Mutants ofPhycomyceswith Decreased Gallic Acid Content

Weinkove, D., Poyatos, J. A., Greiner, H., Oltra, E., Avalos, J., Fukshansky, L., Barrero, A. F., and Cerdá-Olmedo, E. 1998. Mutants ofPhycomyceswith decreased gallic acid content.Fungal Genetics and Biology25, 196–203. Most plants and some fungi accumulate phenols. Two hydroxybenzoic acids, gallic and protocatechuic acids, are abundant in the giant sporangiophores of the zygomycetePhycomyces blakesleeanus,much more so than in the basal mycelium or the culture medium. The actual concentrations vary with illumination, age of the culture, and composition of the medium. We devised a simple screening procedure to isolatehbamutants whose sporangiophores contained less gallic acid than the wild type. The most useful mutant had very low concentrations of hydroxybenzoic acids in the sporangiophores, but about the same as the wild type in the basal mycelium and the medium. The mutant was only slightly different from the wild type in growth and morphology. Mutant and wild-type sporangiophores grew away from ultraviolet C sources (260 nm) equally well. Contrary to previous conjectures, ultraviolet tropism does not depend on the ultraviolet absorption of gallic acid or other free hydroxybenzoic acids in the sporangiophore. Against expectations, phenols did not impair DNA extraction: sporangiophores produced better DNA preparations than basal mycelia and thehbamutant only slightly better than the wild type.     

Parameters governing gravitropic response of sporangiophores inPhycomyces blakesleeanus

The sporangiophores (spphs) of the fungusPhycomyces blakesleeanus bend upward in a negative gravitropic response when placed in a horizontal position in the dark. The spphs of a hypergravitropic mutant showed higher bending rate and shorter latency period than those of the wild type. In both strains, spphs of smaller diameter had higher bending rates. No significant differences were found between the wild type and the mutant and between the thin spphs and the spphs of standard diameter in respect to their elongation rates. Phototropic rate was also the same between the wild type and the mutant. Parameters influencing the gravitropic response such as diameter of the spph, absolute elongation rate, and ratio of differential growth between the upper and the lower sides of the extension zone of spph were investigated to elucidate the kinetics of bending in the mutant. The results demonstrate that the rapid gravitropic response in the mutant is due to its higher (about 5–6 times) differential-growth rate compared with the wild type.     

Phycomyces: distribution of growth velocities in the growing zone

Distribution of growth velocities in the growing zone of stage IVb Phycomyces sporangiophores was measured by photographing the growing zone after dusting it with starch grains. When the entire growing zone is fully dark-adapted to red light and then subjected to a saturating white light stimulus, the entire growing zone increases in growth rate. When the growing zone is partially light-adapted, again the entire growing zone responds when subjected to a saturating white light stimulus but to a lesser degree than the fully dark-adapted sporangiophore. Phototropic mutants of class 1 and class 2 show a distribution of growth in the growing zone similar to wild type sporangiophores both during steady-state growth and during light-stimulated growth.     

Interaction between gravitropism and phototropism in sporangiophores of Phycomyces blakesleeanus

The interaction between gravitropism and phototropism was analyzed for sporangiophores of Phycomyces blakesleeanus. Fluence rate-response curves for phototropism were generated under three different conditions: (a) for stationary sporangiophores, which reached photogravitropic equilibrium; (b) for sporangiophores, which were clinostated head-over during phototropic stimulation; and (c) for sporangiophores, which were subjected to centrifugal accelerations of 2.3g to 8.4g. For blue light (454 nm), clinostating caused an increase of the slope of the fluence rate-response curves and an increase of the maximal bending angles at saturating fluence rates. The absolute threshold remained, however, practically unaffected. In contrast to the results obtained with blue light, no increase of the slope of the fluence rate-response curves was obtained with near-ultraviolet light at 369 nm. Bilateral irradiation with near-ultraviolet or blue light enhanced gravitropism, whereas symmetric gravitropic stimulation caused a partial suppression of phototropism. Gravitropism and phototropism appear to be tightly linked by a tonic feedback loop that allows the respective transduction chains a mutual influence over each other. The use of tropism mutants allowed conclusions to be drawn about the tonic feedback loop with the gravitropic and phototropic transduction chains. The results from clinostating mutants that lack octahedral crystals (implicated as statoliths) showed that these crystals are not involved in the tonic feedback loop. At elevated centrifugal accelerations, the fluence-rate-response curves for photogravitropic equilibrium were displaced to higher fluence rates and the slope decreased. The results indicate that light transduction possesses a logarithmic transducer, whereas gravi-transduction uses a linear one.     

