Direct Interaction of ATP7B and LC3B Proteins Suggests a Cooperative Role of Copper Transportation and Autophagy

Macroautophagy/autophagy plays an important role in cellular copper clearance. The means by which the copper metabolism and autophagy pathways interact mechanistically is vastly unexplored. Dysfunctional ATP7B, a copper-transporting ATPase, is involved in the development of monogenic Wilson disease, a disorder characterized by disturbed copper transport. Using in silico prediction, we found that ATP7B contains a number of potential binding sites for LC3, a central protein in the autophagy pathway, the so-called LC3 interaction regions (LIRs). The conserved LIR3, located at the C-terminal end of ATP7B, was found to directly interact with LC3B in vitro. Replacing the two conserved hydrophobic residues W1452 and L1455 of LIR3 significantly reduced interaction. Furthermore, autophagy was induced in normal human hepatocellular carcinoma cells (HepG2) leading to enhanced colocalization of ATP7B and LC3B on the autophagosome membranes. By contrast, HepG2 cells deficient of ATP7B (HepG2 ATP7B−/−) showed autophagy deficiency at elevated copper condition. This phenotype was complemented by heterologous ATP7B expression. These findings suggest a cooperative role of ATP7B and LC3B in autophagy-mediated copper clearance.


Introduction
Copper is one of the d-block metals required by several enzymes to catalyze important biochemical reactions. The major role of copper is that of a redox-active element having the ability to adopt two oxidation states, the oxidized form Cu(II) and the reduced form Cu(I) which is utilized in energy production by the respiratory chain, free radical scavenging and synthesis of neuropeptides [1,2]. The cellular copper homeostasis is tightly regulated by active ion transport across cellular membranes, which act as natural barriers, via the lysosome-associated signaling network [3]. Once copper concentration increases beyond sustainable levels, the lysosomes will undergo exocytosis to export the stored copper from cells [3,4]. The copper-transporting protein, ATP7B (Copper-transporting ATPase 2; UniProtKB-Q64446) plays a central role in copper transportation from the cytosol to the cellular organelles. Mutations of the ATP7B gene (OMIM, 606882) cause Wilson disease (OMIM, 277900), which is an inherited disorder of copper accumulation in various tissues resulting in hepatic and neurological manifestation [5]. At physiological state, i.e., normal copper level, ATP7B is a trans Golgi network (TGN) resident membrane integral protein that transfers copper from the cytosol into the lumen of the TGN [6]. Copper will be further transferred to blood circulation via copper-binding proteins such as ceruloplasmin [7]. A high intracellular copper concentration stimulates the re-localization of ATP7B to lysosomal associated vesicle compartments [4]. Lysosomal ATP7B facilitates copper uptake into the lysosomal lumen. Lysosomes containing excess copper ions will be fused with the plasma membrane to release copper into the extracellular space.
However, recent studies have shown that autophagy is also associated with the copper clearance process. First, induction of autophagy with rapamycin could reduce the copper accumulation in senescent cells and, secondly, the deletion of the copper transport protein ATP7A led to stronger copper accumulation and a more pronounced autophagy-lysosome defect [8]. A later study suggested copper-induced autophagy as a survival mechanism to prevent cell death in human hepatocellular carcinoma HepG2 cells deficient of ATP7B (HepG2 ATP7B −/− ) [9]. The main role of autophagy is the cellular quality control. To this end, cargoes such as damaged organelles and waste products like aggregated proteins and other excess macromolecules are selectively removed [10]. The process requires double-membrane vesicles, the autophagosomes, to sequester cytosolic material prior to their fusion with endosomes or lysosomes and final degradation [11]. The autophagy process comprises induction, nucleation of the phagophore, elongation of the phagophore membrane to form the autophagosome, autophagosome-lysosome fusion and cargo degradation to produce new building blocks, and energy [12].
Autophagy induction is regulated by a number of sequential events involving different kinases. One of the major steps in autophagy is the phagophore elongation that is regulated by the formation of the lipidation of microtubule-associated protein light chain 3 (MAP1LC3, or short LC3) [13]. Lipidation of LC3 requires the cysteine protease Atg4B that processes the c-terminal end of LC3 to generate the LC3 active I variant (LC3I). Covalent conjugation of phosphatidylethanolamine (PE) to LC3I produces lipidated LC3II which in turn conjugates to phagophore membranes to promote autophagosome formation. Thus, LC3 is used as a bona fide autophagic marker [14,15].
The selection of cargoes to be degraded is mediated by the selective autophagy receptors. The receptor SQSTM/p62 (sequestosome 1) is one of the factors involved in the recognition of aggregated proteins, which are selected for elimination [16,17]. The nuclear dot protein52 (NDP52) and SQSTM/p62 receptors participate in the degradation of invading bacteria in the cellular defense mechanism, which constitutes a further vital role in which autophagy is involved [18,19]. Selective autophagy receptors are required for the recruitment of the selected cargoes on the autophagosome membranes via direct interaction of its two crucial domains, the unlipidated binding domain and the LC3 interaction region (LIR), with the ubiquitinated cargoes and LC3, respectively [20].
The LIR motifs not only play a role in the selection of the cargo to be eliminated, but LIR motifs of various proteins are also responsible for the rigorously coordinated course of the autophagy process by interaction with LC3. For instance, the LIR motifs of ULK1 are required to tether and stabilize the ULK1 complex on the autophagosome to promote the autophagy initiation and LIR motif of Atg4 is required for substrate LC3 recognition to mediate the cleavage which promotes the autophagy elongation [21,22]. Furthermore, the LIR motif has been found on the RavZ protein; the pathogenic bacteria protein from Legionella pneumophila that is produced to inhibit host autophagy requires the LIR motif to recognize LC3-PE for the cleavage [23,24]. This information suggests the interaction of distinct proteins containing LIR motifs with LC3 expanding interplay of autophagy and other cellular pathways.
The present study was designed to provide further mechanistic insights on whether the copper dependent ATPase ATP7B can act as an interface in the communication between unsustainably high copper concentrations and autophagy regulation. We found that one of the LIR motifs, designated LIR3, interacted with LC3B in vitro. Further evidence indicates partial colocalization of ATP7B and LC3B on the surface of the autophagosome membrane in HepG2 cells. Substitution of the conserved hydrophobic residues W1452 and L1455 on the LIR3 motif to alanine reduced the interaction of ATP7B and LC3B in vitro and in the cells. HepG2 cells deficient of ATP7B showed impaired autophagosome-lysosome fusion under elevated copper levels. Altogether, these results suggest that correct autophagymediated copper clearance depends on the LIR-motif mediated translocation of ATP7B to the autophagosome membrane.

