Immunohistochemical localization of annexin VI in the endocytic compartment of rat liver hepatocytes

Annexin VI has been isolated from rat liver endosomes and affinity purified antibodies have been produced. By Western blotting, in rat liver subcellular fractions, anti-annexin VI was demonstrated to recognise a 68 kDa band in the three endosomal fractions. In the present study, immunogold labeling of ultrathin Lowicryl sections of rat liver has been used to get insights into the ultrastructural hepatocyte localization. Although at the immunofluorescence level the staining seemed located at the apical, canalicular plasma membrane, domain of the hepatocytes, the electron microscopy revealed that 80% of the labeling, with the anti-annexin VI antibody was specifically localized not at the plasma membrane but in the close subapical endocytic compartment surrounding the bile canalicular plasma membrane of the hepatocyte. Double immunogold labeling with an anti peptide antibody to Rab5 and anti-annexin VI showed that 80% of the Rab5 positive apical endosomes were also labeled with anti-annexin VI antibodies. However, there was no significant colocalization of annexin VI and structures labeled with antibodies to the polymeric immunoglobulin receptor. The results suggest that annexin VI could be involved in regulating the functioning of this apical compartment in the hepatocyte.     

EEA1, an early endosome-associated protein. EEA1 is a conserved alpha-helical peripheral membrane protein flanked by cysteine "fingers" and contains a calmodulin-binding IQ motif

Early endosomes are cellular compartments receiving endocytosed material and sorting them for vesicular transport to late endosomes and lysosomes or for recycling to the plasma membrane. We have cloned a human cDNA encoding an evolutionarily conserved 180-kDa protein on early endosomes named EEA1 (Early Endosome Antigen1). EEA1 is associated with early endosomes since it co-localizes by immunofluorescence with the transferrin receptor and with Rab5 but not with Rab7. Immunoelectron microscopy shows that it is associated with tubulovesicular early endosomes containing internalized bovine serum albumin-gold. EEA1 is a hydrophilic peripheral membrane protein present in cytosol and membrane fractions. It partitions in the aqueous phase after Triton X-114 solubilization and is extracted from membranes by 0.3 M NaCl. It is a predominantly alpha-helical protein sharing 17-20% sequence identity with the myosins and contains a calmodulin-binding IQ motif. It is flanked by metal-binding, cysteine "finger" motifs. The COOH-terminal fingers, Cys-X2-Cys-X12-Cys-X2-Cys and Cys-X2-Cys-X16-Cys-X2-Cys, are present within a region that is strikingly homologous with Saccharomyces cerevisiae FAB1 protein required for endocytosis and with Caenorhabditis elegans ZK632. These fingers also show limited conservation with S. cerevisiae VAC1, Vps11, and Vps18p proteins implicated in vacuolar transport. We propose that EEA1 is required for vesicular transport of proteins through early endosomes and that its finger motifs are required for this activity.     

Cholesterol-dependent retention of GPI-anchored proteins in endosomes

Several cell surface eukaryotic proteins have a glycosylphosphatidylinositol (GPI) modification at the Cterminal end that serves as their sole means of membrane anchoring. Using fluorescently labeled ligands and digital fluorescence microscopy, we show that contrary to the potocytosis model, GPI-anchored proteins are internalized into endosomes that contain markers for both receptor-mediated uptake (e.g. transferrin) and fluid phase endocytosis (e.g. dextrans). This was confirmed by immunogold electron microscopy and the observation that a fluorescent folate derivative bound to the GPI-anchored folate receptor is internalized into the same compartment as co-internalized horseradish peroxidase-transferrin; the folate fluorescence was quenched when cells subsequently were incubated with diaminobenzidine and H2O2. Most of the GPI-anchored proteins are recycled back to the plasma membrane but at a rate that is at least 3-fold slower than C6-NBD-sphingomyelin or recycling receptors. This endocytic retention is regulated by the level of cholesterol in cell membranes; GPI-anchored proteins are recycled back to the cell surface at the same rate as recycling transferrin receptors and C6-NBD-sphingomyelin in cholesterol-depleted cells. Cholesterol-dependent endocytic sorting of GPI-anchored proteins is consistent with the involvement of specialized lipid domains or 'rafts' in endocytic sorting. These results provide an alternative explanation for GPI-requiring functions of some GPI-anchored proteins.     

