Herpes simplex virus delivery to orthotopic rectal carcinoma results in an efficient and selective antitumor effect.

Cancer of the rectum poses a complex therapeutic challenge because of its proximity to adjacent organs and anal sphincters. The addition of radiotherapy before surgical resection has been shown to confer good survival rates while preserving sphincter function. Nevertheless, radiation is associated with significant side effects. On the basis of our previous work showing that herpes simplex virus type-1 (HSV-1) preferentially infects human colon cancer, we set out to examine the oncolytic effect of HSV-1 on orthotopic rectal tumors in mice. Two vectors were compared for oncolytic activity, HSV-1(Gbeta) with wild-type replication and an attenuated HSV-1 vector (HSV-G47Delta). Intratumoral injection of HSV-1(Gbeta) and HSV-G47Delta resulted in a significant reduction or disappearance of the tumors and increased survival of mice. Although the use of HSV-1(Gbeta) was associated with systemic toxicity, HSV-G47Delta appears to possess a selective oncolytic activity. Moreover, infection with HSV-G47Delta resulted in the activation of the double-stranded RNA-dependent protein kinase (PKR) pathway. A significant improvement in viral replication and the antitumor effect was observed when the PKR inhibitor 2-aminopurine was coadministered with HSV-G47Delta to the tumor. In conclusion, the efficacy of local delivery of HSV-G47Delta combined with a specific chemical inhibitor of antiviral activity points to a novel therapeutic modality for rectal cancer and other solid tumors.

A role for VICKZ proteins in the progression of colorectal carcinomas: regulating lamellipodia formation.

VICKZ proteins are a highly conserved family of RNA binding proteins, implicated in RNA regulatory processes such as intracellular RNA localization, RNA stability, and translational control. During embryogenesis, VICKZ proteins are required for neural crest migration and in adults, the proteins are overexpressed primarily in different cancers. We hypothesized that VICKZ proteins may play a role in cancer cell migration. In patients, VICKZ expression varies with tumour type, with over 60% of colon, lung, and ovarian tumours showing strong expression. In colorectal carcinomas (CRCs), expression is detected at early stages, and the frequency and intensity of staining increase with progression of the disease to lymph node metastases, of which 97% express the protein at high levels. Indeed, in stage II CRC, the level of VICKZ expression in the primary lesion correlates with the degree of lymph node metastasis. In culture, VICKZ proteins rapidly accumulate in processes at the leading edge of PMA-stimulated SW480 CRC cells, where they co-localize with beta-actin mRNA. Two distinct cocktails of shRNAs, each targeting all three VICKZ paralogues, cause a dramatic drop in lamellipodia and ruffle formation in stimulated cells. Thus, VICKZ proteins help to facilitate the dynamic cell surface morphology required for cell motility. We propose that these proteins play an important role in CRC metastasis by shuttling requisite RNAs to the lamellipodia of migrating cells.

Unusual presentation of familial Mediterranean fever: role of genetic diagnosis.

OBJECTIVE: To describe the role of molecular analysis in the diagnosis of an unusual presentation of familial Mediterranean fever (FMF). CASE REPORT: Two patients presenting with prolonged fever without signs and symptoms of serositis are described. FMF was diagnosed by genetic analysis, which disclosed that both patients were homozygous for the M694V mutation of the Mediterranean fever (MEFV) gene. CONCLUSION: Molecular analysis of FMF should complement the investigation of patients with fever of unknown origin. This test enables a definite diagnosis of the disease and may promote the diagnosis and treatment of patients with an unusual or incomplete clinical picture of FMF.

A dynamic balance between ARP-1/COUP-TFII, EAR-3/COUP-TFI, and retinoic acid receptor:retinoid X receptor heterodimers regulates Oct-3/4 expression in embryonal carcinoma cells.

