Increased endocytotic and lysosomal activities in denervated type I and type II muscle fibres

Summary Previous work has shown that increased endocytotic and lysosomal activities occur in the endplate region of denervated skeletal muscle fibres. This, however, does not engage all fibres of a muscle at a given time after denervation. The present study was carried out in order to determine if both type I (slow) and type II (fast) muscle fibres can react to denervation by increased endocytotic and lysosomal activities. Uptake of horseradish peroxidase as a marker for endocytosis was studied in conjunction with acid phosphatase staining for lysosomal activity in type I and type II fibres of the denervated mouse hemidiaphragm. Fibre typing was performed using a monoclonal antibody against fast skeletal myosin and by adenosine triphosphatase staining. The results show that increased endocytosis and lysosomal activation occur in both type I and type II fibres after denervation.     

Increased endocytotic and lysosomal activities in denervated type I and type II muscle fibres.

Previous work has shown that increased endocytotic and lysosomal activities occur in the endplate region of denervated skeletal muscle fibres. This, however, does not engage all fibres of a muscle at a given time after denervation. The present study was carried out in order to determine if both type I (slow) and type II (fast) muscle fibres can react to denervation by increased endocytotic and lysosomal activities. Uptake of horseradish peroxidase as a marker for endocytosis was studied in conjunction with acid phosphatase staining for lysosomal activity in type I and type II fibres of the denervated mouse hemidiaphragm. Fibre typing was performed using a monoclonal antibody against fast skeletal myosin and by adenosine triphosphatase staining. The results show that increased endocytosis and lysosomal activation occur in both type I and type II fibres after denervation.     

Proteolytic enzyme activity in rat hindlimb muscles in fetus and during post-natal development

The enzymatic activity of two lysosomal enzymes, acid phosphatase and cathepsin D, was determined in fetus and during post-natal development of the rat gastrocnemius muscle in comparison to the histological differentiation of this muscle. The specific activity of cathepsin D and acid phosphatase was 7 and 2.5 fold higher in the muscle during development until 20 days after birth, than that of mature muscle, respectively. A trend of gradual decrease in the activity of these enzymes was observed concomitantly with the differentiation and maturation of the muscle from mononucleated cells in the fetus to myotubes formation at day 1 after birth, followed by the formation of "young" and then striated myofibers in 10- and 20-day old neonates, respectively. However, no correlation could be found between the lysosomal enzyme activity and the developmental stages of the muscle until 20 days after birth. It is suggested that the elevated activity of lysosomal acid hydrolases may be associated with late developmental processes from young to mature myofibers in normal skeletal muscle and not only in various pathological conditions.     

Modification of motoneuron size after partial denervation in neonatal rats

Our previous studies have shown that partial denervation of extensor digitorum longus muscle (EDL) in the rat at 3 days of age causes an increase in the activity of the intact motoneurons. The originally phasic pattern of activity of EDL became tonic after partial denervation. These modifications of motoneuron activity were associated with the change in the phenotype of the muscle from fast to slow contracting and with a conversion of the muscle fibres from a fast to a slow type. The present study investigates whether the size of the cell body of the active EDL motoneurons change in parallel with the altered muscular activity. The study involved partial denervation of rat EDL muscle by section of the L4 spinal nerve at 3 days of age. Then the remaining motoneurons from L5 spinal nerve supplying the EDL muscle were retrogradly labelled with horseradish peroxidase two months later. The results show a reduction in motoneuron size in parallel with an increase in activity of the motoneurons after partial denervation of EDL muscle.     

Membranous complexes characteristic of melanocytes derived from patients with Hermansky–Pudlak syndrome type 1 are macroautophagosomal entities of the lysosomal compartment

Hermansky–Pudlak syndrome (HPS) is an autosomal recessive disorder resulting from mutations in a family of genes required for efficient transport of lysosomal‐related proteins from the trans‐Golgi network to a target organelle. To date, there are several genetically distinct forms of HPS. Many forms of HPS exhibit aberrant trafficking of melanosome‐targeted proteins resulting in incomplete melanosome biogenesis responsible for oculocutaneous albinism observed in patients. In HPS‐1, melanosome‐targeted proteins are localized to characteristic membranous complexes, which have morphologic similarities to macroautophagosomes. In this report, we evaluated the hypothesis that HPS‐1‐specific membranous complexes comprise a component of the lysosomal compartment of melanocytes. Using indirect immunofluorescence, an increase in co‐localization of misrouted tyrosinase with cathepsin‐L, a lysosomal cysteine protease, occurred in HPS‐1 melanocytes. In addition, ribophorin II, an integral endoplasmic reticulum protein that is also a component of macroautophagosomes, and LC3, a specific marker of macrophagosomes, demonstrated localization to membranous complexes in HPS‐1 melanocytes. At the electron microscopic level, the membranous complexes exhibited acid phosphatase activity and localization of exogenously supplied horseradish peroxidase (HRP)‐conjugated gold particles, indicating incorporation of lysosomal and endosomal components to membranous complexes, respectively. These results confirm that membranous complexes of HPS‐1 melanocytes are macroautophagosomal representatives of the lysosomal compartment.     

