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; )     

DISTRIBUTION AND TURNOVER OF PHOSPHATE COMPOUNDS IN GROWING CHLORELLA CELLS

1. Using the Chlorella cells which had been uniformly labeled with³²P, the distribution of phosphorus in various fractions ofcell material was investigated. Uniformly ³²P-labeled Chlorellawas further grown in a P-free medium or in a standard "cold"medium, and the change of distribution of ³²P (as well as theuptake of exogenous P) in various cell fractions was followed.
2. Analysis of the ³²P-labeled algal cells showed that the highestin P-content was the fraction of RNA followed by those of polyphosphates,lipid, nucleotidic labile phosphate compounds, DNA and protein(in decreasing order). ATP and ADP were found to be only minorfractions of the total labile phosphates.
3. On incubating the³P-labeled alga in a P-free medium, the P.contentsin the fractionsof DNA, protein, lipid and ATP increased, thosein polyphosphatesand ADP decreased, and that in RNA remainedalmost unchanged.When the ³²P-labeled alga was further grownin the normal "cold"medium, DNA and protein increased withthe expenditure of endogenous³²P, but with practically no incorporationof external P. Inthe meantime the P in polyphosphates decreasedconsiderably,and the RNA fraction incorporated a large amountof externalP but only a little of endogenous³²P.
4. It was inferred that,under the experimental conditions of thepresent study, thephosphorus used in the syntheses of DNA andprotein was primarilytaken from polyphosphates, while thatused in the synthesesof RNA, phospholipid and polyphosphateswas, for the most part,taken from the extracellular P-source.

¹A part of this paper was read at the Vth International Congressof Biochemistry, Moscow, August 10–16, 1961. (Received June 4, 1961; )     

EFFECT OF ULTRAVIOLET LIGHT UPON VARIOUS PHYSIOLOGICAL ACTIVITIES OF CHLORELLA CELLS AT DIFFERENT STAGES IN THEIR LIFE CYCLE

1. Using Chlorella ellipsoidea as material, investigations weremade of the effects of ultraviolet irradiation upon variousactivities of cells at different developmental stages in theirlife cycle. Cell activities investigated were photosynthesis,respira tion, over-all growth, modes of synchronous growth andcell division as well as the formation of nucleic acids. Theu. v.- light applied was 30 µµW/cm²in intensityand 2537 Å in wavelength.
2. The most u. v.-sensitive wasthe over-all growth activity, andin this respect the irradiationapplied at the L₂-stage wasmore inhibitive than that givenat the D-stage. The next mostvulnerable was the photosyntheticactivity, the sensitivitybeing the same in the D- and L-cells.The most resistant towardu.v. was the endogenous respirationof D-cells followed by theirrespiration using exogenous glucoseas substrate. The L₂-cellsappeared to be unable to use exogenousglucose as substrateof respiration, but their endogenous respirationwas considerablystronger than that of D-cells, and its u. v.-sensitivitywasthe same as that of glucose respiration of D-cells.
3. WhenD-cells were u. v. irradiated immediately before the startofsynchronous culture, growth and cell division as well astheformation of DNA and RNA were retarded in proportion totheu. v.-dose applied. The division number (n) was normal (around4) at lower u.v.-doses (1-2 minute irradiation), but was reducedto a half (about 2) at a higher dose.
4. When, during the synchronousculture, 1-minute u.v.- irradiationwas applied at various stagesof the ripening phase, the divisionwas retarded, but the cells,after attaining an abnormally largesize, divided into about8. If the irradiation was given atthe L₄-stage, the divisionnumber was practically unmodified(n=4.5), although the divisionwas somewhat retarded comparedwith that of the control culture.When a 1-minute irradiationwas given at the L₂-stage, thereoccurred an apparent stimulationof DNA- and RNA-formation,a phenomenon which corresponds tothe production of a largernumber of daughter cells than itwas the case in control cultures.
5. Thus the cells which were moderately u.v.-irradiated at differentstages of synchronous culture were able to complete their lifecycle, but later a certain portion of irradiated cells becameunable to grow normally.

