Adaptation to cycloheximide of macromolecular synthesis in Tetrahymena

Cycloheximide (CHI) at 10 ng/ml partially inhibited protein synthesis in exponential cultures of Tetrahymena Sp. At 20 ng/ml or greater, inhibition was complete. When protein synthesis was inhibited to any extent, cell division ceased immediately. In all instances where measured, synthesis of RNA and DNA also ceased. After a period of delay, cellular functions reinitiated in the order: (i) protein synthesis, (ii) DNA synthesis and, (iii) RNA synthesis and cell division. The delay in cell division was divided into three phases of: I, zero; II, low; and, III, fully recovered rates of exponential protein synthesis. The length of the three phases increased with increasing concentration of CHI Prior growth of cells for one generation in the presence of 7.5 ng/ml CHI (facilitation) eliminated phase I and slightly decreased phases II and III following subsequent challenge with an inhibitory concentration of CHI. Facilitation for six generations further decreased phases II and III. Protein synthesis and cell division were not inhibited during facilitation In the culture, succinate dehydrogenase activity did not increase during the delay but increased normally at the onset of division. In contrast, NADPH-cytochrome c reductase activity continued to increase for an hour after inhibition of protein synthesis, was constant for a period and did not increase again until an hour after reinitiatoin of cell division and RNA synthesis Inhibition of division of all cells was immediate and reinitiation of synthesis and cell division was non-synchronous.     

An analysis of the growth of the retinal cell population in embryonic chicks yielding proliferative ratios, numbers of proliferative and non-proliferative cells and cell-cycle times for successive generations of cell cycles

Growth curves of the retinal cell population of embryonic chicks were fitted by a branching-process model of cell population growth, thereby estimating the proliferative ratios and mean cell-cycle times of the generations of cell cycles that underlie retinal growth. The proliferative ratio determines the proportion of cells that divides in the next generation, so the numbers of proliferative and non-proliferative cells in each generation of cell cycles were obtained. The mean cell-cycle times determine the times over which the generations are extant. Assuming growth starts from one cell in generation 0, the proliferative cells reach 3.6 × 10⁶ and the non-proliferative cells reach 1.1 × 10⁶ by generation 23. The next four generations increase the proliferative cell numbers to 13.9 × 10⁶ and produce 20.1 × 10⁶ non-proliferative cells. In the next five generations in the end phase of growth, non-proliferative cells are produced in large numbers at an average of 13.9 × 10⁶ cells per generation as the retinal lineages are completed. The retinal cell population reaches a maximum estimated here at 98.2 × 10⁶ cells. The mean cell-cycle time estimates range between 6.8 and 10.1 h in generations before the end phase of growth and between 10.6 and 17.2 h in generations in the end phase. The retinal cell population growth is limited by the depletion of the proliferative cell population that the production of non-proliferative cells entails. The proliferative ratios and the cell-cycle-time distribution parameters are the likely determinants of retinal growth rates. The results are discussed in relation to other results of spatial and temporal patterns of the cessation of cell cycling in the embryonic chick retina.     

Prolongation of MGE 412 transposition induction after gamma-irradiation in an isogenic line of Drosophila melanogaster]]

The dose dependence of the rate of gamma-induced transpositions and consequent dynamics of the MGE 412 pattern after gamma-irradiation were investigated in isogenic line 49 in generations F1, F12, F140, and F170. It was shown that the results on dose dependence of transpositions was very similar with the corresponding results of the classic works by Timofeeff-Ressovsky et al. (1935). It is suggested that the transcribed copies of retrotransposon 412 "cure" gamma-radiation-induced double-strand DNA breaks. The phenomenon of prolongation of MGE transposition induction during early generations after treatment was shown. In this period (F1-F12), the maximum transposition rate (lambda approximately equal to 2 x 10(-2) events per MGE copy, per haploid genome, per generation) and the maximum number of heterozygous MGE copies were achieved. In the late generations (F140 and F170), the reduced induction level (lambda approximately 10(-3) was established. In the population of effective size Ne = 2000 individuals, this corresponds to the state when lambda > 1/4Ne, i.e., when the transposition flow prevails over the MGE copy loss by genetic drift. These data together with some indirect evidence argue for the hypothesis that the spontaneous transposition rate is proportional to the average number of heterozygous MGE copies per diploid genome.     

