Effects of light and nitrogen limitation on the cell cycle of the dinoflagellate Amphidinium carteri

Cell cycle phase durations of cultures of Amphidinium carteriin light- or nitrogen-limited balanced growth were determinedusing flow cytometry. For both types of growth rate limitation,the increases in generation time caused by increasing degreesof limitation were due solely to expansion of the G₁ phase ofthe cell cycle. The durations of the S and G₂ + M phases wereindependent of growth rate. Furthermore, when cells were deprivedcompletely of light and nitrogen, they arrested in the G₁ phaseof the cell cycle. The results indicate that light- and nitrogen-dependentprocesses are heavily concentrated in the early part of thecell cycle, while DNA replication and cell division, once initiated,are independent of light or nitrogen supply.     

Induction of Cell Division Synchrony and Variation of Cytokinin Contents through the Cell Cycle in Tobacco Cultured Cells

Cell division synchrony was induced in tobacco {Nicotiana tabacum)cultured cells by several treatments. Very high synchrony throughouttwo cell cycles was induced by aphidicolin treatment (inhibitorof DNA polymerase , 10 µg/ml) and by treatment with lowtemperature (4°C) and hydroxyurea (50 µg/ml). Themitotic index reached its maximum (52% and 40% in aphidicolinand hydroxyurea treatments, respectively) at 11 h after removalof the added chemical. During the treatments, the cells werearrested in the G₁/S phase of the cell cycle. In the aphidicolin-inducedsystem, incorporation of ¹⁴C-thymidine confirmed that DNA synthesiswas started immediately after removal of the chemical. The aphidicolin-induced synchronous cells were used to studythe contents of butanol-soluble cytokinins during the cell cycle.Cytokinin contents increased conspicuously at the G₂/M boundary. ¹Present address: Department of Biology, Otsuma Women's University,Chiyodaku, Tokyo 102, Japan. (Received May 14, 1985; Accepted November 8, 1985)     

Cell Cycle Changes in the Shoot Apex of Silene coeli-rosa During the Second and Third Days of Floral Induction

The cell cycle in Silene coeli-rosa shoot apices was measuredto test whether or not early components of the floral stimulus,produced during the 2nd and 3rd long days (LD) of an inductiveLD treatment, resulted in an increase in the duration of G₂phase in constant 20–24 h cell cycles. Plants were grownat 20°C in short days (SD) of 8 h light and 16 h darknessfor 28 d (day 0). Starting on day 0, plants were given SD or3 LD each comprising an identical 8 h day and 16 h photo-extension,or 3 dark-interrupted (d.i.) non-inductive LD, interrupted at1700 h of each day with 1 h of darkness. The cell cycle (percentagelabelled mitoses method) and changes in cell number were determinedin the shoot apical meristem. During days 1–2 of the SDtreatment, the cell cycle and mean cell generation time (MCGT)was 18 and 32 h, respectively, giving a growth fraction of 56%.During days 2–3, the cell cycle and MCGT shortened to15 and 23 h, respectively (growth fraction = 65%). During days1–2 of the LD and d.i. LD treatments, cell cycles andMCGTs were 9–10 and 27–29 h, respectively, resultingin smaller growth fractions (about 33%). Thus, shortened cellcycles and altered growth fractions occurred regardless of whetheror not the treatment was inductive. The LD treatment resultedin a marked shortening of G₁ and, to a lesser extent, S-phase,whilst G₂ remained constant. These changes were consistent withincreases in the proportion of cells in G₂ during the photoextensionof each LD which were suppressed during the comparable periodsof the d.i. LD treatment. The latter treatment resulted in eachphase occupying virtually identical proportions of the cellcycle as in the SD treatment. Thus, the unique cell cycle responsesto the initial part of the inductive LD treatment were increasesin the proportion of cells in G₂ coupled with G₁ and G₂ beingof similar duration. Cell cycle, mean cell generation time, shoot apex, Silene coeli-rosa     

Lung endothelial cell proliferation with decreased shear stress is mediated by reactive oxygen species

