Abstract
A threonine-to-Isoleucine (Thr52Ile) mutation within the pro-domain of the Sorcs1 gene was positionally cloned as the gene underlying a quantitative trait locus that affects fasting insulin levels in mice. In humans, genome-wide association studies and linkage studies have shown that SORCS1 is associated with diabetes and all of diabetes complications. We have recently shown that deletion of Sorcs1 in mice made obese with the leptinob mutation results in diabetes and an insulin granule stability defect. This present study investigates the functional consequence of the Sorcs1 Thr52Ile mutation in the rat INS1 β-cell line expressing either the wildtype or mutant Sorcs1 allele. We find that Sorcs1 Thr52Ile mutation is associated with increased basal insulin secretion, reduced glucose-stimulated insulin secretion and decreased insulin content in INS1 cells. Moreover, expression of Thr52Ile causes differential processing of the Sorcs1 protein resulting in the formation of an additional 90 kDa mutant form of the protein. The mutant form of the protein is localised to the ER, retains its pro-domain, and concurrently reduces expression of the functional mature 130 kDa Sorcs1 protein. These findings provide a mechanistic clue to why this specific allelic variation in Sorcs1 was associated with reduced insulin levels and type 2 diabetes.
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Introduction
Sorcs1 is a member of the vacuolar protein sorting -10 (VPS10) family of proteins. VPS10, when identified in yeast, was described as a receptor expressed in the trans-Golgi-network (TGN) that trafficks its cargo (the vacuolar hydrolase pro-carboxypeptidase-Y) from the TGN to the endosome1. In mammals, there are five members of the VPS10 protein family; Sortilin, SorLA, and Sorcs1-3. Sortilin and SorLA are well-studied and have been shown to play a role in intracellular protein trafficking and sorting, suggesting that all VPS10 proteins may play a similar role.
Sorcs1 is a type I transmembrane protein that comprises an N-terminal signal peptide, a pro-domain, a Vps10 domain (Vps10-D), a leucine-rich polycystic kidney disease domain, a transmembrane domain, and a short C-terminal cytoplasmic tail2, with alternatively spliced isoforms of the protein exhibiting differential subcellular localisation3,4. The conserved and characteristic Vps10-D of Sorcs1 and its family members contains a β-propeller forming a tunnel via which soluble ligands can interact5 and be transported between subcellular compartments6.
The link between Sorcs1 mutation and pathophysiology was first implicated in late-onset Alzheimer’s disease7, in which amyloid precursor protein transport and subsequent amyloid-β secretion are affected. Sorcs1 overexpression correlated with increased amyloid-β secretion, while a mutation in Sorcs1 at the cytoplasmic tail domain increased amyloid-β generation in human embryonic kidney cells, demonstrating a specific role for Sorcs1 in secretory protein retention and anterograde trafficking between the Golgi and the plasma membrane8,9.
Using a forward genetics approach employing the diabetes-resistant C57BL/6J (B6) and the diabetes-susceptible Black and Tan Brachyury (BTBR) mouse strains, introgression of the ob/ob allele identified quantitative trait locus for type 2 diabetes on chromosome 19 in the F2 generation10. Localisation of this locus in subcongenic BTBR mice expressing both the ob/ob allele and segments of B6 chromosome 19 revealed a single nucleotide polymorphism in the Sorcs1 gene (threonine-to-isoleucine substitution at amino acid 52 (Thr52Ile)), associated with the diabetic phenotype10. Mice homozygous for the B6 Sorcs1 allele exhibited fasting hyperglycaemia, reduced fasting plasma insulin levels, and irregular pancreatic islet morphology10. Subsequently, SORCS1 was identified in several human genome-wide association studies to be associated with diabetes11,12 and all of diabetes complications; neuropathy, hypoglycemia unawareness, retinopathy and nephropathy13.
In a follow up study, we generated mice with a global deletion of the Sorcs1 gene. When made obese with the leptinob mutation, the mice were severely diabetic and the pancreatic β-cells had a severe deficiency in insulin secretory granules. We concluded that Sorcs1 is involved in the trafficking and biogenesis of the insulin secretory granules14.
