Enhancement of nitrogen fixation inAnabaena flos-aquae (Cyanobacteria) via low-dose ultrasonic treatment

Low-dose (50 W), short-duration (5 min) ultrasonic treatments were delivered to log phase batch cultures of the cyanobacteriumAnabaena flos-aquae grown in nitrogen-free medium. Near the mid-point of nine-day experimental periods, ultrasonically-treated cultures exhibited higher growth rates, enhanced chlorophylla content, and greater acetylene reduction capacity when compared to cultures grown with reciprocal shaking alone. Heterocyst frequency was markedly higher in ultrasonically-treated cultures over the duration of five-day experimental periods.Author for correspondence     

Rhythmic settling induced by temperature cycles in continuously-stirred autotrophic cultures of Euglena gracilis (Z strain)

Summary Temperature cycles which produced synchrony of cell division in autotrophic Euglena (preceding paper, Terry and Edmunds, 1970) usually also evoked a cellular settling rhythm. The rhythm was expressed as a recurrent cycle of cell attachment to culture-vessel surfaces, with nearly the same phase angle to each of the different temperature cycles. Attachment occurred in cultures stirred rapidly enough for thorough mixing of the cell suspension, but it was possible to prevent attachment by increased agitation. The settling rhythm was entrained by temperature cycles with periods shorter than the minimum period length required to phase cell division, but the rhythm also persisted with a circadian period at constant temperature in continuous light following entrainment by 12,12 hr temperature cycles. The rhythm appeared in stationary-phase cultures exposed to either cold-synchronizing or heat-synchronizing temperature cycles, and also in growth-phase cultures exposed to cold-synchronizing cycles. The settling rhythm was generally not observable in heat-synchronized growth-phase cultures although it often appeared in the same cultures as they approached the stationary phase.This work is derived from a dissertation submitted to the Department of Biological Sciences of the State University of New York at Stony Brook by OzTerry in partial fulfillment of the requirements for the degree of Doctor of Philosophy. It was supported in part by a National Science Foundation Cooperative Graduate Fellowship to 0. Terry and in part by National Science Foundation research grants GB-4140 and GB-6892 and by State University of New York Research Foundation Grant-in-Aid 31-7150A to L. Edmunds.     

Cell division arrest by gamma-irradiation in photoautotrophic suspension culture of Euphorbia characias: Maintenance of photosynthetic capacity and overaccumulation of sucrose

Gamma-irradiation (250 Gy) applied to photoautotrophic cell suspensions of Euphorbia characias L. in the exponential growth phase led to the arrest of cell division and to a subsequent overaccumulation of sucrose and dry matter. From the fourth day of culture, the chlorophyll content and gross photosynthesis were not depressed by gamma-treatment nor by sugar accumulation. In both cultures, no difference was observed between oxygen uptake in the light at CO₂ saturating concentration and in the dark, suggesting that no change in energy-dissipative reactions took place after irradiation. A slight increase in oxygen uptake in both light and dark was observed in irradiated cells during the first four days. However, in the absence of limiting factors, the photosynthetic capacities of the dividing and irradiated non-dividing photoautotrophic cells were identical but higher than that of the non-dividing cells in the stationary growth phase. This suggests that gamma-irradiation arrests cell division by a mechanism different to that occuring in stationary-phase cultures. This may be of value in investigating the metabolism of secondary products.     

Regulatory mechanisms of biosynthesis of betacyanin and anthocyanin in relation to cell division activity in suspension cultures

