Activity responses of two species of Peromyscus (Rodentia,Muridae) to varying light cycles

Summary Activity of Peromyscus floridanus and P. gossypinus was studied through a sequence of light-dark regimes including 12-hr light, 12-hr dark; 18-hr light, 6-hr dark; continuous light; and 12-hr light, 12-hr dark. Two populations of each species and both wild caught (field) and first generation laboratory conceived and reared (lab) mice of each stock were tested. All mice were strongly nocturnal during the initial 12-hr and 18-hr photoperiods, although gossypinus was relatively more active during the light phase than floridanus. Both species tended to become aperiodic in constant light, but floridanus showed a greater tendency to adhere to the nocturnal cycle of the preceding 18-hr photoperiod. Although the two species were relatively more active in light during the second 12-hr photoperiod than during the first 12-hr light, 12-hr dark regime, floridanus reestablished a stronger nocturnal cycle than gossypinus. Lab groups exhibited essentially the same trends between species and populations as the field animals, thus indicating some genetic basis for the observed differences. P. gossypinus had a higher over-all absolute activity level than floridanus. There was also less difference between the performance of field and lab groups of gossypinus than of floridanus. Both species showed a decline in activity with increased photoperiod, the effect being more pronounced in floridanus.The difference in the activity responses of the two species appears to be correlated with the characteristics of their habitats and nest sites. The stricter nocturnality of floridanus is associated with relatively xeric, open habitat in which daytime activity would seem to involve higher risk of predation and greater heat strss and water loss than in the case of the more humid denser forest environments typical of gossypinus. P. floridanus also nests in burrows, whereas nests of gossypinus are typically located in more accessible places where a lower threshold for activity in light might increase a mouse's chances of escaping from a predator when surprised in the nest during the day. The floridanus populations tended to differ more in percentage of activity in light and level of absolute activity than the corresponding gossypinus stocks. The difference in the activity patterns of the two floridanus populations was correlated with the density of vegetation in their respective habitats. Relative eye size was not clearly associated with species and population differences in activity responses to light.     

Floral initiation in Lolium temulentum L.: the role of phytochrome in the responses to red and far-red light

Summary The possibility that phytochrome is involved in the promotion of flowering by far-red light was investigated. The addition of far-red (FR) to a day extension with red (R) light promotes inflorescence initiation in Lolium. A 2-hour interruption with darkness also promoted flowering compared with the uninterrupted red light control; apex length was further increased by a 10-minute FR irradiation given before the 2-hour dark interruption and was decreased by 10-minutes of R light given in the middle: both FR promotion and R inhibition were reversed by R and FR respectively. Apex length increased approximately linearly with increasing duration of dark interruption up to at least 2 1/2 hours. When varying ratios of R:FR light were substituted for a 2-hour dark period, apex length was increasingly depressed as the % R was increased above 25%; no difference between 25% R/75% FR and 100% FR could be detected. Apex length was inversely linearly related to the calculated [Pfr]/[P] ratios above about 40% Pfr.FR promoted flowering when given during a 5-hour interruption of a day extension with R light but, between 0.25 and 0.90 J m² s^-1, there was no effect of intensity of FR; at 0.11 J m^-2 s^-1 apex length was shorter than at 0.25 J m^-2 s^-1 but longer than in darkness. When the duration of FR (from the beginning of a dark interruption of a day extension with R) was varied, apex length increased with increasing duration of FR up to 1 1/4 to 2 hours but further increasing the duration of FR did not promote flowering more.The results implicate phytochrome in the promotion of flowering by FR light. It has been demonstrated that a low [Pfr]/[P] ratio (less than present in 25% R/75% FR) is needed over a relatively long period of time: this explains why a relatively high proportion of FR light must be added to R for several hours in order to give maximum promotion of flowering. It is concluded that, in Lolium, the increased flowering response to FR light is brought about by a reduction of [Pfr]/[P] ratio at the appropriate time, although the possibility that another effect of far-red is also involved has not been rigorously excluded.     

