Genetic inactivation of prohormone convertase (PC1) causes a reduction in cholecystokinin (CCK) levels in the hippocampus, amygdala, pons and medulla in mouse brain that correlates with the degree of colocalization of PC1 and CCK mRNA in these structures in rat brain.

Prohormone convertase (PC1) is found in endocrine cell lines that express cholecystokinin (CCK) mRNA and process pro CCK to biologically active products. Other studies have demonstrated that PC1 may be a one of the enzymes responsible for the endoproteolytic cleavages that occur in pro CCK during its biosynthesis and processing. Prohormone convertase 1 (PC1) has a distribution that is similar to cholecystokinin (CCK) in rat brain. A moderate to high percentage of CCK mRNA-positive neurons express PC1 mRNA. CCK levels were measured in PC1 knockout and control mice to assess the degree to which loss of PC1 changed CCK content. CCK levels were decreased 62% in hippocampus, 53% in amygdala and 57% in pons-medulla in PC1 knockout mice as compared to controls. These results are highly correlated with the colocalization of CCK and PC1. The majority of CCK mRNA-positive neurons in the pyramidal cell layer of the hippocampus express PC1 mRNA and greater than 50% of CCK mRNA-positive neurons in several nuclei of the amygdala also express PC1. These results demonstrate that PC1 is important for CCK processing. PC2 and PC5 are also widely colocalized with CCK. It may be that PC2, PC5 or another non-PC enzyme are able to substitute for PC1 and sustain production of some amidated CCK. Together these enzymes may represent a redundant system to insure the production of CCK.

Neuronal cell lines expressing PC5, but not PC1 or PC2, process Pro-CCK into glycine-extended CCK 12 and 22.

Endocrine tumor cells in culture and in vitro cleavage assays have shown that PC1 and PC2 are capable of processing pro-CCK into smaller, intermediate and final, bioactive forms. Similar studies have shown that PC5 has the ability to process a number of propeptides. Here, we use GT1-7 (mouse hypothalamic) and SK-N-MC and SK-N-SH (human neuroblastoma) tumor cell lines to study the ability of PC5 to process pro-CCK. RT-PCR and Western blot analysis showed that the cells express PC5 mRNA and protein, but not PC1 or PC2. They were engineered to stably overexpress CCK and cell media was analyzed for pro-CCK expression and cleavage of the prohormone. Radioimmunoassays showed that pro-CCK was expressed, but no amidated CCK was detected. Lack of production of amidated CCK may be due to the lack of the appropriate carboxypeptidase and amidating enzymes. Production of glycine-extended CCK processing products was evaluated by treatment of media with carboxypeptidase B followed by analysis with a CCK Gly RIA. Glycine-extended forms of the peptide were found in the media. The predominant forms co-eluted with CCK 12 Gly and CCK 22 Gly on gel filtration chromatography. The results demonstrate that these cell lines which express PC5 and not PC1 or PC2 have the ability to process pro-CCK into intermediate, glycine-extended forms more closely resembling pro-CCK products in intestine than in brain.

Role of tyrosine sulfation and serine phosphorylation in the processing of procholecystokinin to amidated cholecystokinin and its secretion in transfected AtT-20 cells.

Mammalian procholecystokinin (pro-CCK) is known to have three sulfated tyrosine residues, one of which is present in the CCK 8 moiety and two additional residues present in the carboxyl-terminal extension. In the present study, inhibition of tyrosine sulfation by sodium chlorate decreased the secretion of processed CCK 8 in CCK-expressing endocrine cells in culture. It was then demonstrated that when each of these tyrosines individually, as well as all three together, was mutated to phenylalanine and expressed in endocrine cells, CCK was still processed and secreted. However, the amount of CCK secreted varied with the type of mutation. Substitution of Phe to Tyr in CCK 8 reduced the quantity of secreted CCK 8 by 50%, and when all the sulfated Tyr were mutated to Phe the quantity of secreted CCK was reduced by about 70%, similar to what is observed with chlorate treatment. Changing of the putative phosphorylation site serine to alanine does not affect the processing. Serine phosphorylation at this site may play a functional role in regulatory events. Our results demonstrate that tyrosine sulfation alters the amount of secretion but is not an absolute requirement for the processing and secretion of CCK in this cell line. Tyrosine sulfation of CCK may still be important for its solubility, stabilization, and/or functional interaction.

Isolation and characterization of RNA aptamers specific for the hepatitis C virus nonstructural protein 3 protease.

