Dipeptidyl Peptidase-4 at the Interface Between Inflammation and Metabolism

Introduction

Dipeptidyl peptidase-4 (DPP4) is a protease with a well-characterized role in regulating the bioactivity of gastrointestinal-derived peptide hormones, leading to significant implications for endocrine pathways.^1,2 Inhibition of DPP4-mediated degradation of gut hormones potentiates islet hormone secretion and enhances postprandial metabolism to successfully treat hyperglycemia in patients with type 2 diabetes (T2D). ³ Dipeptidyl peptidase-4 has also cleaves and inactivates several chemokines and cytokines with a significant impact on inflammation and immune function. ⁴ Dipeptidyl peptidase-4 can also directly cleave the extracellular matrix and influence cell migration.^5,6

Interestingly, both activation of intracellular signaling cascades regulating immune cell activation and its interaction within a complex to influence extracellular matrix proteolysis can occur independently of catalytic activity.^5,7 Therefore, dissection of the actions mediated by the catalytic activity and posttranslational regulation of its host of substrates versus those mediated by cleavage-independent or direct protein interactions with cell surface receptors, extracellular matrix, and cell signaling cascades is currently important given its emerging role as a biomarker of metabolic disease. ⁸ Recent research has placed these distinct functions at a direct intersection, where regulation of inflammation may influence the progression of dysglycemia, insulin resistance, obesity, and nonalcoholic fatty liver disease (NAFLD) (Figure 1). Here, we discuss and contrast the potential substrates identified with those experimental observations which appear to be independent of catalytic activity and highlight relevance for human disease.

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Figure 1.

Schematic illustrating the metabolic consequences and cellular specificity of dipeptidyl peptidase-4 regarding glucose tolerance and inflammation and the evidence indicated to date on substrate cleavage and regulation vs noncatalytic/direct protein-protein interactions as the mechanisms underlying these effects. ADA indicates adenosine deaminase; G-CSF, granulocyte colony-stimulating factor; GIP, glucose-dependent insulinotropic polypeptide; GLP-1, glucagon-like peptide 1; GM-CSF, granulocyte macrophage colony-stimulating factor; IGF-1, insulin growth factor; MDC, macrophage-derived cytokine; MIP-1, macrophage inflammatory protein 1; PYY, peptide tyrosine tyrosine; SDF-1, stromal-derived factor 1.

DPP4 Structure and Catalytic Activity

Dipeptidyl peptidase-4 is a type II cell surface exopeptidase with a classic serine triad defining the C-terminal catalytic active site and a single hydrophobic sequence anchoring the mostly extracellular protein (only 6 amino acids extend into the cytoplasm in the membrane). ⁹ Dipeptidyl peptidase-4 belongs to the prolyl endopeptidase family, a group of atypical serine proteases with an active site consisting of the catalytic residues Ser630, Asp708, and His740, which hydrolyze a prolyl bond in substrate proteins.^2,9-13

Transcriptional Control of DPP4

Dipeptidyl peptidase-4 contains a GC-rich sequence.^14,15 This region contains several consensus binding sites for transcriptional factors, including hepatocyte nuclear factor-1-beta (HNF1B), ¹⁶ cut-like homeobox 1 (CUX1) ¹⁷ glucocorticoid receptor, ⁶ and specificity protein 1 (SP1), ¹⁸ as well as several cytokines, such as interferon-γ and tumor necrosis factor α (TNF-α), which regulate Dpp4 messenger RNA (mRNA) expression in a cell type–specific manner. ¹⁸ Promoter analysis has also identified consensus sites for nuclear factor kappa-light-chain-enhancer of activated B cells (NF-κB) and epidermal growth factor activating protein 1. ¹⁹ In HepG2 cells, incubation with high concentrations of glucose increases the expression of Dpp4 ²⁰ and has been confirmed by luciferase assays.^21,22 Positive correlations have been established with plasma DPP4 activity and fasting plasma glucose ²³ and HbA1c ²⁴ However, this regulation may be more complicated in vivo as patients with improved glycemic control do not consistently experience a reduction in circulating DPP4, ²⁵ and short-term treatment of mice with the glucose-lowering agent Exendin-4 does not reduce circulating DPP4 activity. ²⁶ Incubation of HepG2 cells with insulin, palmitate, oleate, or cholesterol did not result in increased DPP4 mRNA expression. In THP-1 macrophages, dexamethasone treatment significantly induced transcriptional upregulation of DPP4 due to the presence of two glucocorticoid responsive elements within the promoter. ⁶