Biochemical evidence that Semliki Forest virus obtains its envelope from the plasma membrane of the host cell

The data from chemical studies and electron microscopy suggest that Semliki Forest virus obtains its envelope by budding into the medium from the plasma membrane of the host cell. Biochemical evidence for this phenomenon, however, has not been published. Therefore, we undertook a series of pulse-chase studies so that we might quantitatively evaluate the importance of the budding mechanism in the morphogenesis of Semliki Forest virus. Baby hamster kidney cells (clone 13) were grown in culture and infected with Semliki Forest virus. The cells were exposed to [4,5-3H] leucine for 20 min and the subsequent incorporation of the label into virus proteins associated with cytoplasmic membranes and extracellular virus was determined. Initial experiments were conducted with microsomes and a precursor-product relationship was demonstrated between viral proteins in the microsomes and in extracellular virus. Further studies were performed with endoplasmic reticulum and plasma membrane preparations. Maximal incorporation of [3H] leucine was observed in the viral proteins located in the endoplasmic reticulum at the end of a 20-min pulse period; greater than 50% of this activity had disappeared within 2 h. The plasma membrane fraction contained no radioactivity at the end of the pulse period; subsequently, maximal labeling of the viral proteins in the plasma membrane occurred 4 h into the chase period and these labeled proteins had disappeared from this membrane 11 h after the pulse. At this time maximal incorporation of the labeled proteins into extracellular virus was observed. These data are consistent with a precursor-product relationship between the viral proteins in the endoplasmic reticulum which migrate to the plasma membrane and are subsequently incorporated into extracellular virus. All the radioactivity in the extracellular virus appears to have been derived from viral proteins associated with the plasma membrane of the cell. Therefore, mechanisms for the morphogenesis of Semliki Forest virus (in baby hamster kidney cells), other than budding from the plasma membrane, are unlikely to be of quantitative importance.     

Hrs, a tyrosine kinase substrate with a conserved double zinc finger domain, is localized to the cytoplasmic surface of early endosomes

Hrs is a 115-kDa double zinc finger protein that is rapidly tyrosine phosphorylated in growth factor-stimulated cells. However, its function remains unknown. Here we show that Hrs is localized to early endosomes. Intracellular localization of endogenous Hrs and exogenously expressed Hrs tagged with the hemagglutinin epitope was examined by immunofluorescence staining using anti-Hrs and anti-hemagglutinin epitope antibodies, respectively. Hrs was detected in vesicular structures and was colocalized with the transferrin receptor, a marker for early endosomes, but only partially with CD63, a marker for late endosomes. A zinc finger domain deletion mutant of Hrs was also colocalized with the transferrin receptor, suggesting that the zinc finger domain is not required for its correct localization. Immunoelectron microscopy showed that Hrs was localized to the cytoplasmic surface of these structures. By subcellular fractionation, Hrs was recovered both in the cytoplasmic and membrane fractions. The membrane-associated Hrs was extracted from the membrane by alkali treatment, suggesting that it is peripherally associated with early endosomes. These results, together with our finding that Hrs is homologous to Vps27p, a protein essential for protein traffic through a prevacuolar compartment in yeast, suggest that Hrs is involved in vesicular transport through early endosomes.     

Japanese encephalitis virus infection in Vero cells: the involvement of intracellular acidic vesicles in the early phase of viral infection was observed with the treatment of a specific vacuolar type H+-ATPase inhibitor, bafilomycin A1

The involvement of intracellular acidic vesicles in the early phase of Japanese encephalitis (JE) virus infection in Vero cells was observed by adding a specific vacuolar type H+-ATPase (V-ATPase) inhibitor (bafilomycin A1) in the cell culture medium. Studies with the detection of viral envelope (E) protein suggested that bafilomycin A1 inhibited virus infection in the cells. Subcellular distribution of incoming biotinylated virions and 3H-uridine-labeled viral RNA were observed in fractions of a Percoll density gradient. At 10 min of the chasing period, virions and viral RNA were found mainly in fractions with a mean density of 1.04 g/ml corresponding to the endosome both in the control and bafilomycin A1-treated cells. At 60 min of the chasing period, the peak of biotin activity was detected in fractions with a mean density of 1.08 g/ml corresponding to the lysosome, whereas the peak of radioactivity did not run parallel with that of biotin and shifted to fractions with a mean density of 1.05 g/ml and higher than 1.084 g/ml, respectively. At 60 min of the chasing period in bafilomycin A1-treated cells, the peak of biotin and radioactivity were still found mainly in the fraction with a density of 1.04 g/ml, representing the endosome. Subcellular fractionation by a Percoll density gradient revealed that bafilomycin A1 treatment resulted in the accumulation of virions in the endosome fraction and suggested the prevention of intracellular translocation of the virions which occurs during the early entry process of an infecting virus to the cells.     

