Elevation of cyclic AMP levels and adenylate cyclase activity in duodenal mucosa from vitamin D-deficient rats by 1alpha,25-dihydroxycholecalciferol (1alpha,25-(OH)2D3).

A single 270 ng dose of 1alpha,25-(OH2D3 rpoduced elevations in cyclic AMP content and adenylate cyclase activity in duodenal mucosa from previously vitamin D-deficient rats. No changes in jejunal or ileal cyclic AMP levels or duodenal cyclic GMP levels were observed. Since 1alpha,25-(OH)2D3 increased both baseline and NaF-stimulated adenylate cyclase activity, it is possible that the vitamin leads to enhanced enzyme synthesis. While parallel changes in duodenal cyclic AMP levels and active calcium absorption in response to 1alpha,25-(OH)2D3 were observed at 6,12,24 and 48 hr after treatment, increases in calcium absorption were observed at 3 hr in duodenum and at 48 hr in ileum in the absence of changes in cyclic AMP levels. Further studies will be required to determine whether or not the changes in duodenal cyclic AMP levels are direct or indirect effects of 1alpha,25-(OH)2D3 administration, and to determine the role, if any, of this nucleotide in the hormones' effect on intestinal calcium absorption.     

The Cell Cycle of Spermatogonial Colony Forming Stem Cells In the Cba Mouse After Neutron Irradiation

Abstract. In the CBA mouse testis about 10% of the stem cell population is highly resistant to neutron irradiation (D_o, 0.75 Gy). Following a dose of 1.50 Gy these cells rapidly increase their sensitivity towards a second neutron dose and progress fairly synchronously through their first post-irradiation cell cycle. From experiments in which neutron irradiation was combined with hydroxyurea it appeared that in this cycle the S-phase is less radiosensitive (D_o, 0.43 Gy) than the other phases of the cell cycle (D_o, 0.25 Gy). From experiments in which hydroxyurea was injected twice after irradiation the speed of inflow of cells in S and the duration of S and the cell cycle could be calculated. Between 32 and 36 hr after irradiation cells start to enter the S-phase at a speed of 30% of the population every 12 hr. At 60 hr 50% of the population has already passed the S-phase while 30% is still in S. the data point to a cell cycle time of about 36 hr, while the S-phase lasts 12 hr at the most.     

Further studies on the effect of aldosterone on Mg2+-HCO3(-)-ATPase and carbonic anhydrase from rat intestinal mucosa

The main purpose of this study is to elucidate the effect of adrenocorticoids on Mg2+-HCO3(-)-ATPase and carbonic anhydrase which are thought to be related to anion transport in mammalian intestinal mucosa and renal tubulus. Rat duodenal mucosa, large intestinal mucosa and kidney cortex were excised and homogenized with mannitol-Tris buffer (pH 7.1) and brush border fraction and cytosol were obtained by a differential fractionation procedure. Brush border Mg2+-HCO3(-)-ATPase and cytosol carbonic anhydrase activities in the duodenal mucosa decreased to 70% and 37% of normal values, respectively 5-11 days after adrenalectomy. Adrenalectomy also decreased significantly both enzyme activities in large intestinal mucosa; on the other hand, renal enzyme activities did not change. Four hours after a single injection of 20-80 micrograms/kg of aldosterone, ip, to adrenalectomized rats, Mg2+-HCO3(-)-ATPase and carbonic anhydrase activities in duodenal mucosa increased gradually to normal or near normal in dose-dependent fashion. Both enzyme activities in large intestinal mucosa were also increased by a larger dose of aldosterone. Again, renal enzyme activities were not affected by any dose of aldosterone. In contrast, corticosterone (1 mg and 4 mg/kg) and dexamethasone (50 micrograms 200 micrograms/kg) had no replacement effect on enzyme activities in all organs. These results showed that the mineralocorticoid, but not glucocorticoids, is a regulator of the enzyme activity of Mg2+-HCO3(-)-ATPase and carbonic anhydrase from intestinal mucosa. The true mechanisms by which both enzymes are activated by aldosterone are not clear at present.     

