Polarity and growth of caulonema tip cells of the moss Funaria hygrometrica

In the caulonema tip cells of Funaria hygrometrica, chloroplasts, mitochondria, and dictyosomes have differences in structure which are determined by cell polarity. In contrast to the slowly growing chloronema tip cells the apical cell of the caulonema contains a tip body. Colchicine stops tip growth; it causes the formation of subapical cell protrusions, redistribution of the plastids, and a loss of their polar differentiation. Cytochalasin B inhibits growth and affects the position of cell organelles. After treatment with ionophore A23 187, growth is slower and shorter and wider cells are formed. D₂O causes a transient reversion of organelle distribution but premitotic nuclei are not dislocated. In some tip cells the reversion of polarity persists; they continue to grow with a new tip at their base. During centrifugation, colchicine has only a slight influence on the stability of organelle anchorage. The former polar organization of most cells is restored within a few hours after centrifugation, and the cells resume normal growth. In premitotic cells the nucleus and other organelles cannot be retransported, they often continue to grow with reversed polarity. Colchicine retards the redistribution of organelles generally and increases the number of cells that form a basal outgrowth. The interrelationship between the peripheral cytoplasm and the nucleus and the role of microtubules in maintaining and reestablishing cell polarity are discussed.Abbreviations DMSO dimethylsulfoxide - CB cytochalasin B Dedicated to Prof. Dr. A. Pirson on the occasion of his 70. birthday     

Distribution of activated calmodulin in the chloronema tip cells of the moss Funaria hygrometrica

Auxin (indole-3-acetic acid) regulates caulonema differentiation as a result of gradual transitional events in the chloronema tip cells in moss protonema. This auxin action in the moss Funaria hygrometrica involves a rapid influx of calcium ions from the extracellular medium. This investigation demonstrates spatial and temporal changes in calmodulin (CaM) activation (formation of Ca(2+)-CaM complex) in the chloronema tip cells subjected to auxin treatment. Photomicroscopic localisation of the fluorescence (excitation at 365 nm and emission of 397 nm) from the tricomplex of Ca(2+)-CaM with trifluoperazine (TFP, a blocker of Ca(2+)-CaM action) shows a tip to base (tip high) gradient of Ca(2+)-CaM in the chloronema tip cells. Comparison of Ca(2+)-CaM-TFP fluorescence over time in the chloronema tip cells of wild type Funaria with the response in an auxin overproducer mutant (86.1) and an auxin deficient mutant (87.13) reveals the involvement of auxin in calmodulin activation as a rapid response prior to cell differentiation.     

Unique Tissue-Specific Cell Cycle in Physcomitrella

Abstract: The moss Physcomitrella patens (Hedw.) B.S.G. is a novel tool in plant functional genomics as it has an inimitable high gene targeting efficiency facilitating the establishment of gene/function relationships.
Here we report, based on flow cytrometric (FCM) data, that the basic nuclear DNA content per cell of Physcomitrella is 0.53 pg, equating to a genome size of 1 C = 511 Mbp. Furthermore, we describe a unique tissue-specific cell cycle change in this plant. Young plants consisting of only one cell type (chloronema) displayed one single peak of fluorescence in FCM analyses. As soon as the second cell type (caulonema) developed from chloronema, a second peak of fluorescence at half the intensity of the previous one became detectable, indicating that caulonema cells were predominantly at the G1/S transition, whereas chloronema cells were mainly accumulating at the G2/M transition. This conclusion was validated by further evidence: i) The addition of ammonium tartrate arrested Physcomitrella in the chloronema state and in G2/M. ii) Two different developmental mutants, known to be arrested in the chloronema/caulonema transition, remained in G2/M, regardless of age and treatment. iii) The addition of auxin or cytokinin induced the formation of caulonema, as well as decreasing the amount of cells in G2/M phase. Additionally, plant growth regulators promoted endopolyploidisation.
Thus, cell cycle and cell differentiation are closely linked in Physcomitrella and effects of plant hormones and environmental factors on both processes can be analysed in a straight forward way. We speculate that this unique tissue-specific cell cycle arrest may be the reason for the uniquely high rate of homologous recombination found in the Physcomitrella nuclear DNA.     

Characteristics of spore germination and protonemal development in Hypnum pacleseens

The spore germination,protonemal development,and gametophyte differentiation of Hypnum pacleseens were observed in cultivation.Photomicrographs showed that spore germination of Hypnum pacleseens occured within the exospore.Its protonema is massive with filamentous chloronema formed inside.The terminal part of the chloronema differentiated into filamentous caulonema and its rhizoid was derived from the apical cell of the filamentous chloronema.The initial cell of gametophyte differentiated from chloronema and caulonema.Sporeling type of Hypnum pacleseens is developmentally similar to Glyphmitrium-type.     

