Ultrastructure of two types of first-generation merozoites of Eimeria bovis

Eimeria bovis has two types of first-generation merozoites with distinct ultrastructural characteristics. Type I merozoites were relatively large (means = 13.2 x 1.5 micron) and crescent-shaped, contained numerous micronemes and amylopectin granules, had a posteriorly located nucleus and a conical-shaped posterior tip, and were highly motile and capable of penetrating cultured cells. Type II merozoites were small (means = 5.9 x 0.9 micron) and spindle-shaped, had a centrally-located nucleus, few micronemes, few or no amylopectin granules, a dome-shaped posterior tip and little motility, and appeared to be incapable of penetrating cultured cells. It is possible that these two types of merozoites have considerably different roles in the life cycle of E. bovis.     

Ultrastructure of Two Types of First-Generation Merozoites of Eimeria bovis1

Eimeria bovis has two types of first-generation merozoites with distinct ultrastructural characteristics. Type I merozoites were relatively large (X = 13.2 times 1.5 μm) and crescent-shaped, contained numerous micronemes and amylopectin granules, had a posteriorly located nucleus and a conical-shaped posterior tip, and were highly motile and capable of penetrating cultured cells. Type II merozoites were small (X = 5.9 times 0.9 μm) and spindle-shaped, had a centrally-located nucleus, few micronemes, few or no amylopectin granules, a dome-shaped posterior tip and little motility, and appeared to be incapable of penetrating cultured cells. It is possible that these two types of merozoites have considerably different roles in the life cycle of E. bovis.     

Neural progenitor diversity and their therapeutic potential for spinal cord repair

Development of the central nervous system (CNS) requires progressive differentiation of neural stem cells, which generate a variety of neural progenitors with distinct properties and differentiation potentials in a spatiotemporally restricted manner. The underlying mechanisms of neural progenitor diversification during development started to be unraveled over the past years. We have addressed these questions by v-myc immortalization method and generation of neural progenitor clones. These clones are served as in vitro models of neural differentiation and cellular tools for transplantation in animal models of neurological disorders including spinal cord injury. In this review, we will discuss features of two neural progenitor types (radial glia and GABAergic interneuron progenitor) and diversification even within each progenitor type. We will also discuss pathophysiology of spinal cord injury and our ongoing research to address both motor and sensory malfunctions by transplantation of these neural progenitors.     

Morphological analysis of honeybee antennal cells growing in primary cultures

A culture technique for the in vitro growth of antennal cells from honeybee is described. On the basis of morphological and immunocytochemical criteria, the cultured cells could be classified into neural and non-neural cells. Neural cells (type D) exhibited the main morphological features of insect olfactory receptor neurones (ORNs). Non-neural cells were large, flat cells that could be divided into three main types: Type A, B and C cells. Type A cells were spindle-like cells and resembled insect myocytes in culture. Type B cells were large cells with a veil-like cytoplasm. These cells tended to group and vacuolate towards the center of the cellular aggregate. Type C cells were either bipolar (Type C1) or multipolar (Type C2) flat cells which closely resembled insect glial cells in cultures.     

Chromaffinity, uranaffinity and argentaffinity of small granule-containing (SGC) cells in rat superior cervical ganglia.

A systemic examination on the small granule-containing (SGC) cells in rat superior cervical ganglia was conducted by conventional and cytochemical electron microscopy including chromaffin, argentaffin and uranaffin reactions. According to the fine structure of dense cored vesicles (DCVs) in the cytoplasm, three types of small granule-containing (SGC) cells were revealed--Type I: 90-160 nm vesicles with cores of moderate or low electron density; Type II: 130-330 nm vesicles, polymorphic with highly electron dense cores; Type III: elongated vesicles (170 nm x 60 nm) with cores of moderate to low electron density. The majority of SGC cells were the Type I cells (78%) and Type II and III cells made up 13% and 9% of SGC cell population, respectively. Cytochemical results demonstrated that only the Type II cells displayed a positive chromaffin reaction and all three types of SGC cells showed argentaffinity and uranaffinity. The present study is the first to demonstrate the argentaffin reaction at ultrastructural level in SGC cells of sympathetic ganglia. Based on the results of the present study we also concluded that (1) the DCVs of Type II SGC cells contained noradrenaline and (2) biogenic amines and nucleotides (ATPs) coexisted in the DCVs of all three types of SGC cells.     

