Subchromosomal DNA synthesis in synchronous V-79 chinese hamster cells after X irradiation

A substantial fraction of replicon initiation events in Chinese hamster V-79 cells have been shown to be refractory to the effects of X irradiation immediately after exposure. This study examines the possibility that the initiation radiorefractive portion is the result of changes in replicon radiosensitivity as a function of position in S phase. The data obtained from DNA fiber autoradiograms and kinetic incorporation of radiolabeled thymidine from cells irradiated at various positions in S phase showed only slight changes in the proportion of replicons refractive to X irradiation immediately after exposure. These results indicate that initiation radiorefractive replicons may be an intrinsic property of V-79 cells and that cell-cycle-specific heterogeneity in radiation response cannot fully account for this phenomenon. The results also indicate that delayed inhibition of initiation events may play a larger role in the observed radiorefractive fraction than previously thought.     

Inhibition of initiation of simian virus 40 DNA replication during acute response of cells irradiated by ultraviolet light.

To study the mechanism by which ultraviolet (UV) light inhibits DNA replication, we examined the effects of UV 254 nm irradiation on the replication of simian virus 40 (SV40) DNA and SV40-based plasmid in monkey cells. The study was designed to determine the relative contributions made by inhibition of replication initiation and chain elongation to the immediate inhibition of DNA replication following UV irradiation. We used two-dimensional neutral-alkaline electrophoresis to examine the behaviour of replication intermediates unambiguously. Kinetic analysis using this technique showed that initiation of replication started to decline at 15 min post-irradiation. When the pulse label incorporated in SV40 replication intermediates before irradiation was chased for 1 h, most of the label was found in mature Form I and II molecules. This indicated that replication elongation took place on damaged template. We also used a transfection technique to show that heavily irradiated plasmids replicated efficiently in unirradiated transfected cells. By the transfection technique, we observed that UV irradiation of host cells dose-dependently inhibited replication of transfected non-irradiated plasmids, suggesting that the inhibition of DNA replication is due to a global change in cellular physiology induced by UV. This change was also apparent from poor staining of the chromatin by fluorescent-DNA-binding dyes immediately after UV irradiation of intact cells. We conclude that a significant fraction of chain elongation proceeds on damaged templates and DNA replication during the acute response of cells irradiated with UV is mainly controlled by the inhibition of replication initiation.     

Radiosensitivity of Mammalian Cells: IV. Effects of X-Irradiation on the DNA Synthetic Period in Synchronized Cells

The effect of X-irradiation on the timing of DNA synthesis in the Chinese hamster ovary cells has been investigated. Mitotically synchronized cells irradiated in mitosis or early G₁ exhibited a fixed, dose-independent (150-2000 rad) delay of 1.6 hr in entry into S, while the duration of S was unaffected. Cells irradiated during late G₁ or the first 0.8 hr of S were not affected either in time of initiation or duration of S. However, when cells 0.8 hr or more into S were irradiated, completion but not initiation of DNA synthesis was delayed, indicating a very precise separation of X-ray effects upon initiation and replication. There was no indication of a re-ordering of cells following irradiation and recovery, since cells in G₂ at the time of irradiation always divided before cells irradiated in S. The results suggest that two separate functions required for initiation and continued replication of DNA may be differentially sensitive to X-irradiation.     

The catalytic subunit DNA-dependent protein kinase (DNA-PKcs) facilitates recovery from radiation-induced inhibition of DNA replication

