INTRODUCTION

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Emiliania huxleyi is a unicellular alga that is distinguished by its exquisitely sculptured calcium carbonate cell coverings known as coccoliths (Fig. 1). E. huxleyi is found throughout the world's oceans and forms extensive blooms sometimes greater than 100,000 km², with cell densities up to 10,000 cells ml¹ (5, 18). It is also considered to be the world's major producer of calcite (35). Because of its relative abundance, widespread distribution, and ability to fix carbon into both organic and biomineralized products, E. huxleyi has attracted the attention of research scientists interested in global carbon cycling (10, 18, 31). E. huxleyi has also been targeted by materials scientists who are interested in the biomineralized skeletons for applications relating to materials chemistry. Such porous shells of calcium carbonate have been targeted by materials scientists as having potential significance as lightweight ceramics, catalyst supports, and robust membranes for high-temperature separation technology (34). Biomedical applications include the use of these biomineralized materials for construction of artificial bone in humans (8, 30, 32), scaffolding supports in tissue engineering (2, 7), complement activation enhancement (29), artificial dental root construction (6, 26), and biomedical implants (34). While a general understanding of some of the ecophysiological aspects of calcification and coccolithogenesis in E. huxleyi has been obtained, little information on the life cycle of this organism is available.

View larger version (90K): [in this window] [in a new window]   FIG. 1.   Scanning electron micrographs of E. huxleyi strain 1516 life cycle types. (A) Nonmotile C cell showing overlapping coccolith plates. (B) Motile S cells representing a possible gametic stage of the life cycle. Note the relative difference in the sizes of these two cell types involved in phase variation mechanisms described in the text. Magnifications, ca. ×8,000 (A) and ×10,500 (B).

The life cycle of E. huxleyi is complex and involves several different cell types including coccolith-bearing cells (coccolithophores; C cells), nonmotile naked N cells, and motile, scale-bearing swarm cells (S cells), each of which can exist independently and reproduce vegetatively (15, 19) (Fig. 1). In liquid culture, N and S cells frequently arise from C cells. The interrelationships between these different cell types and the mechanisms that govern these phase variation events, however, have not been defined. Flow cytometry data indicate that the DNA complement of the motile S cells is half that of the C cells (15, 24). This suggests that the S- and C-cell types are haploid and diploid with respect to one another and that the S cells may represent a gametic stage. Billiard (4) and Green et al. (15) contend that the C cell and the S cell act as alternate phases of a life cycle involving meiosis and syngamy. Whether E. huxleyi is a monoecious or dioecious alga, however, is not known. While it seems likely that the life cycle of E. huxleyi involves a sexual stage, meiotic division leading to the formation of S cells acting as gametes has never been documented, nor has the actual fusion of the S cells in sexual reproduction. Prior to this study C cells and S cells have only been observed in liquid culture, and the physiological and molecular signals controlling interconversion of these cell types remain unknown (15). To understand the life cycle of E. huxleyi, the environmental and physiological conditions that trigger E. huxleyi C cells to exit the mitotic cycle and initiate sexual reproduction must be defined.

In this report we describe conditions for induction of phase switching from the diploid coccolithophore cell (C-cell) to the haploid swarm cell (S-cell) life cycle stages of marine alga E. huxleyi. We also describe a mechanism for induction of the reverse change, from S cell back to C cell. To our knowledge, this is the first report demonstrating plating of E. huxlyei on solid media, a laboratory condition which we have found induces differentiation of the diploid life cycle stage to the haploid gametic stage. The ability to manipulate the life cycle of E. huxleyi in the controlled laboratory environment, as demonstrated herein, represents a powerful tool for identifying the mechanisms underlying the phase transition from vegetative growth to sexual reproduction in E. huxleyi. In addition, these data will aid in the development of genetic tools for investigating the molecular mechanisms governing the processes of calcium carbonate biomineralization and coccolithogenesis in this organism.

	MATERIALS AND METHODS

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Media and growth conditions. E. huxleyi strain 1516 was obtained from the Provasoli-Guillard National Center for Culture of Marine Phytoplankton. Stock cultures were maintained by inoculating cells into 75 ml of F/50 or F/2 medium (17) in 250-ml flasks. Cultures were incubated photoautotrophically at 17 to 18°C under cool white fluorescent light (660 µmol · m² · s¹) and under either a continuous-light or a discontinuous-light (12-h dark, 12-h light) cycle. Previous reports had shown that coccolith production in E. huxleyi was enhanced in cells grown on F/50 versus F/2 media. Consequently, most experiments described in this study utilized F/50 as the growth medium, unless noted otherwise. Growth on plates was obtained in F/50 media supplemented with 1.5% Agar Select (Sigma Co., St. Louis, Mo.). Other agar sources employed in the plating media (e.g., Difco agar and agarose) inhibited or prevented growth of strain 1516.