Effect of process variables on supercritical fluid disruption of Ralstonia eutropha cells for poly(R-hydroxybutyrate) recovery

This research focuses on the disruption of the gram-negative bacterium Ralstonia eutropha cells by supercritical CO2 for poly(R-hydroxybutyrate) (PHB) recovery. The variables affecting cell disruption such as drying strategy, type of modifier, and cultivation time, as well as operating pressure, temperature, and repeated release of supercritical CO2 pressure, have been studied. Effect of this disruption technique on PHB molecular mass was also investigated. PHB recovery was examined using a combination of this method and chemical pretreatments. For salt pretreatment, the cells were exposed to 140 mM NaCl and heat (60 degrees C, 1 h). The cells were also exposed to 0.2-0.8% (w/w) NaOH to examine the effect of alkaline pretreatment. Bacterial cells treated in growth phase exhibited less resistance to disruption than nutrient-limited cells in the stationary phase. It was also found that the wet cells could be utilized to recover PHB, but purity of the product was lower than that obtained from freeze-dried cells. Pretreatment with a minimum of 0.4% (w/w) NaOH was necessary to enable complete disruption with two times pressure release. Salt pretreatment was less effective; however, disruption was improved by the application of alkaline shock. The proposed method is economic and comparable with other recovery methods in terms of the percentage of PHB recovery and energy consumption, while it is environmentally more benign.     

Growth kinetics of cells following freezing in liquid nitrogen

The growth kinetics of cells frozen to ?196 °C were monitored after thawing by various techniques. Progression through the cell cycle in the exposed generation was observed by monitoring cell growth either via multiplicity counts or by electronic cell counts of trypsinized suspensions. Subsequent generations were followed by time-lapse microcinematography.The division delay in the exposed generation of exponential-phase cells was dependent on cell age at the time of freezing and varied from 4 to 8 hr. The time of the first generation was still prolonged significantly but subsequent generations revealed cell cycle times that are comparable to unfrozen cells. In the case of plateau-phase cells, mitosis was delayed 7 hr in the exposed generation. This is 50% longer than the delay seen for pre-DNA synthetic g₁ cells in exponentially growing cultures.A rather important observation in this study was that frozen-thawed cells which divide once will probably continue dividing whereas eventual nonsurvivors are not likely to divide at all. The latter, however, remain active for more than 35 hr as observed microscopically, hence possibly indicating residual metabolic activity.     

Inheritance of resistance and cross resistance pattern in indoxacarb-resistant diamondback moth Plutella xylostella L.

Leaf-dip assay of Plutella xylostella against indoxacarb showed that the concentration that produced 50% mortality (LC₅₀) of indoxacarb ranged from 20.1 to 11.9 ppm, with highest in Nasik and lowest levels in Coimbatore strains. In selection studies, the LC₅₀ of indoxacarb was 18.5 ppm at generation 1 (G1), which increased to 31.3-fold (167.8 ppm) resistance after ten exposed generations (G10) as compared to unexposed. The LC₅₀ of quinalphos was 74.4 ppm, which increased to 10.0-fold (631.5 ppm) resistance after G10. The LC₅₀ of cypermethrin resistant strain resulted in an 11.5-fold increase in resistance after G10. In P. xylostella , heritability (h²) after ten generations of selection was estimated at 0.4. The number of generations required for tenfold increase in LC₅₀ (1/R) were 6.7. The response to indoxacarb selection in P. xylostella was 0.2 and the selection differential was estimated as 0.4. The phenotypic standard deviation was 0.2. Reciprocal crosses between indoxacarb-resistant and susceptible strains showed that the inheritance of indoxacarb resistance was autosomal. The degree of heritability (D_LC) (0.4, 0.4) indicated incomplete recessive inheritance of indoxacarb resistance.     

Epiplastome variation of the number of chloroplasts in stomata guard cells of sugar beet (Beta vulgaris L.)

In stomata guard cells of sugar beet, variation in the number of chloroplasts was studied in successive generations: (1) hybrid generation; (2) generation yielded by uniparental apozygotic seed reproduction; (3) generation obtained after seed treatment with a colchicine solution; (4) generation obtained after seed treatment with 5-azacytidine. As compared to hybrid generation, uniparental seed reproduction increases the average number of chloroplasts in stomata guard cells (from 13.5 to 15.0) and decreases distribution variance of this trait by a factor of 3 to 4. Colchicine increases both average number of chloroplasts in stomata guard cells (from 13.5 to 18.2) and distribution variance (about twice). 5-Azacytindine reduces the number of chloroplasts in cells (from 15.0 to 12.9) but enhances distribution variance (about 1.5 times). Variation in the number of chromosomes in stomata cells is related to myxoploidy in meristem tissue, on the one hand, and to the rate of cell division, on the other. Uniparental seed reproduction is suggested to enhance the number of organelles per cell due to high myxoploidy in cell populations, which is typical of inbred plants. Colchicine blocks spindle division and sharply increases the level of myxoploidy in cell populations and the number of organelles per cell. 5-Azacytidine hypomethylates chromosome DNA, increases the rate of cell divisions, and reduces the number of organelles per cell. The described changes in the number of chloroplasts are inherited in cell lineage ("cell hereditary memory") and successive sporophyte generations.     