While the phenotype of Sorcs1 knock out mice provided an opportunity to study the consequence of a complete loss-of-Sorcs1, it does not necessarily provide true insight into the functional consequences of the non-synonymous Thr52Ile Sorcs1 variants associated with type 2 diabetes. The objective of this study was to investigate the consequences of Sorcs1 Thr52Ile in an in vitro model employing the well-established INS1 β-cell line. Under stable doxycycline inducible expression of either the wildtype BTBR Sorcs1 allele (wtSorcs1), or the mutant B6 Sorcs1 allele (mutSorcs1), differential processing of the Sorcs1 protein was observed. MutSorcs1-expressing cells demonstrated the formation and endoplasmic reticulum (ER) retention of a 90 kDa mutant pro-protein, which exhibited an extended half life and resulted in reduced total expression of the mature Sorcs1 protein. Functionally, this reduction was associated with increased basal insulin secretion, blunted glucose-stimulated insulin secretion and reduced total insulin content. As Sorcs1 mutation drives an obesity-regulated diabetic phenotype in animals, these findings have significant implications for the human-associated gene variants and substantiates its role as a genetic contributor to type 2 diabetes.
Materials and Methods
Cell culture
Glucose-responsive INS1 832/13 (INS1) rat β-cell line were stably transfected with wild type or mutant Sorcs1 cDNA, with a myc tag at the C-terminal, using the Tet-On system to generate doxycycline-inducible Sorcs1-expressing cells. Cells were cultured in RPMI 1640 medium supplemented with 10% FBS, 2 mM L-glutamine, 1 mM sodium pyruvate, 50 mM beta-mercaptoethanol, 10 mM HEPES, 1% penicillin-streptomycin, at 37 °C in 5% CO2. Sorcs1 expression was induced by addition of 2.25 µM doxycycline hyclate (Sigma, D9891) into culture media for 18 h at 37 °C (or 15 °C and 20 °C for temperature trapping experiments).
Generation of doxycycline inducible stable cell lines
The T-RExTm system from Invitrogen was used to generate the doxycycline-inducible Sorcs1 wildtype and mutant stable cell lines according to the manufacturer’s instructions. Briefly, INS1 832/13 cells, which expresses very low levels of endogenous Sorcs1, were first transfected with pcDNA™6/TR plasmid, which encodes the Tet repressor (TetR) under the control of the human CMV promoter, with Lipofectamine 2000 and selected with blasticidin to generate the TetR stable cell lines. A clonal stable cell line that expresses the highest levels of TetR was then used to transfect linearized pCDNA4TOMycHisA-myc-Sorcs1-WT or pCDNA4TOMycHisA-myc-Sorcs1-WT expression vectors and selected with zeocin.
Cell protein extraction and processing
Whole cell lysates (WCL) were obtained from cells using RIPA buffer (Merck, 20-188) containing cOmplete protease inhibitor cocktail (Roche, 4693159001), sonication using a tip probe for 20 s, and centrifugation at 14 k xg for 10 min. Protein quantification was performed using a BCA protein assay (Pierce, 23225). For disulphide bond reduction, WCL were treated with 10 mM DTT at 56 °C for 30 min, then 50 mM N-Ethylmaleimide (NEM) or iodoacetamide (IAA) was added to lysates for 40 min at RT in the dark prior to SDS-PAGE. For glycan cleavage analysis by western blot, WCL were treated with either 1250 U or 2500 U Endo H (NEB, P0702S) or 500 U PNGase F (NEB, P0709S) under denaturing conditions as per manufacturer’s protocols, after overnight induction of Sorcs1 expression prior to analysis by SDS-PAGE. For proprotein convertase inhibition, cells were incubated in culture media containing 10 µM proprotein convertase inhibitor (Calbiochem, 537076) or DMSO control for 30 min prior to 18 h induction of Sorcs1 expression. For protein synthesis inhibition, cells were incubated with either DMSO or 5 µM cyclohexamide for up to 2 hours prior to harvest in RIPA buffer.
Western blotting
Cell lysates were analysed on 7.5% Tris-glycine-SDS-PAGE under reducing conditions of either 0.1 M DTT or 1% (v/v) BME, and probed with mouse anti-myc (Merck, 900000032846), mouse anti-beta-actin (Sigma, A5441) and rabbit anti-GAPDH (Santa Cruz, sc-25778) antibodies respectively.
