Gamete discharge by Bryopsis plumosa (Codiales, Chlorophyta) induced by blue and UV-A light

Gamete discharge by the coenocytic green alga Bryopsis plumosa (Hudson) C. Agardh is induced by light. The mature male gametangia consist of a mass of quiescent male gametes and a large central vacuole. Within a few minutes after the onset of irradiation, breakdown of the tonoplast of the central vacuole and initiation of gamete motility occur simultaneously. This is followed by a forced discharge of moving gametes through a hole ruptured at the subapical region of the gametangium. The action spectrum for the light-induced gamete discharge was determined from a series of fluence-response curves. This action spectrum, having two major maxima at 370 and 450 nm, indicates the involvement of a blue light/UV-A-absorbing photoreceptor previously described as ‘cryptochrome’.     

Production of anisogametes and gamete motility dimorphism in Monostroma angicava

 The reproductive strategy of a marine alga with a heteromorphic biphasic life cycle was studied by analyzing various sexual reproductive characters in light of the evolution of anisogamy. Gametophytes of Monostroma angicava were dioecious and their gametes were slightly anisogamous. Volume of gametangium, density of gametangia and area of mature gametangial parts on each gametophyte did not differ from male to female. Therefore, the reproductive biomass investment for gamete production was considered to be the same for each sex. Anisogamy in this alga appeared to be derived from the difference in the number of cell divisions during gametogenesis, because the majority of male gametangia each produced 64 (2⁶) gametes and the female produced 32 (2⁵) gametes. This corresponded with measurements of cell size in male and female gametes. Further, the sex ratio was 1:1 for sexually mature plants sampled at Charatsunai. Therefore, it was suggested that in the field twice as many male gametes are released as female gametes. Liberated gametes of both sexes showed positive phototaxis. The swimming velocity of freshly liberated male gametes was a little higher than that of female gametes. Male gametes had the potential to swim for ca. 72 h and female gametes for ca. 84 h. The difference in gamete motility between the two sexes seemed to be related to cell size. Planozygotes were negatively phototactic and swam more rapidly than gametes of either sex. Received: 5 March 1997 / Revision accepted: 18 July 1997     

Blue- and green-light signals for gamete release in the brown alga, Silvetia compressa

The intertidal brown alga Silvetia compressa releases gametes from receptacles (the reproductive tissue) rapidly upon a dark transfer (following a photosynthesis-dependent period in the light, termed potentiation). In this study, the wavelength-dependence of this process was investigated. During the potentiation period in white light (WL), gametes are not released. However, gametes were released during potentiation in blue light (BL), or in low red light/blue light (RL/BL) ratios, but not in RL alone, high RL/BL ratios, or in broadband blue-green light (B-GL) (presence of BL, but absence of RL). RL was as effective as WL for potentiation, i.e., both lead to gamete release following transfer to darkness. Rates of linear photosynthetic electron transport were similar in RL and BL. Gamete release in BL was inhibited by equal amounts of additional narrow-waveband light between the green and red regions of the spectrum, with light-induced gamete release restricted between <491 nm and 509 nm. Very little light-induced gamete release occurred between 530 nm and 650 nm. It is proposed that a BL-responsive photoreceptor is responsible for light-induced gamete release. Transfer of WL-potentiated receptacles to GL near 530 nm resulted in significant de-potentiation and reduced gamete release during a subsequent dark transfer. This effect was not seen at 509 nm or 560 nm and revealed the presence of a second photoreceptor system repressing or counteracting potentiation in the light. We propose that the restriction of gamete release to periods when irradiance is blue-shifted may constitute a depth-sensing mechanism for this intertidal alga, allowing controlled release of gametes at high tide and/or less turbid periods, thus minimizing gamete dilution, and promoting fertilization success.     

FLOW CYTOMETRIC ANALYSIS OF SPERMATOGENESIS IN THE DIATOM THALASSIOSIRA WEISSFLOGII (BACILLARIOPHYCEAE)1

Flow cytometry was used to detect and quantify sexual differentiation in the centric diatom Thalassiosira weissflogii (Grun.). Size (light scatter), chlorophyll, protein and DNA contents were measured for each cell throughout the process of differentiation. Male gametes were small round cells characterized by one complement of DNA and a lower protein and chlorophyll content than vegetative cells. Male gamete formation was induced by a long period of darkness (2 days) followed by a transfer to continuous light. Up to 30% of the initial cell population produced male gametes which appeared in the culture 14 h after release from darkness. Male gamete production was also detected in exponentially growing cultures in continuous light, but to a much smaller degree.     

