Two-color flow-cytometric analysis of the growth cycle of Plasmodium falciparum in vitro: identification of cell cycle compartments

A previous study (Hare JD, Bahler DW: J Histochem Cytochem 34:215, 1986) has shown that the flow cytometric analysis of acridine-orange-stained Plasmodium falciparum growing in vitro generates a complex two-color display, regions of which correlate with the major morphological stages. In this report, four cell cycle compartments (A-D) are defined by characteristic ratios of red and green fluorescence of cells distributed throughout the erythrocytic cycle as well as by the differential effects of several metabolic inhibitors. The primary characteristic of cells in compartment A is the significant increase in red fluorescence. Inhibition of DNA synthesis by either aphidicolin or hydroxyurea causes the accumulation of cells at the interface between compartments A and B, whereas n-butyrate prevents cells in compartment A from reaching the A-B interface. Cells in compartment A display a small increase in green fluorescence which is independent of DNA synthesis but is enhanced by n-butyrate treatment. Cells in compartment B display a continued increase in red fluorescence coupled with a significant increase in green fluorescence, reflecting the onset of DNA synthesis in compartment B. The transition to compartment C is more abrupt and is associated with a marked increase in green fluorescence and little increase in red fluorescence. Compartment D is characterized by an increase in red fluorescence and a continued rise in green fluorescence. It is postulated that these discontinuities in the two-color display reflect not only changes in the rates of RNA and DNA synthesis but also decondensation of parasite chromatin in compartment A as the organism prepares for DNA synthesis, and re-condensation in compartment D as the newly replicated chromatin prepares for segregation into merozoites. The method described promises to provide a sensitive and rapid technique to study the effects of various factors on the growth cycle of the parasite.     

Molecular Analysis of Bacterial Communities in a Three-Compartment Granular Activated Sludge System Indicates Community-Level Control by Incompatible Nitrification Processes

Bacterial community structure and the predominant nitrifying activities and populations in each compartment of a three-compartment activated sludge system were determined. Each compartment was originally inoculated with the same activated sludge community entrapped in polyethylene glycol gel granules, and ammonium nitrogen was supplied to the system in an inorganic salts solution at a rate of 5.0 g of N liter of granular activated sludge⁻¹ day⁻¹. After 150 days of operation, the system was found to comprise a series of sequential nitrifying reactions (K. Noto, T. Ogasawara, Y. Suwa, and T. Sumino, Water Res. 32:769–773, 1998), presumably mediated by different bacterial populations. Activity data showed that all NH₄-N was completely oxidized in compartments one and two (approximately half in each), but no significant nitrite oxidation was observed in these compartments. In contrast, all available nitrite was oxidized to nitrate in compartment three. To study the microbial populations and communities in this system, total bacterial DNA isolated from each compartment was analyzed for community structure based on the G+C contents of the component populations. Compartment one showed dominant populations having 50 and 67% G+C contents. Compartment two was similar in structure to compartment one. The bacterial community in compartment three had dominant populations with 62 and 67% G+C contents and retained the 50% G+C content population only at a greatly diminished level. The 50% G+C content population from compartment one hybridized strongly with amo (ammonia monooxygenase) and hao (hydroxylamine oxidoreductase) gene probes from Nitrosomonas europaea. However, the 50% G+C content population from compartment two hybridized strongly with the hao probe but only weakly with the amo probe, suggesting that the predominant ammonia-oxidizing populations in compartments one and two might be different. Since different activities and populations come to dominate in each compartment from an identical inoculum, it appears that the nitrification processes may be somewhat incompatible, resulting in a series of sequential reactions and different communities in this three-compartment system.     

Ultrastructure of the testis in Synbranchus marmoratus (Teleostei,Synbranchidae): the germinal compartment

Synbranchus marmoratus, is a protogynic diandric species in which two types of males, primary and secondary, are found. In both types, the germinal compartment in the testes is of the unrestricted lobular type, but in secondary (sex reversed females) males the lobules develop within the former ovarian lamellae. In the present study, the germinal compartment was examined in both types of males using light microscopy as well as scanning and transmission electron microscopy. Germinal compartment is limited by a basement membrane and contains Sertoli and germ cells. During maturation, processes of Sertoli cells form the borders of spermatocysts containing isogenic germ cells. Characteristically, type A and type B spermatogonia have a single nucleolus and grouped mitochondria associated with dense bodies or nuage. Type B spermatogonia, spermatocytes and spermatids are joined by cytoplasmatic bridges and are confined within spermatocysts. Secondary spermatocytes are difficult to find, indicating that this stage is of short duration. Biflagellated spermatozoa have a rounded head, no acrosome, and possess a midpiece consisting of two basal bodies, each of which produces a flagellum with a typical 9+2 microtubular composition. No associations occur between sperm and Sertoli cells. There were no differences between spermatogenesis in primary and secondary males in this protogynic, diandric fish.     

