Purification and immunofluorescence localization of the mutant gene product of a Tetrahymena cdaA1 mutant affecting cell division

A division arrest mutant, cdaA, of Tetrahymena thermophila is known to have a ts-defect in the formation of the fission zone which determines the position of the fission plane. A protein (Mr = 85,000; pI = 4.7, designated as p85) has recently been identified in our laboratory as a possible gene product of the cdaA locus by two-dimensional gel electrophoresis and genetic experiments (Ohba et al., submitted). In the present research, we have isolated p85, prepared its antibody, and demonstrated that in wild-type cells or in cdaA cells at permissive temperature, immunofluorescence for p85 appears on the equatorial basal bodies at the predicted fission zone just before formation of the zone. In such a case, the fission zone appears to be formed just anterior to the fluorescence-associated basal bodies, and then constriction of the division furrow occurs at the zone. However, in cdaA cells at the restrictive temperature, the equatorial p85 deposit and subsequent fission zone formation and furrowing do not occur at all. Thus, we conclude that p85 plays a key role in the formation of the fission zone and in the positioning of the equatorial fission line.

The energy budget of Tetrahymena and the material fluxes into and out of the adenylate pool

The material budget of the adenylate pool deals with all processes which physically establish and maintain this pool, while the energy budget is concerned with the intracompartmental ATP recycling. Both budgets were analysed in Tetrahymena thermophila exposed to various energy and material demands. Some of the general conclusions are: at a maximum growth rate the overall ATP consumption during one cell cycle is 10(-10) mol ATP; the contribution of osmoregulation and ciliary motion to the budget is about 1% each; at zero net growth, energy is consumed because of a continuous recycling of matter between the monomer and the polymer compartment. The rate of ATP production is about 1000-fold greater than the rate of adenylate monomer influx. The residence time of adenylate monomers within the pool is about 30 min, but for ATP molecules it is only 2 sec.

Regulation of histone acetylation during macronuclear differentiation in Tetrahymena: evidence for control at the level of acetylation and deacetylation

During the postzygotic period of the sexual cycle (conjugation) in the ciliated protozoan, Tetrahymena, daughter products from a single micronuclear mitotic division develop into new macronuclei (anlagen) or new micronuclei depending upon their cytoplasmic location. In this study we have monitored the status of histone acetylation in synchronous populations of developing nuclei isolated from conjugating cells. Particular attention has been paid to the level of histone acetylation in new macronuclei following their differentiation from micronuclei. Like micronuclei isolated from vegetative cells (Vavra et al., 1982), micronuclei from conjugating cells (5 hr, 10-12 hr, and 15-16 hr) contain little if any acetylated histone and incorporate little postsynthetic acetate under any of our experimental conditions. In contrast, young new macronuclei (4C, 10-12 hr) incorporate significant amounts of acetate in vitro and in vivo provided that sodium butyrate is included during the labeling period. These results suggest that 4C anlagen contain both active acetylase and deacetylase activities even though the actual steady state level of acetylation found in these nuclei is low, more like that of micronuclei. At later stages of macronuclear maturation (8C, 15-16 hr), inner histones are hyperacetylated in a manner similar to parental, fully differentiated macronuclei. Furthermore, 8C anlagen incorporate acetate well even in the absence of sodium butyrate. Taken together these results suggest that endogenous deacetylase enzymes become either down-regulated and/or the rate of histone acetylases increases markedly during macronuclear differentiation.

Large-scale selection synchrony of Tetrahymena thermophila

A method is described, based on the phagocytosis of colloidal ferrite particles, which gives highly synchronous populations of Tetrahymena thermophila. To ensure a successful synchrony, the cell culture doubling time, the limits of the phagocytic period and the distribution of cell stages must first be determined. Once these parameters are known, synchrony can be achieved under a variety of growth conditions and with cultures ranging in volume from a few millilitres to 12 litres or more. The main advantages of the method are that the apparatus required is simple, large volumes of cells can be handled easily, and the synchronous populations can be prepared within a few hours. In principle, the method should be applicable to any cell population in which phagocytosis occurs discontinuously over the cell cycle.

