VOLVOX POCOCKIAE,A NEW SPECIES WITH DWARF MALES1

Volvox pocockiae is described as the second species in the section Janetosphaera. The somatic protoplasts are connected by cytoplasmic strands approximately the same diameter as flagella, and the construction of the spheroid is identical to that of V. aureus. Asexual reproduction by the division of gonidia differs from that in V. aureus in the enlargement of the gonidium prior to its division to form the embryo. Sexual reproduction is very similar to that in V. spermatosphaera, a species in the section Merrillosphaera without cytoplasmic connections. Dwarf males are formed in the posterior end of the parental spheroid, and, as in V. spermatosphaera, the dwarf males are composed exclusively of androgonidia with no sterile somatic cells. Females are facultatively asexual spheroids, the gonidia of which function as eggs. The single biflagellate zoospore produced by the germinating zygote undergoes cleavage to form a germling spheroid. The differentiation of gonidia in the asexual embryo and in the germling spheroid is evident only after inversion and enlargement of the spheroid have begun.     

DESCRIPTION OF TWO NEW MONOECIOUS SPECIES OF VOLVOX SECT. VOLVOX (VOLVOCACEAE,CHLOROPHYCEAE), BASED ON COMPARATIVE MORPHOLOGY AND MOLECULAR PHYLOGENY OF CULTURED MATERIAL1

Species of Volvox sect. Volvox (Volvocaceae, Chlorophyceae) are unique because they have thick cytoplasmic bridges between somatic cells and spiny‐walled zygotes. This section is taxonomically important because the genus Volvox is polyphyletic. However, taxonomic studies of species in Volvox sect. Volvox have not been carried out on cultured material. Here, we performed a taxonomic study of monoecious species of Volvox sect. Volvox based on the comparative morphology and molecular phylogeny of chloroplast genes and the internal transcribed spacer (ITS) regions of nuclear rDNA using various strains originating from Japan and two preserved strains from the USA. The strains were clearly divided into four species, V. globator L., V. barberi W. Shaw, V. kirkiorum sp. nov., and V. ferrisii sp. nov., on the basis of differences in numbers of zygotes (eggs) in the sexual spheroids, form of zygote wall, and somatic cell shape. Sequences for ITS of nuclear rDNA resolved that the two new species have phylogenetic positions separated from V. globator, V. barberi, V. capensis F. Rich et Pocock, and V. rousseletii G. S. West UTEX 1862 within Volvox sect. Volvox.     

THE FLAGELLAR PHOTORESPONSE IN VOLVOX SPECIES (VOLVOCACEAE,CHLOROPHYCEAE)1

Steering their swimming direction toward the light is crucial for the viability of Volvox colonies, the larger members of the volvocine algae. While it is known that this phototactic steering is achieved by a difference in behavior of the flagella on the illuminated and shaded sides, conflicting reports suggest that this asymmetry arises either from a change in beating direction or a change in beating frequency. Here, we report direct observations of the flagellar behavior of various Volvox species with different phyletic origin in response to light intensity changes and thereby resolve this controversy: Volvox barberi W. Shaw from the section Volvox sensu Nozaki (2003) changes the direction of the flagellar beating plane, while species encompassed in the group Eudorina (Volvox carteri F. Stein, Volvox aureus Ehrenb., and Volvox tertius Art. Mey.) decrease the flagellar beating frequency, sometimes down to flagellar arrest.     

Do Protoplasmic Connections Function in the Phototactic Coordination of the Volvox Colony During Light Stimulation?*

SYNOPSIS. The flagellar behavior of the colonial flagellates Volvox carteri Stein and Volvox perglobator Powers was examined by placing 1.01 μm polystyrene particles in solution with swimming colonies, and photographing these particle movements. When directional light stimulation was administered to individual colonies, a cessation of flagellar activity occurred in the anterior cells of the stimulated side in both species. Since Volvox perglobator possesses prominent intercellular connections and Volvox carteri does not, the results of these experiments suggest that the connections linking colony members in some species do not function in the coordination of flagellar activity associated with light orientation behavior.     

BACTERIAL ENDOSYMBIONTS IN VOLVOX CARTERI (CHLOROP HYCEAE)1

The morphology of the bacterial endosymbiont of Volvox carteri Stein (Clone KA-1) was studied with the electron microscope. Endosymbionts were found in the cytoplasm of somatic cells, gonidia and sperm, but never in nuclei, chloroplasts or mitochondria. DNA preparations contained, an extra DNA species assumed to be endosymbiont DNA. Attempts to isolate the endosymbionts or to “cure” the alga with antibiotics were unsuccessful. All progeny from crosses of infected and noninfected strains contained the endosymbiont.     