Regulatory mechanisms of betacyanin biosynthesis in suspension cultures of Phytolacca americana and anthocyanin in Vitis sp. were investigated in relation to cell division activity.Betacyanin biosynthesis in Phytolacca cells clearly shows a positive correlation with cell division, as the peak of betacyanin accumulation was observed at the log phase of batch cultures. Incorporation of radioactivity from labelled tyrosine into betacyanin also showed a peak at early log phase. Aphidicolin, an inhibitor of DNA synthesis, and propyzamide, an antimicrotubule drug, reduced betacyanin accumulation and inhibited the incorporation of radioactivity from labelled tyrosine into betacyanin at concentrations which were inhibitory to cell division. Both inhibitors reduced the incorporation of radioactivity from labelled tyrosine to 3,4-dihydroxyphenylalanine (DOPA), but the incorporation of labelled DOPA into betacyanin was not affected. These results suggest that the conversion of tyrosine to DOPA is coupled with cell division activity.In contrast, the anthocyanin accumulation in Vitis cells showed a negative correlation with cell division. Accumulation occurred at the stationary phase in batch cultures when cell division ceased. Aphidicolin or reduced phosphate concentration induced a substantial increase in anthocyanin accumulation as well as the inhibition of cell division. Chalcone synthase (CHS) activity increased at the time of anthocyanin accumulation. Northern blotting analysis indicated that changes in CHS mRNA levels corresponded to similar changes in enzymatic activity. The pool size of endogenous phenylalanine was low during active cell division, but increased before anthocyanin began to accumulate and concomitantly with increasing levels of CHS mRNA. Exogenous supply of phenylalanine at the time of low endogenous levels induced the elevation of CHS mRNA and anthocyanin accumulation. These results indicate that the elevation of endogenous phenylalanine levels, when cell division ceases, may cause the increase in CHS mRNA levels, resulting in increased CHS activity and subsequently in anthocyanin accumulation in Vitis suspension cultures.Abbreviations CHS chalcone synthase - CHFI chalcone flavanone isomerase - DOPA 3,4-dihydroxyphenylalanine - PAL phenylalanine ammonia lyase     

MECHANISMS OF FLUID SHEAR‐INDUCED INHIBITION OF POPULATION GROWTH IN A RED‐TIDE DINOFLAGELLATE1

Net population growth of some dinoflagellates is inhibited by fluid shear at shear stresses comparable with those generated during oceanic turbulence. Decreased net growth may occur through lowered cell division, increased mortality, or both. The dominant mechanism under various flow conditions was determined for the red‐tide dinoflagellate Lingulodinium polyedrum (Stein) Dodge. Cell division and mortality were determined by direct observation of isolated cells in 0.5‐mL cultures that were shaken to generate unquantified fluid shear. Larger volume cultures were exposed to quantified laminar shear in Couette‐flow chambers (0.004–0.019 N·m ^{? 2} shear stress) and to unquantified flow in shaken flasks. In these larger cultures, cell division frequency was calculated from flow cytometric measurements of DNA·cell^?1. The mechanism by which shear inhibits net growth of L. polyedrum depends on shear stress level and growth conditions. Observations on the isolated cells showed that shaking inhibited growth by lowering cell division without increased mortality. Similar results were found for early exponential‐phase cultures exposed to the lowest experimental shear stress in Couette‐flow chambers. However, mortality occurred when a late exponential‐phase culture was exposed to the same low shear stress and was inferred to occur in cultures exposed to higher shear stresses. Elevated mortality in those treatments was confirmed using behavioral, morphological, and physiological assays. The results predict that cell division in L. polyedrum populations will be inhibited by levels of oceanic turbulence common for near‐surface waters. Shear‐induced mortality is not expected unless shear‐stress levels are unusually high or when cellular condition resembles late exponential/stationary phase cultures.     

RNA synthesis and cell division in cold-synchronized cells of Tetrahymena pyriformis

Cells of Tetrahymena pyriformis have been cold-synchronized using a repetitive cycle of six, two-hour cold shocks (9.5°C) alternating with decreasing periods (60–30 minutes) at 28°C. This system gives a maximum division index of 70–80% occurring at 90 minutes from the end of the last synchronizing cold-treatment (EC). Examination of the division sensitivity of these cells to actinomycin D applied continuously at ten-minute intervals from EC reveals that division is essentially blocked until approximately 40 minutes past EC, after which a rapid decrease is sensitivity to the inhibitor occurs. Coinciding with this period of high sensitivity is the occurrence of a peak of C¹⁴ uridine incorporation at 40 minutes past EC. Inhibition of this peak is correlated with an inhibition of division, whereas strong inhibition of RNA synthesis beyond 60 minutes past EC has little effect on division activity. The similarity of these findings with those of the heat-synchronized system is discussed with the suggestion that both heat- and cold-synchronizing treatments result in the synchronous resynthesis of a division-associated fraction of RNA.     

