Phytochrome-dependent modulation and re-induction of growth of the first rhizoid in Dryopteris paleacea Sw

Phytochrome-dependent growth in Dryopteris paleacea Sw. was investigated in young, developing gametophytes with respect to formation and differentiation of rhizoids. Under continuous red light (Rc), the first rhizoids grew synchronously by tip elongation at a constant rate of 240 μm · d⁻¹ until formation and outgrowth of the second rhizoid. Cessation of growth of the first rhizoids and outgrowth of the second rhizoids showed a correlation in time assumed to be mediated by intercellular signaling. The first rhizoids showed two modes of response to actinic irradiations: (i) modulation of rhizoid growth, and (ii) re-induction of growth in non-growing rhizoids. In the former, the promotory effect of actinic irradiations on rhizoids pre-cultured under Rc determined both the time for which rhizoids continued to grow after transfer into darkness and the final rhizoid length. In the latter, re-induced growth was studied using non-growing rhizoids which were obtained after irradiation with a far-red light (FR) pulse at the end of the pre-culture in Rc and transfer into darkness for 3 d to stop growth. Re-induction of growth occurred with a lag phase of 36 to 48 h after formation of the FR-absorbing form of phytochrome (Pfr) by a red light (R) pulse. From the incomplete R/FR reversibility it is evident that, here, coupling of Pfr to signal transduction is possible within minutes. Re-induction of growth possesses the advantage that the effect of actinic irradiations can be studied as an all-or-none response at the level of single gametophytes in future experiments. The present results clearly indicate that the developmental stage of the whole gametophyte, i.e. temporal and spatial patterns undergone during development, affects the regulation of rhizoid growth by the external factor light. Received: 8 June 1998 / Accepted: 22 December 1998     

Phytochrome Control of Chlorophyll and Carotenoid Accumulation in Sorghum bicolor

Etiolated Sorghum bicolor seedlings manifested a significantmorphological response to short term irradiations by red andfar-red light and to a continuous far-red light. Accumulationof chlorophylls in white light and carotenoids in darkness isunder red/far-red reversible control as well as along with theeffectiveness of ‘High Irradiance Reaction’. Phytochromeis also found to eliminate the lag phase during the accumulationof chlorophylls and carotenoids in white light. (Received March 11, 1981; Accepted May 2, 1981)     

Different actions of red and blue or far-red lights in the photoperiodic tuberization of Begonia evansiana

The spectral dependence of Begonia evansiana in supplementarylight periods of photoperiodic tuberization and sprouting wasinvestigated. Supplementary application of red light inhibitedtuber development, thereby stimulating vegetative growth. Supplementaryblue or far-red light also suppressed tuber development, butbarely stimulated vegetative growth. However, both red and blue light, given at 6°C during themain light period or the supplementary light period, permittedthe tuberization under the subsequently given conditions ofeither long-days or darkness at 23°C. Blue light appliedafter 5-days of irradiation with white light at 10°C, showedalmost the same action as far-red light, which suppressed tuberizationin darkness. The nature and function of the pigments concernedin the photoperiodic responses are discussed. (Received October 11, 1968; )     

Photomorphogenesis of the Gynophore, Pod and Embryo in Peanut, Arachis hypogaea L.

Darkened excized gynophores ceased to elongate after 8–10days in vitro and started to form a pod. Gynophore elongationwas inhibited to a greater extent in total darkness than underlow irradiance, while pod and embryo growth was stimulated indarkness only. Intact gynophores, enclosed in transparent vials containingglass beads, continued to elongate in both light and darkness.In light the elongating gynophores thickened as they penetratedbetween the glass beads, forming a seedless pod at the bottomof the vials. In the dark the elongating gynophores producedsmall pods in which the seeds had started to grow. Excized gynophores elongated in vitro under continuous whitelight at a rate similar to that of intact exposed gynophores.The rate of elongation in vitro, was lower under continuousblue or red-enriched light, than under white light, and wasfurther reduced under continuous far-red irradiation. Pods didnot form during any of the continuous irradiation treatmentsbut only after transfer to darkness, the largest pods formingafter continuous far-red irradiation. As little as 10 min daily exposure to red or far-red irradiancehad the same effect on gynophore elongation as continuous irradiation.Pods formed only when the daily periods of far-red irradiationwere 30 min or less. Reducing the daily exposures to 2 min decreasedthe time to onset of pod formation from 30 to 16 days. Far-redfollowing red irradiation was effective in inhibiting gynophoreelongation stimulated by red irradiation. Pod formation in red/far-redirradiation was only 50 per cent of that observed in far-redirradiation. The involvement of light in continual gynophoreelongation and in the concomitant inhibition of proembryo growthis discussed. Arachis hypogaea L., peanut, gynophore, photomorphogenesis, embryo development, pod development, proembryo     

