자가포식 - microautophagy, chaperon mediated autophagy에 대하

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Chaperone-mediated autophagy and endosomal microautophagy: Jointed by a chaperoneTHEMATIC MINIREVIEW: Chaperones and selective autophagy

Author links open overlay panelKumsal Tekirdag, Ana Maria Cuervo

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A variety of mechanisms deliver cytosolic materials to the lysosomal compartment for degradation through autophagy. Here, we focus on two autophagic pathways, the chaperone-mediated autophagy and the endosomal microautophagy that rely on the cytosolic chaperone hsc70 for substrate targeting. Although hsc70 participates in the triage of proteins for degradation by different proteolytic systems, the common characteristic shared by these two forms of autophagy is that hsc70 binds directly to a specific five-amino acid motif in the cargo protein for its autophagic targeting. We summarize the current understanding of the molecular machineries behind each of these types of autophagy.

다양한 메커니즘이 세포질 물질을 리소좀 구획으로 전달하여 자가포식을 통해 분해합니다. 여기서는 기질 표적을 위해 세포질 샤프론 hsc70에 의존하는 샤프론 매개 자가포식과 엔도솜 미세 자가포식이라는 두 가지 자가포식 경로에 중점을 둡니다. hsc70은 서로 다른 단백질 분해 시스템에 의해 분해될 단백질의 분류에 참여하지만, 이 두 가지 형태의 자가포식이 공유하는 공통적인 특징은 자가포식 표적을 위해 화물 단백질의 특정 5-아미노산 모티프에 직접 결합한다는 점입니다. 이러한 각 유형의 오토파지에 대한 분자 메커니즘에 대한 현재 이해도를 요약합니다.

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autophagy

chaperone

lysosome

membrane protein

protein targeting

selective degradation

Introduction

Autophagy refers to the degradation of a variety of cytoplasmic material in lysosomes (1). The delivery of autophagic cargo to lysosomes inside double membrane vesicles (autophagosomes) or macroautophagy has become the best characterized form of autophagy (Fig. 1) (2). However, cytosolic materials reach the lysosomal lumen through other mechanisms that also contribute to the overall intracellular autophagic activity (3). The lysosomal membrane can invaginate to internalize cargo in vesicles that pinch off from the invaginated membrane (4). This process known as microautophagy is conserved from yeast to mammals and contributes to degradation of proteins and organelles sequestered “in bulk” or in a selective manner (Fig. 1). Cytosolic proteins can also enter lysosomes for degradation through a protein translocation system at the lysosomal membrane, in a process known as chaperone-mediated autophagy (CMA)2 (Fig. 1) (5).

자가포식은 리소좀에서 다양한 세포질 물질이 분해되는 것을 말합니다(1). 이중막 소포(오토파고솜) 또는 거대 오토파지 내부의 리소좀으로 오토파지화물을 전달하는 것이 오토파지의 가장 특징적인 형태가 되었습니다(그림 1)(2). 그러나 세포질 물질은 전반적인 세포 내 자가포식 활동에도 기여하는 다른 메커니즘을 통해 리소좀 루멘에 도달합니다(3). 리소좀 막은 침입하여 침입한 막에서 꼬집어져 나오는 소포의 화물을 내재화할 수 있습니다(4). 미세 오토파지로 알려진 이 과정은 효모에서 포유류에 이르기까지 보존되어 있으며 '대량으로' 또는 선택적으로 격리된 단백질과 소기관을 분해하는 데 기여합니다(그림 1). 세포질 단백질은 또한 리소좀 막의 단백질 전위 시스템을 통해 리소좀으로 들어가 분해될 수 있으며, 이 과정에서 샤페론 매개 자가포식(CMA)2 (그림 1) (5)으로 알려져 있습니다.

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Figure 1. CMA and eMI in the context of mammalian autophagic pathways. In macroautophagy, cargo (proteins and organelles) sequestered inside autophagosomes in bulk (non selective macroautophagy) or selectively (left) is then delivered to lysosomes through autophagosome/lysosome fusion. In CMA all cargo (proteins) are selectively delivered to lysosomes upon recognition by hsc70 and targeting and binding to the lysosomal membrane protein LAMP2A. Microautophagy requires invagination of the lysosomal membrane to degrade cytosolic material. Proteins and organelles can also be targeted to late endosomes for degradation in mammals through what is known as endosomal microautophagy. Whether mammalian cells are able to directly invaginate the lysosomal membrane to trap cytosolic cargo, as described in yeast, remains unknown (??). CASA, chaperone-assisted selective autophagy.

포유류 자가포식 경로의 맥락에서의 CMA 및 eMI. 매크로 오토파지에서는 오토파지좀 내부에 대량으로(비선택적 매크로 오토파지) 또는 선택적으로(왼쪽) 격리된 화물(단백질 및 세포소기관)이 오토파지좀/리소좀 융합을 통해 리소좀으로 전달됩니다. CMA에서 모든 화물(단백질)은 hsc70에 의해 인식되고 리소좀 막 단백질 LAMP2A를 표적화하여 결합하면 리소좀으로 선택적으로 전달됩니다. 미세 오토파지는 세포질 물질을 분해하기 위해 리소좀 막의 침입을 필요로 합니다. 포유류에서 단백질과 소기관은 또한 소포체 미세 오토파지로 알려진 것을 통해 후기 소포체로 표적화되어 분해될 수 있습니다. 포유류 세포가 효모에서 설명한 것처럼 리소좀 막에 직접 침입하여 세포질화물을 포획할 수 있는지 여부는 아직 알려지지 않았습니다(??). 

