Our animal experiments were conducted with the permission of the Institutional Animal Care and Use Committee of Fudan University. The Guide for the Care and Use of Laboratory Animals published by the Chinese National Institutes of Health were followed during the study. Five-week-old male Sprague-Dawley (SD) rats were provided by the SLRC Laboratory Animal Center (Shanghai, China). Type 1 diabetic rats were induced by a single-dose of intraperitoneally injected streptozotocin (STZ, 65 mg/kg in 0.1 mol/L citrate buffer solution, pH 4.5; Sigma, MO, United States). An equivalent volume of citrate buffer vehicle was administered to the non-diabetic group. Diabetes was defined as blood glucose levels of 16.7 mmol/L 1 week after STZ injection. Random blood glucose and body weight were checked weekly and blood pressure was measured by tail-cuff plethysmography monthly (BP-98A, Softron Beijing Incorporated, Beijing, China). After the onset of diabetes, diabetic rats were allocated into two groups (n = 6 in each group). One group (DM + PKK group) was treated with daily peritoneal injection of PKK (60 U/kg/d; Qianhong Bio-pharma Company, Changzhou, China), and the control group (DM group) was treated with saline (0.1 ml/10 g/d). The dose of PKK used in this study was based on previous study (Liu W. et al., 2016). Non-diabetic control rats (NDM group) received the same saline injection as the DM group (0.1 ml/10 g/d). Rats were housed in a temperature-controlled room, maintained under a 12-h light/12-h dark cycle and were provided free access to regular water and standard laboratory chow. Before sacrifice, rats were anesthetized with intraperitoneal injection of 10% chloral hydrate (0.3 ml/100 g). The adequacy of anesthesia was determined by the loss of a pedal withdrawal reflex (Chen et al., 2013). After being treated for 12 weeks, all animals were sacrificed. Hearts were excised immediately and washed thoroughly with saline to flush the blood. Heart tissues were isolated for further analysis.

Left ventricular samples for electron microscopy were cut into approximately 1 mm³ pieces and fixed in 10% glutaraldehyde overnight. After dehydration and embedding as described previously (Hou et al., 2013), ultrathin sections were cut from blocks and mounted on copper grids. The grids were then counterstained with lead citrate and uranylacetate. The images were recorded under a transmission electron microscope (FEI Tecnai G2 Spirit, Hillsboro, OR, United States).

Left ventricular myocardium were fixed in 4% paraformaldehyde overnight. Tissues were embedded in paraffin, stained with hematoxylin and eosin (H&E), PAS, or Masson reagent as described previously, and examined using an optical microscope (x400, Olympus, Richmond Hill, ON, Canada). Myocyte area was determined perpendicularly to the outer contour of the cell membrane at the nucleus level. The cross-sectional area of single myocytes was measured using ImageJ software. The outline of 100–200 cardiomyocytes was traced in each group. Average myocyte area of each sections was calculated. For the quantification of PAS and Masson staining, at least 10 images were captured for each section. ImageJ was used for the analysis and the results were expressed as the percentage of PAS (or Masson) staining positive area out of the total area of the cross-section.

Heart tissues were fixed with 4% paraformaldehyde overnight and then embedded in paraffin. Expressions of nitrotyrosine, TNF-α, TGF-β1, and collagen I were examined on the tissue section using immunohistochemical (IHC) analyses as described previously (Tian et al., 2009). The dilution concentration of nitrotyrosine antibody (Millipore, Burlington, MA, United States), tumor necrosis factor α (TNF-α) antibody (Abcam, Cambs, United Kingdom), transforming growth factor β1 (TGF-β1) antibody (Abcam, Cambs, United Kingdom), collagen I antibody (Abcam, Cambs, United Kingdom), and CD31 (Abcam, Cambs, United Kingdom) was 1:100, 1:50, 1:200, and 1:300, 1:500, respectively. For IHC analysis, each section was captured in at least 10 pictures and all pictures were quantified. The protein expression intensity was assessed by estimating the area of the objects and the medium pixel intensity per object, as the integrated optical density (IOD). IOD to area ratio was used to present the results. All images were acquired and processed in TIFF format, analysis was done using Image Pro Plus 6.0 software (Media Cybernetics, Rockville, MD, United States). Capillary density was assessed by capillaries/myocyte nucleus (C/M) values. C/M values were counted in 5 fields randomly selected from each slice.