Exposure of cells to ionizing radiation inhibits DNA replication in a dose-dependent manner. The dose response is biphasic and the initial steep component reflects inhibition of replicon initiation thought to be mediated by activation of the S-phase checkpoint. In mammalian cells, inhibition of replicon initiation requires the ataxia telagiectasia mutated (ATM) gene, a member of the phosphatidyl inositol kinase-like (PIKL) family of protein kinases. We studied the effect on replicon initiation of another member of the PI-3 family of protein kinases, the catalytic subunit of DNA-dependent protein kinase (DNA-PKcs) by measuring either total DNA synthesis, or size distribution of nascent DNA using alkaline sucrose gradient centrifugation. Exposure of human cells proficient in DNA-PKcs (HeLa or M059-K) to 10 Gy inhibited replicon initiation in a time-dependent manner. Inhibition was at a maximum 1 h after irradiation and recovered at later times. Similar treatment of human cells deficient in DNA-PKcs (M059-J) inhibited replicon initiation to a similar level and with similar kinetics; however, no evidence for recovery, or only limited recovery, was observed for up to 8 h after irradiation. In addition a defect was observed in the maturation of nascent DNA. Similarly, a Chinese hamster cell line deficient in DNA-PKcs (irs-20) showed little evidence for recovery of DNA replication inhibition up to 6 h after irradiation, whereas the parental CHO cells showed significant recovery and an irs-20 derivative expressing the human DNA-PKcs complete recovery within 4 h. Normal kinetics of recovery were observed in xrs-5 cells, deficient in Ku80; in 180BR cells, deficient in DNA ligase IV; as well as XR-1 cells, deficient in XRCC4, an accessory factor of DNA ligase IV. Since all these cell lines share the DNA double strand break rejoining defect of M059-J and irs20 cells, the lack of recovery of DNA replication in the latter cells may not be attributed entirely to the prolonged presence of unrepaired DNA dsb. We propose that DNA-PKcs, in addition to its functions in the rejoining of DNA dsb and in DNA replication, also operates in a pathway that in normal cells facilitates recovery of DNA replication after irradiation.     

Ultraviolet light-induced inhibition of small nuclear RNA synthesis

Two apparently distinct types of inhibition of the synthesis of U1, U2, U3, U4, and U5 small nuclear RNA, induced by ultraviolet (UV) radiation, have been described before: immediate and delayed. Our present observation can be summarized as follows: a) neither the immediate nor the delayed inhibition appear to be mediated by the formation of cyclobutane pyrimidine dimers, since they were not prevented by photoreactivating light, in ICR 2A frog cells; b) the inhibition of U1 RNA synthesis, monitored in HeLA cells within the first few minutes after irradiation, extrapolated to a substantial suppression at time zero of postirradiation cell incubation, providing further support for the proposal that the immediate inhibition is a reaction separate from the delayed UV light-induced inhibition of U1 RNA synthesis; c) the transition from the pattern of the immediate inhibition to that of the delayed inhibition (disappearance of the UV-resistant fraction of U1 RNA synthesis and increased rate of inhibition) occurred gradually, without an apparent threshold, within the first 2 hr of incubation after irradiation; and d) the incident UV dose that resulted in a 37% level of residual U1 RNA synthesis (D37) during the delayed inhibition was about 7 J/m2, with an apparent UV dose threshold, and was about 60 J/m2 for the immediate inhibition.     

Effect of tannic acid on the synthesis of protein and nucleic acid by rat liver

1. As early as 1hr. after the intraperitoneal administration of tannic acid to rats, it could be demonstrated in the liver. At 3hr. the nuclear fraction contained the largest amount of tannic acid. 2. Nuclear RNA synthesis was inhibited in vivo 2hr. after the administration of tannic acid. Induction by cortisol of tryptophan pyrrolase was 90% inhibited at 24hr. 3. Incorporation of [1-(14)C]leucine into protein by liver slices from treated rats was decreased by 50% after 24hr. Its incorporation into postmitochondrial supernatant from treated animals was not inhibited. Incorporation into slices and postmitochondrial supernatants were inhibited in vitro by tannic acid. 4. The sequence of events: concentration of tannic acid in nuclei, inhibition of nuclear RNA synthesis, inhibition of protein synthesis and production of necrosis, is discussed.     

