Trypan Blue as a marker of plasma membrane permeability in alloxan-treated mouse islet cells

Molecular Engineering of Plasma Membrane and Mitochondria Dual-Targeted NIR-II AIE Photosensitizer Evoking Synergetic Pyroptosis and Apoptosis

Phototherapy provides a noninvasive and spatiotemporal controllable paradigm to inhibit the evasion of the programmed cell death (PCD) of tumors. However, conventional photosensitizers (PSs) often induce a single PCD process, resulting in insufficient photodamage and severely impeding their application scopes. In this study, molecular engineering is conducted by adjusting electron donors to develop an aggregation-induced NIR-II emissive PS (DPITQ) for plasma membrane and mitochondria dual-targeted tumor therapy by evoking synergetic pyroptosis and apoptosis. DPITQ displays boosted type I and II reactive oxygen species generation as well as a high photothermal conversion efficacy (43%) after laser irradiation of 635 nm. The excellent biocompatibility and appropriate lipophilicity help the DPITQ to specifically anchor in the plasma membrane and mitochondria of cancer cells. Furthermore, the photosensitized DPITQ can disrupt the intact plasma membrane and cause mitochondrial dysfunction, ultimately causing concurrent pyroptosis and apoptosis to suppress cancer cell proliferation even under hypoxia. It is noteworthy that the DPITQ nanoparticles (NPs) present clear NIR-II fluorescence imaging capability on the venous vessels of nude mice. Notably, the DPITQ NPs exert efficient NIR-II fluorescence imaging-guided phototherapy both in multicellular tumor spheroids and in vivo, causing maximum destruction to tumors but minimum adverse effects to normal tissue.

Alternating electric fields can improve chemotherapy treatment efficacy in blood cancer cell U937 (non-adherent cells)

BACKGROUND

Recent achievements in cancer therapy are the use of alternating electrical fields at intermediate frequencies (100-300 kHz) and low intensities (1-3 V/cm), which specifically target cell proliferation while affecting different cellular activities depending on the frequency used.

METHODS

In this article, we examine the effect of electric fields on spherical suspended cells and propose the combination of Daunorubicin, a chemotherapy agent widely used in the treatment of acute myeloid leukemia, with electric field exposure. U937 cells were subjected to an electric field with a frequency of 200 kHz and an intensity of 0.75 V/cm, or to a combination of Daunorubicin and electric field exposure, resulting in a significant reduction in cell proliferation. Furthermore, the application of an electric field to U937 cells increased Daunorubicin uptake.

RESULTS

Apoptosis and DNA damage were induced by the electric field or in conjunction with Daunorubicin. Notably, normal cells exposed to an electric field did not show significant damage, indicating a selective effect on dividing cancer cells (U937). Moreover, the electric field affects the U937 cell line either alone or in combination with Daunorubicin. This effect may be due to increased membrane permeability.

CONCLUSIONS

Our findings suggest that the use of electric fields at intermediate frequencies and low intensities, either alone or in combination with Daunorubicin, has potential as a selective anti-cancer therapy for dividing cancer cells, particularly in the treatment of acute myeloid leukemia. Further research is needed to fully understand the underlying mechanisms and to optimize the use of this therapy.

The level of menadione redox-cycling in pancreatic β-cells is proportional to the glucose concentration: role of NADH and consequences for insulin secretion

Pancreatic β-cells release insulin in response to elevation of glucose from basal (4-7mM) to stimulatory (8-16mM) levels. Metabolism of glucose by the β-cell results in the production of low levels of reactive oxygen intermediates (ROI), such as hydrogen peroxide (H(2)O(2)), a newly recognized coupling factor linking glucose metabolism to insulin secretion. However, high and toxic levels of H(2)O(2) inhibit insulin secretion. Menadione, which produces H(2)O(2) via redox cycling mechanism in a dose-dependent manner, was investigated for its effect on β-cell metabolism and insulin secretion in INS-1 832/13, a rat β-cell insulinoma cell line, and primary rodent islets. Menadione-dependent redox cycling and resulting H(2)O(2) production under stimulatory glucose exceeded several-fold those reached at basal glucose. This was paralleled by a differential effect of menadione (0.1-10μM) on insulin secretion, which was enhanced at basal, but inhibited at stimulatory glucose. Redox cycling of menadione and H(2)O(2) formation was dependent on glycolytically-derived NADH, as inhibition of glycolysis and application of non-glycogenic insulin secretagogues did not support redox cycling. In addition, activity of plasma membrane electron transport, a system dependent in part on glycolytically-derived NADH, was also inhibited by menadione. Menadione-dependent redox cycling was sensitive to the NQO1 inhibitor dicoumarol and the flavoprotein inhibitor diphenylene iodonium, suggesting a role for NQO1 and other oxidoreductases in this process. These data may explain the apparent dichotomy between the stimulatory and inhibitory effects of H(2)O(2) and menadione on insulin secretion.

