Lacrimal gland epithelial cells stimulate proliferation in autologous lymphocyte preparations.

Autoimmune dacryoadenitis is a frequent cause of lacrimal insufficiency. In order to test hypotheses regarding mechanisms that can trigger this syndrome, we developed a method to obtain a preparation of rabbit lacrimal gland epithelial cells essentially free of immune-system cells. The method relies on controlled digestion to disperse lacrimal acini, and recovers acini by filtration through various sizes of nylon mesh. Purity and integrity of the preparation were established qualitatively using light and electron microscopy. Contamination by immune-system cells was quantitated by immunohistochemistry using anti-CD18, and -RTLA (rabbit thymic lymphocyte antigen) antibodies. The novel method produced preparations of highly-purified lacrimal gland epithelial cells (pLGEC) with expected morphological characteristics with less than 1.5% of the cells staining for CD18 or RTLA. The method also yielded preparations of lacrimal gland interstitial cells (LGIC) enriched for lymphocytes; in these preparations either CD18 or RTLA were detected on nearly 10% of the cells. pLGEC promoted proliferation in preparations of autologous splenic lymphocytes (SPL) that was blocked by anti-MHC class II but not anti-MHC class I antibodies. This observation, combined with the apparent requirement that pLGEC must contact the autologous lymphocyte preparation to promote proliferation, supports the hypothesis the proliferation arises from antigen-presentation via MHC class II by pLGEC.

Autologous lacrimal-lymphoid mixed-cell reactions induce dacryoadenitis in rabbits.

Autoimmune dacryoadenitis, such as occurs in Sjögren's syndrome, is a frequent cause of lacrimal insufficiency, which in turn can cause dry eye. Rabbits are used frequently to test ocular therapies. Our goal is to develop a rabbit model of autoimmune dacryoadenitis to identify and test candidate therapies. Our approach arises from the observations that lacrimal gland epithelial cells stimulate proliferation in cultured autologous lymphocyte preparations and that an anti-MHC II antibody blocks this proliferation. The purpose of this study was to determine if injecting this proliferating autologous mixed cell reaction could induce dacryoadenitis in rabbits. After establishing that irradiated lacrimal gland epithelial cells stimulate proliferation in autologous peripheral blood lymphocytes, irradiated cells from a single lacrimal gland were co-cultured with autologous lymphocytes and after 5 days the mixed cell reaction, or components of the reaction, were injected into the contralateral lacrimal gland of the donor rabbit. After 2 weeks, the injected glands were removed and lymphocytic infiltration quantitated using digital image analysis of immunostained histological sections. Injecting an autologous mixed cell reaction of co-cultured irradiated lacrimal gland epithelial cells and lymphocytes reliably induced abundant periductal foci of >200 lymphocytes expressing CD18 and/or a rabbit thymic lymphocyte antigen (RTLA). Injection of medium or autologous lymphocytes alone elicited little response; injections of lymphocytes cultured with lysates of lacrimal gland epithelial cells elicited variable, modest responses. These lysates did not stimulate proliferation in the mixed cell reaction and proliferation was not observed if a porous membrane separated co-cultured lacrimal gland cells and lymphocytes. The results demonstrate that injecting an autologous mixed cell reaction of lacrimal gland epithelial cells and lymphocytes reliably creates a model of autoimmune dacryoadenitis. The relative ineffectiveness of components of the reaction to do the same supports the hypothesis that lacrimal gland epithelial cells trigger or exacerbate lacrimal autoimmune disease by presentation of autoantigens via MHC II. This experimental system can aid efforts to further understand mechanisms of diseases, and to identify and test candidate therapies.

Proliferation of lacrimal gland acinar cells in primary culture. Stimulation by extracellular matrix, EGF, and DHT.