Identification of Canonical LIR Motifs on ATP7B
The LIR motifs of ATP7B were identified from the iLIR webserver [25]. The amino acid sequence of ATP7B (UniProtKB, P35670) was submitted on the server and 21 canonical LIR-motifs were identified with an internal consensus sequence of W/F/YxxL/I/V (where x can be any amino acid). Furthering filtering of the results based on the knowledge that potential LIR motifs are located on the flexible or disordered regions of protein structures identified three likely LIR motifs on the ATP7B protein, including LIR1 (FAFDNV), LIR2 (TPWDQV), and LIR3 (DKWSLL).

Cloning and Purification of LC3B
LC3B gene was cloned into the expression pET-His 6 -MBP (Addgene, Watertown, MA, USA, 29708) and pET-His 6 -glutathione S-transferase (GST) (Addgene, 29655) vectors containing a TEV cleavage site located downstream from the affinity tags. The forward (TAAAATATTATGCCGTCGGAGAAGACC) and reverse primers (TAAGGATCCGTTA-CACTGACAATTTCATCCCGAA) containing SspI and BamHI enzyme restriction sites were used for the amplification of LC3B cDNA from pEGFP_LC3B vector was a kind gift from Karla Kirkegaard made available at addgene: http://n2t.net/addgene:11546; (accessed on 3 January 2019). The pET-His 6 -MBP-LC3B vector was used for LC3B protein production. The expression host, E. coli BL21-codonplus (DE3)-RIL (Agilent Santa Clara, CA, USA, 230245) cells were transformed with the pET-His 6 -MBP-LC3B vector. Protein expression was induced with 0.4 mM isopropyl β-D-1-thiogalactopyranoside (Carl Roth, 2316.3) at 20 • C overnight. The cells were harvested and resuspended in HEPES buffer containing 1 mg/mL lysozyme (Sigma Aldrich, L6876) and 1X protease inhibitor cocktail (Roche Life Science, Penzberg, Germany, 11697498001). Incubation at room temperature for 30 min and subsequent sonication was carried out to attain complete cell lysis. The supernatant was collected by centrifugation at 75,600× g using Beckman Coulter J-30I Avanti Centrifuge and JA-25.50 rotor for 30 min at 4 • C. The LC3B protein, containing His 6 /MBP tag at the N-terminus, was purified using Ni-NTA affinity chromatography (QI-AGEN, Hilden, Germany, 30210). The tags were cleaved with TEV protease (The European Molecular Biology Laboratory (EMBL), Heidelberg, Germany) and removed by performing a second step of Ni-NTA affinity chromatography. Protein concentration was measured with the Pierce™ BCA Protein Assay Kit (Thermo Scientific, 23227).

