The Hermansky-Pudlak syndrome 1 (HPS1) and HPS2 genes independently contribute to the production and function of platelet dense granules, melanosomes, and lysosomes

Hermansky-Pudlak syndrome (HPS) is an inherited hemorrhagic disease affecting the related subcellular organelles platelet dense granules, lysosomes, and melanosomes. The mouse genes for HPS, pale ear and pearl, orthologous to the human HPS1 and HPS2 (ADTB3A) genes, encode a novel protein of unknown function and the beta(3)A subunit of the AP-3 adaptor complex, respectively. To test for in vivo interactions between these genes in the production and function of intracellular organelles, mice doubly homozygous for the 2 mutant genes were produced by appropriate breeding. Cooperation between the 2 genes in melanosome production was evident in increased hypopigmentation of the coat together with dramatic quantitative and qualitative alterations of melanosomes of the retinal pigment epithelium and choroid of double mutant mice. Lysosomal and platelet dense granule abnormalities, including hyposecretion of lysosomal enzymes from kidneys and depression of serotonin concentrations of platelet dense granules were likewise more severe in double than single mutants. Also, lysosomal enzyme concentrations were significantly increased in lungs of double mutant mice. Interaction between the 2 genes was specific in that effects on organelles were confined to melanosomes, lysosomes, and platelet dense granules. Together, the evidence indicates these 2 HPS genes function largely independently at the whole organism level to affect the production and function of all 3 organelles. Further, the increased lysosomal enzyme levels in lung of double mutant mice suggest a cause of a major clinical problem of HPS, lung fibrosis. Finally, doubly mutant HPS mice are a useful laboratory model for analysis of severe HPS phenotypes.

Dictyostelium LvsB mutants model the lysosomal defects associated with Chediak-Higashi syndrome

Chediak-Higashi syndrome is a genetic disorder caused by mutations in a gene encoding a protein named LYST in humans ("lysosomal trafficking regulator") or Beige in mice. A prominent feature of this disease is the accumulation of enlarged lysosome-related granules in a variety of cells. The genome of Dictyostelium discoideum contains six genes encoding proteins that are related to LYST/Beige in amino acid sequence, and disruption of one of these genes, lvsA (large volume sphere), results in profound defects in cytokinesis. To better understand the function of this family of proteins in membrane trafficking, we have analyzed mutants disrupted in lvsA, lvsB, lvsC, lvsD, lvsE, and lvsF. Of all these, only lvsA and lvsB mutants displayed interesting phenotypes in our assays. lvsA-null cells exhibited defects in phagocytosis and contained abnormal looking contractile vacuole membranes. Loss of LvsB, the Dictyostelium protein most similar to LYST/Beige, resulted in the formation of enlarged vesicles that by multiple criteria appeared to be acidic lysosomes. The rates of endocytosis, phagocytosis, and fluid phase exocytosis were normal in lvsB-null cells. Also, the rates of processing and the efficiency of targeting of lysosomal alpha-mannosidase were normal, although lvsB mutants inefficiently retained alpha-mannosidase, as well as two other lysosomal cysteine proteinases. Finally, results of pulse-chase experiments indicated that an increase in fusion rates accounted for the enlarged lysosomes in lvsB-null cells, suggesting that LvsB acts as a negative regulator of fusion. Our results support the notion that LvsB/LYST/Beige function in a similar manner to regulate lysosome biogenesis.

New proteins from old diseases provide novel insights in cell biology

The lysosomal disease concept was developed by Hers in 1963. At the time, few could have imagined the breadth and depth of knowledge about cell biology that these disorders would reveal. With a collective hindsight of nearly four decades, it is fair to say that we have learned more about the lysosomal system of cells through the study of these rare diseases than by any other means. Given the advancements of the past year, it is apparent that some of the most significant insights are yet to come, as we delineate the last remaining and most enigmatic of these diseases.