The first CMA studies saw the light (6) when autophagy was still considered a non-selective form of in bulk degradation. This made CMA the first evidence that autophagy can be selective, because only the subset of cytosolic proteins bearing in their amino acid sequence a pentapeptide recognized by hsc70 (heat-shock cognate protein of 70 kDa) was selected for degradation through CMA. The landscape of autophagy has changed, and selective forms of both macro- and microautophagy have been described (Fig. 1). Cargo recognition by chaperones has been described for these three autophagic processes, and even the same chaperone, hsc70, can triage cytosolic proteins to all of them. hsc70 binds exposed hydrophobic residues in misfolded or aggregated proteins in the macroautophagy variant known as chaperone-assisted selective autophagy (7). This is in clear contrast to the sequence-mediated targeting of proteins by hsc70 to CMA or a selective form of microautophagy, endosomal-microautophagy (eMI) (8). Here, we review these two forms of sequence-specific hsc70-mediated selective autophagy describing their substrates, molecular effectors and regulators, and the intracellular compartments where they occur.

오토파지가 여전히 비선택적 형태의 대량 분해로 여겨지던 시절에 최초의 CMA 연구가 빛을 보았습니다(6). 아미노산 서열에 hsc70(열충격 인지 단백질 70kDa)에 의해 인식되는 펜타펩타이드를 포함하는 세포질 단백질의 하위 집합만이 CMA를 통한 분해를 위해 선택되었기 때문에 CMA는 오토파지가 선택적일 수 있다는 최초의 증거가 되었습니다. 오토파지의 환경이 바뀌었고, 매크로 오토파지와 마이크로 오토파지의 선택적 형태가 모두 설명되었습니다(그림 1). 샤프론에 의한 화물 인식은 이 세 가지 자가포식 과정에 대해 설명되어 왔으며, 동일한 샤프론인 hsc70도 세포질 단백질을 모두 분류할 수 있습니다. hsc70은 샤프론 보조 선택적 자가포식으로 알려진 매크로 오토파지 변형에서 잘못 접히거나 응집된 단백질의 노출된 소수성 잔류물에 결합합니다(7). 이는 서열을 매개로 한 hsc70의 CMA에 대한 단백질 표적화 또는 선택적 형태의 마이크로오토파지인 엔도솜-마이크로오토파지(eMI)(8)와는 분명한 대조를 이룹니다. 여기에서는 이 두 가지 형태의 서열 특이적 hsc70 매개 선택적 자가포식에 대해 기질, 분자 이펙터 및 조절자, 그리고 이러한 자가포식이 발생하는 세포 내 구획에 대해 설명합니다.

Chaperone-mediated autophagyGeneral description

CMA is a selective form of autophagy with distinctive mechanisms for cargo recognition and internalization into the lysosomal lumen (5). Only proteins amenable to unfolding can be internalized in lysosomes by CMA through a mechanism with resemblance to protein transport systems into other organelles such as mitochondria or ER (5).

CMA starts with binding of hsc70 (9) to a consensus pentapeptide motif in the substrate protein (6). hsc70 targets these proteins to the lysosomal membrane, and after binding to the cytosolic tail of LAMP2A (lysosome-associated membrane protein type 2A) (10), the substrate proteins are unfolded (11) and translocated one-by-one into the lysosomal lumen (Fig. 2). Transport through the membrane requires multimerization of LAMP2A into the CMA translocation complex (12) and a form of the hsc70 resident in the lysosomal lumen required to complete substrate translocation (13, 14). The substrates are then rapidly degraded in the lysosomal lumen.

CMA는 화물 인식 및 리소좀 루멘으로의 내재화를 위한 독특한 메커니즘을 가진 선택적 형태의 자가포식입니다(5). 펼쳐질 수 있는 단백질만 미토콘드리아나 ER과 같은 다른 소기관으로의 단백질 수송 시스템과 유사한 메커니즘을 통해 CMA에 의해 리소좀에서 내재화될 수 있습니다(5).

CMA는 기질 단백질의 컨센서스 펜타펩타이드 모티프에 hsc70(9)이 결합하는 것으로 시작됩니다(6). hsc70은 이 단백질을 리소좀 막으로 표적화하고, LAMP2A(리소좀 관련 막 단백질 2A형)의 세포질 꼬리에 결합한 후(10), 기질 단백질이 펼쳐져(11) 리소좀 루멘으로 하나씩 전위됩니다(그림 2). 막을 통한 수송을 위해서는 LAMP2A가 CMA 전위 복합체(12)로 다중화되어야 하고, 기질 전위를 완료하는 데 필요한 리소좀 내강에 상주하는 hsc70의 형태가 필요합니다(13, 14). 그런 다음 기질은 리소좀 루멘에서 빠르게 분해됩니다.

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Figure 2. Steps and lysosomal membrane components of CMA. Proteins degraded through CMA are recognized by hsc70 in the cytosol (step 1) and are targeted to the lysosomal membrane where they bind to LAMP2A (step 2). Substrate binding triggers multimerization of LAMP2A (step 3) to form the complex that mediates substrate translocation (step 4). hsp90 stabilizes LAMP2A through this transition, and luminal hsc70 assists with the internalization of the substrate that then is rapidly degraded by lysosomal proteases (step 5). The stability of LAMP2A in the translocation complex is regulated by the depicted subset of proteins. Once substrate translocate, LAMP2A, dissociates into monomers (step 6). Changes in the turnover of LAMP2A at the lysosomal membrane also contribute to modulate CMA activity (step 7).