FLOW CYTOMETRIC ANALYSIS OF SPERMATOGENESIS IN THE DIATOM THALASSIOSIRA WEISSFLOGII (BACILLARIOPHYCEAE)1

Flow cytometry was used to detect and quantify sexual differentiation in the centric diatom Thalassiosira weissflogii (Grun.). Size (light scatter), chlorophyll, protein and DNA contents were measured for each cell throughout the process of differentiation. Male gametes were small round cells characterized by one complement of DNA and a lower protein and chlorophyll content than vegetative cells. Male gamete formation was induced by a long period of darkness (2 days) followed by a transfer to continuous light. Up to 30% of the initial cell population produced male gametes which appeared in the culture 14 h after release from darkness. Male gamete production was also detected in exponentially growing cultures in continuous light, but to a much smaller degree.     

GAMETE RELEASE IS INCREASED BY CALM CONDITIONS IN THE COENOCYTIC GREEN ALGA BRYOPSIS (CHLOROPHYTA)

Water motion did not inhibit gamete release in cultures of the coenocytic green alga Bryopsis plumosa (Hudson) C. Agardh; however, the number of gametangia that released gametes increased significantly under transiently calm conditions. This stimulatory effect of calm conditions in the laboratory was found in isolates from two different areas of the Maine coast. The isolates were all monoecious, but strong differences in levels of fertilization, numbers of male and female gametes remaining following fertilization, and levels of polygamy (=zygotes formed by fusions of more than two gametes) were observed among isolates. These data support the hypothesis that organisms with external fertilization are able to sense and respond to water motion in ways that favor reproductive success.     

LIGHT AND ELECTRON MICROSCOPIC OBSERVATIONS OF PREFERENTIAL DESTRUCTION OF CHLOROPLAST AND MITOCHONDRIAL DNA AT EARLY MALE GAMETOGENESIS OF THE ANISOGAMOUS GREEN ALGA DERBESIA TENUISSIMA (CHLOROPHYTA)1

Gametogenesis in male and female gametophytes was studied by light microscopy and EM in the dioecious multinucleate green alga Derbesia tenuissima (Moris & De Notaris) P. Crouan & H. Crouan, where male and female gametes differ in size. Gametogenesis was divided into five stages: 32 h (stage 1), 24 h (stage 2), 16 h (stage 3), 8 h (stage 4), and 0.5 h (stage 5) before gamete release. At stage 1, the first sign of gametogenesis observed was the aggregation of gametophyte protoplasm to form putative gametangia. At stage 2, gametangia were separated from the vegetative protoplasm of gametophytes. Morphological changes of nuclei and organelles occurred at this early stage of male gametogenesis, and organelle DNA degenerated. At stage 3, male organelle DNA had completely degenerated, whereas in female gametangia, organelle DNA continued to exist in both chloroplasts and mitochondria. Gametogenesis was almost completed at stage 4 and fully at stage 5. Small male gametes had a DNA‐containing nucleus and a large mitochondrion and one or several degenerated chloroplasts. The mitochondria and plastids were devoid of DNA. The large female gametes had a nucleus and multiple organelles, all of which contained their own DNA. Thus, degeneration of chloroplast DNA along with morphological changes of organelles occurred at male gametogenesis in anisogamous green algae (Bryopsis and D. tenuissima), in contrast with previous studies in isogamous green algae (Chlamydomonas, Acetabularia caliculus, and Dictyosphaeria cavernosa) in which degeneration of chloroplast DNA occurred after zygote formation.     