The ocular albinism type 1 gene product is an N-glycoprotein but glycosylation is not required for its subcellular distribution

The ocular albinism type 1 (OA1) gene product is a membrane glycoprotein that may play a role in controlling melanosome growth and maturation. A number of mutations in the OA1 gene lead to ocular albinism due at least in part to retention of the aberrant protein in the endoplasmic reticulum. To examine whether N-glycosylation plays a role in the post-translational trafficking of the Oa1 protein, we constructed a series of mutant mouse Oa1 cDNAs encoding an Oa1-green fluorescent protein fusion in which some or all of the potential glycosylation sites were eliminated by site-directed mutagenesis. Biochemical studies in transfected cells treated with tunicamycin and peptide:N-glycosidase F suggest that asparagine at amino acid 106 is essential for N-glycosylation of the protein. Mutation at amino acid 106 that eliminated glycosylation did not affect the endo/lysosomal distribution of the Oa1 protein in either COS cells or cultured murine melanocytes.

Hermansky-Pudlak syndrome and Chediak-Higashi syndrome: disorders of vesicle formation and trafficking

The rare autosomal recessive metabolic disorders Hermanky-Pudlak syndrome (HPS) and Chediak-Higashi syndrome (CHS)share the clinical findings of oculocutaneous albinism and a platelet storage pool deficiency. In addition, HPS exhibits ceroid lipofuscinosis and CHS is characterized by infections and an accelerated phase. The two disorders result from defects in vesicles of lysosomal lineage. Of the two known HPS-causing genes, HPS1 has no recognizable function, while ADTB3A codes for a subunit of an adaptor complex responsible for new vesicle formation from the trans-Golgi network. Other HPS-causing genes are likely to exist. The only known CHS-causing gene, LYST, codes for a large protein of unknown function. In general, HPS appears to be a disorder of vesicle formation and CHS a defect in vesicle trafficking. These diseases and their variants mirror a group of mouse hypopigmentation mutants. The gene productsinvolved will reveal how the melanosome, platelet dense body, and lysosome are formed and trafficked within cells.

Targeting antigen in mature dendritic cells for simultaneous stimulation of CD4+ and CD8+ T cells

Due to their potent immunostimulatory capacity, dendritic cells (DC) have become the centerpiece of many vaccine regimens. Immature DC (DCimm) capture, process, and present Ags to CD4(+) lymphocytes, which reciprocally activate DCimm through CD40, and the resulting mature DC (DCmat) loose phagocytic capacity, but acquire the ability to efficiently stimulate CD8(+) lymphocytes. Recombinant vaccinia viruses (rVV) provide a rapid, easy, and efficient method to introduce Ags into DC, but we observed that rVV infection of DCimm results in blockade of DC maturation in response to all activation signals, including CD40L, monocyte-conditioned medium, LPS, TNF-alpha, and poly(I:C), and failure to induce a CD8(+) response. By contrast, DCmat can be infected with rVV and induce a CD8(+) response, but, having lost phagocytic activity, fail to process the Ag via the exogenous class II pathway. To overcome these limitations, we used the CMV protein pp65 as a model Ag and designed a gene containing the lysosomal-associated membrane protein 1 targeting sequence (Sig-pp65-LAMP1) to target pp65 to the class II compartment. DCmat infected with rVV-Sig-pp65-LAMP1 induced proliferation of pp65-specific CD4(+) clones and efficiently induced a pp65-specific CD4(+) response, suggesting that after DC maturation the intracellular processing machinery for class II remains intact for at least 16 h. Moreover, infection of DCmat with rVV-Sig-pp65-LAMP1 resulted in at least equivalent presentation to CD8(+) cells as infection with rVV-pp65. These results demonstrate that despite rVV interference with DCimm maturation, a single targeting vector can deliver Ags to DCmat for the effective simultaneous stimulation of both CD4(+) and CD8(+) cells.

Dexamethasone megadoses stabilize rat liver lysosomal membranes by non-genomic and genomic effects

PURPOSE

Membrane-stabilizing effects may be part of glucocorticoid action during high-dose glucocorticoid therapy. The present study investigates the mode of action of dexamethasone megadoses on rat liver lysosomal membranes.

METHODS

Following intravenous administration of dexamethasone in rats, the release of beta-glucuronidase from liver lysosomes was assessed ex vivo as a marker for lysosomal membrane integrity.

