Collagen biosynthesis by human skin fibroblasts. III. The effects of ascorbic acid on procollagen production and prolyl hydroxylase activity.

Human skin fibroblasts were cultured under conditions optimized for collagen synthesis, and the effects of ascorbic acid on procollagen production, proline hydroxylation and the activity of prolyl hydroxylase were examined in cultures. the results indicated that addition of ascorbic acid to confluent monolayer cultures of adult human skin fibroblasts markedly increased the amount of [3H]hydroxyproline synthesized. Ascorbic acid, however, did not increase the synthesis of 3H-labeled collagenous polypeptides assayed independently of hydroxylation of proline residues, nor did it affect the amount of prolyl hydroxylase detectable by an in vitro enzyme assay. Also long-term cultures of the cells or initiation of fibroblast cultures in the presence of ascorbic acid did not lead to an apparent selection of a cell population which might be abnormally responsive to ascorbic acid. Thus, ascorbic acid appears to have one primary action on the synthesis of procollagen by cultured human skin fibroblasts: it is necessary for synthesis of hydroxyproline, and consequently for proper triple helix formation and secretion of procollagen.

Collagen biosynthesis by human skin fibroblasts. I. Optimization of the culture conditions for synthesis of type I and type III procollagens.

Skin fibroblasts in culture can provide a convenient means to study aberrations of collagen metabolism in a variety of clinical conditions. In the present study, the culture conditions for the synthesis of procollagen by cultured human skin fibroblasts were optimized by independently varying parameters in the cell culture environment. To study the synthesis of procollagen the cell cultures were labeled with [3H]proline and the collagenous polypeptides were determined either by measuring the synthesis of hydroxy[3H]proline or by assaying the 3H-labeled proteins digested into dialyzable 3H-labeled peptides by bacterial collagenase. On the basis of the experimental results, the following culture conditions are suggested for optimal synthesis of procollagen: (a) cell culture medium should be supplemented with ascorbic acid (25--50 micrograms/ml) and fetal calf serum (20%); (b) the pH of the culture medium should be kept above 7.2 and preferably in the pH range 7.5--7.8; (c) the cell cultures should be used one to two days after reaching visual confluency. Under these conditions the synthesis and secretion of [3H]procollagen was found to be linear through a 24 h incubation period, and procollagen was demonstrated to be a major gene product of the fibroblasts. The relative synthesis of type I and type III procollagens was also monitored by isolating these genetically distinct procollagens by DEAE-cellulose chromatography or by measuring type I and III collagens by sodium dodecyl sulfate polyacrylamide gel electrophoresis after limited pepsin proteolysis. No marked changes were observed in type I/III procollagen ratios in situations where the total formation of hydroxy[3H]proline was significantly affected. The average coefficient of variance for procollagen synthesis between replicate cultures was found to be relatively small (14%), and the optimization of the culture conditions for the control cells has, therefore, created a reliable and reproducible basis for employing human skin fibroblasts to study collagen metabolism in acquired and inherited diseases.

Collagen biosynthesis by human skin fibroblasts. II. Isolation and further characterization of type I and type III procollagens synthesized in culture.

