Haemolymph parasite of the shore crab Carcinus maenas: pathology, ultrastructure and observations on crustacean haplosporidians

A protozoan parasite with some features of haplosporidians is described from the European shore crab Carcinus maenas. The parasite establishes a systemic infection through the haemal sinuses and connective tissues. Intracellular stages of the parasite were found within reserve inclusion, connective tissue, and muscle cells, while free forms were present in all haemal spaces. A uninucleate stage appeared to develop to a multinucleate plasmodial stage following multiple mitotic divisions of the nucleus. Histopathology also indicated that nuclear division may occur to form multinucleate plasmodia, in connective tissue, reserve inclusion and muscle cells, the multinucleate plasmodium being enclosed in the host-cell plasma membrane. It appears that the multinucleate plasmodium may then undergo internal cleavages which result in plasmodial fragmentation to form many uninucleate stages. Both stages, but particularly the uninucleate stage, contained cytoplasmic, large, ovoid, dense vesicles (DVs), some of which contained an internal membrane separating the medulla from the cortex, as in haplosporosomes. Golgi-like cisternae, closely associated with the nuclear membrane, formed DVs and haplosporosome-like bodies (HLBs), superficially resembling viruses. Infrequently, HLBs may condense to form haplosporosomes. The DVs, as in spores of some Haplosporidium spp. and paramyxeans, may give rise to, and are homologous with, haplosporosomes. Other features, such as the presence of an intranuclear mitotic spindle, lipid droplets, and attachment of DVs and haplosporosomes to the nuclear membrane, indicate that the C. maenas parasite is a haplosporidian. A similar organism reported from the haemolymph of spot prawns Pandalus spp., and haplosporidians reported from prawns Penaeus vannamei and crabs Callinectes sapidus may belong to this group. It is concluded that the well-characterised haplosporidians of molluscs and some other invertebrates may not be characteristic of the whole phylum, and that morphologically and developmentally similar organisms may also be haplosporidians, whether they have haplosporosomes or not.     

Molecular analysis of a haplosporidian parasite from cultured New Zealand abalone Haliotis iris

In the Austral summer and autumn of 2000 and 2001, mortalities of black-footed abalone Haliotis iris (Martyn, 1784) occurred in a commercial facility in New Zealand. Histological analyses suggested that infection by a haplosporidian parasite was responsible. To confirm identification as a haplosporidian and to help determine if this parasite represented a new, undescribed species, DNA was extracted from infected host tissues scored as positive for infection by histological examination. Small-subunit rRNA (SSU rRNA) gene sequences from both the host abalone and a parasitic organism were amplified by PCR and characterized. Although the sequence for this parasite was novel, not matching any known SSU rRNA gene sequences, phylogenetic analyses strongly supported grouping this parasite with the haplosporidians. Parsimony analyses placed the parasite at the base of the phylum Haplosporidia, ancestral to Urosporidium crescens and the Haplosporidium, Bonamia, and Minchinia species. Sequencing of multiple parasite DNA clones revealed a single polymorphic site in the haplosporidian SSU rRNA gene sequence.     

Intracellular localization and endocytosis of brush border enzymes in the enterocyte-like cell line Caco-2.

Immunoelectron microscopy was used to localize the brush border hydrolases sucrase-isomaltase (SI) and dipeptidylpeptidase IV (DPPIV) in the human colon carcinoma cell line Caco-2. Both enzymes were detected at the microvillar membrane, in small vesicles and multivesicular bodies (MVBs), and in lysosomal bodies. In addition, DPPIV was found in the Golgi apparatus, a variety of apical vesicles and tubules, and at the basolateral membrane. To investigate whether the hydrolases present in the lysosomal bodies were endocytosed from the apical membrane, endocytic compartments were marked with the endocytic tracer cationized ferritin (CF). After internalization from the apical membrane through coated pits, CF was first recovered in apical vesicles and tubules, and larger electronlucent vesicles (early endosomes), and later accumulated in MVBs (late endosomes) and lysosomal bodies. DPPIV was localized in a subpopulation of both early and late endocytic vesicles, which contained CF after 3 and 15 min of uptake, respectively. Also, internalization of the specific antibody against DPPIV and gold labeling on cryosections showed endocytosed DPPIV in both early and late endosomes. However, unlike CF, no accumulation of DPPIV was seen in MVBs or lysosomal bodies after longer chase times. The results indicate that in Caco-2 cells the majority of brush border hydrolases present in lysosomal bodies are not endocytosed from the brush border membrane. Furthermore, the labeling patterns obtained, suggest that late endosomes may be involved in the recycling of endocytosed DPPIV to the microvilli.     

