Evidence that actin reinforces the extensible hyphal apex of the oomyceteSaprolegnia ferax

Summary Filamentous actin in the apices of growing hyphae of the oomyceteSaprolegnia ferax is distributed such that it could compensate for weakness in the expanding apical cell wall and thus play a role in morphogenesis of the tip. The tapered extensible portion of the hyphal tip where the cell wall is plastic contains a cap of actin which differs in organization from the actin in subapical, inextensible regions of the hypha. Rapidly growing hyphae which are expected to have a longer plastic cell wall region contain longer actin caps. Furthermore, the weakest point in the hyphal apex, demonstrated by osmotic shock-induced bursting, was within the taper where the wall is plastic but never in the extreme apex where actin was most densely packed and presumably the strongest. Treatment of hyphae with cytochalasin E/dimethyl sulphoxide induced rapid changes in actin caps. Cap disruption was accompanied by transient growth rate increases, subsequent rounding and swelling of apices and a shift of osmotically induced burst points closer to the apex. These correlated changes are consistent with a role for the actin cap in tip morphogenesis. The association between regions of plasticity in the apical cell wall, the extent of the actin cap, the location of the weakest point in the apex and the effects of damage to the actin cap suggest that the cap functions to support the apex in regions where the cell wall is weak.Abbrevations CE cytochalasin E - DMSO dimethyl sulphoxide - RP rhodamine phalloidin Dedicated to the memory of Professor Oswald Kiermayer     

Cytoskeletal changes during resumption of tip growth in nongrowing protonemal cells of the fernAdiantum capillus-veneris L.

Summary Nongrowing, two-celled protonemata of the fernAdiantum capillus-veneris L. resume tip growth within the apical cell upon irradiation with red light. In this study, the phenomenon of growth resumption was analyzed with reference to changes in cytoskeletal organization. Continuous observations of apical cells with time lapse video-microscopy revealed that the nucleus migrated toward the tip ca. 1.9 h after the onset of red light, much earlier than the initiation of tip growth, which took place ca. 8.5 h after irradiation. Cytoskeletal organization was observed at various time points during growth resumption by fluorescent staining of microfilaments (MFs) and microtubules (MTs) with rhodamine-phalloidin and anti-tubulin antibodies. At 2 h after red-light irradiation, endoplasmic MF and MT strands appeared at the apical end of nucleus. These strands extended into the apical endoplasm, where filaments were rare prior to irradiation. Many fine filaments branched from the strands to the cell periphery, including the cortex of the apical-dome region. At this time, cortical circular arrays of MTs and MFs, normally found in the growing apex of protonemal cells, were absent. Both MT and MF circular arrays appeared during the resumption of tip growth concomitantly. The half-maximum appearance of MT and MF circular arrays within a population occurred at 5.4 h and 5.8 h after red-light irradiation, respectively. Thus, the process of red-light-induced resumption of tip growth in fern protonemal cell is composed of a series of events. These events include: (1) the appearance of strands extending from the nucleus toward the apical cortex and the migration of nucleus toward the apex; (2) the formation of circular MT and MF arrays at the sub-apical cortex; and (3) the initiation of cell growth at the apex. These results reflect the significant roles of MF and MT cytoskeleton in the resumption of tip growth.Abbreviations MBS m-maleimidobenzoic acid N-hydroxysuccinimide ester - MF microfilament - MT microtubule     