Human skin fibroblasts in culture have previously been shown to synthesize genetically distinct procollagens type I and type III. In the present study, cultured human skin fibroblasts were incubated under conditions optimized for synthesis of these procollagens in medium containing [3H]proline. The newly synthesized type I and type III 3H-labeled procollagens in the culture medium were then isolated as native proteins by DEAE-cellulose chromatography, or by gel filtration and SDS-polyacrylamide slab gel electrophoresis under denaturing conditons after limited pepsin proteolysis. The chromatographic procedures were optimized to yield reliable and reporducible results with good recoveries. The isolated procollagens were identified by cyanogen bromide peptide mapping and characterized by cleavage with highly purified collagenase synthesized by human skin fibroblasts. Assay of the relative synthesis of type I/III procollagens by normal human skin fibroblasts using DEAE-cellulose chromatography indicated that 80% of the procollagen in the medium was type I while the remaining 20% consisted of type III. When the ratio of newly-synthesized type I/III collagens was estimated by gel filtration or using SDS-polyacrylamide slab gel electrophoresis after limited pepsin proteolysis, relatively fewer type III collagen alpha-chains were recovered. This observation suggests that some of the type of the type III collagen molecules are in a conformation which is less resistant to digestion by pepsin than the triple-helix of type I procollagen. The coefficient of variation for the relative synthesis of type I and type III procollagens by control cultures was relatively small (16%), indicating that the phenotypic expression of type I and type III procollagen genes, under optimized culture conditions, is under a relatively tight control. The results further suggest that the optimized methodology developed for assay of the relative synthesis of type I and type III procollagens and collagens by cultured human skin fibroblasts can be utilized in studies on collagen aberrations in acquired and inherited diseases of connective tissue.

Endothelial cells express insulin-like growth factor-binding proteins 2 to 6.

Cultured endothelial cells have been shown to produce insulin-like growth factor-binding proteins (IGFBPs); however, the identity of these BPs has not been defined. We now demonstrate that cultured bovine endothelial cells produce IGFBP2, IGFBP3, and IGFBP4 and have mRNA specific for IGFBP2, -3, -4, -5 and -6. DNA probes for bovine IGFBP2-6 were obtained by polymerase chain reaction (PCR) amplification of cDNA from bovine large vessel pulmonary artery and aortic endothelial cells as well as omental and periaortic fat microvessel cells, using oligonucleotide primers whose sequences were based on the reported cDNA sequences of IGFBP2-6. The PCR-derived probes were labeled with 32P and used for Northern blot analysis of RNAs obtained from the four bovine endothelial cell types. Transcripts corresponding to IGFBP2-6 were found in RNA from large vessel endothelial cells (bovine pulmonary artery and bovine aorta) and microvessel cells (periaortic and omental fat). The PCR-derived probe for IGFBP4 was used to screen a bovine pulmonary artery cDNA library for a full-length bovine IGFBP4 cDNA clone. One positive clone, containing a single EcoRI insert of approximately 2.0 kilobases, was selected for further characterization by DNA sequence analysis. This clone contained an open reading frame encoding a 258-amino acid protein that was 97% identical to human IGFBP4, 268 basepairs of 5'-untranslated region, and a longer 1044 basepairs of 3'-untranslated region. IGFBP4 protein was purified from bovine pulmonary artery-conditioned medium, shown to have N-terminal amino acid sequence DEAIHCPPCSEEKLARCR (identical to human IGFBP4) and to be secreted in glycosylated and nonglycosylated forms. Immunoblots further demonstrated that microvessel cells, at early passage, secrete predominantly IGFBP2 and IGFBP3, while large vessel cells, at early and late passages, secrete IGFBP3 and IGFBP4. Thus, cultured bovine endothelial cells synthesize and secrete IGFBP2, IGFBP3, and IGFBP4 and have mRNA encoding IGFBP2-6. The production of specific IGFBPs by endothelial cells raises the interesting possibility that the vascular endothelium contributes to circulating and tissue levels of specific IGFBPs in vivo.

Insulin-like growth factor-binding proteins from vascular endothelial cells: purification, characterization, and intrinsic biological activities.