Growth-rate adaptation of Phycomyces sporangiophores to partial depletion of oxygen

The growth rate of Phycomyces blakesleeanus sporangiophores was found to be very sensitive to sudden changes in the oxygen concentration. A change from 20% to 15% oxygen elicits a transient decrease in the growth rate which returns to normal 10 min after altering the concentration. After a step change to 10% oxygen, the growth rate shows two minima at 6–8 and 30–35 min and it reaches about 80% of its original value 50 min after this change. A threshold curve for this negative growth response shows that sporangiophores begin to sense a decrease in the oxygen concentration from 20% to 17%. Seven phototropically abnormal mutants with defects in the genes madA to madG were tested for the oxygen response. Two strains, C149madD120 and C316madF48, were found to have recoveries different from those of the wild type after step changes from 20% to 10% oxygen.     

Blue-light promotion of flowering is absent in hy4 mutants of Arabidopsis

Loss of a blue-light photoreceptor in the hy4 mutants of Arabidopsis thaliana (L.) Heynh substantially delayed flowering (>100 d to flower vs. 40–50 d), especially with blue light exposure from lamps lacking much red (R) and/or far-red (FR) light. Red night breaks were promotory but flowering was still later for the hy4-101 mutant. However, with exposure to light from FR-rich lamps, flowering of all mutants was early and no different from the wild type. Thus, flowering of Arabidopsis involves a blue-light photoreceptor and other, often more effective photoreceptors. The latter may involve phytochrome photoresponses to R and FR, but with little or no phytochrome response to blue wavelengths.Abbreviations HIR high irradiance response - FR far-red - R red - WT wild type     

OCTAHEDRAL CRYSTALS IN PHYCOMYCES. II

"Phycomyces blakesleeanus" sporangiophores contain octahedral crystals throughout their cytoplasm and vacuole. More octahedral crystals were found in the wild-type strain G5 (+) than in the β-carotene-deficient mutant C5 (-), and much more than in the mutant C141 (-), which is sensitive to only high light intensity. In the wild type, the number of crystals per sporangiophore increased until the sporangiophore reached stage IV, and then decreased. Stage I contained the most crystals per unit volume. Cultures grown in darkness had the maximum number of crystals. Under high light intensity, there was an overall reduction of crystals. The crystals are regular octahedrons. The crystals were isolated from the sporangiophores by a method of sucrose density-gradient centrifugation. They contain nearly 95% protein, are stable in organic solvents, but can be solubilized in buffer solution above pH 9.5 and below 2.5. The crystals weakly fluoresce with an emission peak at 540 nm, which is affected by irradiation with white light. Absorption spectra of freshly prepared crystals show absorption maxima around 265–285 nm, 350–380 nm, and 450–470 nm. These absorption peaks for the crystals are close to those of the phototropic and light-growth action spectra. These data suggest that the crystals may contain a flavoprotein which may be the photoreceptor pigment of "Phycomyces".     

Action spectra of the light-growth response in three behavioral mutants of Phycomyces

Null-point action spectra of the light-growth response were measured for three mutants of Phycomyces blakesleeanus (Burgeff) and compared with the action spectrum of the wild type (WT). The action spectrum for L150, a recently isolated night-blind mutant, differs from the WT spectrum. The L150 action spectrum has a depression near 450 nm and small alterations in its long-wavelength cutoff, the same spectral regions where its photogravitropism action spectrum is altered. This indicates that the affected gene product influences both phototropism and the light-growth response. For L85, a hypertropic (madH) mutant, the light-growth-response action spectrum is very similar to that of WT even though the photogravitropism action spectrum of L85 has been shown previously to be altered in the near-UV region. The affected gene product in this mutant appears to affect phototropic transduction but not light-growth-response transduction. The action spectrum of C110, a stiff (madE) mutant, differs significantly from the WT spectrum near 500 nm, the same spectral region where sporangiophores of madE mutants have been shown to have small alterations in second-derivative absorption spectra. This indicates that the madE gene product may be physically associated with a photoreceptor complex, as predicted by system-analysis studies.Abbreviations SE standard error of the mean - UV ultraviolet light - Wt wild type I dedicated to Masaki Furuya on the occasion of his 65th birthdayWe thank H. Reiner Schaefer for performing some of the experiments and for help in data analysis, David Durant for computer programming, and Benjamin Horwitz for helpful discussions. This work was supported by a grant from the National Institutes of Health (GM29707) to E.D. Lipson.     