Posttranscriptional Regulation of DPP4

Dipeptidyl peptidase-4 exerts enzymatic activity in both the membrane-anchored and circulating soluble form,^2,9,12 and it requires heterodimerization or homodimerization for catalytic function. ¹³ As a dimer, DPP4 selectively and preferentially cleaves a dipeptide from the N-terminus with a position 2 proline or alanine and a protonated amino terminus. ¹¹ Dipeptidyl peptidase-4 can be posttranslationally modified, including glycosylation (sialylation) at several sites responsible for targeting DPP4 to the apical membrane. ²⁷ Particularly noteworthy is the N-glycosylation at the Asn 319 site, which when mutated significantly reduces dimerization and catalytic activity. ²⁸ In addition, DPP4 can also be oxidized, which reduces its activity. ²⁹

Dipeptidyl peptidase-4 is present on the membrane of parenchymal cells within metabolic organs, including hepatocytes, enterocytes, islets cell, and within endothelial cells and immune populations.^26,30 The level of expression depends on the cell type, differentiation state, and/or the activation state.^4,31,32 Dipeptidyl peptidase-4 can also be shed from the membrane and circulates throughout many bodily fluids. ³³ Sheddases are a class of membrane-bound enzymes that can cleave transmembrane proteins and have been proposed for the release of DPP4 from the cell membrane into circulation as classic endothelial reticulum/Golgi secretion pathways are not involved. ³⁴ Matrix metalloproteinases (MMP) 1, 2, 14, and 9 and Kallikrein-related peptidase 5 (KLK5) have all been identified to have a role in shedding. ³³ However, the contribution, regulation, and cell-type specificity of these sheddases to the regulation of soluble DPP4 and disease progression are currently unknown.

Direct Protein-Protein Interactions With DPP4

In addition to its well-described peptidase activity, DPP4 also possesses noncatalytic functions through its interaction with ligands, including adenosine deaminase (ADA), caveolin-1, ³⁵ extracellular matrix (collagen and fibronectin), and C-X-C chemokine receptor 4 (CXCR4). ¹⁹ Dipeptidyl peptidase-4 is a co-stimulator for T-cell activation by interaction and activation of ADA. As adenosine is a potent suppressor of T-cell proliferation, inducing its degradation through increased ADA activity induces T-cell proliferation. However, studies using DPP4 with a mutation within the active site rendering it catalytically inactive or a mutant DPP4 unable to bind ADA, demonstrated that DPP4 induces T-cell proliferation through pathways independent of ADA and substrate degradation. ³⁶ Dipeptidyl peptidase-4 has also been proposed to bind directly to CD45 to induce T-cell receptor signaling. ³⁷ However, given that mice with genetic elimination of Dpp4 or treatment with a highly selective DPP4 inhibitor (DPP4i) had comparable and robust primary and secondary antibody responses to T-dependent antigens provides compelling evidence that although DPP4 has a role in mediating T-cell activation, it is not absolutely required for T-cell–directed immune responses. ³⁸ Evidence also exists that DPP4 physically interacts with caveolin-1 on antigen-presenting cells to induce aggregation and phosphorylation, which activates NF-κB. ³⁹ In addition, DPP4 has been demonstrated to activate signaling on endothelial cells through direct interaction with the mannose 6 phosphate/insulin-like growth factor 2 receptor.^40,41

