Effects of local anesthetics and related compounds on the endocytosis and catabolism of asialo-glycoproteins in isolated hepatocytes

The effects of local anesthetics, including procaine and dibucaine, and some related amine compounds, such as dansyl-cadaverine, were studied with respect to their effects on the uptake and degradation of asialo-glycoproteins in isolated hepatocytes 0.5 mM of either dibucaine or dansyl-cadaverine reduced the rates of uptake to 18–19% of control values; other amines were less effective. Dibucaine and dansyl-cadaverine both acted by reducing the surface binding capacity of the cells as well as by reducing the rate of internalization of surface-bound asialo-glycoprotein. All of the compounds that affected the uptake, including dansyl-cadaverine, also reduced the rate of degradation. This effect could be studied separately from their effect on uptake. The concentrations that were required in order to reduce degradation were, in general, 0.5-0.25 of those which caused a reduction in the uptake. Even though dibucaine, lidocaine and dansyl-cadaverine were found to accumulate in the lysosomes, it was concluded from studies with isopycnic centrifugation in sucrose gradients that all three compounds inhibited the rate of transfer of endocytosed protein from endocytic vesicles to lysosomes. This effect could be due to a reduced rate of fusion between endocytic vesicles and lysosomes.     

Calcium in hippocampus following lidocaine induced seizures: an electron cytochemical study

The effect of lidocaine seizures on cellular accumulation of calcium was studied in hippocampal subfields CA1 and CA3 and the dentate gyrus of rats, using the combined oxalate-pyroantimonate method. The specificity of the reaction was ascertained by EGTA treatment and X-ray microanalysis. In control rats, calcium was visualized between myelin lamellae of axons, in synaptic vesicles and in some lysosomes. Two hours after onset of lidocaine seizures selective neuronal degenerations appeared in hippocampal subfields CA1 and CA3 but not in the dentate gyrus. Calcium deposits were present in numerous mitochondria of pyramidal cells and, occasionally, also of neuroglial cells. Many of these mitochondria exhibited ultrastructural alterations. Calcium uptake was most prominent in the CA3 sector but was also present in the CA1 subfield as well as the dentate gyrus. Intracellular calcium uptake, in consequence, is not the unique attribute of selectively vulnerable hippocampal neurons.     

Effect of local anesthetic lidocaine on electrostatic properties of a lipid bilayer

The influence of the local anesthetic lidocaine on electrostatic properties of a lipid membrane bilayer was studied by molecular dynamics simulations. The electrostatic dipole potential, charge densities, and orientations of the headgroup angle have been examined in the presence of different amounts of charged or uncharged forms of lidocaine. Important changes in the membrane properties caused by the presence of both forms of lidocaine are presented and discussed. Our simulations have shown that both charged and uncharged lidocaine cause almost the same increase in the electrostatic potential in the middle of the membrane, although for different reasons. The increase, ∼90 mV for 9 mol % of lidocaine and 220 mV for 28 mol % of lidocaine, is of a size that may affect the functioning of voltage-gated ion channels.     

The tumescent technique: the effect of high tissue pressure and dilute epinephrine on absorption of lidocaine

Injection of lidocaine into the subcutaneous tissues by the tumescent technique results in a delayed absorption of the local anesthetic and has allowed clinicians to exceed the maximum recommended dose of lidocaine without reported complications. However, little knowledge exists about the mechanisms that permit such high doses of lidocaine to be used safely with this technique. The presence of low concentration epinephrine and the increased tissue pressure resulting from the tumescent injection have both been implicated as important factors, but neither has been studied in patients whose results were not altered by the variability of the suction procedure. The purpose of this work was to determine the effect of tissue pressure during tumescent injection and presence of low concentration epinephrine on the absorption of lidocaine from subcutaneous tissues in human volunteers. Twenty healthy female human volunteers were randomized into four study groups. After body fat measurements, all subjects received an injection of 7 mg/kg of lidocaine into the subcutaneous tissues of both lateral thighs. The injected solution consisted of 0.1% lidocaine and 12.5 meq/liter sodium bicarbonate in normal saline with or without 1:1,000,000 epinephrine. Tissue pressure was recorded during injection using a specially designed double-barreled needle. The time required for injection was also recorded. Subjects in group 1 received lidocaine with epinephrine injected by a high-pressure technique. Group 2 subjects received lidocaine with epinephrine injected by a low-pressure technique. Group 3 subjects received lidocaine without epinephrine injected under high pressure. Group 4 subjects received lidocaine without epinephrine injected under low pressure. Following injection, sequential blood samples were drawn over a 14-hour period, and plasma lidocaine concentrations were determined by gas chromatography. No suction lipectomy was performed. Maximum tissue pressure during injection was 339 +/- 63 mmHg and 27 +/- 9 mmHg using high- and low-pressure techniques, respectively. Addition of 1:1,000,000 epinephrine, regardless of the pressure of injected fluid, significantly delayed the time to peak plasma concentration by over 7 hours. There was no significant difference in the peak plasma concentration of lidocaine among the four groups. Peak plasma concentrations greater than 1 mcg/ml were seen in 11 subjects. Epinephrine (1:1,000,000) significantly delays the absorption of lidocaine administered by the tumescent technique. High pressure generated in the subcutaneous tissues during injection of the solution does not affect lidocaine absorption. The delay in absorption may allow time for some lidocaine to be removed from the tissues by suction lipectomy. In addition, the slow rise to peak lidocaine concentration in the epinephrine groups may allow the development of systemic tolerance to high lidocaine plasma levels.     

