Studies in the Physiological Action of 2,2-Dichloropropionic Acid: II. THE EFFECTS OF LIGHT AND TEMPERATURE ON THE FACTORS RESPONSIBLE FOR THE INHIBITION OF GROWTH

When Lemna minor and Salvinia natans, grown in a constant environment,are subjected to sub-lethal concentrations of 2,2-dichioropropionicacid (DCPA), the relative growth-rates are progressively reduced.These cumulative reductions, which are greater for S. natans,are correlated with decreases in (1) the rate of leaf or frondformation, (2) the mean area per leaf or frond, and (3) thenet assimilation rate. Of these components, the first is themost important and the third is the least. The effects of light intensity (300, 600, 900 f.c.), temperature(20, 25, and 30°C), and concentration of DCPA on both therelative growth-rate and rate of leaf or frond multiplicationhave been examined in multi-factorial experiments. Over theconcentration range selected (100, 200, and 400 mg/l for S.natans and 100, 300, and 6oo mg/l for L. minor) there are positiveeffects of light intensity, temperature, and concentration.For each concentration the order of the depression is maximalunder a combination of the highest temperature and the greatestintensity. Using radioactive DCPA it has been established that uptake isalso a cumulative process, and that S. natans has a greatercapacity to absorb DCPA. The rate of uptake is independent ofthe light intensity but increases with temperature and concentration. DCPA brings about morphological and structural changes. In S.natans, many of the leaves become submerged and the proportionis positively dependent on light, temperature, and concentration.This failure to float is associated with a reduction in thedensity of epiderrnal hairs. It is concluded that the inhibitory effects of DCPA are maximalunder conditions which are optimal for both meristematic activityand accumulation.     

The Effect of Light Intensity, Day Length, and Temperature on Fatty Acid Synthesis and Desaturation in Vicia faba L.

Some effects of light intensity, day length, and temperatureon the fatty acid composition of the major glycerolipids ofleaves of Vicia faba L. (cv. Giant Windsor) were observed. Increasinglight intensity caused an increase in the relative concentrationsof 16 : 1 in PG and 18 : 3 in MGDG and DGDG. Increasing daylength during growth (and continuous illumination of leaf tissue)had no effect on 16 : 1 in PG but caused a decrease in the 18: 3 content of PG, PC, MGDG, and DGDG. Since the quantitiesof these lipids increased under these conditions, the decreasewas not due to photodestruction but to the differences in therelative rates of biosynthesis and desaturation of fatty acids.Incubation of leaf tissue in the dark for 4 d had little effecton the fatty acid composition of MGDG, DGDG, and PG. Temperaturealso controls fatty acid synthesis and desaturation. Above theoptimum growth temperature (20 °C), the 18 : 3 content ofMGDG, DGDG, PG, and PC decreased. In mature leaf tissue, thedegree of unsaturation of MGDG may be modified upward in responseto temperature changes. When plants were grown at 30 °Cand transferred to 20 °C the level of 18 : 3 in MGDG ofthe leaf tissue increased to levels found in plants grown onlyat 20 °C. The level of 18 : 3 in MGDG does not decreaseas rapidly when plants grown at 20 °C were transferred to30 °C. This suggests that the lower temperature induceddesaturation of 18 : 2 to 18 : 3.     

Interactions in the Physiological Effects of Growth Substances on Plant Development