AN ULTRASTRUCTURAL BASIS FOR HYPHAL TIP GROWTH IN PYTHIUM ULTIMUM

Hyphae of the fungus Pythium ultimum extend by tip growth. The use of surface markers demonstrates that cell expansion is limited to the curved portion of the hyphal apex. Growing and non-growing regions are reflected in internal organization as detected by light and electron microscopy. The young hypha consists of three regions: an apical zone, a subapical zone and a zone of vacuolation. The apical zone is characterized by an accumulation of cytoplasmic vesicles, often to the exclusion of other organelles and ribosomes. Vesicle membranes are occasionally continuous with plasma membrane. The subapical zone is non-vacuolate and rich in a variety of protoplasmic components. Dictyosomes are positioned adjacent to endoplasmic reticulum or nuclear envelope, and vesicles occur at the peripheries of dictyosomes. A pattern of secretory vesicle formation by dictyosomes is described which accounts for the formation of hyphal tip vesicles. Farther from the hyphal apex the subapical zone merges into the zone of vacuolation. As hyphae age vacuolation increases, lipid accumulations appear, and the proportional volume of cytoplasm is reduced accordingly. The findings are integrated into a general hypothesis to explain the genesis and participation of cell components involved directly in hyphal tip growth: Membrane material from the endoplasmic reticulum is transferred to dictyosome cisternae by blebbing; cisternal membranes are transformed from ER-like to plasma membrane-like during cisternal maturation; secretory vesicles released from dictyosomes migrate to the hyphal apex, fuse with the plasma membrane, and liberate their contents into the wall region. This allows a plasma membrane increase at the hyphal apex equal to the membrane surface of the incorporated vesicles as well as a contribution of the vesicle contents to surface expansion.     

Elaborate spatial patterning of cell-wall PME and PMEI at the pollen tube tip involves PMEI endocytosis, and reflects the distribution of esterified and de-esterified pectins

In dicots, pectins are the major structural determinant of the cell wall at the pollen tube tip. Recently, immunological studies revealed that esterified pectins are prevalent at the apex of growing pollen tubes, where the cell wall needs to be expandable. In contrast, lateral regions of the cell wall contain mostly de-esterified pectins, which can be cross-linked to rigid gels by Ca(2+) ions. In pollen tubes, several pectin methylesterases (PMEs), enzymes that de-esterify pectins, are co-expressed with different PME inhibitors (PMEIs). This raises the possibility that interactions between PMEs and PMEIs play a key role in the regulation of cell-wall stability at the pollen tube tip. Our data establish that the PME isoform AtPPME1 (At1g69940) and the PMEI isoform AtPMEI2 (At3g17220), which are both specifically expressed in Arabidopsis pollen, physically interact, and that AtPMEI2 inactivates AtPPME1 in vitro. Furthermore, transient expression in tobacco pollen tubes revealed a growth-promoting activity of AtPMEI2, and a growth-inhibiting effect of AtPPME1. Interestingly, AtPPME1:YFP accumulated to similar levels throughout the cell wall of tobacco pollen tubes, including the tip region, whereas AtPMEI2:YFP was exclusively detected at the apex. In contrast to AtPPME1, AtPMEI2 localized to Brefeldin A-induced compartments, and was found in FYVE-induced endosomal aggregates. Our data strongly suggest that the polarized accumulation of PMEI isoforms at the pollen tube apex, which depends at least in part on local PMEI endocytosis at the flanks of the tip, regulates cell-wall stability by locally inhibiting PME activity.     

Cytokinin production by Asparagus shoot apex cultured in vitro

The cytokinin producing capacity of asparagus (Asparagus officinalis L.) shoot apex was examined by means of shoot apex culture in vitro, where adventitious roots were never formed. The cultured shoot apices continued to diffuse a small but constant amount of cytokinin into the medium throughout five passages of subculture. The cytokinin content in the apices at the end of the subculture was not different from that at the beginning of the subculture. These results indicate a production of cytokinin by the apices. However, the finding is not in conflict with the hypothesis that the root tip is the major source of cytokinin supply, because the root tip of asparagus produced more cytokinin than the shoot apex and the decline of shoot growth observed during the subculture was partially restored by an application of zeatin into the medium.     