Acute cessation of flow (ischemia) leads to depolarization of the endothelial cell (EC) membrane mediated by K_ATP channels and followed by production of reactive oxygen species (ROS) from NADPH oxidase. We postulated that ROS are a signal for initiating EC proliferation associated with the loss of shear stress. Flow cytometry was used to identify proliferating CD31-positive pulmonary microvascular endothelial cells (mPMVECs) from wild-type, Kir6.2^–/–, and gp91^phox–/– mice. mPMVECs were labeled with PKH26 and cultured in artificial capillaries for 72 h at 5 dyn/cm² (flow adaptation), followed by 24 h of stop flow or continued flow. ROS production during the first hour of ischemia was markedly diminished compared with wild-type mice in both types of gene-targeted mPMVECs. Cell proliferation was defined as the proliferation index (PI). After 72 h of flow, >98% of PKH26-labeled wild-type mPMVECs were at a single peak (PI 1.0) and the proportion of cells in the S+G₂/M phases were at 5.8% on the basis of cell cycle analysis. With ischemia (24 h), PI increased to 2.5 and the ratio of cells in S+G₂/M phases were at 35%. Catalase, diphenyleneiodonium, and cromakalim markedly inhibited ROS production and cell proliferation in flow-adapted wild-type mPMVECs. Significant effects of ischemia were not observed in Kir6.2^–/– and gp91^phox–/– cells. ANG II activation of NADPH oxidase was unaffected by K_ATP gene deletion. Thus loss of shear stress in flow-adapted mPMVECs results in cell division associated with ROS generated by NADPH oxidase. This effect requires a functioning cell membrane K_ATP channel. cell signaling; ischemia; mechanotransduction; K_ATP channels; NADPH oxidase     

Allocation of Organ Biomass in Perfect and Imperfect Flowers

Perianth M_P, gynoecium M_G, and androecium M_A dry-weight biomass(in g) of 39 species of perfect flowers was measured. Thesedata were pooled with published data from an additional 51 speciesand used to determine size-dependent variations in (M_G and M_A)in terms of the hypothesis that the quotient of M_G and M_A exceeds1·0 for out-breeding (xenogamous) species and less than1·0 for in-breeding (autogamous) species. Ordinary leastsquare regression of the pooled data (n = 90) showed M_G = 0·118M^0·916_P (r² = 0·884) and M_A = 0·186 M^0·975_P(r² = 0·865), indicating that the biomass of the gynoeciumproportionally decrease as floral size increases. The exponentsof these regressions indicate that the ratio of gynoecial toandroecial biomass decreased with increasing floral size suchthat comparatively small flowers (M_P < 0·0021 g) hadM_G/M_A > 1·0 (predicted for 'out-breeders') while comparativelylarger flowers (M_P > 0·0021 g) had M_G /M_A < 1·0(predicted for 'in-breeders'). Thus, on average, the type ofbreeding system was a size-dependent phenomenon. To test whether the biomass of a floral organ-type is a legitimateindicator of gender reproductive effort, the biomass (in g)of stamen filaments M_m and anther sacs M_AS of 39 species wasdetermined. Least square regression of these data showed M_AS= 0·188 M^0·854_fil (r² = 0·967), indicatingthat species with larger stamen filaments, on the average, boreproportionally smaller anther sacs and thereby cautioning againstthe uncritical use of the allocation of biomass to floral organ-typeas a strict gauge of gender-function investment. To determine whether the loss of one gender-function resultsin proportional reallocation of biomass to the remaining gender-function,the size-dependency of androecial and gynoecial biomass wasdetermined for a total of 33 perfect and imperfect flowers ofCucumis melo. Regression of the data obtained from perfect flowersyielded M_A = 0·402 M^1·47_P (r² = 0·898)and M_G = 4·63 M^1·36_P (r² = 0·842). SinceM_G/M_A M^0·11_P , the biomass allocation to the gynoeciumrelative to the androecium decreased with increasing floralsize. This result was consistent with the broad interpecificcomparison based on 90 species with perfect flowers . Regressionof the data for imperfect flowers yielded M_A = 0·151M^1·02_P (r² = 0·675) and M_G = 4·68 M^1·47_P(r² = 0·996), indicating a near allometric relation forthe androecium and a strong positive anisometry for the gynoecium.Thus, for flowers of comparable size, a loss of female genderobtains a modest to significant again in androecial biomasswhereas the loss of male gender yields only a slight increasein gynoecial biomass. Collectively, the results of these studies indicate that biomassallocation patterns are size-dependent phenomena whose complexitieshave been largely ignored in the literature.Copyright 1993,1999 Academic Press Allometry, floral biomass, reproduction     