Although effectors of other forms of autophagy are conserved from yeast to mammals, LAMP2A, the essential CMA component (10), appears late in evolution. LAMP2A is a spliced variant of the lamp2 gene, absent in yeast, fungi, and worms (15). A gene with homology to the mammalian lamp2 gene has been identified in Drosophila but with a C terminus homologous to LAMP2C, but there is no evidence of splicing. In zebrafish, the two lamp2 variants described show higher homology to the mammalian LAMP2B and -2C variants. The LAMP2A exon has so far been described only in birds and mammals (15).

CMA, as the other components of the cellular proteostasis networks (16), does not function in isolation. Blockage of CMA in vitro and in vivo is compensated for by up-regulation of macroautophagy and of the proteasome system in most cell types (17, 18). Conversely, cells respond to inhibition of macroautophagy or the proteasome by constitutively activating CMA (1920, 2122). In most cases, compensation ensures the maintenance of cellular quality control and the energetic balance under basal conditions (17, 1819). However, these systems are not redundant, and upon persistent loss, compensation is no longer possible (17, 19). For example, CMA is up-regulated in cells of Huntington’s disease patients to compensate for macroautophagy malfunctioning (23). However, this continuous overloading of CMA accelerates the normally occurring decline of CMA with age and contributes to accumulation of pathogenic huntingtin and other prone-to-aggregate proteins (23).

Characteristics of the proteome amenable for CMA degradation

All proteins degraded by CMA contain a pentapeptide-targeting motif and can completely unfold (24). Cytosolic origin was considered a characteristic of all CMA substrates but, recent studies, support that proteins from other compartments (i.e. nucleus or mitochondria) can also be degraded by CMA if they access the cytosol (18, 25).

The need for substrate unfolding is imposed by the translocation complex. Studies using an artificial CMA substrate unable to unfold demonstrated that unfolding is not required for lysosomal binding, but it is absolutely necessary for lysosomal translocation (11). Protein aggregates, irreversible oligomers (26, 2728), and proteins part of multiprotein complexes can only be degraded by CMA after disassembly and complete unfolding (29).

The pentapeptide-targeting motif in CMA substrates is necessary for their identification by hsc70 and sufficient for their lysosomal targeting (6). In fact, insertion of the motif in fluorescent proteins leads to their lysosomal degradation via CMA and are used as reporters of CMA activity (21). The motif is defined as KFERQ-like and is based on specific biochemical and physical properties of its constituent amino acids (24). Early experimental studies demonstrated that hsc70 binds to targeting motifs that contain one or two of the positively charged amino acids lysine (K) or arginine (R), one or two of the hydrophobic amino acids, phenylalanine (F), valine (V), leucine (L) or isoleucine (I), and one of the two negatively charged amino acids, aspartic acid (D) or glutamic acid (E), flanked by a glutamine (Q) on either side of this pentapeptide (6, 24).

Approximately, 40% of proteins in mammalian proteomes contain this KFERQ-like motif making them amenable for CMA once it is exposed (i.e. by unfolding, dissociation from other proteins, or from membranes) and accessible to hsc70 (24). The number of potential CMA substrates is estimated to be even higher, as new motifs can be generated by post-translational modifications such as phosphorylation (that contributes the negative charge) or acetylation of a lysine (that behaves as a glutamine) (3031, 3233).

The presence of a KFERQ-like motif is required to classify a protein as bona fide CMA substrate, but as described below, it is no longer sufficient because the same motif is also used by hsc70 to target cytosolic proteins to late endosomes via eMI (8). Hence, validation of proteins as CMA substrates requires experimental validation (5, 34).The list of experimentally validated CMA substrates continues to grow and includes a broad variety of proteins involved in diverse cellular processes such as glycolytic enzymes (18, 30, 35, 36), lipogenic enzymes (18), lipid droplet structural proteins (32), RNA-modifying enzymes (37), proteins involved in calcium biology (38, 39), transcription factors and their regulators (40, 4142), cell cycle regulators (25), ubiquitin–proteasome components (43), proteins involved in immune function (39, 44), and in cell survival/cell death decisions (4546, 4748), as well as a subset of proteins that contribute to the pathogenesis of known neurodegenerative disorders (23, 26, 2728, 43, 49, 5051).

Specific lysosomes dedicated to CMA

Even though the LAMP2A receptor is present in all types of lysosomes, not all lysosomes can perform CMA. The presence of hsc70 in lysosomes defines their CMA capabilities (14). The abundance of CMA-competent lysosomes (enriched on hsc70) fluctuates depending on the CMA requirements. During high CMA activity demand (i.e. sustained periods of starvation (14) and mild oxidative stress (52)), the number of CMA-competent lysosomes increases at the expense of a reduction in the number of other types of lysosomes (53). A similar lysosomal switch occurs during aging, when the number of LAMP2A molecules per lysosome decreases and cells compensate for this loss by increasing the percentage of lysosomes containing hsc70 (54).

Experimental introduction of hsc70 in the lumen of CMA-incompetent lysosomes is sufficient to make them capable to perform CMA (14), suggesting that CMA-inactive lysosomes contain the rest of the CMA machinery. Despite their higher efficiency for CMA, these lysosomes can still engage in the other autophagic pathways. For example, CMA-active lysosomes can fuse with autophagosomes, albeit with lower efficiency (55).

Lysosomal and cytosolic hsc70 originate from the same gene, but they present different electrophoretic properties in support of compartment-specific post-translational modifications (13). The exact mechanism by which hsc70 reaches lysosomes is unknown. Neither blockage of macroautophagy (20) or CMA (56) reduced the content of hsc70 in lysosomes. The abundance of hsc70 in late endosomes (8) makes attractive the idea that endosome/lysosome fusion may contribute hsc70 to the lysosomal lumen. The resistance of hsc70 to degradation is only maintained at a very acidic pH and small increases in lysosomal pH render lysosomal hsc70 unstable (14). It is possible that fluctuations in lysosomal pH determine changes in hsc70 conformation and lead to its rapid degradation.