Isolation and characterization of multivesicular bodies from rat hepatocytes: an organelle distinct from secretory vesicles of the Golgi apparatus

Hepatocytes of estradiol-treated rats, which express many low density lipoprotein receptors, rapidly accumulate intravenously injected low density lipoprotein in multivesicular bodies (MVBs). We have isolated MVBs and Golgi apparatus fractions from livers of estradiol-treated rats. MVB fractions were composed mainly of large vesicles, approximately 0.55 micron diam, filled with remnantlike very low density lipoproteins, known to be taken up into hepatocytes by receptor- mediated endocytosis. MVBs also contained numerous small vesicles, 0.05- 0.07 micron in diameter, and had two types of appendages: one fingerlike and electron dense and the other saclike and electron lucent. MVBs contained little galactosyltransferase or arylsulfatase activity, and content lipoproteins were largely intact. Very low density lipoproteins from Golgi fractions, which are derived to a large extent from secretory vesicles, were larger than those of MVB fractions and contained newly synthesized triglycerides. Membranes of MVBs contained much more cholesterol and less protein than did Golgi membranes. We conclude that two distinct lipoprotein-filled organelles are located in the bile canalicular pole of hepatocytes. MVBs, a major prelysosomal organelle of low density in the endocytic pathway, contain remnants of triglyceride-rich lipoproteins, whereas secretory vesicles of the Golgi apparatus contain nascent very low density lipoproteins.     

Detection of 'Candidatus Xenohaliotis californiensis' (Rickettsiales-like prokaryote) inclusions in tissue squashes of abalone (Haliotis spp.) gastrointestinal epithelium using a nucleic acid fluorochrome.

Rickettsiales-like prokaryotes appear to be etiologic agents of a number of newly described diseases of fish and shellfish. 'Candidatus Xenohaliotis californiensis' is a Rickettsiales-like prokaryote responsible for withering syndrome, a fatal disease of wild and farmed Eastern Pacific abalone, Haliotis spp. The bacterium proliferates in gastrointestinal epithelial cells, forming large intracytoplasmic inclusions. We describe a method of rapidly detecting and assessing the intensity of 'Candidatus Xenohaliotis californiensis' infections in abalone gastrointestinal tissue using the nucleic acid-specific fluorochrome Hoechst 33258. In excised tissue pieces dried onto slides, rehydrated in the Hoechst stain and viewed with ultraviolet light, the large bacterial inclusions were strongly fluorescent and could be easily distinguished from smaller host cell nuclei. This provided a rapid, inexpensive alternative to paraffin section microscopy or molecular techniques, allowing detection of the pathogen within minutes of tissue excision. Comparison of the fluorochrome method with conventional histological analysis for the ability to detect inclusions in 109 samples was 90% accurate, with discrepancies due to false negative diagnosis of low-level infections. An alternative nucleic acid-specific fluorochrome, propidium iodide, showed a staining pattern identical to that of Hoechst 33258. These methods should prove useful for the rapid detection of inclusion-forming Rickettsiales-like prokaryotes in tissues from many host species.     

