Intracellular Photoreceptive Site for Polarotropism in Protonema of the Fern Adiantum capillus-veneris L.

Polarotropic response was induced by short-term irradiationwith polarized red light in single-celled protonemata of thefern Adiantum capillus-veneris L. that had been grown apicallyunder red light for 6 days then for 15 hr in the dark. Sequentialobservation of the apical growth with a time-lapse video systemshowed that the direction of apical growth changed within 30min after the brief irradiation. Microbeam irradiation withpolarized red light of the subapical, dark-grown flank of theapical, 5–15 µm region of the protonema inducedthe polarotropic response most effectively. When both sidesof the flank were irradiated simultaneously with different fluencesof polarized red light with the same vibrating plane of 45°with protonemal axis, polarotropism took place normally, ifthe fluence ratio, B/A (B: fluence given to the side towardwhich the protonema should bend in polarotropism, A: fluencegiven to the other side) was not less than one-half. But, ifthe ratio became less than that, the protonemata no longer showedpolarotropism, they grew toward the side of higher fluence dependingon the difference in fluences between both sides. (Received August 1, 1981; Accepted September 29, 1981)     

Phytochrome-mediated polarotropism of Adiantum capillus-veneris L. protonemata as analyzed by microbeam irradiation with polarized light

Summary Perception of polarized light inducing phytochrome-mediated polarotropism in protonemata of the fern Adiantum capillus-veneris L. was analyzed using brief microbeam irradiation with polarized red (R) or far-red light (FR). The polarotropic response inducible by irradiation of the subapical 10–30-m part with polarized R vibrating parallel to the cell axis was nullified by subsequently giving R at the apical 0–2.5-m region. This inhibitory effect of R showed an action dichroism, that is, polarized R vibrating normal to the cell axis was effective but the parallel-vibrating R was not. On the other hand, FR irradiation of the extreme tip after irradiation of the whole cell with depolarized R effectively induced a tropic response. This FR effect also showed action dichroism, with parallel-vibrating polarized FR being more effective than FR vibrating normal to the cell axis. When the apical-dome region and the adjacent subapical 10–20-m region were sequentially irradiated with polarized R vibrating obliquely in different directions, polarotropism took place depending on the vibrating direction of the light given to the apical-dome region. Obliquely vibrating polarized FR given to the apical dome after irradiation of the whole cell with depolarized R also induced polarotropism. Thus, the difference in amount (or percent) of the far-redabsorbing form of phytochrome (Pfr) between the extreme tip and the subapical region appears to be crucial in regulating the direction of apical growth; the difference in Pfr level between the two sides of the protonemal apex may occur mainly at the apical dome. Furthermore, the transition moments of the red-absorbing form of phytochrome (Pr) and Pfr seem to be aligned parallel and normal, respectively, to the cell surface at the periphery of the apical hemisphere.Abbreviations FR far-red light - Pfr far-red-absorbing form of phytochrome - Pr red-absorbing form of phytochrome - R red light     

Polarotropism and Photomovement of Chloroplasts in the Protonemata of the Ferns Pteris and Adiantum: Evidence for the Possible Lack of Dichroic Phytochrome in Pteris

The actions of red and blue light in the photomovement of chloroplastsand the polarotropic response were studied in the protonemataof the homosporous ferns Pteris vittata L. and Adiantum capillus-venerisL. In Pteris, polarotropism could be induced with blue lightbut not with red light, while both colors of light were effectivein Adiantum protonemata. The photomovement of chloroplasts inthe two species studied by both polarized light and microbeamirradiation, also revealed similar responses to red and bluelight as the polarotropism; i.e. both colors of light were effectivein Adiantum but only blue light was active in Pteris. The resultsin Adiantum were consistent with previous results, which ledto the conclusion that both phytochrome and a blue light-absorbingpigment are involved in the two responses (Kadota et al. 1982,1984, Hayami et al. 1986, Yatsuhashi et al. 1985). By contrast,phytochrome is not involved in either polarotropism or chloroplastmovement in Pteris. Since the phytochrome system is evidentlyactive in every other photoresponses so far investigated inPteris as well as in Adiantum, the present study suggests thata phytochrome system specific to polarotropism and to photomovementof chloroplasts is absent in Pteris. Discussions are presentedon the possible involvement of two phytochrome populations ina fern gametophyte cell and on the possible lack of dichroicphytochrome in Pteris. (Received October 7, 1988; Accepted March 8, 1989)     

Phototropism and polarotropism of primary chloronemata of the moss Physcomitrella patens: responses of mutant strains