Flow Cytometric Determination of Nuclear Replication Stage in Seed Tissues

Flow cytometric determination of DNA levels in embryos of fullymatured seeds of various plant species revealed large amountsof 2C DNA signals, indicating that most cells had arrested thecell cycle at the presynthetic G₁ phase of nuclear division.The accumulation of cells at G₁ was found both in orthodox andin recalcitrant (i.e. Castanea sativa) seed species. As recalcitrantseeds are characterized by the absence of maturation drying,the arrest of the cell cycle in the presynthetic phase may notbe linked to the seed water status. Apart from the 2C signal, 4C values were found in the embryoof some seed species (e.g. Raphanus sativus) indicating thatcells were arrested in G₂ Cells arrested in G₂ were primarilylocated in the root-tip region of the embryo. In addition, combinationsof higher C values (i.e. 8C, 12C, 16C and 64C) were observedin the endosperm of Solanum melongena and Lycopersicon esculentum,and in the root-tip cells of Phaseolus vulgaris and Spinaciaoleracea. These mixtures of polyploid nuclei (also called 'polysomaty')may arise from a developmentally controlled cellular endoreduplicationand indicates that in each cell type of the seed the amountof DNA is regulated both spatially and temporally.Copyright1993, 1999 Academic Press Endive, Cichorium endiva, lettuce, Lactuca sativa, egg-plant, Solanum melongena, pepper, Capsicum annuum, tomato, Lycopersicon esculentum, radish, Raphanus sativus, bean Phaseolus vulgaris, spinach, Spinacia oleracea, chestnut, Castanea sativa, beech, Fagus sylvatica, pine, Pinus nigra, DNA content, flow cytometry, seed, nuclear replication stage, C levels, storage     

Generation of Hydroxyl Radical in Isolated Pea Root Cell Wall, and the Role of Cell Wall-Bound Peroxidase, Mn-SOD and Phenolics in Their Production

The hydroxyl radical produced in the apoplast has been demonstratedto facilitate cell wall loosening during cell elongation. Cellwall-bound peroxidases (PODs) have been implicated in hydroxylradical formation. For this mechanism, the apoplast or cellwalls should contain the electron donors for (i) H₂O₂ formationfrom dioxygen; and (ii) the POD-catalyzed reduction of H₂O₂to the hydroxyl radical. The aim of the work was to identifythe electron donors in these reactions. In this report, hydroxylradical (·OH) generation in the cell wall isolated frompea roots was detected in the absence of any exogenous reductants,suggesting that the plant cell wall possesses the capacity togenerate ·OH in situ. Distinct POD and Mn-superoxidedismutase (Mn-SOD) isoforms different from other cellular isoformswere shown by native gel electropho-resis to be preferably boundto the cell walls. Electron paramagnetic resonance (EPR) spectroscopyof cell wall isolates containing the spin-trapping reagent,5-diethoxyphosphoryl-5-methyl-1-pyrroline-N-oxide (DEPMPO),was used for detection of and differentiation between ·OHand the superoxide radical (O₂^–·). The data obtainedusing POD inhibitors confirmed that tightly bound cell wallPODs are involved in DEPMPO/OH adduct formation. A decreasein DEPMPO/OH adduct formation in the presence of H₂O₂ scavengersdemonstrated that this hydroxyl radical was derived from H₂O₂.During the generation of ·OH, the concentration of quinhydronestructures (as detected by EPR spectroscopy) increased, suggestingthat the H₂O₂ required for the formation of ·OH in isolatedcell walls is produced during the reduction of O₂ by hydroxycinnamicacids. Cell wall isolates in which the proteins have been denaturated(including the endogenous POD and SOD) did not produce ·OH.Addition of exogenous H₂O₂ again induced the production of ·OH,and these were shown to originate from the Fenton reaction withtightly bound metal ions. However, the appearance of the DEPMPO/OOHadduct could also be observed, due to the production of O₂^–·when endogenous SOD has been inactivated. Also, O₂^–·was converted to ·OH in an in vitro horseradish peroxidase(HRP)/H₂O₂ system to which exogenous SOD has been added. Takentogether with the discovery of the cell wall-bound Mn-SOD isoform,these results support the role of such a cell wall-bound SODin the formation of ·OH jointly with the cell wall-boundPOD. According to the above findings, it seems that the hydroxycinnamicacids from the cell wall, acting as reductants, contribute tothe formation of H₂O₂ in the presence of O₂ in an autocatalyticmanner, and that POD and Mn-SOD coupled together generate ·OHfrom such H₂O₂.     

