Morphogenesis in the Heterotrich Ciliate Climacostomum virens. I. Oral Development During Cell Division

The principal characteristics of stomatogenesis during division in Climacostomum virens are: (A) Kinetosomal proliferation on the left side of a variable number of kineties in the ventral somatic cortex forms an oral primordium consisting of several kinetosomal fields, which then fuse to form a single anarchic field. (B) A constant topographical relationship exists between the primordium and a well defined cortical pattern, the zone of discontinuity. (C) The anarchic field primordium divides into 2 unequal parts—to the left, the AZM primordium, and to the right, the paroral primordium, which differentiates into the apical membranelles, the peristomial field, and the buccal tube. (D) Preoral and oblique kineties of the somatic cortex form along the right side of the paroral primordium. (E) Parental oral structures are partially dedifferentiated. Stomatogenesis in C. virens and other heterotrichs is compared.     

Physiological Reorganization and Post-Traumatic Regeneration in Stylonychia mytilus: Reflections on Developmental Constraints and the Evolutionary Origin of Alternative Modes of Asexual Morphogenesis

We investigated development of cortical ciliature in Stylonychia mytilus during starvation-induced physiological reorganization, and during regeneration following amputation of the anterior part of the cell. Cortical reorganization in the two processes is generally similar. The posterior part of the adoral zone of membranelles is resorbed and replaced with newly assembled membranelles. The pre-existing set of ventral cirri and dorsal bristles is entirely resorbed and replaced with new ones. Regenerants exhibit posterior displacement of the frontal-ventral-transverse cirri primordium and the undulating membrane primordium, and recruit basal bodies from ectopic locations for the development of these ciliature. This illustrates flexibility in the initiation site of ciliary primordia, and opportunism in utilizing building blocks. Such morphogenetic versatility of hypotrichs provides the basis for the operation of a global control of pattern formation, which governs cortical reorganization in dividers, and additionally, in the absence of the prerequisites for binary fission, alternative modes of cortical development such as physiological reorganization or regeneration. These considerations suggest that the three processes are homologous and that physiological reorganization and regeneration have evolved from binary fission. In physiological reorganization and regeneration, the micro- and macronuclei reorganize to resemble that in binary fission; these nuclear events are considered evolutionary relics of the nuclear development of binary fission. Tetrahymena also exhibits such morphogenetic flexibility; stomatogenesis is under global control, so that asexual cells can replace its oral apparatus without undergoing binary fission. Paramecium , on the other hand, adopts a more rigid strategy in relying heavily on pre-existing structures for morphogenetic cues; this could have imposed constraints in the exploration of alternative modes of asexual development.     

Stomatogenesis and Formation of Cirri in Fragments of Oxytricha fallax Stein

Of fragments involving a partial removal of the original adoral zone of membranelles (AZM), the monomacro-nucleate ones become reorganized monostomes resulting from a simple fusion of the remnant AZM to the oral primordium induced, and the binucleate ones become dividers by initiation of the oral primordium posteriorly from the posterior terminal of the remnant AZM. The cirral primordium in any fragment arises alongside its corresponding oral area. Weisz's idea of the dominance and inhibition of the original oral system extending over the oral primordium site is applicable in stomatogenesis of the present species. This application is found also in cirral formation.
In fragments from early stage dividers, a formed oral primordium is easily absorbed by influence of the intact original AZM. This event also occurs after complete removal of the AZM. Such results led to the hypothesis that the oral primordium in the normal divider may be formed under some stoma-togenic activation of the AZM followed by escape from inhibition also arising from the same source. Irrevocable furrow formation and irreversibility of the oral primordium in stomatogenesis occur in later stages of division. Nevertheless division in these stages is blocked when certain operations are performed, forming monsters possessing the AZM of the opisthe translocated to the side opposite to that of the proter. In other monsters obtained from a fusion of the AZM of the proter to that of the opisthe, division occurs belatedly, prior to which secondary oral and cirral primordia are produced.     