The dependence of the endocytosis of the epidermal growth factor receptors on the degree of receptor occupancy

Two subpopulations of epidermal growth factor (EGF) receptor with different affinity to EGF have been demonstrated for many cell types. There are reasons to assume a key role of high-affinity receptors in stimulation of cell response to EGF. Nevertheless, characteristics of its action remain obscure. In the present work an attempt has been made to study internalization and intracellular compartmentalization of high-affinity receptors. For this purpose endocytosis of 125I-EGF in A431 cells was stimulated by low (less than 1 nM) EGF concentrations as well as after blocking of low-affinity binding sites with specific monoclonal antibodies 2E9. By subcellular fractionation in 17% Percoll gradient it was demonstrated that in both cases internalized 125I-EGF was found first in light, and then in heavy endosomes staying there for a long time. Effectiveness of 125I-EGF delivery to prelysosomal heavy endosomes as well as initial internalization rate is maximal at low EGF concentrations and is reduced dramatically with increasing of receptor occupancy. Monoclonal antibody Mab108 specifically recognizing high-affinity receptors were capable of stimulation of receptor internalization with initial rate higher than that of high EGF concentrations, but Mab108-receptor complexes were localized in light endosomes. Preincubation of the cells with low concentrations of EGF led to redistribution of considerable portion of 125I-Mab108 into heavy endosomes, which may be a result of high-affinity receptor tyrosine kinase activation. Our data confirm a hypothesis of TK involvement in regulation of both internalization and sorting of EGF-receptor complexes. Structural organization of high-affinity receptors is not sufficient for receptor targeting to degradation pathway.     

Multiple interactions between insect lipoproteins and fat body cells: extracellular trapping and endocytic trafficking

The binding and internalization of a circulating insect lipoprotein, high density lipophorin (HDLp), by insect fat body cells was studied at the electron-microscopic level using ultrasmall gold-labeled HDLp and DiI-labeled HDLp, which were visualized by silver enhancement and diaminobenzidine photoconversion, respectively. Internalization of HDLp seems to conflict with the selective process by which the lipids are transported between HDLp and fat body cells. The pathway followed by the internalized lipoproteins was investigated. In addition, the localizations of HDLp in fat body cells of young and older adult locusts were compared because of the previously reported age-related differences in distribution of cell-associated and internalized HDLp. In the present study, internalized labeled HDLp was observed in early endosomes, late endosomes, and putative lysosomes. In older adults, these labeled structures were much less abundant than in young adults. Moreover, in these animals, the labeled endosomal/lysosomal vesicles were located close to the plasma membranes. A more intense labeling was observed in the extracellular matrix in older adults compared to young adults. In both developmental stages, an apparent accumulation of labeled HDLp was found in extracellular spaces. We propose that this entrapment of HDLp may be essential for selective lipid transport between HDLp and fat body cells.     

Temporal synthesis of band 3 oligomers during terminal maturation of mouse erythroblasts. Dimers and tetramers exist in the membrane as preformed stable species

