ROLE OF SULFUR IN THE CELL DIVISION OF CHLORELLA, WITH SPECIAL REFERENCE TO THE SULFUR COMPOUNDS APPEARING DURING THE PROCESS OF CELL DIVISION. I.

1. The role of sulfur in the cell division of Chlorella was studiedby following the fate of the sulfur supplied to the sulfur-deficientcells using ³⁵S as a tracer.
2. The sulfur-deficient cells whichwere unable to perform celldivision were made capable of divisionby the provision of ³⁶S-labeledsulfate under non-photosynthesizingconditions. Soon after theprovision of sulfate the labeledsulfur went rapidly into thecold perchloric acid (PCA)-solublefraction of algal cells,almost entirely in the form of sulfateand/or some other inorganicsulfur substance (s). With the lapseof time, more or less remarkablechanges occurred in the patternof ³⁵S-distribution in differentfractions of cell material.It was noticed that, at the onsetof cell division, a sulfur-containingpeptide-nucleotide compound(s)(SPN), which has been reportedearlier, appeared in a largequantity in the cold PCA-solublefraction, and that its quantitydecreased gradually during thesubsequent process of cell division,suggesting that the compoundwas transformed into some othersubstance (s), presumably withits nucleotide moiety going intonucleic acids and the peptidemoiety going into some essentialproteins.
3. Another noteworthyphenomenon observed during the process ofcell division wasthe incorporation of ³⁶S in a group of hotPCA-soluble substances.These sulfur substances were revealedto be sulfur-containingnucleotidic compounds, which might possiblybe some essentialcomponents of, or substances in close relationto, deoxypentosenucleic acid (DNA).

(Received March 1, 1960; )     

"GIGANTISM" OF CHLORELLA VULGARIS I. RELATION OF GIGANTISM TO CELL GROWTH AND DIVISION

1. The sugars which induced gigantism of Chlorella cells wereglucose,fructose, galactose, mannose, xylose and arabinose.These sugarswere utilized as respiratory substrates by thealgal cells.
2. The cellular division of Chlorella was stimulatedby glucoseand galactose, but suppressed by fructose, mannose,xylose andarabinose, while all these sugars evoked gigantism.No correlationwas found between cellular division and gigantism,
3. The photosynthetic activity of giant Chlorella varied withthesorts of sugars added. It was decreased by glucose, fructoseand mannose, but was unaffected by other sugars such as galactose,xylose and arabinose.
4. The respiratory activity of giant Chlorellacells as much higherthan that of control cells.
5. The amountsof protein-N and dry weight per unit volume of giantChlorellawere much less than those of control cells.

¹ Present address: Department of Chemistry, College of GeneralEducation, Osaka University, Toyonaka, Osaka.     

SYNCHRONIZATION OF BACTERIAL CULTURE BY PREINCUBATION OF CELLS AT HIGH CELL DENSITY

The growth of Escherichia coli strain B in a liquid medium wasfound to cease at a cell density of 5x10⁹ cells per ml. (Thiscritical concentration is designated as the maximum or M-concentration.)Even cells harvested from the logarithmic growth phase couldnot divide at this or higher cell densities. Investigationson the metabolic activities of such cultures, however, showedthat the synthesis of cellular protein and nucleic acid wastaking place under such circumstances, showing that only someprocess (or processes) particularly related to cell divisionwas suppressed at the critical cell concentration in question. This finding led us to devise a new method of synchronizationof E. coli: cells harvested from a logarithmic phase were preincubatedat the critical concentration of 5x10⁹ cells per ml for 45 minutes,and then diluted 100 times with fresh medium. This led to synchronizationof cell division, as shown by a stepwise multiplication in cellnumber. (Received June 20, 1961; )     

Studies on the Growth in Culture of Plant Cells: XX. UTILIZATION OF 2,4-DICHLOROPHENOXYACETIC ACID BY STEADY-STATE CELL CULTURES OF ACER PSEUDOPLATANUS L

