Toshie Yoneyama

Decameric GTP Cyclohydrolase I Forms Complexes with Two Pentameric GTP Cyclohydrolase I Feedback Regulatory Proteins in the Presence of Phenylalanine or of a Combination of Tetrahydrobiopterin and GTP

The activity of GTP cyclohydrolase I is inhibited by (6R)-l-erythro-5,6,7,8-tetrahydrobiopterin (BH4) and stimulated by phenylalanine through complex formation with GTP cyclohydrolase I feedback regulatory protein (GFRP). Gel filtration experiments as well as enzyme activity measurements showed that the number of subunits of GFRP in both the inhibitory and stimulatory complexes is equal to that of GTP cyclohydrolase I. Because GFRP is a pentamer and GTP cyclohydrolase I was shown here by cross-linking experiments to be a decamer, the results indicate that two molecules of a pentameric GFRP associate with one molecule of GTP cyclohydrolase I. Gel filtration analysis suggested that the complex has a radius of gyration similar to that of the enzyme itself. These observations support our model that one molecule of GFRP binds to each of the two outer faces of the torus-shaped GTP cyclohydrolase I. For formation of the inhibitory protein complex, both BH4 and GTP were required; the median effective concentrations of BH4 and GTP were 2 and 26 μm, respectively. BH4 was the most potent of biopterins with different oxidative states. Among GTP analogues, dGTP as well as guanosine 5′-O-(3′-thiotriphosphate) exhibited similar inducibility compared with GTP, whereas other nucleotide triphosphates had no effect. On the other hand, phenylalanine alone was enough for formation of the stimulatory protein complex, and positive cooperativity was found for the phenylalanine-induced protein complex formation. Phenylalanine was the most potent of the aromatic amino acids.

Vascular inducible nitric oxide synthase gene therapy: Requirement for guanosine triphosphate cyclohydrolase I

BACKGROUND Human inducible nitric oxide synthase (iNOS) gene transfer inhibits myointimal hyperplasia in vitro. However, unstimulated vascular smooth muscle cells (SMC) do not synthesize tetrahydrobiopterin (BH4), an essential cofactor for iNOS, which may be an obstacle to successful vascular iNOS gene therapy. We investigated the capacity of gene transfer of guanosine triphosphate (GTP) cyclohydrolase I (GTPCH), the rate-limiting enzyme for BH4 biosynthesis, to supply cofactor for iNOS activity. METHODS A human GTPCH expression plasmid (pCIS-GTPCH) was transfected into rat aortic SMC (RAOSMC) and BH4-deficient NIH3T3 cells engineered to stably express human iNOS (3T3-iNOS). GTPCH activity and intracellular biopterins were assessed as a measure of successful transfection, and the capacity of GTPCH to reconstitute iNOS activity was used to determine whether BH4 was made available to the iNOS protein. RESULTS The pCIS-GTPCH-transfected 3T3 cells had demonstrable GTPCH activity as compared with control cells (169.3 +/- 6.6 pmol/hr/mg versus 0, p < 0.001). Intracellular biopterin levels were also increased in transfected 3T3 and SMC (60.6 +/- 2.6 and 101.7 +/- 28.3 pmol/mg, respectively, versus less than 4 in control cells). GTPCH reconstituted near-maximal iNOS activity in 3T3-iNOS cells despite a gene transfer efficiency of less than 1%. GTPCH and iNOS enzymes did not have to coexist in the same cell for the synthesized BH4 to support iNOS activity. CONCLUSION GTPCH gene transfer reconstitutes iNOS activity in BH4-deficient cells despite poor transfer efficiency. GTPCH can deliver a cofactor to targeted cells even if it is synthesized in neighboring cells, and may be a means to concurrently deliver BH4 with iNOS in vivo.

Optimization of ex vivo inducible nitric oxide synthase gene transfer to vein grafts.