¹Present address: Department of Biochemistry, Dartmouth MedicalSchool, Hanover, New Hampshire, U.S.A. (Received March 6, 1961; )     

RIBONUCLEIC ACIDS APPEARING DURING THE PROCESS OF CHLOROPLAST REGENERATION IN THE "GLUCOSE-BLEACHED" CELLS OF CHLORELLA PROTOTHECOIDES

1. Investigations were made on the modes of synthesis of differentspecies of RNA which appear during the greening (chloroplastregeneration) of the "glucose-bleached" cells of Chlorella protothecoidescontaining profoundly degenerated plastids.
2. RNAs were extractedfrom the algal cells which had been labelledwith ³²P for 1hr before harvesting at different stages of thegreening inthe light and in darkness, and subjected to columnchromatographywith methylated albumin-coated kieselguhr. Itwas found that,during the greening process, the elution profilesof RNAs, interms of the optical density at 260 mµ and³²P-radioactivity,changed profoundly.
3. Based on these and other results, it wasconcluded that duringan early phase of the chloroplast regenerationin the glucosebleachedalgal cells, there occurs an active formationof both ribosomalRNAs (rRNAs) and the RNAs corresponding tosoluble RNA (sRNA),the formation coming, however, later toa standstill when thesynthesis of chlorophyll has proceededto a certain level. Thequantity ratio of sRNA to rRNA was foundto be constant (30:70)at different stages of the greening (bothin the light and indarkness), with a few exceptions. The synthesisof the chloroplastribosomal RNA is markedly accelerated bylight, and its maximumrate is observed sometime later thanthat of the non-chloroplast("cytoplasmic") ribosomal RNA. Itwas suggested that there areat least two different sites ofsynthesis of ribosomal RNAs,one in the plastid and the otheroutside of it (most probablyin the nucleus).

¹A part of this work was reported at the Symposium on Cell Differentiationsponsored by the Institute of Applied Microbiology, Universityof Tokyo, in November 1965. ² Present address: Institute for Plant Virus Research, Ministryof Agriculture and Forestry, Aoba-cho, Chiba.     

PHYSIOLOGICAL AND BIOCHEMICAL CHANGES OF CARROT ROOT CALLUS DURING SUCCESSIVE CULTURES

1. The longer the period of stock culture, the more remarkableis the growth inhibition by 8-azaguanine in callus.
2. Chloramphenicol,5-methyltryptophane and mitomycin C exert greaterinhibitionon growth in CCL than in CCS.
3. Bud formation is inhibited bysome concentrations of chloramphenicolwithout accompanyinginhibition of the growth.
4. Cell size and the contents of RNA,DNA, protein and lipid percell of CCL are greater than thoseof CCS, respectively. Thecontents per cell of RNA and lipidin "mitochondrial fraction"are higher in CCL than in CCS.
5. Incorporationof guanine-8-¹⁴C into RNA of CCS occurs rapidlyin the first12 hr and slows down thereafter, but that in CCL-RNAincreasessteadily for 16 hr. This difference in rate of theincorporationafter 12 hr between CCS and CCL is principallydue to the differencein rate of the incorporation into RNAof nuclear, mitochondrialand soluble fractions.

1. The rate of RNA breakdown in CCL wasnot so great as the rateof synthesis.
2. 8-azaguanine (10^–3and 10^–4M) inhibits incorporationof guanine-8.¹⁴C intoRNA of both CCS and CCL during 14 hr,but thereafter (up to25 hr) it inhibits the incorporation intoCCL-RNA alone leavingthat into CCS-RNA unaffected.

1. In CCL 510^–5M 8.azaguaninedoes not affect total radioactivityincorporated into bulk RNA,but inhibits incorporation intoRNA of "mitochondrial fraction".

(Received December 23, 1964; )     

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; )     

DNA Synthesis and Cell Division During Spore Germination in Lygodium japonicum

This paper describes the ontogenetic sequence of cell divisionsand associated DNA synthetic patterns observed in sectionedspores of Lygodium japonicum (Thunb.) Sw., collected at differentstages of germination. Following exposure to a saturating doseof red light, the spore undergoes an asymmetric division toform a basal cell, which retains nearly all of the storage inclusions,and an apical cell which expands and protrudes from the rupturedsporoderm. Division of the apical cell results in formationof a protonemal cell and an intermediate cell. Subsequently,the latter cell divides to form the primary rhizoid and a wedgecell adjacent to the protonemal cell. Secondary rhizoids mayarise from later divisions of either the basal cell or the wedgecell. In addition, the wedge cell appears to have the capacityto form a secondary prothal-lial filament. Histochemical localizationof cell constituents indicates an increasing concentration ofcytoplasmic RNA and protein in the presumptive protonemal regionof the spore cell prior to division. Autoradiography of ³H–thymidineincorporation has shown that synthesis of nuclear DNA precedeseach cell division. Although strictly nuclear DNA synthesisoccurs during early stages of germination, extra-nuclear DNAsynthesis increases greatly following division of the sporecell. The results are discussed in relation to earlier studieson cell division patterns seen in whole mount preparations ofgerminating spores of different species of Lygodium. Lygodium japonicum, spore germination, cell division, DNA synthesis     