The interrelated effects of 3-indolylacetic acid and sodium2 : 4-dichlorophenoxyacetate on the growth and development ofLemna minor and Helianthus annuus have been investigated bymeans of multifactorial experiments, involving three to fivelevels of each compound. A clonal population of L. minor wasmaintained under constant conditions of light (550 foot-candles)and temperature (25 C.) and the growth regulators were addedto a phosphate-buffered culture solution (pH 51), which waschanged every 2 days. In the H. annuus experiments the compounds,in aqueous solution, were placed by means of a micro-pipetteon the leaves of young plants grown in a greenhouse or in theopen. Indolylacetic acid, at concentrations up to 25 p.p.m., increasesthe relative growth rate of L. minor on either a dry-weightor frond-area basis. Sodium dichlorophenoxyacetate at 0025p.p.m. has little effect on growth, but at and above concentrationsof 02 p.p.m. growth is depressed. The ratio of frond area tototal dry weight is increased by indolylacetic acid but is depressedby the phenoxyacetate. In the presence of indolylacetic acid,more particularly at the higher levels, the relative inhibitionof growth caused by sodium dichlorophenoxyacetate is reduced. When sunflowers are treated daily with indolylacetic acid (0,6, 30, 150 µg./ plant) or initially with sodium dichlorophenoxyacetate(0, 20, 100 µ.g./plant) in all possible combinations,then the relative growth rates of the treated leaves, the leavesabove the treated leaves, the first internode, and the rootsare depressed when each compound is applied alone. On the otherhand, the growth rate of the hypocotyl is increased by bothgrowth regulators, while for the second internode indolylaceticacid decreases the growth rate but the phenoxyacetate at thelower level accelerates it. The combined action of the two compoundson the different parts tends to be cumulative, save for thehypocotyl, where the effect of indolylacetic acid is dependenton the level of the phenoxyacetate. It is concluded that these results cannot be explained on theconcept of wholly additive effects. There is evidence that thecompounds can mutually interfere in their actions and it wouldseem that more than one mechanism is involved. Many of the resultscan be satisfactorily interpreted on the basis that the twocompounds act on a common system and that they compete withone another, but the results are not compatible with the postulatethat the dichlorophenoxyacetic acid directly inactivates indolylaceticacid.     

Interactions between temperature and light intensity on growth and photosynthesis of the cyanobacterium Oscillatoria agardhii

Oscillatoria agardhii was grown in turbidostat cultures undera 16/8 h light/dark cycle at various combinations of light intensityand temperature. Temperature was found to influence only themaximal growth rate; this relationship was linear over the temperaturerange studied. An equation was derived describing the growthrate (µ) as a continuous function of light intensity andtemperature. The light harvesting pigments chlorophyll a andC-phycocyanin increased in concentration when growth becamelight limited. The regulation patterns observed did not suggestany influence of temperature on their steady state concentrations.The initial slope of the P versus I curves (     

Some Effects of Light Intensity, Daylength and Temperature on Growth of Fruiting and Non-fruiting Watermelon (Citrullus lanatus)

Plants of watermelon [Citrullus lanatus(Thunb.) Matsum. &Nakai, cv. Early Yates] were grown for up to 3 months aftergermination in controlled environment cabinets, and variousaspects of vegetative growth and fruit development were measured.Effects of light intensity were studied by comparing growthat 8, 16 and 32 klx at constant temperature and daylength (25^°C, 14 h). Effects of daylength were studied by comparing8, 14 and 24 h at constant light intensity and temperature (32klx, 25 ^°C), and effects of tem perature were studied bycomparing 20^°, 25^°, 30^°, 35^° and 40 ^°C atconstant light intensity and day- length (32 klx, 14 h). Withincreasing light intensity and daylength lateral growth waspromoted whereas main shoots were less affected. Increase intemperature above 25 ^°C resulted in longer main shoots andprolific lateral growth, due both to more and to longer laterals.Environmental differences had little effect on internode lengthbut did affect the size of basal leaves. However, an increasein total leaf area at higher temperatures or with Continuouslight was mainly due to more leaves rather than larger leaves.The presence of developing fruit greatly reduced vegetativegrowth of plants. Main shoot length, lateral growth, numberof leaves, and even size of individual leaves, were all reduced.This reduction did not apply to d. wt of whole plants. Fruitingplants were very efficient, on a leaf area basis, in accumulatingd. wt. At 25 ^°C at the two higher light intensities with14 h days the presence of one developing fruit was inhibitoryto the setting of any subsequent fruit. With short days or lowlight, more fruits were set but they were small. With continuouslight or high temperature more than one fruit could developand they were large.     