Insulin-like growth factor (IGF)-binding proteins are produced by several cell types, including vascular endothelial cells. The production of IGF-binding proteins by endothelial cells is of particular interest, since these cells are directly bathed by the circulating IGFs and form the initial barrier to the passage of circulating IGFs from the bloodstream to subendothelial tissues. We have purified IGF-binding proteins from medium conditioned by cultured bovine endothelial cells by sequential passage over Bio-Gel P-60, multiplication-stimulating activity affinity, anion exchange (DEAE cellulose) and/or hydrophobic (phenyl-Sepharose) chromatography. Two peaks of IGF-binding activity were eluted from the phenyl-Sepharose column. After cross-linking, each peak contained two to five protein bands on gels that specifically bound IGF-I and -II with mol wt ranging from about 28-44K. Material in peak 1 bound IGF-I congruent to IGF-II and had no affinity for insulin and proinsulin. Peak 2 IGF-binding proteins bound IGF-II with substantially higher affinity than IGF-I and did not recognize insulin or proinsulin. Peak 1 material from phenyl-Sepharose chromatography was a potent stimulator of both glucose transport and aminoisobutyric acid (AIB) uptake in microvessel endothelial cells, with maximal stimulation of both processes being 300-400% of control values. In contrast, peak 2 material either had no intrinsic bioactivity or was slightly inhibitory or stimulatory, depending on the concentration of peak 2 material that was added. The bioactivity in peak 1 was not due to copurification of other endothelial proteins capable of stimulating glucose and AIB uptake, such as IGF-I/-II, platelet-derived growth factor, and basic fibroblast growth factor, since bioactivity was retained after acid treatment, antibody neutralization, and selective affinity chromatography to deplete these other factors. When peak 1 material was added to IGF-I the bioeffects (glucose and AIB uptake) of IGF and binding proteins were additive, and in some experiments the binding proteins potentiated the effect of IGF on endothelial cells, suggesting that the binding protein-IGF complex may retain the bioactivity of both the binding protein(s) and the IGF.

Insulin-like growth factor binding protein (IGFBP)4 accounts for the connective tissue distribution of endothelial cell IGFBPs perfused through the isolated heart.

Insulin-like growth factor binding protein 4 (IGFBP4) was purified to homogeneity from conditioned media of bovine pulmonary artery endothelial cells and shown to have the N-terminal amino acid sequence DEAIHCPPCS, a sequence unique to IGFBP4. The IGFBP4 was separated into predominantly glycosylated and nonglycosylated fractions, with each fraction separately perfused through isolated, beating rat hearts. Both forms of IGFBP4 crossed the capillary boundary of the heart and distributed primarily in subendothelial connective tissue components with a connective tissue/cardiac muscle distribution ratio of 20:1 for the glycosylated fraction and 27:1 for the nonglycosylated fraction. Perfused IGFBP1, 2, 3, and IGF-I also crossed the capillary boundary but in contrast to IGFBP4, preferentially localized in cardiac muscle with a connective tissue/muscle ratio of approximately 1:3. We conclude that the connective tissue distribution previously reported for IGFBPs in conditioned media of pulmonary artery endothelial cells is due to IGFBP4.

Insulin-like growth factor binding protein production by bovine and human vascular smooth muscle cells: production of insulin-like growth factor binding protein-6 by human smooth muscle.

Insulin-like growth factor binding protein (IGFBP) secretory profiles were determined for vascular smooth muscle cells (VSMC) derived from bovine aorta and human aorta, pulmonary artery, and coronary artery. The bovine cells produced IGFBP-4, IGFBP-3, and an IGFBP-3 protease. IGF-I stimulated messenger RNA (mRNA) and media levels of IGFBP-3. The human cells produced IGFBP-3, IGFBP-4, and IGFBP-3 and IGFBP-4 proteases. The three human cells also produced a 30K IGFBP, shown to be IGFBP-6, based on increased affinity for IGF-II vs. IGF-I, size decrease when treated with O-glycanase, but not N-glycanase, reactivity with IGFBP-6 antiserum, presence of a 1.3-kilobase pair mRNA that hybridized to IGFBP-6 specific complementary DNA, and N-terminal amino acid sequence corresponding to IGFBP-6. In the human cells, IGF-I increased media levels of IGFBP-3 through stimulation of IGFBP-3 mRNA and dissociation of cell bound IGFBP-3, and decreased IGFBP-4 via potentiation of IGFBP-4 proteolysis. Neither the bovine nor the human aorta VSMC produced sufficient IGFBP-2 or IGFBP-2 mRNA to be detected by ligand blot and Northern analysis, as previously reported for porcine and rat aorta smooth muscle cells. The variable expression of IGFBPs and IGFBP proteases by VSMC are likely to contribute to differential vascular reactivity to the IGFs in larger arterial blood vessels.

