The Photobiology of Fern Gametophytes: I. THE PHENOMENON OF RED/FAR-RED AND YELLOW/F AR-RED PHOTOREVERSIBILITY

This paper shows that the hypothetical yellow-light-absorbingpigment P₅₈₀ is an unnecessary postulate for describing thephotobiology of fern filaments. The existence of P₅₈₀ was originallypredicted on the basis of action and response spectra that assumedthat filament elongation is the growth parameter subject todirect photocontrol. The present work supports an alternativeconcept, that the cross-sectional area at the base of the apicaldome is the photocontrolled parameter. Far-red irradiation reversesthe effects of both red and yellow light, and dose-responsecurves for yellow light parallel but lag behind the curves forred light. These observations indicate that the responses offern filaments to the entire long wavelength spectral region(yellow to far-red) can be attributed to absorption of lightby phytochrome alone.     

Hormonal influence on photocontrol of the protandry in the genus Helianthus

Under natural photoperiodic conditions protandry in hermaphrodite disc flowers of sunflower (Helianthus annuus L.) is determined by the different elongation rates of the style and filaments. The elongation of the filament and style starts simultaneously after the daily dark period, but the style growth rate is slower. When plants close to anthesis are exposed to continuous white light (WL) a loss of protandry occurs: the filaments do not grow far enough to extrude the anthers from the corolla. The histological analyses show that the number of filament epidermal cells remains unaltered after organ elongation and that cells respond to photoperiod only by cell expansion. Emasculation does not substantially inhibit filament cell expansion, whereas isolation of the filament or stamen from the corolla suggests that this organ could be the perception site of the filament growth stimulus. In vitro treatments with auxin (indole-3-acetic acid, IAA or alpha-naphthaleneacetic acid, NAA) reverses the inhibition of cell expansion caused by continuous WL, whereas gibberellic acid (GA(3)) at high concentrations reproduces the effect of continuous WL. Experiments carried out on various Helianthus spp. show that all these plants have evolved the same photo- and hormonal-control of the protandry. In experiments in which the light treatments were continued for 24 h, the auxins drastically reduced the inhibiting effect of red light (R) and dichromatic treatments FR (far red)+R, whereas GA(3) repressed filament extension regardless of light quality. As far as auxins are concerned, the response of sunflower filaments does not appear to be connected with the polar transport of the hormone. Moreover, the promoting effect of darkness is not mediated by an increase of endogenous free IAA in disc flowers. However, sunflower filaments manifested a similar temporal pattern of response to the light/dark cycle and to auxin.     

Electrical Changes in the Apical Cell of the Fern Gametophyte during Irradiation with Photomorphogenetically Active Light

Electrophysiological procedures were used to evaluate cellular responses of fern (Onoclea sensibilis L.) gametophytes to photomorphogenetically active light. Red, far red, and blue light caused rapid changes in the membrane potential of the apical cell of the gametophyte filament; other cells in the filament were not similarly responsive. Measurements made with one electrode in the apical cell revealed that the membrane potential depolarized in red light and repolarized in far red light. Irradiation with blue light caused a hyperpolarization, the rapidity of which was dependent on a red light pretreatment. More refined measurements with one electrode in the tip of the apical cell and another in the base of the cell showed that both red and blue light treatments cause the apical cell to behave as a dipole. Because of the profound, long-term morphological changes that follow light irradiation in this organism, it was hoped to use it to elucidate the role that electrical parameters play in determining subsequent developmental events.     