Fluorescent Polarization
Binding experiments were done in a black 384-microwell plate. The CF-labelled peptides and purified LC3B protein were dissolved in a HEPES buffer. Each CF-labelled peptide in a volume of 25 µL at a concentration of 2.5 µM was combined with 25 µL of LC3B at a concentration range from 0.2-330 µM. The fluorescent polarization was measured with the excitation and emission wavelengths of 535 nm and 585 nm, respectively. The obtained polarization data were corrected by subtraction of the peptide alone (blank). The dissociation constant (K d ) was quantified using a nonlinear curve fitting the site-specific binding on GraphPad Prism 5.0 for Windows (GraphPad Software, La Jolla, CA, USA). Experiments were performed in three independent replications.

Autophagy Detection
5 × 10 5 HepG2 cells were cultured in 2 mL of DMEM medium supplemented with 10% FBS and 1% P/S. Once the cell reached 80% confluence, they were treated with varied concentration of CuSO 4 (Sigma Aldrich, 209198) from 200 µM to 800 µM for 24 h. For the starvation induction, cells were additionally treated with Earle's Balanced Salt Solution (EBSS) media (Sigma Aldrich, E3024) for 2 h with or without 50 µM chloroquine (CLQ) prior to lysis with RIPA buffer containing inhibitor cocktails (Roche Life Science, 11697498001). Protein concentration was determined to be sure that the protein of each sample was equally loaded on the Criterion TGX precast gel for western blot detection. ATP7B, GAPDH and LC3B-II/LC3B-I was determined using the above-mentioned antibodies. Western Blot analysis was carried out as described above.

Colocalization Experiments
For the detection of the effect of copper on autophagosome-lysosome fusion, 50,000 cells of each HepG2 WT and HepG2 ATP7B −/− were grown on laminin-coated coverslips for 24 h, transduced with BacMam-GFP-RFP-LC3B overnight according to the manufacturer's recommendations. The cells were then treated with CuSO 4 at a concentration range from 100 µM to 800 µM for 24 h, fixed with 4% paraformaldehyde for 15 min and finally stained with 250 ng/mL DAPI (Thermo Fisher scientific, Molecular Probes, D1306) for 5 min. The coverslips were fixed on a glass slide using Mowiol 4-88 (Sigma Aldrich, 81381). The fluorescence cell imaging was acquired using a confocal Zeiss LSM 780 microscope with a 63 × 1.40 Oil DIC M27. The image sections with a comparable technical quality of BacMam signal strength and antibodies staining signal were randomly selected under the microscope to ensure an unbiased analysis. Red and yellow puncta count per cell was done using the particle analysis in image J. For protein ATP7B trafficking analysis, 50,000 cells of HepG2 WT and HepG2 ATP7B −/− were cultured in a 500 µL cell culture medium on a laminin-coated coverslip for 24 h, then transfected with EGFP-ATP7B. After 6 h post transfection, cells were transduced with BacMam-RFP-Golgi or the BacMam-RFP-Lysosome overnight, then treated with various concentrations of CuSO 4 or 200 µM of bathocuproine disulfonate (BCS) for 24 h or EBSS for 2 h, respectively. To detect LC3B or endogenous ATP7B, the fixed cells were incubated with anti-LC3B or anti-ATP7B antibodies at 4 • C overnight followed by secondary antibody incubation, Alexa Fluor 568 goat antirabbit, at temperature for 1 h in the dark. Pearson's correlation coefficient was analyzed per cell using the colocalization threshold of ImageJ Fiji.