The nuclear pores of early meiotic prophase nuclei of plants

Summary Pollen mother cells at early meiotic prophase fromFritillaria lanceolata, F. mutica, Tulbaghia violacea, the lily “Formobel”,Triticum aegilopoides, T. dicoccoides, T. aestivum and synaptic and asynaptic forms ofT. durum were studied in thin sections with the electron microscope (a) in relation to distribution of nuclear pores (b) in respect of fine structure of the pore complex in those of the first four. The pores were distributed in random clusters during leptotene to pachytene in all plants, except in the two forms ofT. durum where there were either no pores or so few that they were not detectable. Probably correlated with this, the two membranes of the nuclear envelope were often widely separated and frequently sacculated. No pores were seen at leptotene in the part of the envelope to which, in theFritillarias and lily, the nucleolus was adpressed at this time. Evidence supporting a recent model which proposes that annuli are composed of three rings of eight granular subunits was obtained. These subunits as well as a dense central element, observed in most pores, were composed of filaments about 3 nm in diameter and evidently protein in character. There was evidence of a continuity between filaments in the central element and those in the rings of subunits which encircle the pore aperture at both the nuclear and cytoplasmic sides of the pore. In profiles of pores knobbed filaments were sometimes seen extending laterally from the pore wall into the perinuclear space at two sides. Questions concerning the role of the annulus are discussed. The author wish to thank Mr. R. F. Scott for construction to the model.     

Light Synchronization of an Endogenous Circadian Rhythm of Cell Division in Tetrahymena*

SYNOPSIS. Synchronization of cell division in axenic cultures of the free-living ciliated eukaryote Tetrahymena pyriformis (W) may be achieved equally as well by a sudden increase in irradiance, DD→LL (switch-up), or by a sudden decrease in irradiance, LL→DD (switch-down), provided that the irradiance transition occurs after a critical time in the late ultradian exponential growth phase. Circadian division indices (～24 hrs) are associated with infradian generation times (GT>>24 hrs).     

Variations in biochemical parameters of Heterocapsa sp. and Olisthodiscus luteus grown in 12:12 light:dark cycles I. Cell cycle and nucleic acid composition

The division cycle of two phytoplankton species, Olisthodiscus luteus and Heterocapsa sp. was studied in relation to a 12:12 light:dark cycle. Batch cultures in exponential phase were sampled every three hours during 48 hours. Cell number, cellular volume and DNA and RNA concentrations were measured. Microscopic observations of the nuclei of Heterocapsa sp. were also performed. In both species, cell division took place in the dark. In Heterocapsa sp., DNA and RNA showed a similar diel variability pattern, with synthesis starting at the end of the light period, previously to mitosis and cytokinesis. In O. luteus. Major RNA synthesis occurred during darkness, and DNA was produced almost continuously. Both species presented different values and diel rhythmicity on the RNA/DNA ratios.     

Lithium treatment of Nicotiana tabacum microspores blocks polar nuclear migration,disrupts the partitioning of membrane-associated Ca2+, and induces symmetrical mitosis

We have found that the normal developmental pathway of Nicotiana tabacum microspores is blocked or switched when microspores are exposed to lithium, and these effects are reversible with Ca²⁺ and myo-inositol. Normal development was defined by the following characteristics: changes in microspore shape from spherical to oval and then ellipsoid; two nuclear displacements, first from a central location to the cell periphery, and then from the periphery to the generative pole; a localization of membrane-associated Ca²⁺ at the generative pole preceding nuclear division; and, finally, an asymmetrical mitosis that results in a two-celled pollen grain with well-differentiated generative and vegetative nuclei. Lithium treatment blocked the localization of membrane-associated Ca²⁺ at the generative pole, and instead it was evenly distributed at both poles. Lithium treatment also blocked the asymmetrical positioning of the microspore nucleus at the generative pole and resulted in an approximately four-fold increase in the frequency of symmetrical mitosis. When Ca²⁺ and myo-inositol were added along with lithium, the effects were substantially decreased, and there was only a small increase in the frequency of symmetrical mitosis compared with controls. The timing of treatment was important; microspores isolated before the first nuclear displacement had a low frequency of further development, while microspores isolated immediately preceding the onset of mitosis were much less sensitive to lithium, and the result was only a small increase in the frequency of symmetrical mitosis. In microspores isolated after the first nuclear displacement, a 1-day exposure to lithium was sufficient to switch the developmental pathway from an asymmetrical to a symmetrical mitosis while still allowing limited further development. However, we have not optimized culturing conditions for embryogenesis and the furthest development observed after a 1-week culture was to four- or five-celled proembryo-like structures.     