Correlation of Plasma FL Expression with Bone Marrow Irradiation Dose

Purpose

Ablative bone marrow irradiation is an integral part of hematopoietic stem cell transplantation. These treatment regimens are based on classically held models of radiation dose and the bone marrow response. Flt-3 ligand (FL) has been suggested as a marker of hematopoiesis and bone marrow status but the kinetics of its response to bone marrow irradiation has yet to be fully characterized. In the current study, we examine plasma FL response to total body and partial body irradiation in mice and its relationship with irradiation dose, time of collection and pattern of bone marrow exposure.

Materials/Methods

C57BL6 mice received a single whole body or partial body irradiation dose of 1–8 Gy. Plasma was collected by mandibular or cardiac puncture at 24, 48 and 72 hr post-irradiation as well as 1–3 weeks post-irradiation. FL levels were determined via ELISA assay and used to generate two models: a linear regression model and a gated values model correlating plasma FL levels with radiation dose.

Results

At all doses between 1–8 Gy, plasma FL levels were greater than control and the level of FL increased proportionally to the total body irradiation dose. Differences in FL levels were statistically significant at each dose and at all time points. Partial body irradiation of the trunk areas, encompassing the bulk of the hematopoietically active bone marrow, resulted in significantly increased FL levels over control but irradiation of only the head or extremities did not. FL levels were used to generate a dose prediction model for total body irradiation. In a blinded study, the model differentiated mice into dose received cohorts of 1, 4 or 8 Gy based on plasma FL levels at 24 or 72 hrs post-irradiation.

Conclusion

Our findings indicate that plasma FL levels might be used as a marker of hematopoietically active bone marrow and radiation exposure in mice.     

The cell cycle of spermatogonial colony forming stem cells in the CBA mouse after neutron irradiation

In the CBA mouse testis about 10% of the stem cell population is highly resistant to neutron irradiation (D0, 0.75 Gy). Following a dose of 1.50 Gy these cells rapidly increase their sensitivity towards a second neutron dose and progress fairly synchronously through their first post-irradiation cell cycle. From experiments in which neutron irradiation was combined with hydroxyurea it appeared that in this cycle the S-phase is less radiosensitive (D0, 0.43 Gy) than the other phases of the cell cycle (D0, 0.25 Gy). From experiments in which hydroxyurea was injected twice after irradiation the speed of inflow of cells in S and the duration of S and the cell cycle could be calculated. Between 32 and 36 hr after irradiation cells start to enter the S-phase at a speed of 30% of the population every 12 hr. At 60 hr 50% of the population has already passed the S-phase while 30% is still in S. The data point to a cell cycle time of about 36 hr, while the S-phase lasts 12 hr at the most.     

Long-term comparative effect of cholecystokinin and gastrin on mouse stomach, antrum, intestine, and exocrine pancreas

Mice were injected three times a day for 12 days with 300 micrograms/kg body weight of gastrin G17 or 37.5 Ivy dog U/kg body weight of CCK or saline. Other mice were also injected four times an hr for 1 hr with 7.5 micrograms/kg of gastrin, nine Ivy dog U/kg of CCK or saline; 1 hr before killing, they were injected with tritiated thymidine to evaluate the labelling indices in peptic, antral, duodenal, jejunal, and ileal mucosae. Four hours after the first injection of the two peptides, the peptic labelling indices increased while those of intestinal mucosa increased 8 hr after these injections. Long-term injections of CCK had a trophic effect on secretory cells of the digestive tract: the number of gastric zymogenic cells, Paneth cells, and the mucous cells of Brünner glands were hypertrophied. The pepsin, amylase, chymotrypsin, and lysozyme activities increased in stomach, exocrine pancreas, and intestine, respectively. Neither parietal cells nor intestinal enterocytes and hydrolase activities were affected. The trophic effect of long-term injections of gastrin is confirmed on parietal cells and exocrine pancreatic parenchyma and is demonstrated in Paneth cells. Confirming cytological results, pancreatic lipase and amylase activities and intestinal lysozyme activity were increased after gastrin. Although CCK and gastrin have a structural analogy, these two peptides did not affect the same cellular types. A specific action of CCK on the main secretory cells of the digestive mucosa is demonstrated.     