Statistical Analysis
Statistical analyses were performed using two-way ANOVA followed by Sidak's multiple comparisons test using GraphPad Prism 5.0. The variance and differences with p < 0.05 were considered significant.

Investigation of LC3-ATP7B Interaction
Several autophagy associated proteins contain functional LC3 interacting regions, so-called LIR motifs. The LIR motif consists of a conserved W/F/YxxL/I/V sequence, in which the conserved aromatic residues are the key residues involved in hydrophobic interactions with the LC3 protein [27,28]. We employed an iLIR online server to identify potential LIR motifs on the ATP7B protein [25]. The iLIR online server identified 21 of the conserved W/F/YxxL/I/V motifs on ATP7B (Supplementary Figure S1a). As most of these motifs are located on rigid areas of the protein structure, they are not likely to interact with LC3 [29]. Thus, further filtering was required and led to three potential LIRs located on flexible structural parts of ATP7B. The first motif, LIR1, containing the sequence of FAFDNV, is located on the flexible N-terminal region, while the second and third motifs, LIR2 and LIR3, containing sequence of TPWDQV and DKWSLL, respectively, are located on the flexible C-terminal region (Figure 1a).
To investigate direct physical interaction, fluorescently labeled peptides containing LIR1-3 sequences from ATP7B were tested for binding with purified LC3B protein using the fluorescence polarization assay. Under the tested conditions, LC3B bound to LIR1 and LIR2 with such low affinity (K d > 250 µM) that actual binding under natural conditions is unlikely (Figure 1b). By contrast, LIR3 showed significant binding affinity with LC3B (K d = 3.72 ± 0.17 µM). Molecular docking simulations revealed that W1452 and L1455 of LIR3 interact in the canonical way with the first and second hydrophobic region on LC3B, respectively ( Figure 1c). In order to verify the importance of this interaction, residues W1452 and L1455 were substituted to alanine. W1452A substitution completely abolished LC3B interaction with no difference to the double substitution W1452A/L1455A (in both K d > 250 µM), whereas L1455A showed a residual binding (K d = 43.0 ± 1.0 µM), which was, however, decreased ninefold compared to native LIR3 (Figure 1b). Multiple sequence alignment of ATP7B among different species confirmed the LIR3 motif conservation (Supplementary Figure S1b). We also investigated the S1453 of LIR3, as it was found to be phosphorylated. S1453A substitution had no effect on the LC3B binding. However, the phosphorylation of S1453 caused a threefold increase in dissociation constant (K d = 12.9 ± 0.9 µM) (Figure 1b).
Interestingly, the tryptophan 1452 in ATP7B was found to be replaced with Histidine residue in ATP7A which suggests that LIR3 may represent a unique property of ATP7B in cellular communication between the copper metabolism and the autophagy pathways. Finally a pull-down assay was used to confirm direct binding of full-length ATP7B to LC3B. Recombinant GST-LC3B expressed in E. coli BL21 cells was used as bait to pull recombinant ATP7B from a HEK293H cell homogenate. As expected, wild-type ATP7B protein was detected in the elution fraction (Figure 1d), whereas binding of the variant W1452A/L1455A (ATP7B W1452A/L1455A ) was largely reduced. The technical control using GST only as bait was negative for ATP7B in the elution fraction (Supplementary Figure S2a). The decreased binding of recombinant ATP7B W1452A/L1455A compared to WT was also observed in samples from HepG2 ATP7B −/− cell homogenates (Supplementary Figure S2b).

Copper Induces Autophagy
Autophagy induction in the HepG2 WT cells was investigated following a 24 h treatment with CuSO 4 at a concentration range of 100 µM to 800 µM. A significant increase of LC3B-II was observed at high CuSO 4 concentrations of 600 µM and 800 µM (Figure 2 (ai),b). A control experiment with CuCl 2 showed a similar result (Supplementary Figure S2c) indicating that different copper sources had no apparent influence on autophagy induction in HepG2 cells. Next we wanted to check whether the increase of the LC3B-II is due to copper-induced autophagy in HepG2 cells and not a defect in autophagic flux due to a defective fusion of autophagosomes and lysosomes. We used a tandem sensor RFP-GFP-LC3B to monitor the autophagosome-lysosome fusion stage. An increased red/yellow puncta ratio occurred at a high CuSO 4 concentration indicating acid-quenching of the GFP protein suggestive of the elevation of autophagosome-lysosome fusion (Figure 2(ci)). The trend of increased fusion was steady depending on CuSO 4 concentration, and significance was reached at 800 µM.
CuSO 4 (Figure 2d). Thus, autophagy was activated depending on the copper and proceeded normally in the HepG2 cells.