Immunofluorescent staining
Cells were plated onto glass coverslips, fixed with 4% PFA for 20 min at RT, washed with 0.1% BSA in PBS with 0.01% Sodium Azide. Following permeabilisation with 0.1% SDS for 5 min, cells were blocked with Serum-Free Protein Block (DAKO, X0909) for 1 h prior to overnight staining at 4 °C with mouse anti-myc (Merck, 900000032846), guinea pig anti-insulin (DAKO, A0564), rabbit anti-TGN38 (Sigma, T9826), rabbit anti-ERp72 (CST, D70D12) or rabbit anti-Calnexin (Abcam, ab22595) antibodies. Then cells were washed, incubated with fluorescent conjugated secondary antibodies (Invitrogen) for 1 h at RT in the dark, washed, then mounted onto microscope slides with Prolong Diamond Antifade Mountant containing DAPI (Thermo Fisher, P36965). Slides were imaged using a Leica TCS SP8 confocal microscope using a 100 X oil objective.
Glucose stimulated insulin secretion assay
Cells are plated overnight in culture media, before media is replaced with HEPES Krebs Ringer buffer (KRBH) (20 mM HEPES, pH 7.4; 119 mM NaCl; 4.75 mM KCl; 2.54 mM CaCl2; 1.2 mM MgSO4; 1.18 mM KH2PO4; 5 mM NaHCO3), containing 2.8 mM glucose for 1 h at 37 °C for basal incubation. Cells are then stimulated with KRBH containing either 2.8 or 16.7 mM glucose for 1 h at 37 °C, and media was collected for insulin secretion determination by Insulin ELISA (Crystal Chem) or Insulin HTRF (Cisbio). Cells were washed then scraped into PBS, centrifuged at 300 xg for 5 min to pellet, then sonicated for 10 s in 50 uL of Lysis Buffer (100 mM Tris, 300 mM NaCl, 10 mM NaF, 2 mM Na) for analysis of total cell DNA concentration (Quant-iT Picogreen DNA kit, Thermo Fisher) and total cell insulin content (HTRF, Cisbio). Insulin secretion and insulin content data are both expressed relative to total cell DNA content.
Subcellular fractionation
Whole cell protein extracts were collected by scraping cells into HEPES/EGTA buffer (5 mM HEPES, 1 mM EGTA), lysed by needle pulse by passing 15 times through a 21-gauge needle, then centrifuged at 1000 xg, 5 min and 4 °C. Supernate was layered on the top of a continuous sucrose gradient of 2 M to 0.45 M sucrose in HEPES/EGTA buffer and centrifuged in a Thermo Fisher superspeed centrifuge (A22-24 × 16 rotor) for 18 h. Sucrose fractions were collected from the top of the gradient and diluted 2:1 with reducing Laemmli sample buffer (4% SDS, 20% glycerol, 10% beta-mercaptoethanol, 0.004% bromphenol blue, 0.125 M Tris HCl) for analysis by SDS-PAGE.
Sorcs1 immunoprecipitation
WCL was pre-cleared using 50% Protein G Sepharose beads (GE Life Sciences, 17061801) prior to immunoprecipitation. Precleared WCL was incubated with anti-myc tag antibody-conjugated agarose beads (Merck, 16-219) overnight at 4 °C, centrifuged at 1000 xg for 30 s, washed at least three times with NP-40 buffer, then twice with PBS. Beads were resuspended into 4X Laemmli sample buffer and protein was eluted with incubation at 95 °C for 10 min and analysed by SDS-PAGE.