Vacuolar apical compartment (VAC) in breast carcinoma cell lines (MCF-7 and T47D): failure of the cell-cell regulated exocytosis mechanism of apical membrane

Abstract. We have previously shown that an integral plasma membrane glycoprotein (AP2) is highly polarized to the apical domain in confluent Madin-Darby canine kidney (MDCK) epithelial cells. However, when the monolayers are prevented from forming intercellular contacts, approximately 60% of the AP2 cellular content is stored in the intracellular vacuolar apical compartment (VAC). In the current work we found that AP2 was present in the non-tumorigenic human mammary epithelial cell line MCF-10A. in the breast carcinoma cell lines MCF-7 and T47D, and in breast ductal carcinomas in vivo. By radioimmunoassay, an intracellular Compartment of AP2 was identified in the mammary cell lines in culture. In MCF-10A, this compartment behaved as in MDCK cells; namely it was observed only when the cells cannot form cell-cell contacts. However, in the carcinoma cell lines MCF-7 and T47D, a significant AP2 intracellular compartment was observed also under conditions permissive for the formation of intercellular contacts. These results were confirmed by immunofluorescence and immunoelectron microscopy experiments that showed VACs in MCF-7 and T47D, even in cells with extensive intercellular contacts. In MCF-7 cells, the addition of serum caused a partial decrease of the AP2 intracellular compartment. The exocytosis of VACs occurred towards the center of multi-cellular groups, forming intercellular lumens, similar to those transiently observed in MDCK cells and to structures described by others during embryo development. Altogether, these results suggest that VAC exocytosis is controlled by cell-cell contact signalling, which may be defective in carcinoma cells.     

What is the clinical relevance of different lung compartments?

The lung consists of at least seven compartments with relevance to immune reactions. Compartment 1 - the bronchoalveolar lavage (BAL), which represents the cells of the bronchoalveolar space: From a diagnostic point of view the bronchoalveolar space is the most important because it is easily accessible in laboratory animals, as well as in patients, using BAL. Although this technique has been used for several decades it is still unclear to what extent the BAL represents changes in other lung compartments. Compartment 2 - bronchus-associated lymphoid tissue (BALT): In the healthy, BALT can be found only in childhood. The role of BALT in the development of the mucosal immunity of the pulmonary surfaces has not yet been resolved. However, it might be an important tool for inhalative vaccination strategies. Compartment 3 - conducting airway mucosa: A third compartment is the bronchial epithelium and the submucosa, which both contain a distinct pool of leukocytes (e.g. intraepithelial lymphocytes, IEL). This again is also accessible via bronchoscopy. Compartment 4 - draining lymph nodes/Compartment 5 - lung parenchyma: Transbronchial biopsies are more difficult to perform but provide access to two additional compartments - lymph nodes with the draining lymphatics and lung parenchyma, which roughly means "interstitial" lung tissue. Compartment 6 - the intravascular leukocyte pool: The intravascular compartment lies between the systemic circulation and inflamed lung compartments. Compartment 7 - periarterial space: Finally, there is a unique, lung-specific space around the pulmonary arteries which contains blood and lymph capillaries. There are indications that this "periarterial space" may be involved in the pulmonary host defense. All these compartments are connected but the functional network is not yet fully understood. A better knowledge of the complex interactions could improve diagnosis and therapy, or enable preventive approaches of local immunization.     

On some topological properties of the systems of compartments

Compartment systems are often used as models for tracer and drug kinetics. The structure of a compartment system is here analyzed by means of theory of graphs methods. In particular the precursor-successor relationship between any two compartments is classified according to the structure of the graph of the system and to the values of the elements of the matrix associated with it. Supported jointly by NASA and AEC.     