Gametic behavior in a marine green alga, Monostroma angicava: an effect of phototaxis on mating efficiency

The role of phototactic behavior of gametes was tested experimentally in the slightly anisogamous marine green alga Monostroma angicava Kjellman, and the effect of phototaxis on mating efficiency was discovered. Both male and female gametes showed positive phototaxis in response to a white light source. In contrast, they did not respond to a red light source. Their swimming velocity did not differ between these two illuminating light sources. It was, therefore, suggested that the search ability of the gamete itself might not vary between phototactic and non-phototactic conditions. The number of zygotes formed during the mating process may be expressed as the product of the number of encounters between male and female gametes and the fraction of encounters that result in sexual fusion. In this study, with high densities of male and female gametes mixed in test tubes, almost all minor (fewer in number) gametes fused sexually within 10 min. After dilution of the gamete suspensions by half, mating efficiency in test tubes illuminated by white light from above was higher than that in dark controls. This suggests that male and female gametes gathered at the water surface through their positive phototaxis, thus increasing the rate of encounters. Mating efficiency also decreased if the test tubes were illuminated from above by white light and also shaken. Since negative phototaxis is clearly shown in planozygotes, we suggest that positive phototaxis of male and female gametes in M. angicava is an adaptive trait for increasing the rate of gametic encounters rather than for the dispersal of zygotes as previously reported for zoospores of some marine algae. Received: 12 February 1999 / Revision accepted: 24 May 1999     

Improved mating efficiency inAcetabularia acetabulum: recovery of 48–100% of the expected zygotes

Summary We have improved zygote recovery 11–1,000 fold by optimizing the physiology of gamete release and mating inAcetabularia acetabulum. Gamete release was affected by agar purity, concentration, and volume/gametangial pair. Cold pre-treatment of gametangia (14–30 d at 10°C in the dark) synchronized subsequent gamete release at 21°C in the light. Cold pre-treatment was nearly twice as effective in synchronizing subsequent gamete release when intact, gametangia-bearing caps rather than isolated gametangia were pretreated. Synchronizing gamete release doubled mating efficiency. In a wild-type laboratory strain ofA. acetabulum, there were 1,561±207 gametes/gametangium which had half-lives of 14.5 d in 0.1% seawater-agar. We recovered 48–93% of the expected numbers of zygotes from a mass mating of 8 to 1,226 gametangia and 11–128% of the expected numbers of zygotes from mating single gametangial pairs: the large range in the calculated mating efficiency may be attributable to the variation in the numbers of gametes made per gametangium. Zygote recovery from single gametangial pairs was highly dependent on the volume of mating matrix. In addition, most zygotes recovered were unattached to any other zygotes in the subsequent generation (> 95% single cells from matings of 1–500 gametangial pairs). Our improvements in mating conditions and zygote recovery (1) have facilitated cell manipulation and culture ofA. acetabulum in the laboratory; and (2) have made controlled crosses for selection and genetic analysis of mutants feasible. These advances have removed a major barrier to genetic analysis of development inAcetabularia.Abbreviations LB Luria-Bertani bacteriological broth - SE standard error of the mean - T_g agar gelling temperatures - DAPI 4,6-diamidino-2-phenylindole     

Mechanism of male gamete motility in araphid pennate diatoms from the genus Tabularia (Bacillariophyta)

During sexual reproduction, araphid pennate diatoms of the genus Tabularia (Kützing) D. M. Williams and Round released male gametes directly into the medium, sometimes at a considerable distance from the female gametes. This raised the question of how male gametes, suspended in water, manage to reach female ones, given that no locomotive organelles have been described in gametes of pennate diatoms. Optical microscopic investigation revealed cytoplasmic projections produced by male gametes of Tabularia tabulata (C. A. Agardh) Snoeijs and T. fasciculata (C. A. Agardh) D. M. Williams and Round. Morphology and behavior of these projections is consistent with pseudopodia, however, which specific type of pseudopodia they may be, remains inconclusive. The growth and retraction of the pseudopodia coincided with gamete motility and so we postulate that it explains the otherwise apparent random movement of male gametes. Spinning, shuffling and chaotic patterns of motility were documented. In theory, gamete mobility increases the probability of gamete encounter thus enhancing the probability of syngamy. This is the first known case where cytoplasmic projections have been described in diatom gametes, and possibly in mature gametes in general.     

Le corps paranucléaire des gamètes géants d'Allomyces javanicus traité à l'acide borique

Summary The gametes ofAllomyces javanicus exhibit a nuclear cap essentially made of ribonucleoprotein with sulphydryl groups.When dipped in phosphate buffered solutions of boric acid M/20–M/400, the male and female gametangia ofAllomyces liberate giant male and female gametes. Such giant gametes exhibit either a single regular nuclear cap (with 2 or 3 nuclei) or a massive and irregular basophilic formation (with 4–10 nuclei).Boric acid may interfere with ribonucleic acid, essential constituent of the nuclear cap, during the cleavage of the gamete-units in the gametangia.     