SYNCHRONOUS CULTURE OF CHLORELLA: I. KINETIC ANALYSIS OF THE LIFE CYCLE OF CHLORELLA ELLIPSOIDEA AS AFFECTED BY CHANGES OF TEMPERATURE AND LIGHT INTENSITY

1. Using the technique of synchronous culture, investigationsweremade of the effects of temperature and light-intensityon cellularlife cycle of Chlorella ellipsoidea. Some improvementsin theculture technique for obtaining a good synchrony of algalgrowthwere described.
2. By following the changes of averagecell volume and cell numberoccurring during culturing, therates of the following processesof life cycle were determined:(i) "growth" (or the increasein cell mass) occurring from thestage of smaller cells (D_a)to the stage of ripened cell (L₃),(ii) "ripening" (or processofformation of "nuclear substances"as estimated from the averagenumber of daughter cells formedfrom single mother cell), and(iii) " maturing and division" which leads to the full maturationof mother cells (L-cells)and their division into separate daughtercells (D-cells).
3. "Growth"and "ripening" were found to be dependent in light,"maturingand division" light-independent. The time requiredfor "growth"and "ripening" (C) is dependent on temperaturebut independentof light intensity, the onset of "maturing anddivision" occurringat the same time (D) of culturing undervaried light intensities.The average cell volume at this stage(L₃),however, was foundto be markedly modified by light intensity;larger with highertemperatures (see Fig. 4).
4. Changes in incubation temperature(under the condition of saturatinglight intensities) were foundto affect the life cycle in thefollowing way: (i) The timeof onset of "maturing and division"(D), varies markedly withculturing temperature; earlier athigher temperatures, (ii)The average cell volume at this stagealso depends on temperature; smaller at higher temperatures.
5. The average number of daughtercells (n) emerging from singlemother cells, was found to beuninfluenced by culturing temperature;(4.0–4.1 underthe conditions of the present study). Itwas found that thedivision number n is remarkably varied bychanging the lightintensity in the "growth" and "ripening"phases; 2.0 at 1 kilolux,3.7 at 5 kilolux, 4.2 at saturatinglight intensities (10 and25 kilolux). This finding was explainedby assuming a light-dependentformation of "nuclear substances"during the "growth" and "ripening"phases, the quantity of thesubstances in the cell at L₃ stagedeterminig the division number.
6. The experimental data wereanalyzed reaction kinetically, therate constants and othercharacteristics of the reactions constitutingthe processesof life cycle were determined, and values forthe apparent activationenergy for each reaction were computed.The reactions were discussedwith special reference to theirrelationship with photosyntheticprocess was discussed.

(Received November 7, 1959; )     

"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.     

DE- AND RE-GENERATION OF CHLOROPLASTS IN THE CELLS OF CHLORELLA PROTOTHECOIDES: IV. EFFECTS OF 5-FLUOROURACIL, DIHYDROSTREPTOMYCIN, CHLORAMPHENICOL AND ACRIDINE ORANGE ON THE PROCESSES OF GREENING AND DIVISION OF "GLUCOSE-BLEACHED" ALGAL CELLS

1. The "glucose-bleached" cells of Chlorella protothecoides, whichwere obtained by the method described previously, were transferredto a glucose-free medium containing basal mineral nutrientsalone in the dark, and after a certain period of time, the cellsuspension was supplied with urea and light to induce the greeningof cells. At different times before and after the provisionof urea and light, the inhibitors were applied to the cultureto test their effects upon the process of greening.
2. Markedgreening of the glucose-bleached cells occurred aftera lagperiod in the control culture. 5-Fluorouracil inhibitedthecell greening strongly when it was applied at differenttimesbefore the provision of urea and light. When applied aftertheprovision of urea and light, the suppressive effect of 5-fluorouracilgradually decreased with the delay of its application. No inhibitiveeffect was observed when the uracil analogue was added laterthan the 12th hr after the provision of urea and light, thetime around which the chlorophyll formation started in the controlculture. On the other hand, the cell division was much morestrongly affected by 5-fluorouracil. Even when it was appliedat the 18th hr after the provision of urea and light, the celldivision was completely halted, indicating that the greeningand division of the glucose-bleached cells are separate processes.Different mechanisms of action of the uracil analogue towardsthese two processes were suggested.
3. Dihydrostreptomycin showedits strongest suppressive effectwhen added at the beginningof the dark incubation of algalcells in the glucose-free medium,and with the delay of application,its effect was progressivelyreduced, even during the periodof the dark incubation. Thesuppression, however, was stillmarked when it was applied atthe 15th hr.
4. Chloramphenicol was found to inhibit stronglythe chlorophyllformation and protein synthesis, but, to a muchlesser extent,RNA synthesis. Acridine orange suppressed thecell greeningand division at such a low concentration as 1.5µg/ml.
5. Based on these observations it was concludedthat synthesesof nucleic acid and protein are essential processesfor thegreening of the glucose-bleached algal cells. Successiveeventsoccurring in the greening process were discussed.