Characteristics of biofilm formation by Candida albicans

A variety of manifestations of Candida albicans infections are associated with the formation of biofilms on the surface of biomaterials. Cells in biofilms display phenotypic traits that are dramatically different from their free-floating planktonic counterparts, such as increased resistance to anti-microbial agents and protection form host defenses. Here, we describe the characteristics of C. albicans biofilm development using a 96 well microtitre plate model, microscopic observations and a colorimetric method based on the use of a modified tetrazolium salt (2,3-bis(2-methoxy-4-nitro-5-sulfo-phenyl)-2H-tetrazolium-5-carboxanilide, XTT) to monitor metabolic activities of cells within the biofilm. C. albicans biofilm formation was characterized by initial adherence of yeast cells (0-2 h), followed by germination and micro-colony formation (2-4 h), filamentation (4-6 h), monolayer development (6-8 h), proliferation (8-24 h) and maturation (24-48 h). The XTT-reduction assay showed a linear relationship between cellular density of the biofilm and metabolic activity. Serum and saliva pre-conditioning films increased the initial attachment of C. albicans, but had minimal effect on subsequent biofilm formation. Scanning electron microscopy and confocal scanning laser microscopy were used to visualize C. albicans biofilms. Mature C. albicans biofilms consisted of a dense network of yeasts cells and hyphal elements embedded within exopolymeric material. C. albicans biofilms displayed a complex three dimensional structure which demonstrated spatial heterogeneity and a typical architecture showing microcolonies with ramifying water channels. Antifungal susceptibility testing demonstrated the increased resistance of sessile C. albicans cells against clinically used fluconazole and amphotericin B as compared to their planktonic counterparts.     

The fine structure of blood cells in the ascidian Perophora viridis

The fine structure of each of the blood cell types of Perophora viridis has been characterized and strong evidence for localization of vanadium in two of these types is given. There are eight cell types; phagocytes which may contain completely engulfed cells, lymphocytes with a prominant nucleolus and scanty cytoplasm packed with clustered ribosomes, and six other cell types each with distinctive granules. Morula cells contain a central nucleus and cytoplasm filled by wedged bodies, about five of which are seen in section. These bodies contain regularly spaced electron dense foci. Green cells have the same organization but contain bodies which are electron dense throughout. Granular amoebocytes contain many smaller lightly staining oval bodies and much glycogen. Another cell type (probably orange cells of light microscopy) contains numerous granular rounded bodies. Compartment cells have vacuoles containing electron dense particles and signet ring cells have usually one large vacuole which is electron dense lined and may contain electron dense particles. Developmental stages of these cell types show involvement of endoplasmic reticulum and Golgi bodies in granule formation. After glutaraldehyde fixation alone the only extremely electron dense components are particles in the compartment cells and signet ring cells implicating these as sites of vanadium localization, although not excluding other cell types.     

Ultrastructural changes in murine lymphocytes induced by aflatoxin B1

This investigation sought to determine whether splenic lymphocytes obtained from Balb/C mice exposed to aflatoxin B1 (AFB1) showed any ultrastructural changes which could account for the immunodysfunction attributable to aflatoxins. Lymphocytes obtained from Balb/C mice administered aflatoxin B1 in olive oil daily for three weeks were studied using both transmission and scanning electron microscopy. The lymphocytes demonstrated ultrastructural changes primarily in the mitochondria where marked internal dissociation of the cristae was revealed by transmission electron microscopy. All other cellular organelles were unaffected. No significant alterations in external structure were observed under scanning electron microscopy. The findings of this study indicate that AFB1 administration does not affect the surface topography of lymphocytes, but AFB1, by causing extensive mitochondrial damage, may affect the way in which these cells function. This could be a possible explanation for the immunodysfunction associated with AFB1.Abbreviations AFB1 Aflatoxin B1 - SEM scanning electron microscopy - TEM transmission electron microscopy     

Identification of an intermediate compartment involved in protein transport from endoplasmic reticulum to Golgi apparatus

We have studied the role of a previously described tubulovesicular compartment near the cis-Golgi apparatus in endoplasmic reticulum (ER)-to-Golgi protein transport by light and immunoelectron microscopy in Vero cells. The compartment is defined by a 53-kDa transmembrane protein designated p53. When transport of the vesicular stomatitis virus strain ts045 G protein was arrested at 39.5 degrees C, the G protein accumulated in the ER but had access to the p53 compartment. At 15 degrees C, the G protein was exported from the ER into the p53 compartment which formed a compact structure composed of vesicular and tubular profiles in close proximity to the Golgi. Upon raising the temperature to 32 degrees C, the G protein migrated through the Golgi apparatus while the p53 compartment resumed its normal structure again. These results establish the p53 compartment as the 15 degrees C intermediate of the ER-to-Golgi protein transport pathway.     

