Observations on the ultrastructure of representatives of the genera Hemiselmis and Chroomonas (Cryptophyceae)

Hemiselmis rufescens Parke and three species of the genus Chroomonas have been examined by electron microscopy. They demonstrate certain characteristic features of the Cryptophyceae, such as the presence of trichocysts and the arrangement of thylakoids in pairs in the plastid. The prominent pyrenoid of the genus Chroomonas is penetrated longitudinally by a tongue of cytoplasmic matrix which originates from between the two pairs of plastid membranes. In the genus Hemiselmis, however, the pyrenoid is traversed by a pair of thylakoids. The nucleus, Golgi apparatus and Corps de Maupas also occupy characteristic positions. These features indicate a close relationship between these two genera and the other major genus Cryptomonas, and support the suggestion that the Cryptophyceae is a discrete taxonomic group.     

COMPARATIVE STUDIES OF PYRENOID ULTRASTRUCTURE IN ALGAE OF THE MONOSTROMA COMPLEX123

The pyrenoid structure in 15 species of the Monostroma complex is very diverse us revealed by a study of the morphology of the pyrenoid matrix, associated starch shell, and pattern of intrapyrenoidalthylakoid bands. From these characteristics 8 types of pyrenoid structure were classified. The variation of pyrenoid structure was shown not only among the species studied, but also between the alternation of generations (M. angicava and M. nitidum). In M. fuscum var. splendens, M. groenlandicum, M. undulatum, and M. zostericola pyrenoid structure is the same throughout the life cycle. The pyrenoid matrix of M. zostericola is surrounded by a double membrane that prevents the direct connection of the pyrenoid matrix with chloroplast thylakoids. The pyrenoid also lacks a starch shell. These findings support the establishment of a new genus Kornmannia by Bliding to include M. zostericola. In addition, similarities in pyrenoid ultrastructure suggest an affinity of Capsosiphon fulvescens with M. groenlandicum.     

COMPARATIVE ULTRASTRUCTURE OF CULTURED SPECIES OF TREBOUXIA1,2

Five species of cultured Trebouxia—T. anticipata, T. decolorans, T. erici, T. gelatinosa, and T. impressa—were examined with the electron microscope. A comparative examination of their pyrenoids revealed pyrenoglobuli associated with single pyrenoid thylakoids. The pyrenoids of T. decolorans, T. erici, and T. gelatinosa possess single thylakoids that cross or deeply penetrate the pyrenoid matrix and are often disposed in parallel arrays. T. anticipata possesses both single and double pyrenoid thylakoids within the matrix. T. impressa possesses vesiculate invaginations of thylakoid membranes into the pyrenoid matrix. The phycobiont. T. erici was examined in detail at the light and electron microscopic levels for pyrenoid alterations associated, with varied environmental regimes and with cell division. A greater amount of starch is present in cells grown in organic culture at 215 lux light intensity than in cells of similar size grown at 1075 or 3600 lux. Pyrenoglobuli are present throughout the life cycle and occur both in aplanospores and in zoospores.     

NEW ULTRASTRUCTURAL ASPECTS OF PYRENOIDS OF THE LICHEN PHOTOBIONT TREBOUXZA (MICROTHAMNIALES,CHLOROPHYTA)1

The pyrenoid structure of Trebouxia, a photobiont of two lichen species, Umbilicaria cinereorufescens (Schaer.) Frey and Parmelia sulcata Taylor, was investigated. In both lichen species, the pyrenoid of the photobiont exhibited straight, unbranched, long or short tubules. In the first lichen species, multiple pyrenoids were observed occasionally, while in the second one, homogeneous masses, called protein bodies, appeared between the thylakoids. These protein bodies were previously observed in some other species of the family Umbilicariaceae. Serial sections from single pyrenoids showed that tubules of the Impressa-type pyrenoid were closely associated with pyrenoglobuli. The three-dimensional reconstruction of a complete chloroplast of a P. sulcata algal cell showed that the protein bodies were spatially separate structures. Immunolocalization techniques to detect the presence of ribulose-bisphosphate carboxylase (Rubisco) in the chloroplast showed that this enzyme was present primarily in the pyrenoid matrix. When protein bodies were present in the chloroplast, Rubisco appeared to be localized in these structures. The presence of pyrenoid satellites and protein bodies with reactivity to anti-Rubisco may be related to the nutritional conditions of the thalli.     