Distribution of chimeric IGF binding protein (IGFBP)-3 and IGFBP-4 in the rat heart: importance of C-terminal basic region.

IGF binding proteins-3 and -4, whether given in the perfused rat heart or given iv in the intact animal, cross the microvascular endothelium of the heart and distribute in subendothelial tissues. IGF binding protein-3, like IGF-I/II, localizes in cardiac muscle, with lesser concentrations in CT elements. In contrast, IGFBP-4 preferentially localizes in CT. In this study, chimeric IGF binding proteins were prepared in which a basic 20-amino-acid C-terminal region of IGF binding protein-3 was switched with the homologous region of IGF binding protein-4, and vice-versa, to create IGF binding protein-3(4) and IGF binding protein-4(3). Perfused IGF binding protein-3(4) behaved like IGF binding protein-4, localizing in connective tissue elements, whereas IGF binding protein-4(3) now localized in cardiac muscle at concentrations identical to perfused IGF binding protein-3. To determine whether these small mutations altered the affinity of the chimera for cells, the ability of (125)I-IGF binding protein-3(4) and (125)I-IGF binding protein-4(3) to bind to microvascular endothelial cells was determined and compared with IGF binding protein-3. IGF binding protein-3(4) retained 15% of the binding capacity of IGF binding protein-3, whereas IGF binding protein-4(3) bound to microvessel endothelial cells with higher affinity and greater total binding than that of IGF binding protein-3. We conclude that small changes in the C-terminal basic domain of IGF binding protein-3 and the corresponding region of IGF binding protein-4 can alter their affinity for cultured cells and influence their tissue distribution in the rat heart.

Intrinsic bioactivity of insulin-like growth factor-binding proteins from vascular endothelial cells.

Conditioned medium from cultured vascular endothelial cells contains material capable of stimulating acute metabolic processes in endothelial cells. The bioactivity of the conditioned medium is not caused by the copurification of known growth factors produced by the cells, in particular platelet-derived growth factor, basic fibroblast growth factor, or insulin-like growth factor (IGF)-I/II. We now demonstrate that the bioactivity is directly due to an IGF-binding protein(s) (ECBP) and, further, that the bioactive domain of the binding protein differs from the IGF-binding domain. Binding proteins (BPs) from cultured pulmonary artery endothelial cells were purified by sequential passage over sizing, multiplication-stimulating activity affinity, and hydrophobic columns. BP fractions were separated into those with and those without biological activity. The bioactive binding protein(s) was cross-linked with disuccinimidyl suberate to IGF-I or the recombinant IGF analog [1-27,Gly4,38-70]IGF-I (Analog). The IGF-I Analog, by itself, had minimal interaction with the type I IGF receptor in cultured microvessel endothelial cells and no intrinsic bioactivity, but did bind with high affinity to ECBP. All free BP and free IGF-I/Analog were removed from the cross-linked mixture by passage over gel filtration and IGF affinity columns. The cross-linked BP-IGF-I complex did not bind to the type I receptor of cultured endothelial cells, but did stimulate glucose and alpha-aminoisobutyric acid uptake in endothelial cells (approximately 2-fold increase); the magnitude of the response was nearly equal to the effect of ECBP or IGF-I alone. The BP-Analog complex also stimulated glucose and alpha-aminoisobutyric acid uptake, with the magnitude of the response approaching the effect of ECBP alone. The BP-Analog complex also did not react with type I IGF receptors on the cultured endothelial cells. We conclude 1) IGF-BP produced by endothelial cells possess intrinsic biological activity; 2) bioactivity of the BP(s) is retained when the IGF-binding domain of the BP is occupied by IGF-I or an inactive IGF-I analog; and 3) IGF-I bound to the bioactive BP does not react with its receptor and possesses minimal, if any, bioactivity in vitro.