尖叶拟船叶藓原丝体发育特征研究

将尖叶拟船叶藓[Dolichomitriopsis diversiformis(Mitt.)Nog.]孢子接种于Knop培养基上,置于恒温培养箱中培养,在光学显微镜下对其原丝体(protonema)发育特征进行了详细观察和记录。结果表明:孢子第2天就开始萌发,第6天时其萌发率达90%以上;原丝体系统由绿丝体(chloronema)和轴丝体(caulonema)构成,假根(rhizoides)产生于芽体基部,由轴丝体退化而成;配子枝原始细胞产生于绿丝体分枝的基部或轴丝体上的斜壁细胞;配子枝(game tophore)形成后其上各部位都可形成假根;孢子萌发类型为真藓型(Bryum-type)。     

Characteristics of spore germination and protonemal development in Hypnum pacleseens

The spore germination, protonemal development, and gametophyte differentiation of Hypnum pacleseens were observed in cultivation. Photomicrographs showed that spore germination of Hypnum pacleseens occured within the exospore. Its protonema is massive with filamentous chloronema formed inside. The terminal part of the chloronema differentiated into filamentous caulonema and its rhizoid was derived from the apical cell of the filamentous chloronema. The initial cell of gametophyte differentiated from chloronema and caulonema. Sporeling-type of Hypnum pacleseens is developmentally similar to Glyphmitrium-type.     

Occurrence and biosynthesis of auxin in protonema of the moss Funaria hygrometrica

We have investigated the presence of auxin and the ability of chloronema cells to synthesize indole-3-acetic acid (IAA) in axenic protonema cell cultures of the moss Funaria hygrometrica. The endogenous level of auxin activity was 4 and 7μg-IAA equivalents/kg in caulonema and chloronema cell types, respectively. Based on an indole-α-pyrone fluorometric assay, the level of putative IAA was observed to be 5.0 and 1.9.μg/kg in caulonema and chloronema cells, respectively. [³H]Tryptophan was metabolized into IAA via the indole-pyruvate pathway by intact chloronema cells and also by the cell free homogenates. More [³H]IAA accumulated when homogenates from cells pre-grown at low cell densities (< 0.5 mg/ml) as compared to those at high cell densities ( > 0.5 mg/ml) were used. Since the activities of peroxidase and IAA-oxidase are known to be high at high cell densities, the lack of accumulation of radioactivity in IAA at high densities can be attributed to a high level of IAA-oxidizing enzymes. Our results suggest a possible relationship between IAA accumulation and caulonema differentiation.     

Intrusive growth of flax phloem fibers is of intercalary type

Flax (Linum usitatissimum L.) phloem fibers elongate considerably during their development and intrude between existing cells. We questioned whether fiber elongation is caused by cell tip growth or intercalary growth. Cells with tip growth are characterized by having two specific zones of cytoplasm in the cell tip, one with vesicles and no large organelles at the very tip and one with various organelles amongst others longitudinally arranged cortical microtubules in the subapex. Such zones were not observed in elongating flax fibers. Instead, organelles moved into the very tip region, and cortical microtubules showed transversal and helical configurations as known for cells growing in intercalary way. In addition, pulse-chase experiments with Calcofluor White resulted in a spotted fluorescence in the cell wall all over the length of the fiber. Therefore, it is concluded that fiber elongation is not achieved by tip growth but by intercalary growth. The intrusively growing fiber is a coenocytic cell that has no plasmodesmata, making the fibers a symplastically isolated domain within the stem. Electronic Supplementary Material Supplementary material is available for this article at     

Connection between the Synthesis of Differentiation Specific Proteins and the Capacity of Cells to Respond to Cytokinin in the Moss Funaria

The differentiation stage of the caulonema in Funaria hygrometrica protonema is distinguished from the chloronema stage by three additional protein bands (CSP) in the soluble protein fraction. During the change of caulonema to chloronema, which is induced by isolation of single filaments (regeneration), the CSP disappear. This is not the consequence of an accelerated degradation or turnover but of a gradual termination in the de novo synthesis of CSP during regeneration as demonstrated by pulse-chase experiments with l -[4,5–³H] leucine. Cytokinin inhibits the termination of the synthesis of CSP. The decrease in synthesis parallels the decrease in ability of the isolated caulonema cells to respond to cytokinin via bud formation. It is therefore concluded that the CSP are involved in the competence of caulonema cells to respond to cytokinins.     