Omission of 2,4-dichlorophenoxyacetic acid (2,4-D) from batchcultures of sycamore produced an immediate reduction in ratesof cell division and eventually in rates of biomass accumulation.The sequential responses of a chemostat and of turbidostat culturessubjected to gradual withdrawal of 2,4-P were: (i) a transientincrease in biomass accumulation, (ii) increased accumulationof p-coumaric acid, flavonoids, and lignin, (iii) increasedcell aggregation, (iv) reduced rates of cell division, and (v)death. During stepwise reduction of 2,4-D supplied to turbidostatcultures, rates of 2,4-D uptake were reduced when the spentmedium concentration fell to 3?5–1?0 ? 10^–7 M. Underthese conditions the 2,4-D concentration in soluble and insolublecell fractions declined. The growth responses were correlatedwith the spent-medium 2,4-D concentration but not with its concentrationin the intracellular fractions.     

EFFECTS OF LIGHT ON THE DEOXYRIBONUCLEIC ACID FORMATION AND CELLULAR DIVISION IN CHLORELLA PROTOTHECOIDES

1. It has been demonstrated previously that when Chlorella protothecoidesis grown in a medium rich in glucose and poor in nitrogen source(urea), chlorophyll-less cells with markedly degenerated plastids—called "glucose-bleached" cells—are produced eitherin the light or in darkness. When the glucose-bleached cellsare incubated in a medium enriched with the nitrogen sourcebut without added glucose, normal green cells with fully organizedchloroplasts are obtained in the light, and pale green cellswith partially organized chloroplasts in darkness. During theseprocesses of chloroplast development in the glucose-bleachedcells, there occurs, after a certain lag period, an active DNAformation followed by a more or less synchronous cellular division.In the present study the effects of light on the DNA formationand cellular division were investigated in the presence of CMUor under aeration of CO²-free air to exclude the interveninginfluence of photosynthetic process.
2. It was revealed thatlight severely suppresses the DNA formationand cellular divisionof the glucose-bleached cells while enhancingremarkably theirgreening. The suppression was saturated atthe light intensityof about 1,000 lux. Blue light was mosteffective, being followedby green, yellow and red light inthe order of decreasing effectiveness.
3. Further experiments unveiled that light exerts two apparentlyopposing effects on the DNA formation depending upon the timeof application during the incubation of algal cells. When thealgal cells were illuminated only during the lag period beforethe active DNA synthesis, there occurred an enhancement of theDNA synthesis occurring during the subsequent dark incubation.When, on the other hand, the cells were transferred to the lightfrom darkness at or after the start of the DNA synthesis, itcaused an almost complete abolition of the subsequent synthesisof DNA in the algal cells. No such effects of light were observedwith RNA and protein (total)
4. These findings were discussedin relation to the process ofchlorophyll formation occurringconcurrently in the algal cells.

(Received August 10, 1967; )     

ULTRASTRUCTURE OF CELL DIVISION AND REPRODUCTIVE DIFFERENTIATION OF MALE PLANTS IN THE FLORIDEOPHYCEAE (RHODOPHYTA): CELL DIVISION IN POLYSIPHONIA1

Cell division in the marine red algae Polysiphonia harveyi Bailey and P. denudata (Dillwyn) Kutzing was studied with the electron microscope. Cells comprising the compact spermatangial branches of male plants were used exclusively because of their small size, large numbers and the ease with which the division planes can be predetermined. Some features characterizing mitosis in Polysiphonia confirm earlier electron microscope observations in Membranoptera, the only other florideophycean algae in which mitosis has been studied in detail. Common to both genera are a closed, fenestrated spindle, perinuclear endoplasmic reticulum, a typical metaphase plate arrangement of chromosomes, conspicuous, layered kinetochores, chromosomal and non-chromosomal microtubules, and nucleus associated organelles (NAOs) known as polar rings (PRs) located singly in large ribosome-free zones of exclusion at division poles in late prophase. However, other features, unreported in Membranoptera, were observed consistently in Polysiphonia. These include the presence of PR pairs in interphase-early prophase cells, the attachment of PRs to the nuclear envelope during all mitotic stages, the migration of a single PR to establish the division axis, a prominent, nuclear envelope protrusion (NEP) at both division poles at late prophase, the prometaphase splitting of PRs into proximal and distal portions, and the reformation of post-mitotic nuclei by the separation of an elongated interzonal nuclear midpiece at telophase. During cytokinesis, cleavage furrows impinge upon a central vacuolar region located between the two nuclei and eventually pit connections are formed in a manner basically similar to that reported for other red algae. Diagrammatic sequences of proposed PR behavior during mitosis are presented which can account for events known to occur during cell division in Polysiphonia. Mitosis is compared with that reported in several other lower plants and it is suggested that features of cell division are useful criteria to aid in the assessment of phylogenetic relationships of red algae.     

