Regulation of the orientation of cortical microtubules inSpirogyra cells

The orientation of cortical microtubules (MTs) was synchronously regulated inSpirogyra cells. While the reorganized MTs in distilled water for 1.5 hr, after 1 hr treatment with amiprophos-methyl (APM) and complete depolymerization of the MTs, were all transverse, those reorganized in 0.30 M mannitol were all oblique or longitudinal. After the MTs had reorganized in 0.30 M mannitol, these cells were then incubated in distilled water for 6 hr, and the orientation of the MTs, in the cells in which MTs could be observed, all became transverse.     

Relationship between microtubule orientation and patterns of cell expansion in developing cortical cells of Lemna minor roots

In actively growing cortical cells in the elongation zone of Lemna minor L. roots, both longitudinal (radial and tangential) and transverse walls expand in both length and width. The longitudinal walls of the three types of cortical cells in the root (i.e. outer, middle and inner) showed the largest expansion in the longitudinal axis. In contrast, the inner cortical cells exhibited the least expansion in width, whereas the middle cortical cells displayed the largest expansion in width. Thus, the profiles of the expansion of longitudinal walls were characteristic for the three types of cortical cells. In this study, both the orientation of cortical microtubule (MT) arrays and their dynamic reorientation, and the density of cortical MTs, were documented and correlated to the patterns of cell wall expansion. Significantly, transverse arrays of cortical MTs were most prominent in the radial walls of the inner cortical cells, and least so in those of the middle cortical cells. Toward the base of roots, beyond the elongation zone, the orientation of cortical MTs shifted continuously from transverse to oblique and then to longitudinal. In this case, the rate of shift in the orientation of cortical MTs along the root axis was appreciably faster in the middle cortical cells than in the other two types of cortical cells. Interestingly, the continuous change in cortical MT orientation was not confirmed in the transverse walls which showed much smaller two-dimensional expansion than the radial walls. Additionally, the presence of fragmented or shortened cortical MTs rapidly increased concomitantly with the decrease of transversely oriented cortical MTs. This relationship was especially prominent in the transverse walls of the inner cortical cells, which displayed the least expansion among the three types of cortical cells investigated. In the root elongation zone, the density of cortical MTs in the inner cortical cells was about three times higher than that in the other two cortical cell types. These results indicate that in the early stage of cell expansion, the orientation of cortical MTs determines a preferential direction of cell expansion and both the shifting orientation and density of cortical MTs affect the magnitude of expansion in width of the cell wall.     

A surgical method for accessing the plasmamembrane ofChara australis

Summary Progress in patch-clamping the plasmalemma ofChara australis has been slow because of the difficulty in obtaining a clean membrane surface upon which obtain a high resistance seal with the patch pipette. A surgical method is described here for cutting an access window in the cell wall of internodal cells fromChara australis. The method has a high success rate and also has the advantage of obviating the need for enzyme treatments. The patch-clamp technique is applied to theChara plasmalemma. Five types of channel activity are observed of which four of these are selective for Cl^– over K⁺.     

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)     

Microtubule Orientation in the Brassinosteroid Mutants <Emphasis Type="Italic">lk,lka</Emphasis> and <Emphasis Type="Italic">lkb</Emphasis> of Pea

Short brassinosteroid (BR) mutants lk, lka and lkb of pea (Pisum sativum L.) were investigated by immunofluorescence microscopy to elucidate the role of brassinosteroids in cell elongation via an effect on the microtubules (MTs). This study adds to our knowledge the fact that brassinolide (BL) can cause MT realignment in azuki bean and rescue the MT organization of BR mutants in Arabidopsis. It provides novel information on both cortical and epidermal cells and presents detailed information about the ratios of all MT orientations present, ranging from transverse (perpendicular to the elongating axis) to longitudinal (parallel to the elongating axis). Experiments were conducted in vivo using intact plants with direct application of a small amount of brassinolide (BL) to the internode. Employing a BR-receptor mutant, lka, and the BR-synthesis mutants, lk and lkb, allowed the identification and isolation of any BR-induced responses in the MT cytoskeleton following BL application. Increases in growth rate were noted in all pea lines including WT following BL application. These increases were strong in the BR-synthesis mutants, but weak in the BR-receptor mutant. Immunofluorescence revealed significant differences in the average MT orientation of cortical cells of mutants versus WTs. Importantly, these mutants possessed abundant MTs, unlike the BR-deficient bul1-1 mutant in Arabidopsis. Following BL application, the epidermal and cortical cells of lk and lkb plants showed a large and significant shift in MT orientation towards more transverse, whereas lka plants showed a small and nonsignificant response in these cells. These results suggest that the BR response pathway is linked to the regulation of MT orientation.     