RESULTS

Dexamethasone megadoses significantly inhibited beta-glucuronidase release 10 min post-administration by 38% (3 mg/kg dexamethasone) and 33% (10 mg/kg dexamethasone) at corresponding dexamethasone liver concentrations of 3.9 x 10(-5) mol/kg and 15.1 x 10(-5) mol/kg, respectively. Comparable inhibition of beta-glucuronidase release (34% for 3 mg/kg and 38% for 10 mg/kg) was observed 24 h after administration of dexamethasone, although dexamethasone liver concentrations had already declined to 0.09 x 10(-5) mol/kg and 0.19 x 10(-5) mol/kg, respectively. A 2-h oral pretreatment of rats with the glucocorticoid receptor antagonist RU 486 (10 mg/kg) did not alter immediate (10 min) stabilization by dexamethasone (3 mg/kg). but almost completely prevented lysosomal membrane protection 24 h after dexamethasone injection.

CONCLUSIONS

Dexamethasone megadoses may preserve lysosomal membrane integrity by a dual action involving both rapid nongenomic effects occurring instantaneously after administration and long-term receptor-dependent genomic events.

Regulation of cell surface expression of CTLA-4 by secretion of CTLA-4-containing lysosomes upon activation of CD4+ T cells

CTLA-4 is expressed on the surface of activated T cells and negatively regulates T cell activation. Because a low-level expression of CTLA-4 on the cell surface is sufficient to induce negative signals in T cells, the surface expression of CTLA-4 is strictly regulated. We previously demonstrated that the association of CTLA-4 with the clathrin-associated adaptor complex AP-2 induces internalization of CTLA-4 and keeps the surface expression low. However, the mechanism to induce high expression on the cell surface upon stimulation has not yet been clarified. To address this, we investigated the intracellular dynamics of CTLA-4 by analyzing its localization and trafficking in wild-type and mutant CTLA-4-transfected Th1 clones. CTLA-4 is accumulated in intracellular granules, which we identified as lysosomes. CTLA-4 is degraded in lysosomes in a short period, and the degradation process may serve as one of the mechanisms to regulate CTLA-4 expression. Upon TCR stimulation, CTLA-4-containing lysosomes are secreted as proven by the secretion of cathepsin D and beta-hexosaminidase in parallel with the increase of surface expression of CTLA-4 and lysosomal glycoprotein 85, a lysosomal marker. These results suggest that the cell surface expression of CTLA-4 is up-regulated upon stimulation by utilizing a mechanism of secretory lysosomes in CD4(+)T cells.

Cathepsin D deficiency induces lysosomal storage with ceroid lipofuscin in mouse CNS neurons

Cathepsin D-deficient (CD-/-) mice have been shown to manifest seizures and become blind near the terminal stage [approximately postnatal day (P) 26]. We therefore examined the morphological, immunocytochemical, and biochemical features of CNS tissues of these mice. By electron microscopy, autophagosome/autolysosome-like bodies containing part of the cytoplasm, granular osmiophilic deposits, and fingerprint profiles were demonstrated in the neuronal perikarya of CD-/- mouse brains after P20. Autophagosomes and granular osmiophilic deposits were detected in neurons at P0 but were few in number, whereas they increased in the neuronal perikarya within days after birth. Some large-sized neurons having autophagosome/autolysosome-like bodies in the perikarya appeared in the CNS tissues, especially in the thalamic region and the cerebral cortex, at P17. These lysosomal bodies occupied the perikarya of almost all neurons in CD-/- mouse brains obtained from P23 until the terminal stage. Because these neurons exhibited autofluorescence, it was considered that ceroid lipofuscin may accumulate in lysosomal structures of CD-/- neurons. Subunit c of mitochondrial ATP synthase was found to accumulate in the lysosomes of neurons, although the activity of tripeptidyl peptidase-I significantly increased in the brain. Moreover, neurons near the terminal stage were often shrunken and possessed irregular nuclei through which small dense chromatin masses were scattered. These results suggest that the CNS neurons in CD-/- mice show a new form of lysosomal accumulation disease with a phenotype resembling neuronal ceroid lipofuscinosis.