The effects of platelet-derived growth factor in cultured microvessel endothelial cells.

The effects of platelet-derived growth factor (PDGF) on thymidine incorporation into DNA and glucose and neutral amino acid uptake were studied in endothelial cells cultured from macrovessels (bovine aorta and pulmonary artery) and microvessels (bovine fat and mouse brain). Similar to previous studies, PDGF did not bind to macrovessel cells, nor did it influence their metabolic function. In contrast, PDGF bound specifically to the two types of microvessel cell culture and in these cells also stimulated the uptake of glucose and neutral amino acids as well as the incorporation of thymidine into DNA. Stimulatory effects of PDGF occurred at concentrations of 2 ng/ml, with maximal stimulation up to 5-fold of the control value for amino isobutyric acid and glucose uptake and up to 8- to 10-fold for thymidine incorporation. The maximal effects of PDGF were additive to those of insulin-like growth factor, I, a known stimulator of all three metabolic processes in microvessel endothelial cells. The binding of PDGF to the endothelial cells was, in general, equivalent to PDGF binding to human foreskin fibroblasts, both in the magnitude of tracer binding and in the affinity of binding. Similar effects were found with recombinant and platelet-derived PDGF. We conclude that these two cultured microvessel endothelial cells not only produce PDGF-like material, but are capable of binding and responding to PDGF.

Connective tissue growth factor (IGFBP-rP2) expression and regulation in cultured bovine endothelial cells.

Media from large vessel endothelial cells (pulmonary artery, aorta) contained intact connective tissue growth factor (CTGF) and a dominant 19-kDa band. N-terminal analysis of the 19-kDa band showed sequence corresponding to CTGF amino acid 181-190, suggesting that the 19-kDa band represented a proteolytic fragment of CTGF. Intact CTGF was increased by cAMP but not by transforming growth factor-beta (TGFbeta). CTGF messenger RNA (mRNA) was not changed by cAMP nor TGFbeta. In two microvessel endothelial cells, mRNA was found at low levels by PCR and Northern analysis, but no CTGF protein was seen on Western analysis. In the microvessel cells, TGFbeta increased and cAMP did not change CTGF mRNA levels, with neither TGFbeta nor cAMP increasing CTGF protein. The discordance between protein and mRNA levels in large vessel and microvessel endothelial cells was mostly explained by the effects of cAMP and TGFbeta on media proteolytic activity; in large vessel cells, cAMP inhibited degradation of CTGF, whereas in microvessel cells, TGFbeta and cAMP stimulated proteolytic activity against CTGF. We conclude that in large vessel endothelial cells, cAMP increased intact CTGF protein by inhibiting degradation of CTGF, whereas TGFbeta stimulated neither CTGF mRNA nor protein; in microvessel cells, TGFbeta increased CTGF mRNA, while both TGFbeta and cAMP stimulated CTGF degradation.

Insulin differentially alters transcapillary movement of intravascular IGFBP-1, IGFBP-2 and endothelial cell IGF-binding proteins in the rat heart.