The phototropic and polarotropic responses of primary chloronemata grown from germinated minated spores of three mutant strains of the moss, Physcomitrella patens, have been studied and compared with those of the wild-type. The mutants and wild-type show the same qualitative tropic responses but differ with respect to the light conditions under which they are expressed. In both the wild-type and mutants the responses are controlled by phytochrome. In monochromatic red light, at low fluence rates, wild-type primary chloronemata grow positively phototropically in unidirectional light or perpendicular to the electrical vector (E) in polarised light; at high fluence rates growth in unidirectional light is lateral to the incident light or, in polarised light, parallel to E. The mutants, however, show only the lateral phototropic or parallel polarotropic responses at all fluence rates of red light tested. In far-red light, the wild-type primary chloronemata adopt a positive phototropic or a perpendicular polarotropic response; the mutants show the same responses but in a lower percentage of filaments. These results and those at other wavelengths indicate either that the mutants are impaired in their ability to adopt the positive phototropic and perpendicular polarotropic responses or that in the mutants the transition between the “low light” (positive phototropic-perpendicular polarotropic) and the “high light” (lateral phototropic-parallel polarotropic) responses is shifted to a lower photon fluence rate. Possible explanations of this phenotypic difference are discussed.     

Dose response behaviour for polarotropism of the germ tube of the liverwort Sphaerocarpos Donnellii aust.

Summary The dose response behaviour for polarotropism of the unicellular germ tube of Sphaerocarpos was studied in blue and near UV. At constant intensities the response is proportional to the logarithm of the exposure duration, and at constant exposure durations the response is proportional to the logarithm of intensity. Neither a polarotropic response to wavelengths > 550 nm, nor a significant influence on response to blue of a pre-, post-, or simultaneous-irradiation with red or far-red could be observed. Also a dark period was without any effect on the polarotropic response to blue. Growth responses under linearly polarized light are described.     

Changes in microtubule and microfibril arrangement during polarotropism inAdiantum protonemata

Polarotropism was induced inAdiantum (fern) protonemata grown under polarized red light by turning the electrical vector 45 or 70 degrees. One hour after the light treatment, tropic responses became apparent in many cells as a slight distortion of the apical dome. Changes in the position of the circumferentially-arranged cortical microtubule band (Mt-band) (Murataet al., 1987) and the arrangement of microfibrils around the subapical part of protonemata were investigated in relation to the polarotropic responses. Twenty minutes after turning the electrical vector, preceding the morphological change of cell shape, the Mt-band began to change its orientation from perpendicular to oblique to the initial growing axis. After 30 min, the Mt-band changed its orientation further under 45 degrees polarized light, but under light rotated 70 degrees, it began to disappear. In phototropic responses induced by local irradiation of a side of the subapical part of a protonema with a non-polarized red microbeam, the Mt-band on the irradiated side disappeared or became faint within 20 min, but neither disappearance nor a change of orientation of Mts occurred on the non-irradiated side. One hour after turning the electrical vector 45 degrees, in half of the cells tested, the innermost layer of microfibrils in the subapical part of the protonema changed its orientation from perpendicular to oblique to the growing axis, corresponding to the changes in the orientation of the Mt-band. After 2 hr, those changes were obvious in all cells examined. The same basic results on the orientation of microfibrils were obtained with protonemata cultured for 2 hr under 70 degrees polarized light. The role of the Mt-band in tropic responses is discussed.     

Dichroic Orientation of Phytochrome Intermediates in the Pathway from PR to PFR as Analyzed by Double Laser Flash Irradiations in Polarotropism of Adiantum Protonemata

The polarotropic response in protonemata of the fern Adiantumis regulated by phytochrome (Kadota et al. 1984); P_R and P_FRhave been shown to be dichroically oriented parallel and normalto the cell surface, respectively (Kadota et al. 1982). Thischange in the dichroic orientation of phytochrome during photoconversionwas analyzed by a newly-built, polarization plane-rotatabledouble laser flash irradiator. A polarotropic response was effectivelyinduced with a flash of polarized red (640 nm) light (6xl0^–7s) having the vibration plane of the electrical vector parallelto the protonemal cell axis. When a flash of polarized far-red(710 nm) light (6xl0^–7s) was given 30 sec after the redflash, the red flash-induced response was reversed by a far-redflash vibrating normal to the cell axis but not by one vibratingparallel. However, when given 2 µs or 2 ms after the redflash, the polarotropic response was not reversed by a polarizedfar-red flash vibrating normal to the cell axis but was reversedby a parallel-vibrating flash. These results suggest that theorientation of phototransformation intermediates existing 2µs or 2 ms after a red flash is still parallel to thecell surface, and that the change in the orientation of phytochromemolecules occurs between 2 ms and 30 s after the red flash. (Received February 3, 1986; Accepted April 23, 1986)     