Growth, metabolism and growth efficiency of a euphausiid crustacean Euphausia pacifica in the southern Japan Sea, as influenced by temperature

Growth (assessed from intermolt period and molt increment) andmetabolism (oxygen consumption) of the post-larva of Euphausiapacifica from the southern Japan Sea were determined at sevengraded temperatures ranging from 1 to 25°C. The intermoltperiod shortened progressively as temperature increased from1 to 20°C, but an effect of temperature on molt-to-moltgrowth increment was not seen. Oxygen consumption rates wereaccelerated by the increase in temperature up to 20°C. Beyond20°C, E.pacifica exhibited reduced oxygen consumption anddied within 1 day without molting. After removing the effectof body size, the relationships between growth rate and temperature,and between oxygen consumption rate and temperature, were established.The carbon budget was calculated as a function of temperature.Because of differential effects of temperature on growth andmetabolism, the net growth efficiency [K₂ growthx100/(growth+metabolism)]changed with temperature. The optimum temperature at which E.pacificaattained the maximum K₂ was 11.4°C, which was derived fromcalculation of cumulative carbon invested in growth and metabolismin this animal. In an alternative method, the optimum temperaturewas obtained mathematically by solving a set of differentialequations. The biological and ecological significance of theoptimum temperature which leads to the maximum K₂ is discussed.     

The Effects of Temperature and Light Intensity on Embryo Numbers in Wheat Doubled Haploid Production through WheatxMaize Crosses

Triticum aestivumxZea mayscrosses are now widely used in theproduction of wheat doubled haploids to produce homozygous lines.Seasonal effects are known to influence the number of haploidembryos produced through wheatxmaize crosses, but the effectsof temperature and light have not been quantified. This studyinvestigated the effect of temperature and light intensity onhaploid embryo production. New Zealand wheat cultivars weregrown in a glasshouse until booting when they were transferredto growth cabinets at three temperatures (day/night; 17/12,22/17 or 27/22 °C at an irradiance of 250 µmol m^-2s^-1PAR).In another experiment, wheat lines were transferred to a growthcabinet at one of three light intensities (300, 500 or 1000µmol m^-2s^-1PAR at 22/17 °C day/night, with a photoperiodof 16 h). The temperature and light intensity at which pollinationswere made and subsequent fertilisation and embryo developmentoccurred, significantly (P<0.01) influenced the frequencyof haploid embryo production. The optimal temperature for embryorecovery was 22/17 °C. The greatest number of embryos wasproduced at a light intensity of 1000 µmol m^-2s^-1. Thesefindings will result in improvements in the overall efficiencyof the wheatxmaize system for wheat doubled haploid production.Copyright1998 Annals of Botany Company Intergeneric crossing, temperature, light intensity,Triticum aestivum,wheat,Zea mays,maize.     

Differences in the Interacting Effects of Light and Temperature on Growth of Four Species in the Vegetative Phase

A comparative study, employing the concepts of growth analysis,has been made of the varying responses in the early vegetativephase of Gossypium hirsutum, Helianthus annuus, Phaseolus vulgaris,and Zea mays to combinations of light intensity (1.08, 2.16,3.24, 4.32, and 5.4 x 10⁴ lx—photoperiod 14 h) and constantdiurnal air temperatures (10, 15, 20, 25, 30, and 35 °C).Depending on the combination of treatments, the temperatureof the internal tissues departed from air temperature by 6.9to 1.4 °C: so only the internal temperatures are cited here. For each species there are complex interactions between theeffects of light and temperature on the net assimilation rate,the leaf-area ratio, and the relative growth-rates of plantweight and leaf area. The magnitude of the changes induced bythe two factors vary both with the growth component and thespecies. The temperature responses are maximal up to 20–5°C while at the highest temperatures they may be negative.The temperature coefficients for leaf-area ratio are consistentlyless than those of the other three components: here betweenspecies the coefficients over 10–20 °C vary by a factorof 9.6, 5.4, and 5.1 for the rates of gain in plant weight andleaf area and the net assimilation rate, while the orderingwithin each growth component is species dependent. Under conditions of optimal temperature the relative growth-rateand net assimilation rate progressively increase, accordingto the species, up to either 4.32 or 5.4x 10⁴ lx. The leaf-arearatio is always largest at the lowest intensity. The level oflight at which the rate of gain in leaf area reaches a maximumranges from 2.16x 10⁴ lx for Phaseolus to between 4.32 and 5.40x10⁴ lx for Gossypium. The highest relative growth-rate and net assimilation rate ofHelianthus exceed those of Zea substantially. Indeed the maximalassimilation rate for Helianthus of 2.10 g dm^–2 week^–1is the highest ever recorded under field or controlled conditions.Possible reasons for this reversal of the photosynthetic potentialsof the two species observed by previous workers are discussed.     