Multivesicular bodies isolated from rat hepatocytes. Cytochemical evidence for transformation into secondary lysosomes by fusion with primary lysosomes

Plasma lipoproteins (and other ligands) are endocytosed by hepatocytes and appear in multivesicular bodies (MVBs) in the Golgi-lysosome region of the cell prior to their degradation. We have isolated MVB fractions from livers of estradiol-treated rats, permitting studies of their properties (Hornick et al. 1985). Here we report our cytochemical studies of lysosomal enzyme activity in partially and highly purified MVB fractions and in MVBs in hepatocytes in situ. Only about 15% of partially or highly purified MVBs were positive for acid phosphatase and arylsulfatase, consistent with the prelysosomal nature of this compartment. Partially purified MVB fractions contained small round vesicles, 70-120 nm in diameter, which stained intensely for these enzymes; occasionally these vesicles appeared to fuse with MVBs, suggesting that these structures are primary lysosomes. Such stained vesicles were rarely seen in highly purified MVB preparations. Acid phosphatase reaction product with cerium as capture reagent appeared as uniform precipitates surrounding endocytosed plasma lipoproteins in positively stained MVBs. Arylsulfatase reaction product, however, appeared as distinctive arc or plaque-like deposits just inside the MVB-limiting membrane, often in continuity with intense reaction product contained in a fusing primary lysosome. Similar putative primary lysosomes were occasionally observed in isolated, "intact" Golgi fractions from the same livers. Similar histochemical reactivities of MVBs and putative primary lysosomes were observed in thin sections of hepatocytes in situ. These observations support the conclusion that, in hepatocytes, MVBs represent the immediate prelysosomal compartment in the endocytic pathway of macromolecular catabolism, and suggest that MVBs are converted to secondary lysosomes by direct fusion with primary lysosomes arising from closely adjacent Golgi compartments.     

Cytochemical analysis of the haplosporosomes and vesicle-like droplets of Haplosporidium lusitanicum (Haplosporida,Haplosporidiidae), parasite of Helcion pellucidus (Prosobranchia)

A cytochemical study of the spore of Haplosporidium lusitanicum, a haplosporidian parasite recently found in Helcion pellucidus, is described. Cytochemical analysis with Sudan Black B at the light microscope level revealed that the vesicle-like droplets (VLD) situated in the apical and basal zones of the endosporoplasm in close contact with the external membrane is strongly stained dark blue. These structures are partially digested with lipase. Both reactions suggest the presence of lipoid components. The dense bodies of the exosporoplasm seem to be analogous in chemical composition. On the other hand, these two distinct structures, when subjected to Thiéry's test for glycoproteins, gave positive results. We think that these materials are complex structures simultaneously containing lipids and glycoproteins. They may be involved in the formation of the complex membranous system (“spherule”) that develops during spore maturation in this species. The matrix of haplosporosomes submitted to Thiéry's test for glycoproteins was also positive. A comparative cytochemical analysis has revealed that the external membrane of the haplosporosomes is more glycoproteinaceous than the internal one, which is more lipoidal.     

Protoplasts as tools in cell biology

Studies of plant protoplasts using both fluorescent dyes and electron dense probes have demonstrated endocytosis in plants. Ultrastructural work with soybean protoplasts using cationized ferritin (CF) revealed an endocytotic pathway from coated pits at the plasma membrane to coated vesicles, the partially coated reticulum, Golgi bodies, multivesicular bodies and finally the vacuole. Endocytosis may be responsible for membrane retrieval from the cell surface or degradation of elicitors or toxins during host-pathogen interactions. Immunofluorescence studies of dividing plant protoplasts have provided new information about the preprophase band (PPB) of microtubules and the shape of spindles. Studies of PPBs in soybean protoplast cultures permitted detailed examination of PPB development and an assessment of the usefulness of the PPB index for identifying morphogenic cultures. In multinucleate protoplasts the size and number of PPBs were apparently not controlled by nuclear number. Research with conifer protoplasts resulted in the discovery of new features of gymnosperm spindles.     

Recent advances in the study of plant coated vesicles

Coated vesicles are organelles common in plant cells. They are associated with the plasma membrane, Golgi apparatus, partially coated reticulum and multivesiclular bodies. In this paper we discuss recent developments in the use of immunochemistry and cytochemistry to investigate the structure and function of plant coated vesicles.     

