Clearance of dying autophagic cells of different origin by professional and non-professional phagocytes.

MCF-7 cells undergo autophagic death upon tamoxifen treatment. Plated on non-adhesive substratum these cells died by anoikis while inducing autophagy as revealed by monodansylcadaverine staining, elevated light-chain-3 expression and electron microscopy. Both de novo and anoikis-derived autophagic dying cells were engulfed by human macrophages and MCF-7 cells. Inhibition of autophagy by 3-methyladenine abolished engulfment of cells dying through de novo autophagy, but not those dying through anoikis. Blocking exposure of phosphatidylserine (PS) on both dying cell types inhibited phagocytosis by MCF-7 but not by macrophages. Gene expression profiling showed that though both types of phagocytes expressed full repertoire of the PS recognition and signaling pathway, macrophages could evolve during engulfment of de novo autophagic cells the potential of calreticulin-mediated processes as well. Our data suggest that cells dying through autophagy and those committing anoikis with autophagy may engage in overlapping but distinct sets of clearance mechanisms in professional and non-professional phagocytes.

Monitoring, removal and risk assessment of cytostatic drugs in hospital wastewater.

Cytostatic agents are applied in cancer therapy and subsequently excreted into hospital wastewater. As these substances are known to be carcinogenic, mutagenic and toxic for reproduction, they should be removed from wastewater at their source of origin. In this study the fate and effects of the cancerostatic platinum compounds (CPC) cisplatin, carboplatin, oxaliplatin, 5-fluorouracil (5-FU) and the anthracyclines doxorubicin, daunorubicin and epirubicin were investigated in hospital wastewater. Wastewater from the in-patient treatment ward of a hospital in Vienna was collected and monitored for the occurrence of the selected drugs. A calculation model was established to spot the correlation between administered dosage and measured concentrations. To investigate the fate of the selected substances during wastewater treatment, the oncologic wastewater was treated in a pilot membrane bioreactor system (MBR) and in downstream advanced wastewater treatment processes (adsorption to activated carbon and UV-treatment). Genotoxic effects of the oncologic wastewater were assessed before and after wastewater treatment followed by a risk assessment. Monitoring concentrations of the selected cytostatics in the oncologic wastewater were in line with calculated concentrations. Due to different mechanisms (adsorption, biodegradation) in the MBR-system 5 - FU and the anthracyclines were removed < LOD, whereas CPC were removed by 60%. In parallel, genotoxic effects could be reduced significantly by the MBR-system. The risk for humans, the aquatic and terrestrial environment by hospital wastewater containing cytostatic drugs was classified as small in a preliminary risk assessment.

Quantitative structure-activity studies on effects of sixteen different steroids on growth and monooxygenases of rat liver.

Sixteen steroids with different endocrine activities were administered to female rats for 6 or 7 days, in a broad range of doses. Liver growth was recorded by measuring weight and DNA contents and monooxygenase activity by assaying the turnover of five different substrates. According to their effects on these parameters steroids were assigned into one of the following three groups: (a) Estrogens estradiol and ethinylestradiol, as well as the progestins norethynodrel and norethisterone (norethindrone) which have estrogenic activity in rats. These agents induced pronounced liver growth and excessive DNA increase which was not associated with major monooxygenase induction. (b) A different type of response consisted of liver growth and DNA increase associated with a pronounced induction of monooxygenase(s) in a characteristic pattern. This response was elicited by pregnenolone-16 alpha-carbonitril, by progestins progesterone, cyproterone acetate, and medroxyprogesterone (but not gestoden and levonorgestrel), by the antimineralocorticoid spironolactone and by the glucocorticoids cortisol and dexamethasone. Apparently, this response pattern was not related to any specific endocrine action but to certain structural features, in particular to the presence of a saturated, at least two-membered alkyl substituent at C17 of the steroid ring system. (c) No or small effects were observed after gestoden, levonorgestrel and the androgens testosterone and methyltestosterone. Dose-response stuides revealed that estrogens estradiol and EE2 induced hepatic effects more potently by four orders of magnitude than progestins. The response patterns observed may be relevant to the tumor-promoting activity of some of the steroids tested.