Development of the protonema and bud formation in mosses

In the course of their development the protonemata of Funaria hygrometrica produce two different substances which diffuse into the substrate. In the chloronema a thermo-labile growth-promoting substance is formed. In the caulonema, after about 10 days, a substance is produced which is thermostable and soluble in amyl alcohol, which can be dialysed, and which functions as a growth inhibitor. Both substances also influence bud formation. This is at an optimum only when there is a certain balance between these two substances.
This promotion is fundamentally different from that brought about by treatment with kinetin, because kinetin can function only as an additional factor in promoting bud formation. Very probably it acts as an agent which creates centres of attraction toward which morphogenetic substances are drawn. This assumption is supported by the fact that kinetin cannot be transported and therefore has no 'after-effect'. It probably functions only in the caulonema cell it penetrates. It converts every caulonema cell into a 'reaction cell'.     

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)     

On the formation of protonema ofDrummondia sinensis of the orthotrichaceae

In the present study, the mode of formation of the protonema ofDrummondia sinensis is recorded and the relationship between the sporeling type as a response to ecological adaptation is discussed. A spore germinates inside the stretched exospore, and later forms a massive protonema consisting of 8–20 cells. Soon after, the stretched spore coat ruptures and a mass of 5–6 cells protrdes from the broken exospore. In this species neither chloronema nor caulonema could be observed, although such is often seen in other species of Bryales. An initial cell of the leafy shoot is formed from the apical cell of the massive protonema.     

Cytokinin increases intracellular Ca2+ in Funaria: detection with Indo-1.

Changes in intracellular [Ca2+] ([Ca2+]i) after cytokinin-treatment in protonema cells of the moss Funaria hygrometrica have been measured using the pentapotassium salt of Indo-1. The extent of dye loading strongly depended on lowering the pH of the incubation medium to 5.0. Exposing dye-loaded cells briefly with Mn2+ did not quench fluorescence suggesting that the source of fluorescence is from the cytoplasm and not from the cell wall. Indo-1 remains responsive to changes in [Ca2+]i in Funaria cells. The [Ca2+]i in quiescent cells (with and without extracellular Ca2+) is 250 nM, which is within the range of reported [Ca2+]i of other plant cells. Treatment of cells with extracellular cytokinin in 4 mM Ca2+ induced a three-fold increase in [Ca2+]i to 750 nM in target caulonema cells. This increase was not observed in Ca(2+)-free medium. These target cells respond to cytokinin treatment by an asymmetrical division, while non-target chloronema cells do not divide. Cytokinin appears to increase [Ca2+]i by extracellular Ca2+ uptake. However, non-target chloronema cells and tip cells also respond to cytokinin treatment by increasing [Ca2+]i. The differential physiological response of these cell types to hormonal stimulation must lie further down the signal transduction chain.     

大帽藓(Encalypta ciliata Hedw.)原丝体发育特征的实验研究

在人工培养大帽藓(Encalypta ciliata Hedw．)孢子的基础上,对其孢子萌发、原丝体发育及配子体发生的全过程进行行了观察、描绘和照相。实验结果表明：在大帽藓的原丝体系统中主要包括两种成分,即：粗短的丝状绿丝体和细长的柳枝状轴丝体。丝状绿丝体一般由4～6个短粗柱状细胞组成,而轴丝体则是由多数细长柱形细胞构成,其上间隔分布有2～5个细胞组成的棒状体,初生假根有或者无。同时,还对大帽藓原丝体发育的特征进行了分析和讨论,初步确定大帽藓孢子萌发属于新的孢子萌发类型——大帽藓型(Encalypta-type)。     

大帽藓(Encalypta ciliata Hedw.)原丝体发育特征的实验研究

在人工培养大帽藓(Encalypta ciliata Hedw.)孢子的基础上,对其孢子萌发、原丝体发育及配子体发生的全过程进行了观察、描绘和照相。实验结果表明:在大帽藓的原丝体系统中主要包括两种成分,即:粗短的丝状绿丝体和细长的柳枝状轴丝体。丝状绿丝体一般由4～6个短粗柱状细胞组成;而轴丝体则是由多数细长柱形细胞构成,其上间隔分布有2～5个细胞组成的棒状体,初生假根有或者无。同时,还对大帽藓原丝体发育的特征进行了分析和讨论,初步确定大帽藓孢子萌发属于新的孢子萌发类型——大帽藓型(Encalypta-type)。     