The fine structure ofPhycomyces

Summary The cytological organization of the apices of sporangiophores and hyphae ofPhycomyces Blakesleeanus was studied by means of light- and electron microscopy. The sporangiophore apex in growth stage I contains a mass of cytoplasm in which is embedded a cluster of lipid globules. Within the plug several zones are differentiated by the grouping of organelles. These zones are not separated by membranes. The most apical zone is low in nuclei and vesicles but rich in mitochondria and dense bodies. Below this zone lies a compact group containing up to several hundred nuclei. Along the midline of the cell, below these nuclei, lies an ovoid region from which vesicles, nuclei and mitochondria are excluded. In this ovoid exclusion zone lies the cluster of lipid globules mentioned above. Lateral to the exclusion zone (i.e. in the peripheral region of the cell) the cytoplasm is rich in nuclei, mitochondria, dense bodies, and especially in developing autophagic vesicles. Of these vesicles, the most mature are found farthest from the cell apex. The region between the exclusion zone and the upper end of the cell's large central vacuole is occupied largely by mature, swollen autophagic vesicles. In addition to the zonal organization described above, microtubules are found to run along the cylindrical cell's axis at a distance from the cell wall, and extend to the extreme apex of the cell. Similar tubules occur in growing hyphae, together with dense bodies, and the hyphal apex contains non-autophagic vesicles that increase in size with distance from the hyphal tip. The hyphae lack the zonation shown by sporangiophore apices. Perinuclear masses of cisternae are described and related to the dictyosomes of higher plants. The findings are discussed in relation to the function of the apices in tip growth and sporulation.This work was supported in part by a National Science Foundation Graduate Fellowship to the author, and in part by grant No. GB 3241 from the National Science Foundation to ProfessorKenneth V.Thimann.     

TIP CELL GROWTH AND THE FREQUENCY AND DISTRIBUTION OF CELLULOSE MICROFIBRIL-SYNTHESIZING COMPLEXES IN THE PLASMA MEMBRANE OF APICAL SHOOT CELLS OF THE RED ALGA PORPHYRA YEZOENSIS1

The supramolecular organization of the plasma membrane of apical cells in shoot filaments of the marine red alga Porphyra yezoensis Ueda (conchocelis stage) was studied in replicas of rapidly frozen and fractured cells. The protoplasmic fracture (PF) face of the plasma membrane exhibited both randomly distributed single particles (with a mean diameter of 9.2 ± 0.2 nm) and distinct linear cellulose microfibril-synthesizing terminal complexes (TCs) consisting of two or three rows of linearly arranged particles (average diameter of TC particles 9.4 plusmn; 0.3 nm). The density of the single particles of the PF face of the plasma membrane was 3000 μm^?2, whereas that of the exoplasmic fracture face was 325 μm^?2. TCs were observed only on the PF face. The highest density of TCs was at the apex of the cell (mean density 23.0 plusmn; 7.4 TCs μm^?2 within 5 μm from the tip) and decreased rapidly from the apex to the more basal regions of the cell, dropping to near zero at 20 μm. The number of particle subunits of TCs per μm² of the plasma membrane also decreased from the tip to the basal regions following the same gradient as that of the TC density. The length of TCs increased gradually from the tip (mean length 46.0 plusmn; 1.4 nm in the area at 0–5 μm from the tip) to the cell base (mean length 60.0 plusmn; 7.0 μm in the area at 15–20 μm). In the very tip region (0–4 μm from the apex), randomly distributed TCs but no microfibril imprints were observed, while in the region 4–9 μm from the tip microfibril imprints and TCs, both randomly distributed, occurred. Many TCs involved in the synthesis of cellulose microfibrils were associated with the ends of microfibril imprints. Our results indicate that TCs are involved in the biosynthesis, assembly, and orientation of cellulose microfibrils and that the frequency and distribution of TCs reflect tip growth (polar growth) in the apical shoot cell of Porphyra yezoensis. Polar distribution of linear TCs as “cellulose synthase” complexes within the plasma membrane of a tip cell was recorded for the first time in plants.     