STUDIES ON THE PATHWAY OF SULFIDE PRODUCTION IN A COPPER-ADAPTED YEAST

Metabolism of some sulfur-containing substances was studiedin a copper-resistant strain of yeast (R), its parent strain(P) and respiratory-deficient(RD) mutants from them. The resultsobtained are as follows:

1. Using sulfate, sulfite and thiosulfate as sulfur sources, Rproducedmore H₂S than P, and both of these had the activityhigher than their RD mutants. All of them produced a large amountof H₂S from cysteine, but only little from methionine, cysteinesulfinic acid and S-sulfocysteine.
2. From sulfite and thiosulfate,P and R produced more H₂S inaerobicthan in anaerobic condition.With sulfate and cysteine, however,H₂S production did not differunder those conditions.
3. In both P and R, the sulfate-to-sulfiteand sulfite-to-sulfidereactions were remarkably lowered byiron and zinc deficiencies.But the cysteine-to-sulfide reactionwas not affected by themetal-deficiencies.
4. H₂S productionfrom sulfate was remarkably depressed by highconcentrationsof pantothenate.
5. Rates of reaction steps on a plausible pathway from sulfatetosulfide and to organic sulfur compounds areestimated forthe strainsused. R is characterized by its largecapacity ofthe reaction step from sulfate to sulfite, and excessivesulfitethus formed is liberatedas sulfide not by the way ofcysteine.

¹Present address: Research Reactor Institute, Kyoto University,Kumatori-cho, Sennan-gun, Osaka     

THE FINE STRUCTURE OF MITOSIS AND CELL DIVISION IN THE CHRYSOPHYCEAN ALGA OCHROMONAS DANICA1

At the ultrastructural level, cell division in Ochromonas danica exhibits several unusual features. During interphase, the basal bodies of the 2 flagella replicate and the chloroplast divides by constriction between its 2 lobes. The rhizoplast, which is a fibrous striated root attached to the basal body of the long flagellum, extends under the Golgi body to the surface of the nucleus in interphase cells. During proprophase, the Golgi body replicates, apparently by division, and a daughter rhizoplast, appears. During prophase, the 2 pairs of flagellar basal bodies, each with their accompanying rhizoplast and Golgi body, begin to separate. Three or 4 flagella are already present at this stage. At the same time, there is a proliferation of microtubules outside the nuclear envelope. Gaps then appear in the nuclear envelope, admitting the microtubules into the nucleus, where they form a spindle. A unique feature of mitosis in O. danica is that the 2 rhizoplasts form the poles of the spindle, spindle microtubules inserting directly onto the rhizoplasts. Some of the spindle microtubules extend from pole to pole; others appear to attach to the chromosomes. Kinetochores, however, are not present. The nuclear envelope breaks down, except, in the regions adjacent, to the chloroplasts; chloroplast ER remains intact throughout mitosis. At late anaphase the chromosomes come to lie against part of the chloroplast ER. This segment of the chloroplast ER appears to be incorporated as part of the reforming nuclear envelope, thus reestablishing the characteristic nuclear envelope—chloroplast ER association of the interphase cell.     