Daily changes in concentrations of prolactin in serum of prepubertal bulls exposed to short- or long-day photoperiods

Early temporal changes in concentrations of prolactin (PRL) in serum after a sudden change in photoperiod and daily responsiveness to PRL-releasing and inhibiting factors were investigated in prepubertal Holstein bull calves exposed to different photoperiods. In calves switched from 8-hr light: 16-hr dark to 16-hr light:8-hr dark, there was no observable change in the daily pattern of serum concentrations of PRL after 1, 2, or 4 days. On the other hand, in animals switched from 16-hr light:8-hr dark to 8-hr light:16-hr dark, there was a consistent increase in serum PRL from 33.4 ng/ml on Day 0 to maximum values of 57.3, 62.7, and 78.9 ng/ml between 14 and 18 hr after onset of light on Days 1, 2, and 4, respectively. Thus, absence of light allowed expression of a daily rhythm in serum concentrations of PRL that persisted for at least 4 days after the photoperiod switch. There were no differences in L-dopa inhibition of PRL release in animals exposed to 16-hr light:8-hr dark at 3 or 15 hr after onset of light. However, thyrotropin-releasing hormone-induced release of PRL was greater 3 hr after onset of light (11 hr after onset of dark) compared with release at 9, 15, and 21 hr after onset of light in animals exposed to 16-hr light:8-hr dark, but not in bulls exposed to 8-hr light:16-hr dark. The results provide evidence that the cue for the putative photosensitive period of PRL secretion in cattle may be more closely associated with onset of dark, not onset of light.     

LEAF INITIATION CORRELATES WITH TIME OF MAXIMAL SENSITIVITY OF THE SDP XANTHIUM (ASTERACEAE) TO DARK INTERRUPTION

The hypothesis was tested that the well-known maximal sensitivity to a light break at or near the middle of the dark period of short-day plant Xanthium is correlated with a specific stage of leaf initiation. Samples were collected at various hours before and during noninductive 6-hr dark periods. Lengths of leaf primordia were calculated from serial transverse sections. The reproducible results confirmed that leaf initiation occurred at or near middark under the 18:6 hr light: dark growing conditions. The author suggests the working hypothesis that for a light break to be effective in nullifying the effect of a “long” night in photoperiodically sensitive plants, the light must react with a specific early stage of leaf initiation.     

Effect of ultraviolet-light interruption on flowering inPharbitis seedlings

Seedlings ofPharbitis nil, strain Violet, were exposed to ultraviolet (UV, 254 nm) light at various times of a 16-hr dark period for 60, 90, and 120 sec. When UV light was given at the 6th hr of the dark period, flowering was most inhibited irrespective of UV dosages. The inhibition pattern of flowering caused by UV light was similar to that caused by red light. Contribution No. 101 from the Department of Biology, Miyazaki University.     

THE EFFECTS OF LIGHT ON THE DEVELOPMENT OF THE CELLULAR SLIME MOLD ACRASIS ROSEA

No fruiting of the NC-18 isolate of Acrasis rosea occurs in cultures maintained in continuous light or in continuous dark. The use of different food organisms does not alter the aforementioned behavior. The time at which fruiting occurs in this isolate can be regulated by administering stimulatory light followed by a dark period. Mature sorocarps are formed approximately 14 hr after the termination of light and the start of darkness. Within this 14-hr interval aggregation and sorocarp development occur. After about 6 hr of dark incubation, NC-18 amebae, previously stimulated by light, form a few weak aggregation centers. After 8 hr of dark incubation there are numerous aggregation areas, large in size and deep rose in color. By 10 hr the aggregations are quite compact and firm in appearance, and between 12 and 14 hr late aggregations, sorogens and, finally, mature sorocarps are formed. The minimum dark period, i.e., the minimum time that is required in darkness (for cultures previously stimulated with light) to obtain at least some fruiting within the 14-hr developmental period, is 7–8 hr for NC-18 and 5–6 hr for Tu-26. Maximum numbers of sorocarps form when cultures are given 10–11 hr of uninterrupted dark. Light-stimulated cultures of NC-18 placed in darkness and interrupted by a 10- or 30-min exposure to wide-spectrum blue or cool white fluorescent light an hour prior to the minimal dark period exhibit a 4–5 hr-delay in fruiting when returned to darkness and inspected at intervals following the second irradiation. Growth and fruiting of NC-18 occurred with purified food sources of each of five different species of Chlorella and with the alga Stichococcus bacillaris. This is apparently the first report of the utilization of algae as food sources by a cellular slime mold. Fruiting of NC-18 was readily arrested by lowering the relative humidity to 40–45%. This change in the moisture content of the surrounding air induced microcyst formation. Growth on buffered medium occurred in the entire pH range tested, 3.5–7.6, but fruiting occurred only between pH 5.0 and 6.6.     