甘蔗茎尖原生分生组织区域化

甘蔗茎尖原生分生组织是甘蔗地上部分一切形态组织的发源中心,通过对6个不同茎径甘蔗品种4个不同营养发育时期的茎尖原生分生组织显微和超微结构观察研究发现:甘蔗茎尖原生分生组织呈半卵型结构,明显分为原套原始细胞区、原体原始细胞区、周缘分生细胞区、髓分生区,其区域化符合原套-原体学说。原套原始细胞区为最外一层细胞,原套细胞之间胞间连丝丰富,而原套与原体细胞之间胞间连丝极少,细胞以垂周分裂为主,扩大原生分生组织表面积;原体位于原套下的分生组织的中央区域,细胞可以进行各个方向的分裂,不断增加体积,原体原始细胞区呈一个球体;周缘分生区位于原套、原体下方两侧,细胞活跃产生叶原基和原形成层细胞;髓分生区细胞位于原体下方周缘分生区内侧,细胞横向分裂纵向排列,使甘蔗茎伸长。     

Structural and functional compartmentalization in pollen tubes

Eukaryotic cellular functions are achieved by concerted activities in the cytosol and functions compartmentalized in the nucleus and other membrane-bound organelles. Moreover, the cytosol and nucleoplasm are populated with mega molecular ensembles that are specialized for different metabolic and biochemical processes. Pollen tubes are unique plant cells with a dramatic growth polarity. Tube growth is restricted to the tip and is supported by a polarized cytoplasmic organization. The apical region of elongating pollen tubes is a domain occupied exclusively by transport vesicles to support the secretion and endocytic activity needed for the rapid cell expansion at the apex. Larger organelles are predominantly segregated to the cytoplasm distal to the subapical region. Underlying the organelle compartmentalization is an elaborate actin cytoskeleton with distinct structural and dynamics properties at the tip, in the subapical region, and in the cytoplasm subtending it. Cytoplasmic domains with differential ionic conditions and spatially restricted localization of molecules in pollen tubes may also be important for regulating the polar cell growth process. The polarized cellular organization in pollen tubes drives an extremely efficient cell growth process that is responsive to extracellular signals, including directional cues. It may be an amplified framework of the cytoplasmic architecture that supports growth in other plant cell types that involves considerably more subtle and transient differential cell expansion.     

Origins of the prestalk-prespore pattern in Dictyostelium development

Using cell-autonomous markers we have traced the origins of prespore cells and two types of prestalk cells (pstA and pstB cells) during slug formation. We show that cell sorting and positional information both contribute to Dictyostelium morphogenesis. The initial pattern established at the mound stage is topologically quite different from that of the slug. Confirming previous studies, we find that prespore cells occupy most of the aggregate but are absent from a thin layer at the base and from the emerging tip. PstB cells are almost entirely localized to the basal region during the early stages of tip formation. Thus prespore and pstB cell differentiation appear to occur in response to localized morphogenetic signals. In the case of pstB cells, these signals presumably emanate from the base and not, as might be expected, from the tip. When first detectable, pstA cells are scattered throughout the aggregate. They then appear to migrate to the apex, where the tip forms.     

Plasma membrane-adjacent actin filaments, but not microtubules, are essential for both polarization and hyphal tip morphogenesis in Saprolegnia ferax and Neurospora crassa

The organization and roles of F-actin and microtubules in the maintenance and initiation of hyphal tip growth have been analyzed in Saprolegnia ferax and Neurospora crassa. In hyphae of both species, the apex is depleted of microtubules relative to subapical regions and near-normal morphogenesis occurs in concentrations of nocodazole or MBC which remove microtubules, slow growth, and disrupt nuclear positioning. In contrast, each species contains characteristic tip-high arrays of plasma membrane-adjacent F-actin, whose organization is largely unaltered by the loss of microtubules but disruption of which by latrunculin B disrupts tip morphology. Hyphal initiation and subsequent normal morphogenesis from protoplasts of both species and spores of S. ferax are independent of microtubules, but at least in S. ferax obligatorily involve the formation of F-actin caps adjacent to the hyphal tip plasma membrane. These observations indicate an obligatory role for F-actin in hyphal polarization and tip morphogenesis and only an indirect role for microtubules.     