Metabolic priorities during starvation: enzyme sparing in liver and white muscle of Atlantic cod,Gadus morhua L

Atlantic cod, Gadus morhua, respond to starvation first by mobilising hepatic lipids, then muscle and hepatic glycogen and finally muscle proteins. The dual role of proteins as functional elements and energetic reserves should lead to a temporal hierarchy of mobilisation where the nature of a function dictates its conservation during starvation. We examined (1) whether lysosomal and anti-oxidant enzymes in liver and white muscle are spared during prolonged starvation, (2) whether the responses of these enzymes in muscle vary longitudinally. Hepatic contents of lysosomal proteases decreased with starvation, whereas those of catalase (CAT) increased and lysosomal enzymes of carbohydrate metabolism and glutathione S-transferase (GST) did not change. In white muscle, starvation decreased the specific activity of lysosomal enzymes of carbohydrate degradation and doubled that of cathepsin D (CaD). The activity of anti-oxidant enzymes and acid phosphatase in muscle was unchanged with starvation. In white muscle neither lysosomal enzymes nor anti-oxidant enzymes varied significantly with sampling position. In cod muscle, antioxidant enzymes, CaD and acid phosphatase are spared during a period of starvation that decreases lysosomal enzymes of carbohydrate metabolism and decreases glycolytic enzyme activities. In cod liver, the anti-oxidant enzymes, CAT and GST, were also spared during starvation.     

Lysosomal enzymes in relation to the isoproterenol-induced secretory cycle in rat parotid gland

Two lysosomal enzymes, cathepsin D and acid phosphatase, were detected in significant amounts in the lysosome-containing subcellular fractions of rat parotid tissue and found to have dissimilar distributions in these fractions. The total levels of these enzymes were measured at various times throughout a complete secretory cycle induced synchronously by fasting rats overnight and administering isoproterenol at time zero. The results showed a 30% increase in cathepsin D activity in the glands by 10 h post-stimulation, and a 20% decrease in acid phosphatase activity 7 h after stimulation. These results suggest that there are cyclic changes in lysosomal enzymes during the secretory cycle of this gland, but that these changes are complex ones and cannot be related to specific cellular processes at this time.     

Identification of subcellular compartments involved in biosynthetic processing of cathepsin D.

We have assigned the biosynthetic processing steps of cathepsin D to intracellular compartments which are involved in its transport to lysosomes in HepG2 cells. Cathepsin D was synthesized as a 51-kDa proenzyme. After formation of 51-55-kDa intermediates due to processing of N-linked oligosaccharides, procathepsin D was proteolytically processed to an intermediate 44-kDa and the mature 31-kDa enzyme. The intersection of the biosynthetic pathway of cathepsin D with the endocytic pathway was labeled with horseradish peroxidase and monitored biochemically by 3,3'-diaminobenzidine cytochemistry. Horseradish peroxidase was used either as a fluid-phase marker to label the entire endocytic pathway or conjugated to transferrin (Tf) to label endosomes only. Directly after biosynthesis cathepsin D was accessible neither to horseradish peroxidase nor Tf-horseradish peroxidase. Newly synthesized 51-55-kDa species of cathepsin D present in the trans-Golgi reticulum were accessible to both horseradish peroxidase and Tf-horseradish peroxidase. The accessibility of trans-Golgi reticulum to both endocytosed horseradish peroxidase and Tf-horseradish peroxidase was monitored by colocalization with a secretory protein, alpha 1anti-trypsin. The proteolytic processing of 51-55-kDa to 44-kDa cathepsin D occurred in compartments which were fully accessible to fluid-phase horseradish peroxidase. Tf-horseradish peroxidase had access to only 20% of 44-kDa cathepsin D while it had no access to 31-kDa cathepsin D. In contrast, the 31-kDa species was completely accessible to fluid-phase horseradish peroxidase. We conclude that proteolytic processing of 51-55-kDa to 44-kDa cathepsin D occurs in endosomes, whereas the processing of 44-31-kDa cathepsin D takes place in lysosomes.     