Polypeptides during early conjugation in Tetrahymena thermophila

As Tetrahymena thermophila cells differentiate from their vegetative life cycle to sexual reproduction, their polypeptide pattern undergoes a series of changes. These changes have been traced in extracellular, cellular, and subcellular compartments. The first alteration is induced by the nutritional shift-down and results in stimulation of at least one ciliary polypeptide and affects a series of polypeptides from other compartments. The second alteration is induced by mixing starved cells of complementary mating types and this stimulates the synthesis of nine ciliary polypeptides before pairs have formed and eight afterwards. At least five of these early and one of the late conjugation-related ciliary polypeptides are removed by low concentrations of EDTA, indicating that they are located on the external side of the plasma membrane. No differences were observed between polypeptides excreted during starvation and after mixing of complementary mating types. At Tris concentrations restrictive for conjugation, cilia lack the conjugation-related polypeptides. Some of these are instead found among the excreted polypeptides. Using O'Farrell gels and silver staining on isogenic cells of all possible mating types, we have been unable to correlate changes in polypeptide patterns to specific mating types.

Intracellular pattern reversal in Tetrahymena thermophila. II. Transient expression of a janus phenocopy in balanced doublets

Homopolar doublets of Tetrahymena thermophila which have two normal oral systems directly opposite one another may undergo a global transformation of cell surface geometry to create transient imitations of mirror-image configurations brought about by mutations at janus gene loci. The process by which a typical doublet transforms into a janus-like organization involves loss of capacity to form oral structures at one of the two normal oral meridians, followed by interpolation of reversed oral structures at a new location to the cell's right of the disappearing normal oral meridian. At the same time, the contractile vacuole pore (CVP) set on the side of the cell that is undergoing the transformation shifts to the left. The combination of these events creates a symmetrical large-scale organization in which both of the CVP sets are situated on one side of the cell, between the normal and the partially reversed oral apparatus. This unilateral positioning of CVP sets is commonly manifested even when reversed oral structures are absent. These configurations probably represent intermediate stages in the transformation of balanced typical doublets into singlets. We propose that this pathway of regulation from the doublet to the singlet state, like the more common one that starts from unbalanced typical doublets (described in the preceding paper), involves reverse intercalation. The remarkable resemblance between the transient configuration described here and the stable configuration of janus mutant cells leads us to suggest that the phenotype of the mutant is also a consequence of reverse-intercalation, in that case provoked by a loss of capacity to maintain positional values rather than by a geometrical instability in the system of positional values.

Intracellular pattern reversal in Tetrahymena thermophila. I. Evidence for reverse intercalation in unbalanced doublets

Homopolar doublets of Tetrahymena thermophila possess two sets of similar cell surface structures, the most prominent of which are the complex and asymmetrical oral apparatuses. These initially are located on opposite surfaces of the duplex cell, but tend to shift so that they are no longer directly opposite each other. The two sets of oral structures are then separated by one wider and one narrower arc of cell surface. When one arc becomes sufficiently narrow, a new third oral apparatus with partially reversed internal asymmetry frequently becomes interposed between the two preexisting oral apparatuses, always within the narrower arc. After this happens, the reliability of development of new oral structures, particularly of the interposed ones, is reduced. Contractile vacuole pores, typically present within both arcs of homopolar doublets, tend to disappear from the narrower arcs. This anomalous partial triplet condition appears to be a transient intermediate stage in the reversion of homopolar doublets to normal singlets. We interpret the interposition of a transient third oral system in doublets that are regulating toward the singlet state as being a consequence of reverse intercalation of new positional values subsequent to excessive crowding of the preexisting positional values. This interpretation is an adaptation of the shortest-distance intercalation rule of the polar coordinate model applied in an intracellular and morphallactic context.

RNA and protein synthesis during meiotic prophase in Tetrahymena thermophila

Tetrahymena is one of the few organisms from which large amounts of precisely staged meiotic material can be obtained. We took advantage of this fact to monitor RNA and protein synthesis during meiosis. The rate of total protein synthesis as well as the synthesis of the majority of heavily labeled conjugation-specific polypeptides (monitored by high resolution two-dimensional gel electrophoresis) was maximal during meiotic prophase. We therefore cloned cDNAs corresponding to genes active during this time. The mRNA levels of three conjugation-specific genes (pC1, pC2, and pC7) and one conjugation-induced gene (pC3) were followed by using the corresponding labeled cDNAs to probe RNA isolated from different times during mating that was also followed cytologically. Synthesis of the conjugation-specific mRNAs was maximal just prior to maximum crescent stage (pachytene). Evidence is presented for transcription by the normally inactive micronucleus just prior to the maximum crescent stage, confirming an earlier report. The significance of these results is discussed.