HYDROXYUREA EFFECTS IN THE C3H MOUSE II. MAMMARY TUMOR CELL KINETICS

The cellular kinetics of C3H mouse mammary tumors were studied following a single dose (3 mg/g body weight) of hydroxyurea (HU). This dose was large enough to cause a significant perturbation in the growth curves of these tumours. This was accomplished by labeling the cells with tritiated 5-iodo-2'-deoxyuridine and performing detailed autoradiographic analysis. This dose of HU caused a temporary inhibition in growth and completely inhibited DNA synthesis for 4–5 hr. The HU-killed cells (pyknotic and karyorrhectic) reach a maximum around 10–12 hr and are apparently all removed in about 1 day. Tumors from a fast-growing line (S102F) showed some evidence for cell synchrony upon recovery from HU inhibition but desynchronization occurred within one cell cycle. The cell generation time was not decreased during the acute recovery phase, but the growth fraction shifted from 0·6 to 1·0, and the data suggested that the normal flow of cells from the proliferating pool to the degenerate pool was temporarily interrupted. The cellular kinetic parameters have probably returned to normal by 48 hr after the HU injection.     

Analysis of cell flow and cell loss following X-irradiation using sequential investigation of the total number of cells in the various parts of the cell cycle

The cell flow and cell loss of an in vivo growing Ehrlich ascites tumour were calculated by sequential estimation of changes in the total number of cells in the cell cycle compartments. Normal growth was compared with the grossly disturbed cell flow evident after a 5 Gy X-irradiation. The doubling time of normal, exponentially growing cells was 24 hr. The generation time was 21 hr based on double-isotope labelling studies and the potential doubling time was 21 hr. Thus, the growth fraction was 1.0 and the cell loss rate about 0.5%/hr. Following irradiation, a transiently increased relative outflow rate from all cell cycle compartments was found at about 3 and 40 hr, and from S phase at 24 hr after irradiation. Minimum flow rates from all compartments were found up to 20 hr. Cell loss as calculated from the cell flow was compared with non-viable cells determined by Percoll density separation. Increase in cell loss as well as non-viable cells was observed at 24 hr after irradiation at the time of release of the irradiation-induced G2 blockage. Up to 50 hr, about 70% of the initial total number of cells were lost. The experiments show the applicability and limitations of cell flow and cell loss calculations by sequential analysis of the total number of cells in the various parts of the cell cycle.     

Effect of Trifluoperazine On Dna Synthesis During Liver Regeneration

Abstract. An intraperitoneal injection of the calcium-calmodulin blocker trifluoperazine into rats at 4 hr after a partial hepatectomy produced a strong inhibition of DNA synthesis observed at 24 hr after surgery; but when injection was administered at 20 hr after hepatectomy, it did not produce any effect on DNA replication. These observations indicate that trifluoperazine acted by blocking one or more events involved in triggering DNA replication but it did not affect on-going DNA synthesis. A more detailed study indicated that when trifluoperazine was injected at 4 hr after surgery, a 12 hr delay in the cytosolic calmodulin surge observed between 6 and 12 hr after partial hepatectomy (previous to initiation of DNA replication) and also in the starting of DNA synthesis was produced. These findings suggest that the pre-replicative surge of cytosolic calmodulin could be involved in triggering DNA synthesis observed after partial hepatectomy.     

Effect of trifluoperazine on DNA synthesis during liver regeneration

An intraperitoneal injection of the calcium-calmodulin blocker trifluoperazine into rats at 4 hr after a partial hepatectomy produced a strong inhibition of DNA synthesis observed at 24 hr after surgery; but when injection was administered at 20 hr after hepatectomy, it did not produce any effect on DNA replication. These observations indicate that trifluoperazine acted by blocking one or more events involved in triggering DNA replication but it did not affect on-going DNA synthesis. A more detailed study indicated that when trifluoperazine was injected at 4 hr after surgery, a 12 hr delay in the cytosolic calmodulin surge observed between 6 and 12 hr after partial hepatectomy (previous to initiation of DNA replication) and also in the starting of DNA synthesis was produced. These findings suggest that the pre-replicative surge of cytosolic calmodulin could be involved in triggering DNA synthesis observed after partial hepatectomy.     