Isolation of a temperature-sensitive variant Chinese hamster ovary cell line with a morphologically altered endocytic recycling compartment

We have enriched a mutagenized population of Chinese hamster ovary (CHO) cells for those defective in endocytosis by selection for survival to treatment with transferrin (Tf)-ricin and Tf-diphtheria toxin conjugates. Surviving cells were screened with a fluorescently labeled Tf uptake assay to identify cells with mor-phologically aberrant endocytic phenotypes. One of the cell lines identified, B104-5, has a striking temperature-induced alteration in the morphology of its endocytic receptor recycling compartment. In parental cells the tightly clustered endocytic recycling compartment is located near the Golgi complex. In the mutant cells, following incubation at 40°C, this compartment appears fragmented and widely dispersed. Surprisingly, this alteration in the morphology of the recycling compartment has no effect on the kinetics of Tf internationalization and recycling. The wild-type endocytic compartment is closely aligned with the microtubule-organizing center and the Golgi apparatus, and like the Golgi, its clustered appearance is dependent upon intact microtubules. Although the disruption of the B104-5 receptor recycling compartment morphology can be phenocopied in wild-type cells by microtubule depolymerizing drugs, the microtubule cytoskeleton in B104-5 cells appears normal in immunofluorescent staining. B104-5 cells, unlike the parental cells, do not proliferate at 40°C. The mutation in B104-5 cells is recessive, as fusion with wild-type cells results in a reversion of the B104-5 phenotype. The finding that the morphology of the recycling compartment in CHO cells can be altered without affecting recycling of endocytosed Tf is consistent with the variety of recycling compartment morphologies observed among different cell lines. An interpretation of this result is that the lesion in B104-5 cells is in a gene that is involved in determining the endocytic compartment morphologies observed in different cell lines. © 1993 Wiley-Liss, Inc.     

Germination of Bacillus anthracis spores within alveolar macrophages

The fatal character of the infection caused by inhalation of Bacillus anthracis spores results from a complex pathogenic cycle involving the synthesis of toxins by the bacterium. We have shown using immunofluorescent staining, confocal scanning laser microscopy and image cytometry analysis that the alveolar macrophage was the primary site of B. anthracis germination in a murine inhalation infection model. Bacillus anthracis germinated inside murine macrophage-like RAW264.7 cells and murine alveolar macrophages. Germination occurred in vesicles derived from the phagosomal compartment. We have also demonstrated that the toxin genes and their trans -activator, AtxA, were expressed within the macrophages after germination.     

Ultrastructure of cells cultured on polycarbonate membranes.

A method is described for preparing undisturbed cell cultures for both scanning and transmission electron microscopy. Cells were propagated on polycarbonate membranes with pores of 0.2 micrometer or less. Cultured cells together with their supports were prepared for both scanning electron microscopy and transmission electron microscopy using routine methods. For transmission electron microscopy a rapid schedule of infiltration and polymerization was used. The method described in this report yielded good results and it allowed the fine structure of cultured cells to be viewed in situ by both scanning electron microscopy and transmission electron microscopy.     

Ultrastructure of Cells Cultured on Polycarbonate Membranes

A method is described for preparing undisturbed cell cultures for both scanning and transmission electron microscopy. Cells were propagated on polycarbonate membranes with pores of 0.2 pm or less. Cultured cells together with their supports were prepared for both scanning electron microscopy and transmission electron microscopy using routine methods. For transmission electron microscopy a rapid schedule of infiltration and polymerization was used. The method described in this report yielded good results and it allowed the fine structure of cultured cells to be viewed in situ by both scanning electron microscopy and transmission electron microscopy.     

Polymerization of secretory IgM in B lymphocytes is prevented by a prior targeting to a degradation pathway.