RNA was extracted from the heart tissue using Trizol reagent (Life Technologies, Waltham, MA, United States). RNA concentration was determined in a spectrophotometer (Nanodrop 2000c, Thermo Scientific, Waltham, MA, United States) at the absorbance of 260 nm. Then, 2 μg of total RNA was converted to cDNA according to the manufacturer’s protocol (G490, Abm, Canada). Target cDNA was analyzed for the expression of genes with the ABI 7500 Sequence Detection System (Applied Bio-systems, Waltham, MA, United States) using the following conditions: 94°C, 5 min; 94°C, 30 s, 55°C, 30 s, 72°C, 1 min 30 s, 40 cycles; 72°C, 10 min. The levels of target gene expression were quantified using a complementary DNA standard curve and data were normalized to β-actin or GAPDH. The results were expressed as fold change. The primers used are shown in Table 1 and Supplementary Table 1. Each sample was repeated for three times.

The heart tissues were homogenized in an ice-cold lysis buffer. These protein samples (30 μg) were resolved using SDS-polyacrylamide gel (10%) electrophoresis and transferred to PVDF membranes (Millipore, Burlington, MA, United States). The membranes were blocked with 5% non-fat milk for 1 h at room temperature and incubated with rabbit anti-collagen I polyclonal antibody (1:5000, Abcam, Cambridge, MA, United States), rabbit anti-TGF-β1 polyclonal antibody (1:2000, Abcam), rabbit anti-IκB-α monoclonal antibody (1:2000, Abcam), rabbit anti-GAPDH antibody (1:5000, Abcam), mouse anti-sarcoplasmic reticulum Ca²⁺-ATPase 2 (SRECA2) monoclonal antibody (1:500, Santa Cruz Biotechnology, Dallas, TX, United States), mouse anti-phospholamban (PLN) monoclonal antibody (1:500, Santa Cruz Biotechnology), mouse anti-endothelial nitric oxide synthase (eNOS) monoclonal antibody (1:500, Santa Cruz Biotechnology), rabbit anti-bradykinin receptor type I (B1R) monoclonal antibody (1:500, Bioss, Beijing, China), rabbit anti-bradykinin receptor type I (B1R) monoclonal antibody (1:500, Bioss, Beijing, China), or rabbit anti-bradykinin receptor type II (B2R) monoclonal antibody (1:500, Santa Cruz Biotechnology), washed and incubated with goat anti-rabbit peroxidase-coupled secondary antibodies (1:5000, Cell Signaling Technology, Danvers, MA, United States) or goat anti-mouse peroxidase-coupled secondary antibodies (1:5000, Cell Signaling Technology). The blots were visualized with an enhanced chemiluminescence reaction (Perkin Elmer Life Science, Waltham, MA, United States) (Zhang et al., 2010). Each sample was repeated for three times.

Serum triglyceride (TG), total cholesterol (TC), low density lipoprotein cholesterin (HDL-C) and high density lipoprotein cholesterin (LDL-C) was measured with a spectrophotometric method according to the manufacturer’s instructions (A110-1, A111-1, A112-1, A113-1; Nanjing Jiancheng Bioengineering Institute, Nanjing, China).

Myocardial GSH and GSSG were measured with a spectrophotometric method according to the manufacturer’s instructions (703002, Cayman Chemicals, Ann Arbor, MI, United States).

Myocardial nitrate/nitrite concentration was determined using a spectrophotometric method according to the manufacturer’s instructions (780001, Cayman Chemicals, Ann Arbor, MI, United States).

Whole blood was collected into tubes containing EDTA as an anticoagulant and was centrifuged for 15 min at 3000 rpm. Plasma was decanted and preserved as single aliquots and stored in a freezer set to maintain -80 °C. N-terminal protein B-type natriuretic peptide (NT-proBNP) was analyzed according to the manufacturer’s instructions (E08752r, CUSABIO, SH, China).