LIGHT-MEDIATED INHIBITION OF IN VITRO DEVELOPMENT OF RUDIMENTARY EMBRYOS OF ILEX OPACA

The mature seeds of Ilex opaca Ait. contain rudimentary heart-shaped embryos. When excised embryos of cv. Farage were grown in vitro with a 16-hr photoperiod, only 20 % reached germination size after 13-day incubation, while 75% of the embryos reached the same stage when incubated in darkness. This light inhibitory effect increased with the length of daily light exposure as the daily photoperiod reached 4 hr. Nearly 50% growth reduction resulted as the cultures were preincubated in light continuously for 2 days before a 10-day dark incubation. After 4 days of light incubation the inhibitory effect could no longer be reversed by the subsequent dark incubation. Once the heart-shaped embryos started to grow in darkness they become progressively insensitive to subsequent light inhibition. After a 6-day initial dark incubation the embryos become immune from the inhibitory effect of light. This light inhibitory effect on in vitro embryo growth was universal in all 11 tested cultivars.     

PHOTOPERIODIC ADAPTATIONS IN EUPATORIUM RUGOSUM

Racial differences based on flowering response to several photoperiods were detectable in two widely separated populations of white snakeroot, Eupatorium rugosum Houtt. The most favorable photoperiod for advanced flowering in Georgia stocks was 12 hr, for those from North Dakota, 14 hr. The difference in latitude between these populations was approximately 12° and represents a mean difference of 75 days in the frost-free season. Under noninductive photoperiod a 1-hr interruption of white light in the middle of 15 hr of darkness stimulated floral initiation in North Dakota plants, whereas the same application at the beginning or at the end of the dark period failed to produce flower buds. The effect of red light (660 mμ) for 10 min given in the middle of the long night was similar to white light on the northern strain, and was negated by far-red (730 mμ). Georgia stocks initiated flowering under 15 hr of darkness but were retarded by white light applied in the middle of the period, thus differing in basic response from North Dakota plants. Red light, in contrast to effects observed in North Dakota plants, retarded initiation of flower buds. This effect was offset by far-red light. When compared with other studies on long-day and short-day species our results suggest that photoperiodic adaptations related to latitudinal distribution occur in white snakeroot. The North Dakota strain showed correspondence to long-day types while short-day tendencies were exhibited by Georgia plants.     

The photoreaction controlling seed germination in Eragrostis curvula

This study reexamines the nature of the previously reportedphotoreaction (7) that controls simultaneous promotion and inhibitionof germination of Eragrostis curvula (SCHRAD.) NEES seeds bya light-interruption of the dark-imbibition period. As the intensity of the illumination that interrupts the dark-imbibitionperiod is increased many fold, the promotion of germinationincreases slightly; but the percent of seed apparently inhibitedincreases appreciably. As the intensity of the illuminationof the main light period following an interrupted dark periodis increased, the inhibitory effects of the interrupting lightare increasingly counteracted. Thus, an interaction occurs betweenthe interruption and the main light period; the higher the energyof the interrupting light, the higher must be the energy oflight during the main period to overcome the apparent inhibition. The reversibility of the separate promotive and inhibitory effectsof light that interrupts the dark-imbibition period and thepromotive effects in the main light period indicate that allare phytochrome controlled. Both promotive and inhibitory effectsare produced at the time of the interruption by the formationof the P_fr form. A physical analogy is used to suggest an explanationfor the inhibitory effects. Thus, only one photoreaction, that of phytochrome, is thoughtto account for all the results. This conclusion is supportedby the finding that both promotive and inhibitory responsesare energy dependent over wide reciprocal variations of timeand intensity of irradiation. (Received December 15, 1967; )     

