Effects of Glyphosate on Isolated Maize Mitochondria

The effects of the herbicide glyphosate (K⁺ salt) on isolatedmaize mitochondria have been investigated. Protein synthesis,oxygen uptake (state 3 and state 4 respiration) and passiveswelling were inhibited at concentrations in the 10^–6–10^–2M range. No decrease of the respiratory control ratio (RCR)or stimulation of ATPase activity by glyphosate (K+ salt) wereobserved. It is concluded that the previously reported decreaseof the RCR and ATPase stimulation by glyphosate (isopropylaminesalt) were probably due to the isopropylamine moiety or to impuritiesof the technical product. Key words: Glyphosate, Herbicide action, Maize, Mitochondria     

Carbon import into barley roots: stimulation by galactose

Galactose was applied to one-half of a split root system ofbarley. It stimulated import of photoassimilate labelled withC-11 from leaf 2 into that root half at concentrations from0.2–50 mol m^–3. The lag before an increase in importwas detected decreased from>60 to <30min as concentrationof galactose was increased across this range. In the presenceof 10 mol m^–3 glucose, 2 mol m^–3 galactose did notincrease import of C-11. Whilst 2 and 50 mol m^–3 galactosehad no effect on respiratory oxygen uptake of roots, they causeda rise in the rate of evolution of ¹¹CO₂ in <5 min. Galactoseat 2 mol m^–3 reduced the rate of elongation of the seminalroot axis, but only more than 4 h after applying it; elongationgrowth had ceased by 6 h. These results are discussed in thecontext of control of translocatory import of carbon into elongatingbarley roots. Key words: Carbon partitioning, galactose, respiration, roots, translocation, sink     

The Metabolism of 3-Indolylacetic Acid in Plant Tissues3

The nature of metabolic products of 3–indolylacetic acid(IAA) extracted from potato tuber disks treated with aeratedIAA solution has been investigated. Two major products, knownat first as ‘V’ and ‘P’ in these studieshave been isolated and ‘V’ has been identified as3-indolylacetylaspartic acid (IacAsp). The rapid uptake of IAA is inhibitited by metabolic poisonssuch as 10^–3 M. cyanide. The maximum mean internal concentrationexceeds the external concentration well–aerated cultures.The mean internal concentration, however only remains for aperiod and then falls off rapidly as a result of extrusion ofabsorbed IAA into the external solution. This extrusion is notinhibited by 10^-3 cyanide; when the mean internal IAA concentrationis 150 µ mol/ml. and the localized IAA concentration musttherefore exceed this value. We conclude therefore that theIAA concentration in the sites where it has accumulated exceedsthe concentration of IAA outside. Uptake of IAA and also its further conversion are inhibitedby indolylacetonitrile and promoted by aspartate, but this promotionis not associated with any gain in amount of indolylacetylaspartate(IacAsp). The data suggest that IacAsp may be formed in tissue from ‘boundIAA’ rather then free IAA. The ‘accelerator ’ found in potato and beans whichhas similar R_F to IAcAsp has been shown definity to be someother substance or substances and not IAcAsp as was at firstthought possible.     

Studies on CN--insensitive respiration in plant roots III. Induction of CN--insensitive respiration with low concentrations of respiratory inhibitors

Induction of CN^–-insensitive respiration with low concentrationsof respiratory inhibitors was studied. If roots were treatedwith 10^–3 M CN^– for 96 hr, the plants died, whilethose treated with 10^–4 M CN^– showed healthy growth. O₂ uptake in untreated rice and wheat roots showed a negativeresponse to 10^–2 M CN^– to a considerable extent.On the other hand, pretreatment with 10^–4 M CN^–for more than 6 hr did not greatly affect respiratory rate,but made respiration insensitive to 10^–2 M CN^–.A similar induction of CN^–-insensitivity was also broughtabout with 10^–4 and 10^–3 M H₂S and 10^–4 MNaN₃. (Received July 6, 1971; )     