PCR amplification of the RubisCO large-subunit and 16S rRNA genes. Amplification the ribulose-1,5-bisphosphate carboxylase/oxygenase (RubisCO) large-subunit gene from E. huxleyi (14) was obtained with the following primers: 5'-ACTGCTACATGGACTGTAGTA-3' and 5'-TAGATCTAATGCAGTTTGAAG-3'. Single-colony isolates were picked from agar plates and resuspended in 15 µl of Tris-EDTA buffer; 5 µl of the resuspended cells was then used in a standard PCR with a 10-min hot start at 95°C and a 52°C annealing temperature. A similar strategy was employed for amplification of the 16S nuclear ribosomal DNA gene from E. huxleyi (3) using the following E. huxleyi-specific primers: 5'-AGTCATATGCTTGTCTCA-3' and 5'-GATAAGGTTCGGACAGCTT-3'.

Induction of phase switching from diploid to haploid stages. Single colonies of strain 1516 consisting exclusively of S cells were obtained by plating dilutions of late-log- to early-stationary-phase cultures (ca. 6 × 10⁵ to 8 × 10⁵ C cells·ml¹) on F/50 medium plates and incubating them for 48 h at 18°C on a 12-h light, 12-h dark cycle. For experiments where a lawn of S cells was desired, C-cell cultures at densities of 10⁵ cells/ml or greater were plated and incubation was extended to 4 or 5 days to ensure complete transition to the S-cell stage. Phase transition to the S-cell stage was confirmed by phase-contrast microscopy of cells resuspended from the plates. Data on the rate of conversion of C to S cell was obtained by resuspending cells from plates at specific time intervals and counting the C cells present and comparing this number to the original number plated. Duplicate plates were counted for each time point, and the average C-cell number was recorded. The rate of decrease in C-cell number per hour was determined from four independent experiments, and the average rate of C-cell conversion to S cells was recorded as the percent decrease in C-cell number per hour.

Induction of phase switching from haploid stage to diploid stage. To regenerate the diploid C-cell stage from S cells, the latter were collected from a single plate with ca. 2 ml of F/50 medium, pelleted gently (3 min at 1,500 × g), and then resuspended in a final volume of 100 to 250 µl of F/50 medium. This concentration step was essential for successful S cell-to-C cell phase transition, suggesting that there may be an attrition rate when resuspending S cells from an agar surface and/or that only a small subset of E. huxleyi cells may be capable of gametogenesis. The resuspended cells were then inoculated into 24-well microtiter plates containing 2.5 ml of the same medium. Phase transition from the S- to the C-cell stage was monitored by phase-contrast or Nomarski optics microscopy.

1

Flow cytometry. E. huxleyi strain 1516 cells from mid-log- and late-stationary-phase liquid-grown cultures (10 ml, representing a minimum of 1 × 10⁶ to 3 × 10⁶ C cells) were pelleted by centrifugation at 1,600 × g for 15 min at 4°C and washed once with sterile phosphate-buffered saline (PBS; 4.3 mM Na₂HPO₄ · 7H₂O, 1.4 mM KH₂PO₄, 2.7 mM KCl, 137 mM NaCl [pH 7.3]). Cells were fixed by resuspending them in 90% methanol (MeOH) and passed through a 251/2-gauge syringe several times to reduce clumping. Cells were stored in MeOH at 20°C for a minimum of 24 h prior to staining. Large-scale preparation of S-cell cultures was performed by spreading 2 ml of mid-log-phase cells (ca. 1 × 10⁶ to 2 × 10⁶ C cells) onto F/50 agar plates (Nunc; Bio-Assay dish; 245 by 245 by 25 mm) and incubating the plates for 4 to 5 days as described above. Cells were resuspended from plates in 20 ml of F/50 medium and prepared for staining as described for liquid-grown cells. To ensure complete dispersal of the resuspended cells from agar surfaces, S cells were passed several times through a 20-gauge syringe, followed by several passages through a 251/2-gauge syringe. Following fixation, the cell samples were harvested and washed in 1 ml of PBS by centrifugation for 30 s at 10,000 × g. Cells were stained in 1 ml of PBS buffer containing propidium iodide (10 or 50 µg · ml¹; Sigma Co.) and RNase A (100 µg · ml¹; Sigma Co.) for 18 to 24 h in the dark at 4°C. Relative DNA contents of C cells and S cells were analyzed with a Becton Dickinson FACSCaliber flow cytometer.