ROLE OF SULFUR METABOLISM IN COPPER-RESISTANCE OF YEAST

Cells of a normal yeast strain and of its copper-resistant substrainwere more severely injured by copper treatment under sulfurdeficiency than under nitrogen or carbon deficiency. Even underthese starved conditions, the resistant substrain gave higherviable counts than the parent strain after the copper treatment.Several hours were needed for the sulfur-starved cells to recovertheir copper-resistance when resupplied with sulfur. The observed effect of the amount of sulfur supply on the cellyield was not contradictory to the idea that resistant cellsuse for their resistance mechanism a part of sulfur they absorb.Methionine made cells more sensitive to copper, and this effectwas antagonized by ethionine to some extent. The importance of sulfur metabolism in copper resistance isdiscussed. ¹This work was supported by a Grant in Aid for Fundamental ScientificResearch, Ministry of Education, Japan. ²Present address: Konan University, Kobe, Japan. (Received October 8, 1959; )     

STUDIES ON THE PRODUCTION AND PHYSIOLOGICAL EFFECTS OF ASYMMETRIN

In shake-flask culture asymmetrin was produced by PenicIlliumthomiiaud Byssochlamys niveaduring autolysis. A bioassay wasdevised to estimate relative concentrations of this compound.Culture filtrates of P. thomiicontaining asymmetrin caused adecrease in wet weight, dry weight, and total nitrogen of Phaseolusvulgarisup to 18 days after treatment. At certain intervalsafter treatment with culture filtrate of B. nivea,respirationwas inhibited, and changes were observed in isotope ratio valuesof plants supplied with glucose-¹⁴ C. Plants treated previouslywith culture filtrates of B. nivearesponded but little to gibberelhcacid. High concentrations of mdoleacetic acid inhibited growthof control plants but stimulated growth of plants treated withculture filtrate of B. nivea. ¹Present address: United Fruit Company, Norwood, Massachusetts.Supported in part by a Public Health Service Fellowship No.GF 13,776 from the division of General Medical Sciences, PublicHealth Service, National Institutes of Health, and Grant G 20989from the National Science Foundation. ²Journal Paper No. 2170 of the Purdue Agricultural ExperimentStation.     

STUDIES ON THE RE-ASSIMILATION OF RESPIRATORY CO2 IN ILLUMINATED LEAVES

Experiments were performed, using rice, barley and Hydrangealeaves, to examine the re-assimilation of respiratory ¹⁴CO₂while photosynthesis is going on in an open air flow system. It was found that the leaves which had assimilated ¹⁴CO₂ beforehandevolved, when kept under photosynthesizing conditions, threeto four tenths (variable according to plant species and externalconditions) of the amount of ¹⁴CO₂ to be produced in the dark.Such an incomplete re-utilization of ¹⁴CO₂ was observed alsoin spinach leaf homogenate as well as in the leaves which hadpreviously absorbed ¹⁴C-glucose. The ¹⁴CO₂ output in rice leaves was found to be acceleratedby the light of high intensity. A possibility of light stimulationon the respiration was suggested. (Received October 7, 1961; )     

WATER PERMEABILITY OF THE CELL WALL IN NITELLA

1. A method has been developed to measure the hydraulic conductivityof the wall of the internodal cell of Nitella flexilis.
2. Therate of water penetration through the cell wall varies linearlywith the hydrostatic pressure difference between the two sidesof the wall, showing that water permeability of the cell wallremains independent of the pressure difference applied.
3. Waterpermeability of the cell wall is inversely proportionalto itsthickness It is 30µµmin^–3{dot}atm^–3when the thickness of the wall is 10 µ.
4. Water permeabilityof the cell wall is the same for inward andoutward water flow.The polar water permeability of the entiremembrane system (walland protoplasmic part) of the living celldemonstrated by KAMIYAand TAZAWA (1) is, therefore, due tothe living protoplasmicpart.
5. The ratio of the inward to outward permeability constantsofthe protoplasmic layer alone is higher than that of the entiremembrane system composed of protoplasmic layer and cell wall.

¹ Dedicated to Prof. H. TAMIYA on the occasion of his 60th birthday.The present work was supported in part by a Grant-in-Aid forFundamental Scientific Research from the Ministry of Education. ² Present address: Sh?in Women's College, Kobe. (Received July 21, 1962; )     

Effect of Nitrate Concentration on the Root: Shoot Ratio in Dactylis glomerata L. and on the Kinetics of Growth in the Vegetative Phase