LDL and UV-oxidized LDL induce upregulation of iNOS and NO in unstimulated J774 macrophages and HUVEC

Oxidized low-density lipoprotein (LDL) diminishes NO production from activated macrophages. The interaction between LDL and inactivated macrophages is neglected and controversial. This study examines the effect of LDL, 7-oxysterols and iron compounds on NO production in unstimulated J774 macrophages. J774 cells and human umbilical vein endothelial cells (HUVEC) were either incubated for 24 h with native LDL (LDL) or ultraviolet (UV)-oxidized LDL (UVoxLDL), in the absence or presence of an inducible nitric oxide synthase (iNOS)- or an endothelial constitutive nitric oxide synthase (eNOS)-inhibitor. J774 cells were also incubated with lipopolysaccharide (LPS), in the absence or presence of an iNOS- or an eNOS-inhibitor. Nitrite was analysed as a marker of NO production. The mRNA levels of iNOS were evaluated by reverse transcriptase polymerase chain reaction. LDL and UVoxLDL significantly increased NO production from unstimulated J774 macrophages. This increase in NO was accompanied by enhanced expression of iNOS mRNA, and was inhibited by the iNOS inhibitor. Furthermore, NO production was elevated and angiotensin-converting enzyme (ACE) activity was reduced in HUVEC following the exposure to LDL and UVoxLDL. In conclusion, LDL may serve as an important inflammatory activator of macrophages and HUVEC, inducing inducible nitric oxide production but diminishing ACE. After its oxidation, this function of LDL may be further enhanced and may contribute to the regulation and progression of atheroma formation.

Nitric oxide/cGMP protects endothelial cells from hypoxia-mediated leakiness

Leakiness of the endothelial bed is attributed to the over-perfusion of the pulmonary bed, which leads to high altitude pulmonary edema (HAPE). Inhalation of nitric oxide has been successfully employed to treat HAPE patients. We hypothesize that nitric oxide intervenes in the permeability of the pulmonary macrovascular endothelial bed to rectify the leaky bed under hypoxia. Our present work explores the underlying mechanism of 'hypoxia-mediated' endothelial malfunction by using human umbilical cord-derived immortalized endothelial cells, ECV-304, and bovine pulmonary artery primary endothelial cells. The leakiness of the endothelial monolayer was increased by two-fold under hypoxia in comparison to cells under normoxia, while optical tweezers-based tethering assays reported a higher membrane tension of endothelial cells under hypoxia. Phalloidin staining demonstrated depolymerization of F-actin stress fibers and highly polarized F-actin patterns in endothelial cells under hypoxia. Nitric oxide, 8-Br-cGMP and sildenafil citrate (phosphodiesterase type 5 inhibitor) led to recovery from hypoxia-induced leakiness of the endothelial monolayers. Results of the present study also suggest that 'hypoxia-induced' cytoskeletal rearrangements and membrane leakiness are associated with the low nitric oxide availability under hypoxia. We conclude that nitric oxide-based recovery of hypoxia-induced leakiness of endothelial cells is a cyclic guanosine monophosphate (cGMP)-dependent phenomenon.

Evans Blue and other dyes as protein tyrosine phosphatase inhibitors

Commonly used dyes including Evans Blue and Trypan Blue were examined for their inhibitory activities against protein tyrosine phosphatases (PTPases), all of them showed inhibition of PTPases with different potencies. Of the 13 dyes tested, four exhibited IC(50) value of less than 10 microM, Evans Blue lowest IC(50) of 1.3 microM against PTP1B. Care must be taken in the use of dyes for clinical or biochemical experiments to avoid unwanted side effects. Some of the low molecular weight dyes might be useful as lead compounds for the development of potent and selective PTPase inhibitors.