Proteases and proteinase inhibitors in experimental glucocorticosteroid myopathy

The unknown enzymatic mechanism of enhanced protein breakdown in steroid myopathy was studied in functionally and biochemically different muscles of rabbits treated with dexamethasone for three weeks. After glucocorticoid administration the fast-twitch glycolytic semimembraneous muscle of treated animals was atrophied, whereas the weight of the slow-twitch oxidative soleus muscle was not altered. The specific activity of the lysosomal endo- and exopeptidases (cathepsin D, E, B and L, lysosomal carboxypeptidase A and dipeptidylpeptidase I) was increased about 2-fold in the atrophied white muscle. The activity of the cytosol enzyme Ca++-activated neutral proteinase was also elevated, whereas that of the other cytosol endopeptidase, chymotrypsin-like enzyme, was unaltered. The level of alanine aminopeptidase was only slightly increased. On the other hand, there were no unequivocal changes in protease activity in the soleus muscle. These findings are in agreement with the known differences in glucocorticoid-sensitivity of the various muscles. Our results suggest that the lysosomal proteolytic system and the Ca++-activated neutral proteinase may play an important role in the glucocorticoid-induced intracellular protein catabolism in muscle. The inhibitor capacities of cathepsin B and trypsin detectable in muscle cytosol were not altered after steroid treatment. Consequently, the increase in cathepsin B activity was not due to the loss of its inhibitor.     

Stoichiometry of electron uptake and oxidation-reduction midpoint potentials of NADH:nitrate reductase.

Upon detergent or hypo-osmotic lysis of CHO-cell postnuclear supernatants or isolated lysosomes at pH 4.8, the lysosomal enzymes beta-hexosaminidase, beta-galactosidase, alpha-fucosidase and cathepsin C were readily pelleted, whereas the exogenous marker, long-term-internalized horseradish peroxidase, was not. Salt or pH elevation greatly decreased lysosomal-enzyme pelletability. The results suggest that, under native conditions, lysosomal hydrolases may be aggregated. Aggregation could promote enzyme retention within the organelle.     

Changes in plasma levels of lysosomal and non lysosomal enzymes during hemorrhagic hypotension.

In a study of 4-hr hemorrhagic hypotension in dogs, the plasma levels of the lysosomal enzymes, cathepsin (CATH) and acid phosphatase (AP) showed early and progressive increases in activity. The plasma levels of the intestinal fraction of alkaline phosphatase (IAkP) and aspartate aminotransferase (AAT) were increased after 2 hr of hypotension and the liver specific enzyme, ornithine carbamyltransferase (OCT), and creatine phosphokinase (CPK), after 3 hr. All of the enzymes showed large increases after 4 hr of hypotension. The plasma levels of CATH showed the earliest and largest relative increase indicating that with the shock model used, this enzyme was the most sensitive indicator of shock severity. The increase in plasma enzyme levels was probably the result of tissue damage in the splanchnic region but the elevation of plasma CPK, a muscle specific enzyme, indicates some muscle cell damage as well. While the increase in the plasma enzyme activity is probably due, in large part, to cellular damage, it is likely that a decreased enzyme removal rate--resulting from a hypofunctional RES--also contributes to the elevated plasma enzyme levels during hemorrhagic hypotension.     

Membranous complexes characteristic of melanocytes derived from patients with Hermansky-Pudlak syndrome type 1 are macroautophagosomal entities of the lysosomal compartment

Hermansky-Pudlak syndrome (HPS) is an autosomal recessive disorder resulting from mutations in a family of genes required for efficient transport of lysosomal-related proteins from the trans-Golgi network to a target organelle. To date, there are several genetically distinct forms of HPS. Many forms of HPS exhibit aberrant trafficking of melanosome-targeted proteins resulting in incomplete melanosome biogenesis responsible for oculocutaneous albinism observed in patients. In HPS-1, melanosome-targeted proteins are localized to characteristic membranous complexes, which have morphologic similarities to macroautophagosomes. In this report, we evaluated the hypothesis that HPS-1-specific membranous complexes comprise a component of the lysosomal compartment of melanocytes. Using indirect immunofluorescence, an increase in co-localization of misrouted tyrosinase with cathepsin-L, a lysosomal cysteine protease, occurred in HPS-1 melanocytes. In addition, ribophorin II, an integral endoplasmic reticulum protein that is also a component of macroautophagosomes, and LC3, a specific marker of macrophagosomes, demonstrated localization to membranous complexes in HPS-1 melanocytes. At the electron microscopic level, the membranous complexes exhibited acid phosphatase activity and localization of exogenously supplied horseradish peroxidase (HRP)-conjugated gold particles, indicating incorporation of lysosomal and endosomal components to membranous complexes, respectively. These results confirm that membranous complexes of HPS-1 melanocytes are macroautophagosomal representatives of the lysosomal compartment.     