In-gel digestion
Protein eluate was separated in a 7.5% Tris-glycine SDS-PAGE and incubated with Coomassie brilliant blue G-250 (Sigma, B0770) for 20 min, rinsed in distilled water and destained in 10% methanol and 7% acetic acid to remove background staining. Protein bands were excised from the gel, diced into 1 × 1 mm pieces and immersed in 30% acetonitrile and 7% triethylammonium bicarbonate and incubated in a Thermomixer C (Eppendorf) for 15 min at 1000 rpm at 22 °C, until gel pieces appeared colourless. The gel was then dried for 5 min in a GeneVac EZ-2 (SP Scientific), incubated in 100 mM DTT and 100 mM NH4HCO3 at 56 °C for 30 min. Supernate was discarded, gel pieces were dehydrated in acetonitrile for 5 min, supernate removed again and gel pieces dried by GeneVac EZ-2 for 5 min before addition of 200 mM indole-3-acetic acid and 100 mM NH4HCO3 and incubation at RT for 40 min in the dark. Supernate was removed, gel pieces dried by GeneVac EZ-2, then rehydrated in 13 µg/ml trypsin in 100 mM NH4HCO3 at 4 °C for 1 h, with additional 100 mM NH4HCO3 added to submerge gel pieces for overnight incubation at 37 °C. Supernate was transferred to a fresh tube, and excess peptides extracted with addition of 60% acetonitrile/0.1% trifluoroacetic acid and sonication for 15 min in a Sonorex Digitec ultrasonic water bath (Bandelin), repeated three times with solution transferred to a fresh tube each time. Final solution was dried using a GeneVac EZ-2.
Peptide desalting
Stage-tips were used in this procedure. Tips were washed once with methanol, once with Elution Buffer (80% acetonitrile, 0.1% trifluoroacetic acid) and then three times with Loading Buffer (0.1% trifluoroacetic acid). Peptides were resuspended in Loading Buffer and loaded onto the stage-tip, then washed thrice with Loading Buffer. Peptides were eluted in Elution Buffer, then dried using a GeneVac EZ-2.
Liquid chromatography tandem mass spectrometry
Peptides were identified using an UltiMate 3000 (Dionex) paired with a Q-Exactive Plus (Thermo Fisher Scientific) in positive polarity mode. Peptides were separated using an in-house packed 75 μm × 40 cm C18AQ column with a 1.9 μm particle size. Separation occurred in a 10–35% ACN gradient containing 0.1% Formic acid at 250 nl/min at 55°C for 90 min. MS1 scan was acquired from a 350–1550 m/z range with a 70 000 resolution, 3e6 automatic gain control (AGC) and 100 ms injection time. Data-dependent acquisition of the top 20 ions was achieved using higher-energy collisional dissociation with a 35 000 resolution, 1e6 AGC, 120 ms injection time, 27% normalised collision energy and a 1.2 m/z isolation width.
MS data analysis
Raw data was processed using MaxQuant (v1.5.3.24) (2) against a hybrid database, including a complete rat Uniprot database (06/2016, 37 529 entries) (3), one mouse Sorcs1 protein sequence (Uniprot ID Q9JLC4-2) and the corresponding Thr52Ile mutant sequence; both containing a C-terminal myc sequence. Processing was conducted using default settings, with the following exceptions: Oxidation of methionine and acetylation of the protein N-terminus were set as variable modifications, and carbaminomethylation of cysteine was set as a fixed modification. Both protein false discovery rate and peptide spectral match were set to 1%. Database-searching was performed twice, with either trypsin or semispecific trypsin as the digestion mode; combining the identification results.
Statistics
All statistical analysis was performed in GraphPad Prism version 8.2.0. Statistical significance was determined by two-tailed student’s t-test or one-way ANOVA with Tukey’s multiple comparisons post-test. A value of p < 0.05 was considered significant.
Results
Sorcs1 Thr52lle mutation results in defective basal insulin secretion
It was a Thr52Ile mutation in the pro-domain of the mouse Sorcs1 protein that led to the identification of the gene as a type 2 diabetes gene10 (Fig. 1A). We will refer to this allele as mutSorcs1. This mutation causes a reduction in insulin levels and congenic mice with insertion of the B6 mutSorcs1 allele in the BTBR background display lower fasting plasma insulin as well as a reduction in insulin during a glucose tolerance test validating that mutSorcs1 underlies the associated phenotype10. In this study, we assesed the functional consequence of mutSorcs1 in vitro by expressing the two variants in INS-1 β-cells and measured glucose-stimulated insulin secretion and insulin content. MutSorcs1 expressing INS-1 cells exhibited significantly heightened basal levels of insulin secretion, with an approximate doubling of insulin secretion under basal conditions (p < 0.05 by one-way ANOVA), and reduced glucose-stimulated insulin secretion (Fig. 1B). Further, cellular insulin content of mutSorcs1 expressing INS-1 cells was significantly lower compared to cells expressing wtSorcs1 (Fig. 1C), validating that our cell system phenocopies the loss of insulin associated with the mutation in mice.
