Gamma-tubulin and MTOCs in Paramecium

The characterization of the two Paramecium gamma-tubulin genes, gammaPT1 and gammaPT2, allowed us to raise Paramecium-specific antibodies, directed against their most divergent carboxy-terminal peptide and to analyze the localization and dynamics of gamma-tubulin throughout the cell cycle. As in other cell types, a large proportion of the protein was found to be cytosolic, but in contrast to the general situation, gamma-tubulin was found to be permanently associated to four types of sites: basal bodies, the micronuclear compartment--within which mitotic and meiotic spindles develop without membrane breakdown, the pores of the contractile vacuoles and the cytoproct which are cortical microtubular organelles fulfilling excretory functions. In addition, a transient site of gamma-tubulin and microtubule assembly was observed at the site of nuclear exchange during conjugation. This complexity accounts for the nucleation of most of the numerous and diverse microtubule arrays present in Paramecium. The sites and mode of nucleation of the microtubule bundles formed in the macronuclear compartment during division remain unclear. These observations lead us to discuss the relationships between microtubules, gamma-tubulin and MTOCs.     

Mutants of Paramecium Defective in Chemokinesis to Folate

Ten mutant lines of Paramecium tetraurelia defective in attraction to folate were isolated and examined. All mutants were normal in response to other attractants and repellents tested. One mutant was able to accumulate in folate given sufficient time. All mutations were recessive and behaved as single site Mendelian lesions. Complementation tests indicate that the mutants fall into three complementation groups. Mutants of Group 2 fall into two phenotypic classes and probably represent two alleles of the mutated fol² gene. Possible sites of the mutants'' blocks in chemoresponse are discussed.     

Mutants Affecting Processing of DNA in Macronuclear Development in Paramecium

In Paramecium tetraurelia, stock 51, the A surface protein is coded by the wild type A51 gene, present in micronuclei in two copies and in macronuclei in about 1500 copies. DNA processing, comprised of DNA cleavage, copy number amplification and telomere addition occurs at autogamy and conjugation when old macronuclei degrade and new macronuclei are formed from micronuclei. In this paper we characterize mutants with macronuclear A gene deletions. These mutants are notable in three respects. First, the mutants do not appear to be simple micronuclear deletions. Although genetic analysis shows that the d12 mutant d12(-1300) is homozygous for the allele A-1300 and the mutant d12(+1) for A+1, analysis by the polymerase chain reaction indicates that the micronuclei in these two mutants contain intact, but presumably altered, micronuclear A genes. They undergo deletion during DNA processing when new macronuclei are formed. Second, the position of the deletions in these alleles has been shown to change. The deficiency present in the d12 allele A-1300 was originally determined to extend from position -1300 (relative to the start of translation of the A gene) to the end of the chromosome. Later, a derivative of this strain, homozygous for the d12 allele A+1 was isolated in which the start site of the deletion was found to have moved from -1300 to +1. Third, a surprising interaction occurs in crosses between a line homozygous for the d12 allele and one homozygous for the wild-type A51 allele. Previous work on the non-Mendelian d48 mutant (which has intact A51 genes in its micronucleus, but has truncated A51 genes in its macronucleus) has shown that intact A51 alleles must be present in the old macronucleus in order for A51 alleles to undergo proper processing. We find that d12 alleles act on A51 alleles in heterozygotes such that intact macronuclear A genes are no longer required for proper processing of A51. Thus, in crosses of 51 x d12 (either +1 or -1300) d12 exconjugants, as well as 51 exconjugants, give rise to clones carrying both intact A51 and truncated d12 alleles. Remarkably the d12 alleles, which are themselves deleted during processing, are capable in the heterozygote of fostering normal processing of the A51 allele.     

Dual labeling of the cytoskeleton and DNA strand breaks in porcine embryos produced in vivo and in vitro

In vitro-produced embryos exhibit decreased cell numbers, small inner cell masses and reduced pregnancy rates after transfer. Evaluation of intracellular components of in vitro-produced or -manipulated embryos will lead to improved methodology for embryo production. Whole mount techniques were developed to utilize terminal deoxynucleotidyl-transferase 3′ nick end labeling (TUNEL) to detect broken DNA. Subsequent labeling of either tubulin or actin filaments provides further evidence of cytological damage. Porcine embryos produced in vitro or in vivo were evaluated throughout the cleavage and preimplantation stages of development. Early cleavage stages up to the 8-cell stage never contained TUNEL-labeled nuclei. However, TUNEL labeling of in vitro-produced morula revealed some blastomeres with broken DNA. Nearly all in vitro-produced blastocysts displayed some TUNEL positive cells, whereas in vivo-collected embryos at a similar stage displayed few, if any, TUNEL-labeled nuclei. The ratio of TUNEL-labeled DNA to total DNA area of in vitro-derived blastocysts was significantly greater than their in vivo counterparts (P < 0.05). Microtubule and microfilament labeling identified blastomeres of unequal size and shape that were losing cellular integrity. These data suggest that the combination of these labeling techniques may be useful in evaluating cellular damage in embryos produced under in vitro conditions. Mol. Reprod. Dev. 51:59–65, 1998. Published 1998 Wiley-Liss, Inc.