THE RELATIONSHIP BETWEEN THE PROMOTION OF ELONGATION OF FERN PROTONEMATA BY LIGHT AND GROWTH SUBSTANCES

Germinating spores of the fern Onoclea sensibilis L. were grown in darkness, so that they developed as filaments (protonemata). Brief daily exposure of the filaments to red, far-red or blue light increased the rate of filament elongation. Filament elongation was also promoted by indoleacetic acid. When filament elongation was promoted with both indoleacetic acid and exposure to light, the growth promotions caused by red and far-red light were additive to auxin-induced growth. Blue light promoted elongation only at sub-optimal concentrations of auxin. Elongation induced by guanine was additive to red- and far-red-induced elongation. Gibberellic acid had no effect on elongation under any condition. Blue-light-induced elongation resembled auxin-induced elongation in its requirement for exogenous sucrose and sensitivity to inhibition by parachlorophenoxyisobutyric acid. Red and far-red light were active regardless of the presence or absence of sucrose and promoted elongation at a concentration of parachlorophenoxyisobutyric acid which completely inhibited blue-light-induced elongation.     

Actin filament array during side branch initiation in protonema cells of the mossFunaria hygrometrica: an actin organizing center at the plasma membrane

Summary With an improved method to visualize the actin filament system it is possible to detect a small, peculiar accumulation of actin filaments under the prospective area of side branch formation inFunaria protonema cells. It consists of a ring-like configuration of actin filaments from which filaments radiate, preferentially along the plasma membrane. During the transition to tip growth the arrangement becomes loosened and eventually disappears whereas the filaments are concentrated in inner regions of the cytoplasm with a maximum in the apical dome.     

Effects of Colchicine and Light on Cell Form in Fern Gametophytes. Implications for a Mechanism of Light-induced Cell Elongation

Spores of the fern, Onoclea sensihilis L., suffer a disruption of normal development when they are cultured on media containing colchicine. Cell division is inhibited, and the spores develop into giant spherical cells under continuous white fluorescent light. In darkness only slight cell expansion occurs. Spherical cell expansion in the light requires continuous irradiation. Photosynthesis does not seem to be involved, since variations in light intensity do not affect the final cell diameter; the addition of sucrose to the medium does not permit cell expansion in darkness; and the inhibitor DCMU does not block the light-induced cell expansion. Continuous irradiation of colchicine-treated spores with blue, red or far-red light produces different patterns of cell expansion. Blue light permits spherical growth, similar to that found under white light, whereas red and far-red light promote the reestablishment of polarized filamentous growth. Although ethylene is unable to induce polarized cell expansion in colchicine-treated spores in darkness or white and blue light, it enhances filamentous growth which already is established by red or far-red irradiation. Both red and far-red light increase the elongation of normal filaments (untreated with colchicine) above that of dark-grown plants, but under all 3 conditions the rates of volume growth are identical. Light, however, does cause a decrease in the cell diameters of irradiated filaments. These data are used to construct an hypothesis to explain the promotion of cell elongation in fern protonemata by red and far-red light. The model proposes light-mediated changes in microtubular orientation and cell wall structure which lead to restriction of lateral cell expansion and enhanced elongation growth.     

Circular Arrangement of Cortical F-actin around the Subapical Region of a Tip-Growing Fern Protonemal Cell

F-actin organization in the tip-growing cells of fern protonematawas investigated by rhodamine-phalloidin staining in two species:Adiantum capillus-veneris and Pteris vittata. Circular arrangementof cortical F-actin was found around the subapical region ofprotonemal cells in both species. In rhizoids, such structureswere absent and the axial filaments appeared to fan out fromthe tip. (Received May 22, 1989; Accepted September 6, 1989)     

The Position of Bud Differentiation on Protonema of the Moss, Physcomitrium sphaericum

The position of the gametophytic bud was examined in relationto the development of protonema in the moss, Physcomitrium sphaericum. Positions of protrusion formation, of the development of protrusionsinto lateral filaments, and of the differentiation of protrusionsinto buds are restricted within the narrow regions of the filaments.The number of cells from the apical cell of the filament tothese positions are constant in any size filament. The growth pattern of the protonema is shown as follow. As afilament grows one-dimensionally through divisions of the apicalcell, new protrusions are produced successively on the 5th cellfrom the apical cell or on its vicinity. The cells which intervenebetween the apical cell and this protrusion increase in numberas the apical cell divides. When this protrusion is positionedat the 8th or 9th cell from the apex, it differentiates intoa bud or a lateral filament. This growth pattern is common toboth the main and lateral filaments. Buds are differentiated not only on caulonema cells in the mainand lateral filament, but also on chloronema cells at the baseof the lateral filaments. (Received December 14, 1981; Accepted April 24, 1982)     

