Podophyllotoxin,Colcemid and Cold Temperature Interfere with Cilia Regeneration in Stentor*

SYNOPSIS Stentor coeruleus, induced to shed their ciliary membranellar bands, regenerate these and associated oral structures within a few hours after treatment. In cells placed in media containing optimal concentrations of mitotic spindle inhibitors, regeneration of the ingestive organelles is reversibly inhibited. Inhibitory effects of Colcemid, podophyllotoxin, and cold temperature reported here are compared with previous results using colchicine, griseofulvin and isopropyl-n-phenyl carbamate on regenerating oral membranellar cilia and cell growth.     

Cilia Regeneration in Stentor: Inhibition, Delay and Abnormalities Induced by Griseofulvin

SYNOPSIS. Stentor coeruleus were experimentally induced to shed their membranellar bands (MB), structures consisting of rows of cilia and their basal bodies. Control stentors entirely regenerate their MB's within 8-10 hours according to a well-known pattern. Stentors replaced in medium containing the fungicide and mitotic spindle inhibitor griseofulvin (10^-5 M ) could be reversibly inhibited from regeneration for about 3 to more than 24 hours. If griseofulvin-inhibited cells were removed and washed, they regenerated like the controls. After about one day in 10^-5 M griseofulvin and at lower concentrations stentors eventually regenerated in the presence of the drug, but abnormally.
Normal unshed stentors show certain minor cytological effects and are unable to divide in griseofulvin (10^-5 M ); however, they can be maintained swimming actively for several weeks in nonlethal concentrations of the drug. Altho some induced abnormalities persist after removal from griseofulvin, all washed cells eventually revert to normal.     

Oral Regeneration in the Ciliate Stentor coeruleus: A Scanning and Transmission Electron Optical Study

SYNOPSIS. Elaboration of ciliated feeding organelles in the protozoon Stentor coeruleus was reinvestigated for the first time by scanning electron microscopy which gives the most realistic 3-dimensional images. Parallel transmission EM studies of synchronized regenerating stentors gave further ultrastructural details of stomatogenesis, while also confirming the expectation that in the structure of its kineties this now classical experimental object does not differ from other species of Stentor previously studied. Within 2 hr after the stimulus to regeneration, several generations of new kinetosomes for the oral primordium are produced, first in association with kinetosomes of kineties at the restricted primordium site. These kinetosomes rapidly sprout membranellar cilia as well as subpellicular microtubules but are still randomly oriented (anarchic field). The forming membranellar band increases from its center-line to both sides while it grows in length. Young cilia are blunt-ended. Recession of the early anlage occurs without rupture of the pellicle; soon apparent is the clear border stripe of unknown function along the right side of the membranellar band. Instantaneous fixation of beating cilia in early primordia revealed random beating, with coordination and presumably membranellar organization not yet attained. In late anlagen there are 2 types of metachronal rhythm: transversely from cilium to cilium across any given membranelle, as well as the easily observable serial beating of membranelles along the entire band. A single file of cilia leads the subsequent cytostomal invagination. The posterior end of the membranellar band then follows to line the cytopharynx.     

Melatonin: Inhibition of Microtubule-Based Oral Morphogenesis in Stentor coeruleus

SYNOPSIS. The temporal separation of macromolecular syntheses from protein assembly into microtubular structures has permitted the use of the Stentor ciliated oral membranellar band regenerating system as an assay for mitotic spindle inhibitors (Banerjee & Margulis, 1971). Melatonin, the pineal gland hormone, is additive to Colcemid in this assay; like Colcemid it specifically inhibits band migration as a sensitive function of developmental stage and concentration. Altho the entire process of band formation and cilia regeneration (stages 0–8) is inhibited by melatonin, stage 3 is especially sensitive.
Delay in morphogenesis at stage 3 can be measured as a precise function of inhibitors (Colcemid, podophyllotoxin, melatonin) of the form y=kxⁿ, where y is delay in hours and k is the concentration of inhibitor in moles. Riboflavin (0.2 μ M ) and nicotinamide (0.2 μM) in combination reversed Colcemid-induced delay in band regeneration, but (unlike melatonin) the vitamins alone were totally without effect on the regenerating system. Therefore melatonin probably interacts with microtubule protein whereas the B vitamins interact in some way with Colcemid to nullify its activity.     