	RESULTS

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Growth of E. huxleyi strain 1516 in continuous light versus a light-dark incubation cycle. The light-scattering effects of the CaCO₃ coccoliths produced by coccolithophores (C cells) prohibit the use of spectrophotometric methods to monitor growth of strain 1516 C cells. Therefore growth was monitored by employing the direct-cell-count method. Figure 2 shows a typical growth curve for E. huxleyi strain 1516 C cells grown in F/50 media under a continuous-light versus a light-dark incubation cycle. Strain 1516 had a generation time of ca. 24 h when incubated under either a 12-h light, 12-h dark cycle or under continuous light. The proportion of swarm cells (S cells) to C cells increased throughout stationary phase (data not shown), supporting previously described microscopic observations suggesting that the production of S cells from C cells was most pronounced during stationary-phase growth (19). The average diameter of the C-cell population increased during stationary phase compared to that during log-phase growth (average cell diameters: log phase, ~4 to 6 µm; stationary phase, ~7 to 10 µm). This was presumably due to the continued accumulation of CaCO₃ coccolith material in batch cultures of strain 1516 when grown on F/50 media (low levels of phosphate and nitrate) as previously described (21).

View larger version (22K): [in this window] [in a new window]   FIG. 2.   Growth of E. huxleyi 1516 C cells in medium F/50 under continuous light () or a 12-h light, 12-h dark incubation cycle (). Each culture was incubated at 17 to 18°C, and the minimum generation times were ca. 24 h under both conditions.

Growth of E. huxleyi strain 1516 on solid media. E. huxleyi strain 1516 was grown photosynthetically in liquid batch cultures to late log or early stationary phase. Figure 3 shows the results of a typical plating experiment in which serial dilutions of C-cell batch cultures (ca. 2 × 10⁶ cells·ml¹) were spread onto F/50 plates and incubated under photosynthetic conditions (continuous light, or 12-h light, 12-h dark cycle) for 4 to 5 days. Duplicate plates of each dilution were incubated in the dark as controls; however, no growth was observed on any of the plates under these conditions. Photosynthetically incubated plates showed pinpoint colonies present within 24 to 48 h of incubation, with maximum plate growth obtained after 4 to 5 days (Fig. 3). Calculation of plating efficiency utilizing viable-cell counts was not possible due to a phase transition phenomenon induced upon plating E. huxleyi on solid media. Diploid C cells appeared to differentiate into numerous S cells within 48 h after plating. Two or three distinct colony morphologies were observed on the plates, ranging from very small (<1-mm-diameter) to larger (>5-mm-diameter) colonies (Fig. 3). The color of the colonies ranged from clear to colorless, creamy to opaque, and green to yellow. Pigmented colonies appeared only after extended incubation on agar plates (>2 weeks).

View larger version (142K): [in this window] [in a new window]   FIG. 3.   Colonies of E. huxleyi cells on agar plates. Late-log-phase cells (ca. 2 × 106 C cells/ml) were diluted to 104, and 0.1 ml was plated on an F/50 medium plate and incubated photosynthetically for 72 h. Note the large number of colonies actually present (ca. 1,000) compared to the number expected (ca. 20) based on the original number of C cells plated, indicating production of multiple S cells from a given C cell during phase transition.

View larger version (96K): [in this window] [in a new window]   FIG. 4.   PCR amplification of genomic DNA from E. huxleyi strain 1516 with primers specific for the E. huxleyi RubisCO large-subunit gene. DNA extracted from single-colony isolates on F/50 plates (lanes 2 and 3) and from liquid-grown cells (lanes 4 and 5) produced the same 1.2-kb fragment. Subsequent sequencing of these PCR products confirmed the presence of the RubisCO large-subunit gene of E. huxleyi. Lane 1, 23-kb ladder.