Tissues formed during distraction osteogenesis in the rabbit are determined by the distraction rate: localization of the cells that express the mRNAs and the distribution of types I and II collagens

An experimental model of leg lengthening was used to study the morphology of, the collagenous proteins present, and the collagen genes expressed in the regenerating tissue following 20% lengthening at four different distraction rates. At a distraction rate of 0.3 mm/day (8 weeks distraction), the regenerate consists of intramembranous bone and localized areas of fibrocartilage. At rates of 0.7 (4 weeks) and 1.3 mm/day (2 weeks), the bone that grows from the cut ends of the cortical bone is separated by fibrous tissue and cartilage is present. At 2.7 mm/day (1 week), only fibrous tissue and sparse bone are present. Type I collagen is present in the matrices around the cells expressing its mRNA and similarly, type II collagen is located around the chondrocytes. Type I collagen mRNA is expressed predominantly by the fibroblasts in the fibrous tissue, the bone surface cells and to a reduced extent by the osteocytes. Type II collagen mRNA is expressed by chondrocytes. The results suggest that osteoblasts and chondrocytes within the regenerate originate from the same pool of progenitor cells, and the differentiation of these cells and the expression of types I and II collagen genes are altered by different rates of distraction. These observations suggest that the optimal rate of distraction in the model is 0.7 mm/day.     

The candidate sour taste receptor, PKD2L1, is expressed by type III taste cells in the mouse

The transient receptor potential channel, PKD2L1, is reported to be a candidate receptor for sour taste based on molecular biological and functional studies. Here, we investigated the expression pattern of PKD2L1-immunoreactivity (IR) in taste buds of the mouse. PKD2L1-IR is present in a few elongate cells in each taste bud as reported previously. The PKD2L1-expressing cells are different from those expressing PLCbeta2, a marker of Type II cells. Likewise PKD2L1-immunoreactive taste cells do not express ecto-ATPase which marks Type I cells. The PKD2L1-positive cells are immunoreactive for neural cell adhesion molecule, serotonin, PGP-9.5 (ubiquitin carboxy-terminal transferase), and chromogranin A, all of which are present in Type III taste cells. At the ultrastructural level, PKD2L1-immunoreactive cells form synapses onto afferent nerve fibers, another feature of Type III taste cells. These results are consistent with the idea that different taste cells in each taste bud perform distinct functions. We suggest that Type III cells are necessary for transduction and/or transmission of information about "sour", but have little or no role in transmission of taste information of other taste qualities.     

Localization of neonatal secretory proteins in different cell types of the rat submandibular gland from embryogenesis to adulthood

In the neonatal rat submandibular gland, Type III cells contain a group of related proteins that we call the B1-immunoreactive proteins (B1-IP; 23.5, 26, and 27.5 kDa). Type I cells lack these, but synthesize a different protein, Protein C (89 kDa). With maturation of the gland, these neonatal cell types are no longer seen in the seromucous acini, which are no longer reactive for the B1-IP. Here, we report the ultrastructural immunocytochemical localization of the B1-IP and Protein C over the course of development. From their first appearance in the embryo, the B1-IP and Protein C are present in different cells which become morphologically typical Type I and III cells prior to birth. At all stages, Type I cells have strong Protein C labeling and no B1 labeling. By 3 days postpartum, ultrastructurally atypical Type III cells are seen (Type IIIP); these label for the B1-IP, but also show labeling with antibody to Protein C. In the next week, as mucous cells appear in the acini, these show both B1-IP and C labeling; the B1 marker is lost by 30 days postpartum, but adult mucous acinar cells continue to show Protein C reactivity. In view of the appearance of Protein C reactivity in neonatal Type IIIP and then in mucous cells, and the presence of B1 reactivity in early but not mature mucous cells, we suggest that Type III cells differentiate into mucous cells and that Type IIIP cells are intermediates in this transformation. We see no evidence for the differentiation of either Type III or mucous cells from Type I cells, although our data cannot rule out this possibility. In adult glands, cells with B1 labeling are seen in intercalated ducts. Cells that appear to be Type I cells are also present in these ducts and label for Protein C. Double labeling for B1-IP and Protein C demonstrated that the two markers were exclusively present in different cells within intercalated ducts. This is of considerable interest, as intercalated ducts have been reported to be the stem cell population for normal and trauma-induced cellular replacement.     