EFFECTS OF CO2 CONCENTRATION DURING GROWTH ON THE INTRACELLULAR STRUCTURE OF CHLORELLA AND SCENEDESMUS (CHLOROPHYTA)1

Effects of CO₂ concentration during growth on intracellular structure were studied with ftve species of Chlorella and Scenedesmus obliquus. Cells grown under ordinary air conditions (low-CO₂ cells) had a well developed pyrenoid surrounded by starch, while those grown under high CO₂ conditions (high-CO₂ cells) had a less developed pyrenoid or no detectable pyrenoid. Two mitochondria, one at each side of the neck of the projection of the chloroplast close to the pyrenoid, were found in low CO₂ cells of C. vulgaris 11h. Usually, lamellar stacks extended in parallel in the chloroplast of low-CO₂ cells of C. vulgaris 11h, while a grana-like structure was found in high-CO₂ cells. However, in C. pyrenoidosa, grana like structures were found more commonly in low-CO₂ cells than in high-CO₂ cells. These results suggest that development of pyrenoid starch is generally correlated with growth under low CO₂ conditions, whereas CO₂-effects on lamellar stacking are species dependent.     

Ultrastructure of Endosymbiotic Chlorella in a Vorticella

SYNOPSIS Observations were made on the ultrastructure of a species of Vorticella containing endosymbiotic Chlorella. The Vorticella , which were collected from nature, bore conspicuous tubercles of irregular size and distribution on the pellicle. Each endosymbiotic algal cell was located in a separate vacuole and possessed a cell wall and cup-shaped chloroplast with a large pyrenoid. The pyrenoid was bisected by thylakoids and surrounded by starch plates. No dividing or degenerating algal cells were observed.     

Structure and chemical composition of endodermal and rhizodermal/hypodermal walls of several species

CWM, isolated cell wall material
ECW, isolated endodermal cell walls
G, guaiacyl monomer
H, p-hydroxyphenyl monomer
HCW, isolated hypodermal cell walls
RHCW, isolated rhizodermal and hypodermal cell walls
S, syringyl monomer
XV, isolated xylem vessels

Endodermal cell walls of the three dicotyledoneous species Pisum sativum L., Cicer arietinum L. and Ricinus communis L. were isolated enzymatically and analysed for the occurrence of the biopolymers lignin and suberin. From P. sativum, endodermal cell walls in their primary state of development (Casparian strips) were isolated. Related to the dry weight, these isolates contained equal amounts of suberin (2·5%) and lignin (2·7%). In contrast, the endodermal cell walls of C. arietinum and R. communis, which were nearly exclusively in their secondary state of development, contained significantly higher proportions of suberin (10–20%) and only traces of lignin (1–2%). The results of the chemical analyses were supported by a microscopic investigation of Sudan III-stained root cross-sections, showing a Casparian strip restricted to the radial walls of the endodermis of P. sativum and well-pronounced red suberin lamellae in C. arietinum and R. communis roots. Compared with recently investigated monocotyledoneous species, higher amounts of suberin by one order of magnitude were detected with the secondary state of development of dicotyledoneous species. Furthermore, the carbohydrate and protein contents of primary (Clivia miniata Reg. and Monstera deliciosa Liebm.), secondary (C. arietinum and R. communis) and tertiary endodermal cell walls (Allium cepa L. and Iris germanica L.) were determined. The relative carbohydrate content of secondary endodermal cell walls was low (14–20%) compared with the content of primary (42–50%) and tertiary endodermal cell walls (60%), whereas the protein content of isolated endodermal cell walls was high in primary (13%) and secondary (8%) and low in tertiary endodermal cell walls (0·9–2%). The results presented here indicate that the quantitative chemical composition of primary, secondary, and tertiary endodermal cell walls varies significantly. Finally, cell wall proteins are described as an additional important constituent of endodermal cell walls, with the highest concentrations occurring in primary (Casparian strips) and secondary endodermal cell walls.     