DNA synthesis, apoptosis, and phenotypic expression as determinants of growth of altered foci in rat liver during phenobarbital promotion.

Carcinogenesis was initiated in female rat liver by a single dose of N-nitrosomorpholine; subsequently phenobarbital (PB) was administered via the diet at a daily dose of 50 mg/kg body weight for up to 49 weeks. Subgroups of rats were left untreated after 10 or 28 weeks on PB. PB produced the following changes: (a) accelerated appearance of neoplastic nodules and hepatocellular carcinoma (from 28 weeks onwards); (b) phenotypic changes in altered foci such as a shift from clear to eosinophilic appearance, enhanced expression of gamma-glutamyltranspeptidase and other markers, and more distinct borders from surrounding liver; (c) an increase in foci number; and (d) accelerated foci enlargement. The increase in foci number was found to be due to increased phenotypic expression of foci. DNA synthesis was measured by [3H]thymidine labeling at multiple time points. The rate of DNA synthesis was always approximately 10-fold higher in foci than in surrounding liver tissue. Despite this, after N-nitrosomorpholine alone foci grew little before 18-24 weeks. Continuous treatment with PB did not produce a persistent further increase of DNA synthesis in foci, although it accelerated foci growth. Furthermore, at early stages small and larger foci showed similar DNA synthesis activity. These findings indicate that the rate of cell replication as measured by DNA synthesis is not the only determinant of the growth rate of foci. Further studies showed that foci with indistinct borders (reflecting weak expression of the altered phenotype) grew much less than foci with distinct borders; this was at least in part due to an increased rate of cell death by apoptosis found in foci with indistinct borders. In conclusion, besides cell replication, apoptosis and the extent of phenotypic expression (remodeling) determine the growth rate of foci. Foci with weak phenotypic expression predominated after N-nitrosomorpholine alone; in these, a high incidence of apoptosis counterbalanced cell replication. In contrast, during PB treatment foci with strong phenotypic expression predominated; in these, apoptotic activity was lower and the high replicative activity could manifest itself. Finally, all effects of PB on foci were largely although not completely reversible upon cessation of treatment; as a result phenotypic expression declined, and "remodeling" foci with high apoptotic activity predominated again.

Effect of transforming growth factor beta on cell death of cultured rat hepatocytes.

We investigate mechanisms of regression of liver hyperplasia which occurs after induction of growth by hepatomitogens and their subsequent withdrawal. We hypothesized that transforming growth factor beta 1 (TGF-beta 1) might be involved in the control of regression. Therefore we studied the effect of this agent on DNA synthesis and death of hepatocytes cultured in vitro. Both the low basal rate of DNA synthesis of untreated cells and its increase by epidermal growth factor (10 ng/ml) were suppressed by TGF-beta 1 at concentrations higher than 0.01-0.1 ng/ml. At the same range of concentrations of TGF-beta 1, the DNA content of the cultures declined significantly and numerous dead cells could be seen in the monolayer. Time course studies showed that TGF-beta 1 (1 ng/ml) decreased DNA content in the cultures linearly to 41 +/- 7% of controls during a period of 48 h. A similar decrease occurred with vital hepatocytes in hematoxylin and eosin stained monolayers. These changes were accompanied by an extensive release of lactate dehydrogenase which began at 20 h and was 70% of the total lactate dehydrogenase content of the cultures at 40-48 h. Little formation of guanidine hydrochloride resistant bodies and no fragmentation of DNA, indicators of apoptotic cell death, were detected after TGF-beta 1 (1 ng/ml) treatment. Time lapse cinematography revealed an active detachment of the cells from the underlying collagen gel. These studies show that inhibition of DNA synthesis by TGF-beta 1 is associated with enhanced cell death in cultured hepatocytes.

The autophagosomal-lysosomal compartment in programmed cell death.