Development, growth and egg production of Centropages abdominalis in the eastern subarctic Pacific

Centropages abdominalis is a neritic, omnivorous, temporallyabundant copepod present throughout the subarctic Pacific andits marginal seas. The two main objectives of this study wereto determine how temperature influences the development of C.abdominalis and whether growth rates of in situ populationsmay be limited by available food. At 6.9°C, median developmenttime from eggs laid to 50% adults was 42 days and the averageweight-specific somatic growth rate was 0.17 day^–1. At4.6°C, median development time to adult was 59 days (projected)and growth rate averaged 0.08 day^–1, suggesting that 4.6°Cmay be approaching the lower temperature for development andgrowth in this species. The functional relationship betweendevelopment time and temperature was established over the temperaturerange in which this species occurs. The in situ adult growthrates between 10 and 13°C averaged 0.14 day^–1 andwere generally lower than the laboratory-reared juvenile growthrates, which may indicate that adult C. abdominalis are foodlimited in the field during summer and autumn.     

Some Effects of Light Intensity, Daylength and Temperature on Flowering and Pollen Tube Growth in the Watermelon (Citrullus lanatus)

The effects of light and temperature on flowering and pollentube growth were studied in watermelon [Citrullus lanatus(Thunb.)Matsum. and Nakai, cv. Early Yates] plants grown in controlledenvironment cabinets. All female flowers were pollinated inone group of plants; none was pollinated in the other group. Temperature increase from 25 ^°C to 35 ^°C with daylengthof 14 h and light intensity of 32 klx caused increase in flowernumber per plant, proportion of male flowers, ovary length anddiameter, ovule number per ovary, rate of pollen tube growthand percentage of penetrated ovules at 24 hand 48 h after pollination.Very few flowers were produced at 40 ^°C, but there was ahigh proportion of male flowers. Increase in daylength from14 h to 24 h at 25 ^°C with light intensity of 32 klx alsoincreased number of flowers per plant, ovary length and diameterand number of ovules per ovary but sex expression and rate ofpollen tube growth were unaffected. Reduction in daylength from14 h to 8 hat 25 °C and light intensity of 32 klx and reductionin light intensity from 32 klx to 8 klx at 25 ^°C and 14h daylength both produced an increase in the percentage of immatureovules. The presence of fruit on the vine resulted in fewerflowers per plant and in reduced ovary legnth and diameter underall conditions tested. The results are discussed in relation to the fruiting responseof the plant.     

Effects of Temperature on the Growth and Development of Lemna minor, under Conditions of Natural Daylight

The effects of temperature on the growth and development ofLemna minor in the open have been studied in the east of Scotlandby means of four water baths constructed to maintain constantwater temperatures of 12.5, 17.5, 22.5, and 27.5 °C whensubjected to natural insolation. Experiments were conductedat weekly intervals between August and November in 1958 andMay and July in 1959. At the beginning of every experiment,for all temperature treatments, 134 fronds were placed in eachof six containers. From the initial and final samples, the weightsof roots and fronds together with frond (leaf) area were measured,so that weekly values for net assimilation rate, leaf-area ratio,and relative growth-rate could be calculated. Daily solar radiationwas recorded by means of bimetallic radiation recorder. In 1958 linear regressions of a satisfactory fit were obtainedwhen the data for net assimilation rate, leaf-area ratio, andrelative growth-rate were calculated on the logarithms of theradiation for each temperature. Since radiation remained relativelyconstant in 1959 it was not possible to evaluate very reliablythe effects of radiation on the growth parameters but only occasionally,notably for the final leaf-area ratio (12.5 °C) were thelines for 1958 and 1959 significantly different. Single lineswere fitted to the points for both years. In all the regressions,apart from that for final leaf-area ratio (12.5°C) the proportionof the variation accounted for ranged from 87 to 97 per cent. The results showed that the net assimilation rate was positivelylinked with radiation and was optimal at 17.5 °C, thoughthe rise from 12.5 to 17.5 °C was not significant. At thehigher temperatures (22.5 and 27.5 °C) there was a significantnegative effect of temperature on the net assimilation rate.The leaf-area ratio and relative growth-rate were positivelydependent on radiation and reached the highest values at thehighest temperatures. The maximum growth-rate recorded amountedto no less than 0.39 g.g^–1 day^–1. The results are discussed in relation to those for other aquaticand terrestrial plants.     