Band 3, the anion transport protein of the erythrocyte membrane, exists in the membrane as a mixture of dimers (B3D) and tetramers (B3T). The dimers are not linked to the skeleton and constitute the free mobile band 3 fraction. The tetramers are linked to the skeleton by their interaction with ankyrin. In this report we have examined the temporal synthesis and assembly of band 3 oligomers into the plasma membrane during red cell maturation. The oligomeric state of newly synthesized band 3 in early and late erythroblasts was analyzed by size-exclusion high-pressure liquid chromatography of band 3 extracts derived by mild extraction of plasma membranes with the nonionic detergent C12E8 (octaethylene glycol n-dodecyl monoether). This analysis revealed that at the early erythroblast stage, the newly synthesized band 3 is present predominantly as tetramers, whereas at the late stages of erythroid maturation, it is present exclusively as dimers. To examine whether the dimers and tetramers exist in the membrane as preformed stable species or whether they are interconvertible, the fate of band 3 species synthesized during erythroblast maturation was examined by pulse-chase analysis. We showed that the newly synthesized band 3 dimers and tetramers are stable and that there is no interconversion between these species in erythroblast membranes. Pulse-chase analysis followed by cellular fractionation showed that, in early erythroblasts, the newly synthesized band 3 tetramers are initially present in the microsomal fraction and later incorporated stably into the plasma membrane fraction. In contrast, in late erythroblasts the newly synthesized band 3 dimers move rapidly to the plasma membrane fraction but then recycle between the plasma membrane and microsomal fractions. Fluorescence photobleaching recovery studies showed that significant fractions of B3T and B3D are laterally mobile in early and late erythroblast plasma membranes, respectively, suggesting that many B3T-ankyrin complexes are unattached to the membrane skeleton in early erythroblasts and that the membrane skeleton has yet to become tightly organized in late erythroblasts. We postulate that in early erythroblasts, band 3 tetramers are transported through microsomes and stably incorporated into the plasma membrane. However, when ankyrin synthesis is downregulated in late erythroblasts, it appears that B3D are rapidly transported to the plasma membrane but then recycled between the plasma membrane and microsomal compartments. These observations may suggest novel roles for membrane skeletal proteins in stabilizing integral membrane protein oligomers at the plasma membrane and in regulating the endocytosis of such proteins.     

Heterogeneous distribution of the sodium-dependent alanine transport activity in the rat hepatocyte plasma membrane

The localization of the sodium-dependent alanine uptake activity in rat liver cells was studied. Fractions representative of the canalicular, the contiguous (lateral) and the blood-sinusoidal surface of the hepatocyte were isolated by means of centrifugal fractionation and density gradient centrifugation. The distribution of various marker-enzyme activities in conjunction with the occurrence of alanine transport activity was studied both in fractions obtained after zonal density gradient centrifugation, and in the subcellular fractions mentioned above. It is concluded that the sodium-dependent alanine transport activity is primarily located in the blood-sinusoidal plasma membrane of the hepatocyte.     

Development and application of sensitive HPLC assays for NK3 antagonists in rat plasma

A density gradient electrophoresis (DGE) apparatus (2.2 x, 14 cm) was constructed for the rapid separation of milligram quantities of proteins. By using binary buffers according to Bier (Electrophoresis 1993, 14, 1011-1018) proteins were rate-zonally separated in less than 60 min. Acidic proteins were separated in a pH 8.6, 56 microS/cm buffer, and basic proteins in a pH 5.4, 76 microS/cm buffer. Thus the A (pI 5.15) and B (pI 5.30) forms of beta-lactoglobulin as well as the sialylated glycoforms of apotransferrin were well separated at pH 8.6. The isoforms of myoglobin (pI 6.9 and 7.35, respectively), RNAse A (pI 9.45) and cytochrome c (pI 10.0) and lysozyme (pI 11) were separated at pH 5.4 within 80 min. On a 7 cm DGE column, subcellular organelles derived from HeLa cells were separated in standard electrophoresis buffer (655 microS/cm) for 90 min at 10 mA. Using a new low conductivity buffer (193 microS/cm) 20 min was sufficient to separate late endosomes, lysosomes, endoplasmic reticulum, early endosomes, plasma membrane, clathrin-coated pits, proteasomes, and clathrin-coated vesicles within a single run directly from a postnuclear supernatant.     

Syntaxin 13 mediates cycling of plasma membrane proteins via tubulovesicular recycling endosomes

Endocytosis-mediated recycling of plasma membrane is a critical vesicle trafficking step important in diverse biological processes. The membrane trafficking decisions and sorting events take place in a series of heterogeneous and highly dynamic organelles, the endosomes. Syntaxin 13, a recently discovered member of the syntaxin family, has been suggested to play a role in mediating endosomal trafficking. To better understand the function of syntaxin 13 we examined its intracellular distribution in nonpolarized cells. By confocal immunofluorescence and electron microscopy, syntaxin 13 is primarily found in tubular early and recycling endosomes, where it colocalizes with transferrin receptor. Additional labeling is also present in endosomal vacuoles, where it is often found in clathrin-coated membrane areas. Furthermore, anti-syntaxin 13 antibody inhibits transferrin receptor recycling in permeabilized PC12 cells. Immunoprecipitation of syntaxin 13 revealed that, in Triton X-100 extracts, syntaxin 13 is present in a complex(es) comprised of betaSNAP, VAMP 2/3, and SNAP-25. This complex(es) binds exogenously added alphaSNAP and NSF and dissociates in the presence of ATP, but not ATPgammaS. These results support a role for syntaxin 13 in membrane fusion events during the recycling of plasma membrane proteins.     