The relatively small fraction of total intracellular hsc70 present in lysosomes has made it difficult to study. The proposed contribution of luminal hsc70 to substrate translocation is based on the fact that lysosomes lacking luminal hsc70 can bind CMA substrates, but do not internalize them, and that blockage of luminal hsc70 with antibodies against hsc70 internalized by endocytosis abolished CMA degradation (13).

Key CMA components: lysosomal chaperones and LAMP2A

Both cytosolic and lysosomal hsc70 are indispensable for CMA. A subset of co-chaperones, including Hsp90, Hsp40, the Hsp70–Hsp90-organizing protein (Hop), the Hsp70-interacting protein (Hip), and the Bcl2-associated athanogene 1 protein (BAG-1) associate to the complex hsc70/KFERQ-containing proteins (57), although the specific contribution of each of them to CMA remains unknown. Their many other cellular functions make the phenotypes resulting from their genetic knockdown difficult to interpret and of little use for understanding their role in CMA. Incubation of isolated lysosomes with blocking antibodies against hsc70 co-chaperones present at the lysosomal surface reduces substrate translocation suggesting that they could play a dual function by assisting hsc70 in substrate targeting and in their unfolding at the lysosomal membrane (Fig. 2) (57). hsc70 also participates in a later CMA step when it actively mediates disassembly of LAMP2A from the CMA translocation complex (12). The coordination and switch between these distinctive functions of hsc70 in different steps of CMA remain poorly studied.

Another key player in CMA is the membrane protein LAMP2A, required for both substrate binding and translocation (10, 12). Binding to LAMP2A is the rate-limiting step of CMA, and therefore, changes in the levels of LAMP2A at the lysosomal membrane up-regulate or down-regulate CMA (58). The lysosomal content of LAMP2A depends on its rates of de novo synthesis, efficiency of lysosomal trafficking, and changes in its half-life once in lysosomes. For example, LAMP2A synthesis increases during CMA activation by oxidative stress (52) or during T cell activation (39). The increase in lysosomal levels of LAMP2A during starvation is attained through a decrease in its degradation at the lysosomal membrane (58, 59) and relocation of LAMP2A present in the lysosomal lumen toward the membrane (58). Sub-compartmentalization of LAMP2A at the lysosomal membrane is responsible for its dynamic regulation. Under resting conditions, LAMP2A is periodically sequestered into lipid microdomains for cleavage by cathepsin A that initiates its membrane release and rapid degradation in the lumen (60). Upon CMA activation, LAMP2A is actively excluded from these microdomains (60). Recent studies have shown that defective targeting of LAMP2A from the Golgi to lysosomes is behind the low efficiency of CMA in the lysosomal storage disease cystinosis (61, 62). These findings highlight LAMP2A trafficking as a possible additional mechanism for regulation of CMA activity.

Binding of CMA substrates to LAMP2A occurs through its short (12 amino acids) cytosolic tail. Blockage of this region with specific antibodies, addition of a 12-residue peptide with the same amino acid composition, or swapping of this cytosolic tail with the one present in LAMP2B or LAMP2C reduce CMA (10, 63). Four positively charged residues, only present in the LAMP2A tail but not in B or C, are necessary for substrate binding (63).

Substrate binding to LAMP2A triggers the multistep transition of monomeric forms of LAMP2A into multimers (64) and their final assembly with other proteins into a translocation complex of about 700 kDa (Fig. 2) (12). Formation of this complex is transient and dynamic, as it disassembles once the substrate is translocated into the lysosome (12, 65). Continuous cycles of assembly and disassembly of LAMP2A may occur because substrates can only bind monomeric LAMP2A and can only be transported into the lumen when LAMP2A is in the translocation complex (12).

A second chaperone implicated in CMA is the lysosomal hsp90, which localizes both at the cytosolic and luminal sides of the lysosomal membrane. The latter helps to stabilize LAMP2A as it transitions through the different stages of multimerization (12).

CMA regulation

CMA is under regulatory mechanisms self-contained in the lysosomal compartment (65). Cleavage by cathepsin A determines the stability of monomeric LAMP2A (60), whereas the stability of the multimeric LAMP2A complex is regulated in a GTP-dependent manner by two proteins: GFAP (glial fibrillary acidic protein) and EF1α (elongation factor 1α) (65). GFAP associates transiently with multimeric LAMP2A and prevents hsc70-mediated disassociation of this complex (Fig. 2). A phosphorylated variant of GFAP is also present at the lysosomal membrane but is bound to EF1α, which makes it inaccessible for binding to other proteins. In the presence of GTP, EF1α is released from the lysosomal membrane, and unmodified GFAP moves from the multimeric complex to bind the exposed phospho-GFAP (65). This results in disassembly of LAMP2A from the CMA translocation complex and its return to the monomeric state (65).

Phosphorylation of lysosomal GFAP is performed by Akt1 under the control of the mechanistic target of rapamycin complex 2 (mTORC2), both at the lysosomal membrane (31). mTORC1, shown to negatively regulate macroautophagy, is present in all type of lysosomes, including CMA-competent lysosomes, but modulation of mTORC1 with drugs such as rapamycin does not affect CMA activity (21). In contrast, mTORC2 and its effector kinase Akt1 are almost exclusively detected in CMA-competent lysosomes where they negatively regulate assembly of LAMP2A into the CMA translocation complex (31). When CMA activation is needed, the phosphatase PHLPP1 (pleckstrin homology domain and leucine-rich repeat protein phosphatase 1), responsible for dephosphorylating Akt1, is recruited to lysosomes and stabilized at the membrane by the GTPase Rac1 (31). Reduced Akt1 activity increases the pool of non-phosphorylated GFAP thus favoring formation of the CMA translocation complex (Fig. 2).