Bl?tenbildung bei Lemna paucicostata 6746 durch kombinierte Anwendung von Abscisins?ure und GCG

To a certain extent the flowering of Lemna paucicostata 6746is evoked in continuous light by application of abscisic acid(ABA) and CCC. Moreover, the action of the combined substancesappears in two separate concentration ranges. In the range ofABA 2?10^–9 M/CCC 10^–7–10^–6 M floweringis initiated without inhibition of vegetative growth and proceedsonly in the presence of high intensity light and sucrose. Acombination of ABA 2?10^–5 M/CCC 10^–3M simultaneouslycauses a strong inhibition of frond multiplication. Here theeffect can be observed also under low intensity light conditionsand without sucrose in the medium. A range with flower inhibitingactivity lies between the two flower promoting concentrationranges. (Received November 16, 1972; )     

Interrelationships between the Nature of the Light Source, Ambient Air Temperature, and the Vegetative Growth of Different Species within Growth Cabinets

The interacting effects within growth cabinets of the natureof the light source and the temperature of the ambient air on14 parameters of vegetative growth have been examined for Gotsypiumhirsutum, Helianthus annuus, Phaseolus vulgaris, and Zea mays.The comparisons were between fluorescent lighting and mixtureswith tungsten lamps (17 and 26 per cent of the total wattage),adjusted to give 32 400 lx and covering six equally spaced andconstant air temperatures from 10 to 35 °C. The relationships are highly complex. Species differ in theirresponses to the three light sources. Moreover, for some parameters,but only for some species, there are highly significant interactionsbetween the nature of the light source and the temperature level.Part of this complexity is due to the varying growth potentialof species at low and high temperatures but important contributingfactors are the differences between the temperatures of theambient air and the plant parts. Such disparities may be positiveor negative and are greater for leaf as against root temperature.The divergencies are larger during the day and largest for leaftemperature. With the higher proportion of tungsten lamps theleaf day temperature ranges from 7.1 °C above an ambienttemperature of 10 °C to 2.5 °C above 35 °C ambient.For fluorescent lighting the leaves are 2.8 °C above ambientat 10 °C and 2.5 °C below at 35 °C. When variations in the response are examined against the meaninternal day temperature of the plant, for some parameters,but not others, differences between light sources are no longerevident. Here again the reactions of species differ. It is concluded firstly that if only ambient air temperaturesare recorded errors will arise in the interpretation of theinduced biological responses, and secondly that departures fromthe ambient air temperatures will be dependent on the designof the cabinet and the lighting system.     

Effects of temperature and salinity on the growth of the red tide flagellates Heterocapsa circularisquama (Dinophyceae) and Chattonella verruculosa (Raphidophyceae)

Growth responses of the red tide flagellates, Heterocapsa circularisquama(Dinophyceae) and Chattonella verruculosa (Raphidophyceae),were examined with 36 different combinations of temperature(5–30°C) and salinity (10–35 PSU). Heterocapsacircularisquama did not grow at or below a temperature of 10°C.The maximum growth rate of H.circularisquama (1.3 divisionsday^–1) was obtained with a combination of 30°C and30 PSU. In contrast, C. verruculosa did not grow at 10 PSU andat temperatures of 25°C or more. The maximum growth rateof C. verruculosa (1.74 divisions day^–1) was obtainedwith a combination of 15°C and 25 PSU. A significant temperature-salinityinteraction on growth was found by factorial analysis. Basedon the physiological characteristics obtained in the presentstudy, these novel flagellates have a potential for future outbreaksof red tides in pre viously unaffected waters.     