Insulin-like growth factor binding-proteins 1 and 2 (IGFBP-1, IGFBP-2) and endothelial cell IGF binding proteins (ECBP) were individually perfused through isolated beating rat hearts in the absence and presence of insulin. Insulin caused an increased movement of IGFBP-1 from the vascular space to tissues of the heart. Subendothelial content of IGFBP-1 was 110%, 126% (p less than .01) and 132% (p less than 0.05) of control hearts when perfused with 1, 10 and 100 ng/ml insulin, respectively. . In contrast, insulin treatment was associated with a decrease in ECBP content in cardiac tissue, being 83%, 62% (p less than 0.005) and 73% (p less than 0.05) of control when perfused with 1, 10 and 100 ng/ml insulin. The efflux of IGFBP-2 from the intravascular space was unaffected by insulin. The subendothelial tissue distribution of the transported binding proteins was not changed by insulin perfusion, with IGFBP-1 and IGFBP-2 localizing predominantly in cardiac muscle and ECBP having greater affinity for connective tissue elements. We conclude that in the perfused rat heart, insulin can differentially alter transcapillary movement of IGFBP-1, IGFBP-2 and endothelial cell IGF-binding proteins. Such insulin-facilitated changes could potentially mediate nutrient-dependent transport of IGF-I and IGF-II to peripheral tissues.

Tissue localization of perfused endothelial cell IGF binding protein is markedly altered by association with IGF-I.

Perfused endothelial cell IGF binding proteins (ECBP) have been previously demonstrated to leave the microcirculation of the rat heart and distribute primarily in connective tissue elements of the heart. In the present study, ECBP have been crosslinked to IGF-I and the biologically inactive [1-27,gly4,38-70]-hlGF-I, an analog of IGF-I lacking the type I IGF receptor domain. The crosslinked ECBPs were perfused through the isolated rat heart and their tissue distributions determined. Both [ECBP-Analog] and [ECBP-IGF-I] left the microcirculation of the heart. [ECBP-Analog] preferentially localized in connective tissue elements with a muscle:connective tissue ratio of approximately 1:6, similar to the tissue distribution of perfused ECBP. In contrast, the [ECBP-IGF-I] complexes localized in cardiac muscle with a muscle to connective tissue ratio of approximately 3:1, virtually identical to the tissue distribution of IGF-I when the IGF-I is perfused through the heart in the absence of any binding proteins. We conclude that 1) ECBP in the presence of IGF will cross capillary boundaries and 2) the tissue distribution of [ECBP-IGF-I] is dictated by the IGF-I molecule.

Transcapillary permeability and subendothelial distribution of endothelial and amniotic fluid insulin-like growth factor binding proteins in the rat heart.

Insulin-like growth factor (IGF) binding proteins (IGFBP) were purified from conditioned media of cultured bovine endothelial cells (ECBP) and from human amniotic fluid (IGFBP-1), and then labeled by radioiodination. 125I-ECBP and 125I-IGFBP-1 were perfused through isolated beating rat hearts for 1 and 5 min, and the hearts fixed and analyzed for 125I-BP content and distribution. One to 4% of the perfused 125I-ECBP and 125I-IGFBP-1 crossed the capillary boundary. The ECBPs predominantly localized as intact 125I-BP in connective tissue elements of the heart with less 125I-BP in cardiac muscle. The ratio of 125I-ECBP in connective tissue: muscle (normalized to percent vol of these compartments) was greater than or equal to 10:1. In contrast, the IGFBP-1 had a greater affinity for cardiac muscle with ratios of 125I-IGFBP-1 in connective tissue:muscle of approximately 1:2. When 125I-IGF-I, in the absence of any BPs, was perfused through the hearts approximately 3-5% left the microcirculation and was found in subendothelial tissues. 125I-IGF-I localized primarily to cardiac muscle with a distribution of connective tissue:cardiac muscle of about 1:3. The findings in the isolated perfused heart were confirmed in intact animals. After 125I-IGFBP-1 was injected into anesthetized rats and allowed to circulate for 5 min, substantial radioactivity was associated with the heart. As in the isolated heart, the IGFBP-1 preferentially localized to cardiac muscle with a connective tissue:cardiac muscle ratio of 1:3. We conclude that IGFBPs produced by endothelial cells and the IGFBP-1 contained in amniotic fluid can cross the capillary boundaries of the rat heart, and that the ECBPs preferentially localize in connective tissue elements of the myocardium, whereas IGFBP-1 predominantly localizes in cardiac muscle.

Insulin, insulin-like growth factors, and vascular endothelium.

