Luigi Fiume

The asialoglycoprotein receptor in human hepatocellular carcinomas: its expression on proliferating cells

SummaryThe expression of the asialoglycoprotein receptor (ASGP-R) on human hepatocellular carcinoma (HCC) cells might be exploited to reduce the extrahepatic toxicity of DNA synthesis inhibitors by their conjugation with galactosyl-terminating peptides. In the present study we first assessed the frequency of ASGP-R expression in 60 HCCs. Secondly, we investigated whether the receptor was maintained on the plasma membranes of DNA synthesizing cancer cells. Needle biopsies of HCC were evaluated. Diagnosis and grading of HCC were performed on routine haematoxylin and eosin-stained sections according to Edmondson and Steiner (1953). Thirty-five tumours were grade I and II and were classified as well differentiated, while 25 tumours were grade III and IV and were classified as poorly differentiated. Sections from formalin-fixed, paraffin-embedded samples were incubated, after antigen retrieval, with an anti-ASGP-R monoclonal antibody revealed by secondary biotinylated antibody and streptavidin–biotin–peroxidase–diaminobenzidine reaction. A clear immunolabelling of plasma membranes of HCC cells was observed in 28 out of 35 (80%) well differentiated (grade I and II) and in five out of 25 (20%) poorly differentiated (grade III and IV) HCCs. The presence of the ASGP-R on the surface of DNA synthesizing cancer cells was also investigated after in vitro bromodeoxyuridine (BrdU) labelling of HCC samples by immunohistochemical visualization of both the ASGP-R and incorporated BrdU on the same section. The results obtained clearly demonstrated that DNA synthesizing cancer cells expressed the ASGP-R on their surface. The presence of ASGP-R on cell plasma membrane in the majority of differentiated HCCs and its maintenance on proliferating cells encourages studies in order to restrict the action of the inhibitors of DNA synthesis of HCC cells by their conjugation with galactosyl-terminating carriers internalized through this receptor.

INHIBITION OF HEPATITIS B VIRUS REPLICATION BY VIDARABINE MONOPHOSPHATE CONJUGATED WITH LACTOSAMINATED SERUM ALBUMIN

Vidarabine (ara A) produces severe dose-dependent side-effects. To examine whether its monophosphate ester (ara-AMP) can be effective in the treatment of chronic hepatitis B when given in reduced dosage as a conjugate with lactosaminated human serum albumin (L-HSA), which selectively enters hepatocytes, five patients with chronic type B hepatitis (HBsAg/HBV-DNA positive for at least 2 years) were treated with the conjugate. The daily dose of conjugate given (35 mg/kg) contains 1.5 mg ara-AMP, whereas the usual daily dose of free ara-AMP is 5-10 mg/kg. In three patients HBV-DNA fell to undetectable levels and remained negative in two; in one of them anti-HBe developed. In the other two patients HBV-DNA decreased but was detectable during treatment--one received three cycles of therapy, and became HBV-DNA negative and anti-HBe positive 45 days after the end of treatment; the other remained HBeAg/HBV-DNA positive. No adverse effects were observed, and biochemical variables (including aminotransferases) remained unchanged or decreased with viraemia. No antibodies (IgM and IgG classes) that bound the conjugate were detected. Thus L-HSA-ara-AMP inhibits HBV replication as well as free ara-AMP but at a third to a sixth of the dose.

Galloflavin (CAS 568-80-9): A Novel Inhibitor of Lactate Dehydrogenase

One of the most prominent alterations in cancer cells is their strict dependence on the glycolytic pathway for ATP generation. This observation led to the evaluation of glycolysis inhibitors as potential anticancer agents. The inhibition of lactate dehydrogenase (LDH) is a promising way to inhibit tumor cell glucose metabolism without affecting the energetic balance of normal tissues. However, the success of this approach depends chiefly on the availability of inhibitors that display good selectivity. We identified a compound (galloflavin, CAS 568‐80‐9) which, in contrast to other inhibitors of human LDH, hinders both the A and B isoforms of the enzyme. To determine the mechanism of action, we collected LDH‐A and ‐B inhibition data in competition reactions with pyruvate or NADH and evaluated the results using software for enzyme kinetics analysis. We found that galloflavin inhibits both human LDH isoforms by preferentially binding the free enzyme, without competing with the substrate or cofactor. The calculated Ki values for pyruvate were 5.46 μM (LDH‐A) and 15.06 μM (LDH‐B). In cultured tumor cells, galloflavin blocked aerobic glycolysis at micromolar concentrations, did not interfere with cell respiration, and induced cell death by triggering apoptosis. To our knowledge, the inhibition of LDH is, to date, the only biochemical effect described for galloflavin. Because galloflavin is not commercially available, we also describe herein a procedure for its synthesis and report its first full chemical characterization.

