Traffic of major histocompatibility complex class II molecules in rabbit lacrimal gland acinar cells.

PURPOSE: It has been suggested that lacrimal gland acinar cells, which have been induced to express major histocompatibility complex class II (MHC II) molecules, might initiate local autoimmunity by using mechanisms similar to those operating in the specialized antigen-presenting cells to process and present autoantigens. Surface-labeling experiments indicate that constituents of the acinar cell plasma membrane participate in a rapid recycling traffic. The authors have surveyed the subcellular distribution of MHC II molecules and have evaluated their participation in the traffic between plasma membranes and intracellular compartments. METHODS: Acinar cells were isolated from rabbit lacrimal glands and maintained for two nights in a serum-free, hormone-supplemented culture medium containing 10 microM carbachol. MHC II molecules were detected with a monoclonal antibody (MAB 2C4), biotinylated goat-antimouse IgG (BGAM), and avidin-ferritin (AvFe) or streptavidin-gold (SAvAu) conjugates. RESULTS: Postembedding labeling with MAB 2C4, BGAM, and AvFe revealed MHC II molecules at the surface membranes, in cytoplasmic vesicles, and in secretory vesicles. When cells were chilled to 4 degrees C and subjected to preembedding labeling with MAB 2C4, BGAM, and AvFe, surface MHC II molecules were specifically labeled. Labeled complexes were rapidly internalized upon warming to 37 degrees C. Postembedding labeling with MAB 2C4, BGAM, and SAvAu revealed additional intracellular MHC II molecules, with a distribution overlapping that of the MHC II molecules labeled during the preembedding procedure. When cells were cultured overnight in the presence of MAB 2C4 and subjected to postembedding labeling with BGAM and AvFe, label was detectable in small vesicles and in secretory vesicles. However, the extent of labeling appeared less than obtained with postembedding labeling with MAB 2C4, BGAM, and AvFe. Preembedding labeling of cells that had been incubated overnight with MAB 2C4 indicated that the cells continued to express MHC II molecules at their surface membranes, and rapid internalization of label upon warming to 37 degrees C confirmed that MHC II molecule traffic continued in the presence of MAB 2C4. Postembedding labeling with MAB 2C4, BGAM, and SAvAu indicated the continued presence of a large intracellular pool of MHC II molecules. CONCLUSIONS: MHC II molecules in lacrimal acinar cells are present in large intracellular and small surface pools. They move rapidly between these two pools, but further work will be required to determine whether the MHC II molecule traffic represents recycling or turnover and whether recycling pools and sequestered pools coexist. The presently available data make it reasonable to propose that the traffic of MHC II molecules to plasma membranes provides a mechanism by which acinar cells display intracellularly generated autoantigens to potentially reactive helper T lymphocytes.

Rabbit lacrimal acinar cells in primary culture: morphology and acute responses to cholinergic stimulation.

PURPOSE: The rabbit lacrimal gland yields large numbers of viable acinar cells that, when exposed to carbachol, respond with accelerated protein release, fluid phase endocytosis (Lucifer yellow uptake), and Na/H antiport activation. The current study was undertaken to determine whether such cells exhibit similar responses after having been maintained in primary culture. METHODS: Cells were isolated from 2-kg, juvenile male New Zealand White rabbits and maintained in a supplemented DMEM/Ham's F-12 medium for up to 72 hours. RESULTS: Electron microscopy showed the organization of freshly isolated cells to be highly polarized, with secretory vesicles at one pole and nucleus at the other; vesicles were heterogeneous in size and in the electron density of their contents. The cells remained polarized after overnight culture, but the secretory vesicle population was more homogeneous in size and content, and the cells tended to aggregate. After 72 hours, roughly half the cells retained good morphology and cytoplasmic polarization, but the vesicles were enlarged and their contents less electron dense. Cells that had been maintained overnight responded to the addition of 10 microM carbachol with a 32.2% +/- 15.5% (n = 12, P < 0.04) increase in the total amount protein released during a standard 20-minute incubation. This represented a mean 125% increase in the temperature-dependent component of protein release. The protein secretory response was decreased to 14.6% +/- 6.1% (n = 3, P < 0.07) for cells that had been maintained for 72 hours. In the same samples, carbachol increased fluid phase endocytosis by 38.3% +/- 8.1% (P < 0.01) and 70.9% +/- 13.4% (P < 0.025), respectively. The protein secretory response was partially, and the endocytic response fully blocked by 1 mM atropine. CONCLUSIONS: This model could be useful as a simplified system in which to study regulation of acinar cell function over days, rather than hours, as is required in fresh tissue models.