The Oct-3/4 transcription factor is a member of the POU family of transcription factors and, as such, probably plays a crucial role in mammalian embryogenesis and differentiation. It is expressed in the earliest stages of embryogenesis and repressed in subsequent stages. Similarly, Oct-3/4 is expressed in embryonal carcinoma (EC) cells and is repressed in retinoic acid (RA)-differentiated EC cells. Previously we have shown that the Oct-3/4 promoter harbors an RA-responsive element, RAREoct, which functions in EC cells as a binding site for positive regulators of transcription and in RA-differentiated EC cells as a binding site for positive regulators of transcription and in RA-differentiated EC cells as a binding site for negative regulators. Our present results demonstrate that in P19 and RA-treated P19 cells, the orphan receptors ARP-1/COUP-TFII and EAR-3/COUP-TFI repress Oct-3/4 promoter activity through the RAREoct site in a dose-dependent manner. While the N-terminal region of the ARP-1/COUP-TFII receptor is dispensable for this repression, the C-terminal domain harbors the silencing region. Interestingly, three different RA receptor:retinoid X receptor (RAR:RXR) heterodimers, RAR alpha:RXR alpha, RAR beta:RXR alpha, and RAR beta:RXR beta, specifically bind and activate Oct-3/4 promoter through the RAREoct site in a ligand-dependent manner. We have shown that antagonism between ARP-1/COUP-TFII or EAR-3/COUP-TFI and the RAR:RXR heterodimers and their intracellular balance modulate Oct-3/4 expression. Oct-3/4 transcriptional repression by the orphan receptors can be overcome by increasing amounts of RAR:RXR heterodimers. Conversely, activation of Oct-3/4 promoter by RAR:RXR heterodimers was completely abolished by EAR-3/COUP-TFI and by ARP-1/COUP-TFII. The orphan receptors bind the RAREoct site with a much higher affinity than the RAR:RXR heterodimers. This high binding affinity provides ARP-1/COUP-TFII and EAR-3/COUP-TFI with the ability to compete with and even displace RAR:RXR from the RAREoct site and subsequently to actively silence the Oct-3/4 promoter. We have shown that RA treatment of EC cells results in up-regulation of ARP-1/COUP-TFII and EAR-3/COUP-TFI expression. Most interestingly, in RA-treated EC cells, the kinetics of Oct-3/4 repression inversely correlates with the kinetics of ARP-1/COUP-TFII and EAR-3/COUP-TFI activation. These findings are in accordance with the suggestion that these orphan receptors participate in controlling a network of transcription factors, among which Oct-3/4 is included, which may establish the pattern of normal gene expression during development.

Retinoic acid represses Oct-3/4 gene expression through several retinoic acid-responsive elements located in the promoter-enhancer region.

The Oct-3/4 gene product, which belongs to the POU family of transcription factors, is a good candidate for regulating initial differentiation decisions. It is expressed in the earliest stages of embryogenesis and repressed in subsequent stages. Retinoic acid (RA)-induced differentiation of embryonal carcinoma (EC) cells is accompanied by decreased expression of the Oct-3/4 gene. Previous findings show that sequences in the Oct-3/4 enhancer region (designated RARE1) are targets for RA-mediated repression (H. Okazawa, K. Okamoto, F. Ishino, T. Ishino-Kaneko, S. Takeda, Y. Toyoda, M. Muramatsu, and H. Hamada, EMBO J. 10:2997-3005, 1991). Our present results demonstrate conclusively that the TATA-less Oct-3/4 promoter is also a target for RA-induced repression. We identified a novel cis element in the Oct-3/4 promoter harbors a putative Sp1 binding site and a RA-responsive element (designated RAREoct), which are juxtaposed to one another. Protein binding to the Sp1 site is independent of protein binding to the RAREoct sequence. Unlike the RARE1 situated in the Oct-3/4 enhancer which does not contain a typical RAR recognition site, the RAREoct identified in this study consists of three directly repeated motifs that exhibit extensive homology to RARE sequences located in RA-responsive genes. Moreover, the RAREoct shows different DNA-binding characteristics and DNase I footprint patterns with nuclear proteins isolated from undifferentiated versus RA-differentiated EC cells. This suggests that the RAREoct element binds different nuclear proteins in RA-treated and untreated EC cells which most probably belong to the RA receptor, retinoid X receptor, or orphan receptor families of transcription factors. Using site-directed mutagenesis, we show that the RAREoct contributes to the transcriptional activation of Oct-3/4 promoter in P19 cells and, most interestingly, mediates the RA-induced repression in RA-differentiated EC cells. Thus, the RAREoct element could be one of the points of integration of several signalling pathways influencing Oct-3/4 expression. In accordance with the suggestion that suppression of Oct-3/4 expression is a crucial step during embryogenesis, the Oct-3/4 upstream region contains multiple targets for RA-induced repression, probably to ensure accurate and prompt repression of Oct-3/4 expression. It is possible that these repressors are differentially used at specific stages of development in response to various signals.