DPP4 Inhibitors in Combination With Metformin

DPP4i are often prescribed together or provided as a dual therapy when metformin is not sufficient to maintain euglycemia.^67-73 Patients who receive dual therapy experience additive glucose-lowering and superior improvements in HbA1c. ⁷⁴ Metformin has been demonstrated to mediate significant metabolic effects through its action within the gastrointestinal tract.^75,76 Preproglucagon (Gcg) is expressed in enteroendocrine L cells, which are dispersed throughout the duodenum but more concentrated toward the distal colon.^77,78 Glucagon-like peptide-1 is processed from the preproglucagon polypeptide by prohormone convertase 1/3 (PC1/3), and its secretion is stimulated by ingested nutrients.^44,79,80

One proposed gut-based mechanism of action for metformin is to stimulate GLP-1 secretion directly from the L cell. ⁸¹ In addition, metformin may also enhance GLP-1R and GIPR expression within the β cell.^82,83 Consistent with increased secretion, nondiabetic, obese patients who received metformin monotherapy experience an increase in active GLP-1, and metformin did not alter the kinetics of GLP-1 degradation by DPP4.^84,85 Metformin is, therefore, an effective partner for additive therapy with a DPP4i. In addition to the superior lowering of HbA1c, dual therapy is a promising course of treatment for reducing adverse cardiovascular events. A recent post hoc subgroup analysis of the three cardiovascular outcome trials for DPP4i suggests that patients treated at baseline with metformin may derive cardiovascular benefit from DPP4i compared with metformin nonusers.^86,87

DPP4 as a Regulator of Immune Cells

Consistent with the promoter analysis, altered expression of DPP4 in autoimmune and infectious diseases, hematological cancers, and tumors has been reviewed in detail elsewhere.^4,7,11,120 There are several significant differences between mice and humans in this regard, as DPP4 expression in the hematopoietic compartment differs between them. In human subjects, DPP4 is expressed predominantly by T cells, whereas in mice, dendritic cells, B cells, and natural killer cells also express significant levels of DPP4. ¹²¹ Lipopolysaccharide treatment of mice increases expression of DPP4 on macrophages 5- to 10-fold, suggesting acute activators of inflammation are associated with significantly increased DPP4 expression in circulating immune cells. ²² Consistent with this, the release of DPP4 is induced by treatment with TNF-α and with insulin. ¹²² The effects of low-grade, often subclinical inflammation observed in patients with metabolic disease offers less clarity in the form of DPP4 expression on immune cell populations. Assessment of 14 controls versus 27 patients with confirmed atherosclerotic plaque identified that DPP4 is elevated on CD11b+ monocytes, and it correlates with plasma TG and cholesterol, but not with glucose or insulin concentrations. ¹²³

Peripheral blood mononuclear cells isolated from patients with T2D demonstrated no difference in DPP4 activity or gene expression. ¹²⁴ It has been reproducibly demonstrated that a significant portion of circulating DPP4 originates from bone marrow–derived cells,^{30,121,125,126} suggesting they are an essential reservoir of soluble DPP4. In patients with severe combined immunodeficiency, as well as studies in irradiated mice, the number of lymphocytes in circulation correlated with levels of circulating DPP4. ¹²¹ Additional evidence suggests DPP4 can derive from osteoclasts and signal through receptor activator of nuclear factor-kappa B ligand (RANKL) under circumstances of bone remodeling. ⁴⁹ RNA-seq data have identified DPP4 as one of the factors produced by adipogenic marrow cells that negatively influence bone healing in response to age and high-fat diet feeding. ¹²⁷ Nine-day treatment with sitagliptin increased the shift toward osteogenic progenitors in the tibia, suggestive of enzymatic activity regulating differentiation. ¹²⁷