Sorcs1 Thr52lle mutation forms an uncleaved protein product of 90 kDa
Sorcs1 is translated as a precursor protein (pro-Sorcs1) which is processes to its mature 130 kDa form by furin-mediated cleavage of an N-terminal 77 animo acids pro-peptide15. We obtained a clue to the functional consequence of mutSorcs1 when we expressed the two variants that contained C-terminal myc-tag in INS1 β-cells, under a doxycycline-inducible system. On 7.5% SDS-PAGE, immunoblotting of the myc-tag showed that wtSorcs1 allele expression results in the formation of a large band at 130 kDa corresponding to the mature protein. However, expression of the Thr52Ile mutSorcs1 allele was visualised as three unique bands corresponding to not only the 130 kDa mature protein band, but additional bands at approximately 90 kDa and 180 kDa (Fig. 1D). It was likely that the large band observed at 130 kDa also contained the pro-form of the Sorcs1 (pro-Sorcs1), and the mature 130 kDa band of both wtSorcs1 and mutSorcs1 resolved as a doublet containing pro-Sorcs1 and mature Sorcs1 in an 7.5% SDS-PAGE when run for an extended duration to specifically separate out higher density proteins (Supplementary Fig. 1A). This was also observed when Sorcs1 was separated on a Bolt™ 4–12% Bis-Tris Plus Gels in Bolt MOPS SDS running buffer (Supplementary Fig. 1B). Densitometry analysis of the mutSorcs1 bands demonstrated that their cumulative density was similar to that of the 130 kDa wtSorcs1 band (Fig. 1E), while densitometry analysis of multiple mutSorcs1 samples indicated that the 90 kDa and 130 kDa bands constituted the predominant forms of the protein (Fig. 1F). We hypothesised that a processing defect, such as additional N-terminal cleavage of mutSorcs1 (as both forms possess the c-terminal myc-tag), could be responsible for the lighter protein product.
Additional 90 kDa mutSorcs1 band is not altered by proprotein cleavage
Conversion of pro-Sorcs1 to its mature form normally occurs through processing by furin-mediated cleavage at two sites15, however, an additional pro-protein convertase cleavage site was predicted to exist in both Sorcs1 alleles16. As the 90 kDa mutSorcs1 band retained its C-terminal myc tag, we aimed to investigate if the mutSorcs1 protein was the result of additional cleavage sites. To investigate this, both wtSorcs1 and mutSorcs1 - expressing INS-1 cells were treated with a cell permeable pro-protein convertase inhibitor (PCI) targeted to furin, but also PC1/3, PC4, PC5/6 and PACE417 in a dose curve (Supplementary Fig. 2A). SDS-PAGE of control and PCI treated cells revealed a small shift in the 130 kDa band in both wtSorcs1 and mutSorcs1–expressing cells to a slightly heavier product at a 10 µM treatment dose, corresponding to a density shift to the pro-Sorcs1 protein (Fig. 2A). A specific furin-inhibitor also mediated the same shift in the 130 kDa wtSorcs1 band (Supplementary Fig. 2B). However, no change in mass was observed in either the lighter 90 kDa fragment or the heavier 180 kDa fragment of Sorcs1 resulting from expression of the mutSorcs1 allele, indicating that its generation was unaffected by pro-protein convertase activity.
To more definitively characterise the mutSorcs1 90 kDa product, peptide identification by LC-MS/MS was performed on 130 kDa and 90 kDa protein bands excised from gels processed from immunoprecipitated Sorcs1 in wtSorcs1 and mutSorcs1 – expressing INS1 samples (Fig. 2B). As expected, the 130 kDa band (corresponding to both pro-Sorcs1 and mature Sorcs1) products from wtSorcs1 and mutSorcs1 demonstrated similar peptide coverage. Most strikingly, peptide coverage of the mutSorcs1 90 kDa product also spanned coverage of the pro-domain of the Sorcs1 protein (Fig. 2C). In agreement with the PCI experiments, these data demonstrate that the protein size discrepancy is not a result of N-terminal cleavage of the mutant protein. Raw peptide coverage data for all three experiments are included in Supplementary Table 1, and peptide quantification by trypsin and semi-specific trypsin digestion excluded peptide contamination.