THE FINE STRUCTURE OF THE FLAGELLAR APPARATUS OF CARTERIA1,2

The fine structure of the flagellar apparatus of 5 species of the green quadriflagellate alga Carteria is described. The 5 species can be morphologically separated into 2 groups on the bases of cell shape and ultrastructure of the pyrenoid and flagellar apparatus. Group I cells are spherical, possess many pyrenoid thylakoids, and retain a flagellar apparatus similar to that of Chlamydomonas reinhardi. The flagellar bases are oriented at approximately 90° to one another, have distal and proximal fibers, and are associated with 4 cruciately arranged microtubule bands. Cells of group II are ellipsoid, possess few pyrenoid thylakoids, and show a complex system of microtubule bands and sigmoid-shaped, electron dense rods which extend between opposite pairs of basal bodies. The basal bodies of group II cells are directed inward in a circular pattern rather than outward as in group I cells. Unlike Chlamydomonas, the distal fiber of the Carteria species is nonstriated. The proximal fiber is striated, and both distal and proximal fibers are composed of 60–80 Å diameter microfibrils.     

ELECTRON MICROSCOPY OF CARTERIA AND CHLAMYDOMONAS

Cultures of Chlamydomonas eugametos, Chl. sp., Carteria eugametos, C. crucifera, C. radiosa, and C. sp. were examined with the electron microscope to determine generic differences between Carteria and Chlamydomonas at the ultrastructural level. The ultrastructure of the flagella, mitochondria, dictyosomes, nuclei and ground substance was noted to be similar in all species. The cellular boundary of all species except Chlamydomonas eugametos contains a 250 A intermediate layer of unknown chemical composition between the fibrillar cellulose wall and the outer capsule layer. Four structural features other than the number of flagella distinguish Carteria from Chlamydomonas: the intermediate layer of the cellular boundary, the chloroplast, the pyrenoid and the eyespot. Only in the Carteria species is the intermediate layer traversed by striations or 12-mμ-wide bars. Striations in the cellulose wall surrounding the flagellar channels also appear in Carteria eugametos and C. crucifera. The chloroplast lamellae of the Carteria species are grouped into discrete stacks of invaginated thylakoids termed pseudograna. The chloroplast lamellae of Chlamydomonas are broad and sheet-like and are also invaginated although less frequently than are the pseudograna of Carteria. The phenomenon of infolding of the chloroplast lamellae is suggested as a general developmental process in the formation of new thylakoids. In Carteria, single thylakoids traverse the pyrenoid and there are 2 rows of granules in the eyespot. Favorable micrographs of the eyespot indicate that the granules may be osmiophilic granules of the chloroplast chemically modified for a photoreceptive function.     

BIOCHEMICAL TAXONOMY AND MOLECULAR PHYLOGENY OF THE GENUS CHLORELLA SENSU LATO (CHLOROPHYTA)

A multimethod approach was used to characterize unicellular green algae that were traditionally assigned to the genus Chlorella Beijerinck and to resolve their phylogenetic relationships within the Chlorophyta. Biochemical, physiological, and ultrastructural characters, together with molecular data such as DNA base composition and DNA hybridization values, were compared with a molecular phylogeny based on complete 18S rRNA sequences. Our results show that Chlorella taxa are dispersed over two classes of chlorophytes, the Trebouxiophyceae and the Chlorophyceae. We propose that only four species should be kept in the genus Chlorella (Chlorophyta, Trebouxiophyceae): C. vulgaris Beijerinck, C. lobophora Andreyeva, C. sorokiniana Shih. et Krauss, and C. kessleri Fott et Nováková. Common characteristics of these taxa are glucosamine as a dominant cell wall component and the presence of a double thylakoid bisecting the pyrenoid matrix. Norspermine, norspermidine, and secondary carotenoids are never produced. Other "Chlorella" species belong to different taxa within the Trebouxiophyceae ( "C." protothecoides = Auxenochlorella protothecoides [Krüger] Kalina et Punčochářová, "C." ellipsoidea, "C." mirabilis, "C." saccharophila, and "C." luteoviridis ) and Chlorophyceae ( "C." zofingiensis and "C." homosphaera = Mychonastes homosphaera Kalina et Punčochářová). The latter taxa can easily be recognized by the production of secondary carotenoids under nitrogen-deficient conditions.     