B lymphocytes express on their surface a membrane form of IgM (mIgM), and synthesize but fail to secrete a secretory form of IgM (sIgM). Plasma cells shift to the exclusive synthesis and efficient secretion of sIgM. The sIgM in B cells differs from that in plasma cells in its pattern of assembly: in plasma cells, monomers of sIgM are assembled into polymers and only polymers are secreted; in B lymphocytes, monomeric sIgM is neither polymerized nor secreted and is degraded intracellularly. In this article we blocked the export of proteins from the endoplasmic reticulum at low temperatures or with energy poisons or brefeldin A, and localized the different assembly steps of mIgM and sIgM in the 38C B lymphocytes and of sIgM in the 38C-derived sIgM-secreting D2 hybridoma. In both cell lines, sIgM assembly into monomers was not affected, whereas polymerization of sIgM in D2 cells and monomer formation of mIgM in 38C cells were strongly inhibited. Moreover, probing with specific lectins revealed galactosylated monomers and polymers in D2 cells and galactosylated hemimer and monomers only of mIgM in 38C cells. In addition, when Golgi functions were hampered with Tris base, monomerization of mIgM and polymerization of sIgM were attenuated. These results indicate that polymerization of sIgM in D2 cells and monomerization of mIgM in 38C cells are post-endoplasmic reticulum events, occurring in or beyond the trans-Golgi galactosylation compartment. Since only polymers are secreted from D2 cells and only monomeric mIgM is displayed on the surface of 38C cells, partially assembled molecules may traverse the secretory pathway yet are restricted from the cell surface. Furthermore, monomeric sIgM in 38C cells is never galactosylated, thus it is degraded prior to the galactosylation compartment. We conclude that targeting of sIgM to degradation in 38C cells precedes its assembly site into polymers in D2 cells. This implies that degradation of sIgM does not result from the incompetence of 38C cells to polymerize. Rather, assembly of sIgM into polymers and their subsequent secretion are prevented in B lymphocytes by preceding targeting of monomeric sIgM to degradation.     

Effects of foot-and-mouth disease virus nonstructural proteins on the structure and function of the early secretory pathway: 2BC but not 3A blocks endoplasmic reticulum-to-Golgi transport

Infection of cells by picornaviruses leads to the generation of intracellular membrane vesicles. The expression of poliovirus (PV) 3A protein causes swelling of the endoplasmic reticulum (ER) and inhibition of protein trafficking between the ER and the Golgi apparatus. Here, we report that the nonstructural proteins of a second picornavirus, foot-and-mouth disease virus (FMDV), also perturb the secretory pathway. FMDV proteins 3A, 2B, 2C, and 2BC expressed alone in cells were recovered from crude membrane fractions, indicating membrane association. Immunofluorescence microscopy showed that 3A was located in a reticular structure and 2B was located in the ER, while 2C was located in both the ER and the bright punctate structures within the Golgi apparatus. 2BC gave punctate cytoplasmic staining and also caused accumulation of ER proteins in large vesicular structures located around the nuclei. The effect of the FMDV proteins on the trafficking of the vesicular stomatitis virus glycoprotein (G protein) from the ER to the cell surface was determined. Unlike its PV counterpart, the 3A protein of FMDV did not prevent trafficking of the G protein to the cell surface. Instead, surface expression of the G protein was blocked by 2BC, with retention of the G protein in a modified ER compartment staining for 2BC. The results suggest that the nonstructural proteins of different picornaviruses may vary in their ability to perturb the secretory pathway. Since FMDV 2BC can block the delivery of proteins to the cell surface, it may, as shown for PV 3A, play a role in immune evasion and contribute to the persistent infections observed in ruminants.     

A simpler way of comparing the labelling densities of cellular compartments illustrated using data from VPARP and LAMP-1 immunogold labelling experiments