The Effect of Environmental Factors on Development of the Land-Grab, Cardisoma guanhumi Latreille

Larvae of the land-crab, Cardisoma guanhumi, Latreille. weremaintained in 24 different combinations of salinity and temperaturefrom the time of hatching. Survival to the first crab occurredin salinities of 15–45 p.p.t., 25° and 30°C. Durationof the five zoeal and one megalops stages was similar in salinitiesof 20–40 p.p.t., but at 15 and 45 p.p.t. a greater periodof time was required for total development. Mortality of allthe larvae at 20°C suggests that temperature plays a moreimportant role in survival and distribution of the larvae ofC. guanhumi than salinity. Increments of size in crabs during the first seven post-larvalmolts were similar in salinities of 5–35 p.p.t., 25°C,but in fresh water increase in size at the time of molting wasreduced. Although there was no apparent relationship betweenfrequency of molting and salinities of 5–35 p.p.t., theduration of intermolt was reduced in crabs maintained in freshwater, and survival was also lower. From the present study there is no indication that the morphologicaland physiological processes that are associated with adaptationof the adult crab to the terrestrial environment are initiatedduring larval development. Although the adult crabs have successfullypenetrated the terrestrial environment, the pelagic larvae arestill subject to the numerous ecological variables of the estuarineand marine environments.     

Sporulation in Rhizopus sexualis and Some Other Fungi Following a Period of Intense Respiration

Rhizopus sexualis grown at 20° C. on liquid I per cent.malt or glucose-asparagine medium showed a peak of respiratoryactivity between 40 and 55 hours-after inoculation. Rate ofrespiration then fell until it reached a steady low level whichcoincided with maximum mycelial growth. Zygospore initiationoccurred at or just after the peak of respiration. At a low temperature (9° C.) or with high concentrationsof glucose the respiration peak was less marked and no zygosporesdeveloped. Single ‘plus’ or ‘minus’strains of the heterothallic species Mucor hiemalis and Phycomycesblakesleeanus showed a pattern of respiration and mycelial growthsimilar to that of R. sexualis but no zygospores were formed.Zygospores did not develop without a preliminary period of intenserespiration, but such a peak period could occur without beingfollowed by zygospore formation. A strain of Sordaria fimicola was grown at 25° C. on a syntheticmedium with 5.0 per cent. sucrose or glucose as source of carbon.Respiration reached a peak at approximately 4 and 5 days respectively,the actual peak value being twice as large on sucrose as onglucose. Dry weight of mycelium was greater on glucose thanon sucrose. Perithecia were formed only on the sucrose medium.Visible peri-thecial initials were first seen shortly afterthe occurrence of the respiratory peak. Mature perithecia werepresent 3 days later. The possible significance of these results is discussed.     

Effects of medium components and light on callus induction, growth, and frond regeneration in Lemna gibba (Duckweed)

Summary Basal media, plant growth regulator type and concentration, sucrose, and light were examined for their effects on duckweed (Lemna gibba) frond proliferation, callus induction and growth, and frond regeneration. Murashige and Skoog medium proved best for callus induction and growth, while Schenk and Hildebrandt medium proved best for frond proliferation. The ability of auxin to induce callus was associated with the relative strength of the four auxins tested, with 20 or 50 μM 2,4-dichlorophenoxyacetic acid giving the highest frequency (10%) of fronds producing callus. Auxin combinations did not improve callus induction frequency. Auxin in combination with other plant growth regulators was needed for long-term callus growth; the two superior plant growth regulator combinations were 10 μM naphthaleneacetic acid, 10 μM gibberellic acid, and 2 μM benzyladenine with either 1 or 20 μM 2,4-dichlorophenoxyacetic acid. Three percent sucrose was best for callus induction and growth. Callus induction and growth required light. Callus that proliferated from each frond’s meristematic zone contained a mixture of dedifferentiated and somewhat organized cell masses. Continual callus selection was required to produce mostly dedifferentiated, slow-growing callus cell lines. Frond regeneration occurred on Schenk and Hildebrandt medium without plant growth regulators but was promoted by 1 μM benzyladenine. Callus maintained its ability to regenerate fronds for at least 10 mo. Regenerated fronds showed a slower growth rate than normal fronds and a low percentage of abnormal morphologies that reverted to normal after one or two subcultures.     