Effect of hepatic nerve stimulation on hepatic uptake of lidocaine in the cat

Hepatic blood flow and lidocaine uptake were measured using a hepatic venous long-circuit preparation in cats anesthetized with pentobarbital-Na. The processes involved with hepatic elimination of lidocaine were not affected by stimulation of the hepatic nerves. The lack of neural influence on hepatic extraction ratios of lidocaine supports the contention that nerve stimulation does not result in shunting or redistribution of blood to non-nutritive sites. In species which do not show complete vascular escape from neurogenic vasoconstriction, a reduced lidocaine elimination would be anticipated since it was shown that reduced hepatic blood flow results in reduced lidocaine elimination. In the intact rat one third of the lidocaine in the blood was extracted on each passage through the liver. This extraction ratio is not affected by arterial levels of lidocaine, by changes in blood flow or by activation of the hepatic nerves.     

The existence of a lysosomal redox chain and the role of ubiquinone

Several studies concerning the distribution of ubiquinone (UQ) in the cell report a preferential accumulation of this biogenic quinone in mitochondria, plasma membranes, Golgi vesicles, and lysosomes. Except for mitochondria, no recent comprehensive experimental evidence exists on the particular function of UQ in these subcellular organelles. The aim of a recent study was to elucidate whether UQ is an active part of an electron-transfer system in lysosomes. In the present work, a lysosomal fraction was prepared from a light mitochondrial fraction of rat liver by isopycnic centrifugation. The purity of our preparation was verified by estimation of the respective marker enzymes. Analysis of lysosomes for putative redox carriers and redox processes in lysosomes was carried out by optical spectroscopy, HPLC, oxymetry, and ESR techniques. UQ was detected in an amount of 2.2 nmol/mg of protein in lysosomes. Furthermore, a b-type cytochrome and a flavin-adenine dinucleotide (FAD) were identified as other potential electron carriers. Since NADH was reported to serve as a substrate of UQ redox chains in plasma membranes, we also tested this reductant in lysosomes. Our experiments demonstrate a NADH-dependent reduction of UQ by two subsequent one-electron-transfer steps giving rise to the presence of ubisemiquinone and an increase of the ubiquinol pool in lysosomes. Lysosomal NADH oxidation was accompanied by an approximately equimolar oxygen consumption, suggesting that O(2) acts as a terminal acceptor of this redox chain. DMPO/(*)OH spin adducts were detected by ESR in NADH-supplemented lysosomes, suggesting a univalent reduction of oxygen. The kinetic analysis of redox changes in lysosomes revealed that electron carriers operate in the sequence NADH > FAD > cytochrome b > ubiquinone > oxygen. By using the basic spin label TEMPAMINE, we showed that the NADH-related redox chain in lysosomes supports proton accumulation in lysosomes. In contrast to the hypothesis that UQ in lysosomes is simply a waste product of autophagy in the cell, we demonstrated that this lipophilic electron carrier is a native constituent of a lysosomal electron transport chain, which promotes proton translocation across the lysosomal membrane.     