Multivesicular bodies in developing tobacco seed and mung bean are functionally equivalent

Protein storage vacuoles (PSVs) are the primarily storage organelles in cotyledon cells for protein preservation in seeds. Storage proteins are transported from the endoplasmic reticulum (ER) to the Golgi apparatus for subsequent delivery to PSVs via presumably Golgi-derived dense vesicles (DVs). However, recent studies demonstrated that storage proteins in early stage of developing cotyledon of mung beans reached the multivesicular bodies (MVBs) prior to the detection of DVs, indicating the possible involvement of MVBs in mediating transport of storage proteins during the early stage of seed development. Here, we further show that the MVBs in developing tobacco seeds are functionally and biochemically equivalent to those in developing mung beans. Thus, MVBs in developing tobacco seeds are structurally distinct from DVs, contain both vacuolar sorting receptors (VSRs) and storage proteins, and they are insensitive to treatments of wortmannin and brefeldin A (BFA).     

Internalization of horseradish peroxidase isozymes by pancreatic acinar cells in vitro

We examined the uptake and fate of four horseradish peroxidase (HRP) isozymes (Type VI, VII, VIII, and IX) in isolated pancreatic acinar cells. The pattern of uptake was similar for all the isozymes examined, with the exception of Type IX. Very little Type IX HRP was internalized by the cells, and what endocytosis did occur was primarily from the apical cell surface in coated vesicles. In contrast, HRP Type VI, VII, and VIII appeared to be endocytosed largely at the basolateral cell surface. Initially, the tracer was found in smooth vesicles and tubules near the plasma membrane. The tubules resembled the basal lysosomes known to be present in these cells. At the early time points, HRP reaction product was also present in multivesicular bodies (MVBs). By 60 min, the HRP was localized in MVBs, vesicles, and tubules adjacent to the Golgi apparatus. By 12 hr after exposure to the isozymes, the tracer was present in small apical vesicles. At no time could reaction product be localized in the rough endoplasmic reticulum, Golgi saccules, or secretory granules. The results of this study suggest that the charge of a soluble-phase marker has little effect on its uptake or intracellular distribution.     

Ultrastructural description of new Rickettsia-like organisms in the commercial abalone Haliotis tuberculata (Gastropoda: Haliotidae) from the NW of Spain

Rickettsia-like organisms (RLOs) were found in the commercially farmed abalone Haliotis tuberculata in the northwestern region of the Atlantic Coast of Spain and are described from light and transmission electron microscopy observations. The RLOs measured approximately 1.6 x 0.9 microm and were found in intracytoplasmic, spherical to ellipsoidal vacuoles (up to 8 microm) in the epithelial cells of the digestive diverticulae. The morphological ultrastructure of these organisms was typically prokaryotic, including a plasmalemma and a thin Gram-negative type cell wall. Several ultrastructural changes were observed in the epithelial cells of the host containing the RLOs. The nuclei became pycnotic and several basophilic dense inclusions appeared in the cytoplasm. In addition, the host cell appeared lysed and was ruptured in advanced stages of infection. It was impossible to ascertain whether the RLOs are responsible for this disease, as a haplosporidian infection was also present. We can only conclude that the presence of RLOs simultaneously with a haplosporidian parasite may contribute to the mortality of the abalone host.     

Human herpesvirus-6 induces MVB formation, and virus egress occurs by an exosomal release pathway

The final envelopment of most herpesviruses occurs at Golgi or post-Golgi compartments, such as the trans Golgi network (TGN); however, the final envelopment site of human herpesvirus 6 (HHV-6) is uncertain. In this study, we found novel pathways for HHV-6 assembly and release from T cells that differed, in part, from those of alphaherpesviruses. Electron microscopy showed that late in infection, HHV-6-infected cells were larger than uninfected cells and contained many newly formed multivesicular body (MVB)-like compartments that included small vesicles. These MVBs surrounded the Golgi apparatus. Mature virions were found in the MVBs and MVB fusion with plasma membrane, and the release of mature virions together with small vesicles was observed at the cell surface. Immunoelectron microscopy demonstrated that the MVBs contained CD63, an MVB/late endosome marker, and HHV-6 envelope glycoproteins. The viral glycoproteins also localized to internal vesicles in the MVBs and to secreted vesicles (exosomes). Furthermore, we found virus budding at TGN-associated membranes, which expressed CD63, adaptor protein (AP-1) and TGN46, and CD63 incorporation into virions. Our findings suggest that mature HHV-6 virions are released together with internal vesicles through MVBs by the cellular exosomal pathway. This scenario has significant implications for understanding HHV-6's maturation pathway.     