Effects of Preillumination on Dark Nitrogen Fixation and Respiration by Anabaena Cylindrica

In whole filaments of Anabaena cylindrica dark nitrogen-fixingactivity (measured as acetylene reduction) and respiration increasedwith the light intensity of a fixed period of preillumination,saturating at ca. 10,000 lux. With saturating light during preillumination,the amount and duration of dark nitrogen-fixing activity increasedwith length of preillumination, but respiration declined rapidlyin the dark. At dark respiration rates below 250 nmol O₂ uptake mg protein^–1?h^–1(State 1) no significant nitrogen-fixing activity is observed.From 250 to 550 nmol O₂ uptake?mg protein^–1?h^–1(State 2), nitrogen-fixing activity depends on O₂ uptake whileabove 550 nmol O₂ uptake?mg protein^–1?h^–1 (State3), nitrogen-fixing activity no longer increases with furtherincrease in O₂ uptake rate. (Received June 18, 1983; Accepted November 10, 1983)     

Ion Transport to the Xylem in Aerenchymatous Roots of Zea mays L.

Aerenchyma was induced in the developing nodal (adventitious)roots of maize (Zea mays L. cv. LG11) in solution culture bytreatment with an atmosphere of 5% (v/v) oxygen (oxygen partialpressure 5.0 k Pa). Ion uptake by aerenchymatous and ordinary(non-aerenchymatous) roots was then compared to determine theeffect of degeneration of much of the cortex in aerenchymatousroots on radial ion movement to the xylem. Rates of uptake andtransport of phosphate, potassium and chloride were followedby labelling 4–12mm length segments of intact roots usingradioactive tracers. In some experiments, enhanced rates ofphosphate transport were induced by means of a divided rootsystem and nutrient deprivation. For all three nutrient ions,and over a range of concentration for phosphate (10–100mmol m^–3 and potassium (0·25–5·0 molm^–3 and with enhanced rates of transport, aerenchymatousroots were at least as effective as ordinary roots (per mm³of root) and sometimes more effective (per mm root length).These findings are discussed in relation to hypotheses concerningthe pathways for radial ion movement across the cortex in ordinaryand aerenchymatous roots. Correspondence to: Long Ashton Research Station, Long Ashton,Bristol BS18 9AF, U.K. Key words: Aerenchyma, ion transport, mineral nutrition, oxygen deficiency, radio-isotopic tracers, roots, structure, Zea mays     

Dinitrocresol, Cyanide, and the Pasteur Effect in Yeast

At pH 5·0 the respiration of yeast is stimulated by lowconcentrations of 3:5-dinitro-o-cresol, reaching a peak levelof 170 per cent, at 10⁵ M. Concentrations above this inhibitoxygen uptake and cause aerobic fermentation to appear, whichin turn reaches a peak value and is then inhibited. The rateof carbohydrate breakdown, or glycolysis, calculated from therates of respiration and aerobic fermentation, increases steadilyup to 3 x 10^–5 M., at which concentration it is 5 timesfaster than the control: higher concentrations depress the rateof glycolysis. The rate of fermentation under nitrogen is abouttwice that of respiration, and it is inhibited over the sameconcentration range as aerobic fermentation. It was found earlier that oxidative assimilation of glucoseby yeast is progressively inhibited by increasing concentrationsof dinitrocresol, and it is now shown that this parallels theincrease in the rate of aerobic glycolysis. It is argued thatdinitrocresol is here acting as an uncoupling agent and thatboth oxidative assimilation and the rate of glycolysis are controlledby the level of energy-rich phosphate. With cyanide there is no stimulation of oxygen uptake, aerobicfermentation only appears when respiration becomes inhibited,and after an initial slight decrease the rate of glycolysisrises to 575 per cent. of the control value at 5 x 10^–4M. It is suggested that the rate of glycolysis only increaseswhen respiration has been inhibited sufficiently to reduce therate of formation of energy-rich phosphate.     

