THE EFFECT OF PARTIAL BODY IRRADIATION ON HAEMOPOIETIC STEM CELL MIGRATION

Data obtained after various types of partial body irradiation support the concept of a small rapidly exchangeable pool of CFUs, which seems to be exhausted rapidly after irradiation. The depletion of this pool is the most plausible explanation for the decrease in stem cell migration observed 3 hr after exposure in C₃H mice. After partial body irradiation the size of the rapidly mobilizable pool is reduced in proportion to the areas of bone marrow irradiated. When only one marrow area is shielded, the recovery of this pool does not occur during the first 24 hr after exposure.     

Clonogenic fibroblast precursors among the peritoneal fluid cells of guinea pigs

There are about 2000 (1830 +/- 360) clonogenic precursors of fibroblast (CFU(f)) in the peritoneal liquid of guinea-pig, which form colonies (clones) in the monolayer cultures. The colonies consist of actively proliferating fibroblasts with different morphology. The proportion of colonies with different morphology shows changes during the growth of cultures. During aseptic inflammation the number of CFU(f) in the peritoneal liquid increases by 25, 15 and 4 times after 6 and 24 hours and 3 days, resp., compared to the control. 99% CFU(f) does not proliferate in situ, and the increase of the number of CFU(f) after inflammation is not followed by their proliferation. The irradiation of the peritoneal cavity killed the most of CFU(f)--97-99%. During the aseptic inflammation, the number of CFU(f) increased to 470 +/- 105 during 4 days after the irradiation, which is 5% of the number of CFU(f) on the 3rd day of inflammation for the non-irradiated animals. Thus, no intensive repopulation of clonogenic precursors of fibroblasts occurs in the peritoneal cavity.     

The effect of endotoxin on murine stem cells

Previous studies showed that after 5 μg of Salmonella typhosa endotoxin there was an increase in colony stimulating factor temporally related to a fall in murine marrow in vitro colony forming cells (CFC). This was followed by differentiation along the marrow granulocytic pathway. The present studies showed that after 5 μg of endotoxin the peripheral blood CFC fell by approximately 50% at one hour, rose to a level ten fold that of control at six hours and then returned to control values by 48 hours. There was a progressive increase in the number of splenic CFC to ten fold that of control from 24 to 72 hours after endotoxin. These data imply a migration of CFC from the marrow to the spleen along with an in-situ increase in splenic CFC. Thus, either migration or differentiation may explain the fall in marrow CFC after endotoxin. Spleen colony forming units (CFU) in the marrow were measured by a transplantation technique and the transplantation fraction (f Fx) determined. A decrease in marrow CFU at 24 hours after endotoxin was secondary to a change in the f Fx. from 11.1% to 7.6%. There was however, an increased percentage of CFU in DNA synthesis in the interval of 6–48 hours after endotoxin, as judged by the hydroxyurea technique. As the marrow CFC fell within 20 minutes of endotoxin administration, the data suggest the CFC may be affected initially and that changes in the generative cycle of the CFU may be of a secondary nature.     

REGULATION OF HAEMOPOIETIC STEM CELL TURNOVER IN PARTIALLY IRRADIATED MICE

The existence of a possible local control of CFU turnover was studied in mice in which one tibia only was irradiated (LR mice) and in mice in which one tibia was shielded during whole-body irradiation ('TBR'mice). In both the LR and 'TBR'mice, the increased CFU turnover continued in the irradiated tibiae even after the time when in the unirradiated (shielded) tibiae it returned to normal levels. The early temporary decrease in the CFU numbers in the shielded tibiae of 'TBR'mice is attributed to a temporary demand for increased differentiation rather than to migration of CFU. The direct control of CFU turnover appears to be local in nature, in contrast to the stimulus for CFU differentiation.     

Restoration of the bone marrow pluripotent stem cells in AKR mice after arabinosylcytosine treatment

The hypothesis of repression of multipotent stem cells (CFU) by leukemic cells to explain their depletion, previously demonstrated in AKR leukemic mice, was tested. Using arabinosylcytosine to destroy leukemic cells, it was shown that the bone marrow CFU pool was acutely depressed between 2 h and 12 h after treatment. However, 5 to 7 days later, this pool was restored, surpassing the value of the bone marrow pool in normal mice. This seems to indicate that the CFU pool in leukemic mice is potentially capable of proliferating but is repressed by leukemic cells.     

