Regulation of lamp2a levels in the lysosomal membrane

The selective degradation of cytosolic proteins in lysosomes by chaperone-mediated autophagy depends, at least in part, on the levels of a substrate receptor at the lysosomal membrane. We have previously identified this receptor as the lysosome-associated membrane protein type 2a (lamp2a) and showed that levels of lamp2a at the lysosomal membrane directly correlate with the activity of the proteolytic pathway. Here we show that levels of lamp2a at the lysosomal membrane are mainly controlled by changes in its half-life and its distribution between the lysosomal membrane and the matrix. The lysosomal degradation of lamp2a requires the combined action of at least two different proteolytic activities at the lysosomal membrane. Lamp2a is released from the membrane by the action of these proteases, and then the truncated lamp2a is rapidly degraded within the lysosomal matrix. Membrane degradation of lamp2a is a regulated process that is inhibited in the presence of substrates for chaperone-mediated autophagy and under conditions that activate that type of autophagy. Uptake of substrate proteins also results in transport of some intact lamp2a from the lysosomal membrane into the matrix. This fraction of lamp2a can be reinserted back into the lysosomal membrane. The traffic of lamp2a through the lysosomal matrix is not mediated by vesicles, and lamp2a reinsertion requires the lysosomal membrane potential and protein components of the lysosomal membrane. The distribution of lamp2a between the lysosomal membrane and matrix is a dynamic process that contributes to the regulation of lysosomal membrane levels of lamp2a and consequently to the activity of the chaperone-mediated autophagic pathway.     

Dietary lipids and aging compromise chaperone-mediated autophagy by similar mechanisms

Chaperone-mediated autophagy (CMA) is a selective form of autophagy whose distinctive feature is the fact that substrate proteins are translocated directly from the cytosol across the lysosomal membrane for degradation inside lysosomes. CMA substrates are cytosolic proteins bearing a pentapeptide motif in their sequence that, when recognized by the cytosolic chaperone HSPA8/HSC70, targets them to the surface of the lysosomes. Once there, substrate proteins bind to the lysosome-associated membrane protein type 2 isoform A (LAMP2A), inducing assembly of this receptor protein into a higher molecular weight protein complex that is used by the substrate proteins to reach the lysosomal lumen. CMA is constitutively active in most cells but it is maximally activated under conditions of stress.     

Dietary lipids and aging compromise chaperone-mediated autophagy by similar mechanisms

Chaperone-mediated autophagy (CMA) is a selective form of autophagy whose distinctive feature is the fact that substrate proteins are translocated directly from the cytosol across the lysosomal membrane for degradation inside lysosomes. CMA substrates are cytosolic proteins bearing a pentapeptide motif in their sequence that, when recognized by the cytosolic chaperone HSPA8/HSC70, targets them to the surface of the lysosomes. Once there, substrate proteins bind to the lysosome-associated membrane protein type 2 isoform A (LAMP2A), inducing assembly of this receptor protein into a higher molecular weight protein complex that is used by the substrate proteins to reach the lysosomal lumen. CMA is constitutively active in most cells but it is maximally activated under conditions of stress.     

Lysosomal membrane glycoprotein lamp2a--receptor for chaperone-mediated degradation of cytosolic proteins

The structure of several lysosomal membrane glycoproteins (lamp1, lamp2, limpI and limpII) has been described. The significance of the receptor glycoprotein lamp2a in the chaperone-mediated autophagy of cytosolic proteins with KFERQ motif has been described in details as well as the chaperone protein Hsc73 and other chaperones involved in this process. Several modulatory mechanisms of the chaperone-mediated autophagy, which is activated in condition of stress and starvation, were also outlined.     

植物表达分泌蛋白的运输及定位

分泌途径主要由内膜系统构成,内质网和高尔基体对于分泌蛋白的运输及定位具有重要作用。分泌蛋白的运输包括顺行途径和逆行途径。蛋白质通过质流和受体介导的途径运输到小泡中。在植物中,分泌蛋白的运输主要通过小泡和相连的小管来完成。分子伴侣和质量控制不仅能优化新合成蛋白的折叠和组装,而且去除了有折叠缺陷的蛋白。分泌蛋白的定位需要特定的信号肽,而高尔基体固有蛋白以依赖跨膜长度的方式,沿着分泌途径的细胞器分布。本文对植物表达分泌蛋白的分泌途径及定位、相关的分子伴侣和质量控制进行了综述。     

A conserved ubiquitin- and ESCRT-dependent pathway internalizes human lysosomal membrane proteins for degradation