Phototropism and polarotropism of primary chloronemata of the moss Physcomitrella patens: responses of the wild-type

Primary chloronemata growing from germinated spores of the moss Physcomitrella patens adopt one of two preferred polarotropic orientations depending on the wavelength and photon fluence rate of monochromatic light. Growth is mainly parallel to the electrical vector of plane polarised light in blue light and higher fluence rates of red light, and perpendicular to the electrical vector in the green and far-red regions of the spectrum and in low fluence rates of red light. The transition between the two polarotropic orientations, at wavelengths where it can be observed, usually occurs over a narrow range of fluence rates, and at this point the filaments do not grow randomly but tend to adopt in approximately equal numbers one of the preferred directions of growth. The primary chloronemata are positively phototropic in far-red light and in red light of low fluence rates, but tend to grow at right angles to the incident light in high fluence rates of red light. Simultaneous illumination with a high fluence rate of red light and a low fluence rate of far-red light causes a marked increase in the percentage of filaments growing towards the red light source at the expense of those growing at right angles to it, supporting the hypothesis that in red and far-red light, at least, the responses are controlled by the photoequilibrium of a phytochrome pool.     

Analysis of the phytochrome gene family in <Emphasis Type="Italic">Ceratodon purpureus</Emphasis> by gene targeting reveals the primary phytochrome responsible for photo- and polarotropism

Using gene targeting by homologous recombination in Ceratodon purpureus, we were able to knock out four phytochrome photoreceptor genes independently and to analyze their function with respect to red light dependent phototropism, polarotropism, and chlorophyll content. The strongest phenotype was found in knock-out lines of a newly described phytochrome gene termed CpPHY4 lacking photo- and polarotropic responses at moderate fluence rates. Eliminating the atypical phytochrome gene CpPHY1, which is the only known phytochrome-like gene containing a putative C-terminal tyrosine kinase-like domain, affects red light-induced chlorophyll accumulation. This result was surprising, since no light dependent function was ever allocated to this unusual gene. Electronic supplementary material  The online version of this article (doi:) contains supplementary material, which is available to authorized users. Accession number for CpPHY4: EU122393.     

Locomotor response of the goldfish to polarized light and itse-vector

Summary The locomotor orientation of eleven goldfish, 20–25 cm long, was monitored during periods varying between 24 hours and 8 1/2 days, to verify the response to a depolarized and polarized sky, 100 cm in diameter, and to abrupt 90 ° degree rotation of thee-vector. The monitor consisted of a cylindrical tank with 16 peripheral compartments (Fig. 1) to which the fish had free access. Entry into and exit from each compartment was electronically recorded. The distribution of entries, which had no cyclical relationship with the compartments in depolarized light, became significantly symmetrical and bimodal in polarized light with the preferred compartments oriented parallel with thee-vector. Abrupt 90 ° rotation of the vector counter clockwise maintained this relationship during the entire duration of the recordings (up to 17 hours) (Fig. 2). The mean of the orientation angles of the fish on leaving compartments aligned with thee-vector were significantly higher than those from the remaining compartments (Fig. 3). This behavior tended to keep the locomotor orientation parallel with thee-vector as the fish moved between compartments. A strong cyclical relationship between these orientation angles and the compartments of origin was present in polarized but absent in depolarized light. Counter clockwise 90 ° rotation of thee-vector maintained the cyclic behavior of angles but the relationship between the larger means and thee-vector shifted over one or two compartments. This shift disappeared in clockwise rotation. This phenomenon may be due to one of these directions being unnatural. The results demonstrate a pronounced sensitivity and response toe-vector orientation in the goldfish. The sensory mechanism remains unknown.The authors are greatly indebted to Dr. T. H. Waterman for a critical review and discussion of the results here presented.     