DPP4 Expression in Mature Adipocytes and Adipocyte Progenitors

Increased DPP4 expression and activity have been consistently associated with obesity (increased body mass index and excess adipose tissue in humans).^{26,35,96,122,128} In addition, leptin concentrations and the size of adipocytes in both visceral and subcutaneous depots positively associate with DPP4, whereas adiponectin levels negatively correlate with circulating DPP4. ¹²⁸ Given its strong correlation with increased adipose tissue accumulation, the origin of obesity-induced circulating DPP4 was originally proposed to be the mature adipocyte.^122,128,129 Consistent with this idea, the genetic elimination of adipose tissue DPP4 triggers beneficial adipose tissue remodeling and improved hepatic insulin sensitivity in diet-induced obesity. ¹³⁰ In addition, in 1-year-old obese mice fed a high-fat, high-cholesterol diet (HFHC), it was determined that a small portion of circulating DPP4 originates from adiponectin + cells. ²⁶

Recent single-cell RNA sequencing combined with elegant microscopy evidence suggests that DPP4 expression is limited in adipose tissue to multipotent progenitors, which exist within the reticular interstitium and give rise to intercellular adhesion molecule 1 (ICAM)+ and CD142+ preadipocytes. ¹³¹ Previous studies are consistent with Dpp4 expression on progenitor populations as decreased DPP4 expression is associated with early steps in adipocyte differentiation, including adipocyte maturation. ¹³² However, it is possible that in states of obesity DPP4+, mesenchymal progenitor cells are depleted, which reduces the population of preadipocytes disrupting the required adipose tissue hyperplasia, shifting to maladaptive hypertrophy within visceral depots. ¹³¹ This concept requires further investigation.

DPP4 Within the Adipose Tissue Stromal Vascular Fraction

Dipeptidyl peptidase-4 expression in adipose tissue is much more prevalent in the stromal vascular fraction than in the adipocyte fraction, particularly under conditions of high-fat feeding ²⁶ Increased DPP4 expression in obese humans and ob/ob mice is observed in populations of dendritic cells and macrophages isolated from visceral adipose tissue. ²² However, the increase in circulating DPP4 observed with increased adipose tissue accumulation is entirely unaffected in mice lacking DPP4 in CD45+ immune cell populations, ³⁰ suggesting that the majority of dysregulated circulating DPP4 due to obesity was not originating from CD45+ immune cells.

DPP4 as a Biomarker of Metabolic Liver Disease

The liver has been proposed as a primary source of circulating DPP4. ¹³³ Within the liver, DPP4 is expressed in both hepatocytes and nonparenchymal cells, yet obesity only increases Dpp4 expression in hepatocytes. ¹³⁴ Analysis by Baumeier et al ¹³⁵ calculated by total weight predicted that in mice, the majority of DPP4 protein release came from the liver. Several groups have identified that circulating DPP4 levels are also positively associated with NAFLD.^20,136 In humans, plasma DPP4 expression and activity are increased in patients with NAFLD and have a strong correlation with liver fat content. ¹³⁵ Higher hepatic DPP4 expression and elevated plasma levels are observed in patients with NAFLD compared with healthy subjects. ²⁰ Nonbiased, discovery-based proteome profiling in the plasma from patients with T2D, NAFLD, and cirrhosis demonstrated that DPP4 protein levels significantly correlated with concentrations of liver enzymes used currently as markers of liver damage, including alanine aminotransferase (ALT), aspartate transaminase (AST), alkaline phosphatase, and gamma-glutamyl transferase. ¹³⁷ Indeed, methylation at CpG sites in the Dpp4 southern shore has been reported to regulate the expression of Dpp4 in the liver, ¹³⁸ but not in adipose, ¹³⁵ kidneys, or brain ¹³⁸ of mice, suggesting liver-specific transcriptional regulation in disease states.