All data were presented as mean ± SEM from three independent experiments. Statistical analysis was performed with the statistical package SPSS for Mac Ver. 20.0 (SPSS, Inc., Chicago, IL, United States). The significance of the differences in mean values among different groups was evaluated using one-way ANOVA followed by Tukey’s test. P-values less than 0.05 were considered statistically significant. All graphs were constructed using Prism program (GraphPad, La Jolla, CA, United States).

Type 1 diabetic rats from the DM group developed robust, sustained, and equivalent hyperglycemia and lower body weight compared to the NDM group. There was no difference in both systolic and diastolic blood pressures between the NDM group and the DM groups. Additionally, exogenous PKK had no effect on the blood glucose, serum lipids, body weight, and blood pressures in STZ-induced diabetic rats (Table 2).

Compared with the NDM group, the adjacent sarcomere displayed Z line misalignments (Figure 1A, white arrows) and disruptions in the DM group. The myofibrils were irregularly arranged (Figure 1B, white arrows). The mitochondria swelled, and the mitochondrial cristae were irregular. Some cristae were fractured in the myocytes from the left ventricular myocardium in the diabetic rats (Figure 1C, white arrows). However, these pathological changes of cardiac ultrastructure in diabetic rats were prevented by PKK treatment.

As shown in Figure 2A, we measured myocardial oxidative stress using immunohistochemistry staining of nitrotyrosine, which is an indicator of oxidative stress. Compared with the NDM group, the accumulation of nitrotyrosine was increased in the myocardial tissues of diabetic rats, which was reduced by PKK treatment (Figure 2A). The GSH/GSSG ratio represents the cellular capacity of anti-oxidative stress. Compared to the NDM group, the cardiac GSH/GSSG was significantly decreased in the DM group, which was increased by PKK treatment (DM group vs. DM+PKK group, p = 0.0561) (Figure 2B). In addition, we also examined the gene expression of Nrf2, SOD, CAT, GR and GPx-1 (Figures 2C–G), which are major anti-oxidan components. All the mRNA expression of these components was decreased in the DM group, which was ameliorated following PKK treatment.

In Figure 3A, the DM group displayed the myocardial accumulation of interstitial collagen (white arrows), whereas it was seldomly observed in the NDM group and DM+PKK group.

We used H&E, PAS, and masson staining to observe the myocardial pathological changes. We found that in the DM group, the cardiomyocyte showed hypertrophy compared to the NDM group, which was improved following PKK treatment (Figures 3B,E). Masson (Figures 3C,F) and PAS (Figures 3D,G) staining detected more collagen and glycogen, respectively, in the myocardial interstitium of the DM group, compared to both NDM and DM+PKK groups (Figures 3C,D,F,G). Black arrows represent the accumulated collagen and glucogen, respectively.

Furthermore, both the mRNA (Figures 4A,C) and protein levels (Figures 4B,D–F) of TGF-β1 as well as collagen I were increased in the diabetic hearts, which were significantly reversed in the DM + PKK group.

As inflammation was involved in the development of DCM (Liao et al., 2017; Wang et al., 2018), we evaluated the expression of tumor necrosis factor (TNF-α) using IHC staining (Figure 5A). The protein levels of TNF-α in the diabetic hearts was increased compared with the NDM group, whereas it was ameliorated in the DM+PKK group. We also detected the mRNA expression of inflammatory markers, including clusters of differentiation 68 (CD68), monocyte chemo-attractant protein 1 (MCP-1), TNF-α, and interleukin-6 (IL-6) (Figures 5B–E). Expression of these proinflammatory markers was upregulated in the diabetic heart, with a similar trend evident for TNF-α protein, while PKK administration reversed that significantly. Activation of the NF-κ B pathway plays an important role in the induction of myocardial inflammation (Liu X. et al., 2016). We assessed IκB-α, a major inhibitor of NF-κB (Karin and Ben-Neriah, 2000). IκB-α was decreased in diabetic hearts, while was increased by PKK treatment (Figure 5F).