Induction of the C cell-to-S cell phase transition on agar plating media. To further investigate the apparent phase transition of C cells to S cells on agar media, we monitored the fate of plated C cells at various times by Nomarski optics microscopy as well as by direct cell counts. Figure 5 shows the sequence of events from a typical experiment following plating of liquid-grown cultures onto solid media. At time zero, a large population of mid-log-phase C cells was spread onto the surface of an F/50 plate, and a sample taken prior to incubation in the light consisted of predominantly C cells (Fig. 5A). Direct microscopic counts showed a steady decrease in the number of C cells present starting at approximately 6 h after incubation on plates. At 12 h, increasing numbers of S cells, along with ruptured C cells, could be observed (Fig. 5A) and direct counts showed nearly an 80% decrease in the C-cell population (Fig. 5B). By 48 h, 98% of the original C-cell population had differentiated to S cells (Fig. 5A and B). The average rate of C cell-to-S cell phase transition ranged between 2 to 3% per h when late-log- to early-stationary-phase C cells were plated. When C cells at the same concentration were heat treated (10 min at 55°C) prior to plating, phase transition to S cells did not occur, indicating that viable C cells were required for this phase transition to the haploid S-cell stage observed on agar plates (data not shown).

View larger version (47K): [in this window] [in a new window]   FIG. 5.   (A) Nomarski photomicrographs of E. huxleyi strain 1516 C cell-to-S cell phase transition over a 48-h period following plating on F/50 media. Magnifications: 0 h, ×564; 12 h, ×677; 24 h, ×752; 48 h, ×677. (B) Rate of decrease in the numbers of C cells present on agar plates during the experiment shown in panel A. The results from four independent experiments were obtained as described in Materials and Methods and showed an average rate of C cell-to-S cell phase transition of 2 to 3% per h on F/50 plates.

Determination of relative DNA contents of C cells and S cells by flow cytometry. To determine the relative DNA contents of strain 1516 C-cell and S-cell types employed in this study, cells were analyzed by fluorescence flow cytometry. Flow cytometry of log-phase cultures, consisting of C cells, showed a major peak at approximately channel 80 (coefficient of variation [CV], ~9%) and a smaller peak at ca. channel 160, corresponding to diploid C cells in the G₀-plus-G₁ and M-plus-G₂ phases of the cell cycle, respectively (Fig. 6A). A late-stationary-phase culture containing a large proportion of S cells relative to C cells yielded a large peak at approximately channels 40 to 45 (CV, ~9.5%), representing the haploid S-cell population, and a smaller diploid cell peak at channel 80 (CV, ~10%) (Fig. 6B). Histogram analyses of flow cytometry samples of single-cell eukaryotes routinely exhibit statistical CVs of 9 to 12%, as reported here. These data confirmed that S cells of E. huxleyi strain 1516 contain one-half the DNA content of C cells, supporting the data by Green et al. (15) obtained from several geographical isolates of E. huxleyi strains grown in liquid culture.

View larger version (21K): [in this window] [in a new window]   FIG. 6.   Flow-cytometric analysis of cultures from E. huxleyi strain 1516. Samples were analyzed after fixation in 90% methanol and staining with 50 µg of propidium iodide ml1. Histograms represent data from the following cultures: log phase, consisting almost exclusively of diploid C cells (A), late stationary phase, containing a large haploid S-cell population and smaller numbers of C cells (B), and pure culture of S cells from agar plates (C). See Results for details.

Regeneration of coccolithophore cell stage from the swarm cell stage. Figure 7 shows the results of a typical experiment depicting the sequence of events occurring during phase transition from the haploid S-cell stage to the diploid C-cell stage. Following initial inoculation of S cells into liquid media from agar plate cultures, single motile S cells were observed over the first 24 h (Fig. 7, D1). By days 2 and 3, S cells began to aggregate into "packs," and these packs continued to increase in size through days 5 to 8. Highly motile S cells were observed at the periphery of the packs and appeared to lose motility as the packs increased in size. While these cell aggregates continued to increase in both size and number through days 7 to 10, several large C cells were visible within, or associated with, most S-cell aggregations by days 5 to 8 (Fig. 7, D8). By days 8 to 11, C cells could be observed in almost every S-cell pack. After 14 days the cultures consisted of predominantly C cells and most of the remaining S cells had disappeared from the media by that time (Fig. 7, D14). The fate of these S cells, which apparently do not contribute to C-cell formation, is currently unknown.