The effect of total body gamma-irradiation on mortality, egg production and egg weight of Japanese quails

Male and female Japanese quail 21 weeks old, that were given total body doses of 60Co gamma-rays ranging from 0 to 30 Gy, showed a peak in mortality at 6-8 days post-irradiation. The LD 50/30 was 22.5 Gy, and the LD 90/30 was 26.7 Gy. No differences were evident in mortality between males and females. The reduction in egg production by 30 days post-irradiation was related linearly to the dose, for doses above 6 Gy. The reduction in egg weight (30 days post-irradiation laying period) was also related linearly to the dose.     

Acute post-irradiation canine intestinal blood flow

Radiation-induced early transient incapacitation (ETI) is accompanied by severe systemic hypotension, during which arterial blood pressure often decreases to less than 50 per cent of normal. One haemodynamic compensatory mechanism is increased peripheral resistance due to vasoconstriction. This vasoconstriction in the small intestine of dogs is disproportionately increased during haemorrhagic or endotoxic shock, and intestinal ischaemia is frequent. In an attempt to elucidate mechanisms underlying radiation-induced ETI and the gastrointestinal radiation syndrome, canine intestinal submucosal blood flow was measured by the hydrogen polarographic technique, both before and after exposure to gamma radiation. Systemic blood pressures, blood gases and haematocrits were determined simultaneously. Data obtained from 12 sham-irradiated dogs and 12 irradiated dogs indicated that 90 Gy, whole-body, gamma radiation produced a 31 per cent decrease in systemic mean blood pressure beginning within 20 min post-irradiation and lasting for at least 90 min. However, the intestinal submucosal blood flow did not decrease as anticipated, but it exhibited an actual post-irradiation increase. This increase in post-irradiation intestinal submucosal blood flow began within 5 min after irradiation and lasted for at least 90 min. Post-irradiation haematocrits were 10.5 per cent higher than those obtained before irradiation and those obtained from sham-irradiated subjects. Histopathological examination of ileal mucosa revealed significant pathologic lesions in some irradiated animals within two hours after exposure.     

EFFECTS OF CHRONIC STEROID INGESTION ON GASTRODUODENAL EPITHELIAL RENEWAL IN THE RAT

Steroids may predispose to peptic ulcer formation. One possible mechanism could be via alteration of normal epithelial renewal. to study the effects of steroids on gastroduodenal epithelial renewal, rats received hydrocortisone sodium succinate in the drinking water to deliver a dose of 10 mg/kg per day. Control rats received plain water. After 4 weeks, the rats were injected intraperitoneally with tritiated thymidine, to label proliferating cells, and killed 1 hr later, to determine measurements of epithelial proliferation, or 24 hr later to determine measurements of epithelial migration. Sections of fundus, antrum and post-pyloric duodenum were processed for light microscopy and autoradiography. In fundic and antral mucosa, steroid treatment resulted in a reduction in the number of labelled cells and in the size of the proliferative zone and, in the fundus, the mucosal thickness was reduced. In the duodenum, although the number of labelled cells remained unchanged, steroid treatment did decrease the number of cells in the proliferative zone; further, crypt depth was reduced in steroid-treated rats, but villous height was increased, resulting in an overall increase in mucosal thickness. Epithelial migration was also depressed in fundic and antral mucosa, but appeared to be accelerated in the duodenum of steroid-treated rats. These studies indicate that although, in the duodenum, the effects of steroids on epithelial renewal are complex, in the stomach chronic steroid ingestion depresses epithelial renewal both in fundic and antral mucosa. This inhibition of epithelial renewal in the stomach may contribute to the ulcerogenic action of steroids by either rendering the mucosa susceptible to the effects of other ulcerogens or by retarding the healing of existing mucosal lesions.     