Extinction of Oct-3/4 gene expression in embryonal carcinoma x fibroblast somatic cell hybrids is accompanied by changes in the methylation status, chromatin structure, and transcriptional activity of the Oct-3/4 upstream region.

In this study we evaluate, for the first time, the molecular mechanism that underlies the extinction of a tissue-specific transcription factor, Oct-3/4, in somatic cell hybrids and compared it with its down-regulation in retinoic acid (RA)-treated embryonal carcinoma (EC) cells. The Oct-3/4 gene, which belongs to the POU family of transcription factors and is abundantly expressed in EC (OTF9-63) cells, provides an excellent model system with which to study the extinction phenomenon. Unlike other genes whose expression has been repressed in hybrid cells but not during in vivo differentiation, Oct-3/4 expression is dramatically repressed in OTF9-63 x fibroblast hybrids and also during embryogenesis. The ectopic expression of Oct-3/4 in hybrid cells under a constitutive promoter is sufficient for transcriptional activation of an octamer-dependent promoter. These results argue against the possibility that fibroblasts contain a direct repressor which binds directly to the octamer sequence and prevents Oct-3/4 protein from binding. The extinction of Oct-3/4 binding activity in the hybrid cells occurs at the level of mRNA transcription, similarly to the repression of Oct-3/4 transcription during in vivo differentiation. This shutdown of Oct-3/4 transcription in hybrid cells and in RA-treated EC cells is accompanied by de novo methylation of its 1.3-kb upstream region. In contrast to EC cells, in which this region is sensitive to MspI digestion, in hybrid cells and in RA-treated EC cells, the Oct-3/4 upstream region is resistant to MspI digestion, which suggests a change in its chromatin structure. Furthermore, extinction is not restricted to the endogenous Oct-3/4 gene but is also exerted upon a transiently transfected reporter gene driven by the Oct-3/4 upstream region. Thus, changes in the cellular activity of trans-acting factors acting on the upstream region also contribute to the inability of the hybrid and RA-treated EC cells to generate Oct-3/4 transcripts. In conclusion, this study draws a connection between the shutdown of Oct-3/4 expression in RA-differentiated EC cells and its extinction in hybrid cells. In both systems, repression of Oct-3/4 expression is achieved through changes in the methylation status, chromatin structure, and transcriptional activity of the Oct-3/4 upstream regulatory region.

Effect of ischemia induced by middle cerebral artery occlusion on superoxide dismutase activity in rat brain.