Endocytic delivery to lysosomes mediated by concurrent fusion and kissing events in living cells

In mammalian cells, macromolecules internalized by endocytosis are transported via endosomes for digestion by lysosomal acid hydrolases . The mechanism by which endosomes and lysosomes exchange content remains equivocal . However, lysosomes are reusable organelles because they remain accessible to endocytic enzyme replacement therapies and undergo content mixing with late endosomes . The maturation model, which proposes that endosomes mature into lysosomes , cannot explain these observations. Three mechanisms for content mixing have been proposed. The first is vesicular transport, best supported by a yeast cell-free assay . The second suggests that endosomes and lysosomes engage in repeated transient fusions termed "kiss-and-run" . The third is that endosomes and lysosomes fuse completely, yielding hybrid compartments from which lysosomes reform , termed "fusion-fission" . We utilized time-lapse confocal microscopy to test these hypotheses in living cells. Lysosomes were loaded with rhodamine dextran by pulse-chase, and subsequently late endosomes were loaded with Oregon green 488 dextran. Direct fusions were observed between endosomes and lysosomes, and one such event was captured by correlative electron microscopy. Fluorescence intensity analyses of endosomes that encountered lysosomes revealed a gradual accumulation of lysosomal content. Our data are compatible with a requirement for direct contact between organelles before content is exchanged.     

Effect of monensin on the neuronal ultrastructure and endocytic pathway of macromolecules in cultured brain neurons

1. The endocytic pathway of horseradish peroxidase (HRP) was investigated in the perikarya of cultured neurons by electron microscopy and enzyme cytochemistry. The tracer was observed in endocytic pits and vesicles, endosomes, multivesicular bodies, and lysosomes. It took approximate 15 min for the transfer of HRP from the exterior of the cell to the lysosomes. 2. Monensin induced distension of the Golgi apparatus and formation of intracellular vacuoles. When neurons were incubated with both monensin and HRP for 30 to 120 min, the number of HRP-labeled endosomes was greater than that in the monensin-free group, whereas the reverse was seen for HRP-positive lysosomes. The formation of HRP-positive lysosomes in monensin-treated cells was blocked by 47 to 79%. 3. These results indicate that the intracellular transport of the endocytosed macromolecule is pH dependent. It is also possible that the export of lysosomal enzymes is inhibited by monensin, resulting in an accumulation of the endosomes and a reduction of the lysosomes.     

Pharmacokinetics and safety of lidocaine and monoethylglycinexylidide in liposuction: a microdialysis study

High doses of lidocaine are administered to patients undergoing liposuction. Monoethylglycinexylidide, the active metabolite of lidocaine, is 80 to 90 percent as potent as lidocaine, and its relative toxicity is approximately that of lidocaine. Monoethylglycinexylidide has not previously been measured in studies on lidocaine in liposuction. The aims of this study were to characterize systemic exposure to lidocaine and monoethylglycinexylidide and to measure lidocaine and monoethylglycinexylidide levels within the tissues. Five female volunteers between the ages of 29 and 40 years underwent liposuction. Lidocaine (1577 to 2143 mg, corresponding to 19.9 to 27.6 mg/kg) was infiltrated during the procedure. Levels of lidocaine and monoethylglycinexylidide in blood and lipoaspirate were assessed perioperatively. Tissue lidocaine and monoethylglycinexylidide levels were measured postoperatively using a microdialysis technique in vivo. The peak (maximal) concentration of lidocaine plus monoethylglycinexylidide was 2.2 to 2.7 microg/ml. Time to peak lidocaine plus monoethylglycinexylidide was 8 to 28 hours after infiltration began. Absorbed lidocaine was estimated to be 911 to 1596 mg; therefore, 45 to 93 percent (mean, 64 percent) of the infiltrated dose was ultimately absorbed. Lipoaspirate analysis showed that 9.1 to 10.8 percent (mean, 9.7 percent) of the infiltrated dose was removed during the procedure. Tissue lidocaine levels below 5 microg/ml were demonstrated from 4 to 8 hours postoperatively. The peak lidocaine plus monoethylglycinexylidide concentration was within safe limits in this group of subjects. Time to peak lidocaine plus monoethylglycinexylidide signifies a delayed peak and therefore a longer period of potential lidocaine toxicity than was originally thought. Microdialysis results demonstrated that tissue lidocaine levels may be subtherapeutic within 4 to 8 hours of the procedure. Investigation into factors controlling the resorption of lidocaine during liposuction is warranted in an effort to improve the duration of effect. Furthermore, considering the active metabolite monoethylglycinexylidide, longitudinal studies are necessary to determine whether improving the side effect profile of lidocaine by reducing the dose administered during liposuction may be possible without decreasing the perioperative analgesic effect.     

