Francie A. Yarber

Actin and non-muscle myosin II facilitate apical exocytosis of tear proteins in rabbit lacrimal acinar epithelial cells

The acinar epithelial cells of the lacrimal gland exocytose the contents of mature secretory vesicles containing tear proteins at their apical membranes in response to secretagogues. Here we use time-lapse confocal fluorescence microscopy and fluorescence recovery after photobleaching to investigate the changes in actin filaments located beneath the apical membrane during exocytosis evoked by the muscarinic agonist, carbachol (100 μM). Time-lapse confocal fluorescence microscopy of apical actin filaments in reconstituted rabbit lacrimal acini transduced with replication-deficient adenovirus containing GFP-actin revealed a relatively quiescent apical actin array in resting acini. Carbachol markedly increased apical actin filament turnover and also promoted transient actin assembly around apparent fusion intermediates. Fluorescence recovery after photobleaching measurements revealed significant (P≤0.05) increases and decreases, respectively, in mobile fraction (Mf) and turnover times (t½) for apical actin filaments in carbachol-stimulated acini relative to untreated acini. The myosin inhibitors, 2,3-butanedione monoxime (BDM, 10 mM, 15 minutes) and ML-7 (40 μM, 15 minutes), significantly decreased carbachol-stimulated secretion of bulk protein and the exogenous secretory vesicle marker, syncollin-GFP; these agents also promoted accumulation of actin-coated structures which were enriched, in transduced acini, in syncollin-GFP, confirming their identity as fusion intermediates. Actin-coated fusion intermediates were sized consistent with incorporation of multiple rather than single secretory vesicles; moreover, BDM and ML-7 caused a shift towards formation of multiple secretory vesicle aggregates while significantly increasing the diameter of actin-coated fusion intermediates. Our findings suggest that the increased turnover of apical actin filaments and the interaction of actin with non-muscle myosin II assembled around aggregates of secretory vesicles facilitate exocytosis in lacrimal acinar epithelial cells.

Cytoplasmic dynein participates in apically targeted stimulated secretory traffic in primary rabbit lacrimal acinar epithelial cells

A major function of the acinar cells of the lacrimal gland is the production and stimulated release of tear proteins into ocular surface fluid. We investigate the participation of cytoplasmic dynein in carbachol-stimulated traffic to the apical plasma membrane in primary rabbit lacrimal acinar epithelial cells. Confocal fluorescence microscopy revealed a major carbachol-induced, microtubule-dependent recruitment of cytoplasmic dynein and the dynactin complex into the subapical region. Colocalization studies, sorbitol density gradient/phase partitioning analysis and microtubule-affinity purification of membranes showed that some dynein and dynactin complex were associated with VAMP2-enriched membranes. Adenovirus-mediated overexpression of p50/dynamitin inhibited the recruitment and colocalization of dynein, the dynactin complex and VAMP2 in the subapical region. Nocodazole treatment and p50/dynamitin overexpression also depleted subapical stores of rab3D in resting acini, suggesting that dynein activity was also involved in maintenance of rab3D-enriched secretory vesicles. These data implicate cytoplasmic dynein in stimulated traffic to the apical plasma membrane in these secretory epithelial cells.

Taxol inhibits endosomal-lysosomal membrane trafficking at two distinct steps in CV-1 cells

Although taxol inhibits membrane trafficking, the nature of this inhibition has not been well defined. In this study, we define the effects of taxol on endocytosis in CV-1 cells using density gradient centrifugation of membranes over sorbitol density gradients. After taxol treatment, resident endosomal enzymes and the epidermal growth factor (EGF) receptor (EGFR) showed significant ( P ≤ 0.05) enrichment in membranes with properties of early endosomes ( fractions 4 and 5); the EGFR and Na+-K+-ATPase were also significantly ( P ≤ 0.05) depleted in lysosomal fractions ( fractions 10 and 11). The suggestion that taxol specifically reduces movement of endosomal constituents to lysosomes was supported by fluorescence microscopy studies revealing restriction of EGF to the peripheries of taxol-treated cells, in contrast to the perinuclear lysosomal-like distribution of EGF seen in controls. Kinetic studies with 125I-labeled EGF were also consistent with a taxol-induced block in traffic from endosomes and lysosomes after 15 min of uptake but also suggested an additional taxol-sensitive step in trafficking that involved redistribution of 125I-EGF within high-density compartments after 150 min. Related changes in cytoplasmic dynein distribution were observed within high-density compartments from taxol-treated cells, suggesting that this motor might participate in this later taxol-sensitive trafficking event. Electron microscopic examination of high-density membranes ( fraction 12) showed that taxol increased the numbers of small (<500 nm) dense vesicles, with a relative depletion of the larger (>500 nm) vesicles found in controls. These data demonstrate that disruption of endocytic events by taxol includes the early accumulation of protein and endocytic markers in endosomes and the later accumulation in a dense compartment that we propose is a subdomain of the lysosomes.