Intestinal Ultrastructure of Nerita picea (Mollusca: Gastropoda), an Intertidal Marine Snail of Hawaii

The neritid snail Nerita picea is a marine prosobranch mollusc which resides high in the intertidal zone on the Hawaiian Islands. Since other studies have shown considerable variations in molluscan gut histology and the relatively few recent ultrastructural reports have revealed novel cellular structures in the molluscan gastrointestinal tract, this investigation was directed toward ultrastructural clarification of the neritid intestine. Seven principal cell types constituted the intestinal architecture, including absorptive cells, zymogen cells, neural and endocrine cells, myocytes, pigment and gland cells. The intestinal epithelium was composed mainly of tall ciliated (9 plus 2 complement of microtubules) columnar absorptive cells which also possessed microvilli, extensive deposits of non-membrane-bound lipid-like droplets, and large reservoirs of glycogen-like granules. Less frequent, columnar zymogen cells contained numerous large zymogen secretory granules and possessed microvilli but not cilia. Small endocrine-like cells with secretory granules were observed basolaterally between some absorptive cells, resembling mammalian gut endocrine cells. Nerve fibers were prevalent in close association with the epithelial cells. A thin layer of non-striated muscle was present, as well as a serosally located gland composed of storage cells with a granular matrix and large granules.     

Nestin-positive spheres derived from canine bone marrow stromal cells generate cells with early neuronal and glial phenotypic characteristics

Bone marrow stromal cells (BMSCs) isolated from humans and rodents have been shown to generate neural cells under specific culture conditions and after transplantation in the central nervous system. The apparent plasticity of BMSCs has therefore been a target of intensive research in attempt to develop a novel therapy for neurological diseases. Canines sustain neurological disorders (e.g., traumatic spinal cord injury) that closely mirror pathology of those in humans. Therefore, we evaluated neural differentiation properties of canine BMSCs to provide insights into basic characterization of these cells for future neurotransplantation trials in canine patients with neurological disorders. We demonstrate that canine BMSCs form spherical cellular aggregates on anti-adhesive culture substrate in serum-free culture media, which morphologically and phenotypically resemble spherical aggregates of neural progenitor cells, so-called neurospheres. Upon dissociation and subculture on adhesive substrate, canine BMSCs express neuronal (ss capital SHA, Cyrillic-tubulin) and glial (GFAP, A2B5, and CNPase) markers. Formation of spherical aggregates appears to be a critical preceding process for some of the glial marker expression (CNPase and A2B5). However, expression of more mature neuronal (MAP2) and glial (MBP) markers could not be induced with the protocol used in this study. We suggest that induction of canine BMSCs into cells with neural progenitor cell characteristics is possible and that these cells may have the potential for future cellular therapy for neurological disorders.     

Cell dynamics during cocoon secretion in the aquatic leech, Theromyzon tessulatum (Annelida: Clitellata: Glossiphoniidae)

One distinguishing feature of clitellate annelids is the presence of specialized segments comprising the clitellum, whose primary function is to secrete a cocoon. Using histological analyses, we have documented cell types (I-V) and cellular processes associated with cocoon secretion in the aquatic leech, Theromyzon tessulatum. Our data indicate that the bulk of the cocoon's biomass arises from precursor cells of a single type that hypertrophy and proliferate ∼1 week prior to egg laying, and then differentiate into either of two cell types (i.e., Type II or Type III) depending on their position within the clitellum. Type II cells are concentrated along the lateral edges and venter of the clitellum and secrete alcian blue-staining granules that form opercula (i.e., glue-like material that seals both cocoon ends), while Type III cells populate the dorsal midline and secrete azocarmine-staining granules that build the cocoon wall. Both cell types occupy spaces between deep muscle layers and extend long-neck tubules to the surface epithelium as they fill with granules a few days prior to egg laying. Other cell types appear to make minor contributions to the cocoon (e.g., Type I, Type IV) or have supporting or signaling roles (e.g., Type V). Our observations suggest that post-translational modification (i.e., glycosylation) of the same core protein(s) distinguishes the granules of Type II/III cells, and that the default state of the Type II/III precursor may be evolutionarily linked to secretory cells in basal polychaetes.     

Neurotransmitters as early signals for central nervous system development

During brain ontogenesis, the temporal and spatial generation of the different types of neuronal and glial cells from precursors occurs as a sequence of successive progenitor stages whose proliferation, survival and cell-fate choice are controlled by environmental and cellular regulatory molecules. Neurotransmitters belong to the chemical microenvironment of neural cells, even at the earliest stages of brain development. It is now established that specific neurotransmitter receptors are present on progenitor cells of the developing central nervous system and could play, during neural development, a role that has remained unsuspected until recently. The present review focuses on the occurrence of neurotransmitters and their corresponding ligand-gated ion channel receptors in immature cells, including neural stem cells of specific embryonic and neonatal brain regions. We summarize in vitro and in vivo data arguing that neurotransmitters could regulate morphogenetic events such as proliferation, growth, migration, differentiation and survival of neural precursor cells. The understanding of neurotransmitter function during early neural maturation could lead to the development of pharmacological tools aimed at improving adult brain repair strategies.     