Impairment of Copper-Induced Autophagy in HepG2 Cells Deficient of the ATP7B Copper
To investigate copper-dependent induction of autophagy in the absence of ATP7B, HepG2 ATP7B −/− cells were treated with CuSO 4 concentrations ranging from 100-800 µM. There was no difference in the level of LC3B-I compared to the wild-type cells (Figure 2(ai,aii)). However, in ATP7B −/− cells the level of LC3B-II was significantly lower upon treatment with CuSO 4 , and even at 600 µM and 800 µM the LC3B-II/LC3B-I ratio did not significantly alter (Figure 2b). The autophagosome and lysosome fusion activity was further observed in both cell lines. In contrast to the HepG2 WT cells, we found an increasing number of yellow puncta at higher CuSO 4 concentrations in the HepG2 ATP7B −/− cells (Figure 2(cii)). The red/yellow puncta ratio was significantly decreased at 800 µM CuSO 4 (Figure 2d). All of those results indicate a disturbed autophagosome-lysosome fusion activity in the HepG2 ATP7B −/− cells. To check if this is not a general autophagy problem in HepG2 ATP7B −/− cells, we applied starvation conditions using EBSS as a positive control for autophagy induction, and CLQ was applied to detect the LC3B flux at basal medium condition. Both HepG2 WT and HepG2 ATP7B −/− cells showed similar LC3B-I/LC3B-II conversion and elevation of the SQSTM1/p62 protein (Figure 2e,f). Moreover, HepG2 ATP7B −/− cells also exhibited the autophagosome-fusion activity under the EBSS treatment as similar to the wild-type cell (Figure 2(ci,cii)). Therefore, the abnormalities of the LC3B-I/LC3B-II conversion and autophagosome-lysosome fusion occurred only under the copper-induced autophagy in the HepG2 ATP7B −/− cells.
To further prove that the autophagy defect was a direct consequence of the ATP7B deficiency, we transiently transfected the HepG2 ATP7B −/− cells with wild type and mutant W1452A/L1455A N-terminal EGFP-tagged ATP7B plasmid vectors (EGFP-ATP7B-WT and EGFP-ATP7B W1452A/L1455A ). For analysis, the cells were sorted by flow cytometry to separate the untransfected cells from the positively transfected ones. At baseline copper level, LC3B-I to LC3B-II conversion was already evident in all cells complemented with either EGFP-ATP7B-WT or EGFP-ATP7B W1452A/L1455A (Supplementary Figure S3(ai,bi)). However, with rising concentrations of CuSO 4 the conversion deficit became evident in the EGFP-ATP7B W1452A/L1455A transfected compared to the EGFP-ATP7B-WT complemented cells, but still significantly higher than in the ATP7B-deficient control cell fraction (Supplementary Figure S3(aii,bii),c). Hence, positively EGFP-ATP7B-WT transfected cells showed a trend towards normalization of LC3I/LC3II conversion comparable to the HepG2 WT cells (compare Figure 2(ai) and Supplementary Figure S3(ai)).