High Endocytotic Activity Occurs Periodically in the Endplate Region of Denervated Mouse Striated Muscle Fibers

High endocytotic activity after denervation of skeletal muscle occurs in a proportion of muscle fibers (both slow and fast fiber types) in the endplate region. The present study was performed in order to examine if a periodicity in the endocytotic activity could explain why the process is not observed in all fibers at a given time. Three markers, horseradish peroxidase (HRP), rhodamine B isothiocyanate-labeled dextran, and fluorescein isothiocyanate-labeled dextran were used to demonstrate endocytotic activity of muscle fibers of the denervated mouse hemidiaphragm in vivo. Acetylcholine esterase staining was used in conjunction with HRP uptake to determine the proportion of denervated muscle fibers with endocytotic activity in the endplate region at any one time. The results show that 25-50% of the muscle fibers display high endocytotic activity in the endplate region at a given time 10 days after denervation. The existence of a periodicity in this endocytotic activity is suggested by results obtained using two different endocytotic markers administered at time intervals of 0-7 days. We conclude that loss of contact with the innervating motorneuron induces a high endocytotic activity which occurs periodically in the perisynaptic region of skeletal muscle fibers.     

STUDIES ON INCREASED ACID HYDROLASE ACTIVITIES IN DENERVATED MUSCLE

Denervation of rat hemidiaphragm led to large increases in the activity of acid proteinase, cathepsin B1 and β-glucuronidase in the muscle. The increases were not confined to the endplate regions of the muscle. Mononuclear cells extracted from normal and denervated extensor digitorum longus and diaphragm muscles contained only a small proportion of the acid proteinase and cathepsin B1 activities in the muscle. Actinomycin D, but not methotrexate, prevented the increase in acid proteinase and cathepsin B1 normally resulting from denervation. Brij/58 increased acid proteinase activity to a smaller extent in the denervated muscle than in the control. The length of the distal nerve stump remaining after denervation influenced the enzyme increases, but acid proteinase and cathepsin B1 appeared to be affected differently. The significance of the post-denervation increase in hydrolase activities is still unknown.     

OCCURRENCE OF PHAGOSOMES AND PHAGO-LYSOSOMES IN DIFFERENT SEGMENTS OF THE NEPHRON IN RELATION TO THE REABSORPTION, TRANSPORT, DIGESTION, AND EXTRUSION OF INTRAVENOUSLY INJECTED HORSERADISH PEROXIDASE

The size, number, and location of lysosomes, phagosomes, and phago-lysosomes in different segments of the proximal and distal tubules, in the collecting tubules, and in invading macrophages of the kidneys of rats were compared by staining lysosomes (acid phosphatase) red, and phagosomes (injected horseradish peroxidase) blue in separate sections, and by staining phago-lysosomes purple by successive application of the reactions for the two enzymes in the same sections. It was concluded from these observations that the absorption of the foreign protein from the lumen and its gradual digestion in large phago-lysosomes took place mainly in the cells of the proximal convoluted tubules of the outer cortex. Several segments of the proximal convoluted tubules were distinguished on the basis of differences in the size and location of the phago-lysosomes and the amounts of peroxidase ingested. The distal tubules showed, in addition to moderate numbers of phago-lysosomes, many small phagosomes in the apical and basal zones of the cells. Moderate numbers of phagosomes and phago-lysosomes were observed in the cells of the collecting tubules. Macrophages showing very large phago-lysosomes were seen in the peritubular capillaries of the medulla, after injection of peroxidase. When high doses of peroxidase were administered, enlarged phago-lysosomes, parts of which seemed to be extruded into the lumen, were formed in the terminal segments of the proximal convoluted tubules.     