Effects of Blue Light Pretreatments on Internode Extension Growth in Mustard Seedlings after the Transition to Darkness: Analysis of the Interaction with Phytochrome

The effects of blue light (B) pretreatments on internode extensiongrowth and their possible interaction with phytochrome mediatedresponses were examined in Sinapis alba seedlings grown for11 d under 280 µmol m^–2 s^–1 of continuousblue-deficient light from low pressure sodium lamps (SOX). SupplementaryB (16 µmol m^–2 s^–1) caused no detectable inhibitionof the first internode growth rate under continuous SOX, butgrowth rate was inhibited after transfer to darkness. This effect,and the growth promotion caused by far-red bend-of-day' lightpulses were additive. The addition of B at 16 µmol m^–2s^–1 during 11 d, or only during the first 9 or 10 d orthe latest 0.75, 1 or 2 d of the SOX pretreatment caused approximatelythe same extent of inhibition after the transition to darkness.A single hour of supplementary B before darkness caused morethan 50% of the maximum inhibition. However, 24 h of lower fluencerates of B (4 or 7 µmol m^–2 s^–1) were ineffective.Covering the internode during the supplementary B period didnot prevent the response to B after the transition to darkness.Far-red light given simultaneously with B (instead of the SOXbackground) reduced the inhibitory effect of B. Above a given threshold fluence rate, B perceived mainly inthe leaves inhibits extension growth in subsequent darkness,provided that high phytochrome photo-equilibria are presentduring the irradiation with B. Once triggered, this effect doesnot interact significantly with the ‘end-of-day’phytochrome effect. Key words: Blue light, extension growth, phytochrome     

PHOTOCONTROL AND TEMPERATURE DEPENDENCE OF GERMINATION OF RUMEX SEEDS

1. Light is not obligatory for the germination of the seed ofRumex obtusifolius L. subsp.agrestis DANSER, which has beenregarded as being a typical light sensitive seed. Even in continuousdarkness, a short period of high (30°) or low temperature(5°) treatment evokes germination very readily. 2. Germination is markedly promoted by 1 min exposure to a redlight and this red light effect is completely removed by 1-hrexposure to a far-red light. Alternations of the red and far-redradiation bring about an alternate promotion and inhihibitionof germination. 3. When a dark interval is inserted between the red and thefar-red treatments, inhibition of germination becomes less distinctas the duration of darkness increases. When the seeds are irradiatedwith far-red prior to red, with an inserted darkness, germinationpromotion due to the red light also decreases with the durationof inserted darkness. 4. Complicated interdependence between the light and temperatureeffects are demonstrated. This suggests a participation of somereactants besides pigments in the photoreaction. 5. The observed interdependence between the light and temperatureeffects on the germination of Rumex seeds implies that, if,as BORTHWICK has assumed, two forms of pigment, viz., a far-red-absorbingform and a red-absorbing one, are participating in the photoreaction,they should be presumed to coexist from the start of imbibition. (Received September 27, 1960; )     

Periodical growth response of Lemna gibba G3 to light-break

Brief exposure to light promotes frond multiplication in Lemnagibba G3 in darkness. Extent of promotion changes periodicallywith the time of the light-break. Response curves are interpretedin terms of a superposition of two modes of growth responseto light-break, which are, respectively, under the control ofdifferent physiological timing devices; circadian oscillationand the hourglass-type clock. Circadian oscillation, which consistsof a half-cycle of increasing photophily followed by anotherhalf-cycle of declining photophily, starts at a light-on signaland continues for a few days with rapid damping. The 24-hr periodof oscillation is the same at temperatures ranging from 16 to26°C. The hourglass is released by a light-off signal to‘accumulate sand’ or to increase photophily in asigmoidal way with time and is temperature-sensitive; the tempoof‘sand accumulation’ being quicker at 21°Cthan at 16 or 26°C. Oscillation is hastened to fade-outat 21°C, most likely due to the accelerated pace of thehourglass. Red and far-red reversibility is disclosed in bothmodes of growth response. (Received December 31, 1969; )     

Effects of Light, pH, Temperature, and Crowding on Megaspore Germination and Sporophyte Formation in Marsilea