Presence of a tubulin pool in the resting cyst of the hypotrich ciliate, Histriculus muscorum

Although microtubular organelles have not been observed in the resting cyst of the ciliate, Histriculus muscorum, the cyst was immunocytochemically stained with anti-tubulin antiserum, and one of its polypeptide bands reacted to the same antiserum after the immunoblotting test. Both these findings demonstrate the presence of tubulin in the resting cyst. The reacted band appeared in the 100,000 g supernatant of the cyst but not in the pellet, suggesting a depolymerized state of the tubulin in the resting cyst.

Reproducible and variable genomic rearrangements occur in the developing somatic nucleus of the ciliate Tetrahymena thermophila

We analyzed the extent, reproducibility, and developmental control of genomic rearrangements in the somatic macronucleus of the ciliate Tetrahymena thermophila. To exclude differences caused by genetic polymorphisms, we constructed whole-genome homozygotes, and we compared the homozygous progeny derived from single macronuclear differentiation events. This strategy enabled us to identify a novel form of variable rearrangement and to confirm previous findings that rearranged sequences occur at a high frequency in the Tetrahymena genome. Rearrangements studied here were deletions of both unique and interchromosomally dispersed repetitive DNA sequences involving DNA rejoining of internal, nontelomeric regions of macronuclear DNAs. We showed that although rearrangements of some sequence classes are reproducible among independently developed macronuclei, other specific sequence classes are variably rearranged in macronuclear development. The variable somatic genomes so produced may be the source of phenotypically variant cell lines.

Analysis of a mutant expressing temperature-sensitive changes of cell size in Tetrahymena

A temperature-sensitive mutant of Tetrahymena expresses an increase in cell volume by a factor of 2.5 upon shift to restrictive temperature. Cellular amounts of protein, RNA, and DNA increase at roughly the same proportions. The mutant cell size is attained by cessation of divisions immediately after temperature shift for a period of time which is about equal to one generation time. During this time cell growth and DNA replication continue at virtually unchanged rates. Maintained at the restrictive temperature the mutant cells divide at the same rate as the wild-type cells. Upon return to the permissive temperature, cell size is reduced by the combined effects of an accelerated division rate together with a decelerated growth rate.

Effect of the antitubulin drug nocodazole on meiosis and postmeiotic development in Tetrahymena thermophila. Induction of achiasmatic meiosis

Nocodazole (ND), a potent antitubulin drug, can be used to dissect the steps of meiosis in Tetrahymena, presumably by interfering with the assembly of microtubules. Its effects depend upon the time during conjugation at which the drug is applied. When applied prior to the elongation of the micronucleus into the characteristic 'crescent' configuration, no crescent is formed and the chromosomes of prepachytene and pachytene condense into spherical nuclei. If ND is applied after micronuclear elongation has begun, but before it is fully elongated, the chromosomes fail to synapse and appear in metaphase I as unpaired monovalents. In contrast, the metaphase I chromosomes appear as bivalents when ND is applied later, during or after the crescent has reached its maximum elongation. Still later, application of ND inhibits chromosome movements during anaphase and telophase of either meiotic division, but does not prevent separation of kinetochores. In some of the blocked restitutive nuclei an additional round of chromosome replication occurs, corresponding to the third pregamic division in normal conjugation. The hyperploid micronuclei produced by such treatment may be useful in certain genetic manipulations and in studying the regulation of nuclear DNA content.