Effect of Rehydration on Recovery, Repair, and Growth of Injured Freeze-Dried Salmonella anatum

From 70 to 90% of the Salmonella anatum cells that survived freeze-drying in nonfat milk solids were injured. After rehydration, these injured survivors failed to grow on a selective plating medium containing deoxycholate but could form colonies on a nonselective medium. In a suitable environment after rehydration, injury disappeared in most of these cells. The rate of this repair at 25 C was very rapid initially and, in a medium containing milk solids, was completed within 1 hr after rehydration. The repaired cells initiated growth about 1 hr later than normal cells and grew at a slower rate. In a medium containing milk solids, initial recovery, extent of repair of injury, initiation of growth, and rate of growth were not influenced by supplementation with extra nutrients in other rehydration media. Rehydration controlled by modifying the concentrations of lactose, sucrose, or milk solids in the rehydration medium influenced the recovery of cells and the time that growth was initiated. Glycerol failed to increase recovery. Higher numbers of cells were recovered by rehydrating at 15 to 25 C, but an earlier initiation of growth and more rapid growth were observed at 35 C.     

Dose-dependent cytokinetic changes following 1-beta-D-arabinofuranosylcytosine and hydroxyurea in L1210 and S-180 in vivo.

DNA synthesis inhibition and recovery in L1210 and S-180 ascites tumors following 1-beta-D-arabinofuranosylcytosine (Ara-C) and hydroxyurea (HU) were measured autoradiographically as a basis for optimizing drug schedules. Tumor bearing mice, 10(6) cells day 0, were treated on day 4 with 20, 200 or 2000 mg/kg Ara-C or 50, 300 or 1800 mg/kg HU. At various intervals following drug, [3H]thymidine was administered i.p. and mice were killed 1 hr later. Tumor cells were analyzed for labeling index (LI) and grain count (GC) to determine the percentage of cells in S phase and the distribution of DNA synthesis rates among the labeled cells, respectively. Following each dose of HU, DNA synthesis was inhibited completely. Recovery of LI was rapid and approached control values by 6 hr. Following each dose of Ara-C, DNA synthesis was inhibited completely for at least 6 hr. Recovery of LI was first noted 6 hr following 20 mg/kg Ara-C and 9 hr following 200 mg/kg. Following both doses the LI reached 100% of the control value by 26 hr. GC analysis indicated that following Ara-C treatment, DNA synthesis was reinitiated first with cells with low GC from 6 to 12 hr followed by cells with increasing GC from 12 to 20 hr. The labeling intensity reached control values by 20 hr and an 'overshoot' occurred by 26 hr. These data suggest that the recovery of DNA synthesis rate is a gradual process. Survival data for mice receiving two doses of Ara-C indicated that the optimal interval for retreatment following the lower dose of Ara-C occurred by 6 hr as compared to 12--16 hr for the higher dose. These times coincided in both instances with recovery of LI to 33--50% of control values. Early recovery of LI may be the best method currently available for estimating the optimal time for retreatment with an S phase specific drug.     

Demonstration of a late amiloride-sensitive event as a necessary step in initiation of DNA synthesis by thrombin