Megaspore germination and sporophyte formation of Marsilea vestitaH. and G. was studied under different light, pH, temperature,and crowding conditions during a 6 d experimental period. Maximumgermination and sporophyte development occurs under relativelylow light intensity. Darkness and high light intensity inhibitsporophyte development. Selected wavelengths of light (red,far-red, green, blue) and darkness reduce both megaspore germinationand sporophyte development as compared to white light. Megasporesand sporophytes show maximum development at 25 ?C in light,whereas their development is reduced at all temperatures indarkness. The optimum pH range for megaspore germination ispH 7–8 and that for sporophyte development is pH 7. Sporocarpcontents alter the pH of unbuffered acidic and basic media towarda more optimal growth condition (pH 6–8) for megasporegermination. Megaspore germination and sporophyte developmentvary inversely with conditions of crowding. Root and leaf growthon developed sporophytes is very similar in most treatments.     

Growth and Dormancy in Lunularia cruciata (L.) Dum.: I. RESUMPTION OF GROWTH AND ITS CONTINUATION

Lunularia cruciata may become dormant at three stages in itslife history: mature thallus, gemma, and spore. The resumptionof growth and its continuation in various conditions have beenstudied in thalli and gemmae. Air-dry, mature thalli of theIsrael strain, planted on a suitable medium, produce adventitiousbranches ventrally from the region immediately posterior tothe existing meristem, which itself fails to resume growth.When dormant gemmae are taken from the gemma-cup, however, theexisting apical cells and meristems simply recommence growing,so that the new growth is continuous with the old. Except inthe case of mature thalli aroused from dormancy, apical dominanceis pronounced, and branching occurs only by bifurcation. Thisdominance can be broken by applying sucrose solution to thegrowing tips—possibly a plasmolytic effect. The growth in area of freshly planted gemmae accelerates forabout 25 days before its relative rate slows to any great extent.During the first half of this period, growth is due exclusivelyto the expansion of existing cells, but subsequently cell numbersincrease rapidly from the 8–10,000 present in the dormantgemma. Cell numbers were estimated by using a modified macerationtechnique, in which chelation followed prolonged fixation. Lunularia grows successfully at quite low light intensities.Of the mineral nutrient deficienccs investigated, lack of Plimits growth most severely, although N-deficiency also restrictsit to a very low level. Gemma-cup production appears to be unaffected by light intensity,at least within levels permitting growth. There is, however,a large temperature effect, cup production decreasing markedlyabove 12° C.     

Light germination ofAnthoceros miyabeanus spores

The effects of light on the spore germination of a hornwort species,Anthoceros miyabeanus Steph., were investigated. Spores of this species were photoblastic, but their sensitivities to light quality were different. Under either continuous white, red or diffused daylight, more than 80% of the spores germinated, but under blue light none or a few of them germinated. Under continuous far-red light or in total darkness, the spores did not germinate at all.Anthoceros spores required red light irradiation for a very long duration, i.e., over 12–24 hr of red light for saturated germination. However, the spore germination showed clear photo-reversibility by repeated irradiation of red and far-red light. The germination pattern clearly varied with the light quality. There were two fundamental patterns; (1) cell mass type in white or blue light: spores divide before germination, and the sporelings divide frequently and form 1–2 rhizoids soon after germination, and (2) germ tube type in red light: spores germinate without cell division, and the single-cell sporelings elongate without cell division and rhizoid formation.     

The involvement of photosynthesis in inducing bud formation on excised leaf segments of Heloniopsis orientalis (Liliaceae)

The role of photosynthesis in inducing adventitious bud formationon leaf segments of Heloniopsis orientalis was investigated.The effect of white light reached a maximum at about l25 J?m^–2?sec^–1.White, red, blue and far-red light were effective in inducingbud formation, but green light was not. In darkness, bud formationwas induced if sugar was added to the nutrient medium. The photosyntheticinhibitors DCMU and AT blocked the effect of light. Bud formationwas inhibited in CO₂-free air. The requirement of sucrose forbud formation in darkness could be replaced by citrate. It wasconcluded from these results that light appears to induce budson leaf segments through some processes dependent upon photosynthesis. (Received January 11, 1978; )     