1 This article is a US Government work and, as such, is in the public domain in the United States of America.

     

Spatial organization of microtubules in various types of cells in the embryonic tectal plate of mouse using immunofluorescence after PEG embedding

The spatial organization of microtubules in mitotic as well as in interphase cells and in axons has been investigated in situ in the embryonic nervous system of mice using high molecular weight polyethylene glycol-embedded semithin sections and immunofluorescence with a tubulin-specific polyclonal antibody. In situ, the overall process of mitosis appears nearly identical to that described in cell culture. All types of mitotic microtubules (kinetochore, interpolar and asterial) can be visualized at the different stages. The slight differences from observations in cell culture are explained by differences in cell interactions. In bipolar neuroepithelial cells, interphasic microtubules appear in the form of a framework surrounding the nucleus during its to-and-fro movements and which follows the modifications in shape of the cell processes. These microtubules seem to play an active role in the mechanism, indicating the modifications in length of the apical process. In the differentiating young neuron, tubulin increases in amount to be involved in the elongation of axonal microtubules. This increase seems to be independent of the presence of axons in the environment. Axonal microtubules are independent of a microtubule-organizing center localized in the perikaryon.     

Phenotypic Characterization of Paranoiac and Related Mutants in Paramecium Tetraurelia

Paranoiac and related mutants of Paramecium tetraurelia display altered membrane excitability. We describe an extension of behavioral characterizations of the paranoiac, fast-2, and tetraethylammonium-insensitive mutants, comparing in detail their reactions to sodium stimulation under standard culture conditions, when grown at various temperatures and when starved. We also use freeze-fracture electron microscopic techniques to analyze in these stocks the morphology of organized arrays of membrane particles, the ciliary plaques. This group of mutants is diverse, showing differences in behavior under standard culture conditions and different reactions to temperature and starvation stresses. Ciliary plaque morphology is altered in some, but not all, of the mutants. The possibility is discussed that these plaques may be sites of potassium or sodium transport.     

Characterization of Mendelian and Non-Mendelian Mutant Strains by Micronuclear Transplantation in Paramecium tetraurelia

ABSTRACT. Mutant strain d48 and d12 cannot express serotype A. In d48, the A i-antigen gene is present in the micronucleus, but not in the macronucleus. It has recently been shown that d12 contains the A gene in its micronucleus, but its macronucleus lacks the gene. Micronuclear transplantations into enucleated cells were performed to analyze those mutants. Reciprocal transplantation between wild type and d48 confirmed that d48 contains the A gene in the micronucleus and its cytoplasm is defective. Wild type 51 enucleated cells into which were transplanted d12 micronuclei could not express A. Amiccronucleate d12 cells into which were transplanted normal micronuclei from 51 or d48 showed no expression of A. These results show that even if the micronucleus of d12 contains the A gene, it must be abnormal, and its cytoplasm is also defective the same as d48. Genetic analysis showed that heterozygote of d12 and wild type 51 or d48 caused a cure of the cytoplasmic defect of d48 and d12 during the development of macronuclei.     

Isolation and Characterization of Paramecium Mutants Defective in Their Response to Magnesium

Four mutant strains of Paramecium tetraurelia with a reduced ability to respond behaviorally to Mg(2+) have been isolated. Voltage-clamp analyses showed that their Mg(2+) insensitivity is associated with a reduced Ca(2+) -dependent Mg(2+) current. The four mutants, which have been dubbed ``eccentric,' result from recessive mutations in two unlinked loci, xntA and xntB. Further analysis of xntA(1) showed it to be unlinked to any of the behavioral mutants of P. tetraurelia described previously, but it is allelic to d4-521, a ``K(+)-resistant' strain, and d4-596, a ``Ba(2+)-shy' mutant. The varied pleiotropic effects of xntA(1), which include increased resistance to Ni(2+) and Zn(2+) poisoning, suggest that the locus encodes a central regulator of cell function in Paramecium.     