Endothelial cells form the intimal lining of the entire vascular system. The vascular endothelium is continuously and directly bathed by components of the bloodstream and represents the initial fixed anatomical surface with which these components come in contact. In the past decade, the methodologies for studying endothelial cell functions have markedly advanced, enabling direct and detailed study of the vascular endothelium. From such studies, it is now apparent that the vascular endothelium represents an extraordinarily complex network of cells demonstrating a multitude of distinct anatomic, metabolic, and immunologic properties critical to such processes as angiogenesis, atherosclerosis, thrombosis, neoplasia, and a variety of metabolic disorders including homocystinuria and diabetes mellitus. This report will focus on the interactions of insulin and the insulin-like growth factors (IGFs) with vascular endothelium, based on studies with cultured endothelial cells, isolated microvessels, and perfused organ systems. Data will be presented relevant to the following concepts: (1) endothelial cells, in culture and in vivo, have specific receptors for insulin, IGF-I, and IGF-II; (2) insulin, IGF-I, and IGF-II have both distinct and overlapping functions in cultured endothelial cells; (3) cultured endothelial cells process receptor-bound insulin, IGF-I, and IGF-II, by distinct processes; (4) in vivo, capillary endothelial receptors are integrally involved in the transport of intact insulin to subendothelial sites of insulin action; and (5) vascular endothelium has specialized cellular features that are likely to contribute to the unique interactions of endothelial cells with insulin and the IGFs.

Potential antitumor agents. 14. 4-Substituted 2-formylpyridine thiosemicarbazones.

A series of 4-substituted 2-formylpyridine thiosemicarbazones has been synthesized which contain a tertiary N at the 4 position. These materials were obtained by reacting 4-nitro-2-picoline N-oxide, either directly or after conversion to the corresponding 4-chloro derivative, with a variety of secondary amines. Rearrangement of the 4-substituted 2-picoline N-oxides with Ac2O yielded respective methyl acetates, which upon acid hydrolysis, MnO2 oxidation, and reaction with thiosemicarbazide resulted in the desired compounds. An alternate procedure which consisted of reacting 4-chloro-2-formylpyridine ethylene acetal with various amines, followed by hydrolysis and reaction with thiosemicarbazide, was also employed. Introduction of an alkyl group at the 3 position of the pyridine ring of 4-morpholino-2-formylpyridine thiosemicarbazone was achieved by utilizing 2,3-dimethyl-4-nitropyridine N-oxide; this material was converted to the corresponding 4-chloro derivative which was then subjected to nucleophilic substitution. 4-Morpholino-2-formylpyridine thiosemicarbazone was the most active antineoplastic agent of this series in mice bearing Sarcoma 180 ascites cells and was significantly superior to 5-hydroxy-2-formylpyridine thiosemicarbazone in this test system.

Potential antitumor agents. 12. 2-Formyl-4-aminophenylpyridine thiosemicarbazones.

The antitumor agent 2-formyl-4-(m-amino)phenylpyridine thiosemicarbazone (4-APPT) has been synthesized by a new route to give significantly better overall yields than previously reported. 4-Phenyl-2-picoline was formed by methylation o4-phenylpyridine with CH3Li which upon nitration produced a mixture of o-, m-, and p-nitro-substituted derivatives. These isomers were separated by the solubility differences of their hydrochloride or nitrate salts in 10, 27, and 40% yields, respectively. Identification and confirmation of the structure of these isomers were carried out by mmr. Each isomer was individually subjected to a series of reactions to oxidize the 2-CH3 group to the corresponding carboxaldehyde and to reduce the NO2 function to an amino group. These agents were tested for antineoplastic activity in mice bearing Sarcoma 180 ascites cells; while the o- and p-amino-substituted derivatives were inactive, the m-amino-substituted agent (4-APPT) approved to be an extremely potent antineoplastic agent.

Antineoplastic and biochemical properties of arylsulfonylhydrazones of 2-formylpyridine N-oxide.