Behaviour of tyrosine amino transferase and convertase during the first hours after hepatectomy in rats

The activity of rat liver tyrosine amino transferase (TAT) increases after hepatectomy with a first prominent peak at 8 h and a second peak at 18 h. This change in activity is probably due to de novo enzyme synthesis since it is prevented by actinomycin-D (AMD). In the same period an increase of the lysosomal converting enzyme (convertase) which catalyses the in vitro transition of TAT from form I to form III, has been observed; this is not accompanied by changes of other lysosomal enzymes, such as acid phosphatase and cathepsin L. The activity of convertase is equal to that of the controls (sham operated animals) 2 h after hepatectomy, increases three times at 5 h, maintains the same value at 8 h and then decreases slowly to control level after 24 h. The correlation between the activity changes of the two enzymes strongly suggests a physiological role of convertase in TAT turnover.     

The role of nerve lysosomal enzymes in the pathogenesis of denervation atrophy. Electromyographic and histochemical study in rats

Section of sciatic nerves of rats produced fibrillations within 3 days. Foci of hyalination leading to necrosis corresponded to segments of muscles containing end plates. The electrolyte content, mainly Ca, was increased, NADH2-TR activity was decreased and membrane ATP-ase was increased. The known increase in hydrolytic enzyme activities in denervated muscles was due to spilling of lysosomal enzymes from degenerating axons at the myoneural junction. This explains the discrepancy between morphological studies indicating paucity of lysosomes in normal muscles and the high hydrolytic enzyme activities in denervation. We propose that denervation changes are at least partly due to the effect of lysosomal spillage from degenerating axons.     

Effects of chloroquine on lysosomes and endocytosis by liver cells in vivo.

1. Chloroquine accumulation in rat liver after a single and repeated drug administration and lysosomal changes resembling some symptoms of lysosomal storage diseases were observed. 2. Repeated chloroquine treatment of rats resulted in increased activity of liver lysosomal enzymes acid phosphatase and beta-galactosidase and a significant enhancement of the activities of cathepsin D and cysteine proteinases were found. 3. No changes in the activity of liver macrophages (as assessed by the colloidal carbon clearance test) or in fluid-phase endocytosis of the marker 125I-polyvinyl-pyrrolidone by hepatocytes in vivo were found.     

Leishmania mexicana: a cytochemical and quantitative study of lysosomal enzymes in infected rat bone marrow-derived macrophages

The cellular localization and activity of the lysosomal enzymes acid phosphatase, trimetaphosphatase, and arylsulfatase were studied in rat bone marrow-derived macrophages infected with Leishmania mexicana amazonensis amastigotes. The specific activity of acid phosphatase normalized for protein content was similar in normal macrophages and in isolated amastigotes, whereas the latter were markedly deficient in trimetaphosphatase and arylsulfatase activities. It is thus likely that trimetaphosphatase and arylsulfatase activities detected in infected macrophages were of host cell origin. The activities of the three enzymes, assayed biochemically, varied independently in the infected macrophages. While arylsulfatase activity was unchanged after infection, the activity of acid phosphatase increased by 19, 40, and 94% at 6, 24, and 48 hr, respectively. Trimetaphosphatase activity rose only slightly during the first 24 hr after infection but increased by 74% at 48 hr. The rise in acid phosphatase activity could be accounted for only partially by multiplication of the amastigotes. Thus, as for trimetaphosphatase, these results suggest enhanced macrophage synthesis of acid phosphatase and/or reduced enzyme degradation by the infected macrophages. The reduction in host cell lysosomes previously described (Ryter et al. 1983; Barbieri et al. 1985) was confirmed but appearance of lysosomal enzyme activity in the parasitophorous vacuole is documented in the present report. Thus, Leishmania do not seem to reduce the amount and the activity of host lysosomal enzymes.     

Immunochemical characteristics of the peroxidases of several mouse tissues]

Enzymes catalyzing peroxidase reaction of a lysosomal fraction in bone marrow, leucocytes, spleen, thyroid gland, stomach, kidney, heart, lungs, brain and skeletal muscle of mice were investigated by immunochemical methods. A high level of peroxidase activity was discovered in leucocytes, bone marrow, spleen, heart and lung, a lower activity appeared to be characteristic of liver, thyroid gland and kidney. The peroxidase activities in brain, skeletal muscle and stomach were low. The reaction of immunoprecipitation with myeloperoxidase-specific antiserum revealed considerable antigenic distinctions between the enzymes catalysing peroxidase reaction in various tissues of mice.