Effect of NaCI Salinity on Flows and Partitioning of C, N, and Mineral Ions in Whole Plants of White Lupin, Lupinus albusL.

Plants of Lupinus albus L., cv. Ultra, were grown hydroponicallywith NO₃^–-nutrition for 51 d under control (0.05 mol m^–3Na⁺ and 10 mol m^–3 Cl^–) and saline (40 mol m^–3NaCI) conditions. Plants were harvested 41 and 51 d after germinationand analysed for content and net increment of C, N and the mineralcations K⁺, Na⁺, Mg²⁺, and Ca²⁺ and the anions Cl^–, NOJ,malate, phosphate, and SO₄^2–. Roots, stem interaodes,petioles and leaflets were analysed separately. During the studyperiod net photosynthesis, respiratory losses of CO₂ from shootand root and the composition of the spontaneously bleeding phloemsap and the root pressure xylem exudate were also determined.Using molar ratios of C over N in the transport fluids, incrementsof C and N, and photosynthetic gains as well as respiratorylosses of C, the net flows of C and N in the xylem and phloemwere then calculated as in earlier studies (Pate, Layzell andMcNeill, 1979a). Knowing the carbon flows, the ratios of ionto carbon in the phloem sap, and ion increments in individualorgans, net flows of K⁺, Na⁺, and Cl^– over the study periodwere also calculated. Salt stress led to a general decrease of all partial componentsof C and N partitioning indicating that inhibitions were notdue to specific effects of NaCI salinity on photosynthesis oron NO₃ uptake. However, there were differences between variouslyaged organs, and net phloem export of nitrogenous compoundsfrom ageing leaves was substantially enhanced under saline conditions.In addition, NO₃^–reduction in the roots was specificallyinhibited. Uptake and xylem transport of K⁺ was more severelyinhibited than photosynthetic carbon gain or NO₃^– uptakeby the root. K⁺ transport in the phloem was even more severelyrestricted under saline conditions. Na⁺ and Cl^– flowsand uptake, on the other hand, were substantially increasedin the presence of salt and, in particular, there were thenmassive flows of Na^– in the phloem. The results are discussedin relation to the causes of salt sensitivity of Lupinus albus.The data suggest that both a restriction of K⁺ supply and astrongly increased phloem translocation of Na⁺ contribute tothe adverse effects of salt in this species. Restriction ofK⁺ supply occurs by diminished K⁺ uptake and even more by reducedK⁺ cycling within the plant. Key words: Lupinus albus, salt stress, phloem transport, xylem transport, partitioning, carbon, nitrogen, K⁺, Na⁺, CI^–     

Effects of NO2 and O3 Alone or in Combination on Kidney Bean Plants (Phaseolus vulgaris L.): Growth, Partitioning of Assimilates and Root Activities

Ten-day old kidney bean plants (Phaseolus vulgaris L. cv. Shin-edogawa)were exposed to 2.0 and 4–0 parts 10^–6 NO2, and0.1, 0.2, and 0.4 parts 10^–6 O3 alone or in combinationfor 2, 4, and 7 d. The effects of these air pollutants wereexamined with respect to the growth, partitioning of assimilates,nitrogen uptake, soluble sugar content, and root respiration. Decreased dry matter production was significant with all treatmentsexcept 2.0 parts 10^–6 NO₂ and 0.1 parts 10^–6 O₃.Exposure to mixtures of the gases produced more severe suppressionof growth than exposure to the single gases. Root/shoot ratiowas significantly lowered at 7 d by the gas treatments otherthan 2.0 parts 10^–6 NO₂ and 0.1 parts 10^–6 O₃. Thetotal nitrogen content of plants was increased by all treatments;the higher percent of nitrogen found with O₃ exposure will resultfrom the growth retardation which increases the concentrationof nitrogen in the plants because the absorption of nitrogenby roots was unaffected. The combination of O₃ with NO₂ significantlydecreased the assimilation of NO₂ by the plants. The concentration of soluble sugars in roots was decreased bythe gas treatments. There was a strong positive correlationbetween soluble sugar content and dry weight of the roots harvestedat 7 d. Root respiration was relatively unchanged until 5 dand then decreased significantly at 7 d by 2.0 parts 10^–6NO₂ and 0–2 parts 10^–6 O₃. Retarded growth of theroots and the decreased root respiration may be due to diminishedtranslocation of sugars from leaves to roots caused by exposureto air pollutants. The uptake of soil nitrogen was not closelyrelated with root respiration in the case of O₃ exposure. Key words: NO₂, O₃, Phaseolus vulgaris, Growth, Sugars, Root respiration     