Ciliary Proteins and Cytodifferentiation in Stentor coeruleus*

To elucidate further the molecular events required for cytodifferentiation in Stentor coeruleus, the effects of several chemical metabolic inhibitors were tested on the outgrowth in situ of the membranellar cilia of the oral feeding organelle. The chemicals used included several inhibitors of cytoplasmic and mitochondrial protein synthesis (cycloheximide, emetine, and chloramphenicol), and an antimitotic agent (colchicine). Ciliary growth was affected only by colchicine, suggesting that a pool of “ciliary proteins” exists in interphase Stentor of sufficient size to permit complete reformation of the membranellar cilia. The implication of these observations to an understanding of the more complicated process of oral regeneration is discussed.     

Mitotic arrest by melatonin

We are testing the hypothesis that migration of the newly formed mouth (i.e., oral membranellar band) in stentor is homologous to mitotic chromosomal movement and that both types of movement within single cells depend directly on microtubule elongation. The following compounds synchronously delay the migration of the oral membranellar band as an exponential function of concentration: Colcemid, podophyllotoxin, β-peltatin and vinblastine. Delay for these compounds can be described by the equation, y = kxⁿ, where y is delay in hours and x is concentration of mitotic spindle inhibitor in moles/l. We discovered that the animal pineal gland hormone, melatonin (5-methoxy n-acetyl tryptamine), also specifically and reproducibly delays oral band regeneration according to an equation of this form. Thus we predicted that melatonin would arrest mitosis. We report here a colchicine-type disruption of the mitotic apparatus in onion root tips by melatonin. Two closely related tryptamine derivatives, n-acetyl serotonin and serotonin were inactive in both the stentor and onion assays: they neither delayed band migration in stentor as an exponential function nor induced mitotic arrest in onion.     

Pattern Formation in Mirror-Image Doublets of the Ciliate Stylonychia pustulata

ABSTRACT. Mirror-image symmetry doublets of the ciliate Stylonychia pustulata were obtained from the progenies of dividing cells in which cell division was inhibited by heat-shocks. In two components consisting of the doublet, the left (cell's) component possessed ciliary organelles arranged in almost the same pattern as in normal singlets, while the right one had surface organelles located in a mirror-image symmetry of those of the left component. In cell division of the doublet, two sets of ciliary primordia that were arranged in a mirror-image symmetry developed synchronously in both components. In about 80% of oral primordia (OP) of the right components, the arrangement of the membranellar bands became abnormal. In some cases, OP of the right component were occasionally separated into two longitudinal halves, each consisting of normal membranelles and inverted membranelles. A set of primordia of the paroral membranelles and fronto-ventro-transverse cirri was rarely derived from the basal bodies of the right half with a band of normal membranelles. As a result, a third component with the ciliary organelles normally arranged emerged on the right side of the original right component. The differentiation of membranelles and segmentation of the primordial streaks into cim proceeded from anterior to posterior. A cytoplasmic bulge with multiple right marginal cirral rows was frequently formed at the right margin of the doublet. The behavior in the separation of third and fourth streaks from a primordial streak of dorsal cirri was not mirror-image symmetrical in each component.     