Amiloride, a Na⁺ influx inhibitor, has been shown to inhibit initiation of DNA synthesis by thrombin in mouse embryo fibroblast-like cells. Long exoosures (24 hr) to high concentrations of amiloride inhibited incorporation of thymidine into the DNA of both thrombin-stimulated and nonstimulated cells, suggesting that this inhibition might not be specific for thrombin-initiated DNA synthesis. Fluorescence microscopy and spectrofluorimetry showed that amiloride was internalized with an apparent mitochondrial association and that the internalized amiloride was readily released from the cells after removing amiloride from the medium. Based on this reversibility, cells were exposed to amiloride for short periods of time during thrombin treatment to determine the temporal relationship between any amiloride-sensitive event(s) and initiation of DNA synthesis. The presence of amiloride (100 μM) during a 12-hr exposure to thrombin did not block thrombin-initiated DNA synthesis or cell division but did delay the onset of DNA synthesis and the peak of thymidine incorporation into DNA by approximately 3 hr, suggesting that early initiation events might proceed in the presence of amiloride. ⁸⁶Rb⁺ transport studies demonstrated that in this system ouabain-sensitive K⁺ uptake via the Na, K-ATPase was stimulated by thrombin during both an early and a late period. This stimulation was amiloride-sensitive under the same conditions used for growth experiments, suggesting that amiloride was inhibiting thrombin-stimulated Na⁺ transport in this system. Additional experiments showed that exposing cells to amiloride only during the first 8 hr after thrombin addition did not inhibit initiation. The presence of amiloride from 8–12 hr after thrombin addition maximally inhibited thrombin-stimulated DNA synthesis. Together these results demonstrate that amiloride inhibits thrombin-initiated DNA synthesis not by inhibiting an early event occurring during the first 8 hr, but rather by inhibiting some later event 8–12 hr after thrombin addition.     

In vitro studies of the rabbit immune system: III. T-cell requirement for initiation but not maintenance of anti-sheep erythrocyte plaque-forming cells

The in vitro anti-sheep erythrocyte plaque-forming-cell (anti-SRBC PFC) response of primed rabbit spleen cells can be abrogated by prior treatment with anti-thymocyte serum plus complement (ATS + C). The direct addition of ATS without C to stimulated cultures also reduces the response 60–90%, if the antiserum is added before the initiation of antigen-stimulated PFC production. However, the PFC response becomes refractory to ATS inhibition by 48 hr. This loss of ATS sensitivity is not caused by T cells themselves becoming refractory to ATS for the following reasons: (i) ATS + C treatment or ATS addition at 48 hr causes cytotoxic effects comparable to similar treatments at 0 hr; (ii) The responsiveness of cells incubated 48 hr before the addition of SRBC remains sensitive to ATS inhibition at that time. The loss of ATS sensitivity is also not the result of soluble T-cell factors which have accumulated in the medium, because the number of PFC in stimulated cultures continues to increase after treating with ATS + C and reculturing in fresh medium at 48 hr. We conclude that T cells are required to initiate the production of antibody by B cells but are not required to maintain the later proliferative events.     

Characteristics of the isoprenaline stimulated proliferative response of rat submaxillary gland.

A simple stochastic model has been developed to determine the cell cycle kinetics of the isoprenaline stimulated proliferative response in rat acinar cells. The response was measured experimentally, using 3H-TdR labelling of interphase cells and cumulative collections of mitotic cells with vincristine. The rise and fall of the fraction of labelled interphase cells and of metaphase cells is expressed by the product of the proliferative fraction and a difference of probability distributions. The probability statements of the model were formulated and then compared by an iterative fitting procedure to experimental data to obtain estimates of the model parameters. The model when fitted to the combined fraction labelled interphase (FLIW) and fraction metaphase (FMWa) waves gave a mean Gis transit time of 21-2 hr, mean Gis +S transit time of 27-0 hr, and mean Gis + S + G2 transit time of 35-8 hr for a single injection of isoprenaline, where Gis is the initiation to S phase time. When successive injections of isoprenaline were given at intervals of 24 and 28 hr the corresponding values after the third injection were 12-4 hr, 20-8 hr and 25-7 hr respectively. The variance of the Gis phase dropped from 18-1 to 1-3 while the other variances remained unchanged. The estimated proliferative fraction was 0-24 after a single injection of isoprenaline, and 0.31 after three injections of the drug. Independently determined values of the proliferative fraction, obtained from repeated 3H-TdR injections, were 0-21 and 0-36 respectively.     