AN ANALYSIS OF STAMEN FILAMENT GROWTH OF NIGELLA HISPANICA

The post-meiotic stamen filament of Nigella hispanica L. under greenhouse conditions grows in length from 1 mm to approximately 10 mm at maturity in 16 days. Analysis of the filament epidermis suggests that the intercalary meristem is diffuse along the filament with a mid-point of activity near the center of the filament. The point of maximal activity, while initially central, is variable as cell division nears completion. Measurement of cell lengths along filaments suggests that an elongation gradient from base to tip is operative in filaments 1 mm and longer. Average cell lengths of epidermal cells increase faster than do those of terminal cells. Once average cell length begins to increase in any region of the epidermis it continues to do so until flower maturity. At maturity the longest epidermal cells are near the filament base and the shortest cells are at the tip. The differences between cell division and cell elongation patterns suggest that these two processes are controlled by different sites or substances. A comparison is made between the development of the Nigella filament and other determinate organs having intercalary meristems.     

Photocontrol of growth pattern in a tissue isolated from the gametophytes of bracken fern

A tissue isolated from the gametophytes of bracken fern, Pteridiumaquilinum grew as unbranched filaments in red or green light,or in complete darkness. Irradiation with blue or white lightled to a shift from filamentous to two-dimensional pattern ofgrowth in the tissue. (Received February 13, 1969; )     

The role of actin in root hair morphogenesis: studies with lipochito-oligosaccharide as a growth stimulator and cytochalasin as an actin perturbing drug

Root hairs develop from bulges on root epidermal cells and elongate by tip growth, in which Golgi vesicles are targeted, released and inserted into the plasma membrane on one side of the cell. We studied the role of actin in vesicle delivery and retention by comparing the actin filament configuration during bulge formation, root hair initiation, sustained tip growth, growth termination, and in full-grown hairs. Lipochito-oligosaccharides (LCOs) were used to interfere with growth ( De Ruijter et al . 1998 , Plant J. 13, 341–350), and cytochalasin D (CD) was used to interfere with actin function. Actin filament bundles lie net-axially in cytoplasmic strands in the root hair tube. In the subapex of growing hairs, these bundles flare out into fine bundles. The apex is devoid of actin filament bundles. This subapical actin filament configuration is not present in full-grown hairs; instead, actin filament bundles loop through the tip. After LCO application, the tips of hairs that are terminating growth swell, and a new outgrowth appears from a site in the swelling. At the start of this outgrowth, net-axial fine bundles of actin filaments reappear, and the tip region of the outgrowth is devoid of actin filament bundles. CD at 1.0 μ m , which does not affect cytoplasmic streaming, does not inhibit bulge formation and LCO-induced swelling, but inhibits initiation of polar growth from bulges, elongation of root hairs and LCO-induced outgrowth from swellings. We conclude that elongating net-axial fine bundles of actin filaments, which we call FB-actin, function in polar growth by targeting and releasing Golgi vesicles to the vesicle-rich region, while actin filament bundles looping through the tip impede vesicle retention.     

Skeletal muscle fiber atrophy: altered thin filament density changes slow fiber force and shortening velocity