Ribavirin conjugated with lactosaminated poly-L-lysine: selective delivery to the liver and increased antiviral activity in mice with viral hepatitis.

Ribavirin (RIBV) is a useful drug in the treatment of chronic type C hepatitis but displays a toxicity for red blood cells (RBC), which limits its dosage and necessitates withdrawal in some patients. Selective concentration of RIBV in liver should improve therapeutic results. Liver targeting can be achieved by coupling the drug to galactosyl-terminating peptides, which specifically enter hepatocytes. In the present work, we conjugated RIBV to lactosaminated poly-L-lysine (L-Poly(Lys)), a hepatotropic carrier enabling intramuscular (IM) administration of conjugates. The L-Poly(Lys)-RIBV conjugate had a heavy drug load (312-327 microg of RIBV in 1 mg of conjugate) and was very soluble in 0.9% NaCl (200 mg/mL). The conjugate was devoid of acute toxicity in mouse. When incubated with human or mouse blood, it did not release the drug. After IM administration to mice, the conjugate was selectively taken up by the liver, where the drug was released in a pharmacologically active form. This was demonstrated using mice infected with a strain of murine hepatitis virus (MHV) sensitive to RIBV. Coupled RIBV, IM injected, inhibited MHV replication in liver at a daily dose two to three times lower than that of the free drug. In mice IM injected with a conjugate tritiated in the RIBV moiety, the ratios between the levels of radioactivity in liver and RBC were two times higher than in animals injected with free tritiated RIBV. In conclusion, the present results support the possibility that the chemotherapeutic index of RIBV in chronic type C hepatitis can be increased by conjugation with L-Poly(Lys).

Liver targeting of antiviral nucleoside analogues through the asialoglycoprotein receptor.

Summary. In order to reduce the extrahepatic side‐effects of antiviral nucleoside analogues in the treatment of chronic viral hepatitis, these drugs are conjugated with galactosyl‐terminating macromolecules. The conjugates selectively enter hepatocytes after interaction of the carrier galactose residues with the asialoglycoprotein receptor present in large amounts and high affinity only on these cells. Within hepatocytes the conjugates are delivered to lysosomes where enzymes split the bond between the carrier and the drug, allowing the latter to become concentrated in the liver. The validity of this chemotherapeutic strategy has been endorsed by a clinical study. Adenine arabinoside monophosphate (ara‐AMP), conjugated with lactosaminated human serum albumin (L‐HSA) and administered to hepatitis B virus (HBV)‐infected patients for 28 days, exerted an antiviral activity to the same extent as the free drug without producing any clinical side‐effects, including the severe neurotoxicity caused by the free drug. Preclinical studies are now underway with conjugates obtained using lactosaminated poly‐L‐lysine (Lacpoly(Lys)) as the hepatotropic carrier. These new conjugates have some advantages over those prepared with L‐HSA: they can be administered by the intramuscular route; they are obtained entirely by chemical synthesis, thus eliminating the problems involved in the use of haemoderivatives; they have a heavy drug load, which permits administration of smaller quantities of conjugate that are more easily digested in lysosomes; and they enable higher quantities of drug to be introduced into hepatocytes. The results of the experiments with two Lac‐poly(Lys) conjugates, one with ara‐AMP and one with ribavirin, are reported in this review.

Inhibition of lactate dehydrogenase activity as an approach to cancer therapy

In the attempt of developing innovative anticancer treatments, growing interest has recently focused on the peculiar metabolic properties of cancer cells. In this context, LDH, which converts pyruvate to lactate at the end of glycolysis, is emerging as one of the most interesting molecular targets for the development of new inhibitors. In fact, because LDH activity is not needed for pyruvate metabolism through the TCA cycle, inhibitors of this enzyme should spare glucose metabolism of normal non-proliferating cells, which usually completely degrade the glucose molecule to CO2. This review is aimed at summarizing the available data on LDH biology in normal and neoplastic cells, which support the anticancer therapeutic approach based on LDH inhibition. These data encouraged pharmaceutical industries and academic institutions in the search of small-molecule inhibitors and promising candidates have recently been identified. The availability of inhibitors with drug-like properties will allow the evaluation in the near future of the real potential of LDH inhibition in anticancer treatment, also making the identification of the most responsive neoplastic conditions possible.

Galloflavin, a new lactate dehydrogenase inhibitor, induces the death of human breast cancer cells with different glycolytic attitude by affecting distinct signaling pathways.