PHOTOMORPHOGENESIS IN PTERIS VITTATA: I. PHYTOCHROME-MEDIATED SPORE GERMINATION AND BLUE LIGHT INTERACTION

1. Spores of the fern Pteris vittata did not germinate under totaldark conditions, while an exposure of the spores to continuouswhite light brought about germination. The germination was mosteffectively induced by red light and somewhat by green and far-red,but not at all by blue light. The sensitivity of spores to redlight increased and leveled off about 4 days after sowing at27–28. The promoting effect of red light could be broughtabout by a single exposure of low intensity. Far-red light givenimmediately after red light almost completely reversed the redlight effect, and the photoresponse to red and far-red lightwas repeatedly reversible. The photoreversibility was lost duringan intervening darkness between red and far-red irradiations,and 50% of the initial reversibility was lost after about 6hr of darkness at 27–28. These observations suggest thatthe phytochrome system controls the germination of the fernspore.
2. When the imbibed spores were briefly exposed to a low-energyblue light immediately before or after red irradiation, theirgermination was completely inhibited. The blue light-inducedinhibition was never reversed by brief red irradiation givenimmediately after the blue light. The escape reaction of redlight-induced germination as indicated by blue light given aftervarious periods of intervening darkness was also observed, andits rate was very similar to that determined by using far-redlight. Spores exposed to blue light required 3 days' incubationin darkness at 27–28 to recover their sensitivity tored light. The recovery in darkness of this red sensitivitywas temperature-dependent. It is thus suggested that an unknownbluelight absorbing pigment may be involved in the inhibitionof phytochrome-mediated spore germination.

(Received August 21, 1967; )     

Responses of Marchantia in Aseptic Culture to Well-known Auxins and Antiauxins

Responses of young thalli of Marchantia nepalensis to ten well-knownauxins and antiauxins in aseptic culture are described. Effectsof one concentration of an auxin or an antiauxin were studiedin both liquid and solid cultures. The normal growth of inoculated thalli was inhibited but callus-liketissue was produced on them by the highest concentration (I.Omg./I.) of almost all the growth substances except MH, TIBA,and 2, 4^–DNP. At a later period callus-like tissue producedby IAA, IBA, and IPA differentiated into new thalli but thatproduced by NAA, NOA, 2,4^–D, and TCPA only did so on beingtransferred to control medium. At lower concentrations inoculated thalli developed normallybut they were soon overgrown by daughter thalli. No protonemalphase comparable to that of mosses could be observed in thedevelopmental stage of a regenerating thallus. The early stageis characterized by a stable filamentous structure, normallyconsisting of two to three cells. Filamentous structures ofvarying number of cells were however produced in some treatments. Profuse rhizoids were produced by the highest concentrationof NOA, 2,4^–D, TCPA, IBA, and IPA. Certain growth substancesinhibited the formation of tuberculate but not of smooth rhizoidsin liquid but not in solid cultures. Also tuberculate rhizoidswith feebly developed pegs were produced in certain liquid culturesonly and even in control liquid culture. More gemma-cups wereproduced in liquid cultures. Germinated gemmae with rhizoidswere invariably present in solid but not in corresponding liquidcultures. Germinated gemmae within gemma-cups were frequentlyfound. The significance of these results is discussed.     

Variations in Tiller Dynamics and Morphology in Lolium multiflorum Lam.Vegetative and Reproductive Plants as affected by Differences in Red/Far-Red Irradiation

Lolium multiflorum Lam, plants were grown in a growth room undertwo light sources with red/far-red ratios of 1·62 and0·84 but similar photosynthetically active radiation.In both situations the capacity to produce new tillers and thelight available per tiller decreased with canopy growth. Tilleringwas further reduced by the low red/far-red ratio while lightinterception and plant dry weight were unaffected by this treatment.In both reproductive and vegetative plants under the lower red/far-redratio the time between leaf expansion and the appearance ofa tiller in its axil was increased and the proportion of ‘maturebuds’ that developed was reduced. Irradiation with lowred/far-red advanced the reproductive development and increasedthe number of fertile tillers per plant. It also caused longerleaf sheaths, blades and reproductive shoots. The results suggestthat as canopy density increases the lower light interceptionper tiller and the photomorphogenic effect of low red/far-redratios may reduce the capacity to produce new tillers. Lolium multiflorum, Lam., annual ryegrass, tillering, tiller growth, leaf growth, flowering, light quality.     