Reorganization of cortical microtubules and cellulose deposition during leaf formation in Graptopetalum paraguayense

In the regeneration of a shoot from a leaf of the succulent, Graptopetalum paraguayense E. Walther the first new organs are leaf primordia. The original arrangement of cellulose microfibrils and of microtubules (MTs) in the epidermis of the leaf-forming site is one of parallel, straight lines. In the new primordium both structures still have a congruent arrangement but it is roughly in the form of concentric circles that surround the new cylindrical organ. The regions which undergo the greatest shift in orientation (90°) were studied in detail. Departures from the original cellulose alignment are detected in changes in the polarized-light image. Departures from the original cortical MT arrangement are detected using electron microscopy. The over-all reorganization of the MT pattern is followed by the tally of MT profiles, the various regions being studied in two perpendicular planes of section. This corrects for the difference in efficiency in counting transverse versus longitudinal profiles of MTs. Reorientation takes place sporadically, cell by cell, for both the cellulose microfibrils and the MTs, indicating a coordinated reorientation of the two structures. That MTs and cellulose microfibrils reorient jointly in individual cells was shown by reconstruction of the arrays of cortical MTs in paradermal sections of individual cells whose recent change in the orientation of cellulose deposition had been detected with polarized light. Closeness of the two alignments was also indicated by images where the MT and microfibril alignments co-varied within a single cell. The change-over in alignment of the MTs appears to involve stages where arrays of contrasting orientation co-exist to give a criss-cross image. During this critical reorganization, the frequency of the MTs is high. It falls during subsequent enlargement of the organ. It was found that the rearrangement of the cortical MTs to approximate a series of concentric circles on the residual meristem occurred before the emergence of leaf primordia. Through their apparent influence on microfibril alignments, the changes in MT disposition, described here, have the potential to generate major biophysical changes that accompany organogenesis.Abbreviation MT(s) microtubule(s)     

Organization of cortical microtubules in graviresponding maize roots

Immunofluorescence labeling of cortical microtubules (MTs) was used to investigate the relationship between MT arrangement and changes in growth rate of the upper and lower sides of horizontally placed roots of maize (Zea mays L. cv. Merit). Cap cells and cells of the elongation zone of roots grown vertically in light or darkness showed MT arrangements that were transverse (perpendicular) to the growth direction. Microtubules of cells basal to the elongation zone typically showed oblique orientation. Two hours after horizontal reorientation, cap cells of gravicompetent, light-grown and curving roots contained MTs parallel to the gravity vector. The MT arrangement on the upper side of the elongation zone remained transverse but the MTs of the outer four to five layers of cortical cells along the lower side of the elongation zone showed reorientation parallel to the axis of the root. The MTs of the lower epidermis retained their transverse orientation. Dark-grown roots did not curve and did not show reorientation of MTs in cells of the root cap or elongation zone. The data indicate that MT depolymerization and reorientation is correlated with reduction in growth rate, and that MT reorientation is one of the steps of growth control of graviresponding roots.Abbreviations MT microtubule - QC quiescent center This work was supported by National Science Foundation grant IBN-9118094.     