The relationship between autophagy and the intracellular degradation of asialoglycoproteins in cultured rat hepatocytes

The relationship between autophagy and the intracellular distribution of endocytosed asialoorosomucoid was studied in cultured rat hepatocytes. Overt autophagy was induced by shifting the cells to a minimal salt medium. Incubation in minimal salt medium led to the formation of buoyant lysosomes at the expense of denser lysosomes manifested as a dual distribution of these organelles in Nycodenz gradients. Asialoorosomucoid was labeled with 125I-tyramine cellobiose. The labeled degradation products formed from this ligand are trapped at the site of degradation and may therefore serve as markers for the subgroup of lysosomes involved in the degradation. In control cells the degradation of the ligand was initiated in a light prelysosomal compartment and continued in denser lysosomes. In cells with high autophagic activity, the degradation of labeled asialoorosomucoid took place exclusively in a buoyant group of lysosomes. These results suggest that degradation of endocytosed ligand takes place in the same secondary lysosomes as substrate sequestered by autophagic mechanisms. These light lysosomes represent a subgroup of active lysosomes which are gradually recruited from dense bodies. Data are also presented that indicate that insulin may prevent the change in buoyant density brought about by incubation in deficient medium.     

The values and limits of an in vitro model of Pompe disease: The best laid schemes o’ mice an’ men ……..†

In Pompe disease, a lysosomal glycogen storage disorder, cardiac and skeletal muscle abnormalities are responsible for premature death and severe weakness. Swollen glycogen-filled lysosomes, the expected pathology, are accompanied in skeletal muscle by a secondary pathology – massive accumulation of autophagic debris – that appears to contribute greatly to the weakness. We have tried to reproduce these defects in murine, Pompe myotubes derived from either primary myoblasts or myoblasts with extended proliferative capacity. The cells accumulated large lysosomes filled with glycogen, but, to our disappointment, did not have autophagic buildup even though basal autophagy was intact. When we suppressed autophagy by knocking down Atg7, we found that glycogen uptake by lysosomes was not affected, suggesting that macroautophagy is not the major pathway for glycogen delivery to lysosomes. But two apparently incidental observations – a peculiar distribution of both microinjected dextran and of small acidic structures adjacent to the interior membrane of large alkalinized glycogen-containing lysosomes – raised the possibility that glycogen traffics to the lysosomes by microautophagy or/and by the engulfment of small lysosomes by large ones. The cultured myotubes, therefore, appear to be a useful model for studying the mechanisms involved in glycogen accumulation in Pompe disease and to test substrate deprivation approaches.

^?From To a Mouse, Robert Burns, 1785     

Actin Filaments and Myosin I Alpha Cooperate with Microtubules for the Movement of Lysosomes

An earlier report suggested that actin and myosin I alpha (MMIalpha), a myosin associated with endosomes and lysosomes, were involved in the delivery of internalized molecules to lysosomes. To determine whether actin and MMIalpha were involved in the movement of lysosomes, we analyzed by time-lapse video microscopy the dynamic of lysosomes in living mouse hepatoma cells (BWTG3 cells), producing green fluorescent protein actin or a nonfunctional domain of MMIalpha. In GFP-actin cells, lysosomes displayed a combination of rapid long-range directional movements dependent on microtubules, short random movements, and pauses, sometimes on actin filaments. We showed that the inhibition of the dynamics of actin filaments by cytochalasin D increased pauses of lysosomes on actin structures, while depolymerization of actin filaments using latrunculin A increased the mobility of lysosomes but impaired the directionality of their long-range movements. The production of a nonfunctional domain of MMIalpha impaired the intracellular distribution of lysosomes and the directionality of their long-range movements. Altogether, our observations indicate for the first time that both actin filaments and MMIalpha contribute to the movement of lysosomes in cooperation with microtubules and their associated molecular motors.     

Relationship between medium pH and that of the lysosomal matrix as studied by two independent methods.