The Chlamydomonas cell cycle is regulated by a light/dark-responsive cell-cycle switch

Cultures of the unicellular green alga Chlamydomonas reinhardii can be synchronized by light/dark cycling not only under photoautotrophic but also under mixotrophic growth conditions. We observed that cultures synchronized in the presence of acetate continue to divide synchronously for one cell-cycle period when transferred to heterotrophic growth conditions. This finding enabled us to investigate the differential effects of light on cell growth and cell division. When cells were exposed to continuous light at the beginning of the growth period they entered the division phase earlier than dark-grown cells as a consequence of an increased growth rate. Illumination at the end of the growth period, however, caused a considerable delay in cell division and an extended growth period. The light-induced delay in cell division was also observed in the presence of 3-(3,4-dichlorophenyl)-1,1-dimethylurea (DCMU), an inhibitor of photosystem II. This finding demonstrates that cell division is directly influenced by a light/dard-responsive cell-cycle switch rather than by light/dark-dependent changes in energy metabolism. The importance of this light/dark control to the regulation of the Chlamydomonas cell cycle was investigated in comparison with other control mechanisms (size control, time control). We found that the light/dard-responsive cell-cycle switch regulates the transition from G1-to S-phase. This control mechanism is effective in cells which have attained the commitment to at least one round of DNA replication and division but have not attained the maximal cell mass which initiates cell division in the light.Abbreviations dCTP deoxycytidine 5-triphosphate - DCMU 3-(3,4-dichlorophenyl)-1,1-dimethylurea     

Heterogeneity of lotus rhizome starch granules as revealed by α-amylase degradation

Lotus (Nelumbo nucifera Gaertn.) rhizome starch granules have an elongated oval shape with the hilum located at one end. The morphologic characteristics were used as a direction anchor to study the heterogeneity of molecular organization of starch granules using microscopy before and after partial digestion by bacterial α-amylase (Bacillus sp.) The partially digested granule showed a single, big eroded hole at the end distant from the hilum. The enzyme-attacked end was revealed to be the loosely packed end and to be the weak point for enzyme hydrolysis. The α-amylase hydrolyzed the loosely packed central part of the granule faster than the densely packed periphery, and left an empty shell with a fish-bone-like tunnel inside. The periphery was more resistant to amylase hydrolysis and had strong birefringence. For the whole starch granule, the selectivity of α-amylase hydrolysis was low for the crystalline and amorphous regions and for amylose and amylopectin molecules. This study elucidated that the molecular organization of lotus rhizome starch granules was heterogeneous.     

Importance of Nutrient Competition and Allelopathic Effects in Suppression of the Green Alga Scenedesmus obliquus by the Macrophytes Chara, Elodea and Myriophyllum

Possible allelopathic effects of substances released from the macrophytes Chara globularis, Elodea canadensis, Myriophyllum spicatum on the common green alga Scenedesmus obliquus were tested in the laboratory with plastic plants and untreated medium as controls. A two-phase approach was used in which first the effects of physical presence of plants was studied (phase I) followed by the effects of plant culture filtrates (phase II). In the presence of plastic plants growth was reduced only marginally, but strong growth inhibition of Scenedesmus occurred in the physical presence of all macrophytes. In contrast, filtrates from Chara had no growth inhibitory effect on Scenedesmus. Myriophyllum filtrate reduced particle-based growth rate by 7% compared to filtration controls, while Elodea culture filtrate reduced volume-based growth by 12%, chlorophyll-based growth by 28% and particle-based growth by 15%. Photosystem II-efficiency of Scenedesmus was reduced in all three macrophyte treatments in phase I, but not in filtrates from macrophyte cultures (phase II). Thus, while enzyme activity or other physiological aspects may have been affected, the current study yielded no proof for allelopathically active compounds being directed at photosynthesis. Mean particle volume (MPV) of Scenedesmus was not influenced by macrophyte exudates and cultures remained dominated by unicells. The strong growth inhibitory effects found for Scenedesmus in the physical presence of macrophytes, but not in plastic controls, and no or weaker response in nutrient-enriched filtrates, suggest nutrient competition was a more powerful driving factor than allelochemicals. However, the experimental design does not exclude disappearance of allelochemicals during the filtration process.     