Acoel spermatozoa: ultrastructure and immunocytochemistry of tubulin

Acoel spermatozoa are filiform and contain two parallel axonemes, which do not show the trepaxonematan 9 + ‘1’ pattern, but instead, another kind of 9 + ‘1’ pattern, or a 9 + 0 or 9 + 2 pattern. Spermatozoa have either cortical singlet microtubules or central microtubules. Identification of these groups of microtubules and recognition of homologies between species is difficult with electron microscopy. In addition to conventional electron microscopy, indirect immunofluorescence of tubulin was performed on three species (Symsagittifera schultzei, Symsagittifera psammophila, and Actinoposthia beklemischevi). This technique facilitated understanding of the general morphology of the filiform spermatozoon and of the arrangement of the microtubular organelles along its length. We have found that different monoclonal antibodies (anti-alpha-, anti-alpha-acetylated- and anti-beta-tubulin) can distinguish distinct subcellular populations of microtubules. The axonemes were labelled by the three antibodies in all species. The cortical microtubules (in Actinoposthia beklemischevi) were labelled by the three antibodies. The central microtubules (in Symsagittifera schultzei and S. psammophila) were labelled with the anti-beta-tubulin antibody and not labelled by the anti-alpha- and anti-alpha-acetylated-tubulin. Similar experiments were performed on other Platyhelminthes and indicated that immunocytochemistry of spermatozoa may provide new characters for phylogenetic studies. This revised version was published online in July 2006 with corrections to the Cover Date.     

Mutants of Nicotiana plumbaginifolia with specific resistance to auxin

Summary We have isolated nine independent auxin-resistant mutants of Nicotiana plumbaginifolia by culturing M₂ seedlings in the presence of indole-3-acetic acid ethyl ester or 1-naphthaleneacetic acid at concentrations which significantly inhibit hypocotyl elongation of the wild type. The mutations were induced by treating seed with ethyl methanesulphonate and were found in the course of screening 10 000 individual M₂ families. Auxin resistance was in all cases the result of a mutation at a single, nuclear locus. The dominance relationships of two of the mutants could be defined as recessive or dominant; all other mutants showed partial dominance. In contrast to previously described mutants of Arabidopsis and N. plumbaginifolia, all of the present mutants were specifically resistant to auxin; the mutants were cross-resistant to several auxins, but showed no increased resistance to cytokinin, abscisic acid, ethylene or 1-amino-cyclopropane-1-carboxylic acid. The importance of the choice of the selection criterion for the isolation of specific resistance traits is discussed.     

New Mutants of Paramecium Tetraurelia Defective in a Calcium Control Mechanism: Genetic and Behavioral Characterizations

The k-shy mutants of Paramecium tetraurelia are altered in several Ca2+-dependent functions which regulate ciliary motility. The isolation, genetics, and phenotypes of these mutants are described. Of six independent isolates, all contained recessive single-factor mutations and comprise two unlinked loci, ksA and ksB. All k-shy strains showed prolonged backward swimming responses to depolarizing stimuli, but gave infrequent responses to some stimuli. At least four k-shy strains displayed temperature sensitivity. Neither ksA nor ksB was allelic or linked to dancer, a mutation causing weak Ca2+ current inactivation and prolonged backward swimming. Analysis of ks+; Dn double mutants revealed synergism between the two mutations. The ksA mutant survived Ba2+ solutions longer than wild type, but was more sensitive to K+. Together with previous studies, these results are consistent with a defect in reducing intracellular Ca2+ causing both prolonged ciliary reversal and reduced Ca2+ channel activity due to more active Ca2+-dependent feedback mechanisms. The integration of the Ca2+-dependent stimulatory and inhibitory functions is therefore dependent on ks+ gene functions. The ksA mutant was rescued by microinjection of wild-type cytoplasm, suggesting a possible behavioral assay for factors related to the ksA+ gene product.     

Induction of Conjugation by Methyl Cellulose in Paramecium

ABSTRACT An improved method has been developed for the induction of selfing conjugation in Paramecium. Methyl cellulose induces selfing conjugation simply and efficiently in all species examined. Induction of conjugation by methyl cellulose was characterized in P. caudatum , where it occurred only in sexually mature, mating reactive cells. Conjugation produced sexual offspring and the time course of nuclear processes was substantially the same as that in natural conjugation between cells of complementary mating types. The method is useful for genetic studies in a wide variety of Paramecium species including P. caudatum, P. tetraurelia, P. multimicronucleatum and P. bursaria.     