1. The method of estimating the intralysosomal pH by measuring the distribution of [14C]methylamine in lysosomes isolated from the livers of Triton WR 1339-treated rats has been critically examined. 2. In lysed lysosomes, methylamine is bound to the membrane fragments, but this binding can be completely suppressed by increasing the concentration of monovalent cations in the medium. 3. In intact lysosomes, the binding of [14C]methylamine is only partly inhibited by monovalent cations at 25 degrees C. 4. THe accumulation of [14C]methylamine in intact lysosomes is progressively inhibited as the concentration of methylamine is increased. A similar inhibition of [14C]methylamine accumulation is obtained with NH4Cl. 5. Similar values for the intralysosomal pH were obtained from measurements of the distribution of methylamine, dimethylamine and trimethylamine, which are accumulated in the lysosomes, and of 5,5-dimethyloxazolidinedione-2,4, which is excluded. 6. The breakdown of endocytosed 123I-labelled bovine serum albumin by intact isolated lysosomes is much less sensitive to the pH of the medium than the breakdown of added protein by lysed lysosomes. 7. The intralysosomal pH has been estimated by comparing the rate of breakdown of endocytosed 125I-labelled albumin in intact lysosomes as a function of medium pH with that of added 125I-labelled albumin by lysed lysosomes at different pH values. The values obtained agree well with those calculated from the distribution of [14C]methylamine. 8. Methylamine and NH4Cl inhibit the breakdown of 125I-labelled albumin in intact lysosomes, particularly at high medium pH, but have no effect on the breakdown by lysed lysosomes. 9. It is concluded that a pH difference across the lysosomal membrane (more acidic inside than outside) is maintained by the presence of indiffusible negatively charged groups within the lysosomes, and by the permeation across the lysosomal membrane of protons together with permeant anions (or of OH- in exchange for anions).     

The small chemical vacuolin-1 alters the morphology of lysosomes without inhibiting Ca2+-regulated exocytosis

Ca2+-regulated exocytosis of lysosomes was previously shown to be required for the repair of plasma membrane wounds. The small chemical vacuolin-1 alters the morphology of lysosomes without affecting the ability of cells to reseal their plasma membrane after injury. On the basis of a failure to detect Ca2+-triggered lysosomal exocytosis in vacuolin-1-treated cells, a recent study proposed that lysosomes are dispensable for resealing. Here, we show that vacuolin-1, despite altering lysosome morphology, does not inhibit the exocytosis of lysosomes induced by exposure to a Ca2+ ionophore, or by plasma membrane wounding. Thus, lysosomes cannot be excluded as agents of membrane repair in vacuolin-1-treated cells.     

The effects of lidocaine on lymphocyte beta-adrenergic receptor at different pH]

The effects of lidocaine on beta-adrenergic receptor binding and the yield of epinephrine-stimulated cAMP at different pH were measured by radioligand binding assay and radioimmunoassay. The results showed that the binding of H-DHA to the receptor and yield of epinephrine-stimulated cAMP increased with increasing pH (P < 0.001) and lidocaine inhibitory potency also increased with increasing pH (P < 0.001); The results indicate that the response to beta-agonists would increase with pH during cardiopulmonary resuscitation when lidocaine is not present, but it would not increase with pH when lidocaine is present, suggesting that lidocaine may inhibit binding of beta-agonists to receptor by changing lipid fluidity of cell membrane with increasing pH.     

Translocation of hepatocyte lysosomes following partial hepatectomy and its inhibition by colchicine

Hepatocyte microtubules were studied during the translocation of lysosomes which follows partial hepatectomy. In hepatocytes of normal rat liver the lysosomes are seen mainly along the bile canaliculi. After partial hepatectomy, these lysosomes lose their pericanalicular arrangement and move towards large inclusions (‘protein droplets’) which result from the marked pinocytosis induced by the removal of about two-thirds of the liver mass. The lysosomes fuse with the inclusions, and by 4 h after partial hepatectomy most of the inclusions demonstrate acid phosphatase activity histochemically. Many microtubules are found in close proximity to the lysosomes. When the rats are treated with colchicine prior to the partial hepatectomy, events are markedly different. The lysosomes change their location but do not hit the cytoplasmic inclusions, and the inclusions remain negative for acid phosphatase activity even 4 h post-hepatectomy. Quantitative ultrastructural study shows that the volume density of microtubules in the hepatocytes decreases to one-third of that in control hepatocytes. This strongly suggests an involvement of microtubules in giving orientation to the translocation of hepatocyte lysosomes under these conditions.     