CULTURE STUDIES ON THE MARINE GREEN ALGA HALICYSTIS PARVULA—DERBESIA TENUISSIMA. II. SYNCHRONY AND PERIODICITY IN GAMETE FORMATION AND RELEASE

Unialgal cultures of the macroscopic, vesicular, coenocytic gametophyte (Halicystis parvula Schmitz) of Derbesia tenuissima (DeNotaris) Crouan fr. were grown under various environmental regimes to elucidate the cytology of gamete formation and the factors controlling synchronous gamete formation and release. No synchrony of nuclear division was observed in vegetative plants or during the early stages of gamete formation. In the later stages of gamete formation in plants in a light-dark cycle, nuclear divisions within any gametangium were synchronous, and the stages of gamete formation were synchronous for the population. This synchrony was not as great for plants in continuous light. Gametes of plants in a light-dark cycle were released explosively immediately following the dark-to-light transition. Release was random and much less forceful for plants in continuous light. After a certain stage of gamete formation, gamete release was timed to occur after a particular interval of darkness, but release could be triggered by light during the last portion of this interval. The length of the dark interval was shorter for male plants than for females, but the period of light sensitivity was longer for females. Formation of gametangia by series of isolated plants was also synchronous and sometimes periodic under certain conditions. Intervals between gametangia on the same plant varied from 2 to 14 days but were usually 4 or 5 days (unlike plants in nature, which show a bi- or tri-weekly periodicity). Male and female plants did not differ in synchrony or periodicity. Different media affected the number of gametangia formed over a period of time but not the synchrony of formation. Under some conditions changing the medium had a stimulating or synchronizing effect. Non-repeated temperature changes also synchronized gamete formation. Optimum temperature for continued gamete formation was about 21 C. Regular daily light and temperature variation together maintained synchronous and periodic gamete formation in populations of isolated plants. Reproduction diminished and became less synchronous at constant temperature either in continuous light or under a light-dark schedule, although in the light-dark regime steps in the formation of any given gametangium remained synchronous with the light-dark cycle. Length of times between gametangial formation on individual plants showed a tendency to occur in multiples of the usual period lengths; e.g., plants sometimes tend to “skip” intervals, thus maintaining the synchrony of the population. These results suggest that interaction between daily environmental cycles and an endogenous physiological cycle may maintain periodic reproduction.     

GAMETOGENESIS AND GAMETE RELEASE OF ULVA MUTABILIS AND ULVA LACTUCA (CHLOROPHYTA): REGULATORY EFFECTS AND CHEMICAL CHARACTERIZATION OF THE “SWARMING INHIBITOR”1

Gametophytes of Ulva mutabilis Føyn and Ulva lactuca L. were artificially induced to form gametangia by removal of sporulation inhibitors. After this treatment, U. mutabilis gametes were ready for swarming on the third morning after induction, while U. lactuca gametangia needed 1–2 d longer for maturation. Release of gametes of U. lactuca was dependent solely upon exposure to the first light in the morning. Gametangia of U. mutabilis, however, also required sufficient dilution of the swarming inhibitor (SWI). SWI was excreted transiently by both Ulva species early during gametogenesis. While the SWI concentration in U. mutabilis medium remained above the inhibitory concentration until the gametangia were mature, the concentration of U. lactuca‐SWI dropped rapidly below this level. In the presence of sufficient SWI, mature gametes of U. mutabilis remained motionless within the gametangia despite light and open exit pores. However, using SEM, an additional seal was detected within these pores, which probably prevented premature swarming until dilution of SWI and exposure to light. Observations by time lapse microscopy and experiments with the myosin kinase inhibitor BDM suggest that the gametes may be either extruded by the gametangium or leave the exit pore by active gliding motion, driven by a myosin‐like motor protein. The SWIs were purified from both Ulva species, and mass spectral analysis showed their molecular masses (292 Da) were identical.     