The structural parameters necessary for the antineoplastic potency of a new class of anticancer agents, arylsulfonylhydrazones of 2-formylpyridine N-oxide, were examined in mice bearing Sarcoma 180 ascites cells. The findings indicated that (a) replacement of the pyridine ring with benzene, quinoline, or isoquinoline resulted in loss of activity (b) movement of the formylhydrazone side chain from the 2 to the 3 or 4 positions of the pyridine N-oxide produced inactive agents (c) the pyridine N-oxide function was essential for anticancer activity, except for 4-substituted derivatives which were active without the N-oxide group, (d) replacement of the SO2 group by CO resulted in complete loss of activity, and (e) a carbon atom could be inserted between the SO2 and aryl ring with retention of anticancer potency. One of the most active members of this series, 1-oxidopyridine-2-carboxaldehyde p-toluenesulfonylhdrazone, exhibited antineoplastic activity against a broad spectrum of transplanted tumors including Sarcoma 180, Hepatoma 129, Ehrlich carcinoma, leukemia L1210, and a subline of Sarcoma 180 resistant to alpha-(N)-heterocyclic carboxaldehyde thiosemicarbazones. This agent caused inhibition of thymidine-3H and uridine-3H incorporation into DNA and RNA, respectively, of Sarcoma 180 ascites cells; protein biosynthesis was relatively insensitive to the action of this compound.

Effect of IGFBP-derived peptides on incorporation of(35)SO(4)into proteoglycans.

18 amino acid peptides from the C-terminal region of IGFBP-3, -5 (P3, P5), increased the incorporation of(35)SO(4)into proteoglycans in endothelial cells with greater stimulation in large vessel than microvessel cells. The homologous region of IGFBP-6 (P6) also stimulated sulfate uptake, but less potently than P3 and P5. P6 variants were synthesized with one or two amino acids changed to the basic amino acid in the equivalent position of P3. The P6 variants with one additional basic amino acid behaved similarly to P6. The P6 mutant with two altered amino acids was equipotent to P3. P3F, a scrambled version of P3 was less effective than P3. P3, P5, P6, P3F and all P6 variants all stimulated glucose uptake, which occurred only in microvessel cells. P1, P2, P4, and equimolar intact IGFBP-3 stimulated neither glucose uptake nor sulfate incorporation. Thus, C-terminal basic portions of IGFBP-3, -5 and -6 alter two specific functions of endothelial cells with sufficient differences to suggest mediation by distinct mechanisms.

Structure-function relationships of insulin-like growth factor binding protein 6 (IGFBP-6) and its chimeras.

Insulin-like growth factor binding protein 6 (IGFBP-6) is a high-affinity IGFBP with substantially greater affinity for insulin-like growth factor-II (IGF-II) than IGF-I. IGFBP-6(3) is a chimera which has a 20 amino acidC -terminal portion of IGFBP-6 switched with the homologous area of IGFBP-3, P3. Unlike IGFBP-4(3), in which the P3 region was exchanged for the homologous region of IGFBP-4 (P4), IGFBP-6(3) does not bind to endothelial cells. Double mutations were made with the P3 region exchanged as well as a second area differing from IGFBP-3 to form IGFBP-6(3)A and IGFBP-6(3)B, by replacing this area with the homologous region of IGFBP-3. Neither [(125)I]IGFBP-6(3)A nor IGFBP-6(3)B specifically bound to endothelial cells. However, each double mutant competed for [(125)I]IGFBP-3 binding to cultured cells. In the perfused heart, transendothelial transport of IGFBP-6 and IGFBP-6(3) was only 25% of similar transendothelial transport of perfused IGFBP-3. We conclude that chimeras of IGFBP-6 and IGFBP-3(6) clearly differ from IGFBP-4(3) in their ability to bind specifically to endothelial cells and in their capacity to undergo transendothelial transportation in the perfused heart.