(Received March 9, 1965; )     

FORMATION OF MYO-INOSITOL AND PHYTIN IN RIPENING RICE GRAINS

With the view to elucidate the role of myo-inositol in the ripeningprocess of rice grains, its distribution, formation and conversionwere studied.

1. myo-Inositol in the ripening rice grains was fractionated intofree-, phosphate ester- and phosphoinositide-forms. At the earlystage of ripening, a considerable part of myo-inositol was foundin free state, and at the end of ripening stage the most partwas found in phosphate ester-state, phytic acid. The contentof phosphoinositide in the grains was low during the ripeningperiod.
2. The occurrence of biosynthesis of myo-inositol inthe ripeningrice grains was confirmed by the observation ofincorporationof ¹⁴C into myo-inositol from ¹⁴C-sugars and itwas found, fromthe feeding experiment of myo-inositol- thatmyo-inositol doesnot undergo reactions further than phosphorylation.
3. The feeding experiment of glucose-l-³²P showed that the distributionpattern of ³²P in different fractions of grain material wasthe same as that of ³²P-phosphate, indicating that phytic acidis one of the final products of phosphorus metabolism in theripening rice grains.
4. These results led to the assumptionthat myo-inositol mightact as an acceptor of phosphorus toremove inorganic phosphorusin favor of starch synthesis byphosphorylase.

(Received September 12, 1962; )     

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; )     

Studies on nucleic acids in chloroplasts isolated from Chlorella protothecoides

1. 1. Subcellular fractions of Chlorella protothecoides were separatedby fractional centrifugation of the algal cell homogenate inmixtures of cyclohexane and CCl₄. The base composition, meltingprofiles and IRC-50 column chromatographic patterns of DNA preparationsfrom the chloroplast and non-chloroplast fractions were examined.It was shown that the algal chloroplast contains at least oneDNA species which is different from the nuclear DNA.
2. 2. RNApreparations from the subcellular fractions were subjectedtoMAK column chromatography, sucrose density gradient centrifugationand analysis for base composition. It was demonstrated thatthe chloroplast contains ribosomal RNA and soluble RNA. Twocomponents of the chloroplast ribosomal RNA were found to havethe same patterns as those of the E. coli ribosomal RNA in MAKcolumn chromatography and zone centrifugation. The major componentof the chloroplast ribosomal RNA was distinctly different fromthat of the non-chloroplastic (cytoplasmic) ribosomal RNA inall properties examined.

¹This work was partly reported at the Symposium on Mitochondriaand Chloroplasts as Self-duplicating Units sponsored by theBotanical Society of Japan in August, 1966, and at the Symposiumon Biogenesis of Subcellular Particles, the 7th Internatl. Congressof Biochemistry, Tokyo, 1967.     

STUDIES ON THE MECHANISM OF GROWTH INHIBITING EFFECT OF LIGHT

1. A substance which inhibits indoleacetic acid (IAA)-and naphthaleneaceticacid (NAA)-induced elongation of Avena coleoptile section andIAA-induced Avena coleoptile curvature was found in an ethersoluble neutral fraction of water extract of sunflower leavesand in agar blocks containing the diffusate from young sunflowerleaves.
2. This substance also inhibits the growth of isolatedsunflowerepicotyl.
3. The R_f value (0.9) of the substance ona paper chromatogramdeveloped with ammoniacal iso-propanolindicates that it isidentical with the inhibitor reported byAUDUS et al. (1956),but not with inhibitor-ß.
4. Theinhibitor can be transported from leaf to stem, and thetransportseems to be accelerated by illuminating the leaf.
5. The auxindiffused from sunflower leaf into agar block may beidenticalwith IAA.
6. A substance, which has the same properties as theinhibitorfrom sunflower leaf, was obtained in crystalline formfrom theleaf of Jerusalem artichoke.
7. The mechanism of growthinhibition caused by this crystallinesubstance seems to involveinactivation of a sulfhydryl group.
8. The reason why the stemgrowth of sunflower seedlings is reducedby strong light isdiscussed: the amount of the inhibitor transportedfrom leafto stem is increased under strong light, and in thestem, growthinhibition is caused by a direct effect of thisinhibitor ongrowth and by its inhibiting effect on the transportof IAAfrom leaf to stem.