The vegetative growth of Dactylis glomerata L. in sand was studiedunder controlled light, temperature, and nutritional conditions.Plants were daily supplied with three nutrient solutions ofdifferent nitrate concentrations (10^–2, 10^–3 and2 x 10^–4 mol I^–1). For each concentration, growthobeyed an exponential law between the fourth and seventh weeksafter sowing. The time constant of the exponential was the samefor the shoot as for the root, and showed no significant variationwith nitrate concentration. The kinetic results and the strong dependence of the root: shootratio on nitrate concentration are discussed on the basis ofThornley's model. Hypothesizing that the molecular mechanismsof nitrate absorption are independent of the nitrate concentrationof the nutrient solution, we derived a relationship betweenthe root: shoot ratio and nitrate concentration. This relationshipwas found to be compatible with the experimental results. Dactylis glomerata L., vegetative phase, kinetics of growth, root: shoot equilibrium, nitrate absorption     

细胞膜脂质流动性的不均一性与细胞分裂动力学的关系

细胞腊脂流动性在不同类属细胞存在着差异,其差异的程度取决于细胞的生理和生化特性。正常淋巴细胞、肺腺癌、肺鳞癌细胞以及结核细胞膜脂流动发生 分别为２．５１７±０．２６７、２２．５５７±３．７７１,３２．８７５±９．７０９和４．０２６±０．７２２。细胞分裂动力学与膜脂质流动性有关系。细胞分裂及其程度是膜脂质流动性差异的物质基础,同时并受细胞膜脂质的组成,脂蛋白生化以及外界因素的ｐＨ、Ｃａ＾２＋等影响,     

EFFECTS OF TEMPERATURE AND ILLUMINANCE ON CELL DIVISION RATES OF THREE SPECIES OF TROPICAL OCEANIC PHYTOPLANKTON1

Three species of tropical oceanic phytoplankton were isolated from two locations in the eastern Pacific Ocean. Unialgal cultures were maintained in an enriched seawater medium. The effects of temperature, and, in separate experiments, illuminance, on the exponential cell division rates of those algae were investigated. For 2 isolates of Gymnoclinium sp. (probably G. simplex), maximum growth rates were 1.25 and 1.7 divisions/24 hr, the optimum temperature range was 23-29 C, the compensation illuminance was 35 ft-c, and the saturation illuminance was 750 ft-c and above. For a small species of Chaetoceros, the maximum growth rate was 6.0 divisions/24 hr, the optimum temperature range was 23-37 C, the compensation illuminance was 10 ft-c, and the saturation illuminance was 600 ft-c. For a small Nannochloris species, the maximum growth rate was 4.5 divisions/ 24 hr, the optimum temperature range was 27-37 C, and the saturation illuminance was 800 ft-c. Nannochloris grew heterotrophically by apparently utilizing organic matter supplied by soil extract.     

STUDIES ON THE METABOLISM OF A SULFUR-OXIDIZING BACTERIUM: I. OXIDATION OF SULFUR

1. Thiobacillus thiooxidans, isolated in our laboratory, was foundto oxidize sulfur, but not thiosulfate. Tetrathionate is alsooxidized slightly. Its ability to oxidize sulfur is inactivatedeven by such a mild treatment as keeping the cells in a frozenstate.
2. Inhibitory action of alcohols on the sulfur oxidationincreasesas the length of carbon chain of alcohols increases.Carboxylicacids do not inhibit the sulfur oxidation at pH abovetheirpK, while they strongly inhibit the reaction at pH belowthepK.
3. The sulfur oxidation is inhibited by cyanide, azide,diethyldithiocarbamateand carbon monoxide, and the inhibitionby carbon monoxide isnot reversed by light. These results suggestthe presence ofmetal enzymes in the sulfur oxidation system.The terminal enzymeof this reaction appears to be differentfrom the usual cytochromeoxidase.

