Light and electron microscopical observations on the heterotrophic protist Thaumatomastix salina comb. nov. (syn. Chrysosphaerella salina) and its allies

The marine flagellates presently known as the chrysophytes Chrysosphaerella salina and C. tripus Takahashi & Hara have been refound and studied with light microscopy and whole mounts for electron microscopy. Based on material from Australia and Denmark (the latter from the type locality), C. salina is shown to be a colourless protist related to Reckertia sagittifera Conrad. It is characterized by a combination of flagellar features previously thought to be restricted to Reckertia , i.e. a short anterior flagellum which is scale-clad, and a longer, usually posterior but naked flagellum. The scales on the body are shown to be silicified. The new light microscopical studies have also shown considerable resemblance between C. salina, C. tripus and the genus Thaumatomastix Lauterborn. C. salina and C. tripus are therefore transferred to this genus together with Reckertia and the 2 marine species described since 1980 as belonging to Chrysosphaerella, C. triangulata Balonov and C. patelliformis Takahashi & Hara. Thaumatomastix bipartita sp.nov. is illustrated and described.
Chrysosphaerella appears to be a genus of photosynthetic, colony-forming chrysophytes restricted to freshwater habitats. Thaumatomastix is a genus of heterotrophic protists, usually solitary, which occurs in both marine and freshwater environments. The two genera show little, if any, phylogenetic relationship to each other.     

A light and electron microscopic study of the flagellate-to-ameba conversion in the MyxomyceteStemonitis pallida

Summary The flagellate-to-ameba conversion process of the MyxomyceteStemonitis pallida was investigated with Nomarski optics and electron microscopy. The flagellate has two flagella, a long and a short one. When the water film containing the flagellates becomes very thin, they retract their flagella, usually the short one first and then the long one. The short flagellum is retracted by only one method, in which the sheath membrane of the flagellum fuses with the cell membrane, consequently causing the axoneme to be absorbed into the cytoplasm. Retraction of the long flagellum can be divided into four types. In all cases, fusion of the sheath membrane and the cell membrane takes place. The retracted axoneme of the long flagellum sometimes beats convulsively for about 10 minutes after retraction, and after 10–15 minutes it became indistinguishable as it was detached from the blepharoplast.Analysis of thin sections shows that the retracted axonemes disintegrate in the following squence: B-tubules, A-tubules, spokes, central microtubules. In almost all cells the degradation begins immediately after retraction and is completed within 90 minutes. Only on rare occasions, structures which seem to have been derived from retracted axonemes are observed in the ameba about 90 minutes after conversion. The basal bodies and cytoplasmic microtubules are a little more stable than the retracted axonemes. Some basal bodies of the short flagellum, whose C-tubules are affected, are present in the amebae more than 90 minutes after conversion. Cytoplasmic microtubules decrease in number and become shorter in the amebae after about 24 hours, when newly formed regions filled with flocculent material appear.     

Motion of the Longitudinal Flagellum in Ceratium tripos (Dinoflagellida): A Retractile Flagellar Motion1

The longitudinal flagellum of Ceratium tripos moves in two dissimilar ways: undulation and retraction. The undulatory wave is planar and has a wavelength of 74.3 ± 9.6 μm and an amplitude of 14.2 ± 2.3 μm in sea water. The beat frequency is 30 Hz at 20°C, pH 8.0. The retractile motion is unique to Ceratium and is triggered by mechanical stimulation on the cell body, especially at the tip of the apical horn. When it retracts, the longitudinal flagellum folds every 4–5 μm along the flagellum. Cinematographic study showed that the flagellum folded from tip to base and was finally installed into the sulcus, a groove on the ventral side of the cell. This motion is completed in sea water within 28 msec. The retracted flagellum then re-extends and restores the undulation within a few seconds. The flagellum unfolds in the proximal portion first, then the distal, and finally the middle portion. Fixation always triggers the retraction. Scanning electron microscopy showed that the flagellum is folded and secondarily twisted in a helix. A new fiber in addition to the flagellar axoneme was found in the retracted flagellum by phase microscopy. This fiber (R-fiber) seems to contract during the retraction to fold the flagellum.     