Nitrate Uptake and Assimilation by Wheat Seedlings during Initial Exposure to Nitrate

Nitrate uptake, reduction, and translocation were examined in intact, 14-day-old, nitrogen-depleted wheat (Triticum vulgare var. Knox) seedlings during a 9-hour exposure to 0.2 mm Ca (NO(3))(2). The nitrate uptake rate was low during the initial 3-hour period, increased during the 3- to 6-hour period, and then declined. By the 3rd hour, 14% of the absorbed nitrate had been reduced, and this increased to 36% by the 9th hour. Shoots accumulated reduced (15)N more rapidly than roots and the ratio of reduced (15)N to (15)N-nitrate was higher in the shoots. A significant proportion of the total reduction occurred in the root system under these experimental conditions. Accumulation of (15)N in ethanol-insoluble forms was evident in both roots and shoots by the 3rd hour and, after 4.5 hours, increased more rapidly in shoots than in roots.An experiment in which a 3-hour exposure to 0.2 mm Ca ((15)NO(3))(2) was followed by a 12-hour exposure to 0.2 mm Ca ((14)NO(3))(2) revealed a half-time of depletion of root nitrate of about 2.5 hours. A large proportion of this depletion, however, was due to loss of (15)N-nitrate to the ambient (14)N-nitrate solution. The remaining pool of (15)N-nitrate was only slowly available for reduction. Total (15)N translocation to the shoot was relatively efficient during the first 3 hours after transfer to Ca ((14)NO(3))(2) but it essentially ceased after that time in spite of significant pools of (15)N-nitrate and alpha-amino-(15)N remaining in the root tissue.     

Caspase-2 involvement during ionizing radiation-induced oocyte death in the mouse ovary

In mammals, the pool of primordial follicles at birth is determinant for female fertility. Exposure to IR during oogonia proliferation and the diplotene stages of ovarian development induced the virtual disappearance of primordial follicles in the postnatal ovary, while half the follicular reserve remained present after irradiation during the zygotene/pachytene stages. This sensitivity difference was correlated with the level of caspase-2 expression evaluated by immunohistochemistry. At the diplotene stage, Western blot and caspase activity analysis revealed that caspase-2 was activated 2 h after irradiation and a significant increase in the number of oocytes expressing cleaved caspase-9 and -3 occurred 6 h after treatment. Inhibition of caspase-2 activity prevented the cleavage of caspase-9 and partially prevented the loss of oocytes in response to irradiation. Taken together, our results show that caspase-2-dependent activation of the mitochondrial apoptotic pathway is one of the mechanisms involved in the genotoxic stress-induced depletion of the primordial follicle pool.     

Hydroxyurea: effects on deoxyribonucleotide pool sizes correlated with effects on DNA repair in mammalian cells

We have measured deoxyribonucleotide pool sizes in different cell types: normal human, transformed human (HeLa), and the permanent hamster line CHO-K1. The range of sizes of the four DNA precursor pools in CHO cells is far greater than in human cells. It is a general rule that hydroxyurea causes rapid depletion of pools (except for dTTP) until the pool present in smallest amount is exhausted; this suggests a tight coupling of the pools to DNA replication (the presumed main cause of the depletion). The effect of hydroxyurea on DNA repair after ultraviolet irradiation (namely, a relatively small accumulation of incomplete repair sites blocked at the resynthesis stage) is probably accounted for by the reduced availability of DNA precursors. However, depletion of the dCTP pool is not an adequate explanation for the observed enhancement by hydroxyurea of the inhibitory effect of cytosine arabinoside; we suggest other possible modes of action. Ultraviolet irradiation has only small effects on the levels of deoxyribonucleotides.     

Laser impact on bacterial ATP: insights into the mechanism of laser-bacteria interactions

The mechanisms of laser action on bacteria are not adequately understood. Here, an attempt has been made to study the fluctuation in ATP (adenosine triphosphate) concentration following laser irradiation from a pulsed Nd:YAG laser on a marine biofilm-forming bacterium Pseudoalteromonas carrageenovora. A stationary phase bacterial suspension (density 10(7-8) ml-1) was exposed to pulsed laser irradiations at a fluence of 0.1 J cm-2 (pulse width 5 ns, repetition rate 10 Hz) for different durations, ranging from 2 s to 15 min. The total viable count (TVC) and ATP concentration of the irradiated samples were determined immediately after the laser irradiation. While the maximum reduction in the TVC observed with respect to the control was 59% immediately after 15 min irradiation, the ATP concentration showed a reduction of about 86% for the same duration. The ATP concentration showed an abrupt reduction from 3 min of laser irradiation and continued to reduce significantly with increasing duration of irradiation. Thus, 3 min irradiation at a fluence of 0.1 J cm-2 is considered as an approximate threshold for ATP production in this bacterium. As the decreased level of ATP production continued, bacterial mortality resulted. The reduction in ATP production could be due to damage caused by the laser irradiations on bacterial metabolic processes such as cellular respiration.     