DPP4 as a Hepatokine

Consistent with the role of hepatocyte-derived DPP4 in metabolic disease, Ghorpade et al ³⁵ identified DPP4 as a circulating casual factor downstream of hepatic CAMKII signaling, which promoted macrophage chemoattractant protein (Mcp1), interleukin 6 (Il6), Tnfa, and il-1b expression and crown-like structures within visceral, but not inguinal or brown adipose tissue. Varin et al ²⁶ a confirmed these findings in Dpp4 ^Hep−/− mice, which confirmed that the 40% increase in circulating DPP4 under high-fat diet feeding or obesity is hepatocyte-derived. Similarly, in the absence of hepatic Dpp4, reduced levels of F4/80 (Adgre1), Il2, C-C chemokine ligand 2 (Ccl2), and Tnfa were observed in both the livers and gonadal adipose tissue of HFHC-fed Dpp4^Hep−/−mice. ²⁶ In both models, reductions in hepatic DPP4 resulted in improvements in whole-body insulin sensitivity, and the effects could not be replicated by treatment with a DPP4i.^26,35 The HFHC-fed mice treated with the DPP4i MK-0626 demonstrated no changes in cytokine expression in the liver, epididymal fat, or plasma. Also, patients with T2D treated for 4 weeks with the DPP4i sitagliptin failed to demonstrate any significant changes in circulating concentrations of inflammatory cytokines, chemokines, or growth factors. ¹³⁹ Conversely, the gonadal white adipose tissue isolated from mice with a hepatocyte-specific overexpression of Dpp4 (1.6-fold increase in hepatic protein and a 2-fold increase in circulating) demonstrated increased markers of macrophage infiltration (F4/80) and inflammatory cytokines (TNF-α and MCP1) and increased leptin:adiponectin ratios. ¹³⁵ Consistent with a direct effect on insulin sensitivity, insulin treatment of HepG2 hepatoma cells and primary mouse hepatocytes infected with adenovirus to overexpress DPP4 demonstrated a reduction in insulin-stimulated Akt phosphorylation. ¹³⁵ Incubation of adipocytes, skeletal muscle cells, and smooth muscle cells with DPP4 reduced Akt phosphorylation induced by insulin in a dose-responsive manner, suggesting these signaling effects are direct. ¹²²

Hypoxia-inducible factor-1 α (Hif1a) is also elevated in obesity, and hepatocyte-specific elimination of Hif1a, but not Hif2a, decreased the upregulation of hepatic Dpp4 observed with an excess of adipose tissue. ⁹⁶ These data suggest that hypoxia may be an initiating factor for the shedding of DPP4 and are consistent with the model proposed by Chowdhury et al. ¹⁴⁰ Deletion of hepatocyte Hif1a, which prevents obesity-induced increases in hepatic DPP4, demonstrated increased active portal GLP-1 and improved glucose tolerance. ⁹⁶ The lack of upregulation of Dpp4 within the liver in Hif1a^−/− mice was associated with a decrease in phosphorylated p65 NF-κB levels, ⁹⁶ confirming that elimination of the obesity-induced increase in hepatic DPP4 is linked to reduced inflammation. It has been difficult to dissect the temporal relationship between lipid accumulation, inflammation, and insulin resistance, as mice with hepatic overexpression of DPP4 exhibited increased liver TG accumulation and adipose tissue accumulation beginning at 20 weeks and persisting throughout the 30-week study. They also exhibited increases in fatty acid transporter CD36. ¹³⁵ Elimination of Dpp4 from hepatocytes with siRNA from mice with diet-induced obesity or ob/ob mice reduced circulating nonesterified fatty acids (NEFA), effects not replicated with sitagliptin treatment. However, both lipogenesis and oleic acid uptake were similar in both control and DPP4 overexpressing hepatocytes, ¹³⁵ and genetic elimination of Dpp4 specifically from hepatocytes did not lead to any changes in NEFA, TG, or liver lipid accumulation. ²⁶ These data suggest aberrant communication between adipose tissue and the liver can be the main driver of DPP4’s role in insulin resistance and inflammation. The main cell type identified to respond to liver-derived DPP4 is the adipose tissue macrophage (ATM). In vitro studies have also identified protease-activated receptor 2 (PAR2) as a potential target of soluble DPP4 action in smooth muscle cells ¹⁴¹ and in cultured human coronary artery endothelial cells. ¹²⁹ Ghorpade et al ³⁵ demonstrated that both PAR2 and caveolin-1 signaling were instrumental in stimulating inflammation in ATM by using an intraperitoneal injection of siRNA encapsulated in micrometer-sized glucan shells to specifically target signaling in ATMs. In addition, they propose that activated factor X may signal synergistically with DPP4 and activate extracellular signal-regulated kinase (ERK1/2) and NF-κB to increase downstream expression mediators of inflammation, including MCP-1, IL-6, and TNF-α. ³⁵ Indeed, disrupting protein-protein interactions with DPP4, but not DPP4 inhibitor treatment, reduced adipose tissue inflammation, ²² consistent with a noncatalytic mechanism of action.