Cytokinins in Germinating Seeds of Phaseolus vulgaris L. III. Transport and Metabolism of 8[14C]t-Zeatin Applied to the Radicle

The application of 8[¹⁴C]t-zeatin to the cotyledons of germinatingbean seeds demonstrated that cytokinins are not readily exportedfrom the cotyledons to the embryonic axis during the early stagesof this process. In the cotyledons the applied zeatin is metabolizedextensively to metabolites which are polar and which occur atR_F 0·2–0·5 on paper chromatograms. Thesemetabolites are stable and are not readily exported from thecotyledons. In contrast the metabolites found at R_F 0–0·2are more readily exported. When exported to the radicles andplumules a large proportion of the translocated metaboliteswere converted to compounds which on paper co-chromatographedwith zeatin. This seems to suggest that the embryonic axis hasthe capacity to synthesize cytokinins and that some of the metabolitesformed during its catabolism can also be used for its synthesis. Phaseolus vulgaris, bean, germination, cytokinins, transport, cotyledons     

Inhibition of Zeatin-Induced Growth of Cucumber Cotyledons by Sulfite Ions

The inhibitory effects of sulfite ions on zeatin-induced cellexpansion in cotyledons excised from dark-grown seedlings ofcucumber (Cucumis sativus L.) were examined. With 50 µMzeatin the growth rate in white light was about twice that ofthe control. Addition of Na₂SO₃ in the growth medium inhibitedthe zeatin-induced growth of cotyledons. Zeatin-treatment increasedthe osmotic potential in cell sap of cotyledons, while sulfitedecreased it. These treatments had no significant effect onpotassium concentration. Sulfite inhibited the zeatin-inducedincrease in contents of fructose and glucose, but did not affectsucrose content. The relative contents of non-cellulosic constituentsof cell walls fell with the advance of culture. This decreasewas repressed by sulfite, indicating that inhibition of expansiongrowth in cucumber cotyledons by sulfite ions was the resultof alterations in the cell wall structure due to changes inthe cell wall metabolism. (Received June 12, 1984; Accepted October 24, 1984)     

Commitment of Mitotic Cells to Meiosis during the G2 Phase of Premeiosis

In the developing anther, archesporial cells that proliferateby mitotic division are converted into meiotic cells duringthe premeiotic interphase. Experiments with explanted microsporocytesof Lilium and Trillium were made to obtain evidence for theconversion of mitotic to meiotic cells during the premeioticperiod. Explanted premeiotic cells were cultured through thedivision cycle at relatively high division frequencies and showeda variety of division types with respect to chromosomal events.The type of division depended on the premeiotic stage at whichthe cells were explanted. Cells in the G₁, S and early G² phasesunderwent mitotic division and formed a diad or binucleate monad.Cells explanted at the late G₂ phase were cultured throughoutthe normal meiotic cycle, which resulted in typical tetrad configuration. In microsporocytes explanted during the main part of the G₂interval, centromere behavior was meiotic, but chromosome pairingand chiasma formation were disturbed. Thus, she G₂ intervalwas shown to be critical for the commitment of mitotic cellsto meiotic division. Detailed analysis showed that the intracellularchanges that commit the cells to meiosis begin shortly aftercompletion of premeiotic DNA synthesis and that these changesare progressive and cumulative. (Received February 2, 1982; Accepted May 24, 1982)     

Cell Cycle Activation During Imbibition and Visible Germination in Embryos and Megagametophytes of Jack Pine (Pinus banksiana Lamb.)