The thyroid hormone receptor-alpha (TRalpha) gene encoding TRalpha1 controls deoxyribonucleic acid damage-induced tissue repair

The thyroid hormone (TH) controls, via its nuclear receptor, TH receptor-alpha1 (TRalpha1), intestinal crypt cell proliferation in the mouse. In order to understand whether this receptor also plays a role in intestinal regeneration after DNA damage, we applied a protocol of gamma-ray irradiation and monitored cell proliferation and apoptosis at several time points. In wild-type mice, the dose of 8 Gy induced cell cycle arrest and apoptosis in intestinal crypts a few hours after irradiation. This phenomenon reverted 48 h after irradiation. TRalpha(0/0) mutant mice displayed a constant low level of proliferating cells and a high apoptosis rate during the period of study. At the molecular level, in TRalpha(0/0) animals we observed a delay in the p53 phosphorylation induced by DNA damage. In our search for the expression of the protein kinases responsible for p53 phosphorylation upon irradiation, we have focused on DNA-dependent protein kinase catalytic subunit (DNA-PKcs). The number of cells expressing DNA-PKcs in crypts remained high 48 h after irradiation, specifically in TRalpha mutants. Altogether, in TRalpha(0/0) animals the rate of apoptosis in crypt cells remained high, apparently due to an elevated number of cells still presenting DNA damage. In conclusion, the TRalpha gene plays a role in crypt cell homeostasis by regulating the rate of cell renewal and apoptosis induced by DNA damage.     

Teniposide (VM-26) treatment enhances the radiation-induced micronuclei in the bone marrow of mouse

The effect of Teniposide (VM-26) pretreatment was studied on the micronuclei induction in the bone marrow of mice exposed to 0, 0.5, 1, 2 and 3 Gy of gamma radiation at 12, 24 and 36 h post-irradiation. Administration of 0.05 mg/kg body weight of VM-26 to mice before irradiation resulted in the significant enhancement of micronucleated polychromatic erythrocytes (MPCE) at 12, 24 and 36 h post-irradiation. Highest elevation in the frequency of MPCE was observed in VM-26+irradiation group after exposure to 0.5 Gy when compared to concurrent DDW+irradiation group. This increase was two fold higher in VM-26+irradiation group at 12 and 24 h, while it was 3 fold higher at 36 h post-irradiation compared to DDW+irradiation group. The peak frequency of MPCE was observed at 24 h post-irradiation in both groups, which declined thereafter. The frequency of micronucleated normochromatic erythrocytes (MNCE) increased in a dose dependent manner in both DDW+irradiation and VM-26+irradiation groups. However, the frequency of MNCE was significantly higher in the latter when compared to the former group. The frequency of MNCE exhibited a continuous elevation up to 36 h post-irradiation in both DDW+irradiation and VM-26+irradiation groups. Treatment of mice with teniposide before irradiation resulted in a significant decline in the PCE/NCE ratio compared to DDW+irradiation group. The PCE/NCE ratio continued to decline up to 36 h post-irradiation in both the groups. The dose response for MPCE and PCE/NCE ratio was linear quadratic, while it was linear for MNCE.     