Deciliation interferes with cell-cycle progression in Tetrahymena

The impact of ciliary regeneration upon cell-cycle progression of the ciliate Tetrahymena was studied. It was found that cell division ceases during ciliary regeneration, and starts again about 4 h after deciliation. Deciliation of an asynchronously multiplying culture results in a rapid interruption of DNA synthesis, followed by resumption 1 h later. This was shown by pulse-labelling the cells with [3H]thymidine at various times after deciliation. Cytophotometric determinations of the macronuclear DNA content substantiated these observations, since the average DNA content per cell remained constant within the first hour of regeneration, confirming the labelling experiments, after which it rose. At its maximum, the average DNA content was more than doubled as compared with the beginning of the experiment. This indicates that a substantial proportion of the regenerating cells performed two rounds of DNA replication prior to cell division. The massive drop in the average DNA content during the fifth hour after deciliation indicates that the culture becomes partly synchronized for cell division by the deciliation procedure. The division synchrony results from a greater delay of the next cell division when G2 cells are deciliated than occurs in G1 cells. This was shown by deciliating cultures of Tetrahymena thermophila cells in the respective stages of the cell cycle, which had been partly synchronized by elutriator centrifugation. Thus, deciliation followed by ciliary regeneration causes a varying degree of retardation in progression through the cell cycle, being greatest for G2 cells and least for G1 cells.

Modulation of linker histones during development in Tetrahymena: selective elimination of linker histone during the differentiation of new macronuclei

Macronuclei of Tetrahymena thermophila contain a typical H1 which has been shown to be missing from micronuclei. Instead, micronuclei contain three unique polypeptides, alpha, beta, and gamma, which are associated with linker regions of micronuclear chromatin. In this report polyclonal antibodies raised against macronuclear H1 are shown to react with alpha, beta, and gamma by immunoblotting analyses. This result suggests that these polypeptides share some common structural feature(s). Also consistent with this result is the finding that both macro- and micronuclei in growing and mating cells stain positively with H1 antibodies by in situ indirect immunofluorescence. However, these analyses demonstrate that the level of linker histone is greatly reduced in the micronucleus of starved cells and in young macronuclear anlagen. These results are in agreement with earlier biochemical studies and together provide strong evidence that dramatic changes in linker histone accompany nuclear differentiation (and dedifferentiation) in Tetrahymena.

New wild Tetrahymena from Southeast Asia, China, and North America, including T. malaccensis, T. asiatica, T. nanneyi, T. caudata, and T. silvana n. spp

Tetrahymena of the T. pyriformis complex collected from varied habitats in Malaysia, Thailand, and The People's Republic of China include strains of the micronucleate species T. americanis and T. canadensis and the amicronucleate T. pyriformis and T. elliotti. Two new breeding species are described-T. malaccensis from Malaysia and T. asiatica from China and Thailand. Two wild selfers from China and some of the amicronucleate strains from all three countries fall into isozymic groups similar to named micronucleate and amicronucleate species. The T. patula complex is represented by two groups of clones from Malaysia that fit the morphological description of T. vorax. They, however, have radically different isozymic electrophoretic patterns and both groups differ from those of previously described T. vorax. As their molecules indicate relationships to other "T. vorax" strains as distant as that between T. vorax and T. leucophrys, they are considered to be new species, T. caudata and T. silvana. A third new breeding species, T. nanneyi, was identified among strains previously collected in North America. Viable immature progeny were obtained from the new strains of the five breeding species. Maximum temperature tolerances were determined for the new strains of four of the breeding species.

How the mirror-image pattern specified by a janus mutation of Tetrahymena thermophila comes to expression

The initial changes of cell-surface organization that occurred as the recessive janA1 (janus) mutation of Tetrahymena thermophila first became expressed were elucidated in a special mating scheme in which old macronuclei homozygous for janA+ were synchronously replaced by new macronuclei homozygous for janA1. During this period of onset of expression, the number, regularity, and asymmetry of the ciliary rows remained unchanged. New normal (primary) oral apparatuses (OAs) continued to be formed posterior to old OAs, as in normal cells. At about four fissions after conjugation, abnormal (secondary) OAs with a partial reversal of asymmetry began to appear nearly opposite to the primary OAs, close to but not at the eventual circumferential position of janA1 secondary OAs. The array of contractile vacuole pores (CVPs), normally located adjacent to two ciliary rows centered near 22% of the cell circumference to the right of the primary oral meridian, underwent a two-step transformation: first, the number of adjacent ciliary rows bearing CVPs increased to 3, 4, and sometimes 5, then "skipped" rows appeared within this broadened CVP-arc to split the single set of CVPs into two separated subsets. The CVP transformations occurred gradually and progressively. They began prior to the expression of secondary OAs but accelerated as secondary OAs appeared. As the CVP arc became broader, its midpoint shifted somewhat to the right, away from the primary oral meridian, but ended up close to halfway between the primary and secondary oral meridians. The data provide a better fit to an intercalation model than to an alternative double-gradient model, suggesting that the janA1 mutation alters the large-scale organization of positional values by preventing the expression of a subset of these values and thus provoking reverse-intercalation of the remainder.