Source—sink characteristics of carbon transport in Chara hispida

Abstract Rates of uptake of ¹⁴C-labelled inorganic carbon were measured for whole Chara hispida plants, detached parts of the shoot and isolated (split-chamber technique) apices, lateral branchlets and rhizoid—node complexes. The rates of inorganic carbon uptake by the rhizoid—node complex expressed per gram fresh weight whole plant were three to four orders of magnitude less than the uptake for the whole plant. Up to 70% of the carbon taken up by the rhizoid—node complex was translocated to the shoot. After 12 h exposure to ¹⁴C-labelled inorganic carbon the concentration of ¹⁴C was greater in apices than in uppermost or central internodal cells and in all lateral branchlets, regardless of whether label was supplied to the whole plant or isolated rhizoid—node complexes. Measurement of inorganic carbon uptake by detached internodal cells and detached and isolated apices and lateral branchlets showed that lateral branchlets had the greatest rates of inorganic carbon uptake. During 12 h exposure to ¹⁴C, isolated lateral branchlets translocated to the attached shoot 55% of the labelled carbon taken up; for isolated apices this value was only 13%. It is concluded that it is highly unlikely that the rhizoid of Chara hispida could acquire a significant fraction of the whole plant requirement for inorganic carbon and that apices are sink regions for photosynthate while lateral branchlets are source regions.     

The origin and organization of cortical microtubules during the transition between M and G1 phases of the cell cycle as observed in highly synchronized cells of tobacco BY-2

The organization of microtubules (MTs) during the transition from the M phase to the G₁ phase of the cell cycle was followed in highly synchronized suspension-cultured cells ofNicotiana tabacum L. (tobacco BY-2) by sequential treatment of cells with aphidicolin and propyzamide. Short MTs were first formed in the perinuclear regions at the expense of phragmoplasts, but when these short MTs elongated to reach the cell cortex, they grew parallel to the long axis and towards the distal end of the cells. As soon as, or shortly before the tips of elongated MTs reached the distal end, transverse cortical MTs were formed in the region proximal to the division plane. Thereafter, almost all cells retained cortical MTs which were transversely orientated to the long axis of cells and could be observed in the G₁ phase. Thus, in the organization of cortical MTs, there are two steps that have been overlooked thus far. This novel observation provides a new scheme for the organization of cortical MTs, which could unify two contrasting hypotheses, i.e. organization in the perinuclear regions versus that in the cell cortex. These observations are discussed in relation to the microtubule-organizing center of plant cells.     

Re-formation of microtubules in Closterium ehrenbergii Meneghini after cold-induced depolymerization

Immunofluorescence microscopy was used to examine the re-formation of microtubules (MT), after cold-induced depolymerization, in Closterium ehrenbergii. The C. ehrenbergii cells undergo cell division followed by semicell expansion in the dark period of daily light-dark cycles. Five types of MTs, namely the MT ring, hair-like MTs around the nuclei, spindle MTs, radially arranged MTs and transverse wall MTs, appeared and disappeared sequentially during and following cell division. The wall MTs were distributed transversely only in the expanding new semicells. When cells were chilled in ice water, wall MTs in expanding cells were fragmented, and then disappeared as did the other types of MTs, within 5 min. When cells were warmed at 20°C after 2 h chilling, wall MTs and the other types of MTs re-formed. At the early stage of wall-MT re-formation in expanding cells, small, star-like MTs were formed, and then randomly oriented MTs developed in both the expanding new and the old semicells. The MT ring was also re-formed at the boundary between the new and old semicells. There were no obvious MT-organizing centers in the random arrangement. As time passed, the randomly oriented wall MTs in the old semicells disappeared and those in the expanding new semicells gradually assumed a transverse orientation. These results indicate that wall MTs can be rearranged transversely after they have been re-formed and that nucleation of wall MTs is separable from the mechanism for ordering them.Abbreviations MT(s) microtubule(s) - MTOC(s) microtubule-organizing center(s)     

Root contraction in hyacinth III. Orientation of cortical microtubules visualized by immunofluorescence microscopy

Summary Cortical microtubules (MTs) were visualized in root cortex cells ofHyacinthus orientalis L. using immunofluorescence techniques. Cellular MT orientation was determined adjacent to radial longitudinal and transverse walls of root tip, uncontracted, contracting, and fully contracted regions. As seen in longitudinal views, MTs formed parallel, apparently helical arrays which were oriented transversely, axially or obliquely depending upon the region. Transverse sectional views showed that MTs adjacent to transverse cell walls formed a variety of patterns which varied with developmental stage and cell location. Microtubules were oriented in crisscross or parallel arrays. The parallel arrays were oriented either parallel, perpendicular or oblique to the radius of the root. There was an apparent temporal progression in MT reorientation from outer cortical to inner cortical cell layers. A resultant progression of reoriented cell growth could account for root contraction. These findings corroborate earlier electron microscopic observations of changing MT orientation accompanying root contraction, and provide cytological evidence to test mathematical and biophysical models of the mechanics of cell expansion.Abbreviations MT microtubule - MF microfibril - MTSB microtubule stabilizing buffer - PBS phosphate buffered saline     

Microtubule organization in the differentiating transfer cells of the placenta inLilium spp.