Dose-rate effects in mammalian cells. IV. Repairable and nonrepairable damage in noncycling C3H 10T 1/2 cells

Repairable and nonrepairable components of gamma-ray damage leading to cell reproductive death were determined by measuring the range over which dose rate influenced the response of non-cycling C3H 10T 1/2 mouse cells. Cell proliferation and cell cycle redistribution were eliminated as factors influencing the dose-rate effect in the system by irradiating confluent monolayers of contact inhibited cells. The radiosensitivity of the cells did not change, and no selective loss of damaged cells occurred over the extended treatment times. A pronounced dose-rate effect was observed over the range between 55.6 and 0.29 Gy/hr, but a limit to the repair-dependent dose-rate effect was reached at 0.29 Gy/hr since no further reduction in effect per unit dose was observed when the dose rate was reduced to 0.17 or 0.06 Gy/hr. The survival curves, which were simple exponential functions of dose at dose rates of 0.29 Gy/hr and below, have a common Do of 7.32 Gy and represent an accurate measurement of the nonrepairable component of damage. Log-phase cultures showed remarkably different responses over the range of dose rates, due in large part to cell cycle redistribution and in some cases, cell proliferation during exposures. The results of these studies were compared with time-dose relationships used in clinical brachy-therapy and agree remarkably well with corrections in total dose suggested by R. Paterson [Br. J. Radiol. 25, 505-516 (1952)] and A.E.S. Green [cited in F. Ellis, Curr. Top. Radiat. Res. Q. 4, 357-397 (1968)] when the standard treatment time is changed. Comparison of our data with in vivo isoeffect curves of total dose vs dose per fraction for "early" and "late" tissue responses indicate that cell cycle redistribution should not be ignored as a factor influencing time-dose relationships in radiotherapy.     

Role of gastrin/pentagastrin in regulation of intestinal cytochrome P-450

1. In the absence of intraluminal inducers, low "basal" levels of cytochrome P-450 and its dependent MFO activities are detected in the rat intestinal mucosa, and may be regulated by endogenous hormones. 2. Rats were nutritionally maintained by either short term (48 hr) intravenous glucose infusion or chronic (8 days) intravenous hyperalimentation, and were treated with various doses of pentagastrin in the infusate. 3. Regardless of the dose (6-90 micrograms/kg/hr) or duration of infusion (2-8 days), pentagastrin had no effect on small intestinal cytochrome P-450, its dependent MFO activity, or the activity of delta-aminolevulinic acid synthetase. 4. The intestinal trophic peptide hormone, gastrin, apparently does not regulate the cytochrome P-450-dependent MFO system of the small intestine.     

Imbalance between apoptosis and proliferation causes late radiation damage of salivary gland in mouse

Severe xerostomia is a common late radiation consequence, which occurs after irradiation of head and neck malignancies. The aim of the present study was to analyze apoptosis and proliferation and their relationship during the late post-irradiation phase. C57BL/6 mice were locally irradiated in head and neck region with a single dose of 7.5 or 15 Gy and their submandibular glands were collected at 40 and 90 days after irradiation. To identify apoptotic cells, the TUNEL method was employed and immunohistochemistry with proliferating cell nuclear antigen (PCNA) was used for detecting proliferation. Histological changes at day 40 were mild in contrast to day 90 when glands of irradiated mice showed severe atrophy, vacuolization and mononuclear infiltration. Acinar cells, granular and intercalated duct cells of mice irradiated with 7.5 and 15 Gy expressed higher apoptotic index than cells of non-irradiated, control glands at both examined time points. At 40 days, a higher proliferation index in granular and intercalated duct cells was detected only in group irradiated with 7.5 Gy. At 90 days, proliferation index for all cell types in both irradiated groups was similar to the controls. According to our results, the imbalance between apoptosis and proliferation caused by X-irradiation may be the reason for gland impairment during the late post-irradiation phase.     