Subcellular compartmentalization of maize storage proteins in Xenopus oocytes injected with zein messenger RNAs

Maize storage proteins synthesized in oocytes were compartmentalized in membrane vesicles because they were resistant to hydrolysis by protease, unless detergent was present. The site of storage protein deposition within the oocyte was determined by subcellular fractionation. Optimal separation of oocyte membranes and organelles was obtained when EDTA and high concentrations of NaCl were included in the homogenization and gradient buffers. Under these conditions, fractions in sucrose gradients containing a heterogeneous mixture of smooth membranes (presumably endoplasmic reticulum, Golgi apparatus, and plasma membrane, density = 1.10-1.12 g/cm3), mitochondria (densities = 1.14 and 1.16 g/cm3), yolk platelets (density = 1.21 g/cm3), and a dense matrix material (density = 1.22 g/cm3) could be separated. Some zein proteins were recovered in the mixed membrane fraction, but the majority occurred in vesicles sedimenting with yolk platelets and granular material at a density of approximately 1.22 g/cm3. When metrizamide was included in the gradient to increase the density, little of the dense matrix material was isolated, and vesicles containing zein proteins were separated from other oocyte components. These vesicles were similar to protein bodies in maize endosperm because they were of identical density and contained the same group of polypeptides.     

Vesiculation and sorting from PC12-derived endosomes in vitro

Formation of small vesicles resembling synaptic vesicles can be reconstituted in vitro by incubating labeled homogenates of PC12 cells with ATP and two cytoplasmic proteins, AP3 and ARF1 [Faúndez, V., Horng, J.-T. & Kelly, R. B. (1998) Cell 93, 423-432]. To determine whether AP3 was mediating budding from plasma membranes or endosomes the organelle that generated the synaptic vesicles was characterized. The budding activity was enriched in organelles that labeled at 15 degrees C, but not at 4 degrees C, that excluded a marker of plasma membranes and that contained internalized transferrin, indicating that the precursor was an endosome. Vesicles formed from the endosomal precursor in vitro excluded transferrin. We conclude that ARF-mediated vesiculation into synaptic vesicle-sized organelles uses an endosomal precursor and occurs simultaneously in vitro with sorting of synaptic vesicle proteins from other membrane protein constituents of the endosome.     

Low density lipoprotein receptor-related protein-1 expression in the testis: regulated expression in Sertoli cells

The low density lipoprotein receptor-related protein (LRP-1) is a multiligand receptor capable of mediating endocytosis of a wide array of ligands that relate to both lipoprotein metabolism and proteinase regulation. Many of its ligands are proteinases, proteinase-inhibitor complexes, and lipoproteins known to be contained within the luminal fluid of the seminiferous tubules or in the interstitial spaces of the testis. Immunocytochemical analysis was performed to characterize the pattern of expression of LRP-1 in cells of the rat testis. Immunoperoxidase staining localized LRP-1 to the cytoplasm of Sertoli cells. The distribution and intensity of the Sertoli cell staining was found to vary according to the stages of the cycle of the seminiferous epithelium. Staining was weak in the basal cytoplasm of Sertoli cells during stages II-VIII and strong and granular in the supranuclear cytoplasm during stages XII-XIV and stage I of the cycle. Immunogold labeling showed gold particles associated with the basal and adluminal plasma membranes, with endocytic vesicles, and with endosome membranes. Labeling was also observed on the plasma membrane and membranes of the endocytic apparatus in macrophages and Leydig cells in the interstitial space. Infusion of 125I-Labeled LRP-1 antibody into seminiferous tubules followed by radioautography showed silver grains overlaying the ad-luminal plasma membrane of Sertoli cells at time 0 and in endocytic vesicles and endosomes in the supranuclear region of Sertoli cells 10-minutes postinjection. When the 125I-Labeled LRP-1 antibody was injected into the interstitial space, silver grains overlayed the basal plasma membrane and coated endocytic pits of Sertoli cells at time 0 and, at 10 minutes, the grains labeled endosomes located in the basal pole of Sertoli cells. 125I-Labeled LRP-1 antibody also labeled the plasma membrane and the endocytic apparatus of macrophages and Leydig cells. The absence of immunogold labeling and radioautographic silver grains within lysosomes of Sertoli cells, Leydig cells, and macrophages suggests that internalized LRP-1 is recycled back to the cell surface. The presence of LRP-1 in the endocytic compartment of these cells is consistent with its functioning in the clearance of proteases involved in seminiferous tubule remodeling and/ or the uptake of cholesterol-bound lipoproteins necessary for the biosynthesis of testosterone. In conclusion, the results of these studies demonstrated for the first time the presence of LRP-1 receptor in the endocytic compartments of Sertoli cells and interstitial cells of the rat testis.     