Flow cytometric determination of cell cycle activation duringimbibition and visible germination in five families of jackpine (Pinus banksiana Lamb.) embryos and megagametophytes revealedthat in seeds that had undergone no imbibition the majorityof cells were in the 2C state. As the imbibition period increased,less of the nuclei were blocked in the G0/G1 state and morebecome active in the cell cycle. The augmentation in the nucleiactive in the 2C–4C cycle as well as those with DNA levelshigher than the 4C state occured gradually and preceeded radicleemergence. In megagametophyte tissue examined at various stagesof imbibition, cell cycle activity became apparent rapidly followingimbibition. In nuclei of green and white embryos examined separatelythe ²frequency distributions were significantly different forall three families after 144h. As imbibition period increased,fewer nuclei from the green embryos were blocked in the 2C state,and more became active in the 2C–4C cell cycle. This wasnot the case for white embryos where no significant linear relationwas noted. Cell cycle activity in the hypocotyl+cotyledons regionand the emerging radicle were examined separately. Functionalrelations found in the hypocotyl+cotyledons region were notevident in the radicle. As visible germination proceeded, cellcycle activity in the hypocotyl + cotyledons region for thisperiod of germination showed a reversal of the activity notedduring imbibition: fewer nuclei were active and once again ahigher proportion were found in the 2C state. cell cycle; C levels; DNA content; flow cytometry; germination; imbibition; jack pine; megagametophyte; Pinus banksiana Lamb     

Cell cycle-dependent expression of a glioma-specific chloride current: proposed link to cytoskeletal changes

We recentlydemonstrated expression of a novel, glioma-specificCl current in glial-derivedtumor cells (gliomas), including stable cell lines such as STTG1,derived from a human anaplastic astrocytoma. We used STTG1 cells tostudy whether glioma Clchannel (GCC) activity is regulated during cell cycle progression. Cells were arrested in defined stages of cell cycle(G₀,G₁,G₁/S, S, and M phases) using serumstarvation, mevastatin, hydroxyurea, demecolcine, and cytosine-D-arabinofuranoside. Cellcycle arrest was confirmed by measuring[³H]thymidineincorporation and by DNA flow cytometry. Using whole cell patch-clamprecordings, we demonstrate differential changes in GCC activity aftercell proliferation and cell cycle progression was selectively altered;specifically, channel expression was low in serum-starved,G₀-arrested cells, increasedsignificantly in early G₁,decreased during S phase, and increased after arrest in M phase.Although the link between the cell cycle and GCC activity is not yetclear, we speculate that GCCs are linked to the cytoskeleton and thatcytoskeletal rearrangements associated with cell division lead to theobserved changes in channel activity. Consistent with this hypothesis,we demonstrate the activation of GCC by disruption of F-actin usingcytochalasin D or osmotic cell swelling.

     

The Effect of L-Phenylalanine on Phenylalanine Ammonia-lyase and Cell Division in Artichoke Callus Culture

5 x 10^–5 M L-phenylalanine overcame the inhibitory effectof white light on cell division in artichoke callus culturesand increased extractable phenylalanine ammonia-lyase (PAL)activity compared to cultures grown in the presence of 5 x 10^–4M phenylalanine The lower concentration of the amino acid alsoenhanced rates of uptake and incorporation of ¹⁴C labelled phenylalaninethroughout G₁ and S. Differences between the two concentrationswere greatest during S with a 4-fold increase in uptake anda 3-fold increase in incorporation It is suggested thereforethat the capacity of 5 x10^–5 M phenylalanine to offsetthe light effect is due to an indirect stimulatory effect onamino acid and protein metabolism Increased levels of extractablePAL activity would then be reflected by this general stimulationof protein synthesis. Helianthus tuberosus L, Jerusalem artichoke, callus culture, cell division, phenylalanine ammonia-lyase     