Phytochrome-mediated branch formation in protonemata of the mossCeratodon purpureus

We have analyzed light induction of side-branch formation and chloroplast re-arrangement in protonemata of the mossCeratodon purpureus. After 12 hr of dark adaptation, the rate of branch formation was as low as 5%. A red light treatment induced formation of side branches up to 75% of the dark-adapted protonema. The frequency of light induced branch formation differed between cells of different ages, the highest frequency being found in the 5th cell, the most distal cell studied from the apex. We examined the effect of polarized light given parallel to the direction of filament growth. The position of branching within the cell depended on the vibration plane of polarized red light. Branch formation was highest when the electric vector of polarized light vibrates parallel to the cell surface and is fluence rate dependent. The positional effect of polarized red light could be nullified to some extent by simultaneous irradiation with polarized far-red light. An aphototropic mutant,ptr116, shows characteristics of deficiency in biosynthesis of the phytochrome chromophore and exhibits no red-light induced branch formation. Biliverdin, a precursor of the phytochrome chromophore, rescued the red-light induced branching when added to the medium, supporting the conclusion that phytochrome acts as photoreceptor for red light induced branch formation. The light effect on chloroplast re-arrangement was also analyzed in this study. We found that polarized blue light induced chloroplast re-arrangement in wild-type cells, whereas polarized red light was inactive. This result suggests that chloroplast re-arrangement is only controlled by a blue light photoreceptor, not by phytochrome inCeratodon.     

Intracellular chloroplast photorelocation in the moss Physcomitrella patens is mediated by phytochrome as well as by a blue-light receptor

 The light-induced intracellular relocation of chloroplasts was examined in red-light-grown protonemal cells of the moss Physcomitrella patens. When irradiated with polarized red or blue light, chloroplast distribution in the cell depended upon the direction of the electrical vector (E-vector) in both light qualities. When the E-vector was parallel to the cross-wall (i.e. perpendicular to the protonemal axis), chloroplasts accumulated along the cross-wall; however, no accumulation along the cross-wall was observed when the E-vector was perpendicular to it (i.e. parallel to the protonemal axis). When a part of the cell was irradiated with a microbeam of red or blue light, chloroplasts accumulated at or avoided the illumination point depending on the fluence rate used. Red light of 0.1–18 W m⁻² and blue light of 0.01–85.5 W m⁻² induced an accumulation response (low-fluence-rate response; LFR), while an avoidance response (high-fluence-rate response; HFR) was induced by red light of 60 W m⁻² or higher and by blue light of 285 W m⁻². The red-light-induced LFR and HFR were nullified by a simultaneous background irradiation of far-red light, whereas the blue-light-induced LFR and HFR were not affected at all by this treatment. These results show, for the first time, that dichroic phytochrome, as well as the dichroic blue-light receptor, is involved in the chloroplast relocation movement in these bryophyte cells. Further, the phytochrome-mediated responses but not the blue-light responses were revealed to be lost when red-light-grown cells were cultured under white light for 2 d. Received: 7 September 1999 / Accepted: 15 October 1999     

Linear Dichroism and Orientation of the Phycomyces Photopigment

The greater sensitivity of a cylindrical Phycomyces sporangiophore to blue light polarized transversely rather than longitudinally is a consequence of the dichroism and orientation of the receptor pigment. The abilities of wild type and several carotene mutants to distinguish between the two directions of polarization are the same. The E-vector angle for maximum response relative to the transverse direction is 42 ± 4° at 280 nm, 7° ± 3° at 456 nm, and 7° ± 8° at 486 nm. The in vivo attenuation of polarized light at these wavelengths is very small. The polarized light effect in Phycomyces cannot arise from reflections at the cell surface or from differential attenuations due to internal screening or scattering.     

Differently oriented chlorophylls in Mesotaenium caldariorum detected by microphotometrical dichroism measurements in vivo