Commitment to Division in Ciliate Cell Cycles

Near the end of the cell cycle, ciliates commit irreversibly to cell division. The point of commitment occurs at the time of oral polykinetid assembly and micronuclear anaphase. The commitment is a checkpoint which requisites a threshold cell mass/ DNA ratio and stomatogenesis. It is also a physiological transition point, involving cdk protein kinases similar to those of other eukaryotes. Both P34 kD and P36 kD kinases, similar to the S. pombe cdc2 kinases, have been described to have activity as monomers. Subsequent to commitment to division, dramatic cytoskeletal modifications occur for separation of organelles, cortex morphogenesis and cytokinesis. Numerous mutants affecting cytoskeletal function associated with the division process have been obtained in several species. Of these, only the ccl mutant in Paramecium affects cell cycle progression prior to commitment to division. The material reviewed is used to speculate about the mechanisms of regulation of pre-fission morphogenesis and cell division related processes in ciliates.     

Nuclear Behavior and Morphogenetic Changes in Fission and Conjugation of Aspidisca costata (Dujardin)

Nuclear behavior and accompanying cytoplasmic changes have been traced in conjugation and binary fission in Aspidisca costata, a fresh water hypotrich. Cases of autogamy in singles also have been found. In conjugation the animals pair with left ventral sides apposed, at an angle of ∼ 100°, connected by a broad bridge. After 2 maturation divisions 4 potential gametic nuclei are formed. Thereafter 1 of 2 alternative plans is followed. The essential difference between them is the occurrence in Scheme B of degeneration of 2 products of the 2nd prezygotic division, thus reducing to 2 the 4 potential gametic nuclei–all viable in Scheme A. Single or double synkarya are thus generated, respectively, in each conjugant, certain of them necessarily by autogamy. After 1 or 2 postzygotic divisions, 4 final nuclei are formed: 1 macronuclear anlage, 2 micronuclei, and a degenerate nucleus. The exconjugants at 1st are astomatous, although a new complete set of cirri (exclusive of the anterior “tooth”) arises during conjugation. A later reorganization in the exconjugants must restore the buccal apparatus and probably also replaces the cirri and tooth. The morphogenetic changes in fission have been observed. All the cirri are replaced, in 2 sets, at each cycle. These originate in a single locus, a pouch anterior to the contractile vacuole. A new adoral zone of membranelles (AZM) arises for the opisthe, as a new tooth. The old AZM and the old tooth are retained by the proter. It is suggested that the tooth is the homolog of the 1/I cirrus of other hypotrichs.     

Reorganization in Amicronucleates with Defective Mouth of the Ciliate Pseudourostyla levis1

ABSTRACT. The purpose of this work is to examine the reorganization process in amicronucleates with defective mouth of the multimicronuclear ciliate, Pseudourostyla levis. The amicronucleates were derived from fragments obtained by transection of normal micronucleates. The cell size of the amicronucleates was extremely unstable and varied from 57.5 to 276.3 μm long (n = 146), whereas the micronucleates kept rather stable cell lengths with a range from 162.5 to 266.3 μm (mean ± SD = 213.1 ± 19.6 μm, n = 206). The renucleates obtained by transplantation of a micronucleus to an amicronucleate returned to almost normal cell size (mean ± SD = 203.7 ± 16.5 μm long, n = 54). Under the usual culture conditions in the amicronucleate cell line, the number of abnormal cells with defective mouth rapidly increased, up to about 60%, until a stationary phase. Similarly, abnormal cells also appeared in micronucleates although the frequency was always less than 10%. The mean number of membranelles in the normal adoral zone of membranelles (AZM) was 82.6 ± 3.9 (±SD, n = 49) vs. 57.3 ± 7.9 (n = 81) in ciliates with defective mouths. The missing part of the AZM was always the anterior part of the lapel. Cells with defective mouth underwent reorganization (= physiological regeneration) under the usual culture conditions. During reorganization, the lapel part of the old AZM was transformed into a new collar part. The defective mouth was repaired through this developmental process. These results suggest that in P. levis the decrease of food supply often leads to the loss of a specific part of the AZM and that this membranellar loss is suppressed by the existence of micronuclei.     