小球藻Rubisco在叶绿体中的免疫金标定位

应用免疫技术对Rubisco在中国小球藻(Chlorellaspp.640909)叶绿体中进行了分子定位及Native-PAGE电泳、SDS-PAGE电泳及其Westen印迹分析,并对小球藻淀粉核(Pyrenoid)超微结构进行了观察.结果显示Native-PAGE电泳图谱主要为一条主带,Westen印迹反应证明该条带即为Rubisco酶,SDS-PAGE电泳及其Western印迹图谱显示Rubisco大亚基分子量大约为55kD.中国小球藻淀粉核为椭圆形,被淀粉鞘所包围,中央有一条由2个类囊体组成的纵向通道,并在蛋白核内段处稍膨胀.淀粉核与叶绿体基质存在多处联系.免疫分子定位显示Rubisco大亚基和全酶分子主要分布于叶绿体的淀粉核上,且Rubisco在淀粉鞘部位也有少量分布,极少部分分布在叶绿体基质中,表明叶绿体淀粉核与光合作用关系密切.Rubisco聚集于淀粉核可能有利于藻类对CO2固定.     

Immunogold localization of ribulose-1,5-bisphosphate carborylsae/oxygenase in chloroplasts of Chlorella]

Ribulose 1,5-bisphosphate carboxylase/oxygenase (Rubisco) is a first key enzyme in the Calvin Circle of plant cell photosynthesis. This paper mainly studied gold immunolocalization of Rubisco of Chlorella spp. 640909, and the Native-PAGE and, SDS-PAGE and Western bloting analysis, as well as the observation to pyrenoid ultra structure. The Native-PAGE result showed a main band, evidenced as the Rubisco band by the Western blot with the antibody against the Rubisco from C. prototothecoides, The special immunoacton of Rubisco from Chlorella spp. 640909 and the antibody to large subunit of Rubisco from C. prothecoides showed the large subunit proteins of Rubisco in the two species of Chlorella shared the high homology. The SDS-PAGE and Western blotting maps showed the molecule weight of the large subunit of Rubisco of Chlorella spp. 640909 was about 55 KD. The shape of pyrenoid ultra structure of the electronic microscope was oblong, and was embedded in starch sheath, with 2 swelling thylakoids through out a center portrait channel of the pyrenoid. There were some connections between pyrenoid and the chloroplast stroma. The distribution of the large subunits and the whole Rubisco in the chloroplast of Chrolella spp. 640909 was studied by immunoelectron microscopy by embedded sections with antibody to large subunit and whole enzyme followed by second antibody, goad anti-rabbit immunoglobulin G conjugated to 10 nm gold particles(Sigma production). The result showed the antibodies against large subunit and whole enzyme heavily labeled the pyrenoid, as well as starch sheath region, whereas the thylakoid region of the plastid was lightly labeled. And the whole Rubisco antibody labeled the pyrenoid surface more heavily than the large subunit antibody did. It is demonstrated the pyrenoid and starch sheath have the photosynthesis function. Rubisco concentrating in pyrenoid and starch sheath is valuable to fix CO2 for photosynthesis in algae.     