The relationship between cell size and cell fate in Volvox carteri

In Volvox carteri development, visibly asymmetric cleavage divisions set apart large embryonic cells that will become asexual reproductive cells (gonidia) from smaller cells that will produce terminally differentiated somatic cells. Three mechanisms have been proposed to explain how asymmetric division leads to cell specification in Volvox: (a) by a direct effect of cell size (or a property derived from it) on cell specification, (b) by segregation of a cytoplasmic factor resembling germ plasm into large cells, and (c) by a combined effect of differences in cytoplasmic quality and cytoplasmic quantity. In this study a variety of V. carteri embryos with genetically and experimentally altered patterns of development were examined in an attempt to distinguish among these hypotheses. No evidence was found for regionally specialized cytoplasm that is essential for gonidial specification. In all cases studied, cells with a diameter > approximately 8 microns at the end of cleavage--no matter where or how these cells had been produced in the embryo--developed as gonidia. Instructive observations in this regard were obtained by three different experimental interventions. (a) When heat shock was used to interrupt cleavage prematurely, so that presumptive somatic cells were left much larger than they normally would be at the end of cleavage, most cells differentiated as gonidia. This result was obtained both with wild-type embryos that had already divided asymmetrically (and should have segregated any cytoplasmic determinants involved in cell specification) and with embryos of a mutant that normally produces only somatic cells. (b) When individual wild-type blastomeres were isolated at the 16-cell stage, both the anterior blastomeres that normally produce two gonidia each and the posterior blastomeres that normally produce no gonidia underwent modified cleavage patterns and each produced an average of one large cell that developed as a gonidium. (c) When large cells were created microsurgically in a region of the embryo that normally makes only somatic cells, these large cells became gonidia. These data argue strongly for a central role of cell size in germ/soma specification in Volvox carteri, but leave open the question of how differences in cell size are actually transduced into differences in gene expression.     

Characterization of the sex-inducer glycoprotein ofVolvox carteri f.weismannia

Summary Sexual inducer pheromones fromVolvox carten f.weismannia, strains 65–30(12) and 1B were purified and characterized as glycoproteins with apparent molecular weights of 27 kDa and 28.5 kDa, respectively. This subspecies yielded 20–40 times more pheromone based on weight per spheroid thanVolvox carteri f.nagariensis, but its specific activity (threshold dilution) is four to five orders of magnitude less (10^–12 to 10^–13 M). Gaschromatographic sugar analysis revealed quantitative differences in the composition of theO- andN-glucans compared with theV. carteri f.nagariensis inducer. TheV. carteri f.weismannia pheromones showed antigenic cross-reaction with an antiserum directed against chemically deglycosylated inducer fromV. carteri f.nagariensis. However, there is only unilateral biological cross-induction. TheV. carteri f.nagariensis inducer is strictly competent for its own gonidia only; the inducers fromV. carteri f.weismannia also cross-induceV. carteri f.nagariensis. This pattern of cross-induction suggests the existence of related pheromone receptors but with different ligand specificities.     

Ultrastructure of Volvox carteri

Summary Somatic cells of mature asexual colonies of Volvox carteri do not possess a true cell wall, but are otherwise similar in ultrastructure to Chlamydomonas. Somatic cells are embedded in multilayered fibrillar material of the colonial matrix. The reproductive cells (gonidia) of Volvox carteri lie internal to the somatic cell layer of the colony matrix in an apparently structureless portion of the colony matrix. Mature gonidia are large vacuolate cells with a central nucleus and parietal chloroplasts and mitochondria. They are non-flagellated at maturity, but each contains a pair of kinetosomes.     

Dormant Stages of the Green Flagellate Volvox in a Natural Habitat

Reproduction and formation of resistant dormant spores in Volvox aureus (Ehr.) and V. tertius (Meyer) were studied in a biocoenosis of a transient pool in July–August 1996 and 1997. Under these conditions, the populations of two Volvox species had species-specific reproductive features. In the V. tertius population, a relatively small amount of male individuals and dormant spores (zygospores) appeared sporadically. On the contrary, in the V. aureus population, dormant parthenospores were formed, but male individuals were never observed.     

A kinesin,invA, plays an essential role in volvox morphogenesis

In Volvox carteri adults, reproductive cells called gonidia are enclosed within a spherical monolayer of biflagellate somatic cells. Embryos must "invert" (turn inside out) to achieve this configuration, however, because at the end of cleavage the gonidia are on the outside and the flagellar ends of all somatic cells point inward. Generation of a bend region adequate to turn the embryo inside out involves a dramatic change in cell shape, plus cell movements. Here, we cloned a gene called invA that is essential for inversion and found that it codes for a kinesin localized in the cytoplasmic bridges that link all cells to their neighbors. In invA null mutants, cells change shape normally, but are unable to move relative to the cytoplasmic bridges. A normal bend region cannot be formed and inversion stops. We conclude that the InvA kinesin provides the motile force that normally drives inversion to completion.     