Sarcoplasmic reticulum Ca²⁺-ATPase 2a (SERCA2a) is directly linked to pump cytosolic Ca²⁺ from the cardiomyocyte back into the sarcoplasmic reticulum (SR) during relaxation of the heart and improving cardiac function during heart failure (Kho et al., 2011; Wahlquist et al., 2014). In the DM group, the protein expression of SERCA2a was decreased compared with the NDM group, whereas it was increased after PKK treatment (Figure 6A). Phospholamban (PLN) is an inhibitor of myocardial SERCA2a, and dephosphorylated PLN interacts with SERCA2a and inhibits cardiac pumping activity (Haghighi et al., 2014). Compared to non-diabetic rats, the dephosphorylated PLN protein level was upregulated in DM rats, whereas PKK treatment down-regulated the dephosphorylated PLN in the heart of diabetic rats (Figure 6B). Therefore, PKK treatment increased the SERCA2a/PLN ratio (Figure 6C), suggesting improved cardiac relaxation and diastolic function by PKK treatment. Brain natriuretic peptide (BNP) is released from the ventricular cardiomyocytes in response to pressure and volume overload. N-terminal protein B-type natriuretic peptide (NT-proBNP) is a metabolite from BNP, which is a reliable biomarker well correlated with echocardiographic indices (Omland et al., 1996; Dong et al., 2006; Ceyhan et al., 2008; Palazzuoli et al., 2010), such as left ventricular ejection fraction (LVEF) and left ventricular end diastolic pressure (LVEDP). Therefore, we measured the plasma NT-proBNP level to evaluate the heart function. The concentrations of plasma NT-proBNP in the NDM, DM, and DM + PKK groups were 74.70 ± 8.596 pg/mL, 139.9 ± 23.64 pg/mL, and 86.40 ± 8.103 pg/mL, respectively (NDM group vs. DM group, p = 0.0116; DM vs. DM + PKK group, p = 0.0429). PKK decreased the plasma NT-proBNP in diabetic rats (Figure 6D), indicating that exogenous PKK could improve the heart function in STZ-induced diabetic rats.

The eNOS/NO pathway is of importance in the progression of DCM and myocardial ischemia/reperfusion injury in diabetes (Paz et al., 2003). The endothelial dysfunction has been shown to be involved in diabetic microangiopathy and cardiomyopathy (Joshi et al., 2014). To determine whether the protective effects of PKK was mediated by this pathway, we measured the expression of eNOS and nitrite (NO^2-)/nitrate (NO^3-) in the heart homogenates. We found reduced eNOS (Figure 7A) and myocardial nitrite/nitrate (Figure 7B) in diabetic heart, suggesting reduction of NO production and the existence of microcirculation disturbance. PKK supplementation increased the protein expression of eNOS and myocardial nitrite/nitrate concentration in diabetic rats, which suggested that the beneficial effects of PKK on heart might be mediated by improving NO production and microcirculation.

To detect the diabetic microangiopathy and determine whether PKK reduces microangiopathy in the heart, we also measured CD31, a marker of capillary density, with immunohistochemistry. CD31 expression was decreased in diabetic hearts (NDM vs. DM: 1.711 ± 0.1021 vs. 1.083 ± 0.0359, P < 0.05), while was increased in DM + PKK group (DM vs. DM + PKK: 1.083 ± 0.03592 vs. 1.510 ± 0.0722, P < 0.05, Figure 7C). Therefore, PKK treatment might reduce the microangiopathy in DCM.

To examine the expression of the components of KKS, including kallikrein1, B1R and B2R, we performed RT-PCR. Compared with NDM group, kallikrein 1 was decreased in DCM while was significantly increased in DM + PKK group (Supplementary Figure 1A). Compared to NDM group, the expression of B1R mRNA was increased in DM group, while the expression of B2R mRNA was unchanged. There were no changes for both B1R and B2R mRNA and protein in DM + PKK group, compared to DM group (Supplementary Figures 1B–F).