In the last decade a tremendous progress has been achieved in understanding the control of apoptosis by survival and death factors as well as the molecular mechanisms of preparation and execution of the cell's suicide. However, accumulating evidence suggests that programmed cell death (PCD) is not confined to apoptosis but that cells use different pathways for active self-destruction as reflected by different morphology: condensation prominent, type I or apoptosis; autophagy prominent, type II; etc. Autophagic PCD appears to be a phylogenetically old phenomenon, it may occur in physiological and disease states. Recently, distinct biochemical and molecular features have been be assigned to this type of PCD. However, autophagic and apoptotic PCD should not be considered as mutually exclusive phenomena. Rather, they appear to reflect a high degree of flexibility in a cell's response to changes of environmental conditions, both physiological or pathological. Furthermore, recent data suggest that diverse or relatively unspecific signals such as photodamage or lysosomotropic agents may be mediated by lysosomal cysteine proteases (cathepsins) to caspases and thus, apoptosis. The present paper reviews morphological, functional and biochemical/molecular data suggesting the participation of the autophagosomal-lysosomal compartment in programmed cell death.

Cell death: programmed, apoptosis, necrosis, or other?

There are at least two major types of active or physiological cell death. The most well-known form, apoptosis or Type I, involves early nuclear collapse, condensation of chromatin, generation of nucleosomal ladders, and cell fragmentation with little or no early alteration of lysosomes. It is most commonly seen in cells deriving from highly mitotic lines, and the cells are phagocytosed by neighboring cells or infiltrating macrophages. In metamorphosing or secretory cells, and under conditions where the majority of cells die, the bulk of the cytoplasm is consumed by expansion of the lysosomal system well before nuclear collapse is manifest. This form of cell death has been termed Type II cell death, and we revert to this terminology. The requirement for protein synthesis is more characteristic of Type II cell death in developmental situations than it is for Type I cell death. The variations seen force a reassessment of those aspects of physiological cell death that are truly universal, thereby focusing attention on the biology of the process. A better understanding of the biology and morphology of dying cells will help clarify the significance of the molecular and biochemical findings.

Cell death by apoptosis and its protective role against disease.

The involvement of cell death in control of tissue growth has long been neglected, but the description of apoptosis as cellular 'suicide', the functional opposite of mitosis, is now attracting more attention to this phenomenon. Physiologically unwanted cells are removed by apoptosis, and toxic chemicals and drugs may enhance or inhibit this type of cell death. These findings are providing new insights into the pathophysiology of a variety of diseases, and suggesting new therapeutic strategies.

The role of growth of normal and preneoplastic cell populations for tumor promotion in rat liver.

A number of different compounds, including phenobarbital, hypolipidemic drugs such as clofibrate and nafenopin, the sex steroids progesterone, cyproterone acetate, estradiol and mestranol, chlorinated hydrocarbons such as DDT, hexachlorocyclohexane, and TCDD and the antioxidant butylhydroxytoluene, appears to promote the development of liver tumors from previously induced initiated cells. The mechanisms of tumor promotion by several representative prototypes of these compounds were studied in rat liver in vivo. All liver tumor promoters mentioned above stimulate growth of normal liver. The growth response is due to cellular hypertrophy and/or increased rate of DNA (and cell) replication and/or decreased rate of cell death. Hepatocytes in foci or islands of altered cells (putatively preneoplastic) show higher rates of replication than normal liver cells; various different liver tumor promoters cause a further increase of proliferation of focal cells. The increased proliferative activity is found in different island phenotypes and thus seems to be a useful marker of the putative preneoplastic state. The focal cells respond to several factors limiting proliferation in normal liver, suggesting that they are not autonomous with respect to growth control. Early preneoplastic foci grow slowly without promotion, despite the relatively high rates of cell replication. Thus their cells seem to have a much shorter life-time than normal hepatocytes or to undergo reversion to the normal phenotype. Promoters seem to accelerate island enlargement by increasing cell replication and delaying cell death or remodeling. Thus, tumor promoters enhance the manifestation of the proliferation advantage of the putative initiated cell population. In addition, promoters cause increases in the number of detectable islands. This can partially be explained by enlargement of existing islands, but phenotypic changes that would enhance the probability of detection of remodelling islands and growth of dormant initiated cells, probably contribute to the apparent increase of island number. Putative preneoplastic foci of unknown origin are frequent in the liver of aged Wistar rats. They are morphologically and functionally very similar to those induced by carcinogens and are responsive to the mitogenic effect of tumor promoters. Promotion of these "spontaneous" foci may explain tumor appearance after long-term application of promoters.The findings may provide a basis for improved identification of initiated hepatocytes (and of initiating hepatocarcinogens) and for detection of tumor promoters. All suspected liver tumor promoters tested so far induced enhanced preneoplastic cell proliferation after single doses. The long-term carcinogenicity bioassay as currently performed does not discriminate between initiating and promoting properties of a test compound if the animals used develop spontaneous preneoplastic lesions in the organ affected.