The lysosome is an essential organelle to recycle cellular materials and maintain nutrient homeostasis, but the mechanism to down-regulate its membrane proteins is poorly understood. In this study, we performed a cycloheximide (CHX) chase assay to measure the half-lives of approximately 30 human lysosomal membrane proteins (LMPs) and identified RNF152 and LAPTM4A as short-lived membrane proteins. The degradation of both proteins is ubiquitin dependent. RNF152 is a transmembrane E3 ligase that ubiquitinates itself, whereas LAPTM4A uses its carboxyl-terminal PY motifs to recruit NEDD4-1 for ubiquitination. After ubiquitination, they are internalized into the lysosome lumen by the endosomal sorting complexes required for transport (ESCRT) machinery for degradation. Strikingly, when ectopically expressed in budding yeast, human RNF152 is still degraded by the vacuole (yeast lysosome) in an ESCRT-dependent manner. Thus, our study uncovered a conserved mechanism to down-regulate lysosome membrane proteins.

A study of how lysosomal membrane proteins are down-regulated reveals a conserved pathway involving ubiquitination of the membrane protein and subsequent internalization into the lysosome lumen by the ESCRT machinery for degradation.     

Lamellar bodies of rat alveolar type 2 cells have late endosomal marker proteins on their limiting membranes

Alveolar type 2 cells are known to take up surfactant phospholipids and proteins from the alveolar space and recycle them into secretory organelles via a receptor-mediated endocytic pathway. To clarify the intracellular route(s) through which materials ingested by the cells are processed, we examined the immunocytochemical localization of late endosomal and lysosomal membrane markers, rab 7 and lamp 1 proteins, within rat alveolar type 2 cells. The limiting membranes of lamellar bodies (LBs) showed positive immunoreactivity for both proteins, whereas multivesicular bodies (MVBs) exhibited positive immunoreactivity only for lamp 1 protein on free vesicles in the MVB lumen. From these findings, it is suggested that LBs are not only secretory granules, but also constitute one of the late endosomal compartments of the cells and that MVBs of this cell type may be targeted to cell organelle(s) other than lysosomes.     

Molecular assemblies and membrane domains in multivesicular endosome dynamics

Along the degradation pathway, endosomes exhibit a characteristic multivesicular organization, resulting from the budding of vesicles into the endosomal lumen. After endocytosis and transport to early endosomes, activated signaling receptors are incorporated into these intralumenal vesicles through the action of the ESCRT machinery, a process that contributes to terminate signaling. Then, the vesicles and their protein cargo are further transported towards lysosomes for degradation. Evidence also shows that intralumenal vesicles can undergo “back-fusion” with the late endosome limiting membrane, a route exploited by some pathogens and presumably followed by proteins and lipids that need to be recycled from within the endosomal lumen. This process depends on the late endosomal lipid lysobisphosphatidic acid and its putative effector Alix/AIP1, and is presumably coupled to the invagination of the endosomal limiting membrane at the molecular level via ESCRT proteins. In this review, we discuss the intra-endosomal transport routes in mammalian cells, and in particular the different mechanisms involved in membrane invagination, vesicle formation and fusion in a space inaccessible to proteins known to control intracellular membrane traffic.     

Lysosomal membrane proteins: life between acid and neutral conditions

Whereas we have a profound understanding about the function and biogenesis of the protein constituents in the lumen of the lysosomal compartment, much less is known about the functions of proteins of the lysosomal membrane. Proteomic analyses of the lysosomal membrane suggest that, apart from the well-known lysosomal membrane proteins, additional and less abundant membrane proteins are present. The identification of disease-causing genes and the in-depth analysis of knockout mice leading to mutated or absent membrane proteins of the lysosomal membrane have demonstrated the essential role of these proteins in lysosomal acidification, transport of metabolites resulting from hydrolytic degradation and interaction and fusion with other cellular membrane systems. In addition, trafficking pathways of lysosomal membrane proteins are closely linked to the biogenesis of this compartment. This is exemplified by the recent finding that LIMP-2 (lysosomal integral membrane protein type-2) is responsible for the mannose 6-phosphate receptor-independent delivery of newly synthesized β-glucocerebrosidase to the lysosome. Similar to LIMP-2, which could also be linked to vesicular transport processes in certain polarized cell types, the major constituents of the lysosomal membrane, the glycoproteins LAMP (lysosome-associated membrane protein)-1 and LAMP-2 are essential for regulation of lysosomal motility and participating in control of membrane fusion events between autophagosomes or phagosomes with late endosomes/lysosomes. Our recent investigations into the role of these proteins have not only increased our understanding of the endolysosomal system, but also supported their major role in cell physiology and the development of different diseases.     