Phytol Changes in Dark Grown Leaves of Barley after Varying Light Treatments

Gas chromatographic determinations revealed a certain amount of free phytol in dark-grown barley leaves. When a short light impulse or continuous light is given to the leaves, the phytol pool is partly emptied due to esterification of chlorophyllide a. The regeneration is slow during the first 2–3 hours. A pretreatment with light flashes followed by a dark period accelerates the regeneration, which stops however after approximately 30 min. Some evidence points to the existence of an acceptor for excess phytol entering at this stage. Connections between phytol changes during irradiation and the lag phase of chlorophyll formation are discussed.     

Integrin β1-dependent invasive migration of irradiation-tolerant human lung adenocarcinoma cells in 3D collagen matrix

Radiotherapy is one of the effective therapies used for treating various malignant tumors. However, the emergence of tolerant cells after irradiation remains problematic due to their high metastatic ability, sometimes indicative of poor prognosis. In this study, we showed that subcloned human lung adenocarcinoma cells (A549P-3) that are irradiation-tolerant indicate high invasive activity in vitro, and exhibit an integrin β1 activity-dependent migratory pattern. In collagen gel overlay assay, majority of the A549P-3 cells displayed round morphology and low migration activity, whereas a considerable number of A549P-3IR cells surviving irradiation displayed a spindle morphology and high migration rate. Blocking integrin β1 activity reduced the migration rate of A549P-3IR cells and altered the cell morphology allowing them to assume a round shape. These results suggest that the A549P-3 cells surviving irradiation acquire a highly invasive integrin β1-dependent phenotype, and integrin β1 might be a potentially effective therapeutic target in combination with radiotherapy.     

MOBILIZATION OF HAEMOPOIETIC STEM CELLS (CFU) INTO THE PERIPHERAL BLOOD OF THE MOUSE; EFFECTS OF ENDOTOXIN AND OTHER COMPOUNDS

Factors affecting the circulation of haemopoietic stem cells (CFU) in the peripheral blood of mice were investigated. I.v. injection of sublethal doses of endotoxin, trypsin and proteinase appeared to raise the number of CFU per ml blood from about 30–40 to about 300–400 or more within 10 min. The effect was smaller when smaller doses of the substances were injected. After this initial rise the number of circulating cells returned to normal in a few hours. Following endotoxin there was a second rise which started 2–3 days after injection and attained a peak on the 6th–7th day. The first rise is explained as a mobilization of stem cells from their normal microenvironments into the blood stream; the second rise is considered to reflect proliferation of CFUs in the haemopoietic tissues. The spleen seems to be acting as an organ capturing CFUs from the blood and not as a source adding stem cells to the blood.
The early mobilization of CFU after endotoxin injection did not coincide with a mobilization of neutrophils. The number of circulating band cells was increased during the first hours.
The importance of 'open sites'in the haemopoietic tissue for capturing CFUs was studied by emptying these sites through a lethal X-irradiation and injecting normal bone marrow cells. When a greater number of syngeneic bone marrow cells was injected intravenously, the level of circulating CFU in irradiated mice was slightly lower than the level in unirradiated mice during the first hours.     

Radiomodifying effect of serotonin on the cells of the hematopoietic system

Mice were injected with serotonin (0.5 and 2.0 mg/mouse) 15 min before and immediately after irradiation (4.5 and 7.0 Gy). With the preparation administered prior to irradiation one could observe an increase in the quantity of CFUc survived (endo- and exo-test), acceleration of restoration of cellularity (in the bone marrow) and growth of the spleen weight. The acceleration of restoration of the bone-marrow cellularity was also noted when serotonin was administered after irradiation. The post-irradiation effect of serotonin was also detected in cells in vitro. It is concluded that the radiomodifying effect of serotonin on the haemopoietic system is due to a decrease in the number of damaged cells and increase in the rate of reproduction of intact cells.     