The study of lacrimal dysfunction and insufficiency, a major cause of dry eye, has been hampered by the inability to induce the proliferation of primary lacrimal acinar cells in vitro. Particularly in light of observations that androgens are able to support the overall size and functional status of the lacrimal glands as well as certain specific lacrimal functions, an in vitro culture system that is permissive for cell proliferation would be most beneficial to study the molecular basis for these processes. Here, we report on the successful establishment of such a system. Using a culture system containing Hepato Stim Medium and Matrigel, we were able to induce the efficient proliferation of primary rabbit lacrimal gland acinar cells with epidermal growth factor (EGF) and dihydrotestosterone (DHT). The generation of this in vitro cell culture system should greatly facilitate study of the regulation of acinar cell function at the molecular and cellular levels.

Androgen influence on lacrimal gland apoptosis, necrosis, and lymphocytic infiltration.

PURPOSE: Previous studies have shown that ovariectomy and hypophysectomy cause regression of the lacrimal gland and have implicated androgens as trophic hormones that support the gland. The purposes of this study were to test the hypothesis that glandular regression after ovariectomy is due to apoptosis, to identify the cell type or types that undergo apoptosis, to survey the time course of the apoptosis, and to determine whether ovariectomy-induced apoptosis could be prevented by dihydrotestosterone (DHT) treatment. METHODS: Groups of sexually mature female New Zealand White rabbits were ovariectomized and killed at various time periods up to 9 days. Additional groups of ovariectomized rabbits were treated with 4 mg/kg DHT per day. At each time period, sham-operated rabbits were used as controls. Lacrimal glands were removed and processed for analysis of apoptosis as assessed by DNA fragmentation and for morphologic examination. DNA fragmentation was determined using the TdT-dUTP terminal nick-end labeling assay and by agarose gel electrophoresis. Labeled nuclei were quantified by automated densitometry. Sections were also stained for RTLA (rabbit thymic lymphocyte antigen), rabbit CD18, and La antigen. Morphology was evaluated by both light and electron microscopy. RESULTS: The time course of apoptosis exhibited two phases, a rapid and transient phase and a second prolonged phase. A transient phase peaked at approximately 4 to 6 hours after ovariectomy. The values for degraded DNA as a percentage of total nuclear area were 4.29%+/-0.79% and 4.26%+/-0.54%, respectively. The values for sham-operated controls examined at the same time periods were 1.77%+/-0.08% and 0.82%+/-0.21%, respectively. The percentage of degraded DNA at 24 hours after ovariectomy was not different from controls examined at the same interval after sham operation. The percentage of degraded DNA 6 days after ovariectomy was significantly increased (8.5%+/-2.4%), compared with sham-operated animals at the same time period (0.68%+/-0.03%). DNA laddering was more pronounced after ovariectomy. Dihydrotestosterone treatment in ovariectomized rabbits suppressed the increase in DNA degradation. Morphologic examination of lacrimal gland sections indicated that ovariectomy caused apoptosis of interstitial cells rather than acinar or ductal epithelial cells. Tissue taken 4 hours and 6 days after ovariectomy showed nuclear chromatin condensation principally in plasma cells. Increased numbers of macrophages were also evident. Significant levels of cell degeneration and cell debris, characteristic of necrosis, were observed in acinar regions 6 days after ovariectomy. Dihydrotestosterone prevented this necrosis. Increased numbers of RTLA+, CD18+, and La+ interstitial cells were also evident 6 days after ovariectomy. In addition, ovariectomy increased La expression in ductal cells. Dihydrotestosterone treatment prevented the increase in numbers of lymphoid cells and La expression. Dihydrotestosterone also promoted the appearance of mitotic figures in acinar cells and increased the sizes of acini by 43% (P < 0.05). CONCLUSIONS: Glandular atrophy observed after ovariectomy is likely to proceed by necrosis of acinar cells rather than apoptosis. This process begins with an apparent time lag after a rapid phase of interstitial cell apoptosis. These processes are accompanied by increased lymphocytic infiltration. These results suggest that a critical level of androgen is necessary to maintain lacrimal gland structure and function and that a decrease in available androgen below this level could trigger lacrimal gland apoptosis and necrosis, and an autoimmune response. Because apoptotic and necrotic cell fragments may be sources of autoantigens that can be processed and presented to initiate an autoimmune reaction, we surmise that cell death triggered by androgen withdrawal may trigger an autoimmune response such as that encountered in Sjögren's syndrome. (ABSTRACT TRUNCATED)

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.