Morphology and Morphogenesis of Fuscheria terricola n. sp. and Spathidium muscorum (Ciliophora: Kinetofragminophora)1

The morphology and morphogenesis of the kinetofragminophoran soil ciliates, Fuscheria terricola n. sp. and Spathidium muscorum Dragesco & Dragesco-Kerneis, 1979, are described. Stained specimens (protargol) are characterized biometrically. The new species differs from the other species of the genus in its body size, body shape, number of kineties, length of extrusomes, and habitat. Both species have telokinetal stomatogenesis, which commences with a proliferation of kinetosomes at those kineties which bear the brosse. Fuscheria terricola does not have a complex perioral ciliature; indeed, it might be that this species has only monokinetids. Thus only a proliferation of kinetosomes and the separation of the kineties takes place in the prospective division furrow. In contrast, S. muscorum differentiates short dikinetid kinetofragments in the region of the division furrow, which are arranged to form the perioral kinety of the opisthe in the intermediate and late stages of the stomatogenesis. The right part of the perioral kinety develops first. This and other studies show that telokinetal stomatogenesis proceeds very differently depending on the differentiation of the oral ciliature; however, detailed studies on the morphogenesis of kinetofragminophoran ciliates are still too few in number for subtypes to be defined.     

The Cortical Morphogenetic Cycle Associated with Cell Division in Diophrys Dujardin, 1841 (Ciliophora,Hypotrichida)1

Morphogenesis of cell division was investigated in Diophrys scutum, D. oligothrix, and D. appendiculata utilizing both light microscopy of living and stained specimens and SEM of preserved specimens. The cortical morphogenetic pattern of Diophrys is similar to that of other members of the family Euplotidae. The opisthe oral primordium, which develops in a subsurface pouch, forms posterior to the parental buccal cavity. The proter inherits the parental adoral zone of membranelles (AZM) apparently unchanged. The endoral membrane forms to the right of the posterior end of the AZM in the proter, in association with the developing AZM in the opisthe. The paroral cirrus and membrane develop from a single streak that first appears along the right edge of the buccal cavity in the proter to the right of the developing buccal structures of the opisthe. Frontal and transverse cirri develop in both proter and opisthe from five separate cirral primordia that form to the right of the buccal cavity. Left marginal cirri do not develop in association with the corresponding parental structures. Kinetosomes formed within the opisthe oral primordium, or kinetosomes that were part of any parental ciliary structure, do not appear to become part of any developing paroral structures, frontal, transverse, or left marginal cirri. Speciation within the genus Diophrys and evolution of the family Euplotidae as they relate to the morphogenesis of cortical structure are discussed.     

First evidence of cell deformation occurrence during a Dinophysis bloom along the shores of the Gulf of Tunis (SW Mediterranean Sea)

Never before observed or cited in Dinophysis studies, deformations in Dinophysis acuminata and Dinophysis sacculus are reported throughout their cellular division phases (cytokinesis, and sulcal list regeneration) in 5 in situ cell cycle studies in the Punic harbors of Carthage (northern Tunisia). Two types of deformation were observed: invaginations in the ventral and dorsal margin and protuberances at the base of the left sulcal list. No virus or bacteria were detected with Syber green stain. In situ division rates (μ) varied among seasons and stations for the same species. D. acuminata exhibited moderate (0.22 day⁻¹) to high (0.68 day⁻¹) μ rates which were however very low (0.02–0.17 day⁻¹) for D. sacculus in autumn and moderate (0.21–0.35 day⁻¹) in late spring. In 2009 the seasonal distribution of Dinophysis indicates maximum Dinophysis cf. ovum abundance in March and a high number of D. acuminata in early June, while in 2010 maximum abundance of the same species was found in mid-June.Molecular and genetic studies and staining with specific fluorescent strains should be addressed to hopefully explain these Dinophysis cell deformations during their in situ division.     