Utilization of iron complexes in an animal cell

The ciliate protozoan Tetrahymena thermophila was grown in synthetic nutrient medium in the absence of the iron chelator citrate. Utilization and toxicity of various iron compounds or complexes in iron-starved cells were assessed from the number of cell doublings obtained within a standard time. The compounds tested included complexes formed between ortho-phosphates and two forms of ferric hydroxides, native and cationized ferritin, and tris-acetylacetonato Fe(III). The ferric hydroxo ortho-phosphate particles are toxic and can be removed from the medium by Millipore filtration. Uptake of ferritin and tris-acetylacetonato-Fe(III) is independent of food vacuole formation and seems to occur by micropinocytosis and by plasma membrane translocation, respectively.

Adolescence in Tetrahymena thermophila

The development of sexual maturity in Tetrahymena thermophila has been shown to include an intermediate stage, adolescence, during which cells are capable of mating with mature cells but not other adolescent cells. When the progeny of successfully mated cells are grown logarithmically and tested frequently for the ability to mate, they are unable to form mating pairs for about 65 generations. This period is known as immaturity. During the next stage, the progeny pair with mature cells but not with other adolescent cells despite the presence of complementary mating types. Adolescence persists for 20-25 generations before the cells attain maturity, which is defined as the ability to mate with any cell of different mating type. Once paired with mature cells, adolescents successfully complete conjugation. Cytological preparations show that both members of the pair undergo meiosis and form macronuclear anlagen. The proteins synthesized during a mating between adolescents and mature cells are similar to those synthesized during a mating between mature cells as determined by two-dimensional gel analysis. Both the adolescent cell and the mature partner contribute genetic markers to the progeny.

Different polypeptides in two homologous cellular structures: the microstomal and macrostomal oral apparatus of Tetrahymena vorax

By two-dimensional electrophoresis it is demonstrated that the macrostomal oral apparatus of Tetrahymena vorax contains about 55 unique polypeptides in addition to a set of about 145 polypeptides also found in the microstomal oral apparatus.

Stage-specific changes in protein synthesis during conjugation in Tetrahymena thermophila

Conjugation in the free-living ciliate Tetrahymena thermophila is an inducible developmental system which results in a synchronized reorganization of the genetic material in both mates of a pair. The cytological events were followed by Feulgen stainings of simultaneously mating cells and protein synthesis was revealed using [35S]methionine pulse labelling and two-dimensional gel electrophoresis. At least 33 proteins, including 24 conjugation-specific proteins, with apparent molecular weights (Mr) between 61 and 200 X 10(3) are stimulated during conjugation. Two slightly acidic proteins (Mr 89 and 73 X 10(3), respectively) are stimulated shortly after mixing of mating-competent cells and mainly before tight pairs are formed. Ten proteins are stimulated during meiosis, and two of these (Mr 90 and 78 X 10(3), respectively) are particularly interesting, since they are highly stimulated and more basic (pI values around 8.5) than most other proteins detected. Twelve proteins are stimulated essentially between pairing and early macronuclear development, three are stimulated from shortly before zygote formation and during the post-zygotic divisions, and six are stimulated during late conjugation, at various parts of macronuclear development. The functions of the conjugation-stimulated proteins are discussed.

Influence of membrane fluidity changes upon the imprinting of polypeptide hormones in Tetrahymena

Hormonal imprinting is a physiological phenomenon, in which after the first encounter the receptorial and functional responses of a cell change for future occasions. The present experiments demonstrate (using Tetrahymena as a model cell) that the imprinting is very sensitive to the changes in membrane physical state. Cultivation of Tetrahymena cells in 28 or 15 degrees C or in ergosterol-supplemented media caused only quantitative differences in the imprinting; however, the process of cooling (shift-down) or reheating (shift-up) resulted in a false reaction. The combined treatment by ergosterol and cooling completely abolished the imprinting. These results indicate that hormonal imprinting is a membrane-dependent process.

