The Phytochrome-Deficient pcd1 Mutant of Pea Is Unable to Convert Heme to Biliverdin IX[alpha].

We isolated a new pea mutant that was selected on the basis of pale color and elongated internodes in a screen under white light. The mutant was designated pcd1 for phytochrome chromophore deficient. Light-grown pcd1 plants have yellow-green foliage with a reduced chlorophyll (Chl) content and an abnormally high Chl a/Chl b ratio. Etiolated pcd1 seedlings are developmentally insensitive to far-red light, show a reduced response to red light, and have no spectrophotometrically detectable phytochrome. The phytochrome A apoprotein is present at the wild-type level in etiolated pcd1 seedlings but is not depleted by red light treatment. Crude phytochrome preparations from etiolated pcd1 tissue also lack spectral activity but can be assembled with phycocyanobilin, an analog of the endogenous phytochrome chromophore phytochromobilin, to yield a difference spectrum characteristic of an apophytochrome-phycocyanobilin adduct. These results indicate that the pcd1-conferred phenotype results from a deficiency in phytochrome chromophore synthesis. Furthermore, etioplast preparations from pcd1 seedlings can metabolize biliverdin (BV) IX[alpha] but not heme to phytochromobilin, indicating that pcd1 plants are severely impaired in their ability to convert heme to BV IX[alpha]. This provides clear evidence that the conversion of heme to BV IX[alpha] is an enzymatic process in higher plants and that it is required for synthesis of the phytochrome chromophore and hence for normal photomorphogenesis.

Phytochrome, Gibberellins, and Hypocotyl Growth (A Study Using the Cucumber (Cucumis sativus L.) long hypocotyl Mutant).

The possible involvement of gibberellins (GAs) in the regulation of hypocotyl elongation by phytochrome was examined. Under white light the tall long hypocotyl (lh) cucumber (Cucumis sativus L.) mutant, deficient in a type B-like phytochrome, shows an increased "responsiveness" (defined as response capability) to applied GA4 (the main endogenous active GA) compared to the wild type. Supplementing far-red irradiation results in a similar increase in responsiveness in the wild type. Experiments involving application of the precursor GA9 and of an inhibitor of GA4 inactivation suggest that both the GA4 activation and inactivation steps are phytochrome independent. Endogenous GA levels of whole seedlings were analyzed by combined gas chromatography-mass spectrometry using deuterated internal standards. The levels of GA4 (and those of GA34, the inactivated GA4) were lower in the lh mutant under low-irradiance fluorescent light compared with the wild type, similar to wild type under higher irradiance light during the initial hypocotyl extension phase, and higher during the phase of sustained growth, in which extension involved an increase in the number of cells in the upper region. In all cases, growth of the lh mutant was more rapid than that of the wild type. It is proposed that GA4 and phytochrome control cell elongation primarily through separate mechanisms that interact at a step close to the terminal response.

New lv Mutants of Pea Are Deficient in Phytochrome B.

The lv-1 mutant of pea (Pisum sativum L.) is deficient in responses regulated by phytochrome B (phyB) in other species but has normal levels of spectrally active phyB. We have characterized three further lv mutants (lv-2, lv-3, and lv-4), which are all elongated under red (R) and white light but are indistinguishable from wild type under far-red light. The phyB apoprotein present in the lv-1 mutant was undetectable in all three new lv mutants. The identification of allelic mutants with and without phyB apoprotein suggests that Lv may be a structural gene for a B-type phytochrome. Furthermore, it indicates that the lv-1 mutation results specifically in the loss of normal biological activity of this phytochrome. Red-light-pulse and fluence-rate-response experiments suggest that lv plants are deficient in the low-fluence response (LFR) but retain a normal very-low-fluence-rate-dependent response for leaflet expansion and inhibition of stem elongation. Comparison of lv alleles of differing severity indicates that the LFR for stem elongation can be mediated by a lower level of phyB than the LFR for leaflet expansion. The retention of a strong response to continuous low-fluence-rate R in all four lv mutants suggests that there may be an additional phytochrome controlling responses to R in pea. The kinetics of phytochrome destruction and reaccumulation in the lv mutant indicate that phyB may be involved in the light regulation of phyA levels.