Nonstructural protein 3 (NS3) from hepatitis C virus (HCV) is a serine protease that provides an essential function in maturation of the virus by cleaving the nonstructural regions of the viral polyprotein. The goal of this work was to isolate RNA aptamers that bind specifically to the NS3 protease active site in the truncated polypeptide DeltaNS3. RNA aptamers were selected in vitro by systematic evolution of ligands by exponential enrichment (SELEX). The RNA pool for SELEX had a 30-nucleotide randomized core region. After nine selection cycles, a pool of DeltaNS3-specific RNA aptamers were obtained. This RNA pool included 45 clones that divided into three main classes (G9-I, II and III). These classes include the conserved sequence GA(A/U)UGGGAC. These aptamers bind to DeltaNS3 with a binding constant of about 10 nM and inhibit approximately 90% of the protease activity of DeltaNS3 and MBP-NS3 (full-length of NS3 fused with maltose binding protein). In addition, these aptamers inhibited approximately 70% of the MBP-NS3 protease activity in the presence of the NS4A peptide P41. G9-I aptamer appeared to be a noncompetitive inhibitor for DeltaNS3 with a Ki approximately 100 nM in the presence of P41. These results suggest that the pool of selected aptamers have potential as anti-HCV compounds. Mutational analysis of the G9-I aptamer demonstrated that the sequences required for protease inhibition are in stem I, stem III and loop III of the aptamer. These regions include the conserved sequence GA(A/U)UGGGAC.

PC2 and 7B2 null mice demonstrate that PC2 is essential for normal pro-CCK processing.

Analysis of CCK content in extracts of whole forebrain from PC2 and 7B2 null mouse brain showed a significant decrease relative to wild-type brains. More detailed analysis revealed that CCK 8 amide levels in cerebral cortex and forebrain regions were more decreased than in hypothalamus. CCK 8 content in PC2 null mouse intestines was identical to control. Null mutant brains contained less CCK 8 than wild type and no other forms were seen when analyzed by gel filtration chromatography. No brain area examined was completely devoid of CCK, suggesting that other enzymes can partially compensate for the loss of PC2. This is the first demonstration that any endoprotease is important for CCK processing but also suggest the presence of a redundant system to ensure production of active CCK in the brain.

Lovastatin is a potent inhibitor of cholecystokinin secretion in endocrine tumor cells in culture.

Lovastatin prevents isoprene synthesis thereby affecting the structural organization of proteins involved in protein transport and secretion. Lovastatin at 1 microM decreases CCK 8 secretion by over 50% in WE cells and in CCK 8 expressing AtT20 cells. At 10 microM CCK 8 secretion was inhibited by two thirds and at 100 microM, cytotoxic effects were observed in both cell types. Addition of mevalonate does not restore CCK secretion and stimulation of secretion by forskolin is also partially inhibited. Cellular content of CCK 8 and pro-CCK were not altered in either of these cell lines except at 100 microM lovastatin. Our results clearly demonstrate that lovastatin at 1 microM strongly inhibits CCK 8 secretion at multiple levels while having little or no effect on its synthesis. This effect on secretion may be partly responsible for the adverse gastrointestinal side effects of lovastatin in patients.

Selection of a RNA aptamer that binds to human activated protein C and inhibits its protease function.

A high-affinity RNA aptamer to human activated protein C (APC) was selected from a pool of random sequences using in vitro selection. Activated protein C, a trypsin-like serine protease plays an important role along with thrombin as a regulator in blood clotting cascade. After seven rounds of selection and amplification, a single predominant nucleic acid sequence APC-167, a 167-base oligonucleotide with a random sequence core of 120 bases, was obtained. The selected aptamer did not bind to thrombin or factor Xa and thus demonstrated specificity to APC. Furthermore, this aptamer was a non-competitive inhibitor to the cleavage reaction of a fluorogenic substrate catalyzed by APC. The inhibition constant (Ki) of APC-167 was 83 nM. The 99-base oligonucleotide (APC-99) derived from APC-167 by deleting both primer binding sites, was also found to inhibit APC strongly (Ki = 137 nM). Two stem-loop structures and at least one G x U wobble base pair in the stem were elucidated as important structural motifs for binding.

Isolation of RNA aptamers specific to the NS3 protein of hepatitis C virus from a pool of completely random RNA.

