Development of novel treatment options for patients with haemophilia.

UNLABELLED: Treatment of haemophilia has vastly improved over the last years, but many needs are still unmet. Baxter is continuously pursuing the aim to provide new therapeutic options to patients with haemophilia and to their treating physicians. In fact, there are several opportunities to improve existing therapies, e.g., by new indications for existing products, the introduction of new products, and by novel therapeutic approaches other than factor replacement. Among these, Baxter is working on a number of innovations, such as pharmacokinetics-tailored factor VIII prophylaxis, bypassing agent prophylaxis with FEIBA in inhibitor patients, development of a longer acting pegylated recombinant FVIII, a new recombinant factor IX, a new recombinant factor FVIIa, the first recombinant von Willebrand factor, recombinant ADAMTS13 (a disintegrin and metalloproteinase with a thrombospondin type 1 motif, member 13) as well as gene therapy to cure haemophilia B. CONCLUSION: Baxter is truly committed to the benefit for the patient, and therefore engaged in providing a more and more individualized treatment, in increasing efficiency of current products, in developing new products and new approaches with added value.

Failure to demonstrate chemoprevention by the monoterpene perillyl alcohol during early rat hepatocarcinogenesis: a cautionary note.

The monoterpene perillyl alcohol (PA) is being considered as a useful chemopreventive and therapeutic agent against human cancers. However, no data are available on the effects of PA in the first stages of hepatocarcinogenesis. To study such effects, putatively initiated cells and preneoplastic foci in hepatocarcinogenesis were used as a model. Male Wistar rats were treated with a single dose of N:-nitrosomorpholine (NNM). Between days 4 and 91 after NNM, subgroups of rats received either PA (1 g/kg body wt/day) or phenobarbital (PB) (50 mg/kg body wt/day) in the diet. Since PA treatment reduced food intake, one control group was fed ad libitum, while a second control was pair fed between days 4 and 91. In order to enhance any treatment effects, all groups, including the controls, were treated with the potent tumor promoter PB after day 91 until the end of the experiment at day 266. Rats were killed at multiple time points and putatively initiated cells and preneoplastic foci were identified by staining positively for placental glutathione S-transferase (G+). The following results were obtained. (i) A few days after NNM treatment single G+ cells emerged; a considerable portion of which developed into foci. (ii) Treatment with PB resulted in an increase in number and size of G+ foci. (iii) PA treatment failed to reduce the number of G+ cells; it somewhat lowered rates of apoptosis in G+ foci and clearly increased their average size. (iv) Eighty-seven days of PA revealed no protective effect on day 266, but, similar to PB treatment, increased the growth of foci. In conclusion, PA exerted no detectable chemopreventive effect in the early stages of rat hepatocarcinogenesis. It rather exerted a PB-like tumor promoting activity. These data argue against a recommendation of PA as a chemopreventive agent for healthy humans.

Quantitative analysis of tumor initiation in rat liver: role of cell replication and cell death (apoptosis).

The formation and development of initiated cells has been studied at the beginning of hepatocarcinogenesis. Rats received the genotoxic carcinogen N-nitrosomorpholine (NNM); placental glutathione S-transferase was used as a marker of initiated cells (G+ cells). Single G+ cells appeared within 24 h after NNM; their frequency increased steeply for approximately 2 weeks, then decreased and finally remained constant. G+ foci consisting of >/=2 G+ cells appeared successively after the single cells. Histological determination of DNA replication and apoptosis revealed that: the formation of single G+ cells may not depend on DNA replication of precursor cells; single G+ cells showed considerably lower DNA replication than G- normal hepatocytes; from the 2-cell stage onwards G+ foci displayed enhanced DNA replication and apoptosis. Data from histological sections were transformed into the third dimension by a new stereological method which considers the non-spherical shape of many G+ lesions. Rates of division and death of G+ cells and of formation and growth of G+ foci were estimated by a stochastic model: initially G+ clones appeared at a rate of 12 000 per day and liver until a maximal number of 176 000 (phase I) was reached; thereafter they declined to 134 000 (phase II); they then remained constant (phase III). Estimated division rates of G+ cells decreased from phase I to phase III, while the death rate increased in phase II, when every third G+ clone disappeared. As a result, at day 50 after NNM only 0.3% of G+ single cells had formed a clone containing >/=5 cells. In conclusion, experimental and computed parameters provide direct evidence that hepatocarcinogenesis evolves clonally and that initiated hepatocytes have a selective proliferation advantage, associated with an enhanced potential to undergo apoptosis. Thereby, depending on the conditions, initiated clones expand or become extinct. Extinction may lead to reversion of the biological effects of initiation.

Initiated rat hepatocytes in primary culture: a novel tool to study alterations in growth control during the first stage of carcinogenesis.