Radiation-induced epigenetic DNA methylation modification of radiation-response pathways

DNA methylation can regulate gene expression and has been shown to modulate cancer cell biology and chemotherapy resistance. Therapeutic radiation results in a biological response to counter the subsequent DNA damage and genomic stress in order to avoid cell death. In this study, we analyzed DNA methylation changes at >450,000 loci to determine a potential epigenetic response to ionizing radiation in MDA-MB-231 cells. Cells were irradiated at 2 and 6 Gy and analyzed at 7 time points from 1–72 h. Significantly differentially methylated genes were enriched in gene ontology categories relating to cell cycle, DNA repair, and apoptosis pathways. The degree of differential methylation of these pathways varied with radiation dose and time post-irradiation in a manner consistent with classical biological responses to radiation. A cell cycle arrest was observed 24 h post-irradiation and DNA damage, as measured by γH2AX, resolved at 24 h. In addition, cells showed low levels of apoptosis 2–48 h post-6 Gy and cellular senescence became significant at 72 h post-irradiation. These DNA methylation changes suggest an epigenetic role in the cellular response to radiation.     

The effect of bile and of sodium taurocholate on the epithelial cell dynamics of the rat small intestine.

The absence of bile from the intestinal lumen of rats for a period of 48 hr led to: a decreased proliferative cell pool, reduced cell shedding, and a 50% decrease of the labeling index in the ileum. The constant duodenal perfusion of Na taurocholate for periods of 48, 60, 72, and 96 hr in animals with a biliary diversion was associated with: deepening of crypts and decreased crypt/villus ratios as well as with acceleration of the epithelial cell migration rate on the crypt-villus units. The data suggest that bile and bile acids constitute important regulatory factors influencing enterocyte proliferation, migration and loss.     

Dose-rate evidence for two kinds of radiation damage in stationary-phase mammalian cells

Survival based on colony formation was measured for starved plateau-phase Chinese hamster ovary (CHO) cells exposed to 250 kVp X rays at dose rates of 0.0031, 0.025, 0.18, 0.31, and 1.00 Gy/min. A large dose-rate effect was demonstrated. Delayed plating experiments and dose response experiments following a conditioning dose, both using a dose rate of 1.00 Gy/min and plating delays of up to 48 hr, were also used to investigate the alternative repair hypotheses. There is clearly a greater change in survival in dose-rate experiments than in the other experiments. Thus we believe that a process which depends on the square of the concentration of initial damage, and which alters the effect of initial damage on cell survival is being observed. We have applied the damage accumulation model to separate the single-event damage from this concentration-dependent form and estimate the repair rate for the latter type to be 70 min for our CHO cells. Use of this analysis on other published dose-rate studies also yields results consistent with this interpretation of the repair mechanisms.     

Nonuniform irradiation of the canine intestine. I. Effects

To investigate the effects of nonuniform irradiation on the small intestine, we prepared 24 dogs for continent isoperistaltic ileostomies under aseptic surgical conditions and general anesthesia. After a 3-week recovery period, the ileum was catheterized with a fiberoptic endoscope to observe the intestinal mucosa and to harvest mucosal biopsies. The baseline macroscopic and microscopic appearance of the intestinal mucosa was determined. Two weeks later, the ileum was catheterized with a 100-cm soft tube containing 40 groups of three thermoluminescent dosimeters placed at equally spaced intervals, and a dose of either 4.5, 8, 10, 11, or 15 Gy 60Co gamma rays was delivered to the right abdomen (nonuniform exposure). This method allowed a direct and precise assessment of the dose received at 40 sites located in the 100-cm intestinal segment. The intestinal mucosa was again evaluated 1, 4, and 6 days after irradiation. All animals exposed to 4.5 and 8 Gy survived, whereas none survived after 11 and 15 Gy. After exposure to 10 Gy, 60% of the animals died within 4-6 days and 40% survived with symptoms associated with both the intestinal and the hematopoietic syndromes. Crypt cell necrosis, blunting of villi, and reduction of the mucosal lining increased between 1 and 4 days after irradiation, and mucosal damage was correlated with intraintestinal dosimetry at Day 6. The granulocyte counts at Day 4 were significantly lower than baseline level in animals that died within 4-6 days but not in survivors. The present model appears to be realistic and clinically relevant, allowing the concurrent study of the intestinal and hematopoietic effects of high-dose nonuniform irradiation similar to that received by patients during radiation therapy as well as by radiation accident victims.