Development of the root system in<Emphasis Type="Italic">Spirodela polyrhiza</Emphasis> (L.) schleiden (Lemnaceae)

The root structure in members of the Lemnaceae is important to plant researchers, because changes during cell differentiation can more easily be monitored in short roots with determinate growth. Here, the structural organization and cellular differentiation of the root system was assessed in the highly reducedSpirodela polyrhiza. While protected by a prophyllous sheath, rapid cell division occurred in the apical and vascular regions of the immature roots. Concentric rings of endodermis with Casparian strips, cortex, and epidermis enclosed a single vascular strand. The cytoplasmic density of the cortex was high at the apex, but decreased progressively along the root. The root root cap junction, closely attached at initiation, later became a distinct boundary layer filled with fibrillar materials. Chloroplasts were well distributed. Numerous plasmodesmata indicated the likely symplastic movement of ions and metabolites in the root system as well as further into the reduced plant body. A high cytoplasmic density at the apex and extreme vacuolization along the cortex provided possible explanations for the considerable distribution of weight along the roots of the plant body. These conditions probably enable the root tip to serve as a pendulum against water motion.     

SOME EFFECTS OF FEEDING BY LYGUS VOSSELERI POPP. (HETEROPTERA, MIRIDAE) ON THE STEM APEX OF THE COTTON PLANT

The effects of damage to the main stem apex of the cotton plant caused by feeding of Lygus vosseleri Popp. have been investigated using a cell counting technique. It was found that mechanical damage of the tip due either to feeding of Lygus or to pricking with a glass needle caused an increase in cell division and maturation rates in the stem apex. The significance of this in relation to the possible effects of Lygus damage on plant height is discussed.     

Hyphal tip organization inAllomyces arbuscula

Summary Light and electron microscopic observations on vegetative hyphae ofAllomyces arbuscula revealed the specialized organization of the tip. There were some minor differences related to culture conditions, but the main ultrastructural features common to all hyphal tips disclosed a special type of organization distinct from that of other fungi. A crescent-shaped apical zone consisted of vesicles and membrane cisternae embedded in a granular matrix. Vesicles fused with the apical plasmalemma and presumably contributed to its expansion and to wall growth. The apical zone contained few ribosomes and generally no other organelles. Mitochondria were concentrated in the immediate subapical zone and scattered through the remainder of the hyphae, as were microbodies. Microtubules formed an asterlike structure with its center in the apical zone. Proximally of the apex, microtubules were axially oriented. Nuclei occurred only a certain distance from the tip. The elements of the apex may maintain the polarity of the hyphae via a gradient and hold it in a state of vegetative growth.     

Plant Population Induced Growth Correlations in the Barley Plant Main Shoot and Possible Hormonal Mechanisms

A morphogenetic study, from the first-leaf stage onwards, wasmade of barley plants grown at a range of plant populationsfrom 50 to 1600 plants m^-2. Increasing density reduced leafnumber from 10.2 to 8 and caused stem internode elongation tostart earlier at a lower node. Final stem length was reduceddue to earlier cessation of growth. The lamina and sheath lengthof the lower leaves was increased with increasing density, andlamina width was decreased. At the highest density the apexreached the double ridge stage 6 days earlier than at the lowestdensity, and this difference persisted throughout the developmentof the apex. The rate of primordium production was little affectedby density, but the duration was markedly affected. Primordiumproduction stopped abruptly, first at the highest density, andthen successively at the lower densities. At this stage changeswere seen at the tip of the apex, and eventually the 10 distalprimordia died. There were small differences in the length ofshoot apex or ear during growth, but earlier cessation of growthin the higher densities led to a shorter ear. Growth of theinternodes of the floral apex started first at the high density. These observations suggest that plants grown at high densitieshad a high concentration of gibberellins (GA) in their tissues.The promotion of apex development by the higher concentrationof GA gave rise to earlier competition for nutrients diffusingthrough the apex. This lead to starvation of the tip of theapex and earlier death of this region and, consequently, fewerspikelets. Differences in the light environment of the plants,either intensity or red/far red ratio, most probably broughtabout the differences in GA.     