Single skinned fibers from soleus and adductor longus (AL) muscles of weight-bearing control rats and rats after 14-day hindlimb suspension unloading (HSU) were studied physiologically and ultrastructurally to investigate how slow fibers increase shortening velocity (V₀) without fast myosin. We hypothesized that unloading and shortening of soleus during HSU reduces densities of thin filaments, generating wider myofilament separations that increase V₀ and decrease specific tension (kN/m²). During HSU, plantarflexion shortened soleus working length 23%. AL length was unchanged. Both muscles atrophied as shown by reductions in fiber cross-sectional area. For AL, the 60% atrophy accounted fully for the 58% decrease in absolute tension (mN). In the soleus, the 67% decline in absolute tension resulted from 58% atrophy plus a 17% reduction in specific tension. Soleus fibers exhibited a 25% reduction in thin filaments, whereas there was no change in AL thin filament density. Loss of thin filaments is consistent with reduced cross bridge formation, explaining the fall in specific tension. V₀ increased 27% in soleus but was unchanged in AL. The V₀ of control and HSU fibers was inversely correlated (R = –0.83) with thin filament density and directly correlated (R = 0.78) with thick-to-thin filament spacing distance in a nonlinear fashion. These data indicate that reduction in thin filament density contributes to an increased V₀ in slow fibers. Osmotically compacting myofilaments with 5% dextran returned density, spacing, and specific tension and slowed V₀ to near-control levels and provided evidence for myofilament spacing modulating tension and V₀. rat; soleus; adductor longus; fiber length; electron microscopy; hindlimb suspension unloading     

Development of the siphonous green alga Penicillus and the Espera state*

The thallus of Penicillus is composed of two filament types: axial filaments of indeterminate growth and laterals of determinate growth. In vegetative reproduction new plants arise from horizontal rhizoids. Four stages can be distinguished in development. In the primordium stage the tip of a rhizoid swells and forms a primordium. In the germling stage ascending and descending axial filaments arise from the primordium, the former grow into a fascicle and give rise to lateral saccate branches, each of which forms an ascending and a descending arm and branches further into rhizoid-like branchlets. Together these structures constitute the foundation of the stipe. At the same time the descending axial filaments elongate and become main rhizoidal filaments with lateral rhizoidal branchlets. In the early juvenile stage the stipe is formed. The elongating ascending axial filaments form a medulla while their laterals produce a cortex. In the late juvenile stage the axial filaments form the capitulum. The Espera state of Penicillus lacks a stipe since the ascending axial filaments do not join in a fascicle. Espera has been grown in laboratory cultures from Penicillus plants collected in the Caribbean region and also been found uncommonly in nature in this area. This state may be a response to environmental stress. The flattening of thalli and their orientation perpendicular to the direction of waves are discussed. A comparison of Penicillus and Codium indicates that at least two types of development exist in multiaxial Eusiphoniidae.     

The Spontaneous Formation of Antheridia in Onoclea is not Blocked by Light

Onoclea sensibilis gametophytes were grown from spores on ashedsoil and agar to determine if the spontaneous formation of antheridiacan be blocked by light. Under most conditions, dark-grown gametophytesformed antheridia later than or at the same time as gametophytesgrown in the light. Under no circumstances was there a rapidonset of maleness in the dark. These results contradict thehypothesis that, in Onoclea, antheridiogen is required to inducemaleness because light inhibits the formation of antheridia.In the light, antheridia formed on heart-shaped thalli. In darkness,antheridia formed on filamentous gametophytes. The timing ofonset of maleness was affected by temperature and the presenceof sucrose. The effect of sucrose on the comparison betweenlight and dark treatments depended on both substrate and temperature Onoclea sensibilis, L., sensitive fern, fern gametophytes, sexuality, light-induced block     

The Effect of Ageing on Bud Differentiation in the Moss, Physcomitrium sphaericum

In the moss Physcomitrium sphaericum, we examined the numberof buds per filament, the position of buds, and the ratio ofbud-differentiated filaments when treated with cytokinin, inrelation to the increase in the number of cells per filament. When filaments of a young protonema were treated with cytokinin,many filaments did not differentiate buds. As the number ofcells in a filament increased, both the mean number of budsper filament and the ratio of bud-differentiated filaments increased.However, the position of bud differentiation was unaffectedby application of cytokinin. A higher concentration of cytokininincreased the mean number of buds per filament and the ratioof bud-differentiated filaments. The relationship between cytokinin, ageing of filaments andthe ability to differentiate buds is discussed. (Received June 17, 1985; Accepted September 9, 1985)     

