Isoforms of the neuronal glutamate transporter gene, SLC1A1/EAAC1, negatively modulate glutamate uptake: relevance to obsessive-compulsive disorder.

The SLC1A1 gene, which encodes the neuronal glutamate transporter, EAAC1, has consistently been implicated in obsessive-compulsive disorder (OCD) in genetic studies. Moreover, neuroimaging, biochemical and clinical studies support a role for glutamatergic dysfunction in OCD. Although SLC1A1 is an excellent candidate gene for OCD, little is known about its regulation at the genomic level. Here, we report the identification and characterization of three alternative SLC1A1/EAAC1 mRNAs: a transcript derived from an internal promoter, termed P2 to distinguish it from the transcript generated by the primary promoter (P1), and two alternatively spliced mRNAs: ex2skip, which is missing exon 2, and ex11skip, which is missing exon 11. All isoforms inhibit glutamate uptake from the full-length EAAC1 transporter. Ex2skip and ex11skip also display partial colocalization and interact with the full-length EAAC1 protein. The three isoforms are evolutionarily conserved between human and mouse, and are expressed in brain, kidney and lymphocytes under nonpathological conditions, suggesting that the isoforms are physiological regulators of EAAC1. Moreover, under specific conditions, all SLC1A1 transcripts were differentially expressed in lymphocytes derived from subjects with OCD compared with controls. These initial results reveal the complexity of SLC1A1 regulation and the potential clinical utility of profiling glutamatergic gene expression in OCD and other psychiatric disorders.

Missense mutations of the transforming growth factor beta type II receptor in human head and neck squamous carcinoma cells.

In this study, we report the occurrence of missense mutations of the transforming growth factor beta (TGF beta) type II receptor gene in two human squamous head and neck carcinoma cell lines. Both mutations are G:C-->C:G transversions, which result in the replacement of a glutamic acid by a glutamine, and of an arginine by a proline residue, respectively. Moreover, both are located at highly conserved sites within the serine-threonine kinase domain. One of the mutants appears to be defective in its autophosphorylation as well as in the transphosphorylation of the TGF beta type 1 receptor protein, whereas the second mutant appears to be constitutively activated. These are the first reported naturally occurring nucleotide substitution mutations in the T beta R-11 gene in human head and neck cancer cells, which may explain their resistance to TGF beta 1-mediated cell cycle arrest.

Effects of KS-501, KS-502 and their enantiomers on calmodulin-sensitive enzyme activity and cellular proliferation.

Calmodulin plays an important role in cellular proliferation as part of a signal transduction pathway activated by phospholipase C. Drugs that block the ability of calmodulin to bind to and activate its target enzymes inhibit the growth of a wide variety of malignant cells. To identify more potent and selective inhibitors of this potential target for new drug development, we studied two recently synthesized compounds, KS-501 and KS-502, for their activity against calmodulin-sensitive enzymes and for their ability to block the growth of parental and multidrug-resistant leukemic cells. KS-501 and KS-502 inhibited the activation of a calmodulin-sensitive cyclic nucleotide phosphodiesterase. The mechanism of enzyme inhibition was through interfering with calmodulin activation rather than through a direct effect on the enzyme. KS-501 was more potent than KS-502 and was studied in greater detail. This compound inhibited the activation of calmodulin kinase I and II, but had less effect against cyclic adenosine 3',5'-monophosphate (cyclic AMP)-sensitive kinase. KS-501 was also more effective than KS-502 in inhibiting the growth of sensitive L1210 leukemic lymphocytes. Both compounds were less effective inhibitors of multidrug-resistant L1210 leukemia than of the parental line. These studies identify a new class of calmodulin inhibitor, with selectivity for calmodulin-dependent kinases over cyclic AMP-dependent protein kinase. Since the total synthesis of the KS-compounds has been accomplished, it should now be possible to develop derivatives with greater activity and selectivity.

Effect of anti-calmodulin drugs on the growth and sensitivity of C6 rat glioma cells to bleomycin.