The toxicity to macrophages of oxidized low-density lipoprotein is mediated through lysosomal damage

Oxidized low-density lipoprotein (ox-LDL) has been shown to degrade poorly within the secondary lysosomes of macrophages but its possible effect on lysosomal integrity has received less attention. The effect of ultraviolet-C oxidized LDL (UVox-LDL) on cellular viability, and lysosomal membrane stability, was examined on cultured murine J-774 cells and human monocyte-derived macrophages (HMDMs). The acridine orange (AO) relocalization test was applied to study the lysosomal integrity of living cells. UVox-LDL dramatically reduced J-774 cell proliferation at a concentration of 25 microg/ml. Incubation with 5 microM copper alone, normally used to induce LDL oxidation, was also toxic. In contrast to the effects of ox-LDL, in concentrations up to 75 microg/ml, native LDL (nLDL) rather stimulated J-774 cell replication. Incubation with UVox-LDL (25-75 microg/ml) also altered cellular AO uptake, depending on time and dose: its lysosomal accumulation decreased and its cytosolic accumulation increased. This shift indicates damaged lysosomal membranes with decreased intralysosomal, and increased cytosolic, H+ concentration. Many J-774 cells exposed to UVox-LDL initially transformed into foam cells and then assumed an apoptotic-type morphology with TUNEL-positive nuclei. We conclude that ox-LDL is cytotoxic to macrophages due to oxidative damage of lysosomal membranes, with ensuing destabilization and leakage to the cytosol of lysosomal contents, such as hydrolytic enzymes, causing degeneration of apoptotic type.

Effects of iron- and hemoglobin-loaded human monocyte-derived macrophages on oxidation and uptake of LDL

It is generally accepted that transition metals are required for cellular LDL oxidation. LDL may also be oxidized by iron and reducing agents in cell-free systems. We hypothesized that lysosomal iron may be exocytosed from macrophages that have been iron loaded by phagocytosis and degradation of iron-rich structures, eg, erythrocytes, and that such released iron may promote LDL oxidation and uptake by macrophages. Human monocyte-derived macrophages (HMDMs) were isolated and cultured for 7 days and then exposed to FeCl3, Fe-ADP, or Fe-EDTA (100 mumol/L) or hemoglobin (25 or 50 micrograms/mL) for 24 hours. After rinsing, LDL (50 to 150 micrograms/mL) was added in fresh culture medium without serum. After another 24 hours the media concentrations of iron and thiobarbituric acid-reacting substances as well as the electrophoretic mobility of LDL were increased, while the cells showed only minimal signs of decreased viability. Lipofuscin, neutral lipids, and phospholipids accumulated in a granular, lysosome-like pattern, and the cells acquired a foam cell-like morphology. There was a strong correlation (r = .87, P = .005) between the amount of iron added during the pre-exposure period and lipofuscin accumulation during the ensuing exposure to LDL in fresh, serum-free medium. Our results support our hypothesis and indicate that lysosomal iron may be exocytosed from HMDMs and promote oxidation and uptake of LDL and thus induce foam cell formation.

Ascorbate-induced free radical toxicity to isolated islet cells

Ascorbate is known to be cytotoxic by generating free oxygen radicals, a property shared with the diabetogenic drug alloxan. Some reports indicate that also ascorbate may be diabetogenic. In this study the cytotoxicity of ascorbate on isolated mouse islet cells has been investigated. Ascorbate (0.5-2.0 mmol/l) induced a concentration-dependent increase of trypan blue uptake by the cells, indicating an increase of membrane permeability to the dye. Trypan blue uptake induced by 2.0 mmol/l ascorbate was inhibited by concomitant incubation of the cells with 200 mg/l superoxide dismutase, 200 mg/l catalase, 3.0 mmol/l cytochrome-c or 50 mumol diethylenetriaminepentacetic acid (DTPA), but not by 50 mmol/l D-mannitol. The results indicate that ascorbate is cytotoxic to islet cells by metal-catalysed free radical generation.