Response of Wheat Seedlings to Low O2 Concentrations in Nutrient Solution: I. GROWTH, O2 UPTAKE AND SYNTHESIS OF FERMENTATIVE END-PRODUCTS BY ROOT SEGMENTS

Root growth of 7-d-old wheat (Triticum aestivum cv. Gamenya)seedlings was impaired at dissolved O₂ concentrations of 0.01and 0.055 mol m^–3 O₂, while growth at 0.115 mol m^–3O₂ was the same as that in continuously aerated controls (0.26mol m^–3 O2). Oxygen uptake by apical (0–2 mm), expanding (2–4mm) and expanded (10–12 mm) tissues of the roots decreasedbelow 0.16, 0.09 and 0.05 mol m^–3 O₂, respectively. Thishierarchy is consistent with the metabolic rates of these tissues.There was a small (c. 9%) inhibition of O₂ uptake and some netsynthesis of ethanol and alanine in root apices at 0.115 molm^–3 O₂. Significant amounts of anaerobic end-productsaccumulated at 0.055 mol m^–3 O₂ and even more so at 0.01mol m^–3 O₂, indicating that oxidative phosphorylationwas strongly inhibited. Net alanine synthesis increased in fully expanded (10–16mm) tissues exposed to <0.003–0.01 mol m^–3 O₂,and this increase was accompanied either by a proportionallysmaller increase in the concentration of other free amino acidsor by a net decrease in free amino acid levels excluding alanine.This suggests that alanine was synthesized as an end-productof anaerobic catabolism and did not accumulate simply becauseof decreased net protein synthesis. Comparing the carbon flow to CO₂, ethanol, lactate and alaninein roots at 0.01 mol m^–3 O₂ with carbon loss as CO₂ inaerated roots suggests that carbon flow to products of metabolismwas not greatly enhanced due to O₂ deficiency. This infers,but does not prove that, in wheat, generation of energy duringperiods of O₂ deficiency is not enhanced due to a Pasteur effect. Key words: Anaerobic, fermentation, oxygen, wheat     

The Carbon Economy of Rubus chamaemorus L. II. Respiration

Respiratory activity and seasonal changes in carbohydrate contentof the storage organs of Rubus chamaemorus L. have been investigated.Leaf dark respiration rate increases in a non-linear mannerfrom 0·7 mg CO₂ evolved dm^–2 h^–1 at 0 °Cto 4·6 rng CO₂ evolved dm^–2 hh^–1 at 30 °C.Root and rhizome respiration rates increase from 1 µ1O₂ uptake g^–1 fresh weight h^–1 at 0.7 ° C to10 µ10, uptake g^–1 f. wt h^–1 at 20 °C.Rhizome carbohydrate reserves decline from a September peakof 33 per cent alcohol insoluble d. wt to 16 per cent in May. The circumpolar distribution of R. chamaemorus is discussedin relation to the evidence presented here and in the precedingpaper of the series.     