To study growth regulation in the beginning of carcinogenesis, we established a novel ex vivo model for co-cultivation of normal and putatively initiated hepatocytes. Rats received the genotoxic hepatocarcinogen N-nitrosomorpholine (NNM). This led to the appearance of hepatocytes expressing placental glutathione S-transferase (G(+) cells). These cells exhibited elevated rates of cell replication and apoptosis, as known from further advanced preneoplasia; G(+) cells were considered initiated. At days 20-22 post-NNM treatment their frequency was maximal (1-2%); approximately 40% were still single and 60% were arranged in mini foci. At this time-point liver cells were isolated by collagenase perfusion and cultivated. G(+) cells, identified by immunostaining of the culture-plates, were present at the same percentage as in vivo, excluding selective loss, enrichment or spontaneous expression of the G(+) phenotype. In untreated cultures G(+) hepatocytes showed significantly higher rates of replicative DNA synthesis than normal G(-) cells. Application of the hepatomitogen cyproterone acetate (CPA) elevated DNA replication preferentially in G(+) cells. Transforming growth factor beta1 (TGF-beta1) suppressed replicative DNA synthesis which was more pronounced in G(+) than in G(-) hepatocytes. Combined treatment with CPA and TGF-beta1 had no effect on G- cells, but considerably inhibited DNA replication in G(+) cells. This suggests that the effects of TGF-beta1 predominated in G(+) hepatocytes. We conclude that putatively initiated G(+) hepatocytes, both in vivo and in culture, exhibit higher basal rates of DNA replication than normal G(-) hepatocytes and an over-response to mitogens and growth inhibitors. Therefore, G(+) cells show (i) nearly identical behaviour in intact liver and in primary culture and (ii) inherent defects in growth control that are principally similar although somewhat less pronounced than in later stages of carcinogenesis. The present ex vivo system thus provides a novel and useful tool to elucidate biological and molecular changes during initiation of carcinogenesis.

Cleavage of poly(ADP-ribose) transferase during p53-independent apoptosis in rat liver after treatment with N-nitrosomorpholine and cyproterone acetate.

The aim of this work was to study the role of the tumor suppressor p53 and of poly(ADP-ribose) transferase (pADPRT) in the control of hepatocyte apoptosis in two different in vivo models, i.e., during the process of tumor initiation by the genotoxin and cytotoxin N-nitrosomorpholine (NNM) and after withdrawal of the hepatomitogen cyproterone acetate (CPA). Treatment with NNM induces apoptosis followed by necrosis and regenerative DNA synthesis. At the first wave of apoptosis 12 h after NNM application, no p53 expression could be detected by immunohistochemical analysis and immunoblotting. However, 24 h after treatment, numerous p53-positive hepatocyte nuclei were detected, whereas hepatocytes in early and later stages of apoptosis were always negative. Simultaneously with the increased p53 levels, p21 protein was induced. This was accompanied by a block in replicative DNA synthesis, as detected by proliferating-cell nuclear antigen immunostaining. Concomitantly with the increase in apoptosis, dramatic degradation of the nuclear enzyme pADPRT was observed, as evidenced by immunoblotting and activity blotting. The decrease in pADPRT enzymatic activity observed 12 h after treatment coincided with the greatest extent of pADPRT cleavage. One prominent cleavage product was 64 kDa, suggesting that granzyme B was involved in pADPRT degradation. In the second in vivo model we used, i.e., withdrawal of treatment with the hepatomitogen CPA, apoptosis of excessive hepatocytes but no necrosis occurs. Again, no induction of p53 expression could be detected in the liver even at the maximum level of apoptosis, whereas a strong correlation between induction of apoptosis and cleavage of pADPRT to a 64-kDa fragment was observed. These results from whole-animal experiments strongly suggest that the induction of apoptosis in rat liver after genotoxic and cytotoxic damage and during regression of hyperplasia is driven by a p53-independent pathway but is accompanied by cleavage of pADPRT.

Apoptosis in the liver and its role in hepatocarcinogenesis.

Apoptosis seems to be the predominant type of active cell death in the liver (type I), while in other tissues cells may die via biochemically and morphologically different pathways (type II, type III). Active cell death is under the control of growth factors and death signals. In the liver, endogenous factors, such as transforming growth factor beta 1 (TGF-beta 1), activin A, CD95 ligand, and tumor necrosis factor (TNF) may be involved in induction of apoptosis. Release and action of these death factors seems to be triggered by exogenous signals such as withdrawal of hepato-mitogens, food restriction, etc. During stages of hepatocarcinogenesis, not only DNA synthesis but also apoptosis gradually increase from normal to preneoplastic to adenoma and carcinoma tissue. Also, in human carcinomas, birth and death rates of cells are several times higher than in surrounding liver. (Pre)neoplastic liver cells are more susceptible than normal hepatocytes to stimulation of cell replication and of cell death. Consequently, tumor promoters may act as survival factors, i.e., inhibit apoptosis preferentially in preneoplastic and even in malignant liver cells, thereby stimulating selective growth of (pre)neoplastic lesions. On the other hand, regimens favoring apoptosis and lowering cell replication may result in selective elimination of (pre)neoplastic cell clones from the liver. Finally, we have studied the first stage of carcinogenesis, namely the appearance of putatively initiated cells after a single dose of the genotoxic carcinogen N-nitrosomorpholine (NNM). Most of these cells were found to be eliminated by apoptosis, suggesting that initiation, at the organ level, can be reversed at least partially by preferential elimination of initiated cells. These events may be regulated by autocrine or paracrine actions of survival factors.