Flower Opening in Asiatic Lily is a Rapid Process Controlled by Dark-light Cycling

In commerce, Asiatic lilies are picked in bud, each stem holdingseveral buds. We found flower opening was rapid, taking lessthan 4 h both on the stem and for excised buds. Opening wasalso strongly synchronous. For a 12 h day-night cycle, openingbegan late in the dark period, reaching a mid-point after 11h of darkness. This was equally true of buds that were excisedwhen nearly ready to open, and those with 3–4 d of developmentto complete. Reversing day and night reversed the time of opening,and red light was as effective as white light in providing ‘day’conditions. A 15 min light break during the night did not affectthe opening. Lengthening the night (8, 12, 16 h) and shorteningthe day delayed opening from 9, to 11, to 13 h after the startof darkness, respectively. In continuous light and continuousdark, synchronicity was lost. If opening flowers were held inextended darkness, two phases of opening could be discriminated.In a ‘dark phase’, petals opened to approx. 40°,and anthers remained intact. When such flowers were returnedto light, there was a ‘light phase’, where petalsopened further, became more pigmented and began to recurve,and the anthers dehisced, these events taking only 2–3h. The net result was that flowers became fully open and anthersdehisced approx. 2 h after dawn, regardless of daylength. Copyright2000 Annals of Botany Company Asiatic lily, Lilium hybrid, flower opening, timing, endogenous rhythm, synchronicity     

The Effects of Red, Far-red, and Blue Light on the Geotropic Response of Coleoptiles of Zea mays

The effects of red, far-red, and blue light on the geotropicresponse of excised coleoptiles of Zea mays have been investigated.Seedlings were grown in darkness for 5 or 6 days, exposed tovarious light treatments, and then returned to darkness fordetermination of the geotropic response. The rate of response of the coleoptiles is decreased after theyhave been exposed to red light (620–700 mµ, 560ergs cm^–2sec^–1 for the 24 hrs, but not for the 4hrs, preceding stimulation by gravity. Furthermore, their rateof response is greatly reduced if they are exposed to red lightfor 10 min and then returned to darkness for 20 hrs before geotropicstimulation. At 25° C an interval of 6 to 8 hrs elapses between a 10-minexposure to red light and the first detectable decrease in thegeotropic response of the coleoptile. This interval can be lengthenedby exposing the seedlings to low temperatures (0° to 2°C) after the light treatment but cannot be greatly shortenedby increasing the duration of exposure to red light. Using a standard procedure of exposing 5-day-old etiolated seedlingsto light for various times, replacing them in darkness for 20hrs and then determining the response of the coleoptiles to4 hrs geotropic stimulation, it has been found that: (a) Exposureto red light for 15 sec significantly decreases the geotropiccurvature of the coleoptiles and that further reduction occurson increasing the length of the light treatment to 2 and 5 min.(b) Far-red light has no effect on the geotropic response ofthe coleoptiles but it can completely reverse the effect ofred light. After repeated alternate exposure to red and far-redlight the geotropic response of the coleoptile is determinedby the nature of the last exposure, (c) Complete reversal ofthe effect of red light by far-red radiation only occurs whenexposure to far-red follows immediately after exposure to red.The reversing effect of far-red radiation is reduced if a periodof darkness intervenes between the red and far-red light treatments,and is lost after a dark interval of approximately 2 hrs. The effect of red light on the rate of geotropic response ofthe coleoptiles is independent of their age and length at thetime of excision. Blue light acts in a similar way to red light, but the seedlingsare less sensitive to blue than to red light. Coleoptiles grown throughout in a mixture of continuous, weak,red, and far-red light have a lower rate of geotropic responsethan etiolated coleoptiles.     

The Protonema of Chara fragilis Desv.: Regenerative Formation,Photomorphogenesis, and Gravitropism

When exposed to constant white light for four weeks, isolated nodes of Chara fragilis Desv. regenerated side branches, rhizoids, and multicellular protonemata, the latter being similar to those germinated from oospores. When kept in darkness the nodes developed protonemata exclusively. These were single-celled, colourless, and tip-growing and, with the light microscope, they looked like rhizoids. Upon exposure to blue light, but not to red or far-red, the growth rates of the protonemata rapidly declined, the cell apices swelled, and the nucleus migrated acropetally. Within 24 h the cells went through the first of a series of divisions resulting in the formation of multicellular protonemata. When returned to darkness after a blue light pulse of 5 h the cell divisions proceeded normally, but the protonemata showed etiolated growth. While growth of the internode was drastically promoted, the development of the multicellular apex and the lateral initial were suppressed. Both uni- and multicellular etiolating protonemata showed negative gravitropism but were phototropically insensitive. It is argued that the single-celled protonema is an organ specialized for the penetration of mud covering the nodes or oospores of Chara and thus serves to search for light, comparable to etiolated hypocotyls and stems in seedlings of higher plants.     