A Temporarily Red Light-Insensitive Mutant of Tomato Lacks a Light-Stable, B-Like Phytochrome.

We have selected four recessive mutants in tomato (Lycopersicon esculentum Mill.) that, under continuous red light (R), have long hypocotyls and small cotyledons compared to wild type (WT), a phenotype typical of phytochrome B (phyB) mutants of other species. These mutants, which are allelic, are only insensitive to R during the first 2 days upon transition from darkness to R, and therefore we propose the gene symbol tri (temporarily red light insensitive). White light-grown mutant plants have a more elongated growth habit than that of the WT. An immunochemically and spectrophotometrically detectable phyB-like polypeptide detectable in the WT is absent or below detection limits in the tri1 mutant. In contrast to the absence of an elongation growth response to far-red light (FR) given at the end of the daily photoperiod (EODFR) in all phyB-deficient mutants so far characterized, the tri1 mutant responds to EODFR treatment. The tri1 mutant also shows a strong response to supplementary daytime far-red light. We propose that the phyB-like phytochrome deficient in the tri mutants plays a major role during de-etiolation and that other light-stable phytochromes can regulate the EODFR and shade-avoidance responses in tomato.

Red light-induced appearance of phosphotyrosine-like epitopes on nuclear proteins from pea (Pisum sativum L.) plumules.

As assayed by western blot analysis, red light induces the appearance of epitopes recognized by anti-phosphotyrosine antibodies in several pea nuclear proteins. The immunostaining is blocked by preadsorbing the antibodies with phosphotyrosine but not by preadsorbing them with phosphoserine or phosphothreonine. This light response is observed whether the red light irradiation is given to pea plumules or nuclei isolated from the plumules. The red-light-induced response seen in plumules is reversible by a subsequent far-red-light irradiation, indicating that the likely photoreceptor for this response may be phytochrome. By immunoblot analysis pea phytochrome A, but not phytochrome B, can be detected in proteins extracted from pea nuclear chromatin-matrix preparations. Phytochrome A and the protein bands immunostained by anti-phosphotyrosine antibodies can be solubilized from unirradiated pea chromatin by 0.3 M NaCl, but irradiating this preparation with red light does not induce the appearance of phosphotyrosine-like epitopes in any nuclear proteins. These results suggest that the association of phytochrome with purified pea nuclei is such that its conversion to the far-red light-absorbing form can induce a post-translational epitope change in nuclear proteins in vivo.

Loading and localization of Fluo-3 and Fluo-3/AM calcium indicators in sinapis alba root tissue.

Stimulus-induced changes in free cytosolic Ca2+ in different types of plant cells have been monitored with the aid of fluorescent calcium indicator dyes. However, there is no simple and convenient method for introducing these dyes into the plant cell cytoplasm. This paper reports tests of different procedures for loading either free fluorescent dyes or their acetoxymethyl esters (Fluo-3 and Fluo-3/AM, respectively) into Sinapis alba root tissue. Loading of Fluo-3 was pH and temperature dependent. Moreover, in the presence of beta-escin (saponin) in the loading medium very high fluorescent signals in root tissues were observed. The highest signals were recorded when tissue was loaded in a medium containing 0.1% beta-escin, at pH 5.0 and 30 degrees C. Only very weak fluorescence signals were found in mustard roots loaded with Fluo-3/AM. Acidity and temperature of the medium had no significant effect on the process. However, addition of eserine, a cholinesterase inhibitor led to a dramatic increase in fluorescence in the root cells. On the basis of these observations rapid and efficient methods of loading both Fluo-3 and Fluo-3/AM into mustard root tissues are proposed.

Ferret respiratory diseases.