ULTRASTRUCTURE OF SWARMERS IN THE LAMINARIALES (PHAEOPHYCEAE). I. ZOOSPORES1

Zoospores of 17 species in 14 genera of Laminariales, collected in the northeast Pacific Ocean, were studied by electron microscopy. These zoospores are unique in the brown algae in lacking both an eyespot in the single chloroplast and any associated swelling at the base of the shorter, posterior flagellum. Spores of all species examined possess a distal whiplash portion on the longer, mastigoneme-bearing anterior flagellum. This appendage may sometimes be as long as the mastigoneme-bearing portion of the flagellum, but it is only seldom preserved in the preparations for electron microscopy. A microtubular cytoskeleton is probably responsible for maintaining the shape of the spore. It consists of a short band of about 10 microtubules between the two basal bodies, scattered tubules converging at the anterior of the spore, a band of 7–9 tubules directed anteriorly from the anterior basal body, and a band directed posteriorly from the posterior basal body. These anterior and posterior bands may form one continuous band looping around the periphery of the spore. Variation with possible taxonomic significance was found in the ultrastructure of vesicles which apparently contain adhesive material, and which are extruded through the plasmalemma when the zoospores settle.     

Ultrastructure of the spermatid and spermatozoon of Macracanthorhynchus hirudinaceus.

The ultrastructure of the spermatid and spermatozoon of Macracanthorhynchus hirudinaceus (Archiacanthocephala) was studied by means of transmission electron microscopy. The flagellum and nucleus in the spermatid gradually expanded simultaneously. The karyoplasma of the spermatid transformed into dense inclusions and a multibarrel structure, which were also found in the spermatozoan body. The multibarrel structure was located close to the flagellum and consisted of many irregular microtubes. The flagellum of the developing spermatozoon was observed in a concavity of the spermatid nucleus. The microtubule arrangement of the flagellum was "9 + 2". No mitochondria or acrosome were observed in spermatozoa.     

ULTRASTRUCTURAL STUDIES ON BIGELOWIELLA NATANS, GEN. ET SP. NOV., A CHLORARACHNIOPHYTE FLAGELLATE

Three isolates from the Provasoli-Guillard National Center for Culture of Marine Phytoplankton at Bigelow Laboratory, previously labeled Pedinomonas sp. and Pedinomonas minutissima from the green algal class Pedinophyceae, have been examined by light microscopy and TEM and shown to belong to the Chlorarachniophyceae, a class of nucleomorph-containing amebae. The three isolates represent the first chlorarachniophycean flagellates to be discovered. The ultrastructure of the cells has been examined in detail, with particular emphasis on the flagellar apparatus, a feature not examined in detail in chlorarachniophytes before. Cells are basically biflagellate, but the second flagellum is represented by a very short basal body only. Flagellar replication has shown this flagellum to be the mature stage, that is, the no. 1 flagellum, whereas the long emergent flagellum is the no. 2 flagellum that shortens into a short basal body during cell division. Mitosis is open with a pair of centrioles at each pole. Emergent flagella are absent during mitosis. Cells may form cysts, and the flagellar basal bodies and part of the flagellar roots are maintained in the cysts. Four microtubular roots emanate from the basal bodies, and the path of one of them is very unusual and very unlike any other known flagellate. No striated roots were observed. Other fine-structural features of the cell include a very unusual type of pyrenoid and a special type of extrusome. Cells are mixotrophic. The three isolates are very similar and are described as Bigelowiella natans , gen. et sp. nov. Ultrastructurally, chlorarachniophytes do not show close relationship to any known group of algae or other protists.     