Developmental stage-dependent response ofPilobolus crystallinus sporangiophores to gravitative and centrifugal stimulation

Gravitropic response of sporangiophores ofPilobolus crystallinus was studied by successive microscopic observation of the sporangiophores horizontally placed in the dark (red light) and by analysis of sporangiophore response to centrifugal stimulation. Negative tropism against the gravitative and also centrifugal stimulation was found only in mature sporangiophores after development of sporangium and after the resumption of elongation beneath the fully-developed subsporangial vescle, but there was no response in younger sporangiophores, implying that the gravitative perception system of the sporangiophores is dependent on their developmental stages.     

Phycomyces: Phototropism and light-growth response to pulse stimuli

The relationship between phototropism and the light-growth response of Phycomyces blakesleeanus (Burgeff) sporangiophores was investigated. After dark adaptation, stage-IVb sporangiophores were exposed to short pulses of unilateral light at 450 nm wavelength. The sporangiophores show a complex reaction to pulses of 30 s duration: maximal positive bending at 3·10^-4 and 10^-1 J m^-2, but negative bending at 30 J m^-2. The fluence dependence for the light-growth response also is complex, but in a different way than for phototropism; the first maximal response occurs at 1.8·10^-3 J m^-2 with a lesser maximum at 30 J m^-2. A hypertropic mutant, L85 (madH), lacks the negative phototropism at 30 J m^-2 but gives results otherwise similar to the wild type. The reciprocity rule was tested for several combinations of fluence rates and pulse durations that ranged from 1 ms to 30 s. Near the threshold fluence (3·10^-5 J m^-2), both responses increase for pulse durations below 67 ms and both have an optimum at 2 ms. At a fluence of 2.4·10^-3 J m^-2, both responses decrease for pulse durations below 67 ms. The hypertropic mutant (madH), investigated for low fluence only, gave similar results. In both strains, the time courses for phototropism and light-growth response, after single short pulses of various durations, show no clear correlation. These results imply that phototropism cannot be caused by linear superposition of localized light-growth responses; rather, they point to redistribution of growth substances as the cause of phototropism.     

Effects of microbeam light on growth and phototropism ofPilobolus crystallinus sporangiophores

A small blue-light beam (50 μm in diam) was used to examine light-growth response and phototropism inPilobolus crystallinus sporangiophores. Continuous irradiation by microbeam of a region 100–150 μm from the apex promoted the growth of a dark-adapted sporangiophore for about 15 min after a lag period of 1–2 min. After the promotion, the growth rate fell below that before the irradiation. Irradiation of the apex of sporangiophore slightly promoted the growth but strongly inhibited the growth after the promotion. A smaller light beam (10 μm in diam) applied continuously at grazing incidence along one side of the sporangiophore caused bending toward the shaded side, implying that the irradiated side grew more rapidly than the shaded side and that the lens effect is involved in the phototropism of young sporangiophores ofP. crystallinus. The involvement of the lens effect was confirmed by the fact that a carotenoid-less mutant was 1.5–2 times more sensitive to unilateral blue light than the wild type, probably because of a smaller intracellular light attenuation during passage through the mutant cell.     

Carotenes and Retinal in Phycomyces Mutants

Three different types of beta-carotene mutants of Phycomyces have been studied. In 2 mutants (Type I) beta-carotene is still the principal carotene but scaled down or up relative to wild type. The carotene mixture of 2 mutants (Type II) consists mainly of phytoene and phytofluene. In Type III (2 mutants) beta-carotene is replaced by lycopene.The examination of the mutants reveals that the receptor pigment is very likely neither beta-carotene nor retinal. Transmission spectra through the growing zone of live sporangiophores of 1 of these mutants which contains less than one-thousandth of the beta-carotene content of wild type show that the receptor pigment extinction is less than 0.003 at its maximum.     

