vaccination or to combat cancer. However, intravenous cytokine delivery is often inefficient and frequently accompanied by systemic toxicity. The goal of this study was to evaluate dogs as a large animal model for gene therapy of cancer because they develop spontaneous oral and epidermal tumors. In this report, we demonstrate that particle-mediated gene transfer of beta-galactosidase, luciferase, interleukin-2, interleukin-6, and granulocyte-macrophage colony stimulating factor (GM-CSF) complementary DNA (cDNA) into the oral mucosa and epidermis of healthy dogs resulted in effective, localized, transgenic protein expression. Additionally, the epidermal sites transfected with GM-CSF developed a profound inflammatory reaction characterized by neutrophilic infiltration. Clinical pathology analyses were unremarkable. These results demonstrate that in vivo particle-mediated gene transfer of canine oral mucosa and epidermis with cytokine cDNA can result in production of biologically active transgenic cytokines with minimal toxicity. These findings have applications to cancer immunotherapy using a gene gun approach.

Flow cytometry measurements of the DNA content of corneal epithelial cells during wound healing.

This study presents the first application of flow cytometry (FCM) techniques to the assessment of cell cycle dynamics in the corneal epithelium after experimental wounding. Anterior keratectomies 6 mm in diameter were created in the central corneas of albino rabbits. The authors sampled the epithelial tissue obtained outside the wound at 12-hr intervals until wound closure at 72 hr. Regenerated epithelium from the surface of the wounded area was collected at 78 hr. The percentages of nuclei in the G0/G1 (growth), S (DNA synthesis), and G2/M (tetraploid/mitosis) phases were determined by FCM. An increase in the percentage of nuclei in the G2/M phase at 36 hr was seen, compared with cell populations in samples from unwounded control corneas. The authors found an increase in mitotic activity in the corneal epithelium during the period of cell migration before wound closure.

EGF cell surface receptor quantitation on ocular cells by an immunocytochemical flow cytometry technique.

A method is presented for the rapid flow cytometric determination of epidermal growth factor (EGF) receptor densities on the surface of cultured ocular cells. The technique uses a biotinylated monoclonal antibody directed against the EGF receptor in conjunction with a streptavidin-bound fluorochrome and requires the specific fluorescence per cell to be measured as a function of ligand and receptor concentration. Because the measurement is noninvasive and restricted to cell surface-bound material, the cells can be kept in a physiologic environment, even at the moment of assay. Calculated receptor densities ranged from 5142/cell (infant human corneal endothelium) to 35,678/cell (infant human keratocytes) to greater than 5 x 10(5)/cell for an A431 control cell line. Species and donor age differences were noted, as was transient receptor downregulation after EGF administration. Flow cytometry represents a valuable time saving procedure for large scale applications while providing the same level of sensitivity as standard radioimmunoassays. This technique is applicable to quantitation of other growth factor cell surface receptors and could greatly expand the use of flow cytometry in the research laboratory.

Zidovudine-induced blockade of the expression and function of the erythropoietin receptor.

Treatment of bone marrow progenitor cells (BMPC) with zidovudine (AZT) at various concentrations (0.5 to 20 microM) in vitro for 24 hr caused a concentration-dependent decrease in erythropoietin (Epo) receptor expression. The decrease in Epo receptors correlated with a decline in mRNA levels of the receptor. These results suggest that AZT-induced down-regulation of Epo receptor expression followed by loss of Epo-receptor mediated signal transduction is a significant contributory factor to AZT-induced erythroid toxicity.

Extracellular-regulated kinase controls beta-amyloid precursor protein mRNA decay.

The precise signaling pathways which contribute to amyloid precursor protein (APP) gene expression remain incompletely characterized. We evaluated the role of protein kinases, calcium and phospholipase C (PLC) in modulating APP mRNA levels. There was a rapid 35-40% reduction in the steady state level of APP mRNA upon stimulation of peripheral blood mononuclear cells (PBMC) with phorbol 12-myristate 13-acetate (PMA), A23187 or ionomycin. However the protein kinase C (PKC), protein kinase A (PKA) or PLC pathways did not mediate these changes in APP mRNA levels. Rather, PMA or ionophore caused a rapid activation of extracellular-regulated kinase (ERK). This effect was independent of PKC and sensitive to U0126. After 4 h of PMA treatment, the remaining APP mRNA became indefinitely stable. We propose a model for the biphasic decay of APP mRNA in which ERK activation by PMA causes sequential upregulation of two APP mRNA binding proteins, nucleolin and hnRNP C. We attribute the initial rapid loss of APP mRNA to the helicase activity associated with nucleolin and later stabilization to hnRNP C binding to the 29 base instability element in the 3'-UTR of APP mRNA.

Human papillomavirus type 18 in conjunctival intraepithelial neoplasia.

Human papillomaviruses are oncogenic viruses that have been found in a variety of epithelial neoplasias. We sought to confirm their presence in conjunctival intraepithelial neoplasia. Five tumors were studied with a polymerase chain-reaction assay designed to detect the E6 region of human papillomavirus types 16 and 18. Human papillomavirus type-16 DNA was found in four of the five tumors, including two tumors that contained both type-16 and type-18 DNA. Viral DNA was not present in the fifth tumor.