(Received May 13, 1960; )     

Nitrogen-13 Studies of Nitrate Fluxes in Barley Roots: II. EFFECT OF PLANT N-STATUS ON THE KINETIC PARAMETERS OF NITRATE INFLUX

Influx of nitrate into the roots of intact barley plants wasfollowed over periods of 1–15 min using nitrogen-13 asa tracer. Based on measurements taken over 15 min from a rangeof external nitrate concentrations (0·2–250 mmolm^–3), the kinetic parameters of influx, I_max and K_m, werecalculated. Compared with plants grown in the presence of nitrate throughout,plants that had been starved of N for 3 d showed a significantlygreater value ofI_max for ¹³N-nitrate influx (by a factor of1·4–1·8), but a similar value of K_m (12–14mmol m^–3). Pre-treating N-starved plants with nitratefor about 5 h further increased the subsequent rate of ¹³N-nitrateinflux, but had little effect in the unstarved controls. Allowingfor this induction of additional nitrate transport, the differencein rates of nitrate influx in control and N-starved plants wassufficient to account for the previously-observed differencein net uptake by the two groups of plants. In barley plants grown without any exposure to nitrate, butwith ammonium as N-source, both I_max and K_m for subsequent ¹³N-nitrateinflux were significantly decreased (by about one-half) comparedwith the corresponding nitrate-grown controls. The importance of changes in the rate of influx in the regulationof net uptake of nitrate is discussed. Key words: Ion transport, nitrate, influx, kinetic parameters, N-deficiency     

EFFECTS OF TEMPERATURE AND ILLUMINANCE ON CELL DIVISION RATES OF THREE SPECIES OF TROPICAL OCEANIC PHYTOPLANKTON1

Three species of tropical oceanic phytoplankton were isolated from two locations in the eastern Pacific Ocean. Unialgal cultures were maintained in an enriched seawater medium. The effects of temperature, and, in separate experiments, illuminance, on the exponential cell division rates of those algae were investigated. For 2 isolates of Gymnodinium sp. (probably G. simplex), maximum growth rates were 1.25 and 1.7 divisions/24 hr, the optimum temperature range was 23–29 C, the compensation illuminance was 35 ft-c, and the saturation illuminance was 750 ft-c and above. For a small species of Chaetoceros, the maximum growth rate was 6.0 divisions/24 hr, the optimum temperature range was 23–37 C, the compensation illuminance was 10 ft-c, and the saturation illuminance was 600 ft-c. For a small Nannochloris species, the maximum growth rate was 4.5 divisions/ 24 hr, the optimum temperature range was 27–37 C, and the saturation illuminance was 800 ft-c. Nannochloris grew heterotrophically by apparently utilizing organic matter supplied by soil extract.     

STUDIES ON NITELLA HAVING ARTIFICIAL CELL SAP I. REPLACEMENT OF THE CELL SAP WITH ARTIFICIAL SOLUTIONS

A method for replacing the cell sap of Nitella with an artificialsolution was introduced. The technique, which is a modificationof KAMIYA and KURODA'S (1, 2), is applicable not only for isotonicbut also for hypertonic or hypotonic solutions. Photometricdeterminations of K⁺, Na⁺, Ca⁺⁺ and Cl^– proved that thereplacement of the cell sap with the present method is satisfactory.The internodal cell of Nitella, whose cell sap was replacedwith an isotonic solution with a simple composition such asa mixture of KCl, NaCl and CaCl₂, can be kept living at leastfor several days, sometimes even for more than one month. (Received September 6, 1963; )     

PRECISE MEASUREMENT OF THE CHANGE OF STATISTICAL DISTRIBUTION OF CELL SIZE OCCURRING DURING THE SYNCHRONOUS CULTURE OF CHLORELLA

Change of statistical distribution of cell size occurring inthe synchronous culture of Chlorella ellipsoidea was followedby using a COULTER counter. The culture was started using apopulation of D-cells which showed a sharp distribution of cellsize. During the growth phase, there occurred characteristicchanges in the height and shape of the distribution curve; namely,the height first decreased with broadening of the distributionand then increased to the level even higher than the originalpeak. The broadening of the curves, which indicates the loweringof degree of homogeneity of population, occurred during theperiod of most active growth, and the homogeneity was restoredat later stages of ripening where the growth became sluggish.When the ripened cells (L₃) were transferred to the darknesstheir volume decreased to some extent before the occurrenceof cellular division. It was assumed that the shrinkage of cellsobserved may be partly due to exudation of water from the cellsand partly to the consumption of fuel material caused by enhancedrespiration, both having been shown to occur at the stage ofcell maturation. (Received June 12, 1964; )