Flow Cytometric Determination of Nuclear Replication Stages in Tomato Seeds during Priming and Germination

Flow cytometric determination of DNA levels in embryos of fullymatured dry tomato (Lycopersicon esculenium) seeds revealedlarge amounts of 2C DNA signals, indicating that most cellshad arrested in the cell cycle at the presynthetic G₁ phaseof nuclear division. After imbibition in water, an augmentationof the 4C signal in the embryonic root tip region was found.This increase could be ascribed to cells entering the syntheticphase of nuclear division leading towards the doubling of chromosomalmaterial. In the root tip cells, 4C:2C ratios increased I dafter imbibition in water though radicle emergence started 2d later. Apparently, DNA synthesis preceded germination. Onlya small increase in the number of cells with 4C DNA levels wasfound in the rest of the embryonic tissues. In whole dry seeds,DNA histograms revealed both a 2C signal and a considerable6C peak, the latter originating from the endoreduplicated endosperm. A priming period of 14 d in PEG-6000 considerably enhanced therate and uniformity of germination. In the ungerminated seeds,the 4C DNA signal of root tip cells started to increase after3 d incubation in PEG. The ratio of 4C:2C steadily increasedduring the 14 d priming period, though did not reach the levelobtained after hydration in water. Upon priming, the 4C:2C ratiowas constant after redrying the seeds towards the original moisturecontent, indicating that the chromosomal material in the rootcells had stably ceased cell cycle activity at the G² phase.The present results indicate that the beneficial effects ofpriming on seedling performance are associated with the actionof replicative DNA synthetic processes prior to germination. Lycopersicon esculeniumMill, tomato, DNA content, flow cytometry, priming, seed, nuclear replication stage, C levels     

Cell cycle-dependent expression of volume-activated chloride currents in nasopharyngeal carcinoma cells

Patch-clamping and cell imageanalysis techniques were used to study the expression of thevolume-activated Cl current,I_Cl(vol), and regulatory volume decrease (RVD)capacity in the cell cycle in nasopharyngeal carcinoma cells (CNE-2Z). Hypotonic challenge caused CNE-2Z cells to swell and activated aCl current with a linear conductance, negligibletime-dependent inactivation, and a reversal potential close to theCl equilibrium potential. The sequence of anionpermeability was I > Br > Cl > gluconate. The Cl channelblockers tamoxifen, 5-nitro-2-(3-phenylpropylamino)benzoic acid (NPPB),and ATP inhibited I_Cl(vol). Synchronous cultures of cells were obtained by the mitotic shake-off technique and by adouble chemical-block (thymidine and hydroxyurea) technique. Theexpression of I_Cl(vol) was cell cycle dependent,being high in G₁ phase, downregulated in S phase, butincreasing again in M phase. Hypotonic solution activated RVD, whichwas cell cycle dependent and inhibited by the Cl channelblockers NPPB, tamoxifen, and ATP. The expression of I_Cl(vol) was closely correlated with the RVDcapacity in the cell cycle, suggesting a functional relationship.Inhibition of I_Cl(vol) by NPPB (100 µM)arrested cells in G₀/G₁. The data also suggest that expression of I_Cl(vol) and RVD capacity areactively modulated during the cell cycle. The volume-activatedCl current associated with RVD may therefore play animportant role during the cell cycle progress.

     

Autolysis Promotes the Extension Capacity of Zea mays Coleoptile Cell Walls in Response to Acid pH Solutions