Effect of propranolol on lidocaine pharmacokinetics

The study aimed at investigating an effect of propranolol on lidocaine pharmacokinetic parameters, especially elimination rate and total clearance rate. The study was carried out in 8 rabbits with cross-over technique. The animals were examined twice. Sequence of therapy was established randomly. Some group of the animals were given propranolol and lidocaine first while the remaining animals were given lidocaine alone. Sequence of drugs administration was changed after one week. Propranolol was given in a single dose of 0.05 mg/kg b.w. intravenously. Lidocaine was injected in a single dose of 3 mg/kg b.w. during 5 minutes i.v. after a 30-minute interval. All drugs were injected into ear vein. Blood for assays was collected 8 times within 6 hours after lidocaine administration. TDx system manufactured by Abbott was used for drug concentration assay with immunofluorescence polarization method. One-compartment open model was used for calculations. The results were analysed with Student t-test for pairs. Significant decrease in AUC, marked decrease in distribution volume and total body clearance following lidocaine and propranolol were noted. The study has shown that there is interaction between propranolol and lidocaine leading to a decrease in total body lidocaine clearance.     

Antagonistic Control of Lysosomal Fusion by Rab14 and the Lyst‐Related Protein LvsB

While loss of the protein Lyst causes abnormal lysosomes in patients with Chediak–Higashi syndrome, the contribution of Lyst to lysosome biology is not known. Previously we found that the Dictyostelium ortholog of Lyst, LvsB, is a cytosolic protein that associates with lysosomes and post‐lysosomes to prevent their inappropriate fusion. Here we provide three lines of evidence that indicate that LvsB contributes to lysosome function by antagonizing the function of DdRab14, a protein that promotes homotypic fusion among lysosomes. (1) Instead of restricting DdRab14 to lysosomes, cells that lack LvsB expand DdRab14 localization to include post‐lysosomes. (2) Expression of activated DdRab14 phenocopies the loss of LvsB, causing inappropriate heterotypic fusion between lysosomes and post‐lysosomes and their subsequent enlargement. (3) Conversely, expression of inactivated DdRab14 suppresses the phenotype of LvsB null cells and restores their lysosomal size and segregation from post‐lysosomes. Our data suggest a scenario where LvsB binds to late lysosomes and promotes the inactivation of DdRab14. This inactivation allows the lysosomes to mature into post‐lysosomes for eventual secretion. We propose that human Lyst may function similarly to regulate Rab‐dependent fusion of lysosomal compartments.     

In Vitro Induction of Antibody-Dependent Cytotoxic Macrophages by the Local Anesthetic Lidocaine

Normal macrophages were activated to antibody-dependent cytotoxic effector cells by in vitro treatment with the local anesthetic lidocaine. Experiments on the dose-response and time course of the effect of lidocaine showed that incubation of normal macrophages with 10 mM lidocaine for 10 min at 28 C was enough for induction of antibody-dependent cellular cytotoxicity. The activation by lidocaine was accompanied by enhanced phagocytosis of sheep red blood cells (SRBC) sensitized with anti-SRBC antiserum, but not enhanced ingestion of polystyrene latex particles (PLP). These findings suggest that lidocaine, which has various effects on cell membranes, induces some perturbation of macrophage membranes, resulting in activation of Fc receptor functions in antibody-dependent cytotoxicity and phagocytosis.     

P-selectin targeting to secretory lysosomes of Rbl-2H3 cells.

The biogenesis of secretory lysosomes, which combine characteristics of both lysosomes and secretory granules, is currently of high interest. In particular, it is not clear whether delivery of membrane proteins to the secretory lysosome requires lysosomal, secretory granule, or some novel targeting determinants. Heterologous expression of P-selectin has established that this membrane protein contains targeting signals for both secretory granules and lysosomes. P-selectin is therefore an ideal probe with which to determine the signals required for targeting to secretory lysosomes. We have exploited subcellular fractionation and immunofluorescence microscopy to monitor targeting of transiently expressed wild-type and mutant horseradish peroxidase (HRP)-P-selectin chimeras to secretory lysosomes of Rbl-2H3 cells. The exposure of the HRP chimeras to intracellular proteolysis was also determined as a third monitor of secretory lysosome targeting. Our data show that HRP-P-selectin accumulates in secretory lysosomes of Rbl-2H3 cells using those cytoplasmic sequences previously found to be sufficient for targeting to conventional lysosomes. This work highlights the similar sorting signals used for targeting of membrane proteins to conventional lysosomes and secretory lysosomes.