Adenovirus infection of the cornea causes histopathologic changes in the lacrimal gland.

PURPOSE: To explore the effects on the lacrimal gland of adenovirus infection of the cornea. METHODS: Rabbit corneas were inoculated with human adenoviruses Ad5, Ad14, or a rabbit adapted form of Ad 5, and in some instances booster inoculations were given. Sections of lacrimal glands removed 21-59 days post-inoculation were immunostained using antibodies against rabbit Class I and Class II MHC molecules, CD4, CD8, CD18, and rabbit thymic lymphocyte antigen (RTLA). Relative numbers of positively stained cells were quantified with a Metamorph image analysis system. RESULTS: RTLA and CD18 antigens were expressed on many interstitial cells in the normal lacrimal gland, but few expressed CD4 or CD8. The number of RTLA+ cells increased by 60-100% after inoculation of Ad5 and after boosting, and CD18+ cells increased from 33-100% after inoculation of Ad5 and after boosting. Booster inoculations also caused focal lymphocytic infiltration. MHC Class I was expressed on interstitial cells and duct epithelium, but not acinar cells, and there was no detectable difference after viral infection. In controls, MHC Class II was localized to a population of interstitial cells and a few acinar cells. A single inoculation of the Ad5 virus did not result in an increase in the total number of MHC Class II-positive cells at 21 days, but inoculation with the rabbit-adapted Ad 5 and booster inoculations caused a 30% increase. CONCLUSIONS: Ad5 and rabbit-adapted Ad5 infection of the cornea induce lymphocytic infiltration in the lacrimal gland, and the effect is enhanced by boosting. There is also an increase in expression of MHC Class II after inoculation with rabbit-adapted Ad5 and with booster inoculations.

Androgen support of lacrimal gland function.

The effects of dihydrotestosterone (DHT) (1 mg/kg) on biochemical parameters related to lacrimal secretion, basal tear flow rate, and pilocarpine-stimulated lacrimal gland fluid secretion, in mature ovariectomized rabbits were studied. The effects of the synthetic estrogen diethylstilbestrol (DES) (100 micrograms/kg), on lacrimal gland biochemical parameters in normal mature female rabbits was also studied. Ovariectomy decreased the total serum levels of testosterone (T) by 88.5% and androstenedione by 35.9%, without changing the levels of dehydroepiandrosterone (DHEA) of its sulfate. Ovariectomy caused a significant regression of the lacrimal glands, decreasing total DNA by 35%, and total protein by 22%. DHT treatment of ovariectomized animals prevented lacrimal gland regression, increasing total gland DNA (31%) and total protein (18%). DHT treatment also increases Na+, K(+)-ATPase activity (29%) and beta-adrenergic receptor binding sites (23%) compared to the ovariectomized group. DHT increased pilocarpine stimulated lacrimal gland fluid secretion (13.26 +/- 1.47 microL/min) compared to the ovariectomized group (7.72 +/- 0.41 microL/min), but DHT treatment paradoxically decreased basal tear flow rate (1.02 +/- 0.04 microL/min) as compared to the ovariectomized rabbits (1.96 +/- 0.12 microL/min). DES decreased the total serum T from 59.33 +/- 10.54 pg/mL to 21.5 +/- 6.06 pg/mL. DES decreased total Na+,K(+)-ATPase by 12% and increased beta-adrenergic receptor binding sites by 83.3%. These results suggest that androgens play a major role in supporting lacrimal gland secretory function. Additionally, they suggest that estrogens may influence certain aspects of lacrimal functions, although it is not clear to what extent those actions are elicited directly or indirectly.

Hypophysectomy-induced regression of female rat lacrimal glands: partial restoration and maintenance by dihydrotestosterone and prolactin.