Retinoic acid as a regulator of planarian morphogenesis

The effect of retinoic acid on regeneration of two species of asexual planarian races, Girardia tigrina and Schmidtea mediterranea, was studied. It was established that retinoic acids at physiological concentrations (10⁻⁷–10⁻¹⁰ M) inhibit the regeneration of the head part of planarians but have no effect on tail blastema growth. It is shown that regeneration of the head part is inhibited as a result of arrest of the cell cycle of neoblasts, proliferating stem cells, during the transition from the G ₁/G ₀ to the S phase. Thus, the morphogenetic role of retinoic acids in planarians, primitive bilaterally symmetrical animals, has been demonstrated.     

Scanning Electron Microscopy of Stomatogenesis Accompanying Conjugation in Euplotes aediculatus*

SYNOPSIS. The succession of morphologic changes in the feeding apparatus (peristome) accompanying conjugation and postconjugant development in the hypotrich Euplotes aediculatus has been examined by scanning electron microscopy (SEM). The details of stomatogenesis inferred from earlier light-microscopic studies of silver-stained preparations have been confirmed and extended. The elaborate peristome is the dominant surface feature of vegetative Euplotes. In conjugation, the ciliates are joined in their peristomial regions; as the conjugants separate, the old feeding apparatus is seen to be disrupted and partially resorbed. In its place is the crescent-shaped primordium of a new peristome, which develops as part of a general cortical reorganization. This primordium expands anteriorly, unfurling a new crown of ciliary membranelles that soon replaces the remaining preconjugant membranellar band. The resulting “exconjugant peristome'’is characterized by a greatly reduced number of adoral membranelles and the absence of paroral membranelles, buccal cavity, and cytostome. Exconjugants thus cannot feed for 2–3 days, until the missing peristomial components are replaced. This occurs by means of a 2nd cortical reorganization, during which new membranelles, developing from another peristomial rudiment, are added directly to the abbreviated exconjugant set. A new buccal cavity is concurrently sculpted as the primordial depression enlarges, and the cells can resume feeding sometime during the 4th day after separation. The implications of this mode of stomatogenesis and the nonfeeding condition are discussed, as are the advantages of SEM for studies of ciliate morphogenesis.     

Précisions Temporelles sur les Processus de la Stomatogenèse de Tetrahymena paravorax analysés en Microscopie Photonique

Resume. Une analyse des séquences morphogénétiques du CiliéTetrahymena paravorax montre que: (A) La durée de la stomatogenèse de bipartition des formes microstomes en croissance exponentielle représente 45% du temps de génération (stade 1—20%; stade 2—3%; stade 3—3%; stade 4—5%; stade 5—5%; stade 6—9%). (B) La division cytoplasmique est inégale (les proters sont plus petits que les opisthes); la différence de taille initiale entre les 2 produits de fission est probablement compensée par une prolongation de la période de croissance chez le proter. (C) Le pourcentage maximum de réorganisation buccale microstome → macrostome pour les populations asynchrones atteint –? 70% au bout de 210 mn d'incubation dans la stomatine. (D) L'initiation de la stomatogenèse de remplacement oral est connectée avec la fin d'une période dont la durée minimale est approximativement celle du stade 0 du cycle normal d'interdivision des microstomes; cette initiation est retardée chez les microstomes exposés à la stomatine dès le début du cycle cellulaire. (E) Le primordium buccal de division peut se résorber en présence de stomatine et la stomatogenèse antérieure peut commencer avant que ne soit terminée cette résorption; la résorption n'est plus induite au-delà d'un point du stade 5 qui précède le début de la constriction du corps cellulaire. SYNOPSIS. An analysis of the morphogenetic sequences in the ciliate Tetrahymena paravorax has shown that: (A) The duration of predivision stomatogenesis in exponentially growing microstomes occupies 45% of the generation time (stage 1—20%; stage 2—3%; stage 3—3%; stage 4—5%; stage 5—5%; stage 6—9%). (B) Cytoplasmic division is unequal (the proters are smaller than opisthes); the initial size difference between the 2 fission products is presumably compensated by an increased growth period in the proter. (C) The maximum percentage of microstome-to-macrostome oral reorganization is –? 70% in asynchronous populations, 210 min after suspension in stomatin. (D) Initiation of oral replacement stomatogenesis is associated with the end of a period which has a minimum duration nearly equal to that of stage 0 characteristic of the normal inter-division cycle of the microstomes; this initiation is delayed if exposure of microstomes to stomatin is begun at the onset of the cell cycle. (E) The buccal primordium formed in division can be resorbed in presence of stomatin and anterior stomatogenesis can start before the resorption is completed: this resorption is not induced if the cells have progressed beyond a point which precedes the beginning of the cell furrowing (stage 5).     

