Mating types in the ciliate Dileptus anser. Inheritance and genetic determination

Hybridological analysis of mating types (MTs) has been first made for the lower ciliate Dileptus anser. Clones of an initially unknown genotype belonging to three MTs (MT I, MT II and MT III), characteristic of D. anser, were isolated from natural reservoirs and further used for crosses. In one group crosses, synclonal inheritance and typical Mendelian behaviour of the character were observed over sexual generations of ciliates. The results suggest that MTs in D. anser may be directly controlled by a single mat locus with three alleles showing peck-order dominance (mat1 > mat2 > mat3). In other words, cells with mat1/mat1, mat1/mat2 and mat1/mat3 genotypes belong to MT I, those with mat2/mat2 and mat2/mat3, and the mat3/mat3 belong to MT II and MT III, respectively. Sexually mature exconjugant clones stably retain their MTs corresponding to their genotypes on vegetative reproduction. The progeny of other group crosses showed various deviations from typical Mendelian behaviour of the character. In some cases, standard Mendelian ratios were more or less violated. Most typical was instability of differentiation for MT in maturing exconjugant clones. Shortly after their maturation, the majority of clones change their MT, rather frequently more than once, although the finally established MT is stably inherited afterwards, during vegetative reproduction. When unstable, exconjugant clones can successively express two or even three MTs characteristic of this species, including MTs that should not have been expected on the basis of parental genotypes available in a given cross. It looks likely that the mat locus in D. anser is complex and multipotential; it is inherited as a whole providing for expression of any MT characteristic of the species (in this respect bearing similarity with Tetrahymena thermophila). Other mechanisms, epigenetic in particular (Nanney, 1958), determine the final expression of one of the three MT potentialities by a given exconjugant clone. Stable, persistent functioning of these mechanisms ensures a stable differentiation for MT and Mendelian behaviour of the character in sexual generations and in crosses. Any disturbances in differentiation control may trigger MT instability in maturing exconjugant clones and violation of regular Mendelian behaviour.     

Mating types in the ciliate Dileptus anser. Shortening of maturation period after micrurgical bisection of exconjugant cells

In many ciliates, young exconjugant clones demonstrate sexual immaturity: they are not able to conjugate with mature cells of complementary mating types (MTs). After several scores of cell divisions, a short period of adolescence (partial maturity) commonly occurs followed by maturation, after which these cells are able to conjugate with cells of other, i.e. complementary, MTs again. Tavrovskaja (1981) reported a significant reduction in the maturity period in Dileptus anser clones, grown from exconjugant ciliates regenerated from small cell fragments. To verify this, in the present study exconjugant D. anser cells were bisected with glass needle after 3 to 4 cell divisions following conjugation. The same procedure was performed with survived and regenerated cells on the 2nd and 3rd days. The clones thus obtained were cultivated, and their ability to mate with each of the three standard clones of MT I, II and III was tested week by week. Indeed, in 22 F1 clones from cross N 7C (MT I) x N 2 (MT II) the immaturity period was reduced 1.4-3.4-fold (2.18 in average) after a threefold bisection, as compared with that in intact subclones. Similarly, in 27 F1 clones from cross N 20 (MT I) x N 14 (MT II) this period was shortened 1.6-3.0-fold (2.19 in average). 12 of these clones showed a 0.9-2.4-fold (1.53 in average) reduction after a single bisection, and 1.6-2.8 (2.12 in average) after a threefold operation. Thus, micrurgical fragmentation of young exconjugant cells can be used to accelerate maturation in D. anser.     

Actinomycin D-induced change of mating type in the ciliate Dileptus anser

The effects of actinomycin D on the expression and inheritance of mating types (MTs) were studied in mature laboratory clones of the ciliate Dileptus anser. In these ciliates, each mature clone isolated from the natural population belongs to one of three complementary MTs, i.e., MT I, MT II, or MT III. In the course of further cultivation of the clone under laboratory conditions, in a series of vegetative generations, its MT remained unchanged. However, treatment with actinomycin D (15 μg/ml, 3 days) causes these clones to transition to a state that is hereditarily unstable for their MTs. At weekly testing for MT for at least 15 weeks after this treatment (which corresponds to more than 100 cell divisions), many subclones of the treated clone were observed to reversibly exchange their MT for another one; a temporary state of immaturity and/or partial maturity was also revealed. These data confirm our hypothesis about epigenetic MT determination in D. anser. Taking into account that actinomycin D also induces the inheritable destabilization of some characters in amoebas Amoeba proteus, which obviously has an epigenetic nature, this antibiotic might be considered an epimutagen.     