Plasma membrane internalization and recycling in rabbit lacrimal acinar cells.

PURPOSE: The purpose of this study was to examine internalization and recycling of plasma membrane constituents in lacrimal gland acinar cells. METHODS: Acinar cells were isolated from rabbit lacrimal glands. Surface-expressed reactive groups were biotinylated at 4 degrees C with sulfo-N-hydroxysuccinimidyl-biotin. Incorporated biotin was then labeled with avidin-horseradish peroxidase complex for light microscopy, with avidin-lucifer yellow conjugate for fluorescence microscopy, and quantitative fluorometry, and with avidin-ferritin conjugate for electron microscopy. RESULTS: At 4 degrees C labels remained at the surfaces of intact cells. Surface avidin-lucifer yellow decreased markedly, giving way to punctate cytoplasmic labeling, on warming to 37 degrees C. Electron microscopy of cells warmed after labeling with avidin-ferritin revealed ferritin in smooth vesicles underlying the plasma membranes, in vesicles adjacent to Golgi membranes, and in multivesicular bodies. Incubation at 37 degrees C before chilling and labeling with avidin-lucifer yellow decreased the cells' capacity to bind avidin-lucifer yellow by 95%, with t0.5 < 0.5 min. If cells were then incubated with avidin-lucifer yellow at 37 degrees C, they took up the marker with a time course that indicated that 60% of the initial biotin either recycled back to the plasma membrane or remained in intracellular compartments that could be reached by endocytosed extracellular fluid. Internalized biotin communicated with extracellular avidin-lucifer yellow with a t0.5 of 2 min, and this process was accelerated by carbachol at concentrations of 10 mumol/l and 1 mmol/l. CONCLUSIONS: Acinar cell plasma membrane constituents participate in an ongoing, secretagogue-modulated recycling traffic between small surface-expressed pools and 10- to 20-fold larger intracellular pools.

Class II antigen expression by lacrimal epithelial cells. An updated working hypothesis for antigen presentation by epithelial cells.

It has been suggested that aberrant expression of Class II histocompatibility antigens (HLA) is involved in T cell activation and leads to autoimmunity. Although Class II antigen expression was found in various nonlymphoid tissues, including salivary glands, its expression on lacrimal epithelial cells has not been reported. In this study, 12 cadaver lacrimal glands were analyzed for HLA-DR and for the numbers and distributions of T suppressor cells (Ts), T helper cells (Th), B cells, and macrophages. None of these cases exhibited the high numbers of inflammatory cells, tissue damage, and fibrosis characteristic of Sjogren's syndrome. The HLA-DR-positive epithelial cells were detected in ten cases; they represented from less than 1% to more than 70% of the epithelial cells. In these ten positive cases, there were greater numbers of T cells per millimeter squared (229 +/- 94 [mean +/- the standard error of the mean]) than in the two HLA-DR-negative cases (37 +/- 1 [mean +/- range]). Three lacrimal gland specimens tested were negative for immunoglobulin (Ig) G-bearing B cells, and two of the three specimens tested had IgA-bearing cells. Acinar cells were isolated from rat and rabbit lacrimal glands and cultured overnight in serum-free media supplemented with several potential mediators of Class II antigen expression: interferon-gamma, carbachol, or isoproterenol. Freshly isolated cells did not express Class II antigens at detectable levels, but in most experiments, they began to express the antigen even in the absence of putative mediators.(ABSTRACT TRUNCATED AT 250 WORDS)

Purification of rabbit lacrimal gland plasma membranes by aqueous two-phase affinity partitioning.