Algal 14C and total carbon metabolisms. 1. Models to account for the physiological processes of respiration and recycling

A consistent set of equations has been written to describe thenet rate of algal ¹⁴CO₂ uptake (and where appropriate respirationand photosynthesis) which take into account separately complicationsdue to respiration of the labelled photosynthetic products andthe recycling of respiratory CO₂. Written specifically intothe equations is the concept of ‘new’ and ‘old’carbon, the coefficient q is used in the respiration model toallow for the differential respiration of organic material fromthe ‘new’ and ‘old’ carbon pools. Analyticalintegrals have been found for respiration and recycling models,and the behaviour of the models studied over periods of 12 h(i.e. up to 70% of the intrinsic generation time). The rateconstant for respiration has a greater effect on the behaviourof the recycling than the respiration model. Over short timecourses (up to 30% of the intrinsic generation time), the effectsof respiration and recycling on net ¹⁴CO₂ uptake are quite distinct,especially at high P/R ratios, and not complicated by assumptionsover the value of q. Although the value of q will have a time-dependentsecondary effect on the modelled total carbon-specific respirationrate, this was found not to give rise to major problems of interpretation.Beyond 50% of the intrinsic generation time, the separate treatmentof respiration and recycling in the models becomes less satisfactory.It was concluded that the present equations, which are not constrainedby mass balance considerations, would not be appropriate fora model that combines the two processes. The pattern of recyclingat low P/R values is identified as one of the major uncertaintiesin producing models of ¹⁴C uptake. The effect of the releaseof dissolved organic material can be anticipated in a generalway. The models have been used to define an experimental strategyto establish the separate effects of respiration and recyclingon the time course of net ¹⁴C uptake. The initial rates givethe clearest resolution of the two processes and it would appearthat with photosynthetic rates in the region of 1 day^–1,incubation periods up to 3–6 h would be suitable to determinethe importance of recycling in controlling net ¹⁴C uptake. Withthe present models, only in the absence of recycling could theeffect of respiration be studied and the value of q established.     

Respiration and Phloem Translocation in the Roots of Chickpea (Cicer arietinum)

Root growth in chickpea (Cicer arietinum) has been studied fromthe early vegetative phase to the reproductive stage in orderto elucidate its growth and maintenance respiration and to quantifythe translocation of assimilates from shoot to root. A carbonbalance has been drawn for this purpose using the growth andrespiration data. The increase in the sieve tube cross-sectionalarea was also followed simultaneously. Plants growing in a nutrient culture medium were studied todetermine the relative growth rate (RGR) 5–60 d aftergermination. RGR declined from 113 to 41 mg d^–1 g^–1during the measurement period. Simultaneous with the RGR analysis,respiration rate was also measured using an oxygen electrode.The respiration rate declined as the plants aged and a drasticreduction was recorded following anthesis. The relationshipbetween RGR and respiration rate was used to extrapolate themaintenance respiration (m) and growth respiration (1/Y_EG).The respiration quotient (r.q.) of the roots was 1.2 and theQ₁₀ in the range 20–25 °C was 2·2. A carbon balance for the roots was constructed by subtractingthe carbon lost during respiration from that gained during growth.The roots were found to respire no less than 80% of the carbontranslocated. The increase in the cross-sectional area composed of sieve tubeswas measured near the root-shoot junction as the plants grew.Chickpea has storied sieve plates which simplifies these measurements.Their cross-sectional area increased during growth mainly becauseof an increase in sieve tube number. The diameter of individualsieve tubes remained constant. Specific mass transfer (SMT) values for seive tubes into theroots have been computed during various stages of growth. SMTvalues were relatively constant before anthesis (approx. 6·5g h^–1 cm^–2), but decreased following anthesis. Wedid not evaluate possible retranslocation from roots: any suchretranslocation would have the effect of increasing our SMTvalues. Chickpea, Cicer arietinum, legume, root, respiration, phloem, translocation, carbon balance, specific mass transfer, sieve-tube dimensions     

Root Aeration and Respiration in Young Mangrove Plants (Avicennia marina (Forsk.) Vierh.)