The chloroplasts of individual cells of Mesotaenium caldariorum were examined microphotometrically under non-polarized and polarized measuring light. The measurement with non-polarized light showed different absorption bands of the thylakoids depending on the position of their surface with respect to the incident light beam: in the edge position, the absorption bands lie at 672 nm, in the face position at 678 nm. From this difference in absorption maxima, we conclude that the molecules related to the sub-bands at the two wavelengths are oriented differently. The Q_y transition of the molecules which absorb light at 678 nm must be oriented parallel to the face of the thylakoids (fraction I), while that of the molecules absorbing at 672 nm is oriented perpendicular to the face (fraction II). Measurement with polarized light leads to the same conclusion that two fractions of differently oriented chlorophylls exist: In the edge position, a very large difference between E_∥ and E_⊥ (dichroism) was found in red light, with a maximum of E_∥ lying at 675 nm and a maximum of E_⊥ at 670 nm, with a shoulder at 650 nm. In the blue region, especially in the Soret band zone, the chloroplast showed a negative dichroism in the edge position, which changes over to positive values when the wavelength exceeds 450 nm. In the face position no dichroism in red or blue light could be detected. Comparison of the ‘edge position dichroism’ in red light with that in blue light justifies the supposition that the chlorin planes of the chlorophyll molecules may be oriented perpendicular or parallel to the thylakoid face, in the case of perpendicular orientation with the Q_y transitions of fraction II and the x-transitions (B_x, Q_x) of fraction I projecting out of the plane, and for parallel orientation with all transition moments lying parallel to the plane (fraction I). The relative dichroism, $\text{(E}{}_{\mathrm{\parallel }}\text{? E}{}_{\mathrm{\perp }}\text{)}\text{(E}{}_{\mathrm{\parallel }}\text{+ E}{}_{\mathrm{\perp }}\text{)}$, measured at the edge position amounts to 0.34 (i.e., 34% of the total absorption) at 680 nm. These data probably do not reflect the total quantity of oriented chlorophyll because from the opposite orientations of the Q_y transition moments of fraction I and II pigment a partial quenching of the measurable dichroism results. The red light absorption bands of the two chlorophylls oriented in an opposite manner (fractions I and II) correspond to the known bands of Photosystem I and II.     

Orientation in a desert lizard (Uma notata): time-compensated compass movement and polarotaxis

Summary The diurnal escape response of fringetoed lizards (Uma notata) startled by predators demonstrates clear directional orientation not likely to depend on local landmarks in the shifting sands of their desert environment. Evidence that celestial orientation is involved in this behavior has been sought in the present experiments by testing the effects of (1) phase shifting the animal's internal clock by 6 h and (2) by training the lizards to seek shelter while exposed to natural polarization patterns. In the first case, 90° shifts in escape direction were demonstrated in outdoor tests, as expected if a time-compensated sun or sky polarized light compass is involved. In the second instance, significant bimodale-vector dependent orientation was found under an overhead polarizing light filter but this was only evident when the response data were transposed to match the zenithe-vector rotation dependent on the sun's apparent movement through the sky. This extends to reptiles the capacity to utilize overheade-vector directions as a time-compensated sky compass. The sensory site of this discrimination and the relative roles of sun and sky polarization in nature remain to be discovered.     

Blue- and red-light action in photoorientation of chloroplasts in Adiantum protonemata

An action spectrum for the low-fluencerate response of chloroplast movement in protonemata of the fern Adiantum capillus-veneris L. was determined using polarized light vibrating perpendicularly to the protonema axis. The spectrum had several peaks in the blue region around 450 nm and one in the red region at 680 nm, the blue peaks being higher than the red one. The red-light action was suppressed by nonpolarized far-red light given simultaneously or alternately, whereas the bluelight action was not. Chloroplast movement was also induced by a local irradiation with a narrow beam of monochromatic light. A beam of blue light at low energy fluence rates (7.3·10^-3-1.0 W m^-2) caused movement of the chloroplasts to the beam area (positive response), while one at high fluence rates (10 W m^-2 and higher) caused movement to outside of the beam area (negative response). A red beam caused a positive response at fluence rates up to 100 W m^-2, but a negative response at very high fluence rates (230 and 470 W m^-2). When a far-red beam was combined with total background irradiation with red light at fluence rates causing a low-fluence-rate response in whole cells, chloroplasts moved out of the beam area. When blue light was used as background irradiation, however, a narrow far-red beam had no effect on chloroplast distribution. These results indicate that the light-oriented movement of Adiantum chloroplasts is caused by red and blue light, mediated by phytochrome and another, unidentified photoreceptor(s), respectively. This movement depends on a local gradient of the far-red-absorbing form of phytochrome or of a photoexcited blue-light photoreceptor, and it includes positive and negative responses for both red and blue light.Abbreviations BL blue light - FR far-red light - Pfr far-red-absorbing form of phytochrome - Pr red-absorbing form of phytochrome - R red light - UV ultraviolet     

Index to Authors,Volume 6

Abstract

The refractive indices of wet-spun films of CsDNA have been measured for light polarized parallel and perpendicular to the helical axis as a function of relative humidity (RH). These data have been combined with previously published data (Biopolymers 30 (1990) 877–887) for the volume per base pair and water content as a function of RH in order to extract the optical polarizabilities. This work was motivated by the study of Weidlich et al. (Biopolymers 26 (1987) 439–453) who reported a ～35% increase at the A-to-B transition in the parallel and perpendicular polarizabilities of NaDNA. In contrast, a much smaller increase in the polarizabilities of CsDNA is found near the A-to-B transition: ～ 12% for the perpendicular direction and < 4% for the parallel direction.     