Acute cerebral ischemia increases the generation of free radicals, causing cell damage, and theoretically may decrease the activity of the scavenging enzyme superoxide dismutase. To investigate the role of superoxide dismutase in cerebral ischemia, we used a model of middle cerebral artery occlusion in rats. In this model an infarct is produced in the pyriform and frontoparietal cortices, extending into the lateral basal ganglia. We measured superoxide dismutase activity by using the xanthine oxidase cytochrome c reduction assay in these areas of rat brains. Tissue samples were analyzed 20 minutes, 2, 6, or 24 hours, or 7 days after middle cerebral artery occlusion and 2 or 24 hours or 7 days after sham operation (n = 8-10 at each time). There was no significant change in superoxide dismutase activity relative to control values in any brain area at any time up to 24 hours after surgery. However, 7 days after middle cerebral artery occlusion a significant decline in superoxide dismutase activity, to 55%-68% (p less than 0.05) of that in unoperated controls, was observed in all brain areas. Our results do not support an important role for changes in the activity of endogenous superoxide dismutase during the acute phase of cerebral ischemia. However, the decrease in superoxide dismutase activity 7 days after ischemia could indicate ongoing additional damage to peri-infarct tissue.

Effect of intrastriatal and intranigral administration of synthetic neuromelanin on the dopaminergic neurotoxicity of MPTP in rodents.

Previous studies showed that the neurotoxin MPTP and its toxic metabolites bind with high affinity to neuromelanin (NM). Therefore, the presence of NM in human and primate but not in rodent substantia nigra, theoretically may be responsible for the species-selective dopaminergic (DA) toxicity of MPTP. We measured DA levels in rodent striatum 7 days after an acute single challenge with MPTP (40 mg/kg, s.c.) given alone or 24 h following unilateral intrastriatal injections of synthetic DA-NM in mice and intrastriatal or intranigral pigment administration in rats. Ipsilateral striatal DA levels were unaffected in control rodents treated with unilateral intrastriatal or intranigral DA-NM. In mice, systemic MPTP produced marked striatal DA depletions which were mildly increased in the striata given prior DA-NM injections. In rats, a species resistant to MPTP, administration of toxin did not affect striatal DA levels. However, after pretreatment with unilateral intrastriatal DA-NM, MPTP induced mild DA falls in ipsilateral striata. By contrast, intranigral administration of DA-NM followed by MPTP, did not alter ipsilateral striatal DA in rats. The findings suggest that intrastriatal DA-NM in mice and rats may augment or initiate, respectively. MPTP-induced damage to sensitive DA-nerve-terminals perhaps by its action as a depot for binding and protracted release and action of the toxin. Lack of effect of intranigral DA-NM which is retained extraneuronally suggests that role of NM in the toxicity of MPTP may depend on its location within DA cell bodies in the nigra.

The neurotoxin MPTP does not affect striatal superoxide dismutase activity in mice.

Intraneuronal superoxide generation may be a possible mechanism of the dopaminergic (DA) neurotoxicity of MPTP. In such case, MPTP might theoretically affect superoxide dismutase (SOD) activity. We determined SOD activity and DA levels in striata of mice at 0.5, 1, 4, 16, 24 h or 7 days after an acute single injection of MPTP (40 mg/kg, s.c.). MPTP produced marked striatal DA depletions from 4 h post-treatment but SOD activity remained unaltered and similar to controls at all time points. Intrastriatal injections of purified SOD 15 min prior to systemic administration of MPTP did not attenuate the MPTP-induced striatal DA depletions in mice at 7 days post-treatment. Combined administration of MPTP with the SOD inhibitor diethyldithiocarbamate markedly enhanced striatal DA decreases produced by MPTP alone. Findings suggest that MPTP does not act via inhibition of SOD. Therefore, potentiation of MPTP toxicity by diethyldithiocarbamate may be due to interference with other enzymatic systems.

Diphenylhydantoin and phenobarbital suppress the dopaminergic neurotoxicity of MPTP in mice.

The combined administration of MPTP with the anticonvulsant drugs diphenylhydantoin or phenobarbital suppressed the MPTP-induced striatal DA depletions in mice. Co-treatment with diazepam, sodium valproate or carbamazepine was ineffective. The mechanism responsible for the protective effect of diphenylhydantoin and phenobarbital against DA neurotoxicity of MPTP is unknown but some previously available findings suggest that they may act, in part, via inhibition of MAO-B and/or DA reuptake in the striatum.