Alloxan cytotoxicity is highly potentiated by plasma membrane- and lysosomal-associated iron--a study on a model system of cultured J-774 cells

Pancreatic islet beta cells, and some other cell types, are sensitive to the damaging effects of alloxan. The mechanisms behind the cytotoxicity have not been fully elucidated, although they are considered to be mediated by the formation and effects of reactive oxygen metabolites. In the present study, the cytotoxic effects of alloxan/cysteine at high and low concentrations were investigated on a model system of cultured J-774 cells. Viability was estimated by the trypan blue dye exclusion test, plasma membrane permeability by a modified microfluorometric fluorescein diacetate technique and lysosomal membrane stability by a microfluorometric acridine orange method. The results showed: (a) hydrogen peroxide, readily diffusing through cellular membranes and produced extracellularly in large amounts by alloxan/cysteine at high concentrations, enters the secondary lysosomes if not previously degraded by cellular anti-oxidant systems. Intralysosomal Fenton reactions, with the formation of hydroxyl radicals, may be induced provided catalytically active lysosomal iron is present. This would result in lysosomal membrane damage followed by leakage of lysosomal contents to the cell sap and cell degeneration. (b) Alloxan/cysteine at low concentrations induced production of superoxide and hydrogen peroxide in low amounts which caused almost no lysosomal damage and appeared to be non-toxic unless there was some plasma membrane-associated iron. Consequently, cells initially allowed to endocytose iron during culture, or briefly exposed to iron just before exposure to alloxan and cysteine, showed greatly enhanced sensitivity. In this case iron, in combination with superoxide and hydrogen peroxide, is believed to give rise to plasma membrane-associated hydroxyl radical production (Fenton reaction) with resultant loss of membrane integrity.(ABSTRACT TRUNCATED AT 250 WORDS)

Effects of alloxan and reducing agents on macrophages in culture

The diabetogenic effect of the quinonoid compound alloxan is not understood in detail although it supposedly involves reactions mediated by alloxan and oxygen radicals. These reactive species may form extra- or intracellularly and cause cell damage through a variety of complex interactions with several macromolecules. The purpose of this study was to elucidate early (less than or equal to 60 min) effects of alloxan and reducing agents (cysteine and ascorbic acid) on cultured macrophages, as assayed by the trypan blue dye exclusion test and the sensitive fluorescein diacetate and propidium iodide (FDA/PI) double staining technique. During the reactions between alloxan and reducing agents, oxygen was consumed as a sign of superoxide anion radical formation. When alloxan alone was added to two different culture media without serum, oxygen was still consumed, indicating formation of oxygen radicals due to the occurrence of reducing substances in cell culture media. This finding demonstrated the necessity of performing further studies in solutions without reducing capacity, e.g. in phosphate-buffered saline. The experiments showed that exposure of normal and malignant macrophages to alloxan and reducing substances resulted in rapidly occurring plasma membrane damage and ensuing cell death. Separate addition of catalase, desferrioxamine or superoxide dismutase resulted in evident, slight and no protection, respectively. The combinations of (i) catalase and desferrioxamine, and (ii) catalase, desferrioxamine and superoxide dismutase, however, inhibited cell damage in a pronounced and complete way, respectively. The results are interpreted as indicating cell damage due to the extracellular formation of hydrogen peroxide and hydroxyl radicals. The latter in close proximity to the cells and acting on the plasma membrane, while the former, after diffusing into the cell, may have several intracellular targets. The FDA/PI technique proved its value as a quantifiable method for the evaluation not only of cell death but also of cell damage with computer-based fluorometry.

Gossypol-induced free radical toxicity to isolated islet cells

1. The cytotoxicity of the polyphenolic potential male antifertility agent gossypol was investigated on isolated mouse islets cells. 2. Gossypol shared many properties with the diabetogenic agent alloxan. 3. Gossypol (0.1-1.0 mmol/l) induced a concentration-dependent increase of Trypan Blue uptake by the cells, indicating an increase of membrane permeability to the dye. 4. Trypan Blue uptake induced by 0.5 mmol/l gossypol was inhibited by concomitant incubation of the cells with enzymatic (200 mg/l superoxide dismutase, 200 mg/l catalase, 3 mmol/l cytochrome-c), or low-molecular weight (50 mmol/l D-mannitol) scavengers of oxygen radicals, and the metal chelator diethylenetriaminepentacetic acid (DTPA) (50 mumol/l). 5. The results support the hypothesis that gossypol is B-cytotoxic by generation of noxious free radicals and that when proposing gossypol as a male antifertility agent, studies to exclude gossypol as a diabetogenic agent should first be performed in vivo.