BACKGROUND Vein graft failure as the result of intimal hyperplasia (IH) remains a significant clinical problem. Ex vivo modification of vein grafts using gene therapy is an attractive approach to attenuate IH. Gene transfer of the inducible nitric oxide synthase (iNOS) gene effectively reduces IH. However, iNOS activity after gene transfer may be impaired by the availability of cofactor, such as tetrahydrobiopterin (BH4). The purpose of this study is to determine the optimal conditions for ex vivo adenoviral-mediated iNOS gene transfer into arterial and venous vessels. METHODS Porcine internal jugular veins and carotid arteries were infected ex vivo with the adenoviral iNOS vector (AdiNOS) and with an adenovirus carrying the cDNA encoding guanosine triphosphate cyclohydrolase I (AdGTPCH), the rate-limiting enzyme for BH4 synthesis. The production of nitrite, cyclic guanosine monophosphate (cGMP), and biopterin were assessed daily. RESULTS Nitric oxide (NO) production after iNOS gene transfer was maximal when vessels were cotransduced with AdGTPCH. NO production in these vessels persisted for more than 10 days. Vein segments generated approximately 2-fold more nitrite, cGMP, and biopterin than arterial segments infected with AdiNOS/AdGTPCH. Submerging vein segments into adenoviral solution resulted in improved gene transfer with greater nitrite and cGMP release compared with infections carried out under pressure intraluminally. Similarly, injury to the vein segments before infection with AdiNOS resulted in less nitrite production. CONCLUSIONS These data demonstrate that AdiNOS can efficiently transduce vein segments ex vivo and that the cotransfer of GTPCH can optimize iNOS enzymatic activity. This cotransfer technique may be used to engineer vein grafts before coronary artery bypass to prevent IH.

COMPETITION FOR TETRAHYDROBIOPTERIN BETWEEN PHENYLALANINE HYDROXYLASE AND NITRIC OXIDE SYNTHASE IN RAT LIVER

Tetrahydrobiopterin (BH4) is an important cofactor for two hepatic enzymes, inducible nitric oxide synthase (iNOS) and phenylalanine hydroxylase (PAH), and competition for BH4 between the two enzymes might limit hepatic iNOS or PAH activity. To test this hypothesis, we determined whether conversion of phenylalanine to tyrosine was modified by changes in NO synthase activity, and conversely whether NO synthesis was limited by the rate of phenylalanine conversion to tyrosine in rat hepatocytes and perfused livers. NO production was decreased only slightly, when flux through PAH was maximized in isolated perfused livers, and in isolated hepatocytes only when BH4 synthesis was inhibited. Increases in NO synthesis did not reduce tyrosine formation from phenylalanine. Phenylalanine markedly increased biopterin synthesis, whereas arginine had no effect. Thus, basal BH4 synthesis appears to be adequate to support iNOS activity, whereas BH4 synthesis is increased to support PAH activity.

Ligand binding to the inhibitory and stimulatory GTP cyclohydrolase I/GTP cyclohydrolase I feedback regulatory protein complexes

GTP cyclohydrolase I feedback regulatory protein (GFRP) mediates feedback inhibition of GTP cyclohydrolase I activity by 6R‐l‐erythro‐5,6,7,8‐tetrahydrobiopterin (BH4), which is an essential cofactor for key enzymes producing catecholamines, serotonin, and nitric oxide as well as phenylalanine hydroxylase. GFRP also mediates feed‐forward stimulation of GTP cyclohydrolase I activity by phenylalanine at subsaturating GTP levels. These ligands, BH4 and phenylalanine, induce complex formation between one molecule of GTP cyclohydrolase I and two molecules of GFRP. Here, we report the analysis of ligand binding using the gel filtration method of Hummel and Dreyer. BH4 binds to the GTP cyclohydrolase I/GFRP complex with a Kd of 4 μM, and phenylalanine binds to the protein complex with a Kd of 94 μM. The binding of BH4 is enhanced by dGTP. The binding stoichiometrics of BH4 and phenylalanine were estimated to be 10 molecules of each per protein complex, in other words, one molecule per subunit of protein, because GTP cyclohydrolase I is a decamer and GFRP is a pentamer. These findings were corroborated by data from equilibrium dialysis experiments. Regarding ligand binding to free proteins, BH4 binds weakly to GTP cyclohydrolase I but not to GFRP, and phenylalanine binds weakly to GFRP but not to GTP cyclohydrolase I. These results suggest that the overall structure of the protein complex contributes to binding of BH4 and phenylalanine but also that each binding site of BH4 and phenylalanine may be primarily composed of residues of GTP cyclohydrolase I and GFRP, respectively.