We describe the purification of lacrimal gland plasma membranes by affinity partitioning using a two-phase system containing polyethylene glycol and dextran in which wheat germ agglutinin conjugated to dextran is used as affinity ligand. When partitioning a microsomal fraction, the plasma membrane marker 5'-nucleotidase was obtained in the affinity ligand-containing bottom phase, whereas the endoplasmic reticulum marker NADH-ferricyanide reductase remained in the top phase. The affinity partitioning behaviour of components involved in exocytosis and cellular signalling was also examined.

Fluid phase endocytosis by isolated rabbit lacrimal gland acinar cells.

It is well known that lacrimal gland acinar cells retrieve secretory vesicle membrane constituents from their apical plasma membranes after stimulated exocytosis of secretory proteins. There have also been indications of a recycling traffic involving the basal-lateral plasma membranes. In an effort to document this traffic, determine how it is regulated, and discern whether it involves more than one intracellular compartment, we studied internalization of the fluid phase marker, Lucifer Yellow, and its relationship to protein release in acinar cells isolated from rabbit lacrimal glands. Loading of intracellular vesicles was apparent with fluoresence microscopy. Stimulation with carbachol increased both the rate of internalization and the intracellular volume equilibrating with extracellular fluid, suggesting the loading of two compartments. A carbachol concentration of 10 microM increased uptake by 80% during 20-min incubations at 37 degrees C. Increasing the carbachol concentration to 1 mM reduced the response by 50%, and it appeared to do so by decreasing the intracellular volume accessible to extracellular fluid, rather than the rate of endocytosis. Carbachol affected protein release differently, increasing it by 50% at 10 microM and 80% at 1 mM. Acceleration of endocytosis by 10 microM carbachol was transient, becoming negligible after 60 min. Vasoactive intestinal peptide (VIP) and isoproterenol increased internalization 35% and 25% respectively; neither reduced uptake at the highest concentrations tested; and only isoproterenol significantly affected protein secretion. Combinations of VIP and carbachol exerted synergistic effects on both fluid phase internalization and protein release. Steady-state uptake at 18 degrees C in the presence of 10 microM carbachol was equal to uptake at 37 degrees C in the absence of carbachol, suggesting a temperature block in the pathway to at least one endocytic compartment. Decreasing the temperature to 18 degrees C eliminated the inhibitory action of excessive carbachol, suggesting that the compartment whose loading was impaired by excessive carbachol was positioned distal to the temperature block. Carbachol accelerated release of marker from preloaded cells, indicating that it stimulated recycling between the plasma membranes and endocytic compartments. This effect was maximal at a concentration of 10 microM and unchanged with increasing concentrations. In accord with the hypothesis that traffic into and out of a certain compartment was particularly dependent on stimulation, a fraction of the marker taken up by optimally stimulated cells at 37 degrees C was retained unless carbachol or VIP was present in the efflux medium.(ABSTRACT TRUNCATED AT 400 WORDS)

Cholinergic stimulation of lacrimal acinar cells promotes redistribution of membrane-associated kinesin and the secretory protein, beta-hexosaminidase, and increases kinesin motor activity.

The role of the microtubule-based motor, kinesin, in membrane trafficking has been investigated in resting and stimulated acinar cells from rabbit lacrimal gland, a cholinergically controlled secretory tissue. Microtubule-dependent motors from extracts of control and carbachol-treated acini were isolated by microtubule-affinity purification and their activity was determined using a video-enhanced differential interference contrast microscopy assay for microtubule gliding. The observation that carbachol treatment resulted in a 2.2-fold stimulation of the frequency of GTP-dependent microtubule gliding in fractions isolated by microtubule-affinity purification and GTP release suggested that kinesin was a target of carbachol-induced stimulation. Resolution of membranes from resting cells by fractionation on a sorbitol density gradient followed by partitioning analysis in a dextran-polyethyleneglycol two-phase system revealed that membrane-associated kinesin codistributed with Golgi-derived membranes, a post-Golgi secretory compartment designated Hex1, membranes from a trans Golgi network-like compartment, endoplasmic reticulum and a group of putative lysosomal membranes containing cathepsin B. Comparable fractionation of carbachol-treated acini showed that stimulation caused redistributions of membrane-associated kinesin, the secretory enzyme beta-hexosaminidase, and galactosyltransferase that appeared to reflect both a reorganization within the Golgi complex and a return of material to the Golgi complex from the secretory pathway. Our findings that carbachol promotes activation of lacrimal acinar kinesin as well as major shifts in kinesin-membrane association within the secretory pathway suggests that kinesin plays a major role in secretory vesicle assembly, apical secretion, and/or secretory vesicle membrane recycling in the lacrimal gland.