SOMATIC CELL FLAGELLAR APPARATUSES IN TWO SPECIES OF VOLVOX (CHLOROPHYCEAE)1

The somatic cell flagellar apparatuses of Volvox carteri f. weismannia (Powers) Iyengar and V. rousseletii G. S. West have parallel or nearly parallel basal bodies which are separated at their proximal ends. The four microtubular rootlets alternate between two and four members, and all are associated with a striated microtubular associated component (SMAC) that runs between the basal bodies. In addition, each half of the flagellar apparatus apparently rotates during development and loses the 180° rotational symmetry characteristic of most unicellular chlorophycean motile cells. All of these features appear necessary for efficient motion of a colony composed of numerous radially arranged cells. However, the structural details of the flagellar apparatuses of these two species differ. The distance between flagella is greater in V. rousseletii than in V. carteri. One distal striated fiber and two proximal striated fibers connect the basal bodies in V. carteri, but both types of fibers are absent from V. rousseletii. In the latter species, a striated fiber wraps around each of the basal bodies and attaches to the rootlets and the SMAC. No such fiber is present in V. carteri. Since the similarities in the flagellar apparatuses can be explained as a result of adaptation for efficient colonial motion in organisms with similar colonial morphology, the differences suggest a wider phylogenetic distance than previously believed.     

SPERM BUNDLE-FEMALE SOMATIC CELL INTERACTION IN THE FERTILIZATION PROCESS OF VOLVOX CARTERI F. WEISMANNIA(CHLOROPHYTA)1

We studied the fertilization reaction in Volvox carter f. weismannia (Powers) Iyengar. Tests for a sperm bundle chemoattractant produced by female spheroids were negative. The flagella of the female spheroid were identified as the site of sperm bundle binding. Treatment of female spheroids with trypsin or protease blocked sperm bundle binding, suggesting surface proteins are involved. Sperm bundle binding is not affected by female spheroid age up to 64 h after inversion of the female spheroid. Soybean trypsin inhibitor prevents fertilization pore formation. This suggests that a trypsin-like enzyme, released by the dissociating sperm bundle, is responsible for fertilization pore formation.     

TEMPERATURE DEPENDENCE OF GROWTH AND PHOSPHORUS UPTAKE IN TWO SPECIES OF VOLVOX (VOLVOCALES,CHLOROPHYTA)1

The growth of Volvox globator L. and Volvox aureus Ehr. was measured at five temperatures and nine phosphorus concentrations. Growth rates were hyperbolically related to phosphorus concentrations for all temperatures using a Monod growth model. Optimal growth rates of 1.17 and 1.00 doublings d^?1 were obtained at 20°C for V. globator and V. aureus, respectively. Neither species grew at 5°C. The half-saturation constants for growth, K_s, were lower for V. aureus. Phosphorus uptake by both species was also dependent upon external phosphorus concentrations and temperature. At all temperatures, maximum phosphorus uptake (μmol P colony^?1 min^?1) was similar for both species; however, the half-saturation constants for uptake showed significant differences between the species. Comparisons of the kinetic constants for growth and phosphorus uptake suggest that V. aureus will outcompete V. globator under phosphorus limited, conditions.     

microRNAs in a multicellular green alga Volvox carteri

microRNAs(miRNAs)have emerged as key components in the eukaryotic gene regulatory network.We and others have previously identified many miRNAs in a unicellular green alga,Chlamydomonas reinhardtii.To investigate whether miRNA-mediated gene regulation is a general mechanism in green algae and how miRNAs have been evolved in the green algal lineage,we examined small RNAs in Volvox carteri,a multicellular species in the same family with Chlamydomonas reinhardtii.We identified 174 miRNAs in Volvox,with many of them being highly enriched in gonidia or somatic cells.The targets of the miRNAs were predicted and many of them were subjected to miRNA-mediated cleavage in vivo,suggesting that miRNAs play regulatory roles in the biology of green algae.Our catalog of miRNAs and their targets provides a resource for further studies on the evolution,biological functions,and genomic properties of miRNAs in green algae.     