Quantitative immunoelectron microscopy of gold label in intracellular compartments often involves calculating labelling densities (LDs). These are related to antigen concentrations and usually refer gold particle counts to the sizes of compartments on sections (for example, golds per microm(2) of organelle profile area or per microm of membrane trace length). Here, we show how LD values can be estimated more simply (without estimating areas or lengths) and also how observed and expected LD values can be used to calculate a relative labelling index (RLI) for each compartment and then test statistically for preferential (non-random) labelling. For random labelling, RLI=1. Compartment size is estimated stereologically by superimposing random test points (which hit organelle profiles in proportion to their area) or test lines (which intersect membrane traces in proportion to their length). By this means, the observed LD of a compartment (LD(obs)) can be expressed simply as golds per test point (organelles) or per intersection (membranes). Furthermore, the LD obtained by dividing total golds (on all compartments) by total points or intersections (on all compartments) is the value to be expected (LD(exp)) when compartments label randomly. For each compartment, RLI=LD(obs)/LD(exp). Statistical analysis is undertaken by comparing observed distributions of golds with predicted random distributions (calculated from point or intersection counts). A compartment is preferentially labelled if two criteria are met: (1) its RLI>1 (i.e. LD(obs) is greater than LD(exp)) and (2) its partial chi-squared value makes a substantial contribution to total chi-squared value. This approach provides a simple and efficient way of comparing LDs in different compartments. Its utility is illustrated using data from VPARP and LAMP-1 labelling experiments.     

Subcellular distribution and function of Rab3A-D in pancreatic acinar AR42J cells

Members of the Rab3 subfamily have been linked to the regulation of exocytosis in secretory cells. We have recently shown by Northern blot analysis that pancreatic acinar-like AR42J cells express all four Rab3 isoforms (Rab3A-D). In the present study, we examined the subcellular distribution of endogenously expressed Rab3 proteins and their relation to the amylase-containing secretory compartment in dexamethasone-differentiated AR42J cells. Rab3A and Rab3C were enriched in the cytosol, Rab3B and Rab3D in the membrane fraction. Accordingly, confocal immunocytochemistry revealed that Rab3B and Rab3D were located in a compartment close to the plasma membrane, whereas anti-Rab3A and Rab3C mainly stained the cytosol. Sucrose density gradient centrifugation showed overlapping, but distinct localization of each Rab3 isoform. The order of banding from lighter to more dense fractions was Rab3C < Rab3A < Rab3B < Rab3D. All Rab3 proteins at least partially colocalized with amylase immunoreactivity. Transient overexpression of Rab3 proteins showed that Rab3A inhibited cholecystokinin (CCK)-induced amylase secretion, whereas overexpression of other Rab3 isoforms had no significant effect. In conclusion, our data indicate that the different Rab3 proteins show distinct subcellular distribution, suggesting different impact on exocrine secretory response in dexamethasone-differentiated AR42J cells.     

A lysosomal targeting signal in the cytoplasmic tail of the beta chain directs HLA-DM to MHC class II compartments

In human B cells, class II molecules of the major histocompatibility complex (MHC-II) accumulate in an endosomal/lysosomal compartment, the MIIC, in which they may encounter and bind peptides. An additional molecule required for MHC-II peptide binding, HLA-DM (DM), has also been localized to the MIIC. Neither the relationship of the MIIC to the endosomal system nor the mechanisms by which DM localizes to the MIIC are understood. To address these issues, DM localization was analyzed in cells that do or do not express MHC-II. DM alpha beta heterodimers were localized in transfected MHC-II-negative HeLa and NRK cells, in the absence of the MHC-II-associated invariant chain, to a prelysosomal/lysosomal compartment by immunofluorescence microscopy. To identify a potential targeting determinant, we analyzed the localization of a chimeric protein, T-T-Mb, in which the cytoplasmic tail of murine DM beta (Mb) was appended to the lumenal and transmembrane domains of a cell surface protein, Tac. Like intact DM, T- T-Mb was localized to a lysosomal compartment in HeLa and NRK cells, as judged by immunofluorescence and immunoelectron microscopy. T-T-Mb was rapidly degraded in this compartment by a process that was blocked by inhibitors of lysosomal proteolysis. The DM beta cytoplasmic tail also mediated internalization of anti-Tac antibody from the cell surface and delivery to lysosomes. Deletion from the DM beta cytoplasmic tail of the tyrosine-based motif, YTPL, resulted in cell surface expression of T-T-Mb and a loss of both degradation and internalization; alanine scanning mutagenesis showed that the Y and L residues were critical for these functions. Similarly, mutation of the same Y residue within full- length DM beta resulted in cell surface expression of DM alpha beta heterodimers. Lastly, T-T-Mb was localized by immunoelectron microscopy to the MIIC in a human B lymphoblastoid cell line. Our results suggest that a motif, YTPL, in the cytoplasmic tail of the beta chain of DM is sufficient for targeting either to lysosomes or to the MIIC.