AUUUA-specific mRNA binding proteins in astrocytes.

Binding of ribonucleoproteins to specific regions of mRNA can alter mRNA stability. This level of posttranscriptional regulation has been shown to play a major role in gene expression of eukaryotic cells. This process involves the binding of ribonucleoproteins to specific region(s) of unstable, rapidly degrading mRNAs such as those found in various cytokines, lymphokines, and oncogenes, thereby increasing the mRNA's stability. In many instances the instability of the mRNA has been mapped to an AU-rich motif in the 3' untranslated region. We transcribed RNA molecules containing four reiterations of an AUUUA motif, and demonstrated with RNA- band shift experiments that the AUUUA motif complexes with phosphorylated AUUUA-specific 43-47 kDa mRNA binding protein(s) found in the cytosol of both rat brain and cultured rat astrocytes.

Fragile X Syndrome and Alzheimer's Disease: Another story about APP and beta-amyloid.

As the mechanisms underlying neuronal development and degeneration become clarified, a number of common effectors and signaling pathways are becoming apparent. Here we describe the identification of Abeta, long considered a pathologic mediator of Alzheimers Disease and Down Syndrome, as similarly over-expressed in the neurodevelopmental disease, Fragile X Syndrome. We also show that mGluR5 inhibitors, currently employed for the treatment of Fragile X, reduce Abeta production in rodent models of Fragile X and AD as well as reduce disease phenotypes including seizures. Thus seemingly disparate neurologic diseases may share a common pathologic instigator and be treatable with a common, currently available class of therapeutics.

Regulation of mRNA stability in the nervous system and beyond.

The ability to control gene expression is central to normal development and function. For a growing number of genes in the central nervous system and peripheral tissues, expression is determined by changes in the rate of mRNA decay. At a molecular level, regulated interactions between the mRNA target and sequence-specific binding proteins either inhibit or accelerate decay, affording tight control over gene expression. This review discusses several examples of such posttranscriptional gene regulation.

Up-regulation of nucleolin mRNA and protein in peripheral blood mononuclear cells by extracellular-regulated kinase.

The signal transduction pathways regulating nucleolin mRNA and protein production have yet to be elucidated. Peripheral blood mononuclear cells treated with phorbol 12-myristate 13-acetate showed steady state levels of nucleolin mRNA that were 2-2.5-fold greater than untreated control cells. The up-regulation of nucleolin mRNA was substantially repressed by U0126, a specific inhibitor that blocks phosphorylation of extracellular-regulated kinase (ERK). Calcium ionophores and ionomycin also activated ERK and substantially elevated nucleolin mRNA levels, demonstrating phorbol 12-myristate 13-acetate and calcium signaling converge on ERK. Drugs that affected protein kinase C, protein kinase A, and phospholipase C signal transduction pathways did not alter nucleolin mRNA levels significantly. The half-life of nucleolin mRNA increased from 1.8 h in resting cells to 3.2 h with phorbol ester activation, suggesting ERK-mediated posttranscriptional regulation. Concomitantly, full-length nucleolin protein was increased. The higher levels of nucleolin protein were accompanied by increased binding of a 70-kDa nucleolin fragment to the 29-base instability element in the 3'-untranslated region of amyloid precursor protein (APP) mRNA in gel mobility shift assays. Supplementation of rabbit reticulocyte lysate with nucleolin decreased APP mRNA stability and protein production. These data suggest ERK up-regulates nucleolin posttranscriptionally thereby controlling APP production.

A redox switch and phosphorylation are involved in the post-translational up-regulation of the adenosine-uridine binding factor by phorbol ester and ionophore.

Messenger RNAs coding for cytokines and lymphokines are extremely unstable due to an AU-rich cis element located in their 3'-untranslated region. Cell activation with phorbol ester 12-O-tetradecanoylphorbol-13-acetate or calcium ionophore has been shown to markedly stabilize these normally labile messages. We have recently described a cytoplasmic protein, denoted the adenosine-uridine binding factor (AUBF) which complexes in vitro to a variety of labile RNAs containing multiple reiterations of the pentamer AUUUA. In order to determine if AUBF plays a role in the stabilization of cytokine and lymphokine mRNAs, we have investigated the mechanisms which control AUBF activity in peripheral blood mononuclear cells as well as Jurkat cells. AUBF is inactive in resting peripheral blood mononuclear cells but can be activated by brief treatment with 12-O-tetradecanoylphorbol-13-acetate or ionophore. Up-regulation is independent of protein synthesis or RNA transcription, suggesting pre-existing AUBF is subject to post-translational modification. AUBF activity can be reversibly blocked by diamide but irreversibly inhibited by n-ethylmaleimide, suggesting that AUBF contains a redox switch as described for other RNA-binding proteins. Finally, AUBF activity is abolished by potato acid phosphatase, demonstrating that AUBF is a phosphoprotein. These data demonstrate that AUBF activity is subject to at least two levels of post-translational regulation and is enhanced by mitogens previously shown to induce the stabilization of AUUUA mRNAs. Based upon these data, we propose that AUBF binding may mediate 12-O-tetradecanoylphorbol-13-acetate and ionophore-mediated labile message stabilization.