Cell proliferation and apoptosis in normal liver and preneoplastic foci.

The growth rate of tissues including tumors is determined by the difference between cell replication and cell death. Among different types of cell death, apoptosis, a form of programmed cell death, is of particular importance. Nongenotoxic carcinogens exert their carcinogenic effects not only via stimulation of cell replication but also by modulating the incidence of apoptosis. This can be seen at different stages of carcinogenesis: a) After initiation in the liver, many initiated cells may undergo apoptosis and never develop into preneoplastic foci, as suggested by both biological and mathematical studies. Thus, apoptosis appears to determine the efficiency of initiation. b) In the promotion stage, early preneoplastic hepatic foci originate either from treatment with a genotoxic carcinogen or spontaneously exhibit much higher rates of cell replication than normal cells, but nevertheless show little preferential growth. This is due to enhanced rates of apoptosis. Some tumor promoters were found to inhibit apoptosis and thereby accelerate foci growth and carcinogenesis. c) In neoplastic nodules and tumors, apoptosis has been shown to be an important growth determinant and to be regulated by growth regulatory hormones, which thereby may decrease or accelerate tumor growth. Studies on the regulation of apoptosis revealed that in the liver, transforming growth factor TGF-beta 1 is involved in the initiation of apoptosis. This was based on three lines of evidence: TGF-beta 1 induced apoptosis in isolated hepatocytes, b) in vivo hepatocytes undergoing apoptosis showed positive immunostaining with antibodies against a precursor of TGF-beta 1.(ABSTRACT TRUNCATED AT 250 WORDS)

Apoptosis in human colorectal tumours: ultrastructure and quantitative studies on tissue localization and association with bak expression.

Apoptotic cell death in human tumours has been demonstrated by electron and light microscopy. In adenomas, fragmented and apoptotic nuclei and signs of phagocytosis have been observed close to the basement membrane. In carcinomas the characteristic structures were apoptotic bodies with small fragments of chromatin. DNA fragmentation was shown by in situ end-labelling. Quantitative assessment of apoptosis and proliferation revealed a high apoptotic index (AI) in all types of adenoma (tubular: 1.77+/-0.35%, tubulovillous: 2.38+/-0.41%; villous: 3.3+/-0.39%) as well as loss of compartmentalization of proliferating and dying cells. In carcinomas a shift towards proliferation was evident, as shown by lower AIs than in adenomas (0.9+/-0.68% and 1.1+/-0.12% for moderately and poorly differentiated tumours), higher Ki67 indices (38.32+/-2.23% and 57+/-3.89%, respectively) and higher mitosis (0.9+/-0.56% and 1.21+/-0.17%, respectively). However, apoptosis was observed in all tumours and is available as a target for therapeutic intervention. Expression of the apoptosis related proteins bcl-2 and bak also reflected loss of compartmentalization. While bcl-2 did not show a consistent relationship to AI in tumour specimens, bak was positively correlated with apoptosis in 4 of 8 adenomas and 4 of 7 carcinomas, suggesting a role for this protein in the induction of apoptosis in a subset of tumours.

Programmed cell death (PCD). Apoptosis, autophagic PCD, or others?