The Influence of Light on Geotropism in Cress Roots

Light affects the growth and orientation of roots of cress seedlings(Lepidium sativum L. cv. Curled). The effects are manifest eitheras increased rates of geotropic curvature or, if the roots arehorizontal, as distorted and crinkled forms of growth. Blue,red, and far-red irradiation can bring about these effects,but with differences of detail: at equal fluence rates duringthe period of geostimulus, blue is more effective than red atincreasing the rate of geocurvature; however, with irradiationprior to a geostimulus, only the stimulatory effects of redirradiation persist for 2–4 h of darkness. Short periods(5 min) of radiation, if given at the time of geostimulus, enhancegeocurvature, again with blue most, and far-red least, effective,but there are no clear indications of red/far-red reversibility.The possibility of there being more than one photosystem responsiblefor the effects of white light on the geotropic responsivenessof roots is discussed.     

Growth and Dormancy in Lunularia cruciata (L.) Dum: VII. THE ISOLATION AND BIOASSAY OF LUNULARIC ACID

The extraction, purification, and isolation of the growth inhibitorpreviously postulated are described. Methanol extraction andseparation into acid, neutral, and basic fractions was followedby paper chromatography of the acid and neutral fractions withdistilled water, re-extraction with methanol, and thin-layerchromatography, the peak of inhibition being located at Rf 0.7–0.8(isopropanol: ammonia: water, 100:5:5), or Rf 0.3–0.4(chloroform: ethyl acetate: acetic acid, 60:40:5) Lunularia gemmae, grown directly on the chromatographic stripwith added nutrient solution, served as the most appropriateand direct bioassay. Area measurements after 5–10 days'growth yielded significant differences. Other bioassays included:Marchantia polymorpha gemmae, lettuce hypocotyl growth, cress-seedgermination, oat coleoptile, and radish cotyledon disc tests.An active inhibitor, i.e. dihydrohydrangeic acid, now named‘lunularic acid’, was isolated in crystalline form.Lunularic acid was found to increase with long-day treatmentof Lunularia thalli, though present even in short-day. Its concentrationcould be altered rapidly when daylength conditions were changed.The growth inhibition was linearly related to concentrationover the range from 0.1 to 10 ppm, very high concentrationsbeing lethal. Abscisic acid, though inhibitory to Lunulariain low concentrations, was not detected in extracts, and couldeasily be separated from lunularic acid.     

Studies in Stomatal Behaviour: X. AN INVESTIGATION OF RESPONSES TO LOW-INTENSITY ILLUMINATION AND TEMPERATURE IN XANTHIUM PENNSYLVANICUM

Two experiments are described in which stomatal sensitivityto low-intensity white light was studied for Xanthium pennsylvanicumWall. In the first experiment a daylength extension for 7, 9, or 15hrs. was given using 10, 40, or 160 lux to shorten a basic 16-hr.night, which was also given at its full length as a tenth treatment.Measurements were made of stomatal opening ability on the morningfollowing the different treatments. With a 15-hr. extensionthere was at all intensities a significant response, shown bya reduced rate of opening in the morning. With a 9-hr. extensionusing 40 or 160 lux, opening ability was reduced, but 9 hrs.of 10 lux was insufficinet to produce a detectable effect. The7-hr. extension was ineffective at all three intensities. In the second experiment stomatal behaviour was observed during20 hrs. of either darkness or 10 lux at four temperatures (15,22, 29, and 36°C.). During 20 hrs. of darkness there wasnight opening at all temperatures, but at lower temperaturesit began sooner and lasted longer. These responses to temperaturedid not fit a simple linear relationship, there being a significantcubic term revealed by non-linear regression analysis. Thiscould be explained if the response was considered in terms ofthe magnitude of the change in temperature (from 25°C.)at the beginning of the experiment; there appeared to be sometemperature compensation over a limited range. in 10 lux, nightopening was suppressed at 29° and 36°, but at 15°it was apparently unaffected by the light; at 22° it wasnot completely suppressed by 10 lux but the time of its occurrencewas delayed. Effects of light and temperature are discussed in relation toan endogenous rhythm in darkness which was previoulsy shownto operate in Xanthium pennsylvanicum (Part IX). It is considered that to explain effects of very low intensitylight it will be necessary to recognize a ‘low intensityresponse’ by stomata, which does not operate via changesin guard-cell carbon dioxide.