Lysosome-related organelles

Lysosomes are membrane-bound cytoplasmic organelles involved in intracellular protein degradation. They contain an assortment of soluble acid-dependent hydrolases and a set of highly glycosylated integral membrane proteins. Most of the properties of lysosomes are shared with a group of cell type-specific compartments referred to as 'lysosome-related organelles', which include melanosomes, lytic granules, MHC class II compartments, platelet-dense granules, basophil granules, azurophil granules, and Drosophila pigment granules. In addition to lysosomal proteins, these organelles contain cell type-specific components that are responsible for their specialized functions. Abnormalities in both lysosomes and lysosome-related organelles have been observed in human genetic diseases such as the Chediak-Higashi and Hermansky-Pudlak syndromes, further demonstrating the close relationship between these organelles. Identification of genes mutated in these human diseases, as well as in mouse and Drosophila: pigmentation mutants, is beginning to shed light on the molecular machinery involved in the biogenesis of lysosomes and lysosome-related organelles.

Molecular genetic study of Pompe disease in Chinese patients in Taiwan

Pompe disease is caused by mutations in the acid alpha-glucosidase (GAA) gene. Multiple kinds of mutations in the GAA gene have been reported worldwide. In order to elucidate the molecular basis of the disease in Taiwanese patients of Chinese origin, we have recruited 11 unrelated families who had at least one member with Pompe disease for study. We used 16 pairs of oligonucleotide primers to amplify all the coding regions from exon 2 to 20 in the family members. The coding regions were sequenced on both the sense and antisense strands. We identified 7 different mutations in 17 alleles but failed to identify the defects in the other 5 alleles. The most common defect was D645E (Asp645Glu), accounting for 36% (8/22 alleles) of mutations, followed by G615R (Gly615Arg) (3 alleles); 1411del4 (Glu471-shift) (2 alleles); and one allele each of R600H (Arg600His); deltaN675 (deltaAsn675); 2380delC (Arg794-shift) and 2815delGT (Val939-shift). The molecular defects of Pompe disease are highly heterogeneous in Chinese. Characterization of the molecular defects of the disease is useful for a genotype-phenotype correlation and for genetic counseling and prenatal diagnosis.

An established light ear mutant (C57BL/6J-Pdeb(rd1) le) mouse cell line exhibits a block to secretion of lysosomal enzymes

The hypopigment mutant mice, light ear, pallid, and beige, possess defects in melanosomes, lysosomes, and platelet dense granules, suggesting that these organelles share a common biogenesis and processing. Light ear and pallid mutants are animal models for Hermansky Pudlak syndrome, whereas the beige mouse is an animal model for Chediak Higashi syndrome. An established skin cell line from the light ear mouse was tested along with pallid and beige cell lines for mutant effects on secretion of lysosomal hydrolase activities of six different lysosomal glycosidases and the trafficking of N-[5-(5,7-dimethyl BODIPY)-1-pentanoyl]-D-erythrosphingosine (C(5)-DMB-ceramide). There were no consistently significant differences between the pallid and the beige mutant cell lines or between these two mutant lines and the control cell line in the percentage secretion of lysosomal hydrolase activities. The light ear mutant cell line, however, displayed a significantly lower percentage secretion of lysosomal hydrolase activities than all other cell lines tested. The light ear mutant cells processed C(5)-DMB-ceramide completely, as seen in the control cell line, whereas pallid and beige cell lines retained fluorescent material and exhibited a block in the complete processing of C(5)-DMB-ceramide 20 h after labeling. The block to secretion of lyososomal hydrolase activities in the light ear mutant cell line will be useful for further studies on this mutant's lysosomal defect.

Encapsulation of DNA in new multilamellar vesicles prepared by shearing a lyotropic lamellar phase

Encapsulation of DNA in a new non-cationic multilamellar vector (Spherulites), composed of phosphatidylcholine, cholesterol and polyoxyethylene alcohol, is described here for the first time. Spherulites entrapping DNA were prepared by shearing a phospholipid lyotropic lamellar phase, using a recently discovered method. The average diameter of these vesicles ranges around 300 nm, and can be adjusted depending on the conditions of the process. The formulation did not result in cytotoxicity for the human cells and could be used as a DNA delivery system. More emphasis is brought to the role of condensing agents like histones on the encapsulation yield, which has been studied using radiolabelled DNA. It is shown that use of histones (histone to DNA ratio of 0.4) can increase significantly the encapsulation of DNA, thus improving the transfection efficiency. Transfection experiments were done with success using the beta-galactoside reporter gene on human primary cells (human skin fibroblasts and human bone marrow stromal cells). The results suggest that the spherulites have to be considered as a new and promising tool for gene transfection.