The relationship between autolytic degradation of ß(1–3),(1–4)-D-glucanand acid pH-induced extension of isolated Zea mays cell wallshas been investigated using a constant-load extension technique.Acidic buffer (4.5) was able to induce an additional extension(E_a) on cell walls already extended at pH 6.8 buffer under a20 g-mass load, indicating that the additional extension (E_a)was the parameter that better represented the effect of thedifferent treatments on the mechanical properties of maize coleoptilecell walls. The additional extension in response to acidic pHwas higher when cell walls had been previously autolysed for24 h at pH 5.5. Furthermore, the acid-pH effect was dependenton the presence during the constant load extension of some thermo-labilefactors, suggesting the participation of expansins. Acid pHincreased E_a of native cell walls through an increase in theplastic extension (E_p) in agreement with a one step mechanismleading directly to irreversible (plastic) wall extension assuggested by Cosgrove (1977). The autolytic degradation of ß(1–3),(1–4)-D-glucan was also able to modify the mechanicalproperties of maize coleoptile cell walls increasing its elasticextension (E_e) in response to pH 4.5 buffer but that modificationonly leads to an increase in wall extension when expansins areactive, suggesting a cooperation between ß-glucanturnover and expansin action. (Received August 5, 1998; Accepted March 16, 1999)     

Luminal L-alanine stimulates exocytosis at the K+-conductive apical membrane of Aplysia enterocytes

In Aplysia intestine,stimulation of Na⁺ absorption withluminal alanine increases apical membraneK⁺ conductance(G_K,a), whichpresumably regulates enterocyte volume during stimulatedNa⁺ absorption. However, themechanism responsible for the sustained increase in plasma membraneK⁺ conductance is not known forany nutrient-absorbing epithelium. In the present study, we have begunto test the hypothesis that the alanine-induced increase inG_K,a inAplysia enterocytes results fromexocytic insertion of K⁺ channelsinto the apical membrane. We used the fluid-phase marker horseradishperoxidase to assess the effect of alanine on apical membraneexocytosis and conventional microelectrode techniques to assess theeffect of alanine on fractional capacitance of the apical membrane(fC_a). Luminalalanine significantly increased apical membrane exocytosis from 1.04 ± 0.30 to 1.39 ± 0.38 ng · min¹ · cm².To measure fC_a,we modeled the Aplysia enterocyte as adouble resistance-capacitance (RC) electric circuit arranged in series. Several criteria were tested to confirm application of the model to theenterocytes, and all satisfied the model. When added to the luminalsurface, alanine significantly increasedfC_a from 0.27 ± 0.02 to 0.33 ± 0.04 (n = 10)after 4 min. There are two possible explanations for our findings:1) the increase in exocytosis, whichadds membrane to the apical plasma membrane, prevents plasma membranefracture, and 2) the increase inexocytosis delivers K⁺ channels tothe apical membrane by exocytic insertion. After the alanine-induceddepolarization of apical membrane potential (V_a), there isa strong correlation (r = 0.96)between repolarization ofV_a, whichreflects the increase inG_K,a, andincrease in fC_a. This correlation supports the exocytic insertion hypothesis for activation ofG_K,a.

     

Changes in Nuclear DNA Content, Cell and Nuclear Size, and Frequency of Cell Division in the Cotyledons of Brassica napus L. during Embryogenesis

Cellular behaviour was examined during embryogenesis in Brassicanapus to test whether or not polyploidy occurs in the cotyledonsduring the phase of oil deposition. Nuclear DNA content, nuclearand cell size, and the mitotic index were measured in the cotyledonson various days post anthesis (dpa). In squashed monolayersfrom 15 dpa cotyledons, a polyploid (>5C) population wasdetected together with a substantial number of cells in G2 (4C).Nuclear volume was measured on sectioned tissues and, at 15dpa, the range of values from the cotyledons (40–500 *m³)contrasted with that in the vestigial suspensor and endosperm(50–> 600 µm³). At 15 dpa the nuclear volumedata suggest that whilst cells in the cotyledons were in Gland G2 many endosperm and suspensor cells were polyploid. Thus,polyploidy observed in the squashed monolayers was probablydue to contaminating endosperm/suspensor cells. At 25 and 35dpa, polyploidy was not detected; all cells were in Gl (2C)and cell area increased. The mitotic index peaked at 20 dpabefore declining and given the narrower distribution of nuclearvolumes at 25 and 35 dpa (50–300 µm³), these dataare consistent with cell arrest in Gl. Thus, polyploidy wasnot detected in the cotyledons of B. napus which differs fromwhat is known about cellular development in legume cotyledons. Key words: Brassica napus L., DNA, nuclear volume