The Sec translocon mediated protein transport in prokaryotes and eukaryotes

Protein transport via the Sec translocon represents an evolutionary conserved mechanism for delivering cytosolically-synthesized proteins to extra-cytosolic compartments. The Sec translocon has a three-subunit core, termed Sec61 in Eukaryotes and SecYEG in Bacteria. It is located in the endoplasmic reticulum of Eukaryotes and in the cytoplasmic membrane of Bacteria where it constitutes a channel that can be activated by multiple partner proteins. These partner proteins determine the mechanism of polypeptide movement across the channel. During SRP-dependent co-translational targeting, the ribosome threads the nascent protein directly into the Sec channel. This pathway is in Bacteria mainly dedicated for membrane proteins but in Eukaryotes also employed by secretory proteins. The alternative pathway, leading to post-translational translocation across the Sec translocon engages an ATP-dependent pushing mechanism by the motor protein SecA in Bacteria and a ratcheting mechanism by the lumenal chaperone BiP in Eukaryotes. Protein transport and biogenesis is also assisted by additional proteins at the lateral gate of SecY/Sec61α and in the lumen of the endoplasmic reticulum or in the periplasm of bacterial cells. The modular assembly enables the Sec complex to transport a vast array of substrates. In this review we summarize recent biochemical and structural information on the prokaryotic and eukaryotic Sec translocons and we describe the remarkably complex interaction network of the Sec complexes.     

TRPML: transporters of metals in lysosomes essential for cell survival?

Key aspects of lysosomal function are affected by the ionic content of the lysosomal lumen and, therefore, by the ion permeability in the lysosomal membrane. Such functions include regulation of lysosomal acidification, a critical process in delivery and activation of the lysosomal enzymes, release of metals from lysosomes into the cytoplasm and the Ca²⁺-dependent component of membrane fusion events in the endocytic pathway. While the basic mechanisms of lysosomal acidification have been largely defined, the lysosomal metal transport system is not well understood. TRPML1 is a lysosomal ion channel whose malfunction is implicated in the lysosomal storage disease Mucolipidosis Type IV. Recent evidence suggests that TRPML1 is involved in Fe²⁺, Ca²⁺ and Zn²⁺ transport across the lysosomal membrane, ascribing novel physiological roles to this ion channel, and perhaps to its relatives TRPML2 and TRPML3 and illuminating poorly understood aspects of lysosomal function. Further, alterations in metal transport by the TRPMLs due to mutations or environmental factors may contribute to their role in the disease phenotype and cell death.     

Endoplasmic reticulum degradation. Reverse protein transport and its end in the proteasome

Degradation of misfolded or unassembled proteins of the secretory pathway is an essential function of the quality control system of the Endoplasmic Reticulum (ER). Using yeast as a model organism we show that a mutated and therefore misfolded soluble lumenal protein carboxypeptidase yscY (CPY*), and a polytopic membrane protein, the ATP-binding cassette transporter Pdr5 (Pdr5*), are retrograde transported out of the ER and degraded via the cytoplasmic ubiquitin-proteasome system. Retrograde transport depends on an intact Sec61 translocon. Complete import of CPY* into the lumen of the ER requests a new targeting mechanism for retrograde transport of the malfolded enzyme through the Sec61 channel to occur. For soluble CPY*, but not for the polytopic membrane protein Pdr5* action of the ER-lumenal Hsp70 chaperone Kar2 is necessary to deliver the protein to the ubiquitin-proteasome machinery. Polyubiquitination of CPY* and Pdr5* by the ubiquitin conjugating enzymes Ubc6 and Ubc7 is crucial for degradation to occur. Also transport of CPY* out of the ER-lumen depends on ubiquitination. Newly discovered proteins of the ER membrane, Der1, Der3/Hrd1, and Hrd3 are specifically involved in the retrograde transport processes.     