Development of sexual maturity in the ciliate Euplotes crassus: sources of variation in the timing of maturity.

The life styles of ciliated protists are particularly suitable for experimental analyses of certain aspects of developmental and genetic biology. The progression from sexual immaturity to maturity to senescence represents one of the most intriguing aspects of developmental programs. The extent to which progeny clones, their subclones, and testers used in the assay result in different lengths of immaturity has been investigated in Euplotes crassus. Six subclones from each of 12 progeny clones from a cross between stocks EC1 and EC2 were tested for maturity with stocks EC3, EC4, and EC5 on every transfer. Analysis of variance was used to partition the total variation in fissions to maturity into parts due to clones, subclones, and testers and the interactions between these levels. The error, interaction of subclones and testers, corresponds to a standard deviation of only 4.1 fissions, while the within clone within tester means range from 15.2 to 46.7 fissions; all levels except testers contribute significantly to the total variation. Most of the variability is attributable to clones (66%), the next most to error (16%), the next most to interaction of clones by testers (13%), and the least to subclones (5%). An a posteriori analysis examined whether the differences among clones were due to the cytoplasm of the clone ancestor (exconjugant), its mat (mating-type) locus genotype, or the mated pair it came from. None of these characteristics was able to interpret simply the large variability among clones. These results provide evidence that the transition from immaturity to maturity is quantitative and complex rather than a jump from one well-defined state to another.     

Three Genes Which Affect Founding of Aggregations in Polysphondylium Pallidum

PN6024 is an extraordinary mutant strain of the cellular slime mold Polysphondylium pallidum, characterized by having defects in many unlinked genes. New strains with altered development appeared spontaneously as aberrant clones of PN6024. Genetic crosses using the macrocyst sexual cycle were used to show that PN6030 (a clone like PN6024 in phenotype) carries mutations at two loci, emm and hge, whereas PN6031 (a clone of altered morphology) carries in addition a mutation at a third locus, mgt. hge and possibly mgt are linked to the mating type locus mat. The relatively high frequency of recombination between mat and hge is strong evidence that meiosis precedes macrocyst germination. The mutant genes themselves are of interest. A major effect of the emm-1 mutation is to remove the requirement for light to trigger aggregation. hge-1 greatly reduces the frequency of aggregation, whereas mgt-1 greatly increases it under standard conditions. None of these mutations interrupts later development leading to stalks and spore cells. It is hypothesized that all three genes act on steps immediately preceding the differentiation of the founder cells which initiate aggregation.     

Identification of microtubule growth deceleration and its regulation by conserved and novel proteins

Microtubules (MTs) are cytoskeletal polymers that participate in diverse cellular functions, including cell division, intracellular trafficking, and templating of cilia and flagella. MTs undergo dynamic instability, alternating between growth and shortening via catastrophe and rescue events. The rates and frequencies of MT dynamic parameters appear to be characteristic for a given cell type. We recently reported that all MT dynamic parameters vary throughout differentiation of a smooth muscle cell type in intact Caenorhabditis elegans. Here we describe local differences in MT dynamics and a novel MT behavior: an abrupt change in growth rate (deceleration) of single MTs occurring in the cell periphery of these cells. MT deceleration occurs where there is a decrease in local soluble tubulin concentration at the cell periphery. This local regulation of tubulin concentration and MT deceleration are dependent on two novel homologues of human cylicin. These novel ORFs, which we name cylc-1 and -2, share sequence homology with stathmins and encode small, very basic proteins containing several KKD/E repeats. The TOG domain–containing protein ZYG-9^TOGp is responsible for the faster polymerization rate within the cell body. Thus we have defined two contributors to the molecular regulation for this novel MT behavior.     