¹ Present address: Botanical Garden, Faculty of Science, Universityof Tokyo, Tokyo (Received February 15, 1961; )     

COMPONENTS OF THE ELECTRON-TRANSFERRING SYSTEM IN ACETOBACTER SUBOXYDANS AND RECONSTRUCTION OF THE LACTATE OXIDATION SYSTEM

1. Cytochromes a₁⁵⁹⁰, b⁵⁶⁰, c₁⁵⁵⁴ and c₁⁵⁵² were isolated andpurifiedfrom a strain of Acetobacter suboxydans. The proceduresusedwere described in detail.
2. The main cytochrome band at550-560 mµ in intact cellssplitted at liquid air temperatureinto two bands, 551 mµ(strong) and 559 mµ (weak).
3. Optical and physiological properties of the four cytochromeswere investigated. Lactic dehydrogenase activity was found tobe associated with cytochrome c₁⁵⁵⁴. The two c₁-type cytochromes,especially cytochrome c₁⁵⁵⁴, persisted in their reduced formafter the purification through many steps.
4. By some combinationsof isolated components reconstruction ofthe oxygen uptake systemcould be realized.
5. The oxygen-consuming activity of purifiedoxidase preparationswas accelerated by a-tocopherol but notby Emasoll 4130 andTween 80.
6. Some discussions were made onthe nature of terminal oxidase,the role of cytochrome c₁⁵⁵²in the electron-transport system,and persistence of reducedstate of c₁-type cytochromes.
7. A possible scheme of the electron-transferringsystem of Acetobactersuboxydans was presented.

(Received May 16, 1960; )     

Inhibitory effect of lycorine on cell division and cell elongation

Lycorine, an alkaloid isolated from bulbs of Amarillidaceae,was found to be a powerful inhibitor of cell division and elongation.Adding different concentrations of lycorine from 10^–6M to 10^–4 M in an appropriate growth-medium strongly inhibitedcell division in explants of lettuce pith parenchyma. The sameresult was obtained with liquid yeast cultures growing exponentially. Lycorine-treated meristematic cells of the primary roots ofVicia faba also showed rapid inhibition of the mitotic indexwhile interphase cells increased proportionately. Lycorine alsoinhibited endogenous and auxin-induced cell elongation in Avenacoleoptiles and pea segments. Since both cell division and cell elongation require proteinsynthesis and RNA synthesis, the assumption is that lycorineprobably inhibits one of the two syntheses. ¹This study was supported by a contract between the NationalResearch Council of Italy and University of Bari, Instituteof Botany. (Received November 27, 1972; )     

COMPARATIVE STUDIES ON GROWTH, RESPIRATION, PHOTOSYNTHESIS AND PIGMENT CONTENT IN RHODOPSEUDOMONAS PALUSTRIS

1. Comparative studies were performed on growth, photosyntheticand respiratory activities, and pigment content in Rhodopseudomonaspalustris.
2. The growth of the organism, as influenced by variousculturalconditions such as light, aerobiosis, anaerobiosisand nutritionalfactors was investigated.
3. The respiratoryactivity of the bacterium was found to be higherin dark-growncells than in cells grown in the light. The photosyntheticactivitydid not significantly depend on the growth conditionsof theculture. Cells of younger cultures were found to be moreactivethan those of older cultures, with respect both to respirationand photosynthesis.
4. The pigment content was found to be higherin the light-growncells than in the dark-grown ones. The ratiophotosyntheticactivity/bacteriochlorophyll was significantlyhigher in thelatter than in the former.
5. Light, as well asvarious nutritional factors, was found toexert a marked accelerationon pigment formation, although ithas not yet been possibleto culture cells completely lackingin photosynthetic pigmentsand accordingly in photosyntheticactivity.