Responses of Adult Plodia interpunctella (Hübner) (Lepidoptera: Pyralidae) to Light and Combinations of Attractants and Light

Responses of adult Indianmeal moth, Plodia interpunctella (Hübner) (Lepidoptera: Pyralidae) to light alone and to a combination of attractant(s) and green/UV lights were studied. When P. interpunctella adults were given a choice between dark areas and areas illuminated with UV, green, or white light, they rested preferentially on surfaces in the illuminated areas. UV light elicited the strongest of the positive phototactic responses. Light traps were not as effective as traps baited with pheromones or food lures in capturing adult moths, and combining green or UV light with these attractants did not significantly increase the trap catches. Gravid females required a period of darkness to realize maximum oviposition, and illumination above 8 lx during the scotophase of a 24-hr light–dark cycle inhibited oviposition.     

Light dependency of the mating process in Closterium acerosum

Sexual cell division and activation of gametangial cells forconjugation in Closterium acerosum were induced by light. L₂₀₀cells conjugated at maximum level under the following conditions;(i) a light intensity higher than 1,000 lux in a 16-hr lightand 8-hr dark regime and (ii) an illumination time longer than12 hr at 3,000 lux. L₂₀₀ cells also conjugated under continuousillumination at 3,000 lux. The action spectrum for the activation of gametangial cellshad peaks around 450, 611 and 665 nm. 3-(4'-Chlorophenyl)-l,l-dimethylurea (CMU) inhibited the accumulationof carbohydrates and sexual cell division at 10^–5 M andthe activation of gametangial cells for conjugation at 10^–4M. (Received August 15, 1977; )     

PHOTO-INHIBITION OF SPORULATION IN ALTERNARIA SOLANI

Lukens, R. J. (Connecticut Agric. Expt. Sta., New Haven.) Photo-inhibition of sporulation in Alternaria solani. Amer. Jour. Bot. 50(7): 720–724. Illus. 1963.—Day-old conidiophores from starved cultures of Alternaria solani require a 12-hr dark period to produce conidia. If the cultures are illuminated during the dark period, conidial production is inhibited. The action spectrum of light inhibiting conidial formation contains 2 maxima, a sharp one at 450 mμ and a broad one extending from 375 to 425 mμ. The entire action spectrum corresponds approximately to the absorption spectra of riboflavin-5-phosphate mononucleotide (FMN) and of 6-carotene. FMN nullifies the effect of light in inhibiting sporulation, but b-carotene does not. Flavins appear to be essential for conidial formation and are photo-inactivated. It is likely that flavins are photo-receptors through which light inhibits conidial formation in A. solani.     

Flowering response of Lemna perpusilla 6746 to a single dark period

Lemna perpusilla 6746 is induced to flower by a single longdark period, but the floral buds once formed disappear afterseveral days under 5000 lux/25?C. Such regression of floralbuds is prevented by lowering the light intensity or temperature,but if the light intensity and/or temperature are lowered beyondcritical levels, new floral buds form. If the cultures are subjectedto 100 lux/20?C, neither regression nor new formation of floralbuds occurs. Under such conditions, the number of floral frondsreaches maximum about 6 days after the inductive dark periodand reamins unchanged for at least 10 days, while the percentageof floral fronds rapidly decreases thereafter, owing to thedilution by newly developed vegetative fronds. When the cultures are subjected to various lengths of a singledark period (25?C) followed by 100 lux/20?C, flowering responsesrepresented by the number of floral fronds per flask show rhythmicfluctuation with a cycle length of about 24 hr. Similar rhythmicresponse is observed when a brief light interruption is givenat different times during a single long dark period. (Received December 2, 1974; )     