PURPOSE: Previous studies have implicated androgens and one or more as yet unknown pituitary or pituitary-dependent factors in the regulation of certain lacrimal gland functions. Many observations suggest that prolactin (PRL) might well be one of these factors. This study was designed to determine the effect of hypophysectomy on biochemical markers of exorbital lacrimal gland secretory capacity and to determine the extent to which dihydrotestosterone (DHT) and prolactin reverse these changes. METHODS: Female rats were hypophysectomized and, 5 days later, were treated for 2 days with DHT (0.25 or 1 mg/kg), PRL (1 or 5 mg/kg), combinations of the low or high doses of DHT and PRL, or vehicle only. The animals were killed, and crude membrane fractions were isolated from their lacrimal glands. An untreated group served as control. RESULTS: Lacrimal glands atrophied rapidly after hypophysectomy, losing 40% of their total and membrane-associated protein and 50% of their total DNA within 5 days. Total Na+,K(+)-ATPase and acid phosphatase activities and beta-adrenergic receptor number were decreased by half, whereas alkaline phosphatase activity and muscarinic cholinergic receptor number were reduced by 25% to 30%. DHT treatment increased total DNA above control values; it partially restored the amount of protein in the gland, the Na+,K(+)-ATPase and acid phosphatase activities, and the beta-adrenergic receptor number; and it fully restored the alkaline phosphatase activity. Prolactin treatment partially restored the amount of protein in the gland and the Na+,K(+)-ATPase activity; it fully restored the alkaline phosphatase activity and cholinergic receptor number; but it had no effect on the acid phosphatase activity or the beta-adrenergic receptor number. The high dose of DHT reduced the increase in cholinergic receptor number elicited by PRL. The high dose of PRL reduced the increases of total Na+,K(+)-ATPase and acid phosphatase elicited by DHT. CONCLUSIONS: These findings suggest that DHT and PRL exert general trophic actions on the lacrimal gland and specifically on lacrimal Na+,K(+)-ATPase, acid phosphatase, and neurotransmitter receptors. They also suggest that excessive levels of either hormone may be deleterious to secretory function. Because sex hormone levels are prone to wide fluctuations in women, our results also suggest a plausible hypothesis to account for the greater incidence in women of lacrimal insufficiency.

Sex-dependent parameters related to electrolyte, water and glycoprotein secretion in rabbit lacrimal glands.

The lacrimal glands of males and females of various species differ with respect to several morphological, biochemical and functional characteristics. The purpose of this study was to determine the effect of sexual maturation on Na+,K(+)-ATPase, muscarinic cholinergic receptors and beta-adrenergic receptors, which are closely related to the secretion of electrolytes and fluid by the gland, and on other membrane-associated enzymes, specifically galactosyltransferase and alkaline and acid phosphatase. Soluble and total membrane fractions were obtained from lacrimal glands of prepubertal (1.0 kg), pubertal (2 kg), and mature (4 kg) of New Zealand white rabbits of both sexes. Prepubertal and pubertal rabbits exhibited no sex differences in the total amount of lacrimal gland protein or in any of the enzymes or receptors, with the exception of galactosyltransferase and alkaline phosphatase. Galactosyltransferase had higher total and specific activities in prepubertal and pubertal males, and alkaline phosphatase had higher specific activity in prepubertal males. As animals matured, total protein and activities of the enzymes increased, and several quantitative differences between males and females became apparent. Samples from mature females contained significantly less DNA and membrane and total protein. Specific activities of Na+,K(+)-ATPase, cholinergic receptors, galactosyltransferase, and acid and alkaline phosphatase were 40% to 80% greater (p < 0.05) in mature females. Total and specific activity for beta-adrenergic receptors, on the other hand, were higher in the male rabbits. These findings suggest that sex hormones play a role in regulating the levels of expression of a number of enzymes and receptors, including several which are clearly involved in lacrimal secretory functions.

Inhibition of sodium-phosphate cotransport in renal brush-border membranes with the stilbenedisulfonate, H2-DIDS.