Examining the specific contributions of individual Arabidopsis metallothioneins to copper distribution and metal tolerance

Metallothioneins (MTs) are small cysteine-rich proteins found in various eukaryotes. Plant MTs are classified into four types based on the arrangement of cysteine residues. To determine whether all four types of plant MTs function as metal chelators, six Arabidopsis (Arabidopsis thaliana) MTs (MT1a, MT2a, MT2b, MT3, MT4a, and MT4b) were expressed in the copper (Cu)- and zinc (Zn)-sensitive yeast mutants, Deltacup1 and Deltazrc1 Deltacot1, respectively. All four types of Arabidopsis MTs provided similar levels of Cu tolerance and accumulation to the Deltacup1 mutant. The type-4 MTs (MT4a and MT4b) conferred greater Zn tolerance and higher accumulation of Zn than other MTs to the Deltazrc1 Deltacot1 mutant. To examine the functions of MTs in plants, we studied Arabidopsis plants that lack MT1a and MT2b, two MTs that are expressed in phloem. The lack of MT1a, but not MT2b, led to a 30% decrease in Cu accumulation in roots of plants exposed to 30 mum CuSO(4). Ectopic expression of MT1a RNA in the mt1a-2 mt2b-1 mutant restored Cu accumulation in roots. The mt1a-2 mt2b-1 mutant had normal metal tolerance. However, when MT deficiency was combined with phytochelatin deficiency, growth of the mt1a-2 mt2b-1 cad1-3 triple mutant was more sensitive to Cu and cadmium compared to the cad1-3 mutant. Together these results provide direct evidence for functional contributions of MTs to plant metal homeostasis. MT1a, in particular, plays a role in Cu homeostasis in the roots under elevated Cu. Moreover, MTs and phytochelatins function cooperatively to protect plants from Cu and cadmium toxicity.     

Effects of {gamma}-tubulin complex proteins on microtubule nucleation and catastrophe in fission yeast

Although gamma-tubulin complexes (gamma-TuCs) are known as microtubule (MT) nucleators, their function in vivo is still poorly defined. Mto1p (also known as mbo1p or mod20p) is a gamma-TuC-associated protein that recruits gamma-TuCs specifically to cytoplasmic MT organizing centers (MTOCs) and interphase MTs. Here, we investigated gamma-TuC function by analyzing MT behavior in mto1Delta and alp4 (GCP2 homologue) mutants. These cells have free, extra-long interphase MTs that exhibit abnormal behaviors such as cycles of growth and breakage, MT sliding, treadmilling, and hyperstability. The plus ends of interphase and spindle MTs grow continuously, exhibiting catastrophe defects that are dependent on the CLIP170 tip1p. The minus ends of interphase MTs exhibit shrinkage and pauses. As mto1Delta mutants lack cytoplasmic MTOCs, cytoplasmic MTs arise from spindle or other intranuclear MTs that exit the nucleus. Our findings show that mto1p and gamma-TuCs affect multiple properties of MTs including nucleation, nuclear attachment, plus-end catastrophe, and minus-end shrinkage.     

Microtubule-dependent transport and organization of sarcomeric myosin during skeletal muscle differentiation

It has been proposed that microtubules (MTs) participate in skeletal muscle cell differentiation. However, it is still unclear how this happens. To examine whether MTs could participate directly in the organization of thick and thin filaments into sarcomeres, we observed the concomitant reorganization and dynamics of MTs with the behavior of sarcomeric actin and myosin by time-lapse confocal microscopy. Using green fluorescent protein (GFP)-EB1 protein to label MT plus ends, we determined that MTs become organized into antiparallel arrays along fusing myotubes. Their dynamics and orientation was found to be different across the thickness of the myotubes. We observed fast movements of Dsred-myosin along GFP-MTs. Comparison of GFP-EB1 and Dsred-myosin dynamics revealed that myosin moved toward MT plus ends. Immuno-electron microscopy experiments confirmed that myosin was actually associated with MTs in myotubes. Finally, we confirmed that MTs were required for the stabilization of myosin-containing elements prior to incorporation into mature sarcomeres. Collectively, our results strongly suggest that MTs become organized into a scaffold that provides directional cues for the positioning and organization of myosin filaments during sarcomere formation.     