Cytokinin induces the developmentally restricted synthesis of an extracellular protein in Physcomitrella patens

Early development of the moss Physcomitrella patens follows a simple course leading to the formation of a filamentous protonema containing only two cell-types, chloronema and caulonema. The addition of the hormone cytokinin leads to the induction of multicellular buds from such protonema. The spectrum of extracellular proteins (ECPs) synthesized by P. patens has been investigated at defined stages of development and under defined hormone treatments. It is found that in contrast to the limited changes in intracellular protein synthesis detectable, in the extracellular environment major and specific changes in the patterns of proteins synthesized occur. For example, the presence of caulonema cells is characterized by the synthesis of a 25 kDa ECP whereas early chloronema differentiation is distinguished by the presence of a 38 kDa ECP. The analysis of the pattern of ECPs synthesized by developmental mutants altered in bud formation, and in response to cytokinin in tunicamycin treated protonema (in which bud induction is blocked) indicate that the synthesis of a 14 kDa ECP is specifically induced by cytokinin. This protein represents a novel cytokinin-induced ECP. These data show that the differentiation of particular cell types in plants is associated with the synthesis of particular ECPs, and suggest that hormones which induce specific morphogenic events may do so via the synthesis of specific ECPs.     

How cotton fibers elongate: a tale of linear cell-growth mode

Cotton fibers (cotton lint) are single-celled trichomes that differentiate from the ovule epidermis. Unidirectional and fast-growing cells generally expand at the dome-shaped apical zone (tip-growth mode); however, previous studies suggest that elongating fiber cells expand via a diffuse-growth mode. Tip-localized Ca(2+) gradient and active secretary vesicle trafficking are two important phenomena of tip-growth. Recently, a high Ca(2+) gradient is found in the cytoplasm of fast-elongating cotton fiber cells near the growing tip. Several protein coding genes participating in vesicle coating and transport are highly expressed in elongating fiber cells. Taken together with the observation that ethylene acts as a positive regulator for cotton fiber and several Arabidopsis tissues that are known to elongate via tip growth prompted us to propose a linear-growth mode for similar cell types.     

Uptake, transport and metabolism of cytokinin in moss protonema

Uptake, transport and metabolism of cytokinin in the protonemaof Funaria hygrometrica were studied using labelled kinetin(6-furfurylamino [8-¹⁴C]-purine). All cells of the protonema,chloronema and caulonema, were able to take up kinetin, whichwas carried in the symplastic transport system from cell tocell. Radioactivity was especially accumulated in growing cellsof the protonema. Kinetin was metabolized immediately afteruptake. While only very little kinetin (less than 1%) remainedas free kinetin and one part was immobilized in chromatographicseparation [e.g. attached to proteins and incorporated intonucleic acids (17)], most of the remaining kinetin was metabolizedto adenine derivatives. Exogenously supplied adenosine changedthe metabolism of kinetin. In the caulonema, adenosine reducedthe turnover of kinetin to other adenine derivatives and enhancedthe content of labelling in the start fraction. Thus adenosinecan stimulate cytokinin-dependent bud formation in moss protonema. (Received November 24, 1977; )     

On the action mechanism of cytokinins in mosses: Caulonema specific proteins

Soluble proteins extracted with Tris-buffer pH 8.8 from both differentiation stages of the protonema of Funaria hygrometrica (chloronema and caulonema) were separated by microgel electrophoresis. 4x10^-3 mg protein/gel was applied. The caulonema, which is the only part of the protonema able to form buds following cytokinin treatment, contained 3 protein bands, which were absent in chloronema. We designate them as caulonema specific proteins (CSP, approximate molecular weight 500,000). The CSP disappear when the caulonema is isolated and its cells regenerate to chloronema. The CSP bind kinetin (6 Furfurylamino [8-¹⁴C]purine) or BAP (6-benzylamino[8-¹⁴C]purine) about 10 times stronger than the remaining protein bands in the gel. The greatest part of the cytokinin is metabolized in a short time and consequently a part of the activity in the gel is incorporated into RNA and removable with RNase. Simultaneous application of adenosine and cytokinin reduced the incorporation of radioactivity into RNA and enhanced the specific activity in one of the CSP bands. In all other bands it remained unchanged.From the results it can be suggested that the CSP are probably involved in the early reactions to cytokinin of the target cells.Abbreviations CSP Caulonema specific proteins - BAP 6-benzylaminopurine - GA₁ gibberellin A₁