Free-flow electrophoretic analysis of endosome subpopulations of rat hepatocytes

The separation of functional early and late endosomes from other cellular compartments by free-flow electrophoresis (FFE) has been previously demonstrated in nonpolarized cells. Here, using 125I-labeled anti-secretory component antibodies ([125I]SC Ab) and FITC-labeled asialoorosomucoid (FITC-ASOR) as markers of the transcytotic and lysosomal pathway, respectively, we demonstrate the separation of three distinct endosome subpopulations from polarized rat hepatocytes. Internalization of both markers at 16 degrees C resulted in their accumulation in a common endosome compartment, indicating that both the transcytotic and the lysosomal pathways are arrested in the sorting early endosome at temperatures below 20 degrees C. After chase of the markers from early endosomes into the transcytotic or the degradative route at 37 degrees C, transcytotic endosomes carrying [125I]SC Ab migrated with an electrophoretic motility between early and late endosomes while late endosomes labeled with FITC-ASOR were deflected more towards the anode than early endosomes. These data indicate that in rat hepatocytes, the transcytotic and lysosomal pathways utilize a common (i.e. early endosomes) and two distinct endosome subpopulations (i.e. transcytotic endosomes, late endosomes) prior to delivering proteins for biliary secretion or lysosomal degradation, respectively.     

Localization of glucocorticoid uptake in normal and ischemic myocardial tissue of isolated perfused cat hearts

We studied the uptake of labeled dexamethasone (3H-Dex) or methylprednisolone (3H-MP) in isolated perfused cat hearts during the first hour of acute myocardial ischemia. Considerable amounts of 3H-Dex and 3H-MP were taken up by the plasma membrane (F1) fraction in control, border zone, and ischemic myocardial tissue. Lesser amounts were incorporated into the remaining cell fractions. A gradient of glucocorticoid uptake was observed that decreased from control tissue to ischemic tissue in all subcellular fractions (i.e., F1 to F5). Accordingly, supernatant fraction (S) to particulate (P) ratios of labeled glucocorticoid uptake increased from control to ischemic tissue, indicating that myocardial cell damage resulted in a decrease in glucocorticoid-binding capacity in subcellular fractions obtained from ischemic tissue. The activity of 5'-nucleotidase (5'ND), a plasma membrane marker in myocardial cells, also decreased from normal to ischemic tissue. Furthermore, we found that uptake of 3H-MP and 3H-Dex was associated with the retention of 5'ND activity in F1 fractions of both border zone and ischemic tissue. Similar protection of plasma membrane integritg occurred in the supernatant fraction as determined by changes in S/P ratios of 5'ND activity. These data provide support for the concepts that (1) plasma membrane changes occur soon after acute myocardial ischemia, and (2) the mechanism by which glucocorticoids exert a protective effect in myocardial ischemia may be related to membrane stabilization.     