Endocytosis in the rat retinal pigment epithelium

Endocytosis in the retinal pigment epithelium (RPE) of rats was studied using horseradish peroxidase, microperoxidase and ferritin tracers. Tracer uptake was mediated by coated pits and coated vesicles. Coated pits formed at two discrete regions at the RPE plasma membrane: that portion of basal membrane directly opposing Bruch's membrane, and at the bases of the apical lamellae and villi. Two populations of coated vesicles were identified and distinguished by size, location and function. Large coated vesicles (91.8 +/- 14.7 nm in diameter) were located near the cell surface and incorporated tracer. Small coated vesicles (64.5 +/- 15.7 nm diameter) located more deeply within the cell were not tracer-labeled, and were often fused with the endoplasmic reticulum or the Golgi apparatus. Observations of the endocytic pathway in rat RPE cells are presented. Tracer was also found in organelles of the lysosomal system, e.g. the multivesicular body, but was not identified in the smooth endoplasmic reticulum or Golgi apparatus.     

Immunoelectron microscopic localization of cholesterol using biotinylated and non-cytolytic perfringolysin O.

We used a proteolytically modified and biotinylated derivative of the cholesterol-binding Theta-toxin (perfringolysin O) to localize cholesterol-rich membranes in cryosections of cultured human lymphoblastoid cells (RN) by electron microscopy. We developed a fixation and immunolabeling procedure to improve the preservation of membranes and minimize the extraction and dislocalization of cholesterol on thin sections. We also labeled the surface of living cells and applied high-pressure freezing and subsequent fixation of cryosections during thawing. Cholesterol labeling was found at the plasma membrane, with strongest labeling on filopodium-like processes. Strong labeling was also associated with internal vesicles of multivesicular bodies (MVBs) and similar vesicles at the cell surface after secretion (exosomes). Tubulovesicular elements in close vicinity of endosomes and the Golgi complex were often positive as well, but the surrounding membrane of MVBs and the Golgi cisternae appeared mostly negative. Treatment of cells with methyl-beta-cyclodextrin completely abolished the labeling for cholesterol. Our results show that the Theta-toxin derivative, when used in combination with improved fixation and high-pressure freezing, represents a useful tool for the localization of membrane cholesterol in ultrathin cryosections.     

Multivesicular bodies in the transitional epithelium of the neonatal mouse urinary border.

The origin of late endosomes - multivesicular bodies (MVBs) in the superficial cells of 16 and 17 embryonic old transitional epithelium of mouse urinary bladder was studied by electron microscopy, lectin labelling and HRP tracing. Analysis of hexagonally structured membrane particles, WGA, and RCA I binding sites revealed structural similarity between plasmalemma, fusiform vesicles and multivesicular bodies. Early endosomes are lined by symmetric unit membrane as well as by asymmetric thickened membrane regions. Multivesicular bodies and fusiform vesicles have asymmetric unit membranes. MVBs may be derived from primary endosomes as well as from fusiform vesicles in the cytoplasm.     