Dynamic behavior of GFP-CLIP-170 reveals fast protein turnover on microtubule plus ends

Microtubule (MT) plus end-tracking proteins (+TIPs) specifically recognize the ends of growing MTs. +TIPs are involved in diverse cellular processes such as cell division, cell migration, and cell polarity. Although +TIP tracking is important for these processes, the mechanisms underlying plus end specificity of mammalian +TIPs are not completely understood. Cytoplasmic linker protein 170 (CLIP-170), the prototype +TIP, was proposed to bind to MT ends with high affinity, possibly by copolymerization with tubulin, and to dissociate seconds later. However, using fluorescence-based approaches, we show that two +TIPs, CLIP-170 and end-binding protein 3 (EB3), turn over rapidly on MT ends. Diffusion of CLIP-170 and EB3 appears to be rate limiting for their binding to MT plus ends. We also report that the ends of growing MTs contain a surplus of sites to which CLIP-170 binds with relatively low affinity. We propose that the observed loss of fluorescent +TIPs at plus ends does not reflect the behavior of single molecules but is a result of overall structural changes of the MT end.     

Regulation of microtubule dynamics by TOG-domain proteins XMAP215/Dis1 and CLASP

The molecular mechanisms by which microtubule-associated proteins (MAPs) regulate the dynamic properties of microtubules (MTs) are still poorly understood. We review recent advances in our understanding of two conserved families of MAPs, the XMAP215/Dis1 and CLASP family of proteins. In vivo and in vitro studies show that XMAP215 proteins act as microtubule polymerases at MT plus ends to accelerate MT assembly, and CLASP proteins promote MT rescue and suppress MT catastrophe events. These are structurally related proteins that use conserved TOG domains to recruit tubulin dimers to MTs. We discuss models for how these proteins might use these individual tubulin dimers to regulate dynamic behavior of MT plus ends.     

Effect of metallothionein on cell viability and its interactions with cadmium and zinc in HEK293 cells

Metallothioneins (MTs) are thought to participate in a wide variety of physiological roles, but the mechanisms involved are still unclear. The study was designed to examine the possible factors related to these mechanisms. Methods, including transfection, MTT assay and flow cytometry, were used to investigate the effect of MTs on cell viability and their interactions with cadmium and zinc in HEK293 cells. The results showed that transient overexpression of human MT1A, MT2 and MT3 genes dynamically affected cell viability, and the effect was influenced by zinc and cadmium ions. Overexpressed MTs with added zinc showed a greater inhibitory effect on cell viability. Overexpressed MTs protected cells against low concentrations of cadmium ions (10 microM), but increased cell death in response to high concentrations (20-50 microM). Out of the three MTs, MT1A was more efficient than MT2 and MT3 in its resistance to cadmium (10 microM), and MT3 together with zinc showed more cell growth inhibition than MT1 and MT2. These results indicate that both of the divalent metal ions that could bind MTs, as well as the individual MT isoforms, affect the role of MTs on cell viability, which may explain in part why the comprehensive effect of MTs on the cells was elusive.     

Microtubule plus end: a hub of cellular activities

Microtubules (MTs) are highly dynamic polymers, which control many aspects of cellular architecture. Growing MT plus ends accumulate a specific set of evolutionary conserved factors, the so-called MT plus-end-tracking proteins (+TIPs). +TIPs regulate MT dynamics and the reciprocal interactions of MTs with the cell cortex, mitotic kinetochores or different cellular organelles. Most +TIPs can directly bind to MTs, but the molecular mechanisms of their specific targeting to the growing plus ends remain poorly understood. Recent studies suggest that the members of one particular +TIP family, EB1 and its homologues, are present in all eucaryotic kingdoms, interact directly with the majority of other known plus-end-associated proteins and may be responsible for their specific accumulation at the MT tips.     