Primary cilia in gastric Gastrointestinal Stromal Tumours (GISTs): an ultrastructural study

Gastrointestinal stromal tumours (GISTs) are the most common mesenchymal (non‐epithelial) neoplasms of the human gastrointestinal (GI) tract. They are thought to derive from interstitial cells of Cajal (ICCs) or an ICC progenitor based on immunophenotypical and ultrastructural similarities. Because ICCs show primary cilium, our hypothesis is based on the possibility that some of these neoplastic cells could also present it. To determine this, an exhaustive ultrastructural study has been developed on four gastric GISTs. Previous studies had demonstrated considerable variability in tumour cells with two dominating phenotypes, spindly and epithelioid. In addition to these two types, we have found another cell type reminiscent of adult ICCs with a voluminous nucleus surrounded by narrow perinuclear cytoplasm with long slender cytoplasmic processes. We have also noted the presence of small undifferentiated cells. In this study, we report for the first time the presence of primary cilia (PCs) in spindle and epithelioid tumour cells, an ultrastructural feature we consider of special interest that has hitherto been ignored in the literature dealing with the ultrastructure of GISTs. We also point out the frequent occurrence of multivesicular bodies (MVBs). The ultrastructural findings described in gastric GISTs in this study appear to be relevant considering the critical roles played by PCs and MVBs recently demonstrated in tumourigenic processes.     

Adult human brain neural progenitor cells (NPCs) and fibroblast-like cells have similar properties in vitro but only NPCs differentiate into neurons

The ability to culture neural progenitor cells from the adult human brain has provided an exciting opportunity to develop and test potential therapies on adult human brain cells. To achieve a reliable and reproducible adult human neural progenitor cell (AhNPC) culture system for this purpose, this study fully characterized the cellular composition of the AhNPC cultures, as well as the possible changes to this in vitro system over prolonged culture periods. We isolated cells from the neurogenic subventricular zone/hippocampus (SVZ/HP) of the adult human brain and found a heterogeneous culture population comprised of several types of post-mitotic brain cells (neurons, astrocytes, and microglia), and more importantly, two distinct mitotic cell populations; the AhNPCs, and the fibroblast-like cells (FbCs). These two populations can easily be mistaken for a single population of AhNPCs, as they both proliferate under AhNPC culture conditions, form spheres and express neural progenitor cell and early neuronal markers, all of which are characteristics of AhNPCs in vitro. However, despite these similarities under proliferating conditions, under neuronal differentiation conditions, only the AhNPCs differentiated into functional neurons and glia. Furthermore, AhNPCs showed limited proliferative capacity that resulted in their depletion from culture by 5-6 passages, while the FbCs, which appear to be from a neurovascular origin, displayed a greater proliferative capacity and dominated the long-term cultures. This gradual change in cellular composition resulted in a progressive decline in neurogenic potential without the apparent loss of self-renewal in our cultures. These results demonstrate that while AhNPCs and FbCs behave similarly under proliferative conditions, they are two different cell populations. This information is vital for the interpretation and reproducibility of AhNPC experiments and suggests an ideal time frame for conducting AhNPC-based experiments.     

Cell populations in the pineal gland of the viscacha (Lagostomus maximus). Seasonal variations

Pineal samples of the viscacha, which were taken in winter and in summer, were analysed using both light and electron microscopy. The differences found between the two seasons were few in number but significant. The parenchyma showed two main cell populations. Type I cells occupied the largest volume of the pineal and showed the characteristics of typical pinealocytes. Many processes, some of which were filled with vesicles, could be seen in intimate contact with the neighbouring cells. The presence in the winter samples of "synaptic" ribbons and spherules, which were almost absent in the summer pineals, suggests a seasonal rhythm. These synaptic-like structures, as well as the abundant subsurface cisterns present in type I cells, appeared as basic differential features which allowed these cells to be distinguished from type II cells. These latter cells, which can be classified as interstitial cells, showed some other distinguishing features, such as irregular-shaped nuclei, abundant deposits of glycogen-like particles and structures of unknown function consisting of concentric cisterns surrounding a dense body. In the summer, interstitial cells displayed numerous large round bodies, which contributed to increase the cellular volume slightly. Regarding other constituents, like glial cell processes, vessels of non-fenestrated endothelium and sympathetic innervation, no qualitative differences were observed between the two seasons studied. We have presented here some morphological evidences of the circannual rhythm of the viscacha pineal, as well as ultrastructural criteria for distinguishing the main cell populations of this organ, which could be useful for studies carried out in other mammals.     