Summary Placental cells in the ovarian transmitting tissue ofLilium spp. are organized as transfer cells with inbuddings facing the ovarian locule. A detailed analysis of microtubule (MT) organization during development of these polarized cells is reported here. Formation of wall projections occurs at the apical part of the cell starting on the day of anthesis, and a fully mature secretion zone is found four days after anthesis. MTs are organized into distinct cortical and central arrays. The cortical array undergoes a unique transition at anthesis. MTs in the basal half of the cell remain in longitudinal bundles while in the apical half of the cell their longitudinal orientation is replaced by a transverse alignment. One day after anthesis, these transverse bundles become a meshwork of short, randomly organized MTs, while MTs in the basal half of the cell retain their longitudinal alignment. The realignment of MTs in the apical half of the cell coincides with the deposition of the secondary cell wall. The central array is composed of short, randomly arranged strands of MTs in the cytoplasm between the nucleus and the apical and basal periclinal walls of the cell. This array first appears as solitary strands in the apical part of the cell one day before anthesis. The central array extends during development and is eventually seen in the basal half of the cell. We propose that MTs in the cortical region near the apical wall act as templates for the deposition of cellulose microfibrils in the secondary cell wall. MTs in the central array in these transfer cells may be involved in the trafficking of vesicles and/or positioning of organelles near the secretion zone.Abbreviations MT microtubule - daa day after anthesis - dba day before anthesis     

Dynamic changes in the arrangement of cortical microtubules in conifer tracheids during differentiation.

The arrangement of cortical microtubules (MTs) in differentiating tracheids of Abies sachalinensis Masters was examined by confocal laser scanning microscopy after immunofluorescent staining. The arrays of MTs in the tracheids during formation of the primary wall were not well ordered and the predominant orientation changed from longitudinal to transverse. During formation of the secondary wall, the arrays of MTs were well ordered and their orientation changed progressively from a flat S-helix to a steep Z-helix and then to a flat S-helix as the differentiation of tracheids proceeded. The orientation of cellulose microfibrils (MFs) on the innermost surface of cell walls changed in a similar manner to that of the MTs. These results provide strong evidence for the co-alignment of MTs and MFs during the formation of the semi-helicoidal texture of the cell wall in conifer tracheids.Abbreviations MT cortical microtubule - MF cellulose microfibril - S1, S2 and S3 the outer, middle and inner layers of the secondary wall The authors thank Mr. T. Itoh of the Electron Microscope Laboratory, Faculty of Agriculture, Hokkaido University, for his technical assistance. This work was supported in part by a Grant-in-Aid from the Ministry of Education, Science and Culture, Japan (no. 06404013).     

Allelopathic activity of Chara aspera

Allelopathic activity of Chara aspera was determined in agar diffusion assays using planktonic cyanobacteria as target organisms. Growth inhibition of cyanobacterial strains was observed in bioassays inoculated with living Chara aspera shoots as well as with 60% aqueous methanol extracts of Chara aspera. For further analysis, the methanol extract was fractionated into three parts: a lipophilic methanol – a butylmethylether-extract and a hydrophilic methanol extract. The bioassays indicated that major allelopathic activity was retained in the hydrophilic methanol – and the lipophilic butylmethylether-extract. Separation of the extracts by means of high performance liquid chromatography followed by fractionation of the eluant resulted in supplementary nine fractions, three from each part, respectively. Three fractions exhibited a strong growth inhibition of the target organism Anabaena cylindrica Lemmermann. The second and the third fraction of the lipophilic butylmethylether extract indicate the presence of novel allelopathic active compounds with lipophilic characteristics. The results lead to the suggestion that more than two chemical compounds in Chara aspera are responsible for the growth inhibition of cyanobacteria.     