¹ Present address: Division of Dermatology and Urology, TokyoMetropolitan Hiroo Hospital, Tokyo. ² Present address: Department of Biology, Saitama University,Urawa. ³ Present address: Department of Biochemistry, School of Medicine,Yokohama University, Yokohama. ⁴ Present address: Department of Biophysics and Biochemistry,Faculty of Science, University of Tokyo, Tokyo. (Received July 23, 1961; )     

STUDIES ON PROTEIN SYNTHESIS IN TOMATO COTYLEDONS AND LEAVES. I. PROTEIN SYNTHESIS AND TURNOVER IN INTACT COTYLEDONS AND LEAVES

1. Details of aseptic culture of virus-free tomato seedlings usedin comparative in vivo and in vitro studies on protein synthesisare described.
2. Developmental changes in the levels of DNA,RNA, protein andchlorophyll content of seedling cotyledonsand leaves were recorded,and are related to protein synthesis.
3. Incorporation of isotopically labeled carbon into proteinwasfollowed both by photosynthetic uptake of ¹⁴CO₂ and by theuptakeof ¹⁴C-amino acids through the roots.
4. A marked stimulationby light of ¹⁴C uptake was observed, andthe higher rate of¹⁴C incorporation from ¹⁴CO₂ than from ¹⁴C-aminoacids intothe protein fraction is discussed in relation tothe pathwaysof protein synthesis in tomato leaves, and alsowith regardto protein turnover.

¹Present address: Dept. of Horticultural Science, Universityof Wisconsin, U.S.A.     

PROMOTION OF ADVENTITIOUS ROOT FORMATION BY HELIANGINE AND ITS REMOVAL BY CYSTEINE

1. Heliangine at 10^–4M promoted the adventitious root formationin hypocotyls of cuttings taken from light-grown (1,900 lux)seedlings of Phaseolus mungo. The promotion was almost completelyreduced by simultaneously supplied 310^–4M cysteine or1.510^–4M cystine, but not suppressed by 310^–4Mof reduced glutathione, alanine or serine.
2. A 4 hr pretreatmentwith 310^–4M cysteine made Phaseoluscuttings less sensitiveto heliangine, but cysteine suppliedafter the treatment withheliangine brought about no effecton the action of heliangine.
3. Cysteine also removed the inhibiting effect of heliangineonthe indoleacetic acid-induced elongation of etiolated Avenacoleoptile sections.
4. In an aqueous solution heliangine formedan addition productwith cysteine, indicating that cysteinecan inactivate helianginewithout any biological processes.
5. On Phaseolus adventitious rooting, no effect was observedofp-chloromercuribenzoic acid, N-ethylmaleimide, 1,4-naphthoquinone,coumarin or penicillin. Reactivity toward sulfhydryl groupsalone does not qualify a substance to be a promotor of rootformation.
6. Maleic hydrazide at 10^–4M promoted root formation,butits effect was not removed by cysteine.

¹ Contribution No. 13 from the Botanical Gardens, Faculty ofScience, University of Tokyo, Koishikawa, Tokyo.     

CHANGES IN RESTING POTENTIAL AND ION ABSORPTION INDUCED BY LIGHT IN A SINGLE PLANT CELL

1. Effect of light on ion absorption and resting potential of theinternodal cell of Nitella flexilis was investigated under variousconditions.
2. On illumination, the resting potential increasedby about 30mVin 10^–4 M KCl and by about 60 mV in 10^–4M NaClsolution. A similar photoelectric response was also observedin 10^–3 M KCl, 10^–2 M CaCl₂ and 5 x 10^–2 MCaCl₂ solutions, but not at all in 10^–2 M KCl solution.
3. Absorption of ions by the cell took place in parallel withthelight-induced change in resting potential.
4. Red and bluelights were very effective in increasing the restingpotential,while green light was almost ineffective. These differenteffectsof color lights were in good agreement with their effectsinincreasing the osmotic value of the cell.
5. The photoelectricresponse was not affected by phenylurethane,which, on the otherhand, strongly inhibited the light-inducedion absorption.
6. Theuptake of ions by the cell from the external medium intothevacuole is assumed to proceed in two different steps: thefirstis the process involving the ion movements across theoutermostplasmalemma, and the second is that involved in thetransportof ions through the cytoplasmic layer and tonoplast.The formerprocess is considered to be influenced by the increasein restingpotential probably caused by the light absorbed bychlorophyll.The process was, however, suggested to be independentof photosynthesis.On the other hand, the latter process issupposed to be relatedto photosynthesis. A discussion was madealong this line.

(Received July 26, 1962; )