Besides the lysosomal regulation of CMA, signaling through the nuclear receptor retinoic acid receptor α (RARα) (66) and the calcineurin–nuclear factor of activated T cells (NFAT) pathway (39) also regulate CMA. Genetic knockdown of RARα activates CMA in a transcription-dependent manner, suggesting that this nuclear receptor is an endogenous inhibitor of the subset of genes required for CMA (66). In T cells, CMA is activated upon engagement of the T cell receptor (TCR) that through generation of mitochondrial ROS promotes nuclear translocation of NFAT1 and its binding to the lamp2 promoter (39). Inhibition of calcineurin (activator of NFAT) or blockage of ROS production prevents CMA activation in this context.

Physiological relevance of CMA

CMA activity is detectable at basal conditions in most cells, but maximal activation occurs during stress such as nutrient deprivation (53, 67), mild-oxidative stress (52, 68), exposure to genotoxic or proteotoxic stressors (25, 69), hypoxia (70, 71), and lipid overload (Fig. 3) (32, 72).

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Figure 3. Physiology of CMA. CMA participates in cellular quality control. CMA participates in (A) cellular quality control through the removal of damaged or abnormal proteins and in (B) cellular metabolism and energetics through recycling of the amino acids of the degraded proteins and by selectively degrading rate-limiting enzymes of lipid and glucose metabolism. C, timely degradation of specific proteins through CMA confers this pathway's regulatory function in multiple cellular processes. Some of these processes and the CMA substrates involved in these pathways are depicted.

In most cells, CMA is up-regulated after periods of nutrient deprivation of 10 h or longer (17, 53) following the earlier macroautophagy response to starvation. Although macroautophagy switches from proteins to lipid (lipophagy) after 4–6 h of starvation (73), CMA activation persists past 3 days of starvation (53) becoming a source of recycled amino acids for protein synthesis (74). Part of these amino acids may also be used as cellular fueling, because cells with compromised CMA have reduced ATP levels (17, 75) and restoration of normal CMA activity in the livers of old mice increases their ATP content (76). Recent studies support that CMA may modulate cellular energetics through mechanisms other than mere amino acid recycling. Mice with selective knockout of LAMP2A in hepatocytes display defective handling of glucose and lipids due to loss of their ability to regulate levels of key metabolic enzymes that are usually turned over by CMA when their activity needs to be suppressed (18).

CMA also participates in protein quality control through selective removal of altered or damaged proteins (Fig. 3). Up-regulation of CMA upon mild oxidative stress facilitates degradation of oxidized proteins (52) that otherwise will aggregate and persist as intracellular protein inclusions (17). This explains why CMA blockage associates with an increase in intracellular protein aggregates (17, 56) and why old mice with preserved CMA activity show reduction in the age-dependent increase in aggregate-oxidized proteins (76).

The ability of CMA to selectively degrade intracellular proteins confers it specialized functions such as regulation of transcription by degradation of several transcription factors or control of cell cycle progression through degradation of cell cycle arrest proteins. CMA contributes to regulation of neuronal survival by degrading inactive forms of the transcription factor MEF2D (myocyte enhancer factor D) (45), of NFκB-mediated transcription via IκBα degradation (41), and of kidney growth through regulation of transcription factor Pax2 (42). The role of CMA in T cell activation is a result of its ability to timely degrade the negative regulators of T cell activation Itch and RCAN1 (39). Contribution of CMA to the immune response through the presentation of antigens in macrophages has also been described (Fig. 3) (77).

Interestingly, the contribution of CMA to protein quality control is compensated for by activation of macroautophagy and proteasome (18), but CMA regulatory functions of CMA are not absorbed by these other systems (39). These findings further supporting that autophagic pathways are not redundant and that each participates in specific cellular functions depending on their timing of activation and on substrate selectivity.

Endosomal microautophagyGeneral description

The concept that the lysosomal membrane invaginates to trap cytosolic components for degradation was proposed in the very early days of the discovery of autophagy. This process, termed microautophagy (4), was first studied in liver (78). Later studies described that yeast use a similar process for the sequestration and degradation of peroxisomes when switched to glucose as a source of energy (79) and lead to the discovery that some of the genes required for peroxisome microautophagy (GSA genes) (80) were shared with macroautophagy (81). Reconstitution of yeast microautophagy in vitro with isolated vacuoles (82) has allowed us to further identify the molecular machinery involved in this process (83).

The term microautophagy has been reserved for degradation of intracellular proteins and organelles directly engulfed by lysosomes or the vacuole (in yeast) (3). This degradation has now proven able to discriminate cargo, giving rise to terms such as micropexophagy (for peroxisomes) (79, 80), micromitophagy (for mitochondria) (84), or microlipophagy (for lipid droplets) (85). Even portions of the nucleus can undergo degradation through this invagination-mediated process (piecemeal microautophagy) (86). Selectivity of yeast microautophagy has been further supported by the discovery of specific cargo receptors, such as Nvj1p in piecemeal microautophagy (87).