Con A Binds to the Membranellar and Somatic Cilia of Stentor and to the Developing Oral Primordium During Oral Regeneration1

Binding sites for Concanavalin A have been located in the ciliate Stentor coeruleus by utilizing FITC-Con A and fluorescence microscopy. When both nonregenerating and regenerating Stentor are fixed prior to FITC-Con A exposure, FITC-Con A binds intensely to the cilia of the membranellar band and to the somatic cilia that cover much of the cell surface. No binding is observed between the ciliary rows. The FITC-Con A also binds to the developing oral primordia of regenerating cells. Binding of FITC-Con A in the early stages of regeneration (prior to stage 4) appears to be less intense than that in the later stages. Additional FITC-Con A binding appeared as a granular fluorescence in the area of the developing buccal cavity beginning at about stage 4 and disappearing around stages 6–7. The presence of α-D-methyl mannoside prevented the binding of FITC-Con A to either regenerating or nonregenerating cells. If nonregenerating Stentor are exposed to FITC-Con A prior to fixation, the binding pattern is entirely different with the fluorescence primarily in the form of random, granular patches spread over much of the cell but with no binding to either type of cilia. These results demonstrate that membrane glycoproteins capable of binding Con A are located primarily in the membranellar and somatic cilia and in the developing oral primordia during oral regeneration in Stentor. Concanavalin A binding to these sites may be involved in the Con A-induced inhibition of oral regeneration observed in earlier studies.     

New frontiers: discovering cilia‐independent functions of cilia proteins

In most vertebrates, mitotic spindles and primary cilia arise from a common origin, the centrosome. In non‐cycling cells, the centrosome is the template for primary cilia assembly and, thus, is crucial for their associated sensory and signaling functions. During mitosis, the duplicated centrosomes mature into spindle poles, which orchestrate mitotic spindle assembly, chromosome segregation, and orientation of the cell division axis. Intriguingly, both cilia and spindle poles are centrosome‐based, functionally distinct structures that require the action of microtubule‐mediated, motor‐driven transport for their assembly. Cilia proteins have been found at non‐cilia sites, where they have distinct functions, illustrating a diverse and growing list of cellular processes and structures that utilize cilia proteins for crucial functions. In this review, we discuss cilia‐independent functions of cilia proteins and re‐evaluate their potential contributions to “cilia” disorders.     

The oral apparatus of Tetrahymena pyriformis, strain WH-6. IV. Observations on the organization of microtubules and filaments in the isolated oral apparatus and the differential effect of potassium chloride on the stability of oral apparatus microtubules.

This report is an ultrastructural analysis of the organization of the isolated oral apparatus of Tetrahymena pyriformis, strain WH-6, syngen 1. Attention has been focused on the organization of microtubules and filaments in oral apparatus membranelles. Oral apparatus membranellar basal bodies were characterized with respect to structural differentiations at the distal and proximal ends. The distal region of membranellar basal bodies contains the basal plate, accessory microtubules and filaments. The proximal end contains a dense material from which emanate accessory microtubules and filaments. There are at least two possibly three different arrangements of accessory structures at the proximal end of membranellar basal bodies. All membranellar basal bodies appear to have a dense material at the proximal end from which filaments emanate. Some of these basal bodies have accessory microtubules and filaments emanating from this dense material. A possible third arrangement is represented by basal bodies which have lateral projections, from the proximal end, of accessory microtubules and filaments which constitute cross or peripheral connectives. There are at least three examples of direct associations between oral apparatus microtubules and filaments: (1) filaments which form links between basal body triplet microtubules, (2) filaments which link the material of the basal plate to internal basal body microtubules, (3) filaments which link together microtubule bundles from membranellar connectives. KCl extraction of the isolated oral apparatus resulted in the selective solubilization of oral apparatus basal bodies, remnants of ciliary axonemes and fused basal plates. Based on their response to KCl extraction two distinct sets of morphologically similar micro tubules can be identified: (a) microtubules which constitute the internal structure of basal bodies and ciliary axonemes, (b) microtubules which constitute the fiber connectives between basal bodies.     