View larger version (47K): [in this window] [in a new window]   FIG. 7.   Nomarski photomicrographs of E. huxleyi strain 1516 during phase transition from the S-cell to the C-cell stage. Note the "packing behavior" of S-cells beginning by about days 2 to 3, resulting in the formation of extremely large aggregations, and the eventual appearance of C cells within and around the S-cell packs by about day 9. Magnifications: D1, ×800; D3, ×320; D8, ×600; D14, ×600.

	DISCUSSION

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The lack of detailed information on the life cycle of E. huxleyi has been due primarily to the inability to identify the conditions causing phase variation between the diploid C-cell and haploid S-cell stages. Previous attempts to identify specific mating types of E. huxleyi S cells had focused on gross morphological characteristics, such as scale morphology (4) or flagellum length (15). However, the relative ploidy levels of S cells versus C cells as determined by flow cytometry (15, 16, 24) did not support these morphological criteria. Consequently, we have undertaken a microbiological and molecular approach to address questions relating to phase variation events in the life cycle of E. huxleyi. The goal of our research is to elucidate details of the life cycle of this organism for the development of genetic approaches directed to understanding the processes of biomineralization and coccolithogenesis in E. huxleyi.

Our preliminary studies of the C cell-to-S cell phase variation in E. huxleyi suggested that C cells could be induced to differentiate into S cells upon plating on agar media. However, before undertaking further studies on the life cycle of E. huxleyi, it was necessary to unequivocally determine that the colonies appearing on the F/50 plates consisted of E. huxleyi cells. The evidence presented herein arguing against bacterial contamination as the source of this growth, along with PCR amplification of the E. huxleyi RubisCO (rbcL) and 16S rRNA genes from single colonies, indicated that phase switching from the C-cell stage to the S-cell stage is induced by plating E. huxleyi cells on solid media.

We have determined that an exponentially growing population of C cells will differentiate into S cells very quickly following plating on solid media (rate, ca. 2 to 3% decrease in C cells per h). Analogous types of phase variation responses have been observed in studies of chemotaxis and phototaxis signal transduction in a variety of bacterial species. For example, the photosynthetic nonsulfur purple bacterium Rhodospirillum centenum produces motile cells with a single polar flagellum in liquid media (12, 27, 28), whereas on solid media it produces peritrichously flagellated swarm cells. This differentiation event is dependent on the viscosity of the medium: increasing medium viscosity triggers the production of cells possessing numerous flagella. Swarm cell differentiation in Serratia liquefaciens also appears to be induced by exposure of cells to surfaces of a particular viscosity (20). This environmental signal is thought to be received by an as yet unidentified sensor, initiating a signal transduction cascade which has been demonstrated to proceed via motility master operon flhDC (20, 36). The production of S cells in E. huxleyi from C cells on solid media is particularly intriguing in that it also involves a phase switch from the diploid to the haploid life cycle stage. Flow cytometry data from this study have confirmed that the relative ploidy level of E. huxleyi strain 1516 S cells is indeed half that of C cells. Previous studies of life cycle dynamics of E. huxleyi have inferred relationships between C cells and S cells exclusively from microscopy of "mixed" cultures. Our flow cytometry data of pure cultures of S cells (plated cells), taken together with PCR amplification of the E. huxleyi rbcL and 16S rRNA genes from single colonies and time course Nomarski optics microscopy, have clearly demonstrated diploid-to-haploid phase transition in a marine coccolithophorid for the first time.

The global distribution of E. huxleyi suggests that it must possess the ability to sense environmental changes, including changes in local fluid motion and medium viscosity. Recently studies with transgenic diatom cells have uncovered sensing systems for detecting and responding to osmotic stress, fluid motion, and iron (11). Perhaps there are similarities in the environmental signals and cognate sensor systems affecting cell motility in bacteria and those involved in inducing the E. huxleyi diploid-to-haploid phase transition, resulting in the generation of a motile life cycle stage. The ability to induce this life cycle phase switch in E. huxleyi allows us to investigate the signal transduction mechanisms involved in this process, and we are currently conducting studies to test these hypotheses.