The effects of nitrous oxide on the secretory activity of pro-opiomelanocortin peptides from basal hypothalamic cells attached to cytodex beads in a superfusion in vitro system

Dispersed cells from adult rat basal hypothalami, attached to Cytodex-3 microcarrier beads, were placed in a column and superfused with aerated high glucose media or media enriched with variable concentrations of nitrous oxide with oxygen. beta-Endorphin and alpha-MSH content was measured in the effluent collected during superfusion and demonstrated a near constant baseline release. Nitrous oxide, 60% (P less than 0.025) and 80% (P less than 0.02), caused significant increases in release of beta-endorphin. Potassium chloride (50 mM) caused a significant increase in release (P less than 0.007) of beta-endorphin whereas saline and 30% nitrous oxide did not. Neither nitrous oxide-enriched media nor potassium chloride had any statistically significant effect on alpha-MSH release. The increase in beta-endorphin secretory activity during exposure to nitrous oxide demonstrates that nitrous oxide may have a stimulatory effect on central pro-opiomelanocortin neurons.

Pancreatic B cells possess defense mechanisms against cell-specific toxicity

Insulin-dependent diabetes develops when more than 90% of the insulin containing B cells are destroyed. The present study investigates whether the target B cells can counteract the damaging effects of cytotoxic substances. Purified islet cells were first exposed for 3-10 min to t-butylhydroperoxide, alloxan, streptozotocin, or B-cell surface antibodies plus complement, then cultured for 20 hr before the percent of dead cells was counted. t-Butylhydroperoxide destroyed all islet cell types whereas the three other agents exerted a dose-dependent toxicity upon islet B cells only. The survival of drug- and complement-treated cells varied with the culture conditions present between the initial cellular attack and the moment of cell death. For the four B-cell toxic agents tested, an increase in medium glucose following any of these treatments reduced the percent of dead cells. This protective effect was not observed with galactose or fructose, nor could it be induced in islet non-B cells; it was additive to the protective action glucose induced during preincubation of the cells prior to their exposure to certain cytotoxic agents such as alloxan. Nicotinamide also enhanced the survival of drug-treated B cells, irrespective of the damaging compound. The vitamin was most effective when applied immediately after the initial drug or complement treatment; it also protected islet non-B cells--in contrast to glucose. The present in vitro study has led to the recognition of defense mechanisms in pancreatic B cells. Physiologic compounds such as glucose and nicotinamide were found to stimulate islet B cells to counteract the damaging effects of B-cell toxic conditions. It is conceivable that the events involved in this protection are implicated in the pathogenesis and/or prevention of insulin-dependent diabetes.

Alloxan toxicity in human and canine spermatozoa. Possible biochemical basis for a species difference in sensitivity

In view of the well known species differences in the sensitivity of pancreatic B-cells to the toxic glucose analogue alloxan, it was tested whether spermatozoa from two species with a different diabetogenic effect of alloxan displayed a similar difference in their sensitivity to this drug. In canine spermatozoa, less than 2 mM alloxan profoundly reduced the rate of glucose oxidation and cellular motility whereas more than 5 mM was required to significantly alter these parameters in human spermatozoa. Such species difference was not observed in spermatozoal sensitivity towards the inhibitory effects of tert-butyl hydroperoxide. The phenomenon is not attributable to a different rate of alloxan uptake since the drug is not incorporated by dog or human spermatozoa. The alloxan toxicity was counteracted by D-glucose and its 3-O-methyl analogue in both species, and was potentiated by ascorbic acid; however, only in man. The protective effect of D-glucose was much less marked in tert-butyl hydroperoxide-cytotoxicity. It is concluded that the observed species difference in spermatozoal alloxan sensitivity is not related to differences in alloxan uptake or in sensitivity to organic peroxides; differences in cellular scavenging of superoxide anion radicals and/or ascorbic acid metabolism may explain the lower sensitivity of human spermatozoa for alloxan.

Effect of extracellularly generated free radicals on the plasma membrane permeability of isolated pancreatic B-cells

Previous experiments on alloxan diabetogenicity suggest that alloxan increases the permeability of B-cell plasma membranes by generation of noxious free radicals. Whether the radicals are generated intra- or extracellularly has however been disputed. To test if extracellularly generated free radicals could decrease trypan blue exclusion of dispersed islet cells, a radical-generating solution of xanthine oxidase/hypoxanthine was employed. The solution increased dye uptake by cells in the cell suspension. Superoxide dismutase and catalase but not scavengers of hydroxyl radicals protected against the increase in dye uptake. Both L- and D-glucose protected the cells from injury. It is concluded that extracellularly generated free radicals induce damage to the plasma membrane of islet cells. The result strengthens the hypothesis of plasma membrane damage by extracellularly generated free radicals as the primary event in alloxan diabetogenicity and may provide a link for explanation of damage caused by islet inflammation in juvenile diabetes.