The occurrence of cell death as a physiological event in multicellular organisms has been known for more than 150 years; in 1972 the term apoptosis was introduced on morphological grounds. However, accumulating evidence suggests that programmed cell death (PCD) is not confined to apoptosis, but that cells use different pathways for active self-destruction as reflected by different morphology: condensation prominent, type I or apoptosis; autophagy prominent, type II; etc. Autophagic PCD appears to be a phylogenetically old phenomenon; it may occur in physiological and disease states. We have studied the relation between morphological and biochemical events during autophagic and apoptotic PCD in human mammary, lymphoblast, and colon cancer cells using electron microscopy and proteom analysis. We find that autophagic cell death (type II) PCD includes degradation of Golgi apparatus, polyribosomes, and endoplasmic reticulum, which precedes nuclear destruction. Intermediate and microfilaments are largely preserved; presumably the cytoskeleton is required for autophagocytosis. Apoptosis (type I) PCD is characterized by condensation of cytoplasm and preservation of organelles; cytoskeletal elements disintegrate in early stages. Either type of PCD involves synthesis of distinct proteins. Finally, both types of PCD share features some of a cell's stress response (e.g., translocation of hsp90). In conclusion our findings support the concept that autophagic cell death is a separate pathway of PCD distinctly different from "classical" apoptosis. However, autophagic and apoptotic PCD should not be considered as mutually exclusive phenomena. Rather, they appear to reflect a high degree of flexibility in a cell's response to changes of environmental conditions, both physiological or pathological.

Role of apoptosis for mouse liver growth regulation and tumor promotion: comparative analysis of mice with high (C3H/He) and low (C57Bl/6J) cancer susceptibility.

Apoptosis constitutes one of the organisms defense lines against cancer. We investigated whether failure of apoptosis may be concurrently causative for the high cancer susceptibility in C3H/He as compared to C57BL/6J mice (low cancer susceptibility). First, in short-term in vivo experiments (7-21 days), mouse liver growth (C3H/He, C57BL/6J) was induced by administration of phenobarbital (PB; 2 days 500 ppm + 5 days 750 ppm via the food) or nafenopin (NAF; 7 days 500 ppm via the food), cessation of PB or NAF treatment served to initiate liver involution. Liver weight, DNA content, hepatocyte ploidy and apoptotic activity were studied as endpoints. Secondly, in a long-term study liver carcinogenesis was initiated by a single dose of N-nitrosodiethylamine (NDEA, 90 mg/kg b.w.) to 5-weeks-old C57Bl/6J and C3H/He mice. After 2 weeks, mice received either standard diet or a diet containing phenobarbital (PB, 90 mg/kg b.w.) for up to 90 weeks. Cell proliferation and apoptosis in normal liver tissue and (pre)neoplastic tissue was quantitatively analysed by histological means. The short term studies revealed that PB and NAF-induced mouse liver growth is essentially due to cell enlargement (hypertrophy). A moderate increase of liver DNA content was brought about by hepatocellular polyploidization; C3H/He mice exhibited the most pronounced ploidy shift, corresponding to their high cancer susceptibility. Upon cessation of PB or NAF treatment, regression of liver mass was neither associated with a loss of DNA nor an increase in apoptoses in the liver of C3H/He and C57Bl/6J mice; food restriction did not enforce the occurrence of apoptosis. Thus, the mouse strains did not differ with respect to the occurrence of apoptosis. In the long-term study, PB promoted liver tumor formation in all strains, exhibiting quantitative differences in growth kinetics of preneoplasia rather than a specific biological quality. Quantitative analysis of apoptosis in normal and (pre)neoplastic liver tissue of C3H/He and C57BL/6J mice revealed no clue to explain their different cancer susceptibility. Rather, cell proliferation seems to be the prevailing determinant of tumor promotion in the liver of both mouse strains.

Role of active cell death (apoptosis) in multi-stage carcinogenesis.

Active cell death is a genetically encoded self-destruction of a cell. There occur morphologically different types of active cell death, e.g. apoptosis in the liver or autophagic cell death in human mammary carcinoma cells after tamoxifen treatment (Pre)neoplastic lesions in rat liver exhibit enhanced rates of apoptosis, which tend to increase with increasing malignancy. Tumor promoters and non-genotoxic carcinogens inhibit active cell death, thereby increasing the accumulation of (pre)neoplastic cells and accelerating the development of cancer. On the other hand promoter withdrawal, fasting or application of negative growth signals such as transforming growth factor beta 1 (TGF beta 1) enhance apoptosis and can lead to selective regression of preneoplastic lesions or tumors.