Feedback Mechanism for Microtubule Length Regulation by Stathmin Gradients

We formulate and analyze a theoretical model for the regulation of microtubule (MT) polymerization dynamics by the signaling proteins Rac1 and stathmin. In cells, the MT growth rate is inhibited by cytosolic stathmin, which, in turn, is inactivated by Rac1. Growing MTs activate Rac1 at the cell edge, which closes a positive feedback loop. We investigate both tubulin sequestering and catastrophe promotion as mechanisms for MT growth inhibition by stathmin. For a homogeneous stathmin concentration in the absence of Rac1, we find a switchlike regulation of the MT mean length by stathmin. For constitutively active Rac1 at the cell edge, stathmin is deactivated locally, which establishes a spatial gradient of active stathmin. In this gradient, we find a stationary bimodal MT-length distribution for both mechanisms of MT growth inhibition by stathmin. One subpopulation of the bimodal length distribution can be identified with fast-growing and long pioneering MTs in the region near the cell edge, which have been observed experimentally. The feedback loop is closed through Rac1 activation by MTs. For tubulin sequestering by stathmin, this establishes a bistable switch with two stable states: one stable state corresponds to upregulated MT mean length and bimodal MT length distributions, i.e., pioneering MTs; the other stable state corresponds to an interrupted feedback with short MTs. Stochastic effects as well as external perturbations can trigger switching events. For catastrophe-promoting stathmin, we do not find bistability.     

Identification of microtubule binding sites in the Ncd tail domain

Nonclaret disjunctional (Ncd) is a minus end-directed, C-terminal motor protein that is required for spindle assembly and maintenance during meiosis and early mitosis in Drosophila oocytes and early embryos. Ncd has an ATP-independent MT binding site in the N-terminal tail domain, and an ATP-dependent MT binding site in the C-terminal motor domain. The ability of Ncd to cross-link MTs through the action of these binding sites may be important for Ncd function in vivo. To identify the region(s) responsible for ATP-independent MT interactions of Ncd, 12 cDNAs coding various regions of Ncd tail domain were expressed in E. coli as C-terminal fusions to thioredoxin (Trx). Ncd tail fusion proteins (TrxNT) were purified by ion exchange (S-Sepharose) and/or Talon metal affinity chromatography. Purified TrxNT and NT proteins were analyzed in microtubule (MT) cosedimentation and bundling assays to identify which tail proteins were able to bind and bundle MTs. Based on the results of these experiments, all TrxNT and NT proteins that showed MT binding activity also bundled MTs, and there are two ATP-independent MT interaction sites in the tail region: one within amino acids 83-100 that exhibits conformation-independent, high-affinity MT binding activity; and another within amino acids 115-187 that exhibits conformation-dependent, lower affinity MT binding activity. It is possible that both of these MT interacting sites combine in the native protein to form a single MT binding site that allows the Ncd tail to bind cargo MTs in vivo.     

Adenomatous polyposis coli (APC) protein moves along microtubules and concentrates at their growing ends in epithelial cells

Adenomatous polyposis coli (APC) tumor suppressor protein has been shown to be localized near the distal ends of microtubules (MTs) at the edges of migrating cells. We expressed green fluorescent protein (GFP)-fusion proteins with full-length and deletion mutants of Xenopus APC in Xenopus epithelial cells, and observed their dynamic behavior in live cells. During cell spreading and wound healing, GFP-tagged full-length APC was concentrated as granules at the tip regions of cellular extensions. At higher magnification, APC appeared to move along MTs and concentrate as granules at the growing plus ends. When MTs began to shorten, the APC granules dropped off from the MT ends. Immunoelectron microscopy revealed that fuzzy structures surrounding MTs were the ultrastructural counterparts for these GFP signals. The COOH-terminal region of APC was targeted to the growing MT ends without forming granular aggregates, and abruptly disappeared when MTs began to shorten. The APC lacking the COOH-terminal region formed granular aggregates that moved along MTs toward their plus ends in an ATP-dependent manner. These findings indicated that APC is a unique MT-associated protein that moves along selected MTs and concentrates at their growing plus ends through their multiple functional domains.     