Membrane proteins involved with sodium/phosphate cotransport across the renal brush border provide the sensitive control for phosphate homeostasis. The present study describes the inhibition of sodium/phosphate cotransport with the stilbenedisulfonate derivatives, DIDS and H2-DIDS. Preincubation of the rat brush-border membrane vesicles with H2-DIDS led to the inhibition of sodium-dependent phosphate uptake with a half maximal concentration, IC50, of about 10 microM. The inhibition was irreversible supporting the notion that H2-DIDS forms covalent bonds with the cotransporter. The cotransporter could be protected by excess sodium phosphate but not sodium chloride, sodium sulfate, sodium succinate, sodium bicarbonate, nor sodium phosphonoformate. These observations suggest that the stilbenedisulfonates may be useful in labeling the sodium/phosphate cotransporter within renal brush-border membranes.

Sodium excretion and renal precession of sodium over inulin.

Renal excretory patterns for inulin and 22Na were measured in rats after simultaneous injection into a renal artery. In normal rats, the excretion of 22Na was much faster than inulin. This is referred to as "precession of sodium" and showed that some of the excreted 22Na had bypassed the intratubular route. During water diuresis, 65% of excreted 22Na was excreted before inulin. The quantity of 22Na preceding inulin (0.10 +/- 0.03% of the amount injected) increased eightfold during infusion of atrial natriuretic peptide (ANP). In saline diuresis, 45% of excreted 22Na (1.47 +/- 0.39% of the amount injected) preceded inulin, but precession was not affected by ANP. In rats with a nephrotic syndrome, 13% of excreted 22Na (0.34 +/- 0.12% of the amount injected) preceded inulin during saline diuresis and increased to 1.66 +/- 0.53% of the amount injected during the infusion of ANP. Precession of sodium was completely abolished in kidneys with papillary necrosis, suggesting that 22Na entered the tubular lumen in the inner medulla. These experiments demonstrate that, in rats, a large fraction of excreted sodium enters the tubules by a route other than filtration. The quantity of sodium entering the tubules by this route shows a 10- to 15-fold variation under conditions that modify the rate of sodium excretion.

Some characteristics of sodium-independent phosphate transport across renal basolateral membranes.

Sodium-independent phosphate transport was evaluated in porcine renal basolateral membrane vesicles. Phosphate uptake was saturable with an apparent Km 10.1 +/- 1.2 mM and Vmax 13.6 +/- 2.0 nmol (mg protein)-1 min-1, n = 5. Phosphate uptake was trans-stimulated with intravesicle phosphate and was enhanced with a positive transmembrane electrical potential. Arsenate and bicarbonate inhibited phosphate transport but other anions including sulfate and phosphonoformate were without effect. These studies indicate that phosphate uptake across basolateral membranes is present in the absence of sodium, is facilitated, and is specific for phosphate. The apparent affinity and rate of phosphate transport across the basolateral membrane is significantly higher than the respective parameters observed for the brush-border membrane.

Effects of atrial natriuretic factor on renal handling of water and electrolytes in rats.

The intravenous injection of an extract of atrial myocardium into anesthetized rats during a hypotonic diuresis resulted in an increase in the renal excretion of water, sodium, potassium, calcium, magnesium, and phosphate. There was an increase in urine concentration which was probably a result of the secretion of vasopressin since it did not occur in Brattleboro (di/di) rats. A transient increase in glomerular filtration rate and renal plasma flow occurred during the first five minutes with a more sustained rise in filtration fraction. Injection of atrial extract also caused a partial inhibition of solute-free water formation in Brattleboro rats subjected to water diuresis and a partial inhibition of solute-free water reabsorption in rats subjected to maximal antidiuresis by infusing vasopressin. In neither case was the degree of inhibition as profound as that observed after injecting furosemide in a dose which caused a comparable natriuretic response. A large dose of furosemide blocked the natriuretic response to atrial extracts whereas, when a comparable level of sodium and water output was produced by massive infusions of saline, the natriuretic response to atrial extract was increased. It is suggested that atrial natriuretic factor might inhibit sodium transport in nephron segments beyond the medullary thick ascending limb. Furosemide might also act at the same tubular site or inhibit tubular secretion of the atrial natriuretic factor.