I. Extracellular Cultivation and Morphological Characterization of Amastigote-Like Forms of Leishmania panamensis and L. braziliensis

. Two strains of the Leishmania braziliensis complex have been adapted to grow extracellularly at elevated temperature as amastigote-like forms in a cell-free medium. These parasites can be serially cultivated and maintained at 32°C for L. panamensis (WR442; L. braziliensis panamensis ) and at 28°C for L. braziliensis (M5052; L. braziliensis braziliensis ). Several observations are presented that the forms adapted at elevated temperature are amastigote-like. Morphologically, the amastigote-like organisms appear rounded to ovoid and are immotile and smaller than promastigotes; the flagellum of the amastigote-like forms does not extend beyond the flagellar pocket. In comparison, the promastigotes are very elongated, with a nucleus at mid-cell length and a very long flagellum. By electron microscopy, the short flagellum of the amastigote-like form is within a distended flagellar pocket; the 9 + 2 axonemal configuration is present but the paraxial rod is not observed. By contrast, the flagellum of the promastigote has a paraxial rod which extends from the axosome level. In addition, these amastigote-like forms of Leishmania are able to infect, to survive and to divide within the macrophage cell line J774.     

Flagellum retraction and axoneme depolymerisation during the transformation of flagellates to amoebae inPhysarum

Summary The transformation ofPhysarum polycephalum flagellates to myxamoebae is characterised by disappearance of the flagellum. This transition, from the flagellate to the myxamoeba was observed by phase contrast light microscopy and recorded by time lapse video photography to determine whether flagellates shed their flagella or they are absorbed within the cell. In addition, the kinetics of flagellum disappearance were also studied. Our observations indicate that the flagellum was absorbed within the cell; the process occurred within seconds. Flagellum resorbtion was preceded by typical morphological cell changes. The shape of the nucleus altered and its mobility within the cell decreased. It was not possible to observe the flagellum within the cell with phase contrast video recordings. Thin section electron microscopy was used to study this intracellular phenomenon. Several stages of flagellum dissolution could be identified within the cell. The two most important stages were: an axoneme surrounded by the flagellar membrane within a plasma membrane lined pocket or vacuole and the naked axoneme without its membrane, free within the cell cytoplasm. The existence of cytoplasmic microtubules prevented identification of any further dissolution stages of the flagellum. A group of microtubules adjacent to the flagellum but within the cytoplasm was observed in flagellates and also in those cells which possesed enveloped axonemes. The flagellum did not dissociate from the kinetosomes before resorbtion.Immunofluorescence studies with the 6-11-B-1 monoclonal antibody indicated that acetylated microtubules exist in myxamoebae after transformation from flagellates for up to 40 min. Acetylated tubulin is not limited to the centrioles in these cells.     

Ultrastructure of spermatozoa of tench Tinca tinca observed by means of scanning and transmission electron microscopy

Structure of tench (Tinca tinca L.) spermatozoa was investigated by means of scanning electron microscopy (SEM) and transmission electron microscopy (TEM). Spermatozoa of 26.1+/-3.8 microm total length possessed typical primitive simple structure, called "aqua sperm", without acrosomal head structures. It was probably the smallest spermatozoon described among cyprinid fishes. Heads were mostly composed of dense and slightly granular material, which appeared to be fairly homogeneous except for the occasional appearance of vacuoles. The midpiece remained separated from the flagellum by the cytoplasmic channel; it was cylindric/cone-shaped, 0.86+/-0.27 microm in length and 1.17+/-0.24 microm in width at proximal part. The proximal centriole was located in the "implantation fossa". The distal centriole appeared almost tangential to the nucleus and it functioned as a basal body for the flagellum. It had an orientation of 140 degrees with respect to the distal centriole. The sperm flagellum with 25.45+/-2.47 microm of total length had no any fin. The diameter of the flagellum perpendicular to the plane of the doublet of central microtubules was 173.67+/-20.45 nm and horizontal plane of the central microtubules was 200.71+/-20.45 nm. Peripheral doublets and the central doublet of microtubules measured 23.39+/-3.18 and 35.88+/-4.44 nm in width, respectively. The diameter of a microtubule was only 9.14+/-2.97 nm. A vesicle was attached to the most basal region of the flagellum and located just under plasma membrane of the flagellum.     