Changes in the duration of the electric response of single nerve fibers following repetitive stimulation

Single nerve fibers were isolated from the nerve innervating the sartorius or semitendinosus muscle of the toad (Bufo marinus). Single nerve fiber responses were recorded with three arrangements of the "bridge insulator" method. During stimulation at 50 to 150 pulses per second for 20 to 140 minutes the spike duration was progressively increased. After tetanization the spike duration usually continued to increase at a more rapid rate. Within 5 to 60 minutes further prolongation stopped and within 1 to 10 hours the spike duration was normal. The duration of the response of tetanized fibers was from 2.5 to more than 10 times the spike duration of untetanized fibers. Prolongation was observed in nerve fibers isolated from nerves tetanized in vivo.     

Human lymphokine-activated killer (LAK) cells

Summary Pretreatment of peripheral blood mononuclear cells (PBMC) with 5 mMl-phenylalanine methyl ester (PheOMe) provides an efficient means to deplete monocytes. PheOMe does not affect the number of large granular lymphocytes after the pretreatment, but does inhibit natural killer cell cytotoxicity temporarily after the pretreatment. However, depletion of monocytes by PheOMe allows lymphokine-activated killer (LAK) cell generation with recombinant interleukin-2 (rIL-2) at high cell density (> 5 × 10⁶ cells/ml). The time of the PheOMe pretreatment is 40–60 min, though some effect could be observed within 15 min, and the pretreatment could be performed at room temperature. Pretreatment density of PBMC with 5 mM PheOMe could be achieved at cell density up to 3 × 10⁷ cells/ml. PheOMe-pretreated cells could be activated by rIL-2 in serumless media at high cell density. Pretreatment of PBMC with 5 mM PheOMe provides an efficient means to deplete monocytes, as compared to plastic and nylonwool adherence. LAK cell generation is similar in both methods of monocyte depletion; therefore, depletion of monocytes allows, LAK cell generation at high cell density. The PheOMe procedure provides an improved and convenient process for preparing LAK cells for adoptive immunotherapy.     

Physiological Adaptations in Hypoxia in Infant Mammals

Newborn rats exposed at 37 C to pure nitrogen continue to breatheslowly for 22 minutes. As they grow older the time to the lastbreath diminishes, and the pattern of breath frequencies changes.At 4 to 11 days of age pretreatment with hypoxia for a few hoursprolongs the time to last breath for 40 to 75%. To that prolongation(physiological adaptation) may be added the smaller effect ofimmediate glucose injection. Neither prolongation is availablein the first two days after birth. The adaptation appears tomodify the regulation of anaerobic breathing in the medullaoblongata, which acquires this specific superfunction in responseto the pretreatment with hypoxia.     

Heat shock dependent fluctuations of RNase activity during the cell cycle of synchronized Tetrahymena.

The total cellular acid RNase activity per milliliter of culture increases sharply following each heat shock in the cell cycle of Tetrahymena pyriformis ST synchronized with heat shocks spaced one generation time apart. Thus, the RNase activity per 10(5) cells is 24.5 units immediately after the end of the sixth heat shock, increases to 39.0 units during the following 55 minutes and decreases to 24.2 units at the start of the seventh heat shock. No change in the RNase activity occurs during the heat shock period. In logarithmically growing cells the RNase activity per 10(5) cells is 15.4 units. The heart shock stimulates the increase in the RNase activity, since no rapid increase occurs during the free running division cycle but a rapid increase occurs after an additional heat shock given at different times during the cell cycle. Inhibition of the increase in RNase activity by cycloheximide suggests that concurrent protein synthesis is required for the stimulation of the RNase activity by the heat shock treatment.     