A role for the deep orange and carnation eye color genes in lysosomal delivery in Drosophila

Deep orange and carnation are two of the classic eye color genes in Drosophila. Here, we demonstrate that Deep orange is part of a protein complex that localizes to endosomal compartments. A second component of this complex is Carnation, a homolog of Sec1p-like regulators of membrane fusion. Because complete loss of deep orange function is lethal, the role of this complex in intracellular trafficking was analyzed in deep orange mutant clones. Retinal cells devoid of deep orange function completely lacked pigmentation and exhibited exaggerated multivesicular structures. Furthermore, a defect in endocytic trafficking was visualized in developing photoreceptor cells. These results provide direct evidence that eye color mutations of the granule group also disrupt vesicular trafficking to lysosomes.

Molecular characterization of a novel endonuclease (Xib) and possible involvement in lysosomal glycogen storage disorders

We cloned and partially characterized a human endonuclease (Xib) which shows sequence homologies to pancreatic DNase I but an enzymatic activity closer to DNase II. We report on the structural differences found between Xib and other recently cloned human DNases. Fluores cence microscopy analysis of transiently transfected cells with Xib::pEGFP constructs indicate that the protein is located in the cytoplasm and possibly anchored to a membrane, as deduced from a hydrophobic amino acid stretch present at the C-terminal end. Xib is overexpressed in muscle and cardiac tissues and is alternately spliced in several normal and neoplastic cells. In situ hybridization studies using human cardiac and muscle biopsies indicate accumulation of Xib transcript in the vacuoles of muscle cells from patients affected by vacuolar myopathy as acid maltase deficiency; however, no point mutations were detected in their DNA.

Molecular basis of the neuronal ceroid lipofuscinoses: mutations in CLN1, CLN2, CLN3, and CLN5

The neuronal ceroid lipofuscinoses (NCLs), also referred to as Batten disease, are a group of neurodegenerative disorders characterised by the accumulation of an autofluorescent lipopigment in many cell types. Different NCL types are distinguished according to age of onset, clinical phenotype, ultrastructural characterisation of the storage material, and chromosomal location of the disease gene. At least eight genes underlie the NCLs, of which four have been isolated and mutations characterised: CLN1, CLN2, CLN3, CLN5. Two of these genes encode lysosomal enzymes, and two encode transmembrane proteins, at least one of which is likely to be in the lysosomal membrane. The basic defect in the NCLs appears to be associated with lysosomal function.

Missense and nonsense mutations in the lysosomal alpha-mannosidase gene (MANB) in severe and mild forms of alpha-mannosidosis

alpha-Mannosidosis is an autosomal recessive lysosomal-storage disorder caused by a deficiency of lysosomal alpha-mannosidase activity. This disease shows a wide range of clinical phenotypes, from a severe, infantile form (type I), which is fatal at <3-8 years of age, to a less severe, late-onset form (type II), which ultimately may involve hearing loss, coarse face, mental retardation, and hepatosplenomegaly. To elucidate the molecular mechanism underlying this disease in both types of patients, we have used PCR, followed by either SSCP analysis or direct sequencing, to analyze the 24 exons and intron/exon boundaries of the alpha-mannosidase gene (MANB) from five patients. Two amino acid substitutions-H72L and R750W, in exons 2 and 18, respectively-and two nonsense mutations-Q639X and R760X, in exons 15 and 19, respectively-were identified in four type II patients. One amino acid substitution, P356R, was identified in exon 8 from a type I patient. This patient and three of the type II patients were homozygous for their mutations (H72L, P356R, R750W, and R760X) and one type II patient was heterozygous for the Q639X and R750W mutations. Transfection experiments of COS 7 cells, using the alpha-mannosidase cDNA containing one of the missense mutations-H72L, P356R, or R750W-revealed that each of these mutations dramatically reduces the enzymatic activity of alpha-mannosidase. These data demonstrate that widely heterogeneous missense or nonsense mutations of the MANB gene are the molecular basis underlying alpha-mannosidosis.