Role of metallothioneins in superoxide radical generation during copper redox cycling: defining the fundamental function of metallothioneins

In order to demonstrate the in vivo antioxidant properties of metallothioneins (MTs), the bacteria Escherichia coli was used as a cell reactor in which we compared the metal binding and antioxidative functions of MTs from different species, with different structures and polypeptide lengths. No protective effects of cytoplasmic MTs from cadmium (Cd) or zinc (Zn) contamination were observed in a wild-type E. coli strain, although these MTs can efficiently bind both Cd and Zn. To test their antioxidant properties, MTs were expressed within the cytoplasm of a sodA sodB deficient mutated strain (QC1726). However, a paradoxical MT toxicity was found when this strain was contaminated with Cd and Zn, suggesting that in a wild-type strain, superoxide dismutase counteracts MT toxicity. The most toxic MT was the one with the strongest Cd and Zn binding capacities. This toxic effect was linked to the generation of superoxide radicals, since a Cd-contaminated QC1726 strain expressing oyster MT isoforms produced 75-85% more O(2)*(-) than the control QC1726 strain. Conversely, under anaerobiosis or in the presence of a copper chelator, MTs protected QC1726 strain from Cd and Zn contamination. A model is proposed to explain the observed MT toxicity.     

Calcium tips the balance: a microtubule plus end to lattice binding switch operates in the carboxyl terminus of BPAG1n4

Microtubules (MTs) are integral to numerous cellular functions, such as cell adhesion, differentiation and intracellular transport. Their dynamics are largely controlled by diverse MT‐interacting proteins, but the signalling mechanisms that regulate these interactions remain elusive. In this report, we identify a rapid, calcium‐regulated switch between MT plus end interaction and lattice binding within the carboxyl terminus of BPAG1n4. This switch is EF‐hand dependent, and mutations of the EF‐hands abolish this dynamic behaviour. Our study thus uncovers a new, calcium‐dependent regulatory mechanism for a spectraplakin, BPAG1n4, at the MT plus end.     

Dynamics and the life cycle of cell microtubules

In living cells microtubules (MTs) continuously grow and shorten. This feature of MTs was discovered in vitro and named dynamic instability. Comparison of dynamic instability of MTs in vitro and in vivo shows a number of differences. MTs in vivo rapidly grow (up to 20 microns/min), duration of their shortening is small (on average 15-20 s), and pauses are prominent. In different animal cells MTs grow from the centrosome and form a radial array. In such cells growth of MTs is persistent, i.e. undergo without interruptions until plus end of a MT reaches cell margin. Analysis of literature and original data shows that interconvertion between phases of growth, shortening and pause is asymmetric: growth often converts into pause, while shortening always converts into growth without pause. We suggest dynamic instability described near the cell margin in numerous publications results not only from intrinsic properties of MTs, but also because of the external obstacles for their growth. MT behavior in the cells with radial array of long MTs could be treated as dynamic instability with boundary conditions. One boundary is the centrosome responsible for rapid initiation of MT growth. Another boundary is cell margin limiting MT elongation. MT growth occurs with constant mean velocity, and potential duration of growth phase might exceed cell radius. MT shortening is usually smaller than MT length however velocity of shortening increases with time. Random episodes of rapid shortening are sufficient for the exchange of MTs in 10-20 min in the cells not more than 40-50 microns in diameter. Experimental data show that similar rate of exchange of MTs is in the large cells. This is achieved employing another mechanism, namely release of MTs and depolymerization from the minus end. In the minus end pathway time required for the exchange of MTs does not depend on cell radius and is determined primarily by the frequency of releases. Thus a small number of free MTs with metastable minus ends significantly reduce time required for the renovation of the radial MT array. Summarizing all experimental data we suggest the life cycle scheme for the MT in a cell. MT is initiated at the centrosome and grows rapidly until it reaches cell margin. At the margin the plus end oscillates, and finally MT depolimerizes. MT "death" comes from a random catastrophe (shortening from the plus end) in small cells or from release and depolymerization of the minus end in large cells.