Ferret behavior often brings them into close contact with potential respiratory pathogens and traumatic insults. Although respiratory disease accounts for a small percentage of cases, they are usually dramatic. Acute and chronic conditions occur, and many lesions are confined to the upper or lower respiratory tree but may not involve both. Pathogens such as influenza A account for a large percentage of upper respiratory infections and often mirror the "flu" season of humans. Traumatic insults to the head and chest are relatively common and account for many veterinary visits. Numerous diseases affecting the upper and lower respiratory systems are discussed, with suggestions for diagnostics and therapies.

Aspects of phytochrome decay in etiolated seedlings under continuous Illumination.

The rate of total phytochrome decay in the dicotyledons Amaranthus caudatus, Mirabilis jalapa and Pisum sativum under continuous illumination with red, incandescent, and blue light depends on the PFR/Ptotal maintained by each source. Amaranthus is an exception to this in that there is a deviation from firstorder decay kinetics under continuous illumination with incancdescent light. This deviation is probably not related to the chlorophyll present in the Amaranthus sample since chlorophyll-rich Pisum buds have the same phytochrome decay rate as epicotyl tissue under continuous incandescent light. Reports of a prolonged lag phase before the onset of first-order decay kinetics of phytochrome in Pisum have not been confirmed and the small lag phase observed in the present work can be accounted for by the time required to attain the PFR/Ptotal ratio characteristic of blue light in a carotenoid rich tissue. In the monocotyledon, Avena sativa, and perhaps monocotyledons in general, decay rate is maximal at a low PFR concentration and the decay curve is the same under continuous red, incandescent and blue light. This dicotyledon/monocotyledon difference with respect to saturation of phytochrome decay does not correlate with the other dicotyledon/monocotyledon difference, the presence or absence of dark reverions of PFR to PR, since the dicotyledons Amaranthus and Mirabilis that lack reversion still show no saturation of decay. Possible growth control by the PFR/Ptotal ratio is discussed in relation to environmental changes in light quality.

Blue light is required for survival of the tomato phytochrome-deficient aurea mutant and the expression of four nuclear genes coding for plastidic proteins.

When dark-grown aurea mutant tomato seedlings which lack more than 95% of the phytochrome present in isogenic wild-type seedlings are kept in white or blue light, four nuclear-encoded transcripts coding for plastidic proteins (the light-harvesting chlorophyll a/b-binding protein of photosystem I and II [cab-PSII], plastocyanin and subunit 2 of photosystem I) are present in comparable amounts. These transcript levels in red light are strongly reduced in aurea seedlings when compared with those of wild type. Thus, blue light is required for normal expression of these genes in the mutant, while red light alone is not sufficient. Red light-grown aurea seedlings are very sensitive to blue light, even 10 minutes of blue light every day suffices to cause a measurable increase in cab-PSII transcript level. The action of blue light on the expression of cab-PSII in the mutant is under phytochrome control. After 8 days of blue light, phytochrome is almost as effective in inducing cab-PSII mRNA as in the isogenic wild type, whereas after 8 days of red light, only a small phytochrome response was observed in the mutant. It is concluded that blue light sensitizes the mutant to the residual phytochrome which allows normal gene expression and survival of the mutant under daylight conditions.

Photomanipulation of phytochrome in lettuce seeds.

Seeds of lettuce (Lactuca sativa L. cv. Grand Rapids) were imbibed and given either short irradiation with red or far red light prior to drying or dried under continuous red or far red light. Seeds treated with either short or continuous red germinate in darkness, whereas seeds treated with either short or continuous far red require a short exposure to red light, after a period of imbibition, to stimulate germination. Irradiation of dry red seeds with far red light immediately before sowing results in a marked inhibition of germination. This result was predicted since far red-absorbing form phytochrome can be photoconverted to the intermediate P650 (absorbance maximum 650 nm) in freeze-dried tissue. A similar far red treatment to continuous red seeds is less effective and it is concluded that in these seeds a proportion of total phytochrome is blocked as intermediates between red-absorbing and far red-absorbing form phytochrome, which only form the far red-absorbing form of phytochrome on imbibition. The inhibition of dry short red seeds by far red light can be reversed by an irradiation with short red light given immediately before sowing, confirming that P650 can be photoconverted back to the far red-absorbing form of phytochrome. The results are discussed in relation to seed maturation (dehydration) on the parent plant.