Association between microtubules and symbiotic fungal hyphae in protocorm cells of the orchid species, Spiranthes sinensis

Seeds of the orchid species, Spiranthes sinensis (Pers.) Ames, were sterilized and germinated in vitro with the symbiotic fungus Ceratobasidium cornigerum (Bourdot) Rogers. Colonized embryos developed into protocorms and these were examined for changes in microtubule arrays, after initial invasion of fungal hyphae into embryos and during peloton formation and degradation. Methods utilized to detect microtubules included immunofluorescence combined with laser scanning confocal microscopy, conventional transmission electron microscopy combined with morphometric analysis, and immunogold labelling. Microtubules were regularly found in close association with intracellular hyphae and degraded hyphal masses. Cortical microtubules disappear during peloton formation but reappear in cells that show fungal lysis. With conventional transmission electron microscopy and immunogold labelling the microtubules associated with fungal hyphae and degenerated hyphal masses were located close to the perifungal membrane that separates fungal hyphae from protocorm cytoplasm.     

Mutations Affecting the Trichocysts in Paramecium aurelia. I. Morphology and Description of the Mutants*

Six types of genic mutants have been isolated. Their phenotypes range from animals with no trichocysts (trichless), to animals with morphologically abnormal trichocysts (football, stubby, pointless, screwy-cigar), to animals which are incapable of extruding otherwise normal looking trichocysts (nondischarge). The football mutant possesses football-shaped trichocysts, which, unlike wild-type trichocysts, do not attach at the cortex. The stubby mutant possesses shorter trichocysts which have a very highly variable morphology. The screwy-cigar animals have thinner and usually longer trichocysts than those found in wild-type cells. The trichocysts of the pointless mutant have all the components of the wild-type organelles but not in their proper relationship. Electron microscopic studies of the mutants have demonstrated that although the morphology of the various mutant trichocysts may differ, their ultrastructure and early developmental stages are comparable to those of trichocysts found in wild type. The mutations are usually pleiotropic, affecting other systems besides trichocysts. The existence of these mutants, particularly trichless, poses some interesting questions regarding the function of trichocysts, and also gives insight into the development of trichocysts.     

Activation-Tagged Tobacco Mutants that are Tolerant to Antimicrotubular Herbicides are Cross-Resistant to Chilling Stress

T-DNA activation tagging was used to generate tobacco mutants with increased tolerance to antimicrotubular herbicides and chilling stress. After transformation, protoplast-derived calli were screened for tolerance to treatments that affect microtubule assembly. In one screen mutants with tolerance to aryl carbamates (a blocker of microtubule assembly) were selected, the second screen was targeted to chilling-tolerant mutants that could survive for several months at 3°C, a third screen combined both factors. The resistance of these mutants to aryl carbamates or chilling was accompanied by resistance of microtubules to these factors. The carbamate tolerant mutants were cross-resistant to chilling stress. This was mirrored by an adaptive reorganization of microtubules and a reduction of microtubule dynamics in response to chilling. The analysis of these mutants suggests (1) that microtubule dynamics limit the tolerance to chilling and EPC, and (2) that the cold sensitivity of microtubules limits chilling tolerance in tobacco.     

A Genetic Screen to Isolate Toxoplasma gondii Host-cell Egress Mutants

The widespread, obligate intracellular, protozoan parasite Toxoplasma gondii causes opportunistic disease in immuno-compromised patients and causes birth defects upon congenital infection. The lytic replication cycle is characterized by three stages: 1. active invasion of a nucleated host cell; 2. replication inside the host cell; 3. active egress from the host cell. The mechanism of egress is increasingly being appreciated as a unique, highly regulated process, which is still poorly understood at the molecular level. The signaling pathways underlying egress have been characterized through the use of pharmacological agents acting on different aspects of the pathways^1-5. As such, several independent triggers of egress have been identified which all converge on the release of intracellular Ca²⁺, a signal that is also critical for host cell invasion^6-8. This insight informed a candidate gene approach which led to the identification of plant like calcium dependent protein kinase (CDPK) involved in egress⁹. In addition, several recent breakthroughs in understanding egress have been made using (chemical) genetic approaches^10-12. To combine the wealth of pharmacological information with the increasing genetic accessibility of Toxoplasma we recently established a screen permitting the enrichment for parasite mutants with a defect in host cell egress¹³. Although chemical mutagenesis using N-ethyl-N-nitrosourea (ENU) or ethyl methanesulfonate (EMS) has been used for decades in the study of Toxoplasma biology^11,14,15, only recently has genetic mapping of mutations underlying the phenotypes become routine^16-18. Furthermore, by generating temperature-sensitive mutants, essential processes can be dissected and the underlying genes directly identified. These mutants behave as wild-type under the permissive temperature (35 °C), but fail to proliferate at the restrictive temperature (40 °C) as a result of the mutation in question. Here we illustrate a new phenotypic screening method to isolate mutants with a temperature-sensitive egress phenotype¹³. The challenge for egress screens is to separate egressed from non-egressed parasites, which is complicated by fast re-invasion and general stickiness of the parasites to host cells. A previously established egress screen was based on a cumbersome series of biotinylation steps to separate intracellular from extracellular parasites¹¹. This method also did not generate conditional mutants resulting in weak phenotypes. The method described here overcomes the strong attachment of egressing parasites by including a glycan competitor, dextran sulfate (DS), that prevents parasites from sticking to the host cell¹⁹. Moreover, extracellular parasites are specifically killed off by pyrrolidine dithiocarbamate (PDTC), which leaves intracellular parasites unharmed²⁰. Therefore, with a new phenotypic screen to specifically isolate parasite mutants with defects in induced egress, the power of genetics can now be fully deployed to unravel the molecular mechanisms underlying host cell egress.     