Additional 90 kDa mutSorcs1 band is not altered by disulphide bonds
All available cysteines within the common Vps10p-D of Sortilin, including 10 of the conserved cysteines within the C-terminal region, have been shown to form disulphide bonds18. Using prediction software analysis, Sorcs1 is expected to have 10 high confidence disulphide bonds. Therefore, we tested the possibility that altered intermolecular disulphide bonding was the cause of the additional mutSorcs1 protein bands observed. INS1 cells expressing wtSorcs1 and mutSorcs1 were immunoblotted in both reducing and non-reducing conditions, however the migration of all mutSorcs1 protein bands were unchanged (Fig. 2D). Densitometry analysis also found no difference between density ratios of the 130 kDa and 90 kDa mutSorcs1 bands in reducing and non-reducing conditions (Fig. 2E).
As the reducing agents used above (DTT and 2-mercaptoethanol) were potentially reversible, we validated these findings by performing irreversible blocking of cysteine oxidation with iodoacetamide or NEM under reducing conditions. A small shift in motility of all mutSorcs1 bands, as well as the 130 kDa wtSorcs1 band (Fig. 2F) indicated that all protein products contained oxidized cysteines – though their presence in the 90 kDa mutSorcs1 was not enough to account for the molecular mass discrepancy compared to wtSorcs1. To eliminate potential misinterpretation of data due to reagents diffusing between adjacent lanes during SDS-PAGE, we included blank lanes between reduced versus non-reduced samples and obtained similar results (Supplementary Fig. 2C).
The 90 kDa mutSorcs1 protein product is formed and retained in the ER
Sequence analysis of murine Sorcs1 predicted the presence of eight N-linked glycans19. As such, alternative post-translational glycosylation in mutSorcs1 was investigated as the cause of the 90 kDa product. INS1 cells expressing wtSorcs1 and mutSorcs1 were subjected to glycan cleavage by either Endoglycosidase H (Endo H) – which specifically cleaves high-mannose N-linked glycans, or Peptide-N-Glycosidase F (PNGase F) – which cleaves almost all N-linked glycans. Each deglycosylation reaction demonstrated distinct mobility shifts for pro-Sorcs1 and mature Sorcs1 bands in both wtSorcs1 and mutSorcs1 lysates. As expected, pro-Sorcs1 (red arrows) – but not processed mature Sorcs1 (black arrows) – shifted to a lower molecular weight when exposed to Endo H, consistent with its localisation within the ER as a uncleaved pro-peptide (Fig. 3A). PNGase F decreased the mass of pro-Sorcs1, and also mature Sorcs1, corresponding with the increasingly de-glycosylated Sorcs1 protein (Fig. 3B). Of significant interest is that the band shifts apparent in both the pro-Sorcs1 protein and 90 kDa mutSorcs1 product were identical in both Endo H treatment and PNGase F treatment (red and blue arrows, Fig. 3C), indicating the presence of only high-mannose N-linked glycans in these proteins – and a lack of Endo H resistance. This data suggests that, like pro-Sorcs1, the 90 kDa mutSorcs1 protein is ER localised.
To investigate this further we performed subcellular fractionation analysis of INS-1 cells expressing either the wtSorcs1 or mutSorcs1 allele to identify potential changes in subcellular localisation (Fig. 3D). Total densities of wtSorcs1 and mutSorcs1 bands co-fractionated almost identically (Fig. 3E), however, comparison of the two mutSorcs1 bands identified subtle differences in subcellular localisation between the 130 kDa wtSorcs1-corresponding band and the 90 kDa band, with peak densities of the latter appearing in heavier sucrose fractions (Fig. 3F).