Elektronenoptische Untersuchungen an Flechten

Summary The substructure in the phycobionts of the genus Trebouxia from different lichens is analysed. In the group Trebouxia I and Trebouxia II a further classification according to the differentiation of the chromatophores and their pyrenoids can be made. Trebouxia I: 1. Very long thylakoids are piled together. A few thylakoids curve through the pyrenoid. 2. The thylakoids are arranged like grana- and stromathylakoids in higher plants. In the pyrenoid the thylakoids are extended to canals. Trebouxia II: 1. Long thylakoids are packed very close together. A few of them pass through the pyrenoid in regular intervals. 2. The thylakoids are single or in piles. In the pyrenoid the thylakoids are again extended to canals. 3. The thylakoids are enlarged to vesicles which extend into the pyrenoid in the same form. 4. The thylakoids show all different forms of the above mentioned differentiations.In the different types of chromatophores there are always a large number of osmiophilic plastoglobuli in the pyrenoid matrix. It is discussed whether they are a reservoir in the lipid metabolism of the lichens.     

Comparative ultrastructure of pyrenoids inTrebouxia (Microthamniales,Chlorophyta)

Pyrenoid ultrastructure has been investigated from cultures of all 26 species ofTrebouxia with the aim of establishing pyrenoids as a taxonomic character. Different arrangements and forms of thylakoid lamellae within the pyrenoid matrix allow eight pyrenoid types to be distinguished. Each type is characteristic of a group of species. Thegigantea- andimpressa-type are similar, differing only in the form of the tubules: short, branched tubules mark thegigantea-type; ± long and straight invaginations theimpressa-type. Thearboricola-type is characterized by meandering pyrenoid membranes developing from lamellae parallel with each other in young autospores. Pyrenoids of thegelatinosa-type are traversed by thin parallel-arranged tubules. Few thylakoids with a curved profile are typical of theirregularis-type. Thecorticola-type is different from all others in having a distinct starch sheath closely connected with the pyrenoid matrix and no pyrenoglobuli being associated with the pyrenoid membranes. No true pyrenoids have been found inT. magna andT. erici. Within the chloroplast, they have indistinct areas with pyrenoglobuli, but without differentiated thylakoids. Pyrenoid morphology is stable in culture on different media as well as in phycobionts within lichen thalli. Comparing the pyrenoid of a lichenizedTrebouxia with that from cultured species, the identification of the phycobiont within the lichen thallus is possible, without the need of culturing the algae. This has been shown in species ofParmelia andHypogymnia. New aspects for the taxonomy and systematics ofTrebouxia are discussed.Dedicated to Prof. DrLothar Geitler on the occasion of the 90th anniversary of his birthday.     

PHYLOGENETIC RELATIONSHIPS OF CAULERPA (CHLOROPHYTA) BASED ON COMPARATIVE CHLOROPLAST ULTRASTRUCTURE1,2

The ultrastructure of chloroplasts from 28 of the 73 species of Caulerpa Lamouroux (Chlorophyta, Caulerpales) has been studied to aid in interpreting phylogenetic relationships among the 12 recognized sections. Variations of systematic value include pyrenoid occurrence and fine structure, thylakoid architecture and amount of photosynthate storage. Comparisons of field and culture specimens indicate these characters are consistent. Chloroplast thylakoids are grouped into bands, with the distribution of bands differing among species. In the most common arrangement, bands are evenly distributed throughout the chloroplast. A few species show lateral displacement of bands whereas others have a majority of bands arranged at one end of the chloroplast. Starch is stored cither as one or two large grains (> 1 μm diam.) or numerous small grains (< 0.5 μm diam.). Electron-transparent regions are common in other species in which chloroplasts rarely store starch. Simple, embedded pyrenoids are present in several species of section Sedoideae. An opaque region occurs in chloroplasts of C. elongata which may represent an intermediate stage in the evolutionary loss of the pyrenoid. It is suggested that the chloroplast of Caulerpa evolved, from a large, complex, pyrenoid-containing organelle housing both photosynthetic and amylogenic functions, to a small, structurally simpler one, specialized for photosynthesis alone. A phylogeny of the 12 sections of Caulerpa is constructed, based on chloroplast evolution which agrees with an earlier morphology-based hypothesis on the origin and evolution of Caulerpa.     