Multivesicular bodies isolated from rat hepatocytes

Summary Plama lipoproteins (and other ligands) are endocytosed by hepatocytes and appear in multivesicular bodies (MVBs) in the Golgi-lysosome region of the cell prior to their degradation. We have isolated MVB fractions from livers of estradiol-treated rats, permitting studies of their properties (Hornick et al. 1985). Here we report our cytochemical studies of lysosomal enzyme activity in partially and highly purified MVB fractions and in MVBs in hepatocytes in situ.Only about 15% of partially or highly purified MVBs were positive for acid phosphatase and arylsulfatase, consistent with the prelysosomal nature of this compartment. Partially purified MVB fractions contained small round vesicles, 70–120 nm in diameter, which, stained intensely for these enzymes; occasionally these vesicles appeared to fuse with MVBs, suggesting that these structures are primary lysosomes. Such stained vesicles were rarely seen in highly purified MVB preparations. Acid phosphatase reaction product with cerium as capture reagent appeared as uniform precipitates surrounding endocytosed plasma lipoproteins in positively stained MVBs. Arylsulfatase reaction product, however, appeared as distinctive are or plaque-like deposits just inside the MVB-limiting membrane, often in continuity with intense reaction product contained in a fusing primary lysosome. Similar putative primary lysosomes were occasionally observed in isolated, intact Golgi fractions from the same livers. Similar histochemical reactivities of MVBs and putative primary lysosomes were observed in thin sections of hepatoyctes in situ.These observations support the conclusion that, in hepatocytes, MVBs represent the immediate prelysosomal compartment in the endocytic pathway of macromolecular catabolism, and suggest that MVBs are converted to secondary lysosomes by direct fusion with primary lysosomes arising from closely adjacent Golgi compartment.A portion of this work was published in abstract form in the Journal of Histochemistry and Cytochemistry, Vol. 34, page 120, 1986.This work was supported by U.S. Public Health Service Grant HL 14237 (Arteriosclerosis SCOR)     

Ultrastructure of Mikrocytos mackini, the cause of Denman Island disease in oysters Crassostrea spp. and Ostrea spp. in British Columbia, Canada

An ultrastructural study was carried out on Mikrocytos mackini, the cause of Denman Island disease in Pacific oysters Crassostrea gigas in western Canada. Three forms were identified, quiescent cells (QC), vesicular cells (VC) and endosomal cells (EC). QC occurred in the vesicular connective tissue (VCT), haemocytes (hyalinocytes), adductor and heart myocytes, and extracellularly. They had a central round to ovoid nucleus, < 7 cisternae of inactive nuclear membrane-bound Golgi, few vesicles and lysosome-like bodies. VC were rarely extracellular and usually occurred in adductor and heart myocytes, in close association with host cell mitochondria. The contents of the host cell mitochondria appeared to pass through a tubular extension into the cytoplasm of the parasite. Cytoplasmic vesicles resembled the tubular structure in appearance and size. EC occurred in the VCT, in haemocytes and extracellularly. They had a dilated nuclear membrane, sometimes containing a looped membranous structure that appeared to derive from the nucleus, and pass into the cytoplasm. A well-developed anastomosing endoplasmic reticulum connected the nuclear and plasma membranes, and endosomes were present in the cytoplasm. QC and EC cells were frequently observed tightly against, or between, the nuclear membranes of the host cell. Few organelles occurred in all forms of M. mackini, especially QC. The lack of organelles found in most eukaryotic cells, including mitochondria or their equivalents, may be due to obligate parasitism and the utilization of host cell organelles reducing the need for parasite organelles. Alternatively, perhaps M. mackini is a primitive eukaryote. Although phylogenetic affinities could not be determined, it is not a haplosporidian. A developmental cycle is proposed from these findings.     

The plasticity of multivesicular bodies and the regulation of antigen presentation

Multivesicular bodies (MVBs) are ubiquitous endocytic organelles containing numerous 50-80 nm vesicles. MVBs are very dynamic in shape and function. In antigen presenting cells (APCs), MVBs play a central role in the loading of major histocompatibility complex class II (MHC II) with antigenic peptides. How MHC II is transported from MVBs to the cell surface is only partly understood. One way involves direct fusion of MVBs with the plasma membrane. As a consequence, their internal vesicles are secreted as so-called exosomes. An alternative has been illustrated in maturing dendritic cells (DCs). Here, MVBs are reshaped into long tubules by back fusion of the internal vesicles with the MVB limiting membrane. Vesicles derived from the tips of these tubules then carry MHC II to the cell surface.