The possible involvement of CHI sequences in adaptive mutagenesis: Evidence from sequence analysis

Recently we proposed that sequences in the immediate neighbourhood of cytosine residues whose sequence context permits their methylation by DNA cytosine methyltransferase (Dcm) experience hypermutagenesis in cells exposed to nonlethal stresses. This hypothesis could explain the peculiar spectrum of the late-arising Lac⁺ mutants seen in theE. coli strain FC40. Here we present results of computer analysis which show that Dcm substrate sequences are overrepresented in theE. coli genome. Interestingly, certain noncanonical Dcm sequences are more overrepresented than the canonical one. The most overabundant of these, DCM-III (5’ GCTGG3’), forms the 5’ end of the recombinogenic octamer CHI (5’ GCTGGTGG3’). CHI is even more overrepresented than DCM-III. We propose that the overabundance of the DCM and CHI sequences is due to their ability to enhance adaptive fitness of the host by inducing hypermutagenesis in cells exposed to nonlethal, growth-blocking stresses. The CHI context seems to stimulate the adaptive activity of DCM-III by a mechanism which may not directly involve its recombinogenic activity.     

Epiplastome Variation of the Number of Chloroplasts in Stomata Guard Cells of Sugar Beet (Beta vulgaris L.)

In stomata guard cells of sugar beet, variation in the number of chloroplasts was studied in successive generations: (1) hybrid generation; (2) generation yielded by uniparental apozygotic seed reproduction; (3) generation obtained after seed treatment with a colchicine solution; (4) generation obtained after seed treatment with 5-azacytidine. As compared to hybrid generation, uniparental seed reproduction increases the average number of chloroplasts in stomata guard cells (from 13.5 to 15.0) and decreases distribution variance of this trait by a factor of 3 to 4. Colchicine increases both average number of chloroplasts in stomata guard cells (from 13.5 to 18.2) and distribution variance (about twice). 5-Azacytindine reduces the number of chloroplasts in cells (from 15.0 to 12.9) but enhances distribution variance (about 1.5 times). Variation in the number of chromosomes in stomata cells is related to myxoploidy in meristem tissue, on the one hand, and to the rate of cell division, on the other. Uniparental seed reproduction is suggested to enhance the number of organelles per cell due to high myxoploidy in cell populations. Colchicine blocks spindle division and sharply increases the level of myxoploidy in cell populations and the number of organelles per cell. 5-Azacytidine hypomethylates chromosome DNA, increases the rate of cell divisions, and reduces the number of organelles per cell. The described changes in the number of chloroplasts are inherited in cell lineage (cell hereditary memory) and successive sporophyte generations.     

Fusidic-acid-resistant staphylococci

Penicillin-resistant staphylococci were examined to determine the spontaneous mutation frequency of resistance to antistaphylococcal antibiotics including fusidic acid, cephalothin and lincomycin. Fusidic-acid-resistant mutants were obtained about twenty times more frequently than cephalothin-resistant mutants and about one hundred times more frequently than lincomycin-resistant mutants. Among the fusidic-acid-resistant mutants, ninety-seven per cent were resistant to 20 g/ml and thirty percent to 100 g/ml of the drug. The fusidic-acid-resistant mutants had prolonged generation times not related to the level of drug resistance. Cross-resistance between fusidic acid and cephalothin and between lincomycin and erythromycin was detected. Preliminary evidence was presented indicating that fusidic-acid-resistant mutants inactivate fusidic acid to a greater extent than sensitive cells.     

Osmotic stress due to changes in plasma glucose and its regulation in IDDM patients.

Intravenous glucose tolerance tests (30 g, 5 min, constant rate) were performed in 8 IDDM patients and in 8 controls. The consequences of the osmotic pressure, induced by glucose, were investigated. Serum choline esterase was used as an endogenous marker of serum dilution. Five minutes after the end of infusion plasma glucose was raised by 182 +/- 12 mg.dl-1 in patients and by 189 +/- 6 mg.dl-1 in controls. Choline esterase values decreased by 6.6 +/- 0.8% and 6.3 +/- 1.0% respectively, P less than 0.01 each. Calculated water shifts into the extracellular space were 924 +/- 112 ml and 882 +/- 140 ml respectively. Fifteen minutes after the end of infusion glucose decreased by 32 +/- 1 mg.dl-1 in IDDM patients and by 57 +/- 2 mg-1 in controls. Serum choline esterase recovered by 2.6 +/- 0.2% and 2.7 +/- 0.2% respectively, P less than 0.01 each, indicating comparable water correction in spite of the slower fall of glucose in IDDM patients. Water correction was more rapid than glucose fall. Diuresis (46 +/- 4 ml versus 42 +/- 3 ml) or cellular uptake of serum solutes (electrolytes, amino acids, urea, creatinine) could not explain this. It is hypothesized that accumulation of free intracellular glucose reduces the osmotic gradient and facilitates cellular water re-uptake.     