Organization of the Acrosome and Helical Structures in Sperm of the Aplysiid, Aplysia kurodai (Gastropoda, Opisthobranchia)

Spermiogenesis in the aplysiid, Aplysia kurodai (Gastropoda, Opisthobranchia) was studied by transmission electron microscopy, with special attention to acrosome formation and the helical organization of the nucleus and the other sperm components. In the early spermatid, the periphery of the nucleus differentiates into three characteristics parts. The first part is that electron-dense deposits accumulate on the outer nuclear envelope. This part is destined to be the anterior side of the sperm because a tiny acrosome is organized on its mid-region at the succeeding stage of spermiogenesis. The second part, in which electron-dense material attaches closely to the inner side of the nuclear envelope, is the presumptive posterior side. A centriolar fossa is formed in this part and the axoneme of the flagellum extends from the fossa. A number of lamellar vesicles derived from mitochondria assemble around the axoneme and form the flagellum complex. The third part is recognized by the chromatin which condenses locally along the inner nuclear envelope. During development of the spermatid, this part extends to form a spiral nucleus accompanied by chromatin condensation and formation of microtubular lamellae outside the extending nucleus.
Finally, in the mature sperm, a tiny, spherical acrosomal vesicle is detected at the apex. The slender nucleus, overlapping both the primary and secondary helices which are composed of different structural elements, winds around the flagellum axoneme.     

A study of the colourless flagellate Rhynchomonas nasuta (Stokes) Klebs

Investigation by light and electron microscopy was carried out using clonal material of Rhynchomonas isolated from freshwater. Parallels were found with Bodo species, but the formation of the proboscis seems to be unique. The latter is not a modification of the short flagellum, as had been previously supposed, but is completely separate from it. The occurrence of the organism in the wild is commented upon.     

Ultrastructure of spermatogenesis and spermatozoa of Cephalodasys maximus (Gastrotricha,Macrodasyida)

Summary Spermatogenesis and sperm ultrastructure of the macrodasyidan gastrotrich Cephalodasys maximus are described by means of transmission electron microscopy. The filiform sperm consists of an acrosomal accessory structure and an acrosomal vesicle, both being surrounded by spiralled material. The successive nuclear helix encloses the spiral-shaped mitochondrion and the axoneme of the flagellum is accompanied by dense strings, three helical elements and peripheral microtubules. During spermiogenesis the acrosomal accessory structure develops first and moves into a cell projection, where the spiral around this acrosomal rod forms. A nuclear section with condensed chromatin and one single fused large mitochondrion follow into the extension, becoming helical. A connecting clasp between nucleus and flagellum shortens to a cap-like structure. Parallel to the acrosomal and nuclear projection the flagellum develops where the spiralled elements and the basal plate form in succession, while the basal body shrinks.     

Extracellular cultivation and morphological characterization of amastigote-like forms of Leishmania panamensis and L. braziliensis

Two strains of the Leishmania braziliensis complex have been adapted to grow extracellularly at elevated temperature as amastigote-like forms in a cell-free medium. These parasites can be serially cultivated and maintained at 32 degrees C for L. panamensis (WR442; L. braziliensis panamensis) and at 28 degrees C for L. braziliensis (M5052; L. braziliensis braziliensis). Several observations are presented that the forms adapted at elevated temperature are amastigote-like. Morphologically, the amastigote-like organisms appear rounded to ovoid and are immotile and smaller than promastigotes; the flagellum of the amastigote-like forms does not extend beyond the flagellar pocket. In comparison, the promastigotes are very elongated, with a nucleus at mid-cell length and a very long flagellum. By electron microscopy, the short flagellum of the amastigote-like form is within a distended flagellar pocket; the 9 + 2 axonemal configuration is present but the paraxial rod is not observed. By contrast, the flagellum of the promastigote has a paraxial rod which extends from the axosome level. In addition, these amastigote-like forms of Leishmania are able to infect, to survive and to divide within the macrophage cell line J774.     