TGF-beta inhibits IL-2-induced tyrosine phosphorylation and activation of Jak-1 and Stat 5 in T lymphocytes

The major yolk protein precursor in mosquito oocytes, vitellogenin (Vg), is internalized by a 205-kDa membrane-bound receptor (VgR). Recently, VgR has been isolated permitting the production of polyclonal anti-VgR antibodies. To elucidate the pathway of VgR internalization and recycling in mosquito oocytes during Vg uptake, we carried out an immunogold electron-microscopic study, labeling both Vg and VgR in ultrathin frozen sections of ovarian tissue. VgR immunolabeling demonstrated that the oocyte plasma membrane was subdivided into microdomains, with VgR being located between and at the lower portions of the oocyte microvilli. During the early stages of internalization, Vg and VgR were observed together in coated pits, coated vesicles, and early endosomes. Fusion of early endosomes created transitional yolk bodies (TYB) in which Vg and VgR became segregated. VgR label was present in the numerous tubular compartments that protruded from the TYBs. These tubular organelles extended to and fused with the plasma membrane, suggesting that they represented the vehicle for VgR recycling. Vg label was not observed in the tubular compartments. Instead, Vg accumulated in the core of the TYB, a region free of VgR label. Mature yolk bodies (MYB) were heavily labeled for Vg, but completely lacked any VgR label, indicating that MYB are storage compartments that do not participate in receptor recycling. Thus, our immunocytochemical data clearly visualize the steps in Vg/VgR internalization, dissociation, sorting, and recycling of the receptor to the plasma membrane.     

Protein associated with human lens 'native' membrane during aging and cataract formation

Plasma membrane contains extrinsic as well as intrinsic proteins. Changes in the extrinsic proteins of lens membrane during human aging and cataract formation have not been investigated in detail. Unlike previous studies which examined lens membrane after being stripped of extrinsic proteins by treatment with chaotropic agents, we have isolated whole or 'native' lens membrane on a sucrose gradient by ultracentrifugation of the total water-insoluble protein. Essentially all of the water-insoluble protein from young to aged to cataractous human lens appeared membrane associated. In young lens (20-37 years old), most of the membrane banded at the 25/45% sucrose interface fraction. This fraction contained relatively little urea-soluble protein and likely represents fiber-cell plasma membrane with its physiologically associated extrinsic and intrinsic proteins. With aging (62-80 years old), about one-third of the membrane, as judged by the distribution of cholesterol, banded at a much higher density (50/58% sucrose fraction). The higher density was due to a great increase in the membrane's relative protein content (protein/cholesterol). Although this extra protein was composed of both urea-insoluble and -soluble fractions, the urea-soluble protein predominated in all lenses. Cataractous lens differed from aged-clear lens in that much more of the total membrane (70-75%) had shifted to the high density and participated in this massive binding of cytosolic proteins. Although alpha-crystallin was the principal extrinsic-membrane protein in young lens, high molecular weight aggregate of modified (acidic) crystallins accounted for the increased extrinsic protein in aging. The extrinsic proteins bound to both clear-aged and cataractous lens membrane were aggregated. In conclusion, examination of human lens native membrane fractions revealed that the association of crystallins with membrane in both aging and cataracts was much greater than previously recognized and most of this increased protein was non-covalently bound to the membrane. Much more of the lens total membrane from cataractous than clear-aged lens was involved in this massive protein association and the protein bound to cataract membrane appeared more highly aggregated.     

Selective incorporation of architectural proteins into terminally differentiated molluscan gill cilia

Incubation of excised gills from the bay scallop Aequipecten irradians with 3H-leucine demonstrates that many ciliary structural proteins can attain a degree of labeling approaching that previously reported for sea urchin or surf clam embryos undergoing ciliary turnover or regeneration. This labeling is not a consequence of any predominant incorporation into new cilia at the meristematic growth tips of the gill since tissue regions of varying maturity incorporate label into the same proteins at similar levels, with the most mature region having the highest incorporation. Sodium dodecyl sulfate-polyacrylamide gel electrophoresis and fluorographic analysis of isolated cilia, separated into detergent-soluble membrane/matrix and detergent-insoluble 9+2 axoneme fractions, reveals that 1) tubulin in the membrane/matrix fraction is labeled whereas tubulin in the axoneme is not; 2) no labeled dynein heavy chains are seen in either fraction; 3) the most heavily labeled axonemal components do not appear to any significant extent in the membrane/matrix fraction; and 4) after thermal depolymerization of the microtubules, nearly all labeled proteins reside in the in-soluble ninefold ciliary remnant, the most prominent being tektin A, an integral component of outer doublet microtubules. Further fractionation of the remnant with sarkosyl-urea to produce tektin filaments demonstrates two solubility classes of tekin A, only the more soluble of which is labeled. Very similar selective architectural protein labeling patterns have been reported for steady-state cilia of sea urchin embryos, and this may indicate a widespread turnover or exchange mechanism characteristic of cilia heretofore considered static.