Prolactin and prolactin receptors in the lacrimal gland.

Light and electron microscopic immunocytochemistry, in situ hybridization and Dot Blot analysis revealed intracellular localization of prolactin-like molecules and prolactin mRNA in epithelial cells of the lacrimal glands of rabbits. There was also positive immunostaining for prolactin receptors on acinar cells and some interstitial cells. On Western blots of homogenates of whole lacrimal gland, isolated lacrimal acinar cells, isolated lacrimal interstitial cells and peripheral blood lymphocytes, prolactin antibody consistently labeled protein bands migrating at approximately 36 and 50 kD. These data confirm that lacrimal gland acinar cells produce endogenous prolactin-like molecules, but also express prolactin receptors. Since prolactin immunoreactivity has been detected in tear fluid and we found no accumulations of immunogold label in endocytic or transport vesicles, we hypothesize that the prolactin-like molecules in tear fluid originate primarily from synthesis within the acinar cells. We hypothesize further that prolactin from pituitary and other non-acinar cell origin has a modulating influence on acinar cell activity as well as immune function in the lacrimal gland, and that some of the prolactin-like molecules produced by the acinar cells contribute to these functions by autocrine/paracrine mechanisms.

Na-K-ATPase in lacrimal gland acinar cell endosomal system: correcting a case of mistaken identity.

Na-K-ATPase is associated with a variety of membrane populations in lacrimal acinar cells. Acinus-like structures formed by rabbit acinar cells in primary culture were incubated with horseradish peroxidase (HRP) to label basolateral and endosomal membranes and then analyzed by electron microscopy cytochemistry with the 3-3'-diaminobenzidine reaction or by fractionation and measurement of marker catalytic activities or immunoreactivities. HRP adsorbed to basolateral membranes at 4 degrees C. Fractionation showed it associated with low-density membranes enriched in acid phosphatase and TGN38 but containing only minor amounts of Na-K-ATPase. Cells internalized HRP to cytoplasmic vesicles, Golgi structures, and lysosomes at 37 degrees C. The major endosomal compartment revealed by fractionation coincided with major peaks of Na-K-ATPase and Rab6 and secondary peaks of galactosyltransferase and gamma-adaptin. Carbachol (10 microM) increased lysosomal and Golgi labeling. Thus most of the Na-K-ATPase is located in the basolateral membrane-oriented endosomal system, concentrated in a compartment possibly related to the trans-Golgi network. Constitutive and stimulation-accelerated traffic to and from this compartment may serve several exocrine cell functions.

Sjögren's autoimmunity: how perturbation of recognition in endomembrane traffic may provoke pathological recognition at the cell surface.

CD4 T cell antigen recognition requires presentation by major histocompatibility complex Class II molecules (MHC II). B cell surface immunoglobulins recognize antigens independently of MHC II, but activation typically requires CD4 cell cytokines as accessory signals. Plasma membrane-endomembrane traffic in lacrimal gland acinar cells, targets of autoimmune activity in Sjögren's syndrome, may satisfy both requirements. The Golgi protein galactosyltransferase and the lysosomal proteins cathepsin B and cathepsin D appear at the plasma membranes during sustained secretomotor stimulation. The RNA transcription termination factor La, a frequent target of Sjögren's autoantibodies, appears in the acinar cell cytoplasm and plasma membranes during viral infection and during in vitro exposure to cytokines. MHC II cycle through endomembrane compartments which contain La, galactosyltransferase, cathepsin B and cathepsin D and which are sites of proteolysis. This traffic may permit trilateral interactions in which B cells recognize autoantigens at the surface membranes, CD4 T cells recognize peptides presented by MHC II, B cells provide accessory signals to CD4 T cells, and CD4 T cells provide cytokines that activate B cells. Acinar cells stimulate lymphocyte proliferation in autologous mixed cell reactions, confirming that they are capable of provoking autoimmune responses.