Gene transfer and expression of human alpha-galactosidase from mouse muscle in vitro and in vivo

Lysosomal storage disorders are amenable to treatment by enzyme replacement. Genetic modification of muscle via direct injection of expression vectors might represent an alternative method of providing the defective enzymes, if adequate and long-lasting expression levels can be achieved in muscle. We have used the C2C12 mouse myogenic cell line to study the effect of combination of muscle-specific regulatory elements on the expression of the human lysosomal enzyme alpha-galactosidase (alpha-gal). In differentiated myotubes, a construct containing the myosin light chain 1/3 enhancer in combination with the human cytomegalovirus promoter resulted in higher expression than constructs combining the same enhancer with the rabbit beta-myosin heavy chain promoter, or containing the CMV promoter only. Increased enzymatic activity was detectable both in cell extracts and in supernatants. Furthermore, human fibroblasts deficient in alpha-gal were able to take up the enzyme from medium conditioned by transfected myoblasts. This did not occur in the presence of mannose-6-phosphate which indicates that the uptake was via mannose-6-phosphate receptors. To our knowledge, this is the first report in which a correctly processed form of human alpha-gal was expressed and secreted from differentiated muscle cells. Direct injection of a plasmid expression vector into mouse tibialis anterior muscle showed significantly increased levels of alpha-gal 7 days after injection.

A new mutation in the gene for lysosomal acid lipase leads to Wolman disease in an African kindred

Cholesteryl ester storage disease (CESD) and Wolman disease (WD) are both autosomal recessive disorders associated with reduced activity and genetic defects of lysosomal acid lipase (LAL). The strikingly more severe course of WD is caused by genetic defects of LAL that leave no residual enzymatic activity. Mutations at the exon 8/intron 8 transition of the LAL gene have been identified in several CESD and WD patients and are responsible for the manifestation of the disease. We have determined the genetic defect in a 3-month-old boy of African origin affected by WD. No enzymatic activity of the lysosomal acid lipase was detectable in white blood cells and cultured fibroblasts. Analysis of his LAL cDNA and genomic DNA revealed that he was homozygous for a mutation at position -3 of the exon 8 splice donor site. A C-->T transition leads to a nonsense codon and to a premature termination of the LAL protein at amino acid 277. Due to this mutation, a shorter LAL mRNA species was also generated that lacked exon 8 and was deficient of the nonsense codon. As a consequence, the protein synthesis proceeded to the natural termination codon, but the enzyme generated had an internal deletion of 24 amino acids (254-277) and was also inactive. These findings, together with our previous observations when analyzing the mutations in WD and CESD patients lead to the conclusion that the more severe WD is due to mutations that absolutely abolish lysosomal acid lipase (LAL) enzyme activity and the cholesteryl ester storage disease phenotype is due to mutations that allow some residual LAL activity to be manifested.

Glycosylation and phosphorylation of lysosomal glycosylasparaginase

Glycosylasparaginase (EC 3.5.1.26) is a lysosomal amidase which hydrolyzes the bond between asparagine and the sugar moiety in N-linked glycoproteins. Deficiency of the enzyme results in aspartylglycosaminuria (AGU), the most common disorder of glycoprotein degradation. Mature enzyme is formed by two proteolytic cleavage steps subsequent to removal of its signal peptide: (1) an activation cleavage in the ER of the initial single-chain 49-kDa polypeptide into a 27-kDa alpha- and 19-kDa beta-subunit; (2) a cleavage in lysosomes which removes 10 amino acids from the C-terminus of the alpha-subunit without affecting enzyme activity. Each subunit of glycosylasparaginase contains one N-linked oligosaccharide (N38, alpha-subunit; N308, beta-subunit). Both oligosaccharides were phosphorylated and releasable by Endo-H digestion, indicating they were of the high-mannose type. These glycosylation sequenons were mutagenized to determine the role of the oligosaccharide at each site in proper folding and transport of glycosylasparaginase. An N38D mutant underwent the lysosomal processing step, indicating that targeting to lysosomes can be via the phosphorylated beta-subunit oligosaccharide alone. Deletion of the beta-subunit oligosaccharide oat N308 by an aspartic acid substitution resulted in very little protein or enzyme activity in the transfected cells, reemphasizing that glycosylation of the beta-subunit site is important for efficient folding and/or targeting. A different mutation to eliminate the same N-glycosylation sequenon (T310A) yielded more protein and enzyme activity, and a double mutant N38D/T310A yielded the same results as the single beta-subunit substitution. Yield of enzyme for all mutants was increased in cells treated with brefeldin A. The N308 glycosylation site of the beta-subunit appears to be more important in maintaining normal transport and stability of human glycosylasparaginase.