Targeting of EGFP chimeras within chloroplasts

We have tested the potential of EGFP, a derivative of the green fluorescent protein (GFP), as a passenger protein for the analysis of protein transport processes across the thylakoid membranes in chloroplasts. In contrast to the majority of fusion proteins commonly used in such studies, EGFP is not of plant origin and can therefore be assumed to behave like a "neutral" passenger protein that is unaffected by any internal plant regulatory circuits. Our in vitro transport experiments clearly demonstrate that EGFP is a suitable passenger protein that can be correctly targeted either to the stroma or to the thylakoid lumen if fused to the appropriate transit peptide. The transport of EGFP across the thylakoid membrane shows, however, a clear pathway preference. While the protein is efficiently targeted by the deltapH/TAT pathway, transport by the Sec pathway is barely detectable, either with isolated thylakoids or with intact chloroplasts. This pathway specificity suggests that EGFP is folded immediately after import into the chloroplast stroma, thus preventing further translocation across the thylakoid membrane by the Sec translocase. The data obtained provide a good basis for the development of molecular tools for transport studies using EGFP as a passenger protein. Furthermore, plant lines expressing corresponding EGFP chimeras are expected to allow in vivo studies on the transport and sorting mechanisms involved in the biogenesis of the chloroplast.     

Role and regulation of the ER chaperone BiP

BiP, an HSP70 molecular chaperone located in the lumen of the endoplasmic reticulum (ER), binds newly-synthesized proteins as they are translocated into the ER and maintains them in a state competent for subsequent folding and oligomerization. BiP is also an essential component of the translocation machinery, as well as playing a role in retrograde transport across the ER membrane of aberrant proteins destined for degradation by the proteasome. BiP is an abundant protein under all growth conditions, but its synthesis is markedly induced under conditions that lead to the accumulation of unfolded polypeptides in the ER. This attribute provides a marker for disease states that result from misfolding of secretory and transmembrane proteins.     

IκB Is a Substrate for a Selective Pathway of Lysosomal Proteolysis

In lysosomes isolated from rat liver and spleen, a percentage of the intracellular inhibitor of the nuclear factor κ B (IκB) can be detected in the lysosomal matrix where it is rapidly degraded. Levels of IκB are significantly higher in a lysosomal subpopulation that is active in the direct uptake of specific cytosolic proteins. IκB is directly transported into isolated lysosomes in a process that requires binding of IκB to the heat shock protein of 73 kDa (hsc73), the cytosolic molecular chaperone involved in this pathway, and to the lysosomal glycoprotein of 96 kDa (lgp96), the receptor protein in the lysosomal membrane. Other substrates for this degradation pathway competitively inhibit IκB uptake by lysosomes. Ubiquitination and phosphorylation of IκB are not required for its targeting to lysosomes. The lysosomal degradation of IκB is activated under conditions of nutrient deprivation. Thus, the half-life of a long-lived pool of IκB is 4.4 d in serum-supplemented Chinese hamster ovary cells but only 0.9 d in serum-deprived Chinese hamster ovary cells. This increase in IκB degradation can be completely blocked by lysosomal inhibitors. In Chinese hamster ovary cells exhibiting an increased activity of the hsc73-mediated lysosomal degradation pathway due to overexpression of lamp2, the human form of lgp96, the degradation of IκB is increased. There are both short- and long-lived pools of IκB, and it is the long-lived pool that is subjected to the selective lysosomal degradation pathway. In the presence of antioxidants, the half-life of the long-lived pool of IκB is significantly increased. Thus, the production of intracellular reactive oxygen species during serum starvation may be one of the mechanisms mediating IκB degradation in lysosomes. This selective pathway of lysosomal degradation of IκB is physiologically important since prolonged serum deprivation results in an increase in the nuclear activity of nuclear factor κ B. In addition, the response of nuclear factor κ B to several stimuli increases when this lysosomal pathway of proteolysis is activated.     

Entering the lysosome through a transient gate by chaperone-mediated autophagy

A subset of cytosolic proteins can be selectively degraded in lysosomes through chaperone-mediated autophagy. The lysosomal-membrane protein type 2A (LAMP-2A) acts as the receptor for the substrates of chaperone-mediated autophagy (CMA), which should undergo unfolding before crossing the lysosomal membrane and reaching the lumen for degradation. Translocation of substrates is assisted by chaperones on both sides of the membrane, but the actual steps involved in this process and the characteristics of the translocation complex were, for the most part, unknown. We have now found that rather than a stable translocon at the lysosomal membrane, CMA substrates bind to monomers of LAMP-2A driving the organization of this protein into a high molecular weight multimeric complex that mediates translocation. Assembly and disassembly of LAMP-2A into and from this complex is dynamic and it is regulated by hsc70 and hsp90, the two lysosomal chaperones related to CMA. This work thus unveils a unique mechanism of protein translocation across the lysosomal membrane, which involves only transient discontinuity of the membrane. The possible advantages of this transitory lysosomal translocon are discussed in light of the unique properties of the lysosomal compartment.