To further investigate Sorcs1 subcellular distribution, immunofluorescent staining of myc and insulin was performed in both myc-tagged wtSorcs1 and mutSorcs1 expressing INS1 cells. Myc was initially co-stained with Sorcs1 to confirm significant co-localisation, with both appearing in reticular structures in the cell periphery (Supplementary Fig. 3A). Insulin co-staining with myc demonstrated no obvious co-localisation between Sorcs1 and insulin granules, in either wtSorcs1 or mutSorcs1 (Supplementary Fig. 3B), though insulin granules appeared characteristically punctate in the cell periphery, with increased intensity in perinuclear regions likely corresponding to pro-insulin (or immature insulin granules) in the TGN. As we previously reported14, myc/Sorcs1 demonstrated co-localisation with the TGN marker TGN38, notably here in both wtSorcs1 and mutSorcs1 INS1 cells (Fig. 4A), however only mutSorcs1 INS1 cells displayed consistent partial co-localisation with the ER markers ERp72 or Calnexin (Fig. 4B,C). Quantification by Pearsons correlation coefficient demonstrated significantly increased co-localisation of ER markers in mutSorcs1-expressing cells than wtSorcs1-expressing cells, but no difference in TGN38 co-localisation (Fig. 4D, p < 0.01).
MutSorcs1 90 kDa exhibits a different half life to the wildtype protein
As these data lend evidence to the presence of a differentially modified, ER-localised mutant Sorcs1 product, we treated wtSorcs1 and mutSorcs1-expressing INS1 cells with cyclohexamide to investigate protein degradation. We found that mutSorcs1-expressing cells demonstrated increased retention of the mutant 90 kDa protein 2 hours post-treatment compared to the 130 kDa protein product (p < 0.01, Fig. 5A,B), further validating an alternate processing pathway for the mutant form protein associated with the Thr52Ile single nucleotide polymophism in Sorcs1.
Discussion
Natural genetic variations can offer better mechanistic insights into complex biological processes that are more informative than investigations using complete gene deletion. This is because a mutation in a gene can either be a loss or gain-of-function mutation. The objective of this study was to elucidate the functional consequence of the Thr52Ile single nucleotide polymorphism in the pro-domain of the Sorcs1 gene that has been associated with type 2 diabetes. Expression of the mutant allele of Sorcs1 in INS1 cells clearly demonstrated alternative processing of the Sorcs1 protein compared to wildtype Sorcs1 when visualised by SDS-PAGE. The significantly lower molecular mass of the mutant protein was striking. The formation of an additional protein band of 90 kDa initially suggested that an additional cleavage of mutSorcs1 by a protease such as furin, however pro-protein convertase inhibition resulted in no change in the size of the alternative band. Furthermore, an upward band shift of the mature 130 kDa band indicated that there was normally efficient processing of the mature Sorcs1 protein from the pro-form in both mutSorcs1 and wtSorcs1 - expressing INS1 cells.
It appears that the 90 kDa product of mutSorcs1 protein is misfolded, though we have been unable to definitively confirm this in our current study. Despite at least 10 cysteine sites at which intramolecular disulphide bonds were predicted to occur, irreversible blocking of cysteine oxidation eliminated a role for disulphide bonds as a source for alternatively folded mutSorcs1 protein products. The retention of the pro-domain as identified by LC-MS/MS, and high-mannose glycosylation profile indicates that this 90 kDa product of mutSorcs1 protein does not completely access the TGN – in which furin-mediated pro-domain cleavage, and hybrid or complex glycosylation occurs. Subcellular fractionation of INS1 further supports the notion that the additional mutSorcs1 protein band localises differently to the 130 kDa wtSorcs1 protein band and therefore undergoes differential processing through subcellular compartments. Immunofluorescent staining also demonstrated ERp72, calnexin and myc co-staining primarily in mutSorcs1 INS1 cells and not in wtSorcs1 INS1 cells, with TGN38 co-localisation in both cell lines. Finally, the 90 kDa mutSorcs1 protein exhibits an increased half life compared to the 130 kDa protein, providing further evidence for its mis-localisation and abnormal trafficking within the cell.
From a functional perspective, earlier work with congenic mouse strains, we found that mutSorcs1 allele in the BTBR mouse background showed impaired insulin secretion in response to an intraperitonial glucose challenge as well as a 30% reduction in fasting plasma insulin relative to the BTBR mouse10. We hypothesize that one explanation for this observation is that insertion of mutSorcs1 into the BTBR mouse strain background favors the formation of the misfolded Sorcs1 protein to a greater extent than we observed in the INS1 β-cell line.