Analysis of gamete and zygote motility in Allomyces

To study the mechanisms of chemotaxis in eukaryotes, the motility patterns of the gametes and zygotes and the chemotactic responses of the male gametes of the lower eukaryote Allomyces macrogynus were examined. Dark-field microscopy of the male gametes showed a smooth swimming pattern interrupted by very brief ‘jerks’ of the cell body that caused a change in swimming direction. Female gametes had a slower swimming velocity than the males and underwent more jerks or turns which accounted for their sluggish motility. The zygotes swam with the fastest velocity and were observed to have a helical swimming pattern involving a continuous turning of the cell body, a behavior absent from the gametes. Introduction of female gametes that produce the chemoattractant sirenin brought about an immediate change in the behavior of the male gametes. They moved in spirals (or helices) towards the source of the chemoattractant (the female gametes), undergoing only a few jerks to reorient the male cells. When very near the female cells, or in high concentrations of added sirenin, many very short motility tracks were observed that finally resulted in contact between the two gamete types. The results indicate that the poor swimming ability of the female gametes facilitates gamete contact, resulting in as many as 30–40 male gametes clustered on a single female cell. Further, male gamete orientation to the sirenin gradient is caused by the chemoattractant suppressing the jerk motion.     

Untersuchungen zur Entwicklung des Phycomyceten Allomyces arbuscula

Polysomes were isolated both from growing gametophytes of Allomyces arbuscula and from gametangia prepared from mycelia at different periods during gametogenesis. Analysis of polysomes by sucrose gradients showed that ribosomes present in the gametangia monosome pool were shifted into polysomes. This shift was found to be correlated with gametangia differentiation. The ribosome distribution remained virtually unchanged during the early stage of gamete formation. In mature gametes and swarming zygotes a low level of polysomes was detected. Labeling of rRNA by ³²PO₄ demonstrated a de novo synthesis of monosomes throughout the period of gametangia differentiation. No incorporation of ³²PO₄ was found to be present in ribosomes prepared from gametangia after onset of gamete formation. On the basis of these labeling experiments it is concluded that radioactivity in polysomes extracted from mature gametes and swarming zygotes can be attributed in part to conserved mRNA.Synchronous formation of gametangia was induced by transferring the vegetative mycelia from growth medium into a low salt buffer. Under these conditions the incorporation of either ³²PO₄ or ³H-uridine into RNA, particularly into rRNA, was found to be markedly decreased. This obviously indicates a shutdown of RNA synthesis. rRNA from induced mycelia examined by polyacrylamide gel electrophoresis was found to be severely degraded. In contrast to this, rRNA isolated from ribosomes of developing gametangia and from gametes exhibited no degradation products. It is suggested that endonucleases cause rRNA hydrolysis in the hyphal cytoplasm during gametangia differentiation. Ribosomes compartmentalized in gametangia seem to be inaccessible to nucleases during the later process of gametogenesis.

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Abkürzungen MAK Methyl-Albumin-Kieselgur - PAA Polyacrylamid - stains all 4,5,4,5-Dibenzo-3,3-diäthyl-9-methylthiacarbocyaninbromid (Serva, Heidelberg)     

Preferential digestion of chloroplast DNA in male gametangia during the late stage of gametogenesis in the anisogamous algaBryopsis maxima

Summary The fate of chloroplast nuclei (cp-nuclei) and mitochondrial nuclei (mt-nuclei) was followed during gametogenesis in male and female coenocytic thalli in the anisogamous algaBryopsis maxima by epifluorescence microscopy, after staining with 4,6-diamidino-2-phenylindole (DAPI), by quantification of chloroplast DNA (cp-DNA) by fluorimetry using a video-intensified, photon-counting system (VIMPICS), and by CsCl density gradient centrifugation. The male and female coenocytic thalli, 48 h before the release of gametes, contain a large number of chloroplasts, each of which is larger in size than the cell nucleus and the mitochondria and contains about 150 cp-nuclei. The size of each chloroplast in the female and male gametangia decreases markedly during gametogenesis as a result of continuous divisions till about 10 h before the release of gametes and, eventually, the numbers of cp-nuclei per chloroplast in the male and female gametangia fall to about 20 and 5, respectively. Two hours later, as the preferential digestion of cp-DNA in the male gametangium occurs, the number of cp-nuclei in the chloroplast of each male gamete falls to zero while the number of cp-nuclei in female gamete does not change, even after release of female gametes. Several mt-nuclei are observed in all of the female gametes. By contrast, the mt-nuclei in the bulk of the male gametes disappear but those in a few gametes remain. The profiles after CsCl density gradient centrifugation of DNAs extracted from male and female plants and gametes support the cytological data. The results suggest that the preferential digestion of cp-DNA in male plants occurs about 8 h before the release of gametes and that there is differential digestion of cp-DNA and mitochondrial DNA (mt-DNA).     