Photosynthetic and respiratory electron transport in a cyanobacterium

In the cyanobacterium Agmenellum quadruplicatum steady-state redox conditions were monitored in vivo for cytochrome (+c553) and P700 versus intensities of an actinic light 1 or light 2 (mainly absorbed by photosystems, and 2, respectively). Parallel measurements of O₂ evolution were used to calibrate intensities for rates of electron transfer. Results show that the quality of actinic light (as light 1 or light 2) depends on intensity as well as wavelength. The contribution of electron flow from respiration is confirmed by observations of relative rate of photoreaction 1 estimated from Ip (intensity × fraction of P700 reduced). With 3,- (3,4-dichlorophenyl-1, 1-dimethylurea) (DCMU) the rate of photoreaction 1 depends upon, and is sensitive to small changes in, the rate of dark respiration. Very slow transient dark reductions of Cyt (f+c553) and P700 following any low intensity actinic light 1 are attributed to respiratory electron flow. Cyclic electron flow around photoreaction 1 cannot be large compared to dark respiration and cannot vary significantly with light intensity.This paper is contributed in honor of my longtime friend, L.N.M. Duysens, who has carried still further the eminence of the Dutch tradition in biophysics.     

CYTOPLASMIC ORGANIZATION AND RHYTHMIC STREAMING IN GROWING BLADES OF CAULERPA PROLIFERA

Light- and electron-microscopic studies of the growing blades and their meristematic tips in Caulerpa prolifera have been correlated with time-lapse photographic studies. The growing blade may be divided into three zones based on the level of maturation. A “meristemplasm” is present at the tip of the growing blade and at sites of wounding. The cytoplasm of these growing regions has an abundant endoplasmic reticulum, Golgi bodies, amyloplasts, and nuclei, but lacks chloroplasts and a central vacuole. An intermediate zone lies between the white meristemplasm and the green, mature basal zone. The basal zone contains a parietal cytoplasm with organelles typical of the Chlorophyta and a dominant central vacuole. Two distinct systems of cytoplasmic streams occur in the basal zone and both contain packets of microtubules orientated parallel to the axis of the streams. As the blade matures and growth ceases, the dominant central vacuole forms up to the tip. In developing blades the tips become white in the absence of light as a result of basipetal movement of the chloroplasts. In plants kept on a 12-hr L: 12-hr D cycle, blade growth and chloroplast migration at the blade tip are rhythmic, and the peak occurs about 2-4 hr after initiation of the dark phase. Experiments are reported using continuous light or darkness after three 24-hr periods of 12-hr L: 12-hr D phasing.     

MITOTIC INDUCTION AND SYNCHRONIZED CELL DIVISION IN OEDOGONIUM CARDIACUM (HASS.) WITTR.

Waves of mitosis are induced in Oedogonium cardiacum grown under a 15 hr light/9 hr dark cycle. Mitosis starts 4 to 5 hr after the start of the dark period. Each mitotic stage has a high initial rate which plateaus at a lower rate for several additional hours. Partial synchronization of mitotic stages results from this induction of cell division. Mitotic divisions last 9 to 10 hr after induction. During the remainder of the 24-hr light/dark cycle, cells are in interphase. Along a filament, several dividing cells tend to be adjacent, with the most advanced stage in the cap cell. Progressively earlier mitotic stages are basal to the dividing cap cell. This pattern of mitotic division differs from the state in nature where only the cap cell usually divides. Chromosomes probably maintain a telophase arrangement during interphase. The suitability and advantages of Oedogonium, a haploid alga with sexual reproduction, as an experimental plant for cytological, developmental, biochemical, and genetic studies is pointed out.     

Carotenoids and Reaction Center II-D1 Protein in Light Regulation of the Photosynthetic Apparatus in Aphanocapsa*