Effects of filipin and steroids on phytochrome pelletability.

Red light given to dark-grown etiolated leaves of Hordeum vulgare L. in vivo or to crude homogenates increases the phytochrome content of the 20,000 g pellet on centrifugation. The steroids cholesterol and stigmasterol inhibit this red light-induced phytochrome pelletability. Filipin (a polyene antibiotic, which is known to combine with steroids) inhibits red light-induced phytochrome pelletability. Filipin and steroids at the appropriate concentration applied together prevent the inhibition caused by either when applied alone. These results suggest that phytochrome may bind to a steroid component of membranes. The phospholipid phosphatidyl choline dipalmitoyl has no effect on red light-induced phytochrome pelletability. Preliminary evidence demonstrates a direct association of soluble phytochrome in its active form and steroids. The physiological significance of red light-induced pelletability and the primary mechanism of phytochrome action are discussed in terms of a hypothetical steroid-binding site.

Ion fluxes and phytochrome protons in mung bean hypocotyl segments: I. Fluxes of potassium.

K(+) [(86)Rb(+)] uptake by Phaseolus aureus Roxb. hypocotyl segments cut immediately below the hook is inhibited by the active form of phytochrome (Pfr). Short load-short wash experiments indicate that the inhibition of uptake occurs across the plasmalemma. A maximal inhibition of short term uptake occurs in 10 to 50 millimolar KCI. Low temperature had only a small effect on influx and the inhibition of influx from 50 millimolar KCI. A consideration of the electrochemical gradient for K(+) suggests that passive K(+) fluxes may predominate under these conditions. Red light induces small depolarizations of membrane potential in subhook cells. Far red light antagonizes this effect. Pfr inhibits efflux of K(+)[(86)Rb(+)] from subhook segments. This effect is also relatively insensitive to low temperature. This inhibition of efflux may reflect inhibition of a K(+) -K(+) exchange process, or reduced passive permeability of the plasmalemma to K(+). In contrast, Pfr enhances short term uptake of K(+)[(86)Rb(+)] in apical hypocotyl hook segments of Phaseolus aureus Roxb. Short load-short wash experiments indicate that fluxes across the plasmalemma are modified by Pfr. A maximal enhancement of short term influx occurs in 50 millimolar KCI. Influx and the red light enhancement of influx from 50 millimolar KCI are relatively insensitive to low temperature. Pfr also enhances efflux of K(+)[(86)Rb(+)] from preloaded apical hook segments. This increased influx may reflect enhancement of a K(+) -K(+) exchange process or increased passive permeability of the plasmalemma to K(+).

Ion Fluxes and Phytochrome Protons in Mung Bean Hypocotyl Segments: II. Fluxes of Chloride, Protons, and Orthophosphate in Apical and Subhook Segments.

The active form of phytochrome (Pfr) decreased CI(-) uptake by subhypocotyl hook segments of Phaseolus aureus Roxb. and increased uptake by apical segments. Pfr had similar effects on Pi [(32)Pi] uptake. Modulations of Pi [(32)Pi] uptake were detectable 10 minutes following photoconversion. Pfr may modulate Pi influx across the plasmalemma. Pfr inhibited H(+) extrusion by subhook segments and enhanced extrusion by apical hook segments. No rapid effects on H(+) extrusion were found. Phytochrome may regulate a K(+) -H(+) exchange process. The differential responses of the two regions of the hypocotyl are discussed with respect to Pfr-mediated changes in growth and development.