A HISTOCHEMICAL STUDY OF THE SEEDLING SHOOT APICAL MERISTEM OF PINUS LAMBERTIANA

Vernalized seeds of Pinus lambertiana were scarified and planted in perlite. At 5, 8, 10, 13 and 16 days after planting, seedlings were selected for morphological examination and histochemical study. The shoot apical meristem consisted of a relatively homogeneous population of cells at 5 days. Cytohistological zonation was observed in the meristem by the eighth day and needle primordia initiation began at this time. Acid phosphatase (AP) activity was high in the extreme tip of the apex at 5 days. At 8 days AP activity was intense in the peripheral zone but weak in the apical initial and central mother cell zones. The apical meristem of the 10–16-day-old seedlings exhibited high AP activity in the peripheral zone only during the early stages of needle primordia initiation. The distribution of cytoplasmic and nuclear protein-bound SH was correlated with cytohistological zonation. Protein-bound SH was distributed relatively uniformly at 5 days, but by the eighth day the 4 cytohistological zones contained differential quantities. Succinic dehydrogenase (SD) activity was observed throughout the apex at 5 days, but by the eighth day the apical initial and central mother cell zones exhibited differentially greater levels of SD activity. Irradiation with 500 R of X-rays at 7 days after planting completely inhibited needle primordia initiation and disrupted the cytohistological zonation of the apex. Correlated with the inhibition of needle primordia initiation was the loss of SD activity in the apical initial and central mother cell zones. Irradiation also resulted in the gradual loss of protein-bound SH from the cytoplasm of the apical initial, central mother cell and peripheral zone.     

Surface-viewed shoot apex ofAngiopteris lygodiifolia Ros. (Marattiaceae)

Marattian ferns are thought to be an exception to the rule that a single apical cell is always present in the shoot apex of ferns; the occurrence of plural apical initials has been generally accepted for these ferns. However, a contradicting conclusion was reached in this study which examined the apical organization of the shoot ofAngiopteris lygodiifolia Ros., using fresh materials which had not been fixed. Shoot apices were hand-sectioned transversely into thin sections, including the surface layer of the shoot apex, which were observed by differential interference contrast microscopy without staining. In contrast with the generally accepted view, the shoot apex ofA. lygodiifolia was found to usually possess a single apical cell with three cutting faces. The segments cut off from the apical cell are regularly arranged in a helical sequence. The apical cell seems to actually function as an initial cell of the whole shoot apex. The shoot apices, particularly those of plants cultivated in a greenhouse, sometimes show somewhat irregular organization. In extreme cases, no apical cell is recognizable. However, even in these exceptional cases of such apparently irregular shoot apices, plural apical initials are not found.     

The local cytomechanical properties of growing pollen tubes correspond to the axial distribution of structural cellular elements

Morphological studies of pollen tubes have shown that the configuration of structural cellular elements differs between the growing apex and the distal part of the cell. This polarized cellular organization reflects the highly anisotropic growth behavior of this tip growing cell. Accordingly, it has frequently been postulated that physical properties of pollen tubes such as cell wall plasticity should show anisotropic distribution, but no experimental evidence for this has been published hitherto. Using micro-indentation techniques, we quantify pollen tube resistance to lateral deformation forces and analyze its visco-elasticity as a function of distance from the growing apex. Our studies reveal that cellular stiffness is significantly higher at the distal portion of the cell. This part of the cell is also completely elastic, whereas the apex shows a visco-elastic component upon deformation. To relate these data to the architecture of the particular pollen tube investigated in this study, Papaver rhoeas, we analyzed the distribution of cell wall components such as pectin, callose, and cellulose as well as the actin cytoskeleton in this cell using fluorescence label. Our data revealed that, in particular, the degree of pectin methyl esterification and the configuration of the actin cytoskeleton correlate well with the distribution of the physical properties on the longitudinal axis of the cell. This suggests a role for these cellular components in the determination of the cytomechanics of pollen tubes.