The roots of young plants of Avicennia marina (Forsk.) Vierh.grown under simulated tidal conditions were harvested so asto obtain the entire root system. The roots were subdividedand weighed and subsamples taken for manometric determinationof respiration rates at different temperatures. The supply capacityof the above-ground portion of the root system was determinedand the results compared in terms of supply and demand. Theoxygen consumption rate of the roots at 15°C was found tobe 1·69±0·07 µmol kg^–1 s^–1for cable roots and 3·27±0·12 µmolkg^–1 s^–1 for fine roots. The Q₁₀ for respirationwas 2·55 for oxygen consumption in both fine and cableroots, and for carbon dioxide production was 2·66 forfine roots and 3·04 for cable roots. The respiratoryquotient varied with temperature but was less than unity. Concentrationdifferences of between 1·8 mol m^–3 and 3·4mol m^–3 between the inside of root and the air were sufficientto permit aeration of the root system by diffusion alone, andthe aerenchyma contained sufficient oxygen to maintain aerobicconditions while the roots were covered with water. The effectof tide and seasonal temperature change on gas exchange, togetherwith the possibility of some form of carbon dioxide fixationwithin the root, are examined and the implications of theseeffects on growth and development are discussed. Key words: Mangrove, root aeration, respiration, aerenchyma     

The Permeability to Oxygen of the Periderm of the Potato Tuber

The permeability to oxygen of the periderm of the potato tuberhas been measured during its development and storage. When expressedas ml O₂, diffusing through 1 cm² periderm in 1 sec under anO₂, pressure of 1 atm, the values for freshly harvested tubersranged from a maximum of 2.4 x 10^–4 in immature tubers,to less than 0.7 x 10^–4 in tubers harvested mature someweeks after the death of the foliage. In every case, after storagefor up to 10 weeks at 10^° C, the permeabilities, as expressedabove, were less than 0.7 x 10^–4 (minimum values, c. 0.5x 10^–4 It was shown that the oxygen deficit under theperiderm was unlikely to exceed 0.03 atm during development,and the oxygen status of the developing tuber should thus beadequate for the low oxygen-affinity oxidase system (if present)to function.     

Respiratory Mechanisms in the Aroid Spadix

The flowers of Skunk-cabbage (Symplocarpus foetidus), like thespadix tissues of other Aroids, have a rapid, carbon monoxideand cyanide (HCN) resistant respiration; oxygen uptake is independentof the oxygen partial pressure over a wide range. Cell fractionswere isolated by differential centrifugation and their oxidativeactivities studied. Oxidation of succinate and citrate by mitochondriacan be inhibited 50 to 60 per cent. by 1 X 10^–3 M. HCN,and antimycin A (AA) causes partial inhibitions. An active mitochondrialcytochrome-c oxidase is present, and it shows a typical sensitivityto cyanide. The mitochondria possess an active reduced diphosphopyridine-nucleotide(DPNH) oxidase system, which is inhibited roughly 80 per cent.by 1 X 10^–3 M. HCN and 1.7 µg./ml. AA. The microsomalDPNH oxidase, which is less sensitive to inhibitors, is lessactive per gramme of tissue than that on the mitochondria. Thefinal supernatant shows little DPNH oxidase. With all fractions,reduced triphosphopyridine nucleotide (TPNH) is oxidized muchmore slowly than DPNH. DPNH-cyto-chrome-c reductase activitywas measured; the mitochondrial system is partially blockedby AA, whereas the microsomal activity is AA-insensitive. Spectro-photometricexamination of a preparation of solubilized mitochondria showedthat cytochromes a, b, and c are present. The results are discussedwith reference to the pathway and localization of hydrogen andelectron transport in the Aroid spadix.     