Motile detergent-extracted cells of Tetrahymena and Chlamydomonas

Tetrahymena and Chlamydomonas cells treated with high (0.25-0.5%) concentrations of the detergent Nonidet P-40 in appropriate buffers retain the shape of the intact cells but are devoid of any ciliary activity unless supplied with MgATP. ATP causes them to swim actively, with beat parameters and swimming patterns indistinguishable from those of intact cells. Both types of detergent-extracted cells are completely devoid of ciliary membranes. The Tetrahymena preparations also lack all cellular membranes, whereas cellular membranes remain intact in the Chlamydomonas preparations. Experiments demonstrating the effects of ATP, ADP, vanadate, erythro-9-[3-2-(hydroxynonyl)]-adenine, and Ca++ are described to illustrate the use of these detergent-extracted cells in research on ciliary motility.

Lectins in the unicellular Tetrahymena. II. Impact of nutrition and sugar treatment on anti-lectin binding

Tetrahymena pyriformis GL cells showed partly intracytoplasmic, partly intramembraneous accumulation of lectin-like proteins in conditions of starvation, as demonstrated cytochemically by reaction with antibodies to pea, lens, bean, Datura, and snail lectin. The lectins binding to simple sugars tended to accumulate in the membrane, whereas those capable of interacting with hexosamines in the cytoplasm. While the fluorescence pattern of lectin localization was generally homogeneous in normally nourished cells, it assumed a variegated appearance in starved cells, owing to patching of the membrane, and spot-like accumulation of lectins in the cytoplasm, presumably within membranes of endocytosed vesicles. Snail lectin was an exception, since its distribution remained homogeneous also in conditions of starvation.

A population-kinetical approach to RNA formation and degradation in growing and in resting cells

Labelled RNA was extracted from growing and stationary cultures of the ciliate Tetrahymena and was separated chromatographically into poly(A)- and no poly(A)-containing fractions. A new method was used to derive from the data (cpm/A260, and tD, doubling time of RNA) absolute values of three growth terms which fully describe the population kinetics of RNA molecules: the rates of transcription, decay, and net growth. At all times the messenger RNA (mRNA) content of Tetrahymena was the result of a self-regulating equilibrium between synthesis and decay. The rates of transcription and of degradation of mRNA and ribosomal RNA (rRNA) were found to be controlled independently, but decay was dominant in establishing the growth-specific quantities per cell. In the stationary phase about 94% of all poly(A)-RNA molecules and about 50% of all mRNA molecules were kinetically silent. The remaining portions were transcribed with high rates, but also degraded immediately. During the culture growth cycle the rate of rRNA net growth responded positively to the cellular rRNA content suggesting an autocatalytic effect of rRNA on the rate of its accumulation.

The partitioning of cytoplasmic organelles at cell division

When an organism has only one or two mitochondria or chloroplasts per cell, it is probable that their partitioning is always stringently controlled so that each daughter cell always receives half the organelles in the parent cell. When there are more copies of an organelle, the available data suggest that partitioning is stochastic but far from random, with a strong tendency toward equality. The molecular mechanisms that promote equal partitioning are not known in any case, but the great variety of organelle behavior suggests that many different mechanisms are involved in different organisms. As Wilson (1925) pointed out, the precision of partitioning of cytoplasmic organelles rarely if ever equals that of mitosis, but it is still an expression of selection for mechanisms that will ensure the hereditary continuity of the organelles. How cells compensate for unequal partitioning by controlling organelle replication is known for only one case. But when one considers that Tetrahymena and Paramecium use different methods to compensate for unequal partitioning of macronuclear DNA, it would not be surprising if organisms use a variety of different compensating replication modes for organelles as well. What is surprising is that so little attention has been paid to these problems. Nothing could be simpler than counting organelles in dividing cells, but this has been done on a large scale in only two systems. Quantitative techniques in cell biology have been developed to the point where such studies could be done even on cells that have too many organelles for direct counting. Molecular mechanisms of partitioning have scarcely been touched on. Much more has been done on the role of the cytoskeleton in determining cell shape, and some observations have been made on its role in positioning organelles in interphase cells, but these kinds of studies have not been extended to dividing cells. Some experiments and observations have been made on the role of microtubules and microfilaments in moving cytoplasmic organelles around the cell during interphase, but again nothing has been done on their possible role in partitioning organelles at cytokinesis. The major lesson of this article is how little has been done, and how much can be done. The partitioning of cytoplasmic organelles at cell division is a wide-open field for future research, and one of great importance for both genetics and cell biology.