We have not been able to determine, to this point, how many S cells arise from a single C cell. In diatoms and many other unicellular algae, gametes are produced from meiotic nuclear division, followed by multiple mitotic divisions to produce from 8 to over 128 microgametes from a single diploid cell (1, 9). Our preliminary microscopic observations suggest that the number of haploid S cells formed per diploid C cell in E. huxleyi may also be large. This hypothesis was also supported by plating results showing that the "actual" number of colonies observed on agar plates was consistently orders of magnitude higher than the "expected" number based on the original number of C cells plated. However, due to the extremely small size of S cells and their tendency to aggregate when resuspended from an agar surface, we have been unable to obtain accurate counts under the experimental conditions employed, including attempts to quantitate cell number using Coulter counter technology. We are currently evaluating other methodologies (e.g., fluorescence flow cytometry) to establish a quantitative relationship between C-cell and S-cell numbers.

To initiate efforts at unraveling the molecular events, or signal transduction mechanism(s), involved in phase variation in the life cycle of E. huxleyi, we set up experiments to regenerate the diploid C-cell stage from haploid S cells. When S cells were inoculated from plates into liquid media, the sequence of events leading to the formation of C cells followed a predictable pattern, proceeding from single motile S cells, through the formation of large aggregations of S cells, and finally resulting in cultures consisting almost exclusively of C cells (11 to 14 days of incubation). Of particular note regarding this phase transition is the fate of the large numbers of S cells that apparently do not contribute to zygote formation. Although large packs of these S cells can be observed up through ca. days 5 to 9, these cells are barely detectable after about day 11 or 12. A similar situation has been described in studies of gametogenesis in the unicellular marine diatom Thalassiosira weissflogii Grun (1). In studies of this alga, cessation of a dark incubation period required for gamete formation resulted in the disappearance of the large numbers of remaining gametes in the culture over about a 50-h time period. The authors hypothesized that the cells may have died and "disintegrated" over time following removal of the induction signal, and thus the fate of these cells in this well-characterized marine diatom remains unresolved. Nonetheless, there is precedent for this phenomenon, which we observed in this study with E. huxleyi. Considering the lack of any published data on gametogenesis and sexual fusion in E. huxleyi, the fate of these S cells must await future investigation.

The comparatively low number of diploid C cells generated from within groups of hundreds of S cells suggests that not all S cells may be capable of acting as gametes. This situation is not uncommon among unicellular eukaryotes, where sexual reproduction involves genes responsible for both determination of mating type and mate recognition to ensure fusion of specific mating types (13, 22). In diatoms, the percentage of cells induced to undergo spermatogenesis was shown to be dependent on three factors: (i) an induction signal (e.g., shift from dim light or darkness) (1), (ii) a decrease in cell size to less than 30 to 40% of its maximum (9), and (iii) the stage of the cell cycle (1). Apparently, once a diatom cell proceeds through an inducible region of G₁ in dim light or darkness, completion of spermatogenesis then requires the possession of a particular genetic constitution. The situation in yeasts is also complex. In these organisms (e.g., Saccharomyces cerevisiae), meiosis occurs only in cells that are heterozygous at the mating locus and an environmental signal involving nutrient limitation is also a prerequisite for sex cell formation (25). The life cycle of marine coccolithophorids is complex, and many factors may be involved in the control of phase variation between haploid and diploid life cycle stages and in mating cell development, gamete recognition, and sexual fusion. Some researchers have even hypothesized that a haploid S cell in the G₂ phase of the life cycle might give rise to a diploid C cell (15, 33). However, this hypothesis could not be experimentally addressed utilizing DNA flow cytometry and microscopy of liquid-grown E. huxleyi cultures as the research tools. Efforts are under way in our laboratory to employ our clonal S-cell isolates in phase transition experiments to determine whether E. huxleyi is a monoecious or dioecious alga. Our ability to manipulate the life cycle stages of this organism under laboratory-controlled conditions will be particularly useful for designing experimental approaches for addressing these types of questions.

These studies have established, for the first time, laboratory conditions for inducing phase switching between the haploid S-cell and diploid C-cell life cycle stages of marine coccolithophorid E. huxleyi. We have discovered that C cells can be induced to differentiate into S cells upon exposure of cells to a solid surface and that this life cycle stage may be maintained indefinitely under these conditions. We have also shown that the C-cell stage can be regenerated from the S-cell stage. To date, most information on the life cycle of E. huxleyi has only been phenomenologically demonstrated, and little is known about the ecology and environmental signals that induce phase switching in this marine alga. These data provide us with a potentially powerful tool for generating recessive mutations in E. huxlyei and for investigating the environmental factors and signal transduction mechanisms responsible for phase variation events in the life cycle of this ecologically and biomedically important marine alga.