Plant regeneration from leaf petioles in <Emphasis Type="Italic">Camptotheca acuminata</Emphasis>

Summary Camptothecin, produced by Camptotheca acuminata, is a pharmaceutically important compound. Transgenic technology has potential uses for the enhancement of camptothecin production; however, an efficient plant regeneration protocol for C. acuminata is not currently available. Factors that affected successful seedling germination were evaluated. The regeneration potential of various parts of seedlings was tested. Camptothecin production in regenerated plants was compared to its production in calluses and the original seedlings. Dark incubation and seed coat removal led to a higher germination rate and a higher survival rate after germination. The best shoot induction medium was found to be Gamborg's B5 medium+8.9 μM benzyladenine. Among the calluses induced from various parts of seedlings, leaf petiole calluses, leaf dise calluses, and cotyledon calluses regenerated shoots, but internode calluses did not. Furthermore, leaf petiole calluses and leaf dise calluses regenerated normal shoots, while cotyledon calluses regenerated hyperhydric shoots. Moreover, leaf petiole calluses had a higher shoot regeneration rate, 50% versus 9%, and a higher shoot number, 6.2±0.5 versus 2.0±0.3, than did leaf dise calluses on the best shoot induction medium. It took 4–6 wk to regenerate shoots after transfer into shoot induction media. Camptothecin concentration in the regenerated plants was significantly higher than that in the calluses and similar to that in the original seedlings. In conclusion, leaf petioles provide efficient plant regeneration of C. acuminata.     

Morphology and Morphogenesis of Onychodromus quadricornutus n. sp. (Ciliophora,Hypotrichida), an Extraordinarily Large Ciliate with Dorsal Horns1

The morphology and the morphogenesis of the freshwater hypotrich ciliate Onychodromus quadricornutus n. sp. have been investigated using living organisms, protargol impregnation, and scanning electron microscopy. Some preliminary and supplementary results about the morphogenesis of O. grandis and Laurentiella acuminata are included. The new species is unique among all described hypotrichs in having four dorsal horns, whose function is unknown. In addition, O. quadricornutus is probably the most voluminous hypotrich ciliate known (2 times 10^-6-5 times 10⁶μm³). Its morphogenetic pattern resembles the oxytrichids O. grandis and L. acuminata. The strongest apomorphic character, which unites these three species, is probably the multiple fragmentation of the dorsal primordia during morphogenesis. This fragmentation causes the characteristic high number and more or less irregular distribution of the dorsal kineties in the non-dividing individuals.     