Neural organization of the lamina neuropil of the larva of the tiger beetle (Cicindela chinensis)

Six neural elements, viz., retinular axons, a giant monopolar axon, straight descending processes (type I), lamina monopolar axons (type II), processes containing clusters of dense-core vesicles (type III), and processes coursing in various directions with varicosities (type IV), have been identified at the ultrastructural level in the lamina neuropil of the larval tiger beetle Cicindela chinensis. Retinular axons make presynaptic contact with all other types of processes. Type I and II processes possess many pre-and postsynaptic loci. Type II processes presumably constitute retinotopic afferent pathways. It remains uncertain whether type I processes are lamina monopolar axons or long retinular axons extending to the medullar neuropil. Type III processes may be efferent neurons or branches of afferent neurons contributing to local circuits. A giant monopolar axon extends many branches throughout the lamina neuropil; these branches are postsynaptic to retinular axons, and may be nonretinotopic and afferent. Type IV processes course obliquely in the neuropil, being postsynaptic to retinular axons, and presynaptic to type I processes.     

Transcriptional Profiling of Adult Neural Stem-Like Cells from the Human Brain

There is a great potential for the development of new cell replacement strategies based on adult human neural stem-like cells. However, little is known about the hierarchy of cells and the unique molecular properties of stem- and progenitor cells of the nervous system. Stem cells from the adult human brain can be propagated and expanded in vitro as free floating neurospheres that are capable of self-renewal and differentiation into all three cell types of the central nervous system. Here we report the first global gene expression study of adult human neural stem-like cells originating from five human subventricular zone biopsies (mean age 42, range 33–60). Compared to adult human brain tissue, we identified 1,189 genes that were significantly up- and down-regulated in adult human neural stem-like cells (1% false discovery rate). We found that adult human neural stem-like cells express stem cell markers and have reduced levels of markers that are typical of the mature cells in the nervous system. We report that the genes being highly expressed in adult human neural stem-like cells are associated with developmental processes and the extracellular region of the cell. The calcium signaling pathway and neuroactive ligand-receptor interactions are enriched among the most differentially regulated genes between adult human neural stem-like cells and adult human brain tissue. We confirmed the expression of 10 of the most up-regulated genes in adult human neural stem-like cells in an additional sample set that included adult human neural stem-like cells (n = 6), foetal human neural stem cells (n = 1) and human brain tissues (n = 12). The NGFR, SLITRK6 and KCNS3 receptors were further investigated by immunofluorescence and shown to be heterogeneously expressed in spheres. These receptors could potentially serve as new markers for the identification and characterisation of neural stem- and progenitor cells or as targets for manipulation of cellular fate.     

Three types of cutaneous glands in the skin of the salamandrid Pleurodeles waltl. A histological and ultrastructural study

Histological and ultrastructural investigations revealed three different multicellular skin gland types in the salamandrid Pleurodeles waltl. The mucous glands are small, with one layer of secretory cells surrounding a central lumen; they produce the viscous and slippery mucus film that has various functions in amphibians. The serous glands can be divided based on their histological and ultrastructural characters into the granular gland Type I (GGI) and the granular gland Type II (GGII). The first type (GGI) is moderately sized and distributed throughout the body surface, with higher concentrations in the parotoid and back regions. In contrast, the second type (GGII) is very large (for Pleurodeles) and was found only in the tail, with highest concentration in the tail dorsum. Both granular gland types contain mainly proteinaceous materials but differ in their morphological features including size, shape, cellular organization and vesicle distribution, vesicle size and vesicle shape. Both GGI and GGII are especially concentrated in body parts that are presented to an attacking predator and are hypothesized to produce repellent to poisonous substances to thwart potential aggressors. J. Morphol., 2009. © 2009 Wiley‐Liss, Inc.     

An ultrastructural study on gastric endocrine cells in the stomach gland patch of the koala Phascolarctos cinereus

The endocrine cells in the stomach gland patch of the koala (Phascolarctos cinereus) were studied ultrastructurally. They were classified into 3 types based on the ultrastructural profiles of their endocrine granules and tentatively categorized as type I, II, and III endocrine cells. Type I cells contained round granules that were for the most part larger than those observed in the other 2 cell types. The granules ranged from moderate to relatively high in electron density. Type II cells were angular in shape and characterized by the presence of granules that were polymorphous in profile. Contents of the endocrine granules in type II cells also showed a range of high to moderate electron density. Type III cells were oval or pyramidal in shape. They contained highly polymorphous granules that were round, oval, dumbbell-like or comma in shape and characterized by the presence of a clear space or halo separating the high to low electron-dense core from the limiting membrane of granules. Type III cells were observed most often whereas type I and II cells were a less frequent observation.