Cytoskeletal participation in stimulated secretion and compensatory apical plasma membrane retrieval in lacrimal gland acinar cells.

One of the main functions of the lacrimal gland is the regulated secretion of tear fluid, rich in proteins and electrolytes, in response to signals provided through the sympathetic and parasympathetic nervous system. Since proper tear-fluid secretion is essential for maintenance of ocular health, a long-term focus of our laboratory has been to understand the molecular mechanisms governing regulated secretion in lacrimal acini. In particular, we have focused on the role of microtubules (MTs), actin-based microfilaments (MFs), and motor proteins associated with either filament system in the stimulated lacrimal acinar secretory response. MTs and MFs constitute two of the three major cytoskeletal filament systems in mammalian cells, the third system being the intermediate filaments.

Adenoviral capsid modulates secretory compartment organization and function in acinar epithelial cells from rabbit lacrimal gland.

Although adenovirus (Ad) exhibits tropism for epithelial cells, little is known about the cellular effects of adenoviral binding and internalization on epithelial functions. Here, we examine its effects on the secretory acinar epithelial cells of the lacrimal gland, responsible for stimulated release of tear proteins into ocular fluid. Exposure of reconstituted rabbit lacrimal acini to replication-defective Ad for 16–18 h under conditions that resulted in >80% transduction efficiency did not alter cytoskeletal filament or biosynthetic/endosomal membrane compartment organization. Transduction specifically altered the organization of the stimulated secretory pathway, eliciting major dispersal of rab3D immunofluorescence from apical stores normally associated with mature secretory vesicles. Biochemical studies revealed that this dispersal was not associated with altered rab3D expression nor its release from cellular membranes. Ultraviolet (UV)-inactivated Ad elicited similar dispersal of rab3D immunofluorescence. In acini exposed to replication-defective or UV-inactivated Ad, carbachol-stimulated release of bulk protein and β-hexosaminidase were significantly (P⩽0.05) inhibited to an extent proportional to the loss of rab3D-enriched mature secretory vesicles associated with these treatments. We propose that the altered secretory compartment organization and function caused by Ad reflects changes in the normal maturation of secretory vesicles, and that these changes are caused by exposure to the Ad capsid.

Aerosolization of Infectious Virus by Excimer Laser

PURPOSE To determine the potential for aerosolization of infectious virus present within the tear film during excimer laser photoablation of the cornea. METHODS Cell monolayers infected with herpes simplex virus or adenovirus, simulating virus-infected corneas, were ablated with the 193-nm excimer laser. Adjacent dishes containing noninfected cell monolayers were subsequently assayed for viral infection. RESULTS Viral spread to sentinel dishes occurred with both herpes simplex and adenovirus. The titer of virus present in the infected cell monolayers influenced the likelihood of spread to adjacent dishes. The presence of a vacuum aspiration system appeared to influence the direction of virus spread, with dishes located in the direction of the vacuum most likely to contain virus. CONCLUSIONS The potential for aerosolization of infectious virus exists with photoablation using a large-diameter excimer laser beam. Our experimental design, however, does not prove that spread of infectious virus is likely to occur in the clinical setting. Appropriate measures should be taken to reduce the possibility of the spread of virus from the patient to the surgeon, other medical staff, or other patients.

Transduced viral IL-10 is exocytosed from lacrimal acinar secretory vesicles in a myosin-dependent manner in response to carbachol

The purpose of this study was to determine the intracellular trafficking and release pathways for the therapeutic protein, viral IL-10 (vIL-10), from transduced acinar epithelial cells from rabbit lacrimal gland. Primary cultured rabbit lacrimal gland acinar cells (LGACs) were transduced with adenovirus serotype 5 containing viral interleukin-10 (AdvIL-10). The distribution of vIL-10 was assessed by confocal fluorescence microscopy. Carbachol (CCH)-stimulated release of vIL-10 was quantified by ELISA. vIL-10 localization and exocytosis was probed in response to treatments with agents modulating actin- and myosin-based transport. vIL-10 immunoreactivity was detected in large intracellular vesicles in transduced LGAC. vIL-10 was partially co-localized with biosynthetic but not endosomal compartment markers. vIL-10 release was sensitive to CCH, and the kinetics of release showed an initial burst phase that was similar but not identical to that of the secretory protein, beta-hexosaminidase. Disassembly of actin filaments with latrunculin B significantly increased CCH-stimulated vIL-10 secretion, suggesting that vIL-10 was released from stores sequestered beneath the subapical actin barrier. That release required the activity of actin-dependent myosin motors previously implicated in secretory vesicle exocytosis was confirmed by findings that CCH-stimulated vIL-10 release was reduced by inhibition of non-muscle myosin 2 and myosin 5c function, using ML-7 and overexpression of dominant negative myosin 5c, respectively. These results suggest that the majority of vIL-10 transgene product is packaged into a subpopulation of secretory vesicles that utilize actin-dependent myosin motors for aspects of actin coat assembly, compound fusion and exocytosis at the apical plasma membrane in response to CCH stimulation.