Apparatus for the Simultaneous Measurement of Water Vapour and Carbon Dioxide Exchanges of Single Leaves

Equipment is described which delivers air with concentrationsof CO₂ and water vapour closely controlled in the ranges 0 to2500 ppm and 5 to 15 mb respectively, at flow rates of up to10 1 min^-1, to each four leaf chambers. The leaf temperatureis controlled to ±0.5 °C and, with a light intensityof 0.3 cal cm^-2 min^-1 visible radiation (0.4 to 0.7 µm)leaf temperature can be maintained at 17.5 °C.The apparatusused to measure the concentration differences between the watervapour and CO₂ entering and leaving the leaf chamber (used tocalculate transpiration, photosynthetic, and respiration rates)is described in detail.Results of tests, which show the necessityfor mounting a fan within the leaf chamber, are reported.Typicallight- and CO₂-response curves are given for kale leaves (Brassicaoleracca var. acephala) and an attempt is made to quantify theerrors in the measurement of photosynthesis and transpiration.     

Enhancement of Gibberellic Acid-stimulated Hypocotyl Elongation of Lettuce (Lactuca sativa L. cv. Grand Rapids) by Phlorizin and Light

The interaction of light, gibberellic acid (GA₃), and phlorizinin the growth of lettuce (Lactuca sativa L. cv. ‘GrandRapids’) hypocotyls was investigated. At all concentrationsof GA₃, phlorizin enhanced GA₃-induced growth at luminous intensitiesabove 50 ft-c (continuous light). Without GA₃, phlorizin hadno effect on hypocotyl growth in the light but it inhibitedgrowth in the dark. Both seedlings and hypocotyl sections respondedto phlorizin in the presence of GA₃. There was no iteractionbetween phlorizin and KCl. Water-growth was severly inhibitedby light. GA₃,-induced growth was slightly inhibited by light,and then only at luminous intensities above 50 ft-c. Thus, relativeto H₂O-growth, GA₃-induced growth increased with increasingluminous intensity up to 450 ft-c, where it reached saturation.It seems that a synergism may exist between light and GA₃ aswell as between phlorizin and GA₃. Lactuca sativa L, lettuce, hypocotyl elongation, gibberellic acid, phlorizin, light     

Influence of temperature on growth, reproduction and longevity of Moina salina Daday, 1888 (Cladocera, Moinidae)

This paper presents the results of a study of the effects oftemperature on the growth, reproduction and longevity of thecladoceran Moina salina, a species of potential use as livefood in marine aquaculture. The growth rate of M.salina increasedwith increasing temperature. Some parameters of development,such as length at death and the number of adult instars, werealso positively related to temperature. Other parameters (durationof juvenile and adult instars) decreased with increasing temperature,while the number of juvenile instars was unaffected. An increasein temperature resulted in a reduction in age at maturity anda decrease in the number of days between broods. The numberof young per female, the number of broods per female, the numberof youngper day of reproductive life, and the number of youngper brood, increased up to a temperature of 25°C. At 15and 20°C. substantial degeneration of eggs and/or embryosoccurred. Likewise, temperature affected the type of reproductioncarried out by sexual females. Temperature and longevity wereinversely correlated. It was concluded that temperature actsas a very important factor regulating the life cycle of M.salina.Temperature >30°C may correspond to sublethal levels,while a temperature of 15°C is considered to impose stress.The range 20–25°C is optimal for the development andreproduction of this species.