Adult rat pancreatic islet cells adherent to microcarrier beads: evaluation of function and morphology

Dispersed adult rat pancreatic islet cells were incubated with Cytodex-3 microcarrier beads for 72 h, during which time single cells adhered firmly to bead surfaces. Electron microscopy revealed well-preserved ultrastructure of attached A, B, and D cells. Perifusion of these cultures showed stable basal insulin release, brisk, biphasic insulin responses to 30-min glucose stimulation, and consistent, monophasic spikes of insulin release in response to repeated, brief pulses of glucose. These results indicate that adult rat islet cells attach to microcarriers and remain viable in culture. This preparation offers advantages for studies of hormone secretory dynamics of differentiated single islet cells, free from cell-to-cell interactions.

Ultrastructure and membrane permeability of cultured pancreatic beta-cells exposed to alloxan or 6-hydroxydopamine

Stereological techniques on electron microscopy micrographs were used to evaluate the morphological changes of cultured islet beta cells that had been exposed to alloxan or 6-hydroxydopamine. Trypan Blue exclusion by cells cultured for 3 days indicated that the cells were 100% viable. Electron microscopy revealed that nearly all of the surviving cultured cells were beta cells. Exposure to 5 mmol/l alloxan or 1-5 mmol/l 6-hydroxydopamine for 10 or 30 min caused a general swelling of the cultured cells with a concomitant swelling of mitochondria and nuclei. The size of the secretory granules was not affected by the drugs. Only 3-10% of the cells excluded Trypan Blue after exposure to 5 mmol/l alloxan or 6-hydroxydopamine. The data conform with the hypothesis that a primary action of alloxan and 6-hydroxydopamine is at the plasma membrane level of beta cells.

Morphological alterations in experimental esophagitis. Light microscopic and scanning and transmission electron microscopic study

The morphology of esophagitis, both in the presence and absence of acid, was studied by light microscopy and transmission and scanning electron microscopy. For this purpose the rabbit esophagus was isolated in situ and perfused with agents known to cause esophageal mucosal damage (HCl, pepsin, taurocholate, and deoxycholate). In addition, changes in the permeability of the plasma membrane of the esophageal epithelial cells were assessed by staining the esophageal epithelium with trypan blue and antinuclear antibodies. The results indicate that HCl alone causes relatively few changes in the esophageal epithelium. However, when combined with pepsin or taurocholate, severe ulcerative changes were caused within an hour. Deoxycholate, which is formed in the upper gastrointestinal tract under nonacidic conditions, also causes severe damage. Further, it was shown that the esophagitis caused by pepsin and bile salts are clearly morphologically different. Bile salts affect primarily the cell membrane and intracellular organelles, while pepsin seems to affect the intercellular substance causing the epithelial cells to be shed. In contrast, the presence or absence of acid per se does not seem to influence the nature of the epithelial damage, since the lesions caused by the two bile salts (deoxycholate vs taurocholate + HCl) were morphologically similar.

CuZn-superoxide dismutase, Mn-superoxide dismutase, catalase and glutathione peroxidase in pancreatic islets and other tissues in the mouse

Exogenous superoxide dismutase, catalase and scavengers of the hydroxyl radical protect pancreatic-islet cells against the toxic actions of alloxan in vitro [Grankvist et al. (1979) Biochem. J. 182, 17--25]. To test whether the extraordinary sensitivity of islet cells to alloxan is due to a deficiency of endogenous enzymes protecting against oxygen-reduction products, we assayed CuZn-superoxide dismutase, Mn-superoxide dismutase, catalase and glutathione peroxidase in mouse islets and other tissues. To correct for any blood contamination, haemoglobin was also measured in the tissue samples. Pancreatic islets were found to belong to tissues with relatively little activity of the protective enzymes. However, the deviation from other tissues in this respect is probably not large enough to explain the especially great susceptibility of islet cells to alloxan.