Gamma Irradiation of Stentor polymorphus

SYNOPSIS. Stentor polymorphus was irradiated with ⁶⁰Co gamma rays at 525 rads/minute to examine the effect on survival, cell division, oral membranellar frequency and oxygen uptake. Both survival and cell division were studied on single cells. The LD₅₀ is 285 kilorads but cell division is inhibited below this dose; 110 kilorads doubles the 1st post-irradiation division interval, and a delay of 240 hours occurs at the maximum tolerated dose of 310 kilorads. Conjugating cells are more sensitive, with an LD₅₀ of approximately 40 kilorads.
The frequency of cilia in the membranellar band, measured stroboscopically, is reduced by 30% after 14.5 kilorads, and stopped by higher doses. Recovery has a similar time scale to recovery of fission. A Clarke electrode was used to measure changes in oxygen uptake after irradiation. Depressions of up to 50% were found. Recovery followed a similar pattern to that of ciliary activity and cell division.     

CILIA REGENERATION IN TETRAHYMENA AND ITS INHIBITION BY COLCHICINE

The cilia of Tetrahymena were amputated by the use of a procedure in which the cells remained viable and regenerated cilia. Deciliated cells were nonmotile, and cilia regeneration was assessed by scoring the percentage of motile cells at intervals following deciliation. After a 30-min lag, the deciliated cells rapidly recovered motility until more than 90% of the cells were motile at 70 min after amputation. Cycloheximide inhibited both protein synthesis and cilia regeneration. This indicated that cilia formation in Tetrahymena was dependent on protein synthesis after amputation. Conversely, colchicine was found to inhibit cilia regeneration without affecting either RNA or protein synthesis. This observation suggested the action of colchicine to be an interference with the assembly of ciliary subunit proteins. The finding that colchicine binds to microtubule protein subunits isolated from cilia and flagella (13) supports this possibility. The potential of the colchicine-blocked cilia-regenerating system in Tetrahymena for studying the assembly of microtubule protein subunits during cilia formation and for isolating ciliary precursor proteins is discussed.     

Mitosis of Micronuclei During Division and Regeneration in the Ciliate Stentor coeruleus1

Stages of mitosis of the micronuclei of Stentor coeruleus were described as seen by transmission electron microscopy. Cells in division and those regenerating new oral membranelles were studied. Microtubules were found in early prophase in the karyoplasm and interspersed between the condensing chromatin. A monaxial intranuclear spindle is formed by early metaphase, with kinetochore microtubule attachment sites on the chromosomes. The spindle elongates, separating the daughter nuclei at anaphase. A new nuclear envelope, consisting of two unit membranes, begins to form at late anaphase. Small segments of membrane found in the space between the newly forming and the old micronuclear envelopes appear to fuse to form the new nuclear envelope. No ultrastructural differences were found in the mitotic nuclei of cells in division or regeneration.     

Circardian rhythm of mitoses in the epithelium of the cornea after splenectomy]

In corneal epithelium of CBA mice the index of colchicine mitoses diminished after splenectomy in the day period characterized by rising mitotic activity in control animals. The duration of active phase of cell division rhythm shortened while the maximum of mitotic activity delayed in comparison with control animals. The total amount of cells entering mitosis during 24 hours diminished by 27.7% and the rate of physiological regeneration of corneal epithelium decreased.     

Transformation in Tetrahymena thermophila. Development of an inducible phenotype.

Tetrahymena thermophila transforms from a pyriform-shaped trophic form to an elongate rapidly swimming, dispersal form under the appropriate conditions of starvation [Nelsen, E. M., and DeBault, L. E. (1978). J. Protozool.25, 113–119]. The development and control of the dispersal phenotype are examined. After an initial starvation period, the cell replaces its oral structures. During oral replacement, a caudal cilium emerges at the posterior end of the cell. As oral replacement is completed, the cell becomes spindle shaped and the newly-formed oral membranelles are positioned beneath the surface of the cell with somatic ciliary rows exterior to them. The spindle-shaped cell then elongates to become the dispersal form. While the cell is developing the new oral structures, it is also drastically increasing its numbers of somatic basal bodies and cilia. The events in the transformation pathway may be arrested or reversed by feeding the cell, except that once oral replacement has begun, it is completed along with an associated streamlining of the cell. Refed cells revert to the normal vegetative phenotype, except that some shape changes persist for several hours, suggesting that they are compatible with, but independent of, growth. Blockage of protein synthesis with cycloheximide prevents all changes associated with transformation, including the shape changes and elongation of the caudal cilium. The relation between transformation and conjugation has also been examined. Less transformation takes place when mating is possible, but transformed cells may also mate.     