리소좀 막이 세포질 성분을 가두어 분해한다는 개념은 오토파지가 발견된 초기에 제안되었습니다. 마이크로 오토파지(4)라고 불리는 이 과정은 간에서 처음 연구되었습니다(78). 이후 연구에서는 효모가 포도당을 에너지원으로 전환할 때 퍼옥시좀의 분리 및 분해에 유사한 과정을 사용하며(79), 퍼옥시좀 미세 오토파지에 필요한 일부 유전자(GSA 유전자)(80)가 거대 오토파지와 공유된다는 사실을 발견하게 되었습니다(81). 분리된 액포(82)로 시험관 내에서 효모 미세 오토파지를 재구성함으로써 이 과정에 관여하는 분자 메커니즘을 추가로 규명할 수 있었습니다(83).

미세 오토파지라는 용어는 리소좀이나 액포(효모의 경우)에 의해 직접 포식되는 세포 내 단백질과 소기관의 분해에 사용되어 왔습니다(3). 이러한 분해는 이제 화물을 구별할 수 있음이 입증되어 미세펙소파지(퍼옥시좀)(79, 80), 미세미토파지(미토콘드리아)(84) 또는 미세리포파지(지질 방울)(85)와 같은 용어가 생겨났습니다. 핵의 일부분도 이러한 침입 매개 과정(단편적 미세 오토파지)을 통해 분해될 수 있습니다(86). 효모 미세 오토파지의 선택성은 단편적 미세 오토파지에서 Nvj1p와 같은 특정 화물 수용체의 발견에 의해 더욱 뒷받침되었습니다(87).

The study of mammalian microautophagy has been slower because of the inability to detect an invagination-like process in secondary lysosomes and the fact that essential genes for yeast microautophagy have no conserved function in mammals. Relatively recent studies demonstrated that a degradative process of similar characteristics to yeast microautophagy occurs in mammals and in late endosomes/multivesicular bodies (LE/MVB) instead of lysosomes (8). This process, termed eMI, contributes to in bulk degradation of proteins present in cytosol trapped in vesicles forming at the LE membrane. However, some cytosolic proteins can also be selectively degraded by eMI after hsc70 binds in their sequence to the same pentapeptide motif previously described for CMA (Fig. 4) (8). hsc70 is not necessary for cargo targeting to microautophagy in yeast, but recent studies support the occurrence of hsc70-mediated eMI in Drosophila (88, 89). Below, we describe this type of hsc70-dependent eMI in the context of other types of microautophagy and in comparison with CMA (Fig. 5).

포유류의 미세 오토파지에 대한 연구는 이차 리소좀에서 침입과 유사한 과정을 감지할 수 없고 효모 미세 오토파지에 필수적인 유전자가 포유류에서 보존된 기능이 없다는 사실 때문에 더디게 진행되어 왔습니다. 비교적 최근의 연구에 따르면 포유류에서 효모 미세 오토파지와 유사한 특성의 분해 과정이 리소좀이 아닌 후기 엔도좀/다소체(LE/MVB)에서 발생한다는 사실이 밝혀졌습니다(8). eMI라고 하는 이 과정은 LE 막에 형성된 소포에 갇힌 세포질에 존재하는 단백질을 대량으로 분해하는 데 기여합니다. 그러나 일부 세포질 단백질은 hsc70이 이전에 CMA에 대해 설명한 것과 동일한 펜타펩타이드 모티프에 서열로 결합한 후 eMI에 의해 선택적으로 분해될 수도 있습니다(그림 4)(8). 효모에서 미세 오토파지에 대한 화물 표적화에는 hsc70이 필요하지 않지만 최근 연구에 따르면 초파리에서 hsc70 매개 eMI가 발생하는 것을 뒷받침합니다(88, 89). 아래에서는 다른 유형의 마이크로오토파지의 맥락에서 그리고 CMA와 비교하여 이러한 유형의 hsc70 의존성 eMI에 대해 설명합니다(그림 5).

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Figure 4. Mammalian endosomal microautophagy. Left, cytosolic proteins can be sequestered along with other cytosolic components by the invaginations that form in the surface of the endosomal membrane through the coordinated function of ESCRT (VPS4A/B and TSG101) and accessory proteins (Alix). Right, selective targeting to late endosomes of proteins bearing a KFERQ-like motif is mediated by hsc70. Upon cargo binding, hsc70 interacts directly with phosphatidylserine (PS) moieties of the endosomal membrane and is internalized along with the substrate in ESCRT-mediated microvesicles. Part of the internalized vesicles undergoes degradation in the endosomal lumen.

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Figure 5. Similarities and differences between CMA and eMI and assays to monitor protein degradation through them. A, summary of common and distinctive characteristics between CMA and eMI identified to date. B, recommended experimental approach to follow to discriminate involvement of CMA or eMI in the degradation of a protein. Blue boxes, methods; gray boxes, observed results.

eMI substrates

Mammalian eMI originated from studies attempting to characterize the contribution of autophagic pathways to antigen presentation in dendritic cells. Analysis of LE/MVB, where cytosolic antigens are processed for presentation, revealed that arrival of some cytosolic proteins persisted even upon genetic blockage of macroautophagy or CMA (8). However, blockage of components of the ESCRT complex I, required for MVB formation, abrogated trafficking of these cytosolic proteins into endosomes. Interestingly, most of the cytosolic proteins internalized through this ESCRT-dependent process underwent full degradation instead of limited cleavage for antigen presentation, thus fulfilling the criteria of an autophagic pathway (8). In fact, studies in other cell types and organs (i.e. liver and brain) confirmed that non-immunological cells also display this form of autophagy (8, 90) that has been named eMI to highlight its cellular localization.