A new cyanobacterial isolate, morphologically closely resembling Aphanocapsa, was characterized for its growth requirements, as well as pigmentation, photosynthetic activity and dynamics of the D1 protein in the reaction center (RC) of photosystem II (PSII). It was shown to be able to grow on glucose in the dark in the presence of DCMU. The cyanobacterium turned light yellow at high light intensity in the absence, and dark emerald green in high light in the presence of sublethal concentrations of the DCMU-type inhibitor atrazine. While total carotenoids per cell slightly decreased with increasing light intensity during growth, the cells still turned pale yellow due to decreased levels of chlorophyll and phycocyanin. In contrast to β-carotene, zeaxanthin and echinenone which decreased with increasing light intensity during growth, the carotenoid glycoside, myxoxanthophyll, continuously increased in concentration. Extremely high rates of light-saturated O₂ evolution were recorded for the high light cultures after a 0.5 h recovery period in the dark. The recovery measured after 2.5 h was shown to be less effective in darkness than in dim light and was prohibited by chloramphenicol. The degree of recovery was dependent on the light intensity during growth. A fast light intensity-dependent RC II-D1 protein turnover was found for the bleached yellow cells rich in myxoxanthophyll. The half-life of the RC II-D1 protein, plotted against the light intensity during growth and experimentation, yielded a curve the slope of which was considerably steeper for Aphanocapsa than for Anacystis. Apparently, the isolated strain of Aphanocapsa reacts more vigorously to changes in the environment than other strains tested and may, therefore, turn out to be a suitable organism in the attempt to elucidate the molecular mechanism of light intensity adaptation.     

STUDIES ON THE ECOLOGICAL AND PHYSIOLOGICAL SIGNIFICANCE OF AMPHICARPY IN GYMNARRHENA MICRANTHA (COMPOSITAE)

The 2 types of fruit (aerial and subterranean) borne by the dwarf desert annual Gymnarrhena micrantha were compared with regard to their responses to factors affecting their formation, dispersal, germination and seedling mortality. The 2 types of fruit differed markedly in several respects. In comparison with the subterranean fruits, the aerial ones are much smaller and more numerous, but the formation of the inflorescence in which they develop is more dependent on a favorable supply of soil moisture. The aerial fruits are dispersed by wind, after becoming detached by a complex series of hygroscopic movements which involve several organs and tissues, while the subterranean fruits never leave the dead parent plant, germinating right through its tissues. Germination of the subterranean fruits starts after a shorter incubation period and is less temperature-dependent in both light and dark. Light stimulated germination of both types of fruit, increasing their germination rates and final percentages, but not affecting the duration of the incubation period. In the subterranean fruits, the rate of germination was equally stimulated by light over the entire temperature range, with a well-defined optimum at 15 C in both light and dark. In the aerial fruits, the same optimum was found only in the light, rates in darkness increasing with decreasing temperatures. In the aerial fruits, alternations of light and dark were more favorable to germination than either continuous light or dark, the full effect being obtained with a single 8-hr or 16-hr light period, provided it was preceded by 16 or 8 hr of darkness, respectively. Similar reactions to combinations of light and dark were not observed in the subterranean fruits. Seedlings developing from the subterranean fruits were much larger, but grew at a relatively much slower rate than those from aerial fruits. The former were distinctly more tolerant of unfavorable soil-moisture regimes, such as low moisture supply and drought. It was concluded that the 2 types of fruit serve 2 distinct functions in the biology of the plant. The aerial fruits are adapted to the function of increasing the distribution of the species within suitable habitats, while the subterranean fruits are adapted to increasing the probability of the survival of the species.     

Einfluss verschiedener Lichtwellenlängen auf die Zusammensetzung von Chlorella in Glucosekultur bei gehemmter Photosynthese

Summary Increasing blue light intensity inhibits the growth of Chlorella pyrenoidosa in glucose culture in which photosynthesis is blocked by DCMU, whereas red light supports growth which is the same as or better than that in dark controls.The action spectrum of light induced protein synthesis from exogenous glucose (photosynthesis inhibited, blue light addition resulting in growth >90% of the dark control) shows only one broad maximum at 450–490 nm which resembles the absorption spectrum of carotenoids.     

Opposite response groups of short-day plants to the spectral composition of the main light period and to end-of-day red or far-red irradiations

Two response groups were found among short-day plants grownin blue green-houses having a high or low far-red admixture.In one group flowering was promoted by low far-red and delayedby high far-red; the other group reacted in an opposite manner.In plants grown under 8-hr day and 16-hr night regimes, floweringin the low far-red group was promoted by red and inhibited byfar-red illumination preceding the 16-hr nights; in the highfar-red group flowering was promoted by far-red and inhibitedby red illumination preceding the dark periods. In both groupsflowering was inhibited by red light applied in the middle ofthe dark period. (Received March 18, 1974; )