Internodal elongation and orientation of cellulose microfibrils and microtubules in deepwater rice

Excised stem sections of deepwater rice (Oryza sativa L.) containing the highest internode were used to study the induction of rapid internodal elongation by gibberellin (GA). It has been shown before that this growth response is based on enhanced cell division in the intercalary meristem and on increased cell elongation. In both GA-treated and control stem sections, the basal 5-mm region of the highest internode grows at the fastest rate. During 24 h of GA treatment, the internodal elongation zone expands from 15 to 35 mm. Gibberellin does not promote elongation of internodes from which the intercalary meristem has been excised. The orientation of cellulose microfibrils (CMFs) is a determining factor in cell growth. Elongation is favored when CMFs are oriented transversely to the direction of growth while elongation is limited when CMFs are oriented in the oblique or longitudinal direction. The orientation of CMFs in parenchymal cells of GA-treated and control internodes is transverse throughout the internode, indicating that CMFs do not restrict elongation of these cells. Changes in CMF orientation were observed in epidermal cells, however. In the basal 5-mm zone of the internode, which includes the intercalary meristem, CMFs of the epidermal cell walls are transversely oriented in both GA-treated and control stem sections. In slowly growing control internodes, CMF orientation changes to the oblique as cells are displaced from this basal 5-mm zone to the region above it. In GA-treated rapidly growing internodes, the reorientation of CMFs from the transverse to the oblique is more gradual and extends over the 35-mm length of the elongation zone. The CMFs of older epidermal cells are obliquely oriented in control and GA-treated internodes. The orientation of the CMFs parallels that of the cortical microtubules. This is consistent with the hypothesis that cortical microtubules determine the direction of CMF deposition. We conclude that GA acts on cells that have transversely oriented CMFs but does not promote growth of cells whose CMFs are already obliquely oriented at the start of GA treatment.     

Reorientation of microtubules at the outer epidermal wall of maize coleoptiles by phytochrome,blue-light photoreceptor,and auxin

Summary The effects of red and blue light on the orientation of cortical microtubules (MTs) underneath the outer epidermal wall of maize (Zea mays L.) coleoptiles were investigated with immunofluorescent techniques. The epidermal cells of dark-grown coleoptiles demonstrated an irregular pattern of regions of parallel MTs with a random distribution of orientations. This pattern could be changed into a uniformly transverse MT alignment with respect to the long cell axis by 1 h of irradiation with red light. This response was transient as the MTs spontaneously shifted into a longitudinal orientation after 1–2 h of continued irradiation. Induction/reversion experiments with short red and far-red light pulses demonstrated the involvement of phytochrome in this response. In contrast to red light, irradiation with blue light induced a stable longitudinal MT alignment which was established within 10 min. The blue-light response could not be affected by subsequent irradiations with red or far-red light indicating the involvement of a separate blue-light photoreceptor which antagonizes the effect of phytochrome. In mixed light treatments with red and blue light, the blue-light photoreceptor always dominated over phytochrome which exhibited an apparently less stable influence on MT orientation. Long-term irradiations with red or blue light up to 6 h did not reveal any rhythmic changes of MT orientation that could be related to the rhythmicity of helicoidal cell-wall structure. Subapical segments isolated from dark-grown coleoptiles maintained a longitudinal MT arrangement even in red light indicating that the responsiveness to phytochrome was lost upon isolation. Conversely auxin induced a transverse MT arrangement in isolated segments even in blue light, indicating that the responsiveness to blue-light photoreceptor was eliminated by the hormone. These complex interactions are discussed in the context of current hypotheses on the functional significance of MT reorientations for cell development.Abbreviations MT cortical microtubule - P_r, P_fr red and far-red absorbing form of phytochrome     

Studies on semipermeability and electrical characteristics in membranes of<Emphasis Type="Italic"> Chara</Emphasis> cells fixed with glutaraldehyde

When internodal cells of Chara corallina were incubated in a solution containing 1% glutaraldehyde, an increase in intracellular osmolality was observed, and this indicates that the plasma membrane maintained its semipermeability. The effect on the membrane potential was studied. Although the active component generated by the electrogenic proton pump was lost, the passive component (more negative than –100 mV) was maintained during glutaraldehyde treatment for more than 1–2 h. The membrane resistance increased significantly. It was found that the tonoplasts also maintained their semipermeability during glutaraldehyde treatment.     