Flagella of a chrysophycean alga play an active role in prey capture and selection

Summary The flagella of the pigmented algaEpipyxis pulchra (Chrysophyceae) were observed with image enhanced video microscopy to play an active role in gathering, physically seizing and selecting prey prior to phagocytosis. Vegetative unicells of this sessile, freshwater species possess two structurally and functionally distinct flagella, both active in feeding. During prey gathering the long flagellum, which is adorned with stiff hairs, beats rapidly to direct a strong water current towards the cell while the short, smooth flagellum moves very little. When a potential food particle is drawn by the current to contact the flagellar surfaces, the long flagellum stops beating and positions itself, in concert with the short flagellum, to seize the prey between them. Both flagella then briefly rotate the prey before selecting or rejecting it. If rejected, the particle is discarded by the coordinated activity of both flagella. If selected as food, the prey is held in place until a complex collecting cup emanates out from a position near the basal bodies and engulfs it. The cup plus enclosed food particle, now a food vacuole, is then retracted back to the cell proper.     

Characterization of two sets of subpolar flagella in Bradyrhizobium japonicum

Bradyrhizobium japonicum is one of the soil bacteria that form nodules on soybean roots. The cell has two sets of flagellar systems, one thick flagellum and a few thin flagella, uniquely growing at subpolar positions. The thick flagellum appears to be semicoiled in morphology, and the thin flagella were in a tight-curly form as observed by dark-field microscopy. Flagellin genes were identified from the amino acid sequence of each flagellin. Flagellar genes for the thick flagellum are scattered into several clusters on the genome, while those genes for the thin flagellum are compactly organized in one cluster. Both types of flagella are powered by proton-driven motors. The swimming propulsion is supplied mainly by the thick flagellum. B. japonicum flagellar systems resemble the polar-lateral flagellar systems of Vibrio species but differ in several aspects.     

Structural study of the basal bodies of the flagella of Bacillus brevis var. G.-B. P+

The structural organisation of the flagellum basal body was studied in Bacillus brevis var. G.-B. P+ by electron microscopy. It was compared with that of Escherichia coli MS 1350. The basal body of a B. brevis flagellum contains, in addition to two pairs of rings on a rod, another ring-like structure (d = 13.6 nm, h = 4.3 nm) which we referred to as a "collar". The collar makes the basal body of B. brevis different from that of B. subtilis, another Gram-positive bacterium. The collar seems to fasten the flagellum of B. brevis to the cell wall. We have concluded that the basal body can differ not merely among bacterial systematic groups, but also among bacteria belonging to one and the same genus. The role of individual elements in the structure of the basal body of bacterial flagella is discussed.     

Ultrastructural aspects of spermatogenesis in Calyptogena pacifica Dall 1891 (Vesicomyidae; Bivalvia)

The process of spermatogenesis and spermatozoon morphology was characterized from a deep‐sea bivalve, Calyptogena pacifica (Vesicomyidae, Pliocardiinae), a member of the superfamily Glossoidea, using light and electron microscopy. Spermatogenesis in C. pacifica is generally similar to that in shallow‐water bivalves but, the development of spermatogenic cells in this species has also some distinguishing features. First proacrosomal vesicles are observed in early spermatocytes I. Although, early appearance of proacrosomal vesicles is well known for bivalves, in C. pacifica, these vesicles are associated with electron‐dense material, which is located outside the limiting membrane of the proacrosomal vesicles and disappears in late spermatids. Another feature of spermatogenesis in C. pacifica is the localization of the axoneme and flagellum development. Early spermatogenic cells lack typical flagellum, while in spermatogonia, spermatocytes, and early spermatids, the axoneme is observed in the cytoplasm. In late spermatids, the axoneme is located along the nucleus, and the flagellum is oriented anteriorly. During sperm maturation, the bent flagellum is transformed into the typical posteriorly oriented tail. Spermatozoa of C. pacifica are of ect‐aqua sperm type with a bullet‐like head of about 5.8 μm in length and 1.8 μm in width, consisting of a well‐developed dome‐shaped acrosomal complex, an elongated barrel‐shaped nucleus filled with granular chromatin, and a midpiece with mainly four rounded mitochondria. A comparative analysis has shown a number of common traits in C. pacifica and Neotrapezium sublaevigatum.     