Biochemical and cellular mechanisms of low-dose effects

Low-dose irradiation is usually considered to be rather ineffective in producing biologically relevant effects. Yet, individual radiation absorption events within cell nuclei or whole cells interact stochastically with subcellular structures due to the multiple ionizations along primary or secondary particle tracks, depending on ionization density. Whereas radiation effects are usually seen in the context of structure and function of DNA, other cellular effects, perhaps influencing DNA by secondary biochemical mechanisms, also warrant attention. Thus, previous work from this laboratory with bone marrow that was obtained from whole-body exposed mice, has shown that single or few instantaneous radiation absorption events per cell from gamma-rays produce an acute and temporary partial inhibition of the enzyme thymidine kinase; the effect appears within about 1 h after the event, reaches its maximum at approximately 4 h and disappears completely within another 6 h. This pattern of enzyme inhibition is fully concordant with the pattern of inhibition of uptake of tritiated thymidine or 125I-labelled deoxyuridine into the DNA; also concordant is a temporary increase in the concentration of free thymidine in the blood serum of the exposed mice. The particular response of thymidine kinase was considered to relate to some, thus far unknown, repair systems and/or to a defence mechanism of the hit cells. In order to further elucidate the role of the acute and temporary partial inhibition of thymidine kinase in cellular metabolism, experiments were carried out in which mice were acutely exposed to 0.01 or 0.1 Gy and again exposed to the same dose at different times up to 12 h after the first exposure. At regular time intervals after the second exposure bone marrow cells were obtained and thymidine kinase activity was studied by various assays. The results indicate that the first acute irradiation conditioned the cells in such a way that the second acute irradiation produced either an enhanced inhibition and recovery of thymidine kinase activity, or no effect at all was seen, when the second irradiation was given between about 3 and 8 h after the first irradiation. From 8 to 12 h after the first irradiation the cells apparently resumed their original state, so that the second irradiation produced effects quite similar to those seen after a single irradiation in unconditioned cells.(ABSTRACT TRUNCATED AT 400 WORDS)     

Analysis of Cell Flow and Cell Loss Following X-Irradiation Using Sequential Investigation of the Total Number of Cells In the Various Parts of the Cell Cycle

The cell flow and cell loss of an in vivo growing Ehrlich ascites tumour were calculated by sequential estimation of changes in the total number of cells in the cell cycle compartments. Normal growth was compared with the grossly disturbed cell flow evident after a 5 Gy X-irradiation. The doubling time of normal, exponentially growing cells was 24 hr. the generation time was 21 hr based on double-isotope labelling studies and the potential doubling time was 21 hr. Thus, the growth fraction was 1.0 and the cell loss rate about 0.5%/hr. Following irradiation, a transiently increased relative outflow rate from all cell cycle compartments was found at about 3 and 40 hr, and from S phase at 24 hr after irradiation. Minimum flow rates from all compartments were found up to 20 hr. Cell loss as calculated from the cell flow was compared with non-viable cells determined by Percoll density separation. Increase in cell loss as well as non-viable cells was observed at 24 hr after irradiation at the time of release of the irradiation-induced G₂ blockage. Up to 50 hr, about 70% of the initial total number of cells were lost. the experiments show the applicability and limitations of cell flow and cell loss calculations by sequential analysis of the total number of cells in the various parts of the cell cycle.     

Dose-Dependent Cytokinetic Changes Following 1-β-D-Arabinofuranosylcytosine and Hydroxyurea In L1210 and S-180 In Vivo