Composition of the essential oil from cell suspension cultures of Achillea millefolium ssp. millefolium

The composition of the essential oil isolated from Achillea millefolium L. ssp. millefolium cell suspension cultures was analysed by GC and GC-MS. The yield of the oil obtained by hydrodistillation or a simultaneous distillation -extraction of these cultures, harvested at days 8–10 (end of exponential phase), was 0.001 % (w/w). The analysis of the volatiles showed the presence of thirteen components; monoterpenes amounted to 5%, sesquiterpene hydrocarbons attained 40%, while eugenol, demethoxyencecalin and two unidentified compounds amounted to 45% of the total oil. Several methods were tested in an attempt to increase the essential oil production by the cultures: growth on solid medium, growth in light, use of a different culture medium, elicitation with cellulase or yeast extract, and growth in a two-phase system. Of the different methods tested, the growth in B5⁺ medium with Miglyol 812 led to the highest essential oil yield (0.002%, w/w), and resulted in a more diverse oil composition.     

Growth kinetics of vitis vinifera cell suspension cultures: I. Shake flask cultures

Vitis vinifera cell suspension cultures carried out in shake flasks were closely examined for biomass growth and cell division in relation to carbohydrate, NH(4), NO(3)PO(4), and dissolved oxygen (DO)consumption. After inoculation, the oxygen uptake rate of the cultures measured on-tine was observed to increase continuously to a maximum value of 3.8 mmol O(2)L(-1)h(-1) at day 7 when cell division ceased and dissolved oxygen reached its lowest level of 17% air saturation. During this first phase of growth, the specific oxygen uptake rate remained constant at approximately 0.6 mmol 02 O(2) g(-1) dw h(-1)or approximately 2.2 mumol O(2), (10(6) cells)(-1) h(-1) whereas dry biomass concentration increased exponentially from 1.5 to 6.0 g dw L(-1). Thereafter, dry biomass concentration increased linearly to approximately 14 g dw L(-1) at day 14 following nitrate and carbohydrate uptake. During this second phase of growth, the biomass wet-to-dry weight ratio was found to increase in an inverse relationship with the estimated osmotic pressure of the culture medium. This corresponded to inflection points in the dry and wet biomass concentration and packed cell volume curves. Furthermore, growth and nutrient uptake results suggest that extracellular ammonium or phosphate ion availability may limit cell division. These findings indicate that cell division and biomass production of plant cell cultures may not always be completely associated, which suggests important new avenues to improve their productivity. (c) 1995 John Wiley & Sons, Inc.     

Carbon-nitrogen relations during batch growth ofNannochloropsis oculata (Eustigmatophyceae) under alternating light and dark

Nannochloropsis oculata (strain CCAP 849/1) was sampled at least every 12 h over a 26-d period of batch culture growth in a 12 h/12 h light/dark illumination cycle. Exponential cell-specific growth rate was 0.5 d^–1. Cell division occurred during the dark phase, while ammonium uptake, pigment synthesis and cell volume increase occurred mainly during the light. Stationary phase cells were on average larger that the largest exponentially growing cells. The lag phase prior to cell division was short with the C/N ratio returning to 6.25 (from 28) within 2 d of refeeding with ammonium. Significant Chl.a synthesis commenced after this period; net synthesis of Chl.a ceased on exhaustion of the N-source with a 40% fall in levels by the end of the stationary phase. Levels of carotenoids per cell also declined during N-deprivation although per ml of culture levels remained constant. Ammonium-refeeding of N-deprived cells resulted in a very rapid rise in glutamine (Gln) and very high ratios of glutamine/glutamate (Gln/Glu peaking at 35 within 1 h); peak Gln/Glu was lower in cells refed in the dark or after a shorter period of N-deprivation. The major intracellular amino acids during exponential phase were Glu, Gln, alanine and arginine, but on exhaustion of the N-source, levels of Gln fell rapidly (Gln/Glu falling to below 0.1 from 0.5–0.9 in the light and 0.3 in darkness during exponential growth). During N-deprivation tyrosine accumulated within the cells. Comparisons are drawn with the growth ofIsochrysis galbana, another alga used in aquaculture, under identical conditions.Author for correspondence     