大猿叶虫生活史的研究

大猿叶虫Colaphellus bowringi是江西山区十字花科蔬菜上的重要食叶害虫,以成虫在土中越夏和越冬。由于成虫滞育期的差异,该虫的化性显示了明显的种内变异。有些个体隔年繁殖;有些个体是一化性的,仅在春季或秋季繁殖1代;有些个体是二化性的,春季和秋季各繁殖1代;有些个体是多化性的,春季1代,秋季2～3代。因此,大猿叶虫在田间一年可发生4代。在春季,滞育成虫于2月底至4月初陆续出土繁殖;在秋季,滞育成虫于8月中旬至10月初陆续出土繁殖。春季羽化的成虫于4月底至6月上旬陆续入土越夏,秋季羽化的成虫于9月中旬至12月底陆续入土越冬。大猿叶虫一生能交配多次,大多数雌虫的产卵期超过1个月,最长达67天。平均每雌产卵量：春季世代为644粒,秋季世代为963粒,最高达1.950粒。各虫态的发育历期：在15～30℃间,卵为13.78～3.14天,幼虫为22.83～6.95天,蛹为12.10～3.18天。发育阈值温度：卵为10.7℃,幼虫为8.8℃,蛹为9.6℃。非滞育成虫的寿命约为1～2个月,滞育成虫的寿命为5～38个月。滞育成虫均入土蛰伏,在土中的蛰伏深度为9～31 cm 。     

Colony Dimorphism in Bradyrhizobium Strains

Ten isolates of Bradyrhizobium spp. which form two colony types were studied; the isolates originated from a range of legume species. The two colony types differed in the amount of gum formed or size or both, depending on the strain. Whole 7-day-old colonies of each type were subcultured to determine the proportion of cells which had changed to the other type. An iterative computerized procedure was used to determine the rate of switching per generation between the two types and to predict proportions reached at equilibrium for each strain. The predicted proportions of the wetter (more gummy) or larger colony type at equilibrium differed significantly between strains, ranging from 0.9999 (strain CIAT 2383) to 0.0216 (strain CIAT 2469), because some strains switched faster from dry to wet (or small to large) and others switched faster from wet to dry (or large to small). Predicted equilibrium was reached after about 140 generations in strain USDA 76. In all but one strain (CIAT 3030) the growth rate of the wetter colony type was greater than or similar to that of the drier type. The mean difference in generation time between the two colony types was 0.37 h. Doubling times calculated for either colony type after 7 days of growth on the agar surface ranged from 6.0 to 7.3 h. The formation of two persistent colony types by one strain (clonal or colony dimorphism) may be a common phenomenon among Bradyrhizobium strains.     

Increased Selection Response in Larger Populations. II. Selection for Ethanol Vapor Resistance in Drosophila Melanogaster at Two Population Sizes

The effect of large population size on selection response was investigated using Drosophila melanogaster, with four "small" lines of 160 selected parents/generation compared to two "large" lines of 1,600 selected parents/generation. All lines were selected under similar conditions at a selection intensity of approximately 0.55 standard deviations, for 65 generations, for increased ethanol vapor resistance (measured in minutes required to become anesthetized). Two unselected control lines of 320 parents/generation were also maintained. A significant effect of population size was found. The final treatment means and standard errors were: 27.91 +/- 1.28 min (two "large" lines); 19.40 +/- 1.54 min (four "small" lines); and 4.98 +/- 0.35 min (two control lines). To estimate the mutation rate for the trait, two isogenic lines of about 400 selected parents were selected for 29 generations. The mean increase in additive genetic variance per generation was 0.0009 times the initial environmental variance of the outbred lines. This is comparable to other reported mutation rates. Mutation can explain part of the difference in evolved resistance between treatments, but it appears that even at rather large population sizes, a large difference in long-term response can be obtained in larger outbred lines, from more complete utilization of the initial genetic variation.     

Interchangeability of mutagens during fractionated effects of unequal concentrations of alkylating agents

The ability of thiophosphamide and dipin to substitute for each other in "clastogenic adaptation" of human lymphocytes was investigated at Go phase. There were used 5 low concentrations of mutagens 2, 0.2, 2.10(-2), 2.10(-3), 2.10(-4) micrograms/ml and the high one of 20 micrograms/ml with which cells were treated 2 hr after the effect of low concentrations. The "protective" concentrations for both mutagens were 0.2, 2.10(-2), 2.10(-3) micrograms/ml. The pretreatment with thiophosphamide caused the decrease in chromatid aberrations in "challenge" treatment with dipin, the pretreatment with dipin caused the decrease in chromosome aberrations in "challenge" treatment with thiophosphamide.