Antipsychotic drugs that bind to and inhibit the action of calmodulin also inhibit cellular proliferation. In addition these drugs are cytotoxic to most malignant cells and can augment the antiproliferative and cytotoxic effects of bleomycin. They are attractive candidates for use against tumors of the central nervous system since they readily pass the blood-brain barrier and accumulate in the brain. To identify more active derivatives, we studied the effect of a series of phenothiazines and a group of related compounds alone or in combination with bleomycin against rat glioblastoma cell lines. C6 cells were grown for 24 hours prior to a 48 hour exposure to anti-psychotic drug alone or to an IC20 concentration of antipsychotic drug with bleomycin. Cells were stained with methylene blue and enumerated spectrophotometrically. Eight phenothiazines were found to augment the effect of bleomycin by > or = 3-fold. These included 1-chlorpromazine (3.8x), chlorpromazine (3.2x), 3-chlorpromazine (3.0x), 4-chlorpromazine (3.4x), thiomethylpromazine (3.3x), didesmethylchlorpromazine (11x), fluphenazine (5.5x) and trifluoperazine (3.2x). Structurally similar compounds also having activity included trans-flupenthixol (6.0x), 2-chloroimipramine (6.0x), desipramine (22x), and penfluridol (24x). There was a direct correlation between the antiproliferative effect of anticalmodulin compounds and the ability of these drugs to inhibit the activation of calmodulin-sensitive phosphodiesterase. However, there was no correlation between the inhibition of calmodulin and the augmentation of the antiproliferative activity of bleomycin. Penfluridol, one of the most active compounds, was chosen for further study. It increased the activity of bleomycin against L1210 leukemic cells by 90-fold and MCF-7 human breast cancer cells by 4-fold. The effect of penfluridol in combination with bleomycin was due to increased cytotoxicity as measured by clonogenic assay.

Terfenadine (Seldane): a new drug for restoring sensitivity to multidrug resistant cancer cells.

In our efforts to identify clinically effective drugs for reversing multidrug resistance (MDR) mediated by P-glycoprotein, we tested terfenadine for anti-MDR activity because it appeared to sensitize a patient to doxorubicin and because it met structural requirements defined for this activity. Terfenadine sensitized MCF-7/ADR human breast cancer cells and L1210/VMDRC.06 murine leukemia cells to doxorubicin. At concentrations < or = 10 microM, terfenadine decreased the IC50 to doxorubicin by up to 25-fold against MCF-7/ADR cells and completely restored sensitivity to L1210/VMDRC.06 cells. The drug had no effect on the sensitive, parental cell lines and enhanced activity of other drugs affected by the MDR phenotype. Terfenadine was as potent as trans-flupenthixol, one of the most active modulators of MDR. The mechanism of action of terfenadine appeared to be due to inhibition of the function of P-glycoprotein since it augmented the accumulation of doxorubicin and inhibited the efflux of rhodamine 123 from MDR lines but had no effect on drug accumulation or efflux in sensitive cells. Terfenadine displaced azidopine from P-glycoprotein, but at concentrations higher than expected based on its overall potency. Since terfenadine is clinically available, has numerous structural derivatives available for study, and has a relatively low toxicity profile, this drug and drugs of its class should be evaluated for future clinical trials.

Cytotoxic activity of 5'-deoxy-5-fluorouridine in cultured human tumors.

The cytotoxic activity of 5'-deoxy-5-fluorouridine (5'-ddFUrd) was established in six cultured human tumor lines: 47-DN and MCF-7 breast carcinomas, MG-63 osteosarcoma, HCT-8 colon carcinoma, Colo-357 pancreatic carcinoma, and HL-60 promyelocytic leukemia. Cells were exposed to a wide range of 5'-dFUrd concentrations (from 0.1 microM to 1.0 mM) for 3, 6, or 24 hrs, and then cloned using standard in vitro clonogenic assays. 5'-dFUrd exhibited its best activity in the 47-DN and MCF-7 breast cell lines and in the MG-63 osteosarcoma line (3-hr LD50 values of 32, 34, and 38 microM, respectively). Less activity was observed in the HCT-8 colon (LD50 = 195 microM) and Colo-357 pancreatic (LD50 = 155 microM) tumor lines, and ver poor activity was noted in the HL-60 leukemia cell line (LD50 = 465 microM). The metabolism of 5'-dFUrd to 5-FU (FUra) and FUra-nucleotides was determined and found to directly correlate with the potency of 5'-FUrd in these cell lines. These results suggest that: (a) there is a marked variation in sensitivity of human cancer cells of different tissue origin to 5'-dFUrd, (b) there is a direct relationship between the sensitivity of human cells to 5'-dFUrd and the ability of the cell to metabolize 5'-dFUrd to FUra, and (c) increasing exposure period of cells to 5'-dFUrd did not markedly alter 5'-dFUrd potency in all human cancer cells examined, with the exception of the 47-DN breast cancer cells.