DPP4 Inhibitors and Metabolic Liver Disease

Both diet-induced obese mice and ob/ob mice treated with the DPP4i linagliptin improved glycemic parameters and reduced the liver fat content and markers of inflammation, suggesting potentiation of DPP4 substrates may have short-term benefit on liver metabolism. ¹⁴² More recently, Kawakubo et al ¹⁴³ treated a genetically obese melanocortin 4 receptor-deficient mouse (model of insulin resistance, hepatic steatosis, nonalcohol steatosis hepatitis [NASH], and hepatocellular carcinoma) with a DPP4i which prevented the progression of simple steatosis to NASH, and decreased hepatic crown-like structures and expression of inflammatory and fibrosis-related genes. Also, in randomized control trials with patients treated with sitagliptin (100 mg) for 1 year, biopsy demonstrated reduced steatosis and ballooning. ¹⁴⁴ In addition, in further studies, sitagliptin (100 mg) decreased ALT and AST and improved histological scoring. ¹⁴⁵ However, adding to the complexity of interpretation, randomized controlled trials of patients with liver disease where patients treated with alogliptin (25 mg/day for 12 months), ¹⁴⁶ vildagliptin (50 mg, twice a day for 6 months), ¹⁴⁶ or sitagliptin (100 mg for 12 months) ¹⁴⁷ reports confirm failure to provide any clear benefit.

DPP4 and Fibrosis

Shigeta et al discovered that the activity of the membrane-bound form of DPP4 is elevated in a diabetic rat model, but reduced in their normoglycemic counterparts. As a result, circulating stromal-derived factor 1 (SDF-1), angiogenesis, and the number of CXC chemokine receptor–positive/vascular endothelial growth factor receptor–positive (CXCR+KDR+) endothelial progenitor cells were decreased, while there was an increase in fibrosis. The opposite was observed in Dpp4^−/− and normoglycemic control rats. ¹⁴⁸ CXCL12 signaling has been proposed to promote liver fibrosis by recruiting immune cell populations and has also been linked to the development of hepatocellular carcinoma, ¹⁴⁹ although it is unclear to date whether DPP4i can potentiate this process. Dipeptidyl peptidase-4 has been demonstrated to define fibroblast populations within human skin biopsies, ¹⁵⁰ and DPP4+ fibroblasts have been shown to express higher levels of myofibroblast markers and collagen, ¹⁵¹ but whether these pathways are relevant in liver disease remains to be determined. Treatment of mice predisposed to fibrosis by treatment with bleomycin or chronic graft versus host disease with DPP4i has resulted in reduced fibrosis and inflammation, and DPP4i have also been found to promote the migration of keratinocytes, and reduce collagen synthesis and deposition, limiting scar formation. ¹⁵²

Future Directions

The substantial body of preclinical evidence in genetic mouse models linking cell-specific actions of DPP4 with insulin resistance, obesity, and NAFLD requires further confirmation and mechanistic studies in patient populations and human model systems to confirm its role as a biomarker or causal agent in disease progression. The novel discovery of the fate of several DPP4+ progenitor cell populations illustrates additional metabolic pathways that may also contribute to the regulation of glucose, insulin sensitivity, and metabolic disease. These observations solidify the need for further elucidation of how DPP4 regulates these pathways—through catalytic activity and cleavage of substrate peptides or direct protein-protein interactions.