Bizarre flagellum of thrips spermatozoa (Thysanoptera,Insecta)

The flagellum of the thysanopteran spermatozoon has been examined by electron microscopy and computer-aided image analysis. The flagellum consists of 27 microtubular elements that probably are formed as outgrowths from three separate basal bodies. Nine of the elements are normal microtubular doublets that carry dynein arms and nine are doublets without dynein arms. The remaining nine elements are microtubular singlets that apparently bear dynein arms and have the same appearance as A-subtubules of microtubular doublets. The 27 elements are arranged in a fixed pattern that consists of nine groups, each of which begins with a microtubular singlet and ends with an arm-less microtubular doublet. Computer-aided image analysis has shown that the A-subtubules of the doublets and the microtubular singlets have lumens with very similar patterns. The sperm tail is known to have some motility; it generates fast waves running along its length. The amalgamated axonemes hence act as a functional flagellum. The thysanopteran sperm tail is the only type of flagellum known to us that consists of microtubules in a highly asymmetric array.     

Flagellar attachment and detachment ofCrithidia fasciculata to the gut wall ofAnopheles gambiae

Summary Flagellar attachment to the cuticle lined fore and hindgut ofAnopheles gambiae has been studied. At an attachment site, the flagellar membrane follows the contour of the surface to which it is apposed. In the colon where there is little folding of the gut the flagellum is truncate but in regions where the cuticular lining is highly folded the tip of the flagellum is more variable in shape. Numerous filaments lying beneath the adhering membrane make attachment sites easy to recognise. Although haptomonads lying close to the gut possess a short flagellum, those cells which in heavy infections are separated from the gut wall by severalm develop a much longer organelle in order to reach the cuticular lining.The induction of flagellar detachment by the addition of distilled water begins with the appearance of membrane invaginations at the adhesion site. Some of these invaginations, which appear to take cuticular material with them, develop into vesicles. It appears that this process progressively reduces the area of adhesion so that when flagellar activity begins, detachment is easily effected.     

Interaction of the regulatory subunit of a type II cAMP-dependent protein kinase with mammalian sperm flagellum

We have reported previously (Horowitz, J. A., Toeg, H., and Orr, G. A. (1984) J. Biol. Chem. 259, 832-838) that most of the type II cAMP-dependent protein kinases in rat sperm are associated with the flagellum. We have now identified flagellar polypeptides which are capable of forming tight complexes with the regulatory subunit of type II cAMP-dependent protein kinase (RII). Flagellar RII-binding polypeptides were identified using an RII overlay/immunoblot procedure and had apparent subunit Mr of 120,000, 80,000, and 57,000 in rat and 120,000 and 57,000 in bovine flagella. RII is released from the flagellum by disulfide reducing agents, e.g. 1 mM dithiothreitol (DTT). Sodium dodecyl sulfate-polyacrylamide gel electrophoresis and Coomassie Blue staining of the DTT-released material shows that a limited subpopulation of flagellar polypeptides are solubilized by disulfide-reducing agents. Neither tubulin, the dynein ATPase, or any of the RII-binding proteins are released by 1 mM DTT, and thin section electron microscopy revealed that the morphology of the flagellum is unaltered by reducing conditions. Our data established that RII is not linked to the flagellum via a direct disulfide bridge. We propose that RII is released from the flagellum, a highly disulfide cross-linked structure, due to structural changes in the flagellum which disrupts the interaction between RII and its binding proteins.