Comparative proteomic analysis of MVB in cells with functional or disrupted ESCRT identified the pool of proteins usually degraded by eMI and confirmed the cytosolic origin of most of them (8). Some of these proteins were present in the vesicles at a similar ratio as in the cytosol, suggesting in bulk internalization. However, hsc70 and proteins bearing the KFERQ-like motif, previously associated only with CMA, were highly enriched in the vesicles (8). In vitro studies reconstituting eMI with isolated LE confirmed that proteins such as GAPDH or RNase A, classic examples of CMA substrates, can also be internalized in an hsc70- and ESCRT-dependent manner by eMI and that mutations in the KFERQ-like motif disrupt their targeting (8). In fact, an early proposed reporter for CMA activity based on fluorescent tagging of GAPDH has now been shown to undergo degradation by both pathways, thus limiting its usability to differentiate between them (91). Endogenous proteins such as Tau, a cytoskeletal protein associated with neurodegeneration, also undergo simultaneous degradation by both eMI and CMA (90). The fact that pathogenic mutations in Tau switch the percentage of the protein degraded by each of these pathways (90) suggests that intrinsic properties of the protein (i.e. mutations, post-translational modifications, oligomeric state, etc.) may be responsible for the autophagic switch of the substrate.

Despite sharing the KFERQ-like motif, CMA and eMI substrates are not fully overlapping. KFERQ-like motif-bearing proteins in a state of semi-aggregation, organized into higher molecular weight complexes or unable to unfold, cannot by degraded by CMA but are still amenable for eMI degradation. Thus, similar experiments to the ones that showed that proteins unable to unfold cannot undergo degradation by CMA (11) support that unfolding of cytosolic KFERQ-like bearing proteins is not a requirement for their association with late endosomes (8). Furthermore, contrary to CMA where the presence of the KFERQ-like targeting motif is necessary and sufficient for hsc70-mediated lysosomal targeting, adding a KFERQ-like motif is not sufficient for targeting of proteins through mammalian eMI. For example, the CMA reporter with a KFERQ-like sequence added to photo-switchable proteins is only targeted to CMA-competent lysosomes but not to endosomes (21), suggesting that the motif is necessary but not sufficient for mammalian eMI. As more eMI substrates become validated, identification of protein sequence or structure requirements for eMI targeting should become possible. In this respect, recent studies in Drosophila have demonstrated that a subset of synaptic proteins is turned over selectively by eMI (88). Interestingly, the requirements for Drosophila eMI are different, and addition of the KFERQ motif to a fluorescent protein is sufficient for its targeting through this pathway (89). Co-existence of CMA and eMI in mammals but not in Drosophila could have forced the need of a second requirement in mammals. Fig. 5 summarizes the main differences described so far between CMA and eMI and the experimental steps currently recommended to differentiate substrates for each of these pathways.

Late endosomes: Hosts for eMI

LEs are the point of entry of cytosolic proteins for eMI as their membrane contains a dedicated machinery (the ESCRT proteins) for invagination, formation of MVB, and their excision for release into the endosomal lumen. This process of LE membrane microvesiculation has been well-characterized in the context of degradation of membrane proteins internalized by endocytosis and in the extracellular release of cytosolic material in the form of exosomes. Components of the ESCRT complex I (i.e. TSG101), II (VPS25), and III (VPS32) and two of the accessory proteins, VPS4 and Alix, have been proven necessary for eMI (Fig. 4) (8, 89). Whether the full ESCRT machinery is required for eMI or whether biogenesis and properties of MVB for eMI differ from those utilized in membrane protein recycling is still unknown. Similarly, it is not clear whether degradation of plasma membrane proteins and eMI occur in the same type of late endosomes, or whether, as in the case of CMA, there is a specific subpopulation of LE dedicated to eMI.

Studies in vitro support that some eMI substrates undergo degradation in LE (i.e. Tau (90)), whereas other proteins (i.e. GAPDH) are internalized in LE, but their degradation is markedly less efficient than in lysosomes (8, 90). It is possible that in these cases most of the degradation occurs by endosomal/lysosomal fusion. Studies in Drosophila support this final degradation of eMI cargo in lysosomes, because an artificial eMI fluorescent substrate can be detected in LAMP1-positive compartments that lack endosome markers (89).

It is important to clarify that the process of eMI is different from the process of loading MVB for release as exosomes. Although both processes share ESCRT components for the loading of cytosolic proteins in MVB, the fate of the cargo is different. Thus, the term eMI should be limited for cytosolic proteins loaded in MVB that undergo degradation in this compartment or upon lysosomal fusion, whereas MVB loading for extracellular release of cytosolic proteins inside exosomes is a type of exocytosis and not a type of autophagy.

Molecular machinery of eMI

Although not required for all forms of microautophagy, hsc70 is the component that defines the type of selective eMI described in this Minireview. Upon binding the eMI substrate proteins through their KFERQ-like motif, hsc70 targets them to LE (8). The co-chaperone Sgt modulates the switch between the chaperone and eMI functions of hsc70 in Drosophila (88). However, the determinants of cargo triage between CMA and eMI remain unknown. During eMI, hsc70 binds directly to LE membranes, but despite their abundance on LAMP2A, hsc70 binds directly instead to phosphatidylserine (PS) at the LE membrane through a stretch of 4–5 lysine residues in the C terminus of the hsc70 LID domain (Fig. 4) (8). Mutations in this region have also revealed that PS binding is required to trigger cargo internalization (92). The role of hsc70 in eMI substrate internalization may be mediated by its ability to deform membranes through oligomerization (88). Whether hsc70 piggybacks in forming MVB or whether it actively triggers their formation is still unknown. Different from CMA, where after transferring the substrate to LAMP2A hsc70 is released back to the cytosol, in the case of eMI, hsc70 undergoes internalization and degradation with the cargo protein (8).