[Lysosomal system in hormonal mechanisms. Review]

The role of lysosomes in the intracellular mechanism of action of several steroid an proteic hormones has been demonstrated. In presence of the specific hormone the target cell induce membranal changes and the lysosomes are moved toward the nucleus; after this the lysosomal enzymes are released in the perinuclear space. For the moment it is not possible to know the biochemical role of this enzymatic activities upon the nucleic acids function and des-repretion process of specific genes, but the inhibition of lysosomes movement utilizing hormone antagonist or dexamethasone inhibits some reproductive process like the implantation of the mammalian egg. We present herein a review related with the mode action of some hormones through the lysosomes in reproductive processes.

Analysis of glucocerebrosidase activity using N-(1-[14C]hexanoyl)-D-erythroglucosylsphingosine demonstrates a correlation between levels of residual enzyme activity and the type of Gaucher disease

Glucosylceramide, a degradation product of complex glycosphingolipids, is hydrolysed in lysosomes by glucocerebrosidase (GlcCerase). Mutations in the human GlcCerase gene cause a reduction in GlcCerase activity and accumulation of glucosylceramide, which results in the onset of Gaucher disease, the most common lysosomal storage disease. Significant clinical heterogeneity is observed in Gaucher disease, with three main types known, but no clear correlation has been reported between the different types and levels of residual GlcCerase activity. We now demonstrate that a correlation exists by using a radioactive, short-acyl chain substrate, N-(1-[14C]hexanoyl)-D-erythro-glucosylsphingosine ([14C]hexanoyl-GlcCer). This substrate rapidly transferred into biological membranes in the absence of detergent [Futerman and Pagano (1991) Biochem. J. 280, 295-302] and was hydrolyzed to N-(1-[14C]hexanoyl)-D-erythro-sphingosine ([14C]hexanoyl-Cer) both in vitro and in situ, with an acid pH optimum. A strict correlation was observed between levels of [14C]hexanoyl-GlcCer hydrolysis and Gaucher type in human skin fibroblasts. The mean residual activity measured in vitro for 3 h incubation in type 1 Gaucher fibroblasts (the mild form of the disease) was 46.3 +/- 4.6 nmol of [14C]hexanoyl-Cer formed per mg protein (n = 9), and in type 2 and 3 fibroblasts (the neuronopathic forms of the disease) was 19.6 +/- 6.5 (n = 9). A similar correlation was observed when activity was measured in situ, suggesting that the clinical severity of a lysosomal storage disease is related to levels of residual enzyme activity.

Human resident langerhans cells display a lysosomal compartment enriched in MHC class II

Langerhans cells are the antigen-presenting cells of the skin, belonging to the family of dendritic cells, which present exogenous antigens in the context of major histocompatibility complex class II (MHC-II) molecules to CD4+ T lymphocytes. Langerhans cells are potent stimulators of different T-cell responses including primary immune responses. Culturing of Langerhans cells leads to modulation of their phenotype and function, as they seem more capable of activating T cells, whereas freshly isolated Langerhans cells are specialized in the endocytosing and processing of antigen. We studied the intracellular distribution of MHC-II molecules and invariant chain (I-chain) in resident Langerhans cells using immunogold labeling of ultrathin cryosections of human epidermis and found the majority of intracellular MHC-II molecules present on membranes of rough endoplasmic reticulum and in so-called MHC-II-enriched compartments (MIIC). The MIIC appeared to be negative for the cation-independent mannose 6-phosphate receptor and positive for the lysosomal enzyme beta-hexosaminidase and acquired the endocytotic tracer, cationized horseradish peroxidase, only after 60 min of internalization. Taken together, these data show that MIIC in Langerhans cells share characteristics with lysosomes. I-chain, which is associated with MHC-II molecules in early biosynthetic compartments, was found in the rough endoplasmic reticulum and Golgi complex, but was detected only occasionally in MIIC and at the plasma membrane. MIIC with internal membrane vesicles showed some I-chain labeling, suggesting that these are newly formed MIIC in which degradation of the I-chain is not yet complete.