Reconsideration of the taxonomy of ellipsoidal species of Chlorella (Trebouxiophyceae, Chlorophyta), with establishment of Watanabea sen. nov.

Subcultures of SAG 211–9b and 1AM C-211, ultimately derived from CCAP 211/9b, a strain isolated by Pringsheim in 1939 and identified as Chlorella sac-charophila (Kruger) Migula were observed using light and electron microscopy. Their morphology proved to be basically identical. Both have two forms of cells, one (E-form) narrowly to broadly ellipsoidal, the other (S-form) ovoid to spheroidal. The cell wall of both forms is composed of a single smooth layer. The chloroplast of young cells is trough-like or saucer-shaped with a smooth margin, while that of mature cells is band- or cup-shaped with deep incisions. The thylakoid lamellae are loosely stacked and neither form has a pyrenoid. Both types of cells are capable of producing autospores: eight to 16 in E-form cells, two to four in S-form cells. These morphological features are different from those of C. saccharophila, which has a pyrenoid and produces only one form of autospores. In the absence of any existing genus that includes Chlorella-like algae with a simple cell wall, no pyrenoid, and two forms of mature cells and autospores, a new genus, Watanabea, is proposed with the type species W. reniformis.     

The pyrenoid is the site of ribulose 1,5-bisphosphate carboxylase/oxygenase accumulation in the hornwort (Bryophyta: Anthocerotae) chloroplast

Summary Chloroplasts of many species of hornworts (Anthocerotae) have a structure that resembles the pyrenoid of green algae but whether these two structures are homologous has not been determined. We utilized immunogold labelling on thin sections to determine the distribution of ribulose 1,5-bisphosphate carboxylase/oxygenase (RuBisCO), the major protein of algal pyrenoids, in sixteen hornwort species with and without pyrenoids. Several species (Phaeoceros laevis, Anthoceros punctatus, A. formosae, A. laminiferus, Folioceros fuciformis, Folioceros sp.,Dendroceros tubercularis, D. japonicus, D. validus, Notothylas orbicularis, N. temperata, andSpaerosporoceros adscendens) have uniplastidic (or primarily uniplastidic) cells with large prominent multiple pyrenoids. In all of these species, the labelling is found exclusively in the pyrenoid and, with the exception of theFolioceros, Dendroceros, andNotothylas species, the labelling is randomly distributed throughout the pyrenoid. In the exceptional species, the pyrenoids have prominent pyrenoglobuli or other inclusions that are unlabelled. InMegaceros flagellaris andM. longispirus, the cells are multiplastidic (with the exception of the apical cell and some epidermal cells) and the chloroplasts lack pyrenoids.Anthoceros fusiformis andPhaeoceros coriaceus have primarily uniplastidic cells but the chloroplasts lack pyrenoids; only an area of stroma in the center of the plastid devoid of starch, reminiscent of a pyrenoid, is found. In all of the species lacking pyrenoids, RuBisCo is found throughout the stroma, including the stromal spaces made by the so-called channel thylakoids. No preferential accumulation of RuBisCo is found in the pyrenoid-like region inA. fusiformis andP. coriaceus. These data indicate that 1) the hornwort pyrenoid is homologous to algal pyrenoids in the presence of RuBisCo; 2) that at least some of the RuBisCo in the pyrenoid must represent an active form of the enzyme; and 3) that, in the absence of pyrenoids, the RuBisCo is distributed throughout the stroma, as in higher plants.Abbreviations RuBisCo ribulose 1,5-bisphosphate carboxylase/oxygenase     

Heterocapsa circularisquama sp. nov. (Peridiniales, Dinophyceae): A new marine dinoflagellate causing mass mortality of bivalves in Japan