Galloflavin (GF), a recently identified lactate dehydrogenase inhibitor, hinders the proliferation of cancer cells by blocking glycolysis and ATP production. The aim of the present experiments was to study the effect of this compound on breast cancer cell lines reproducing different pathological subtypes of this tumor: MCF-7 (the well differentiated form), MDA-MB-231 (the aggressive triple negative tumor) and MCF-Tam (a sub-line of MCF-7 with acquired tamoxifen resistance). We observed marked differences in the energetic metabolism of these cell lines. Compared to MCF-7 cells, both MDA-MB-231 and MCF-Tam cells exhibited higher LDH levels and glucose uptake and showed lower capacity of oxygen consumption. In spite of these differences, GF exerted similar growth inhibitory effects. This result was explained by the finding of a constitutively activated stress response in MDA-MB-231 and MCF-Tam cells, which reproduce the poor prognosis tumor forms. As a further proof, different signaling pathways were found to be involved in the antiproliferative action of GF. In MCF-7 cells we observed a down regulation of the ERα-mediated signaling needed for cell survival. On the contrary, in MCF-Tam and MDA-MB-231 cells growth inhibition appeared to be contributed by an oxidative stress condition. The prevalent mechanism of cell death was found to be apoptosis induction. Because of the clinical relevance of breast cancer forms having the triple negative and/or chemoresistant phenotype, our results showing comparable effects of GF even on aggressively growing cells encourage further studies to verify the potential of this compound in improving the chemotherapy of breast cancer.

Selective delivery to the liver of antiviral nucleoside analogs coupled to a high molecular mass lactosaminated poly-l-lysine and administered to mice by intramuscular route

In order to obtain hepatotropic conjugates of antiviral drugs suitable for intramuscular administration, three nucleoside analogs (adenine arabinoside monophosphate, ribavirin and azidothymidine) were coupled to a high molecular mass lactosaminated poly-L-lysine. The conjugates had a high molar ratio drug/conjugate and after intramuscular administration to mice, were selectively taken up by the liver and eliminated by the kidney only in minute quantities. The high molar ratio and low renal elimination are important properties not possessed by conjugates previously prepared by using a small molecular mass lactosaminated poly-L-lysine. The conjugate with adenine arabinoside monophosphate (ara-AMP) was found to be devoid of acute toxicity for mice and in spite of its high molecular dimension (Mn = ca. 72,500) did not induce antibodies in this animal after repeated intramuscular injections. This conjugate could have two advantages over a similar complex of ara-AMP with lactosaminated human albumin currently under clinical trials for the treatment of chronic type B hepatitis which must be injected intravenously: it might provide better patient compliance since it is injectable intramuscularly and could introduce larger amounts of ara-AMP into hepatocytes due to its higher drug/carrier molar ratio.

Targeting of antiviral drugs to the liver using glycoprotein carriers

Abstract In order to improve the efficacy and to reduce the side-effects of antiviral drugs in the treatment of chronic hepatitis B, a lysosomotropic approach through covalent linkage of the drugs to appropriate glycoproteins was adopted. Antiviral nucleoside analogs were coupled to asialofetuin and to lactosaminated albumin (L-SA) (two galactosyl-terminating glycoproteins). The conjugates were selectively taken up by liver cells where they released the drugs in a pharmacologically active form. L-SA conjugates showed the advantage of being non-immunogenic when prepared with homologous albumin and injected intravenously. The majority of the experiments reported in this article were performed employing a conjugate of L-SA with ara-AMP, a drug active against hepatitis B virus (HBV). The results of animal studies warranted a 7-day administration of L-HSA-ara-AMP to patients with chronic hepatitis B. Conjugated ara-AMP was shown to inhibit HBV growth at a dose 3–6 times lower than that of the free drug.

Impairment of Aerobic Glycolysis by Inhibitors of Lactic Dehydrogenase Hinders the Growth of Human Hepatocellular Carcinoma Cell Lines

Background/Aims:By reducing the number of ATP molecules produced via aerobic glycolysis, the inhibition of lactic dehydrogenase (LDH) should hinder the growth of neoplastic cells without damaging the normal cells which do not rely on this metabolic pathway for their energetic needs. Here, we studied the effect of oxamic and tartronic acids, 2 inhibitors of LDH, on aerobic glycolysis and cell replication of HepG2 and PLC/PRF/5 cells, 2 lines from human hepatocellular carcinomas. Methods:Aerobic glycolysis was measured by calculating the amounts of lactic acid formed. The effect on replication was assessed by culturing the cells in both standard conditions and glucose-deprived medium, which was used to shut down aerobic glycolysis. Results: The oxamic and tartronic acids inhibited aerobic glycolysis, impaired the growth of both cell lines and also induced an increased expression of p53-upregulated modulator of apoptosis, a signal of cell death. A strong impairment of cell replication by oxamic acid was only found when the cells were cultured in the presence of glucose, indicating that it was for the most part owing to inhibition of aerobic glycolysis. Conclusions:Inhibition of aerobic glycolysis achieved by blocking LDH could be useful in the treatment of human hepatocellular carcinomas. Without interfering with glucose metabolism in normal cells, it could hinder cell growth by itself and could also enhance the chemotherapeutic index of associated anticancer agents by decreasing the levels of ATP selectively in neoplastic cells.