Programmed cell death and its protective role with particular reference to apoptosis.

Apoptosis is a type of programmed cell death involved in growth control of tissues. It is considered as a cellular suicide functionally opposite to mitosis. It may serve to remove "unwanted" damaged or dangerous, e.g. precancerous, cells. Chemical compounds can interfere with the regulatory network which controls apoptosis and can thereby stimulate or prevent cell death. Both induction or inhibition of apoptosis may result in various diseases such as of the immune system, malformation or tumor development. The protective role of apoptosis against carcinogenesis is described in some detail. Tumor formation seems to occur through several stages, namely initiation, promotion, progression, and involves formation and growth of premalignant cell populations. At least in some model systems initiated cells and premalignant cell populations have been found to exhibit enhanced cell replication, but also enhanced apoptotic activity as compared to the normal tissue. Therefore, initiated cells may be eliminated by apoptosis. Tumor promoters can inhibit apoptosis in putative preneoplastic cells and thereby accelerate tumor development. Furthermore, in hormone-dependent cancers malignant cells may undergo massive apoptosis in response to hormone withdrawal or antihormone treatment. Finally, the regulation of apoptosis will be addressed. Our results suggest that transforming growth factor beta 1, a negative regulator of epithelial tissue growth, is a signal inducing apoptosis of liver cells.

Dose-response and threshold effects in cytotoxicity and apoptosis.

Cell death can occur as an active, programmed event in response to cytotoxic injury or to endogenous growth limiting factors; the latter serve to maintain homeostasis of cell number in tissues. Cells seem to use different pathways for programmed death, as reflected by their different morphology and different biochemistry. Severe cell damage leading to incapacitation of essential cell functions such as ATP synthesis or the maintenance of membrane potential may lead to "necrosis". In any event, the incidence and rate of cell death increase with increasing signal intensity. Cytotoxic injury requires a certain number of primary insults; cell death will therefore occur only beyond a definable threshold. Growth factor control of cell death is receptor-mediated with dose-response relations including threshold phenomena follow the general principles of receptor kinetics. The occurrence of programmed cell death during the stages of carcinogenesis introduces a reversible component into this disease. Therefore, there may exist thresholds of dose or durations of exposure to certain carcinogens below which irreversible disease is not generated.

Apoptosis and multistage carcinogenesis in rat liver.

Apoptosis is a type of active cell death. It is involved in the homeostasis of cell number in tissues and is controlled by the growth regulatory network in the organism. It is also involved in the active removal of damaged cells. We have studied the role of apoptosis in cancer pre-stages and overt cancer in vivo, using rat liver as our main model system. Quantitative determination of apoptosis in histological specimens revealed that the rate of apoptosis tends to increase from normal to (pre)neoplastic to malignant cells. Thereby active cell death largely counterbalances the increasing replicative activity in developing malignancy. Tumor promoters shift the balance in favor of cell replication, whereas promoter withdrawal, fasting or TGF-beta 1 favor apoptosis (anti-promotion). Preneoplastic cells are more susceptible than normal liver cells to stimulation of both cell replication or cell death. Consequentially (pre)neoplastic tissue may preferentially grow or die during the appropriate treatment. Regimens that favor apoptosis and lower cell replication are shown to result in the elimination of preneoplastic cell clones from the liver (anti-initiation) and to reduce the cancer risk of the animal.

In vitro studies on subtypes and regulation of active cell death.