Several protein complexes have been implicated in other forms of microautophagy. For example, clathrin and a family of ER proteins (class E VPS) are necessary for yeast microlipophagy (93, 94), the family of proteins Niemann-Pick type C and the phosphoinositide-binding protein Ivy1 for the formation of membrane invaginations in yeast microautophagy (95, 96), and specific cargo-recognizing proteins contribute to micropexophagy, micromitophagy, and piecemeal microautophagy of the nucleus (84, 85, 87). However, the lack of systematic studies makes it difficult to sort out which molecular players are common to all microautophagy processes and which ones are process-specific. Similarly, the involvement of macroautophagy proteins (Atg) in microautophagy seems to depend on the type of microautophagy. Thus, yeast microlipophagy occurs independent of Atgs, whereas Drosophila eMI requires Atg1 and Atg13 (89).

eMI regulation

Activation of mammalian eMI has not been observed late upon starvation (8), in clear contrast with Drosophila eMI, which is maximally activated after starvation exceeding 24 h (89). This responsiveness of eMI to starvation in flies has led us to propose that eMI functions could have split late in evolution between eMI and CMA. The fact that Atg1 and Atg13, required for Drosophila eMI, act downstream of TOR suggests that this major nutrient sensor may be behind the starvation-induced activation of eMI. TOR and EGO also regulate yeast microautophagy (97) and microlipophagy (96), and 5′-AMP-activated protein kinase and Atg14 have also been implicated in the activation of microlipophagy (85).

Cytosolic hsc70 is a very abundant protein whose levels remain rather constant making it unlikely that changes in hsc70 levels are physiologically used to regulate eMI. Vesicle formation is the limiting step of microautophagy in yeast (82) and that also seems to be the case in eMI (92). It is thus more likely that changes in levels and dynamics of the assembly of ESCRT proteins may contribute to eMI regulation. It is also possible that availability of specific nutrients may contribute to modulate eMI through direct changes in the lipid composition of the late endosomal membrane, for example by expanding the raft-like membrane regions as recently described in yeast (95).

Physiological functions of eMI

Cellular functions of eMI remain for the most part unknown. A role for eMI in protein quality control has been proposed in light of its constitutive nature and the accumulation of oxidized proteins (most of them bearing KFERQ-like motifs) in MVB from old animals (98). Failure to timely eliminate these oxidized products in the dendritic cells of old mice negatively impacts LE and antigen processing and presentation with age. Yeast microautophagy contributes to quality control of intracellular membranes (99).

Selective targeting of proteins through eMI makes possible a regulatory effect of eMI on specific cellular processes by controlling intracellular levels of their limiting proteins. In this respect, blockage of eMI in Drosophila slows down neurotransmission by altering degradation of specific synaptic proteins (88). Active search for eMI substrates will help in gaining an understanding of the physiological relevance of this pathway.

Concluding remarks and pending questions

The landscape of selective autophagy has undergone major changes in recent years. Although CMA initially pioneered the concept of selectivity in lysosomal degradation, nowadays some level of selectivity in the cargo degraded has been described for almost every type of autophagy. As the molecular determinants of each pathway become known, it should become easier to understand the differences among these autophagic processes and their specific physiological relevance. The fact that the two different pathways described in this Minireview share not only the same chaperone but even the specific way in which hsc70 binds to the cargo highlights the level of cross-talk among different autophagic pathways and the existence of the mechanism in place, whereby substrates of a pathway can be easily rerouted to another pathway. However, the different dynamics and timing of activation of CMA and eMI make it impossible to compensate for specific regulatory functions of each of these pathways and result in functional phenotypes. Many open questions remain about the molecular mechanisms behind CMA and more so about eMI, their regulation and bases of their cross-communication with other pathways, and how hsc70 triages substrates between CMA and eMI. Further understanding of which intrinsic properties of the substrate proteins contribute to the hsc70-mediated triage will also help to complete this picture.

선택적 오토파지의 환경은 최근 몇 년 동안 큰 변화를 겪었습니다. CMA는 처음에 리소좀 분해의 선택성 개념을 개척했지만, 오늘날에는 거의 모든 유형의 자가포식에 대해 분해되는 화물에서 어느 정도의 선택성이 설명되고 있습니다. 각 경로의 분자 결정 요인이 알려짐에 따라 이러한 자가포식 과정 간의 차이점과 특정 생리적 관련성을 이해하는 것이 더 쉬워질 것입니다. 이 미니리뷰에서 설명한 두 개의 서로 다른 경로가 동일한 샤프론을 공유할 뿐만 아니라 hsc70이 화물과 결합하는 특정 방식까지 공유한다는 사실은 서로 다른 자가포식 경로 간의 누화 수준과 경로의 기질이 다른 경로로 쉽게 경로를 변경할 수 있는 메커니즘의 존재를 강조합니다. 그러나 CMA와 eMI의 활성화 역학과 타이밍이 서로 다르기 때문에 이러한 각 경로의 특정 조절 기능을 보상하는 것이 불가능하고 기능적 표현형을 초래할 수 있습니다. CMA의 분자 메커니즘, 특히 eMI의 조절 및 다른 경로와의 교차 통신의 기반, hsc70이 CMA와 eMI 사이에서 기질을 분류하는 방법에 대해서는 아직 많은 미해결 문제가 남아 있습니다. 기질 단백질의 어떤 고유한 특성이 hsc70 매개 분류에 기여하는지에 대한 추가 이해도 이 그림을 완성하는 데 도움이 될 것입니다.

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Ana Maria Cuervo

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Kumsal Tekirdag

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