Heterocapsa circularisquama Horiguchi sp. nov. is described from Ago Bay, central Japan. The dinoflagellate produced large-scale red tides in the bays of central and western Japan and caused mass mortality of bivalves, notably the pearl oysters. The cell is small and is composed of a conical epitheca and a hemi-spheroidal hypothecs. The chloroplast is single and is connected to the single pyrenoid. The nucleus is elongated and is located in the left side of the cell. Thecal plate arrangement has been determined as: Po, cp, 5′, 3a, 7″, 6c, 5s, 5″′, 2″″. Heterocapsa circularisquama is morphologically very similar to Heterocapsa illdefina and it is almost impossible to distinguish these two species at light microscopical level. The characteristics which can be used to distinguish these two species are the morphology of body scales and the ultrastructure of the pyrenoid matrix. The body scales of H. circularisquama possess six radiating ridges on the circular basal plate; no such ridges can be observed on the roughly triangular basal plate of the scales of H. illdefina. Furthermore, the scales of the latter species possess substantially shorter spines compared to those of H. circularisquama. The pyrenoid matrix of H. circularisquama is hardly perforated by cytoplasmic tubules, while in H. tlldefina the pyrenoid matrix is always penetrated by many cytoplasmic tubules. Based on the arrangement of thecal plates, morphology of body scales, and ultra-structure of the pyrenoid, I am placing H. circularisquama sp nov. into the genus Heterocapsa.     

Electron Microscopic Observations on the Symbiosis of Paramecium bursaria and its Intracellular Algae*

SYNOPSIS. Observations were made on the fine structure of Paramecium bursaria and its intracellular Chlorella symbionts. Emphasis was placed on the structure of the algae and structural aspects of the relationship between the organisms. The algae are surrounded by a prominent cell wall and contain a cup-shaped chloroplast which lies just beneath the plasma membrane. Within the cavity formed by the chloroplast are a large nucleus, a mitochondrion, one or more dictyosomes, and numerous ribosomes. The chloroplast itself is made up of a series of lamellar stacks each containing 2–6 or more thylakoids with a granular stroma and starch grains intercalated between the stacks. The thylakoid stacks of mature algae are frequently more compact than those of recently divided algae. A large pyrenoid is located within the base of the chloroplast. It is made up of a granular or fibrillar matrix surrounded by a shell of starch. The matrix is bisected by a stack of 2 thylakoids. Prior to the division of the chloroplast the pyrenoid regresses; pyrenoids subsequently form in the daughter chloroplasts thru condensation of the matrix material and the reappearance of a starch shell. This shell appears to be formed by the hollowing-out of starch grains already present in the chloroplast stroma. Accordingly, in this case, starch moves from the stroma to the pyrenoid. The algae are located thruout the peripheral cytoplasm of the Paramecium. Each alga is located in an individual vacuole except immediately following division of the algae when the daughter cells are temporarily located in the vacuole which harbored the parental cell. Shortly thereafter the vacuole membrane invaginates, thereby isolating the daughter algae into individual vacuoles. Degenerating symbiotic algae are seen; because these are frequently found in vacuoles with bacteria, they are presumed to be undergoing digestion. Due to the conditions of culture these algae could have been either of intracellular or extracellular origin.     

Comparative studies onChlorella cell walls: Induction of protoplast formation

Among 12 strains ofChlorella ellipsoidea, C. vulgaris, andC. saccharophila tested, 4 strains (1,C. ellpsoidea; 2,C. vulgaris; 1,C. saccharophila) formed osmotically labile protoplasts after treatment with mixtures of polysaccharide degrading enzymes. The relationship between enzymatical digestibility and structure or composition ofChlorella cell walls were studied by electron microscopy and staining techniques with some specific dyes. The cell wall structures of the 12Chlorella strains were grouped into three types: (1) with a trilaminar outer layer, (2) with a thin outer monolayer, and (3) without an outer layer. Protoplasts were formed only from the strains with a cell wall of Type 2. In the strains with a cell wall of Type 1, the outer layer protected the inner major microfibrillar layer against enzymatic digestion. The cell wall of Type 3 was totally resistant to the enzymes; the chemical composition of the cell wall would be somewhat different from that of other types.