AN ELECTRON MICROSCOPE STUDY OF GAMETE RELEASE AND SETTLING IN THE COMPLANATE FORM OF SCYTOSIPHON (SCYTOSIPHONACEAE,PHAEOPHYTA)1

This paper describes the ultrastructural characteristics of gametes and their liberation from the gametangia in Scytosiphon sp., a brown alga showing only slight sexual differentiation. Both male and female gametes are released initially into a central cavity which forms in the gametangial sorus by the extensive dissolution of the internal cell walls. Scytosiphon sp. gametes possess structural features in common with the zoids of other species of brown algae. Gamete fine structure is discussed in relation to cell function. After release from the gametangial sorus, female gametes can be distinguished from males by the presence of a large number of Golgi-derived vesicles with electron dense cores. It is possible that these vesicles contain the sex attractant compound. When gametes settle they become spherical, the flagella and eyespot are withdrawn into the cell and adhesive material, apparently originating from the activity of the Golgi body, appears on the surface of the cell.     

Regulation by light of ammonium transport systems in Chlamydomonas reinhardtii

The unicellular green alga Chlamydomonas reinhardtii is able to take up methylammonium/ammonium from the medium at different stages of its sexual life cycle. Vegetative cells and pre‐gametes mostly used a low‐affinity system (LATS) component, but gametes obtained after light treatment of N‐deprived pre‐gametes expressed both LATS and high‐affinity system (HATS) components for the uptake of methylammonium/ammonium. The activity of the LATS component was stimulated by light in only 5 min in a process independent of protein synthesis. By using the lrg6 mutant that produces sexually competent gametes in the dark, light effects on ammonium transport and gamete differentiation have been separately analysed. We have found light regulation of four Amt1 genes: Amt1; 1, Amt1; 2, Amt1; 4 and Amt1; 5. Whereas light‐dependent expression of Amt1; 1, Amt1; 2 and Amt1; 4 was independent of gametogenesis, and that of Amt1; 5 was activated in the lrg6 mutant, suggesting a connection between this transporter and the subsequent events taking place during gametogenesis.     

Gametic Differentiation of Chlamydomonas reinhardtii: Control by Nitrogen and Light

Gametic differentiation of the unicellular green alga Chlamydomonas reinhardtii proceeds in two steps controlled by the extrinsic signals nitrogen deficiency and light. Nitrogen deprivation induces the differentiation of vegetative cells to sexually immature pregametes. A light signal is required to convert the pregametes to gametes. Both signals are also required for the maintenance of mating competence. Two converging signal transduction chains are proposed to control gamete formation. For the differentiation of pregametes to gametes, a fluence rate-dependent reaction, requiring continuous irradiation, is suggested by photobiological experiments.     

THE ULTRASTRUCTURE OF DERBESIA TENUISSIMA (DE NOTARIS) CROUAN. I. ORGANIZATION OF THE GAMETOPHYTE PROTOPLAST,GAMETANGIUM, AND GAMETANGIAL PORE1,2,3

The fine structure of vegetative and reproductive gametophytes of Derbesia tenuissima is described. Development of the gametangium and release of the gametes progress as follows: (1) In initial stages of gametangium formation, prior to 24 hr before gamete release, there is an accumulation and proliferation of nuclei, chloroplasts, and other organelles. (2) This is followed by separation of the gametangium from the rest of the plant by a gametangial membrane; segregation of organelles into gametes has begun by 12 hr before release and the process is completed by 2.5 hr before release. (3) Enzymatic wall dissolution of the pore area occurs between 2.5 and, 12 hr before normal lights-on time. (4) The release mechanism appears to be an instantaneous light-induced increase in lurgor pressure rupturing the weakened pore area, of the wall and causing a forcible expulsion of the gametes. (5) Following release, the pore is sealed by organellar debris and the gametangial membrane. Additional wall layers are presumed to be laid down internal to the plugged pore by the vegetative protoplasm which migrates into the area.