STUDIES ON CILIA : III. Further Studies on the Cilium Tip and a "Sliding Filament" Model of Ciliary Motility

This study confirms and extends previous work on the lateral cilia of the fresh-water mussel, Elliptio complanatus, in support of a "sliding filament" mechanism of ciliary motility wherein peripheral filaments (microtubules) do not change length during beat (see Satir, 1967). Short sequences of serial sections of tips are examined in control (nonbeating) and activated (metachronal wave) preparations. Several different tip types, functional rather than morphogenetic variants, are demonstrated, but similarly bent cilia have similar tips. The peripheral filaments are composed of two subfibers: a and b. The bent regions of cilia are in the form of circular arcs, and apparent differences in subfiber-b length at the tip are those predicted solely by geometry of the stroke without the necessity of assuming filament contraction. Various subfibers b apparently move with respect to one another during beat, since small systematic variations in relative position can be detected from cilium to cilium. While subfiber-b lengths are uniform throughout, subfiber-a lengths are morphologically different for each filament: 8 and 3 are about 0.8 µ longer than 1, 4 and 5, but each unique length is independent of stroke position or tip type. Subfiber-a does not contract, nor does it move, e.g. slide, with respect to subfiber-b of the same doublet. The central pair of filaments extends to the tip of the cilium where its members fuse. Subunit assembly in ciliary microtubules is evidently precise. This may be of importance in establishing the relationships needed for mechanochemical interactions that produce sliding and beat.     

Phototropism in Vaucheria geminata II. The mechanism of bending and branching

The mechanism of phototropic bending and branching in Vaucheriageminata was analyzed. Using the half-side-illumination methodit was shown that phototropic bending is initiated by the formationof a new growth center on the illuminated side of the apicaldome of the tube, not by the difference in growth rate betweenthe lighted and shaded sides of the tip. Branching was alsoinitiated when the part proximal to the apical dome was illuminated.Blue light was effective for branching as it was for phototropicbending. The refractive indices measured at the growing tipand an area other than the tip were 1.36 and 1.34 respectively.A hyaline patch resembling the hyaline cap, which appeared priorto the onset of tip-growth in the apical dome, was invariablyformed shortly before the initiation of a new branch at theilluminated locus. (Received December 20, 1974; )     

Anther-filament Extension in Lilium: Potassium lon Movement and Some Anatomical Features

The growth of the anther filaments in the Lilium bud is essentiallyexponential after a length of 5 mm is reached, when the celldivision rate declines and growth is by cell extension, particularlyof cells in the central part of the filament. During the periodof extension, fresh vascular tissue is formed and xylem continuityis conserved up to the time of anther dehiscence, in contrastto the Graminae where the filament extends much more rapidly.The expansion of the lily filament depends in part on the continuoustransfer of potassium ions from the receptacle throughout theperiod of growth. Although starch to sugar conversion may bean important source of osmoticum as the cells expand, regulationof K⁺ ion movement would be likely to provide a more sensitiveand faster method of regulation of cell osmoticum. Anther filament, extension growth, filament, ion movement, Lilium, lily, potassium, stamen filament, turgidity, vasculation, xylem     

Evidence for Superthin Filaments

We have examined a variety of invertebrate and vertebrate musclesin the electron microscope and have seen evidence of a third,very thin (25 Ä) filament in all of them. This filamenthas been seen in H zones, A bands, and I bands, as well as bridgingthe gap between actin and myosin filaments in greatly stretchedmuscle. It, thus, seems likely that, if a third filament exists,it is elastic and extends throughout the sarcomere from Z discto Z disc, unlike the hypothetical actin-actin(s) filament ofHanson and Huxley (1955), or the actinmyosin gap filaments ofSjostrand (1962) and Carlsen, et al. (1965). These filaments therefore provide an answer to some of the presentparadoxes of muscle ultrastructure.