Ontogenetic diversity of colonies and intercellular cytoplasmic bridges in the algae of the genus Volvox

In all representatives of the genus Volvox, cells of cleaving embryos are connected by cytoplasmic bridges, which play an important role in the process of young colony inversion. However, during subsequent development, the intercellular bridges are retained not in all species of Volvox; the occurrence of the bridges in an adult colony correlates with the small size of mature gonidia (asexual reproductive cells) and with the presence of cell growth in the intervals between divisions. This complex of ontogenetic features is derived and arises independently in three evolutionary lineages of colonial volvocine algae. A putative role of the syncytial state of adult colonies for the evolution of developmental cycles in Volvox is discussed.     

FEULGEN MICROSPECTROPHOTOMETRIC STUDIES OF PANDORINA MORUM AND OTHER VOLVOCALES (CHLOROPHYCEAE)12

The nuclear DNA content during normal vegetative growth and division has been examined in three species of Volvocales, Chlamydomonas reinhardtii Dangeard, Pandorina morum Bory, and Volvox carteri f. nagariensis Iyengar. The results are consistent with the nuclear cycle reported in the literature for Eudorina. Nuclear DNA content does not increase during the prolonged cell growth phase. At the time of colony formation, nuclear DNA doubles, the nucleus divides, and this alternation continues until the final 2ⁿ complement of progeny nuclei is formed. The 4- and 8-nucleate stages of dividing gonidia of V. carteri have a nuclear DNA content in the same range as the somatic cells; they are not polyploid or polytene. Four normal clones of Pandorina, having 2, 5 or 12 chromosomes, all had similar amounts of DNA per nucleus, suggesting that the species has a nuclear genome of fairly constant size rather than consisting of many strains representing a polyploid series. One unique clone, a hybrid with double the chromosome number of either its parents, had twice as much DNA as the normal clones. The Feulgen spectrophotometric method is sufficiently sensitive to detect 2-fold differences in DNA content at the level of 2 × 10^?13 g of DNA /nucleus, and its use avoids the complications associated with the presence of organelle DNA.     

Reversal of sexual induction in Volvox carteri by ultraviolet irradiation and removal of sexual pheromone

Washing in fresh culture medium or short exposure to ultraviolet irradiation (UV) was found to reverse the action of the sexual pheromone produced by the green alga Volvox carteri. Induced gonidia which would normally form egg-bearing females formed mainly asexual individuals in response to these treatments. The UV effect is strongly dependent on the stage of the life cycle at which exposure is given. Sexual induction in this organism requires early and continuous exposure to the sexual pheromone. The mechanism by which UV reverses sexual induction is not understood, but it could be caused by inactivation of the pheromone or by inactivation of a pheromone-induced repressor of asexual characters.     

VOLVOX BARBERI,THE FASTEST SWIMMER OF THE VOLVOCALES (CHLOROPHYCEAE)1

Volvox barberi W. Shaw is a volvocalean green alga composed of biflagellated cells. Vovocales with 16 cells or more form spherical colonies, and their largest members have germ‐soma separation (all species in the genus Volvox). V. barberi is the largest Volvox species recorded in terms of cell number (10,000–50,000 cells) and has the highest somatic to reproductive cell ratio (S/R). Since they are negatively buoyant, Volvocales need flagellar beating to avoid sinking and to reach light and nutrients. We measured V. barberi swimming speed and total swimming force. V. barberi swimming speeds are the highest recorded so far for volvocine algae (～600 μm · s^?1). With this speed, V. barberi colonies have the potential to perform daily vertical migrations in the water column at speeds of 2–3 m · h^?1, consistent with what has been reported about Volvox populations in the wild. Moreover, V. barberi data fit well in the scaling relationships derived with the other smaller Volvox species, namely, that the upward swimming speed V_up∝N^0.28 and the total swimming force F_S∝N^0.77 (N = colony cell number). These allometric relationships have been important supporting evidence for reaching the conclusion that as size increases, colonies have to invest in cell specialization and increase their S/R to increase their motility capabilities to stay afloat and motile.     

Comparative Analysis of Embryonic Inversion in Algae of the Genus <Emphasis Type="Italic">Volvox</Emphasis> (Volvocales,Chlorophyta)

Recent literary data on inversion (turning inside out) in the embryos of flagellated algae of the genus Volvox are critically analyzed. In this process, active changes in the shape of embryonic cells and the displacement of intercellular cytoplasmic bridges play an important role. After inversion, the flagella appear on the outer side of the young colony and provide its motility. Within the genus Volvox, two main modes of embryo inversion have been recently established during the asexual developmental cycle—inversion of type A and inversion of type B—represented by the two species most thoroughly studied, respectively, Volvox carterif. nagariensis and V. globator. However, the published opinion that the inversion of V. aureus embryos is of the type B seems to be doubtful. Comparative and evolutionary aspects of embryonic inversion in Volvox are discussed with the use of data on other genera of colonial volvocine algae.