Isolation and Characterization of a Xanthophyll Aberrant Mutant of the Green Alga Nannochloropsis oculata

Novel mutants (xan1 and xan2) of the unicellular green alga Nannochloropsis oculata are impaired in xanthophyll biosynthesis, thereby producing aberrant levels of xanthophylls. High-performance liquid chromatography (HPLC) analysis revealed that the xan1 and xan2 mutants have double the violaxanthin (V) content, but have significantly decreased lutein content in their cells compared to the wild type. Furthermore, these mutants contain two to three times more zeaxanthin than the wild type under low light (LL) growth conditions. However, this xanthophyll aberration in N. oculata did not affect the normal growth and the major cellular chemical composition of the xan1 strain. The xanthophyll pool size of the LL-grown mutant was 1.8-fold greater than that of the wild type. Under high light (HL) growth conditions, V content was substantially decreased in both the mutant and wild types because of the epoxidation state of the xanthophylls. Under LL growth conditions, the deepoxidation states of the xanthophyll pool sizes were 0.1 and 1.2 in the wild type and the mutant, respectively. However, the deepoxidation states of the xanthophyll pool sizes were 0.78 in the wild type and 0.87 in the mutant under HL growth conditions. We observed that the level of one of the commercially important xanthophylls, zeaxanthin, was higher in the mutant than in the wild type under all culture conditions. This mutant is discussed in terms of its commercial value and potential utilization by the algal biotechnology industry for the production of zeaxanthin.     

Vegetative regeneration on sexual organs inPhycomyces blakesleeanus

Phycomyces blakesleeanus produced an abundance of sexual organs when two mating types met on solid medium, but only about 14.7% of the sexual organs developed to the final stages. On the sexual organs showing arrested development, vegetative hyphae or dwarf sporangiophores (microphores) often regenerated. This vegetative regeneration was accelerated when the paired and looped progametangia were isolated from mycelia, when the counterparts of the progametangial cells constructing the loop were surgically incised, and whenPhycomyces was mated at high temperature (25–27°C). A leaky-carotenogenic mutant, whose sexual reaction was imperfect and arrested at an intermediate stage even when mated with the wild type, also regenerated hyphae with a high frequency on these arrested intermediate organs. The vegetative regeneration seems to result from interruption of a cell-to-cell recognition system between cells of different mating type, which is believed to be essential for the mating process of this fungus in addition to the pheromonal actions.     

Blue Light Reception in Phycomyces: Red Light Sensitization in madC Mutants

Sporangiophores of the zygomycete fungus Phycomyces blakesleeanus are sensitive to near UV and blue light. The quantum effectiveness of yellow and red light is more than 6 orders of magnitude below that of near UV or blue light. Phototropism mutants with a defect in the gene madC are about 10⁶ times less sensitive to blue light than the wild type. These mutants respond, however, to yellow and red light when the long wavelength light is given simultaneously with actinic blue light. In the presence of yellow or red light the photogravitropic threshold of madC mutants is lowered about 100-fold though the yellow and the red light alone are phototropically ineffective. A step-up of the fluence rate of broad-band red light (> 600 nm) from 6 × 10^?3 to 6W m^?2 elicits, in mutant C 148 madC, a transient deceleration of the growth rate. The growth rate of the wild type is not affected by the same treatment. The results are interpreted in terms of a red light absorbing intermediate of the blue light photoreceptor of Phycomyces. The intermediate should be short-lived in the wild type and should accumulate in madC mutants.     

Complementation betweenPhycomyces mutants of mating type (+) with abnormal phototropism

Summary Twelve mutants ofPhycomyces blakesleeanus with defects in sporangiophore phototropism (genotypemad) were obtained from a wild type of the (+) mating type by mutagenesis with nitrosoguanidine. These mutants were tested for genetic complementation against standard (+)mad mutants derived from sexual crosses between the isogenic (+) strain and established (-)mad mutants (Ootaki et al., 1974; Eslava et al., 1976). Heterokaryons for complementation tests were obtained by grafting stage I sporangiophores. The (+) mutants were also investigated for their sensory responses such as photoinduction of sporangiophores and avoidance. The mutants were grouped into two classes, based on the phenotypic classification scheme of Bergman et al. (1973). There were eleven class 1.2 mutants and one class 2 mutant. Complementation tests revealed that all eleven class 1.2 mutants carry the genemadC and the class 2 mutant carriesmadD. There was no evidence that any were double mutants. These results are consistent with the phenotypic classification and with the complementation results of themad mutants of the (-) mating type.     