A mycorrhizal fungus changes microtubule orientation in tobacco root cells

Summary Cortical cells of mycorrhizal roots undergo drastic morphological changes, such as vacuole fragmentation, nucleus migration, and deposition of cell wall components at the plant-fungus interface. We hypothesized that the cytoskeleton is involved in these mechanisms leading to cell reorganization. We subjected longitudinal, meristem to basal zone, sections of uninfectedNicotiana tabacum roots to immunofluorescence methods to identify the microtubular (MT) structures associated with root cells. Similar sections were obtained from tobacco roots grown in the presence ofGigaspora margarita, an arbuscular mycorrhizal fungus which penetrates the root via the epidermal cells, but mostly develops in the inner cortical cells. While the usual MT structures were found in uninfected roots (e.g., MTs involved in mitosis in the meristem and cortical hoops in differentiated parenchyma cells), an increase in complexity of MT structures was observed in infected tissues. At least three new systems were identified: (i) MTs running along large intracellular hyphae, (ii) MTs linking hyphae, (iii) MTs binding the hyphae to the host nucleus. The experiments show that mycorrhizal infection causes reorganization of root MTs, suggesting their involvement in the drastic morphological changes shown by the cortical cells.     

The microtubular cytoskeleton during development of the zygote,proembryo and free-nuclear endosperm inArabidopsis thaliana (L.) Heynh

The microtubular cytoskeleton has been studied during development of the zygote, proembryo and free-nuclear endosperm inA. thaliana using immunofluorescence localization of tubulin in enzymatically isolated material. Abundant micro tubules (MTs) are found throughout proembryogenesis. Microtubules in the coenocytic endosperm are mainly internal. By contrast, there is a re-orientation of MTs to a transverse cortical distribution during zygote development, predominantly in a subapical band which accompanies a phase of apical extension. The presence of these cortical arrays coincides with the elongation of the zygote. Cortical arrays also accompany elongation of the cylindrical suspensor. Extensive networks of MTs ramify throughout the cytoplasm of cells in the proembryo proper. Perinuclear arrays are detected in a number of cell types and MTs contribute to typical mitotic configurations during nuclear divisions. Preprophase bands of MTs are absent throughout megasporogenesis and embryo-sac development and do not occur in endosperm cell divisions. We have observed MTs throughout the first division cycle of the zygote. By placing the observed stages in a most probable sequence, we have identified this cell cycle as the point during embryogenesis at which a preprophase band is reinstated as a regular feature of cell division. Preprophase bands were observed to predict planes of cytokinesis in cell divisions up to the octant stage.Abbreviations DIC differential interference contrast optics - MT microtubule - PPB preprophase band of microtubule We thank Ms. Margaret Travers for her helpful English translation of Yakovlev and Alimova (1976) and Mr. James Whitehead for preparation of Fig. 11. M.C.W. was supported by an Australian Postgraduate Research Award.     

Oospore dimensions and wall ornamentation in <Emphasis Type="Italic">Chara braunii</Emphasis>

Morphological features of oospores of a rarely noted species Chara braunii Gmel. were examined in a local population (fishpond near Tuplice village, Ziemia Lubuska region, mid-western Poland). The largest polar axis (LPA, length), largest equatorial diameter (LED, width), isopolarity index (ISI = LPA/LED* 100), and the number of ridges and width of fossa of 90 oospores were measured. Additionally, the oospore wall ornamentation pattern was examined by means of scanning electron microscopy (SEM). As a result, a cylindrical shape and the lack of so-called “shoulder” were found. Oospore length and width ranged between 466.8–600.1 μm and 250.1–366.7 μm, respectively, with the ISI index values between 148 and 213. The number of ridges was 8–10 and the width of fossa varied between 50.0 and 66.7 μm. The oospore width appeared to be the most changeable feature, whereas, by contrast, the number of ridges was the least variable character. Wall ornamentation can be described as tuberculate and a ribbon was present on the ridges. As a comparative material for the study performed, 9 oospores from Professor Izabela Dąmbska’s Collection of Charophytes of Poland were measured. It was evidenced that variation ranges of most of the features of Chara braunii oospores from Tuplice fishpond are similar to those of Professor Dąmbska’s herbarium materials and to data reported by authors from other countries as well. The morphology of reproductive structures does not follow the variation of thalli characteristics.