Organization of cortical microtubules and microfibril deposition in response to blue-light-induced apical swelling in a tip-growing Adiantum protonema cell

The arrangements of cortical microtubules (MTs) in a tip-growing protonemal cell of Adiantum capillus-veneris L. and of cellulose microfibrils (MFs) in its wall were examined during blue-light (BL)-induced apical swelling. In most protonemal cells which had been growing in the longitudinal direction under red light, apical swelling was induced within 2 h of the onset of BL irradiation, and swelling continued for at least 8 h. During the longitudinal growth under red light, the arrangement of MFs around the base of the apical hemisphere (the subapical region) was perpendicular to the cell axis, while a random arrangement of MFs was found at the very tip, and a roughly axial arrangement was observed in the cylindrical region of most cells. This orientation of MFs corresponds to that of the cortical MTs reported previously (Murata et al. 1987, Protoplasma 141, 135–138). In cells irradiated with BL, a random rather than transverse arrangement of both MTs and MFs was found in the subapical region. Time-course studies showed that this reorientation occurred within 1 h after the onset of the BL irradiation, i.e. it preceded the change in growth pattern. These results indicate that the orientation of cortical MTs and of cellulose MFs is involved in the regulation of cell diameter in a tip-growing Adiantum protonemal cell.Abbreviations BL blue light - MF(s) microfibril(s) - MT(s) microtubule(s)     

Four distinct photoreceptors contribute to light-induced side branch formation in the moss <Emphasis Type="Italic">Physcomitrella patens</Emphasis>

Side branch formation in the moss, Physcomitrella patens, has been shown to be light dependent with cryptochrome 1a and 1b (Ppcry1a and Ppcry1b), being the blue light receptors for this response (Imaizumi et al. in Plant Cell 14:373, 2002). In this study, detailed photobiological analyses were performed, which revealed that this response involves multiple photoreceptors including cryptochromes. For light induction of branches, blue light of a fluence rate higher than 6 μmol m⁻² s⁻¹ for period longer than 3 h is required. The number of branches increased with the increase in fluence rate and in the irradiation period. The number of branches also increased when red light was applied together with the blue light, although red light alone had a very few effect. By partially irradiating a cell, both receptive sites for blue and red light were found to be located around the nucleus. Further, both red and blue light determine the positions of branches being dependent upon the vibration plane of polarized light. Red light control of branch position was nullified by simultaneous far-red light irradiation. A blue light effect on branch position was not found in lines with disrupted phototropin genes. Thus, dichroic phytochrome and phototropin, possibly on the plasma membrane, regulate branch position. These results indicate that at least four distinct photoreceptor systems, namely, cryptochromes and red light receptor around or in the nucleus, dichroic phytochrome and phototropin around the cell periphery, are involved in the light induction of side branches in the moss Physcomitrella patens.     

ON THE MECHANISM OF DECUSSATE PHYLLOTAXIS: BIOPHYSICAL STUDIES ON THE TUNICA LAYER OF VINCA MAJOR

Phyllotaxis theory typically assumes that an acropetal influence from recently formed leaves acts on the apical dome to initiate new leaves. Biophysical theory postulates that established plant organs elongate because their primary walls, particularly those in the organ surface layer, are transversely reinforced by cellulose to give the organ overall hoop reinforcement. These two postulates are combined here in a biophysical theory for phyllotaxis. The essential acropetal influence from young leaves is proposed to be the stretching of the adjacent dome tissue by the growth of leaf bases. Cytoskeletal responses on the dome produce reinforcement patterns which initiate new hoop reinforced leaves. Growth of these leaves remodels the dome for the next round of organs. Data pertinent to this theory are presented here for Vinca major. The surface (tunica) layer of the apical dome was isolated by paradermal cuts. Using polarized light, the cellulose alignment in this surface layer was determined, cell by cell, for various stages of the plastochron. The growing dome is typically elliptical, with the major axis shifting by 90° during each plastochron. The periphery of the dome always has cellulose oriented parallel to its margin; the central region, when the major axis is pronounced, has reinforcement normal to this axis. During the plastochron this reinforcement pattern is modified, by plausible biophysical mechanisms, to account for the three major activities of the dome: 1) production of a hoop-reinforced leaf at each end of the ellipse, 2) formation of a hoop-reinforced stem segment, 3) revision of dome structure to produce the same initial reinforcement pattern as at the start of the plastochron, but at 90°.