Influence of temperature, salinity and nutrient limitation on yessotoxin production and release by the dinoflagellate Protoceratium reticulatum in batch-cultures

The toxic dinoflagellate Protoceratium reticulatum (Claparède & Lachmann) Buetschli is recurrently present in the Adriatic sea. It is the producing organism of yessotoxin (YTX) and some of its analogues and thus its presence in seawater often results in shellfish farm closure for long periods. However, molluscs become highly toxic also at the presence of low cell concentrations, due to the high YTX content present in most algal strains. As no data were available on the environmental conditions favouring growth and YTX production by Adriatic P. reticulatum strains, in the present work, we investigated the effect of nutrient limitation, salinity and temperature on growth and YTX content in P. reticulatum cultures. Liquid chromatography–mass spectrometry (LC–MS) analyses were carried out to determine YTX production as well as the difference between the YTX amount retained in cells and that released in growth medium, in order to relate cell content to excretion mechanisms. The toxin content was determined in cells collected at the stationary phase, since both toxin production and release were found to be higher in this growth stage than in the exponential phase. As for nutrient-effect, a severe P-limitation strongly affected cell growth and favoured toxin accumulation, as consequences of both impaired cell division and lower toxin release. N-limited cultures, on the contrary, had a toxin content similar to controls and the highest percentage of release. P. reticulatum was confirmed to be tolerant towards salinity changes as it could grow at salinity values in the range of 22–42. The highest YTX production was observed at intermediate salinity values (32) whereas toxin release, expressed as percentage of the total amount produced, decreased as salinity increased. P. reticulatum growth was impaired in cultures kept at 26 °C in respect to those grown at 16 and 20 °C. YTX release decreased as temperature increased; however, cells kept at 26 °C displayed a very high YTX content. The environmental implications of these physiological behaviours highlight that farmed molluscs can become less toxic in colder waters at lower salinity values.     

Aberrant microtubule organization can result in genetic abnormalities in protoplast cultures of Vicia hajastana Grossh

Protoplast cultures of Vicia hajastana have a high division frequency. However, 20–40% of the microcolonies fail to develop beyond the 20-30-cell stage. Aneuploids and polyploids were found in early divisions and persisted in older cultures. The resulting protoplast-derived suspension culture differed karyologically from the original culture. Karyokinesis and cytokinesis were studied using simultaneous staining of microtubules (MT) by immunofluorescence, DNA by Hoechst 33258 (2-[2-(4-hydroxyphenyl)-6-benzimidazoyl]-6-[1-methyl-4-piperazyl]benzimidazole) and cell walls by Calcofluor. Freshly prepared protoplasts showed mitoses and high frequencies of binucleate cells, which probably resulted mainly from failure of cytokinesis. In early divisions, many mitoses showed metaphase chromosomes with kinetochore MT but lacking polar MT. These aberrant mitoses probably accounted for an increase in hyperploid cells observed in protoplast cultures. Multipolar spindles, which gave rise to hypoploid cells, were also seen in the early divisions. Telophase abnormalities included dislocated phragmoplasts and incomplete formation of cross walls. Many divisions resulted in daughter nuclei of unequal size. Unequal segregation of chromosomes was detected by cytofluorimetric measurements of telophase nuclei stained with Hoechst. After 5 d of culture, 91% of the divisions with incomplete cross walls also contained different-size nuclei; conversely, 78% of the divisions with fully formed cross walls contained nuclei of equal size. The malfunctioning of spindles and phragmoplasts in the same cells indicates a functional interdependence of the different MT configurations in mitosis. During the first 24 h of culture, a high frequency of abnormalities was found in spindles, cross-wall formation and chromosome segregation; this was reduced substantially in the cells undergoing first division by 48 h. The data indicate that it may be possible to manipulate the frequency of abnormalities by controlling the onset of the first division in protoplast cultures.Abbreviations 2,4-D 2,4-dichlorophenoxyacetic acid - MT microtubule(s) - PB prophase band(s) - PNF perinuclear fluorescence - PPB pre-prophase band