Morphology and morphogenesis of Holosticha heterofoissneri nov. spec. from the Yellow Sea,China (Ciliophora,Hypotrichida)

The morphology and morphogenesis of the marine hypotrichous ciliate Holosticha heterofoissneri nov. spec. from mollusc culture in Qingdao, China are described based on living and protargol-impregnated specimens. The new species is characterized by: adoral zone slightly bipartite, consisting of on average 43 membranelles; constantly 5 dorsal kineties, and 12 pairs of cirri in midventral rows, and 14–16 macronuclear segments, which differs from the closely related species, H. foissneri. Its morphogenetic process shows the following features: (1) the parental AZM is retained unchanged and will be inherited by the proter, only the old UM reorganized; (2) FVT-cirral anlagen in both division parts derive from the breaking of primary primordia; (3) during the formation of FVT-cirral anlagen, most midventral cirri remain intact; and there appears an 'extra' anlage (EA) between the UMA and other FVT-cirral primordia; (4) the generation type of the dorsal kineties is of 'one group mode', the leftmost one of the 4 primordia fragmentates to form a new kinety; (5) at the early stage of morphogenesis, replication bands of macronuclear segments are apparently present.     

Cell cycle mutation in Paramecium tetraurelia discriminates between sexual and vegetative functions

The temperature-sensitive mutation cc1 blocks a number of cell cycle processes in Paramecium including macronuclear DNA synthesis, oral morphogenesis, and the later stages of micronuclear mitosis. Oral morphogenesis and micronuclear mitosis also occur in the sexual pathway. This study shows that cc1 cells can proceed through conjugation or autogamy under restrictive conditions; neither stomatogenesis nor micronuclear mitosis is blocked. Fertilization and macronuclear determination occur normally, but DNA synthesis in macronuclear anlagen is blocked. Therefore, this mutation discriminates between oral replacement during meiosis and vegetative prefission stomatogenesis, and between mitotic spindle elongation during the pregamic and postzygotic divisions and spindle elongation during the vegetative cell cycle. These results point to a fundamental regulatory difference between morphogenesis in the vegetative and sexual pathways. © 1994 Wiley-Liss, Inc.     

Morphologic and molecular data suggest that Lynnella semiglobulosa n. g., n. sp. represents a new family within the subclass Choreotrichia (Ciliophora, Spirotrichea)

The morphology, morphogenesis, and phylogeny of an undescribed oligotrich sensu lato (s. lat.) ciliate, Lynnella semiglobulosa n. g., n. sp., found in Daya Bay, southern China, were investigated. This species shares some features with both oligotrichs sensu stricto and choreotrichs, but most morphological and morphogenetic characters as well as the phylogenetic analysis suggest that it should be assigned into subclass Choreotrichia temporarily. Lynnella semiglobulosa is distinguished from members of all known genera and families of the subclass Choreotrichia by a unique combination of characteristics of the buccal and somatic ciliatures. Thus, a new family Lynnellidae n. fam. and a new genus Lynnella n. g. are proposed for it. The new family is distinguished by an open adoral zone of membranelles (AZM) in which, however, there are no ventral membranelles; the distal and proximal portions of the new adoral zone lie close to each other forming an open circle in stomatogenesis. The new genus Lynnella is characterized by possessing two longitudinally oriented somatic kineties, one dorsal and one ventral, several proximal membranelles progressively lengthened toward the proximal end of adoral zone, and two macronuclear nodules. In phylogenetic analyses based on small subunit rRNA gene sequences, L. semiglobulosa clustered basally to all choreotrichs, but with relatively weak support; nevertheless, the possibility of a relationship with the subclass Oligotrichia was not rejected by the approximately unbiased nor Shimodaira-Hasegawa test. Based on morphological, morphogenetic, and molecular evidence of L. semiglobulosa, it is confirmed that the open AZM should be a plesiomorphic character of oligotrichs s. lat. as suggested previously.     

Discotricha papillifera: Structure and Morphogenesis of a Marine Interstitial Ciliate*

SYNOPSIS. Discotricha papillifera Tuffrau, a marine interstitial ciliate, is redescribed with the aid of light, scanning, and transmission electron microscopy from cells collected at a New Hampshire beach. Presence of primitive membranelles as well an an advanced stomatogenesis is demonstrated. The ultrastructure, including a unique membrane-bounded septate structure, is described. The cell is tentatively placed in the nassulid suborder Microthoracina, but affinities with other groups are discussed.