Hepatitis C virus (HCV) is a single-stranded RNA virus and its genome is translated into a single large polyprotein. The viral-encoded NS3 protein possesses protease, nucleoside triphosphatase, and helicase activities. Since these activities appear to be important for viral replication, efforts are being made to identify compounds that might inhibit the enzymatic activities of NS3 and serve as potential anti-HCV agents. We used a genetic selection strategy in vitro to isolate, from a pool of completely random RNA (120 random bases), those RNA aptamers that could bind to NS3. After six cycles of selection and amplification, 14% of the pooled RNAs could bind specifically to the NS3 protein. When the aptamers in the pool (cycle 6) were analyzed for binding and inhibition of the proteolytic activity of NS3 with the NS5A/NS5B peptide as substrate (S1), two aptamers, designated G6-16 and G6-19 RNA, were found to inhibit NS3 in vitro. Kinetic studies of the inhibition revealed that the aptamer G6-16 inhibited the NS3 protease with an inhibitory constant (Ki) of 3 microM. We also analyzed aptamers G6-16 and G6-19 for their action with a longer protein substrate (amino acid region 2203-2506) and found that these aptamers efficiently inhibited the proteolytic activity of NS3. In addition, both G6-16 and G6-19 aptamers were found to inhibit the helicase activity of NS3. Since these aptamers possesses dual inhibitory function for NS3, they could prove to be useful as anti-HCV drug leads.

Expression of highly active recombinant NS3 protease domain of hepatitis C virus in E. coli.

The serine protease domain of HCV comprising amino acids 1027-1218 (deltaNS3) was expressed in E. coli with a His tag at its N-terminal end. The protease was purified to apparent homogeneity by a single step affinity chromatography resulting in high yields (approximately 3 mg/l of cultured cells). The deltaNS3 efficiently cleaves a 17-mer peptide corresponding to the NS5A-NS5B junction with kcat/Km = 160 x 10(-3) min(-1) microM(-1) in the presence of NS4A peptide. Our deltaNS3 represents the minimal domain possessing highly active protease of NS3 constructed so far. The deltaNS3 protein also efficiently processed a longer substrate corresponding to NS5A/5B junction (2203-2506 amino acids) that was synthesized by in vitro transcription and translation system.

Unusual biphasic melting behaviour of Rhodotorula gracilis DNA.

Ultraviolet, fluorescence and CD spectral analysis suggested unusual structural features of Rhodotorula gracilis ATCC 90950 DNA. R. gracilis DNA exhibited 13% hyperchromicity at 260 nm as against 26% shown by calf thymus DNA. The biphasic melting curve, one phase between 88-92 degrees C and the other between 92-97 degrees C, was attributed to different unwinding pattern of R. gracilis DNA as a function of rise in temperature. The binding affinity of ethidium bromide to R. gracilis DNA determined was almost the same as that of calf thymus DNA. Fluorescence spectra with rise in temperature showed decrease in the quanta of fluorescence intensity after transition temperature, suggesting the quenching due to variation in structure. The CD spectra of R. gracilis DNA did not resemble the spectra of any of the known DNA forms and it showed increase in the magnitude of negative band with rise in temperature suggesting a B-C transition. Disruption of intermolecular and higher order structures by sonication and salt concentration did not change this behaviour implicating the influence of sequence and base composition of R. gracilis DNA on thermal melting transition.

Interaction of Co, Mn, Mg and Al with d(GCGTACGC): a spectroscopic study.

Spectroscopic study on the interactions of trace elements Co., Mn, Mg and Al with d(GCGTACGC) indicated the following: Al and Mg did not alter Tm values. Mn enhanced Tm at lower concentration and decreased it at higher concentrations. Interestingly Co at higher concentration elevated the Tm. These studies also showed lower concentrations of Mn displaced EtBr, whereas Al could displace it at higher ionic strength. Mg and Co displaced EtBr fluorescence at moderate concentrations. The binding constant values and CD spectra clearly indicated strong binding of these elements to DNA.

A simple method for isolation of high-molecular-weight DNA from Rhodotorula gracilis.

Unsheared DNA has been isolated from Rhodotorula and Rhodosporidium yeasts using a cell-wall-digesting enzyme preparation from Paecilomyces lilacinus. Pulsed-field gel electrophoresis indicated that at least 11 chromosomes were present in Rhodot. gracilis ATCC 90950. The DNA was amenable to digestion with restriction enzymes.

Alteration of superhelical state of DNA by aluminium (Al).

The effect of aluminium (Al) on the supercoiled state of pUC18 DNA was studied by ethidium bromide fluorescence and agarose gel electrophoresis. Al at physiologically relevant concentrations relaxed the intact supercoiled DNA as well as the topoisomers induced by chloroquine. EDTA prevented the unwinding effect of Al on supercoiled DNA. Al did not alter the mobility of linear DNA in agarose gels. The implications of this finding in neurological disorders are discussed.