Active cell death (ACD) comprises several subtypes as indicated by morphology at light- and electron-microscopical level: for example type I ACD or apoptosis, with nuclear condensation, fragmentation, cytoplasmic condensation; type II ACD, nuclear pyknosis, cytoplasmic autophagy. Morphologically different types of cell death are considered to reflect differences in the underlying biochemical and molecular events eventually leading to cell collapse. However, currently no simple biochemical or molecular marker for detection of ACD subtypes is available and, therefore, morphological methods are still required to classify ACD. Sometimes, distinction of ACD from necrosis may be equivocal. Type I ACD occurs in primary hepatocyte cultures treated with TGF-beta1 and in colonie adenoma cell cultures treated with the proteinkinase C inhibitor H7 (1[5-iso-quinolylsulfonyl]-2-methylpiperazine). The anti-survival activity of TGF-beta1 was confirmed in vivo as TGF-beta1 strongly induced apoptosis in normal tissue and in preneoplastic lesions of rat liver. Type II ACD was observed in human mammary carcinoma cells (MCF-7) after treatment with tamoxifen. The anti-survival activity of H7 and of the anti-oestrogens tamoxifen, 4-hydroxy-tamoxifen, ICI 164384 could be dissociated from their anti-proliferative action. In conclusion, cell culture studies provide a means to select compounds with high anti-survival activity for further exploration in preclinical and clinical testing.

Endocrine disrupters in the aquatic environment: the Austrian approach--ARCEM.

A consortium of Austrian scientists (ARCEM) carried out a multidisciplinary environmental study on Austrian surface and ground waters including chemical monitoring, bioindication, risk assessment and risk management for selected endocrine disrupters: 17beta-estradiol, estriol, estrone, 17alpha-ethinylestradiol, 4-nonylphenol, 4-nonylphenol ethoxylates (4-NP1EO, 4-NP2EO) and their degradation products, ocytlphenol, ocytlphenol ethoxylates (OP1EO, OP2EO) as well as bisphenol A. To obtain data representative for Austria, a material flow analysis served to select relevant compounds and water samples were collected monthly over one year at those sites routinely used in Austrian water quality control. The following results were obtained and conclusions drawn: 1. Chemical monitoring: As compared to other countries, relatively low levels of pollution with endocrine disrupters were detected. 2. Bioindication: In the surface waters under study, male fish showed significant signs of feminization and demasculinization (increased production of the egg-yolk protein and histological changes of the gonads. 3. Risk assessment: For humans, exposure via either drinking water abstraction (ground water) or fish consumption was considered. The exposure levels of the compounds under study were below those considered to result in human health risks. Likewise, for bisphenol A and octylphenols, there was no indication for risk posed upon the aquatic environment (fish). However, nonylphenol or 17alpha-ethinylestradiol exposure along with results of bioindication (2) suggest a borderline estrogenic activity in a considerable number of surface waters. Consequently the emissions of these substances into the surface waters affected have to be reduced. 4. Risk management: Waste water treatment experiments revealed a positive correlation between the removal rate of endocrine disrupters from the waste water and the sludge retention time in the treatment plants. These substances are removed to a higher extend at low loaded plants designed for nutrient removal than at plants that remove carbon and/or employ nitrification only. As to drinking water treatment, chlorine dioxide and ozone were found to eliminate all investigated substances, except nonylphenol ethoxylates. (For the complete study see: www.arcem.at)

[The role of nitric oxide in reproduction]. / Die Rolle des Stickstoffmonoxids bei der Reproduktion.

Nitrix oxide (NO) is a highly reactive and short-lived radical (half-life time: 10-12 s), which is derived from L-arginine by the NO synthases (NOS) in several organ systems. The release of NO by endothelial cells leads to rapid relaxation of vascular smooth muscle cells, whereas release by several neuronal cells causes neurotransmission. When NOS is actively induced in immune cells or certain epithelia it causes cytotoxicity and/or apoptosis of these cells. In the reproductive organs NO is now considered to be an important trigger molecule for several physiological mechanisms. Follicular synthesized NO is involved in rupture of the follicle during ovulation. Moreover, NO participates in the acrosome reaction of spermatozoa during capacitation. Apoptosis and collagenolysis of the functional endometrium may be involved in endometrial shedding during menstruation. Since NO induces both apoptosis and collagenolysis, the newly discovered production of NO in late secretory endometrium could act as a key mechanism in the process of menstrual disintegration of the endometrium. Additionally, NO is necessary to support and maintain the decidualization process and plays a pivotal role in implantation.