Remarkable retardation of the senecence of tobacco leaf disks by cordycepin, an inhibitor of RNA polyadenylation

The antibiotic cordycepin (3'-deoxyadenosine), a known specificinhibitor of nucleic acid synthesis and polyadenylation of RNA,remarkably retarded decrease in the chlorophyll and proteincontents of senescing tobacco leaf disks. The effectivenessof cordycepin, at its optimum concentration (ca. 4 x 10^–5M), was 53% as effective as a cytokinin, benzyladenine at 10^–6M. Adenosine and 2'-deoxyadenosine had no anti-senescence action. (Received May 29, 1975; )     

Effect of some Flavonoids and Phenolic Acids on Seed Germination and Rooting

Nandakumar, L. and Rangaswamy, N. S. 1985. Effect of some flavonoidsand phenolic acids on seed germination and rooting.Mdash;J.cxp. Bot. 36: 1313–1319. Effects of isovitexin (isolated from leaves of Rhynchosia minima),leucocyanidin, gallic acid, and protocatechuic acid on seedgermination and subsequent seedling growth of a crucifer Brassicacampestris, and two legumes Lens esculenta and R. minima, aswell as effects of isovitexin on rooting of onion bulbs aredescribed. Neither of the flavonoids affected seed germinationin any of the three systems studied. However, both the flavonoidspromoted seedling growth in B. campestris and L. esculenta;the promotion of root growth was more marked. At 10^–5and 10^–7M, isovitexin also promoted rooting of onion bulbs.In the range of 2.27 ? 10^–4M to 3.28 ? 10^–3M, leucocyanidinpromoted growth of both root and shoot in L. esculenta, whereasin the range 3.28 ? 10^–3M to l.64?lO^–3M it suppressedseedling growth. In contrast to the flavonoids, the two phenolicacids tested inhibited seed germination at 10^–3M, andat lower concentrations they suppressed seedling growth. The promotive effects of the flavonoids isovitexin and leucocyanidin,especially on root growth, hold promise for the use of suchnaturally occurring plant substances in studies on the physiologyof plant growth and development. Key words: Flavonoids, phenolic acids, seed germination, rooting     

Carbon Dioxide Exchange of Developing Apple (Malus pumila Mill.) Fruits

The carbon dioxide exchange of developing apple fruits was monitoredduring development. The results of measurements on detachedfruits in the laboratory were consistent with those made onattached fruit in the field. Respiration rate at 20 °C inthe dark declined from 120 ng CO₂ g^–1 fr. wt. s_–1on 5 June (4 weeks after full bloom) to less than 3 ng g^–1fr. wt. s^–1 by late September. In the light, net CO₂ evolutionwas much decreased, but on no occasion did photosynthesis exceedrespiration and no net CO₂ uptake was detected. The Q₁₀ fordark respiration over the interval from 15 to 25 °C changedfrom 2.8 in early June to 1.6 in early August     

A study on senescence in tobacco leaf disks I. Inhibition by benzylaminopurine of decrease in protein level

The drop in protein level as an index of senescence in tobaccoleaf disks was examined in the dark in the presence of BA and/orinhibitors of protein synthesis. Cycloheximide at 10^–6–10^–5M and 10^–5 g/ml actinomycin-D accelerated the senescenceand interfered with the anti-senescence action of 10^–6M BA. Chloramphenicol (10^–8– 10^–4 M) and puromycin(10^–8–10^–4M) did not modify the senescenceor the action of BA. Cycloheximide was more effective at earlierstages of the dark culture of the disks. The rate of ¹⁴C-leucineincorporation into the protein fraction was increased by BAand decreased with senescence, and this drop was removed byBA. The incorporation was also suppressed by cycloheximide equallyin the presence and absence of BA. The drop in labeled proteinof the disks during the chasing period was retarded by not onlyBA but cycloheximide also. The conclusion reached, based onthese and relevant findings, was that BA affects the anti-senescenceaction by promoting synthesis and at the same time inhibitingdegradation of protein. (Received December 2, 1974; )