Our data suggests that the alternatively processed or misfolded mutSorcs1 products accumulate in the ER and reduce the expression of mature 130 kDa Sorcs1 protein which is a major determinant of insulin content. This reduction in mature 130 kDa Sorcs1, reduces normal β-cell function. The increased insulin secretion at 2.8 mM glucose observed in mutSorcs1 INS1 cells is also reminiscent of the elevated basal (pro)insulin secretion characteristic of Type 2 Diabetes, and indicative of dysregulated proximal insulin processing. Though these data are incongruent with the reduced plasma insulin levels seen in B6 Sorcs1 allele-expressing mice10, it is likely that the elimination of whole-body Sorcs1 is incomparable with the more subtle phenotype of a single nucleotide polymorphism. Pro-peptide cleavage in the TGN of VPS10 proteins is required for exposure of ligand-binding regions in both Sortilin20 and SorLA, and these pro-peptides are then capable of binding to its own mature protein18. This is hypothesised to be a form of self-regulation by either assisting with protein-folding or to inhibit premature ligand binding18. While Sorcs1 pro-peptide has low affinity for mature Sorcs1, it instead is capable of binding mature Sortilin15. Sorcs1 has thereby been implicated in post-Golgi cargo trafficking, primarily through its inhibition of Sortilin-regulated ligand uptake and transcription factor interaction by competitive binding of mature Sortilin protein15. As such, it stands to reason that a 50% reduction of the mature 130 kDa Sorcs1 protein may in turn result in an increase of Sortilin function. This is further evidenced in INS1 cells overexpressing Sortilin, which exhibit decreased total insulin content (unpublished observations), implicating a role for Sortilin in the downregulation of insulin within the β-cell, potentially through its role in lysosomal trafficking21,22. However, although Sortilin is a known receptor for soluble ligands such as amyloid precursor protein23, neurotensin24, PCSK925, as well as being involved in retrograde trafficking of GLUT426, it is not yet known whether sortilin is also capable of regulating proinsulin trafficking.
Polymorphisms affecting Sorcs1 function have previously been reported7,12,27. Similarly, pro-domain missense mutations are not uncommonly associated with disease28,29. We have demonstrated that the Thr52Ile mutant Sorcs1 product is subject to impaired processing in the β-cell. Sorcs1 trafficking and function in particular, appears highly regulated by its pro-domain. We speculate that aberrant function of β-cells associated with Thr52Ile mutation in the Sorcs1 gene is driven by the stoichiometric loss of wildtype Sorcs1 protein in favour of the mutant form of the protein. This, in turn, may imbalance the trafficking network associated with normal insulin content and secretory function.
Data availability
The datasets generated during and/or analysed during the current study are available from the corresponding author on reasonable request.
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Acknowledgements
The authors acknowledge the facilities, and the scientific and technical assistance of Sydney Microscopy and Microanalysis, University of Sydney and Sydney Mass Spectrometry, Charles Perkins Centre. The work was supported by Diabetes Australia Research Program (Y16G-KEBM). MAK is supported by a Jennie Mackenzie Philanthropic Fellowship, University of Sydney. Y.A. is recipient of the Australian Postgraduate Scholarship. ZB was a recipient of Charles Perkins Centre Summer Scholarship.
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M.A.K. conceived and designed the study. B.Y. and Z.B. performed the majority of the experiments. Y.A. performed deglycosylation experiments. Z.S. performed two of the LC-MS/MS experiments. All authors performed data analysis and statistical analysis for the respective experiments they performed. B.Y. and M.A.K. wrote the paper. All authors reviewed and edited the manuscript and approved the final version of the manuscript.
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Yau, B., Blood, Z., An, Y. et al. Type 2 diabetes-associated single nucleotide polymorphism in Sorcs1 gene results in alternative processing of the Sorcs1 protein in INS1 β-cells. Sci Rep 9, 19466 (2019). https://doi.org/10.1038/s41598-019-55873-6
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DOI: https://doi.org/10.1038/s41598-019-55873-6
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