DNA synthesis inhibition and recovery in L1210 and S-180 ascites tumors following 1-β-D-arabinofuranosylcytosine (Ara-C) and hydroxyurea (HU) were measured autoradiographically as a basis for optimizing drug schedules. Tumor bearing mice, 10⁶ cells day O, were treated on day 4 with 20, 200 or 2000 mg/kg Ara-C or 50, 300 or 1800 mg/kg HU. At various intervals following drug, [³H]thymidine was administered i.p. and mice were killed 1 hr later. Tumor cells were analyzed for labeling index (LI) and grain count (GC) to determine the percentage of cells in S phase and the distribution of DNA synthesis rates among the labeled cells, respectively. Following each dose of HU, DNA synthesis was inhibited completely. Recovery of LI was rapid and approached control values by 6 hr. Following each dose of Ara-C, DNA synthesis was inhibited completely for at least 6 hr. Recovery of LI was first noted 6 hr following 20 mg/kg Ara-C and 9 hr following 200 mg/kg. Following both doses the LI reached 100% of the control value by 26 hr. GC analysis indicated that following Ara-C treatment, DNA synthesis was reinitiated first with cells with low GC from 6 to 12 hr followed by cells with increasing GC from 12 to 20 hr. the labeling intensity reached control values by 20 hr and an ‘overshoot’ occurred by 26 hr. These data suggest that the recovery of DNA synthesis rate is a gradual process. Survival data for mice receiving two doses of Ara-C indicated that the optimal interval for retreatment following the lower dose of Ara-C occurred by 6 hr as compared to 12–16 hr for the higher dose. These times coincided in both instances with recovery of LI to 33–50% of control values. Early recovery of LI may be the best method currently available for estimating the optimal time for retreatment with an S phase specific drug.     

Population dynamics of the murine lymphokine activated killer system: precursor frequency and kinetics of maturation and renewal

Abstract The proliferation kinetics and population renewal of recombinant interleukin-2 (rIL-2)-induced murine lymphokine activated killers (LAK) arising from splenic precursors was studied. Extensive proliferation has been shown to accompany the de novo generation of LAK cytotoxicity. In this report, a thymidine 'hot pulse' suicide technique was employed to examine the sensitivity of LAK progenitors during various time periods following culture initiation. Hot pulse during the first 24 hr of culture resulted in a 30–35% reduction in lytic activity when assayed on day 5. Pulse periods between days 1 and 4 resulted in almost complete inhibition (90–95%) of lytic function when assayed on day 5. Proliferation of LAK progenitors was documented by limiting dilution analysis comparison of splenic precursors and functionally mature LAK cultures. These studies showed a 75- to 80-fold enrichment of LAK progenitors after 3 days culture in rIL-2. By flow cytometric cell cycle analysis, we demonstrated that the number of cells in the S/G₂/M phase increased with the length of rIL-2 culture and represented approximately 40% of the cells by day 4. Finally, we used the rate of decay of lytic activity following irradiation as a factor to define the mean life span of a cytotoxic effector in the absence of cellular input. An exponential decrease to approximately 50% of controls was observed within 8–9 hr after irradiation. Taken together, these results suggest that the LAK system is highly dynamic and requires continuous cellular proliferation for its maintenance.     

Population dynamics of the murine lymphokine activated killer system: precursor frequency and kinetics of maturation and renewal

The proliferation kinetics and population renewal of recombinant interleukin-2 (rIL-2)-induced murine lymphokine activated killers (LAK) arising from splenic precursors was studied. Extensive proliferation has been shown to accompany the de novo generation of LAK cytotoxicity. In this report, a thymidine 'hot pulse' suicide technique was employed to examine the sensitivity of LAK progenitors during various time periods following culture initiation. Hot pulse during the first 24 hr of culture resulted in a 30-35% reduction in lytic activity when assayed on day 5. Pulse periods between days 1 and 4 resulted in almost complete inhibition (90-95%) of lytic function when assayed on day 5. Proliferation of LAK progenitors was documented by limiting dilution analysis comparison of splenic precursors and functionally mature LAK cultures. These studies showed a 75- to 80-fold enrichment of LAK progenitors after 3 days culture in rIL-2. By flow cytometric cell cycle analysis, we demonstrated that the number of cells in the S/G2/M phase increased with the length of rIL-2 culture and represented approximately 40% of the cells by day 4. Finally, we used the rate of decay of lytic activity following irradiation as a factor to define the mean life span of a cytotoxic effector in the absence of cellular input. An exponential decrease to approximately 50% of controls was observed within 8-9 hr after irradiation. Taken together, these results suggest that the LAK system is highly dynamic and requires continuous cellular proliferation for its maintenance.