Effect of BCG on hematopoietic stem cells: Experimental and clinical study

Summary In (DBA/2×C57Bl/6) F1 mice the i.v. injection of 1 mg of living BCG does not increase the total number of CFU/s per femur, but a marked increase in the percentage of CFU/s in S phase is noted as early as the 8th hr. BCG injected i.v. also increases the absolute number of colony-forming units in agar per femur. The effect of BCG appears quite different from the known effect of bacterial endotoxin, and in particular it does not induce a significant increase in the level of CSF. The administration of BCG 24 hrs after treatment with a single dose of 200 mg/kg of cyclophosphamide significantly reduces the time of hematologic restoration, but the same dose of BCG given after a lethal dose of total body irradiation does not increase survival time in mice. These different effects of BCG seem to be related to the role of BCG in stimulating the multiplication maturation pool of the bone marrow without producing any increase in the reserve pool.     

Amino acid pools in CHL V79 cells during induction of thermotolerance: reduction in free intracellular glutamine

The amino acid pools in Chinese hamster lung V79 cells were measured as a function of time during hyperthermic exposure at 40.5 degrees and 45.0 degrees C. Sixteen of the 20 protein amino acids were present in sufficient quantity to measure accurately. The total amino acid pool and all individual amino acids, except glutamine, remained relatively constant for at least 90 min at 40.5 degrees C and for 30 min at 45 degrees C. The glutamine pool decreased rapidly to 20% of its control value within 30 min at 40.5 degrees C with a T1/2 = 15 min. At 45 degrees C, the decrease was 36%. Thermotolerance developed at 40.5 degrees C with a T1/2 = 30 min; thus, glutamine depletion preceeds the development of thermotolerance. The depletion of glutamine is probably due to increased metabolism and oxidation of glutamine through the TCA cycle at hyperthermic temperatures. Glutamine, as is true for other amino acids, was shown to protect proteins from thermal inactivation and V79 cells from hyperthermic killing when added in excess (4-10 mM) to the medium during heat stress. However, the stability of the total amino acid pool during the development of thermotolerance indicates that resistance to heat does not result from the accumulation of amino acids which then protect against thermal damage. The effects of the large decrease in the glutamine pool are unknown, although glutamine depletion may act as a signal for part of the heat shock response.     

Effect of glycolysis on the metabolism of adenylates in human erythrocytes

The ATP content in human erythrocytes depleted without glucose falls down to half of the initial value within 2-3 hours and reaches practically zero within more than 10 hours. The ADP content increases 2-3-fold during the 1st hour after depletion and then slowly decreases. The AMP content increases 10-fold during several hours, but the rate of this process constantly decreases. The adenylate pool decreases at a constant rate ranging from 0.13 to 0.25 mmol/l cell. h; this is accompanied by accumulation of IMP. Addition of glucose to depleted erythrocytes results in partial recovery of the ATP level within 1-2 hours. The sooner glucose addition after the depletion, the greater the recovery. Simultaneously the ADP and AMP levels drastically decrease to new constant values. The decline of the adenylate pool ceases and the rate of IMP accumulation increases. Normally, the [ATP]/adenylate pool ratio lies within the small interval 0.85-0.94 irrespective of significant individual differences in the absolute values of [ATP]. This ratio is decreased during depletion and restored to the initial value after glucose addition. The mass-action ratio of the adenylate kinase reaction changes greatly during depletion and restoration of erythrocyte ATP.     

Laser Impact on Bacterial ATP: Insights into the Mechanism of Laser-Bacteria Interactions

The mechanisms of laser action on bacteria are not adequately understood. Here, an attempt has been made to study the fluctuation in ATP (adenosine triphosphate) concentration following laser irradiation from a pulsed Nd:YAG laser on a marine biofilm-forming bacterium Pseudoalteromonas carrageenovora. A stationary phase bacterial suspension (density 10^7-8 ml^{m 1}) was exposed to pulsed laser irradiations at a fluence of 0.1 J cm^{m 2} (pulse width 5 ns, repetition rate 10 Hz) for different durations, ranging from 2 s to 15 min. The total viable count (TVC) and ATP concentration of the irradiated samples were determined immediately after the laser irradiation. While the maximum reduction in the TVC observed with respect to the control was 59% immediately after 15 min irradiation, the ATP concentration showed a reduction of about 86% for the same duration. The ATP concentration showed an abrupt reduction from 3 min of laser irradiation and continued to reduce significantly with increasing duration of irradiation. Thus, 3 min irradiation at a fluence of 0.1 J cm^{m 2} is considered as an approximate threshold for ATP production in this bacterium. As the decreased level of ATP production continued, bacterial mortality resulted. The reduction in ATP production could be due to damage caused by the laser irradiations on bacterial metabolic processes such as cellular respiration.     