Copper-Dependent Cellular Trafficking of ATP7B in HepG2 Cells
HepG2 WT cells expressing EGFP-ATP7B-WT were treated for 24 h with CuSO 4 to investigate cellular ATP7B localization. Surprisingly, only 2.6% of ATP7B was found colocalized with TGN positive compartments with no additional application of CuSO 4 ; this condition is hereafter called "basal medium condition" referring to: DMEM plus 10% fetal bovine serum plus 1% Penicillin-Streptomycin. However, a large proportion (68.7%) of ATP7B was colocalized with lysosomal LAMP1 protein (Supplementary Figure S4a-d).
After treatment with 400 µM CuSO 4 , the colocalization of EGFP-ATP7B with lysosomal structures even increased about 1.2-fold (83.6%) while no TGN fraction was detectable.
Endogenous ATP7B protein in HepG2 cells was probed and also found highly colocalized with lysosomes and there was a small portion of ATP7B localized with TGN (4.4%) at basal medium condition in agreement with earlier studies in HepG2 cells [4,31]. The lysosomal fraction of ATP7B could likewise be elevated upon CuSO 4 treatment while the TGN fraction of ATP7B disappeared (Supplementary Figure S4e,f).
As expected, only a small portion of EGFP-ATP7B was colocalized with the autophagy marker protein LC3B (2.4%) at basal copper concentration. This fraction was elevated under high CuSO 4 concentration by 4.8-fold (11.6%) (Figure 3a,c and Supplementary Figure S4d). Moreover, the colocalization of the ATP7B and LC3B was particularly observed on the surface of autophagosome vesicles as shown in the inset of Figure 3a. ATP7B W1452A/L1455A harboring the mutated LIR3 motif showed a similar preference to colocalize with LAMP1 positive compartments (77.8%) as the wild-type protein. However, it failed to colocalize with TGN under basal medium conditions (Supplementary Figure S5a,b) and showed inability to translocate to LC3B positive vesicles in response to CuSO 4 treatment (Figure 3b,c) indicating that this variant cannot perform its distinct purpose on autophagosome membranes. Lastly, we investigated whether the traces of detectable copper in the basal medium (<1 µmol/L) significantly altered ATP7B localization in the HepG2 cells. In fact, adding the copper chelator BCS to remove residual copper from the medium prior to the examination substantially elevated the ATP7B fraction in the TGN about 12.6-fold (32.8%) compared to basal medium condition (Supplementary Figure S4a,c,d). Despite the changed baseline situation with significantly more ATP7B in the TGN before CuSO 4 treatment, the autophagosomal fraction of ATP7B was not elevated upon the addition of CuSO 4 compared to ATP7B in cells under basal medium condition (Figure 3c). This suggests that the fraction of 11.6% LC3B colocalized ATP7B did not directly translocate from the TGN, warranting further research into the mechanism of ATP7B transport process under high copper levels.