Ca2+ Current-Deficient Pawn Mutants are Promoted to Queens During Chronic Depolarization of Paramecium tetraurelia

Chronic KCl-induced depolarization of Paramecium tetraurelia enhances Ca²⁺-dependent backward swimming behavior over a period of 8–24 hr. Here, we investigated the electrophysiological mechanisms underlying this adaptive phenomenon using voltage-clamp techniques. Cells that had been adapted to 20 mm KCl showed several significant changes in the properties of the Ca²⁺ current that mediates ciliary reversal in Paramecium (I _Ca ), including a positive shift in voltage sensitivity and a significant slowing of inactivation. In seeking an explanation for these changes, we examined the effects of chronic depolarization on mutants that do not normally express a Ca²⁺ current or swim backward. Surprisingly, pawn B mutant cells slowly regained the ability to reverse their cilia during KCl exposure with a time course that mirrored behavioral adaptation of the wild type. This behavior was accompanied by expression of a novel Ca²⁺ current (I _QUEEN ) whose voltage sensitivity was shifted positive with respect to the wild-type Ca²⁺ current and that was slow to inactivate. Coincidental expression of I _QUEEN in the wild type during adaptation would readily explain the observed changes in I _Ca kinetics. We also examined the effects of chronic depolarization on Dancer, a mutant suggested previously to have an I _Ca inactivation defect. The mutant phenotype could be suppressed or exaggerated greatly by manipulating extracellular KCl concentration, suggesting that Dancer lesion instead causes inappropriate regulation of I _QUEEN . Received: 23 April 1999/Revised: 29 June 1999     

Analysis of Different Methodological Approaches to Measuring Microtubule Length in the Cytoplasm of Cultured Cells

It is generally assumed that microtubules in tissue culture cells extend from the centrosome to cell periphery, and the length of individual microtubules averages several dozens of microns. However, direct electron-microscopic measurements have cast some doubt on this assumption. In this study, the average length of microtubules in cultured Vero cells was estimated using a combined approach. The length of free cytoplasmic and centrosomal microtubules was determined by means of electron microscopy in serial sections; concurrently, the length of free microtubules in the lamella was measured in preparations stained with tubulin antibodies (an indirect immunofluorescent method), by tracing saltatory particle movements along the microtubules in living cells. According to the data of immunofluorescent microscopy, microtubule length in the lamella averaged 4.57 ± 3.69 m. However, since two or more microtubules can overlap, their length may be slightly overestimated by this method. On the other hand, saltatory movements are easy to monitor and measure fairly accurately, but their range may be shorter than the actual microtubule length because of a limited processiveness of motors (kinesin and dynein). On average, the trajectories of saltatory movements in living cells were 3.85 ± 0.72 m long. At the electron-microscopic level, microtubule length was analyzed using pseudo-three-dimensional reconstructions of the microtubule systems around the centrosome and in the lamella. The length of free microtubules in the lamella reached 18 m, averaging 3.33 ± 2.43 m; the average length of centrosomal microtubules was 1.49 ± 0.82 m. Good correspondence between the data on microtubule length and arrangement obtained by different methods allows the conclusion that most of the free microtubules in Vero cells actually have a length of 2–5 m; i.e., they are much shorter than the cell radius (about 25 m). Microtubules extending from the centrosome are shorter still and do not reach the cell periphery. Thus, most microtubules in the lamella of Vero cells are free and their ordered arrangement is not associated with their attachment to the centrosome.