Involvement of membrane GABA transporter in alpha-latrotoxin-stimulated [3H]GABA release

Alpha-latrotoxin evokes massive [3H]GABA release from rat brain synaptosomes by stimulating exocytosis and outflow from non-vesicular pool. In the present study, GABA transporter-mediated [3H]GABA release was shown to be involved in alpha-latrotoxin-triggered release of [3H]GABA from non-vesicular pool. The following agents have been exploited as tools: (1) a protonophore carbonyl cyanide-p-trifluoromethoxyphenyl-hydrazon (FCCP) and bafilomycin A1 for evoking depletion of synaptic vesicle [3H]GABA and enlargement of non-vesicular pool; (2) a non-substrate high-affinity GABA transport blocker NO-711 for determining participation of GABA carrier in the toxin-stimulated GABA release; (3) a competitive inhibitor of GABA reuptake nipecotic acid for heteroexchange [3H]GABA release. As shown by the experiments with nipecotic acid, FCCP and bafilomycin A1 considerably increase the content of non-vesicular [3H]GABA. The treatment of the synaptosomes with these agents modified the response to alpha-latrotoxin, particularly to its subnanomolar concentrations: the lack or substantial lowering of the toxin-evoked release during the first 2 min after the toxin addition and substantial enhancement of release up to the 5th minute were observed. Only the step of enhanced release was sensitive to GABA transporter blocker NO-711. Distinct sensitivity to NO-711 was shown to be characteristic for different steps of alpha-latrotoxin-stimulated [3H]GABA release from the control, untreated synaptosomes: lack of any effect of NO-711 during the first 2 min and powerful inhibition in 10 min after the toxin application. Taken together these data appear to indicate that the toxin non-simultaneously from vesicular and non-vesicular origins releases the neurotransmitter, the first rapid step reflects exocytosis stimulation, and the second tardy step is at least in part due to the release mediated by GABA transporters. The incomplete inhibition with NO-711 of the tardy step of the release evoked by nanomolar toxin concentrations suggests the participation not only of the GABA transporters.     

Metabolic Pools of ATP in Cultured Bovine Adrenal Medullary Chromaffin Cells

Cultured bovine adrenal chromaffin cells contain a pool of ATP sequestered within the chromaffin vesicles and an extravesicular pool of ATP. In a previous study it was shown that the turnover of ATP in the extravesicular pool was biphasic. One phase occurred with a t1/2 of 3.5-4.5 h whereas the second phase occurred with a t1/2 of several days. The studies described here were undertaken to characterize further the vesicular and extravesicular pools of ATP by examining the effects of metabolic inhibitors, adenosine, and digitonin on ATP utilization and subcellular localization immediately after and 48 h after labeling with [3H]adenosine and 32Pi. Immediately after labeling a combination of cyanide, 2-deoxy-D-glucose, the beta-glucono-1,5-lactone resulted in a 90-95% depletion of the labeled ATP but only a 25% depletion of the endogenous ATP within 30 min. Forty-eight hours after labeling, addition of the inhibitors resulted in a 70% depletion of the [3H]ATP but only a 25% depletion of the [32P]ATP and endogenous ATP. Addition of 10 microM adenosine to the media resulted in a similar loss of [3H]ATP in cells examined immediately after or 48 h after labeling. Adenosine increased the amounts of [32P]ATP when added immediately after labeling but had no effect on the [32P]ATP content when added 48 h after labeling.(ABSTRACT TRUNCATED AT 250 WORDS)     

Mutagenic effect of cyclophosphan on bone marrow cells of irradiated rats]

The rate of chromosome aberrations in bone marrow cells of male rats was investigated in 24 hours after the cyclophosphan intraperitoneal injection (25 mg/kg). Cyclophosphan was given to rats exposed earlier (15 days, 1, 3, 4, 6 or 9 months before) to X- and gamma-irradiation (400 rads). It was found that preliminary irradiation led to the increase in the mutagenic effect of cyclophosphan as compared to that obtained for intact rats. This effect was demonstrated during 4 months after acute X-irradiation at a dose rate of 70 rads/min and during 1 month after chronic gamma-irradiation at a dose rate of 100 rads/day. Later the effect was shown to disappear in both cases. Chronic irradiation was found to be less efficient in the stimulation of chromosome damages caused by chemical mutagens. The increase of the mutagenic effect of cyclophosphan resulted in the increase of both the number of cells carrying chromosome breaks and the severity of a damage per cell. Different ways of the irradiation effect on the mutagenic action of chemicals are discussed.