Discussion
Several recent studies have examined the relationship between copper metabolism and autophagy. Some found that excess copper negatively influenced autophagy and impaired autophagic-lysosome degradation [8,32]. Recent research demonstrated that copper induced autophagy to protect cells from apoptotic cell death [9]. Our study demonstrated that copper induces autophagy in HepG2 WT cells. However, HepG2 ATP7B −/− cells revealed an abnormal course of autophagy at the LC3B-I to LC3B-II conversion stage under excess CuSO 4 overload >600 µM. A previous study demonstrated that oxidative stress-induction with H 2 O 2 impaired the conversion of LC3B-I to LC3B-II due to dysfunctionalization of the ubiquitination-like proteins ATG3 and ATG7, which are crucial for LC3B-II formation [33]. Since H 2 O 2 can be further decomposed into reactive oxygen species via Cu(I) involvement [34], this may serve as a valid explanation for the observed effects. Moreover, autophagosome-lysosome fusion was abnormal in HepG2 ATP7B −/− cells. Damaged lysosomes may cause impaired autophagosome-lysosome fusion, as irregular-sized and -shaped lysosome structures have been previously observed in the HepG2 ATP7B −/− cells under excess copper [9]. In order to closely investigate the autophagy dysfunction, we initially intended to monitor the degradation of SQSTM/p62 on western blot as well to demonstrate an altered autophagosome-lysosome fusion state in HepG2 ATP7B −/− . To our surprise, however, we observed the phenomenon that the SQSTM/p62 levels were subject to large interexperimental variation. A recent article reported that SQSTM/p62 gene expression can be stalled in HepG2 cells during prolonged starvation, which may lead to misinterpreted autophagy activation [35]. Therefore, an experimental alternative in the form of the Tandem GFP-RFP-LC3 was used to demonstrate the autophagosome-lysosome fusion state instead of SQSTM/p62. In any case, the presence of ATP7B is necessary to avoid cellular damage. The rescue of the LC3-I to LC3-II conversion phenotype in HepG2 ATP7B −/− cells by episomal ATP7B expression further suggests the prerequisite of the presence of ATP7B for the proper functioning of copper-induced autophagy. An effect that occurs via the direct, rapid copper shuttling is conceivable due to the rapid kinetics of complementation.
We hypothesized that ATP7B recognized LC3B via its LIR motif and translocates to LC3B-positive compartments such as autophagosomes. ATP7B, disrupted of the LIR3 motif by mutating tryptophan 1452 and leucine 1455, failed to translocate to the autophagosome membrane. Moreover, the mutant also failed to normalize the LC3-I to LC3-II conversion phenotype, indicating a persisting autophagosome-lysosome fusion deficit in the HepG2 ATP7B −/− cells under the excess copper condition. These results suggest that ATP7B-LC3B interaction and ATP7B translocation are important stages in the autophagy process under copper-elevated condition in the HepG2 cells. Further studies are required to investigate whether this interaction has a regulatory task to facilitate copper uptake into autophagosomes.
Only a small portion of ATP7B was found to be colocalized with LC3B in the HepG2 cells, either at basal medium condition or elevated copper. Instead, ATP7B is mainly localized on lysosomes in the HepG2 cells. Consistent with this finding, lysosomal localization of ATP7B in HepG2 cells at both low and high copper conditions was reported previously [4,36]. Other cell lines of hepatocytic origin, e.g., WIF-B and Can10, have been described as lacking the association of ATP7B with the lysosome at basal copper conditions, but show lysosomal translocation under high copper concentrations [37,38]. These cells may be more appropriate to study the ATP7B transport path beginning in the TGN.
A biochemical interpretation of the higher abundance of ATP7B on LAMP1 instead of LC3B-positive compartments could be that the interaction of the ATP7B with lysosomal targeting proteins might be stronger than the interaction with LC3B. This is due to the fact that ATP7B contains the conserved [D/E]xxx[LL] motif required for interaction with clathrin-associated adaptor protein complexes (APs), which target proteins on the clathrin coated vesicles to the lysosomes [39]. Remarkably, the [D/E]xxx[LL] motif of ATP7B, which is required for AP interaction, is identical to the amino acid sequence of LIR3 (DKWSLL), which is required for LC3B interaction. It is important to note that the hydrophobic residues W1452 and L1455 that are required for the LC3B interaction are also crucial for ATP7B localization at the TGN, as the double mutation abolished the TGN localization while localization with lysosome remained similar to the wild-type as shown in Supplementary  Figures S4a,b and S5a,b. This result suggests that residues W1452 and/or L1455 are important for the localization on the TGN [40,41] and that APs, likely AP1, are involved in the ATP7B localization on the TGN and retrieval from lysosomes since mutations of L1454 and L1455 on ATP7B significantly reduced interaction with AP1 [41]. However, the substitutions of either W1452 and L1455 with Alanine had no effect on lysosomal localization (suggesting that sorting of ATP7B to lysosomes emerges in an AP independent manner), but rather uses a Golgi bypassing route to cytoplasmic vesicles such as endosomes, autophagosomes and lysosomes directly from ER [42].
As the interaction of ATP7B with LC3B or the AP proteins is at the same site, there should be a molecular switch to define the interaction. It has been previously reported that the hyperphosphorylated ATP7B under the copper elevated condition facilitated ATP7B trafficking to cytoplasmic vesicles [43,44]. The S1453 within the DKWSLL motif was one of the residues found to be phosphorylated. Therefore, we further investigated the effect of the phosphorylation of the S1453 on the interaction with LC3B. We found a threefold increase in the dissociation constant, indicating that the phosphorylation status of LIR3 residue S1453 is likely to play a role in LC3B binding.

Conclusions
These high copper concentrations can trigger autophagy in the cell. This study provides the first evidence of a direct physical interaction between the LIR3 motif of the ATP7B copper transporting ATPase and the bona fide marker of autophagy, LC3B. More specifically, ATP7B localization on autophagosomal compartments was observed upon CuSO 4 treatment in HepG2 WT cells and ATP7B, recruited to the autophagosome membrane, may in turn facilitate the copper uptake into the autophagosome. Internalized copper may subsequently be eliminated into the extracellular space for further disposal. The abnormal autophagy process in HepG2-ATP7B −/− cells is evidence that the loss of ATP7B prevents the important interaction between ATP7B and LC3B at the interface between copper metabolism and the autophagy pathway. Moreover, the impaired autophagosomelysosome fusion in the HepG2 ATP7B −/− cell suggests an alternative, more complex role of ATP7B on the clearance of excess copper involving regulated intracellular translocation and facilitation of the autophagosome-lysosome fusion process at copper-induced autophagy, but the exact role of ATP7B in this context remains elusive.  Table S1: Sequences and monoisotopic masses of the peptides used in the study.