Sheddase Activity of Tumor Necrosis Factor-α Converting Enzyme Is Increased and Prognostically Valuable in Head and Neck Cancer

Tumor necrosis factor α converting enzyme (TACE) is a sheddase overexpressed in cancers that generates cancer cell growth and survival factors, and is implicated in carcinogenesis and tumor growth. This indicates that TACE could be a potentially important cancer biomarker. Unexpectedly, TACE expression in cancer tissues does not correlate with cancer stage or invasiveness. Although TACE sheddase activity is a more direct and potentially better indicator of TACE biology and might be a better cancer biomarker than TACE expression, it has not been studied in cancer tissues. In the present study, we developed a reliable specific assay for quantification of TACE sheddase activity, investigated TACE activity and TACE protein expression in head and neck cancer (HNC) tissues, and examined the correlation of the results with HNC clinical stages and likelihood to recur. We found that HNC cell lines and tissues contained remarkably higher quantities of TACE activity and TACE protein than normal keratinocytes or oral mucosa. siRNA silencing of TACE resulted in the inhibition of release of the tumorogenic factors amphiregulin and transforming growth factor α, and tumor protective factors tumor necrosis factor receptors from HNC cells. Importantly, TACE activity, but not TACE protein expression, was significantly higher in large, T3/T4, primary tumors relative to small, T1/T2, primary tumors, and especially in primary tumors likely to recur relative to those unlikely to recur. These data show that increased TACE activity in cancer is biologically and clinically relevant, and indicate that TACE activity could be a significant biomarker of cancer prognosis. (Cancer Epidemiol Biomarkers Prev 2009;18(11):2913–22)

ADAM10 Sheddase Activity is a Potential Lung-Cancer Biomarker

Background: Increases in expression of ADAM10 and ADAM17 genes and proteins are inconsistently found in cancer lesions, and are not validated as clinically useful biomarkers. The enzyme-specific proteolytic activities, which are solely mediated by the active mature enzymes, directly reflect enzyme cellular functions and might be superior biomarkers than the enzyme gene or protein expressions, which comprise the inactive proenzymes and active and inactivated mature enzymes. Methods: Using a recent modification of the proteolytic activity matrix analysis (PrAMA) measuring specific enzyme activities in cell and tissue lysates, we examined the specific sheddase activities of ADAM10 (ADAM10sa) and ADAM17 (ADAM17sa) in human non-small cell lung-carcinoma (NSCLC) cell lines, patient primary tumors and blood exosomes, and the noncancerous counterparts. Results: NSCLC cell lines and patient tumors and exosomes consistently showed significant increases of ADAM10sa relative to their normal, inflammatory and/or benign-tumor controls. Additionally, stage IA-IIB NSCLC primary tumors of patients who died of the disease exhibited greater increases of ADAM10sa than those of patients who survived 5 years following diagnosis and surgery. In contrast, NSCLC cell lines and patient tumors and exosomes did not display increases of ADAM17sa. Conclusions: This study is the first to investigate enzyme-specific proteolytic activities as potential cancer biomarkers. It provides a proof-of-concept that ADAM10sa could be a biomarker for NSCLC early detection and outcome prediction. To ascertain that ADAM10sa is a useful cancer biomarker, further robust clinical validation studies are needed.

Modification of proteolytic activity matrix analysis (PrAMA) to measure ADAM10 and ADAM17 sheddase activities in cell and tissue lysates

Increases in expression of ADAM10 and ADAM17 genes and proteins have been evaluated, but not validated as cancer biomarkers. Specific enzyme activities better reflect enzyme cellular functions, and might be better biomarkers than enzyme genes or proteins. However, no high throughput assay is available to test this possibility. Recent studies have developed the high throughput real-time proteolytic activity matrix analysis (PrAMA) that integrates the enzymatic processing of multiple enzyme substrates with mathematical-modeling computation. The original PrAMA measures with significant accuracy the activities of individual metalloproteinases expressed on live cells. To make the biomarker assay usable in clinical practice, we modified PrAMA by testing enzymatic activities in cell and tissue lysates supplemented with broad-spectrum non-MP enzyme inhibitors, and by maximizing the assay specificity using systematic mathematical-modeling analyses. The modified PrAMA accurately measured the absence and decreases of ADAM10 sheddase activity (ADAM10sa) and ADAM17sa in ADAM10-/- and ADAM17-/- mouse embryonic fibroblasts (MEFs), and ADAM10- and ADAM17-siRNA transfected human cancer cells, respectively. It also measured the restoration and inhibition of ADAM10sa in ADAM10-cDNA-transfected ADAM10-/- MEFs and GI254023X-treated human cancer cell and tissue lysates, respectively. Additionally, the modified PrAMA simultaneously quantified with significant accuracy ADAM10sa and ADAM17sa in multiple human tumor specimens, and showed the essential characteristics of a robust high throughput multiplex assay that could be broadly used in biomarker studies. Selectively measuring specific enzyme activities, this new clinically applicable assay is potentially superior to the standard protein- and gene-expression assays that do not distinguish active and inactive enzyme forms.