Morphogenesis in the Heterotrich Ciliate Climacostomum virens. II. Oral Development During Regeneration1

The regeneration (RG) of the oral apparatus (OA) by Climacostomum virens (Ciliophora, Heterotrichida) is examined by estimation of the ability of live cells to ingest food as well as by Nomarski interference contrast microscopy, bright field microscopy of protargol-stained specimens, and by scanning electron microscopy. When placed in a 6% (w/v) urea solution for ～ 2 min 10 sec, populations of 10,000–100,000 cells shed a large part of their OA. In more than 90% of the cells that shed, the discarded segment is comprised of the apical membranelles, most of the adoral membranelles, and of a variable part of the buccal tube. After washing and incubation at 26°C, 50% of the cells regenerate a functional OA in 4 h 47 min, and after 5 h 26 min, 90% of the cells are able to ingest food. At any given moment during the process, 50–90% of the cells are morphologically in the same stage of RG. Seven stages (among which three are divided into two substages) of RG are defined. The process begins by the disorganization of the remnant oral structures. Concomitantly, kinetosomes multiply along the kineties of the zone of discontinuity and form the longitudinally oriented oral primordium. The latter gives rise to the adoral primordium, which rapidly produces the adoral zone of membranelles (AZM), and to the paroral primordium, which subsequently forms the apical membranelles, the buccal peristomial kineties, and the paroral kinety. Morphogenetic movements lead to incurvation of the AZM and the frontal field and to invagination of the buccal tube.     

Participation of the Undulating Membrane in the Formation of Oral Replacement Primordia in Tetrahymena pyriformis*

SYNOPSIS. Cells of T. pyriformis GL-C, transferred from a complete axenic medium to a medium lacking amino acids, cease dividing after several hours, and instead begin to undergo oral replacement. This process can be synchronized by a single long 33.8 C treatment. Oral replacement was also observed during stationary phase of normal culture growth in cells of strain GL-C and WH-6 (syngen 1). In strain GL-C the oral replacement primordium is initiated by the appearance of a small number of kinetosomes adjacent to the anterior end of kinety 1, just posterior to the undulating membrane (UM). The UM then loses its cilia and becomes disorganized, and is thus converted into a field of kinetosomes which is broadest near its posterior end. This UM-derived field then becomes joined with the much smaller field which had appeared earlier near the anterior end of kinety 1. As a consequence, the right margin of the UM-derived field becomes continuous with the anterior end of kinety 1, and thus comes to appear as an anterior extension of this kinety. The membranelles and UM of the new oral area differentiate within this composite field. While this is going on, the membranelles of the old oral area are progressively resorbed; these old membranelles always remain spatially separate from the oral replacement primordium. In strain WH-6, the stomatogenic field initially formed adjacent to kinety 1 is substantial, and the role of the UM kinetosomes in stomatogenesis is less obvious than in strain GL-C. The posterior portion of the UM probably contributes to the oral replacement primordium, while the anterior portion is resorbed. In this strain small supernumerary primordia are occasionally seen adjacent to the portion of kinety 2 which is nearest to the posterior region of the UM. It is suggested that the junction between the posterior portion of the UM and the neighboring cortex can serve as an inductive zone for initiation of stomatogenesis, the UM itself having a varying capacity for direct provision of kinetosomes for the stomatogenic field. The flexibility of the stomatogenic site in T. pyriformis is discussed in relation to the apparent restriction of potentialities in peniculine ciliates such as Paramecium.     