End-product regulation of carotenogenesis in Phycomyces

Wild-type Phycomyces blakesleeanus synthesizes the yellow pigment, beta-carotene. Colour mutants exhibit various alterations in the biosynthesis of beta-carotene or in its regulation. The presence of certain chemicals in the medium stimulates carotenogenesis in the wild type. We attribute different mechanisms of action to agents which stimulate or fail to stimulate different sets of mutants; this is the case of retinol and dimethyl phthalate. Dimethyl phthalate and veratrol are active on the same mutants, and therefore are likely to act in the same way. The main regulation of carotenogenesis, end-product inhibition, does not operate in the mutants of certain genes; these mutants are indifferent to retinol. By using a collection of retinoids we conclude that their action depends on their structural similarity to a part of the beta-carotene molecule. From these and other observations we propose that end-product inhibition of the pathway is mediated by a complex of beta-carotene and two gene products and that the retinoids compete with beta-carotene and prevent end-product inhibition.Deceased     

Pigments associated with the flagellum ofEuglena gracilis

The pigments associated with the flagellum of the phytoflagellateEuglena gracllis were characterized by HPLC. The pigment pattern of the wild-type strain was compared with a set of white mutants which did not display phototaxis and photoaccumulation in response to blue light. Flagella of the wild type contained FMN and FAD. Two mutants which lacked the stigma but retained a small paraxonemal body (PAB) contained less flavins. The whiteEuglena mutant FB, which retained a residual stigma and also a PAB, and the white phytoflagellateAstasia longa, a close relative ofEuglena, had normal amounts of flagellar flavins. Cells and flagella ofEuglena wild type contained an unldentified pterin-like pigment, called Pt₁₆, which was substantially reduced inAstasia and theEuglena mutants. A third pigment, designated P₅₂₈ with major absorption at 528 nm and fluorescence emission at 550 nm was present mainly in flagella. The association of the three pigment types with flagella and their respective alterations in the white strains indicates their possible role in photoreception. Dedicated to Pill-Soon Song on the occasion of his 60th birthday.     

High-and low-intensity photosystems in Phycomyces phototropism: Effects of mutations in genes madA,madB, and madC

Sporangiophores of Phycomyces blakesleeanus Burgeff that have been grown in darkness and are then suddenly exposed to unilateral light show a two-step bending response rather than a smooth, monotonic response found in light-adapted specimens (Galland and Lipson, 1987, Proc. Natl. Acad. Sci. USA 84, 104–108). The stepwise bending is controlled by two photosystems optimized for the low-and high-intensity ranges. These two photosystems have now been studied in phototropism mutants with defects in genes madA, madB, and madC. All three mutations raise the threshold of the low-intensity (low-fluence) photosystem by about 10⁶-fold and that of the high-intensity (high-fluence) system by about 10³-fold. Estimates for the light-adaptation time constants of the low-and high-intensity photosystems show that the mutants are affected in adaptation. In the mutants, the light-adaptation kinetics are only slightly affected in the low-intensity photosystem but, for the high-intensity photosystem, the kinetics are considerably slower than in the wild type.Abbreviations WT wild type     

A new gene (madI) involved in the phototropic response of Phycomyces

Summary Only eight genes are known to be involved in the phototropic response of Phycomyces (madA-H). Mutants affected in these genes have played a major role in the analysis of photosensory transduction processes in this system. A set of new mutants isolated by Alvarez et al. (1989) that are unable to bend towards dim unilateral blue light were studied by complementation and recombination. Two of these mutants have mutations in madE, one has a mutation in madF and one is a double madE madF mutant. The three remaining mutants tested did not complement each other and showed positive complementation with strains carrying mutations in the genes madA, madB, and madC, indicating that they carried mutations in a new gene designated madI. Recombination analysis showed that madI is unlinked to madA, madB and madC.