Oral assembly in left-handed Tetrahymena thermophila

We have investigated oral development in a non-genetically derived left-handed (LH) form of Tetrahymena thermophila, in which the large-scale asymmetry of arrangement of cortical structures is reversed whereas the local asymmetry of ciliary architecture remains normal. Approximately 1/2 of the oral apparatuses (OAs) of LH cells develop in the form of superficial mirror-images of OAs of RH cells. In most of these OAs, membranelles are assembled from the cells' anterior to posterior. Nonetheless, the posterior ends of these membranelles undergo the basal body displacements that lead to a "sculptured" appearance, so that the membranelles of LH OAs become organized as rotational permutations of membranelles of normal RH OAs. Many of these membranelles re-orient to a normal orientation near the end of oral development. Membranelles and undulating membranes (UMs) may develop independently of each other, and formation of postciliary microtubules of UMs is separate from that of ribbed wall microtubules. In some cases, the entire OA develops and remains as a 180 degrees rotational permutation of the normal, resembling the inverted OAs of mirror-image doublets and LH cells of Glaucoma scintillans described by Suhama. We present a model for these complex developmental outcomes. These developmental patterns resemble those described previously and less completely for "secondary" OAs of cells with mirror-image global patterns, including janus cells. The present study demonstrates that such alterations in oral development are not a direct outcome of genotypic changes.     

Formation of viable cell fragments by treatment with colchicine

Time-lapse cinematography of human fibroblasts revealed that mitotic cells separated into numerous cell fragments containing varying amounts of chromatin and cytoplasm when treated with colchicine. As cell fragments were very loosely attached to the surface of the culture vessel during their formation, they could be easily detached like mitotic cells by gently shaking the vessel and thus separated from normal interphase cells. Fragments obtained by this procedure were able to exclude trypan blue indicating, therefore, an intact cell membrane. When placed into Petri dishes many of them attached to and even spread out on the surface. Five hours later the majority of the attached fragments incorporated [³H]leucine. Time-lapse films showed that fragments were able to extend and retract pseudopodia at least for several hours after their formation. Although the fragments degenerated within a few days, in the present experiments the possibility was not excluded that fragments which had lost only a very small amount of chromatin and cytoplasm survived for longer periods of time. The observations clearly indicate viability of many newly formed fragments.     

Ciliated band structure in planktotrophic and lecithotrophic larvae of Heliocidaris species (Echinodermata: Echinoidea): a demonstration of conservation and change

The evolution of lecithotrophic (non-feeding) development in sea urchins is associated with reduction or loss of structures found in the planktotrophic (feeding) echinopluteus larvae. Reductions or losses of larval feeding structures include pluteal arms, their supporting skeleton and the ciliated band that borders them. The barrel-shaped lecithotrophic larva of Heliocidaris erythrogramma has, at its posterior end, two or three ciliated band segments comprised of densely packed, elongate cilia. These cilia may be expressions of the epaulettes that would have been present in an ancestral larval form, represented today by the feeding echinopluteus of H. tuberculata . We compared the development and cellular organization of the larval ciliary structures of both Heliocidaris species to assess whether the ciliary bands of H. erythrogramma are expressions of the feeding ciliated band or epaulettes of an echinopluteus. Epaulette development in feeding larvae of H. tuberculata involves separation of specific parts of the ciliated band from the rest of the feeding ciliated band, hyperplastic addition of ciliated cells and hypertrophic growth of the cilia. Like epaulettes, the ciliated bands of H. erythrogramma are composed of long spindle-shaped cells arranged in a cup-shaped collection that bulges into the blastocoel; and these cells have elongated cilia. In their developmental origin and topological arrangement however, the ciliated bands of H. erythrogramma correspond more closely with parts of the pluteal feeding ciliated band than with epaulettes. The larvae of this echinoid appear to develop epaulette-like bands from parts of the original (but reduced) feeding ciliated band. The evolution of development in H. erythrogramma has thus involved both conservation and change in echinopluteal ciliary structures.