VEGF receptor binding peptide‐linked high mobility box group‐1 box A as a targeting gene carrier for hypoxic endothelial cells

High mobility group box‐1 (HMGB‐1) is a nuclear protein that can bind to and condense plasmid DNA. In this study, we developed a recombinant VEGF receptor binding peptide (VRBP) linked to HMGB‐1 box A (VRBP‐HMGB1A) as a targeting gene carrier to hypoxic endothelial cells. Hypoxic endothelial cells in ischemic tissues of solid tumors are important targets for gene therapy. A recombinant VRBP‐HMGB1A expression vector, pET21a‐VRBP‐HMGB1A was constructed. VRBP‐HMGB1A was over‐expressed in BL21 strain and purified by nickel‐chelate affinity chromatography. Complex formation between VRBP‐HMGB1A and pCMV‐Luc was confirmed by gel retardation assay. pCMV‐Luc was retarded completely at a 2/1 weight ratio (peptide/plasmid). For transfection assays, calf pulmonary artery endothelial (CPAE) cells were incubated under hypoxia for 24 h, prior to transfection to induce the VEGF receptors on the cells. VRBP‐HMGB1A/pCMV‐Luc complexes were transfected to hypoxic CPAE cells. The highest transfection efficiency was at a 30/1 weight ratio (peptide/plasmid). In addition, VRBP‐HMGB1A had higher efficiency than poly‐L ‐lysine (PLL) specifically in hypoxic CPAE cells, However, VRBP‐HMGB1A had lower efficiency than PLL in 293, H9C2, and normoxic CPAE cells. In MTT assay, VRBP‐HMGB1A was less toxic than PLL to cells. In conclusion, VRBP‐HMGB1A is a potential gene carrier for targeting hypoxic endothelial cells and thus, may be useful for cancer gene therapy. J. Cell. Biochem. 110: 1094–1100, 2010. Published 2010 Wiley‐Liss, Inc.     

Dexmedetomidine protects against high mobility group box 1‐induced cellular injury by inhibiting pyroptosis

Dexmedetomidine (DEX) is a widely used clinical anesthetic with proven anti‐inflammatory effects. Both high mobility group box 1 (HMGB1) and pyroptosis play an important role in the inflammatory response to infection and trauma. Thus far, there have been no studies published addressing the effect of DEX on HMGB1 and pyroptosis. In order to fill this gap in the literature, bone marrow‐derived macrophages (BMDMs) were exposed to HMGB1 (4 µg/mL) with or without DEX (50 μM) pretreatment. The production of pro‐inflammatory cytokines [such as tumor necrosis factor α (TNF‐α), interleukin 1β (IL‐1β), and IL‐18], phosphorylation of extracellular signal‐regulated protein kinases 1 and 2 (ERK1/2) and P38, and the activation of caspase‐1 were measured by enzyme immunosorbent assay, western blot analysis, confocal microscope, and flow cytometry, respectively. We found that DEX protected against HMGB1‐induced cell death of BMDMs. In addition, DEX suppressed the generation of TNF‐α, IL‐1β, and IL‐18 as well as the phosphorylation of ERK1/2 and P38. Moreover, DEX inhibited caspase‐1 activation and decreased pyroptosis. Taken together, these findings demonstrate the protective effect of DEX in mediating HMGB1‐induced cellular injury, thus indicating that DEX may be a potential therapeutic candidate for the management of infection and trauma‐derived inflammation.     

Extracellular high‐mobility group box 1 mediates pressure overload‐induced cardiac hypertrophy and heart failure

Inflammation plays a key role in pressure overload‐induced cardiac hypertrophy and heart failure, but the mechanisms have not been fully elucidated. High‐mobility group box 1 (HMGB1), which is increased in myocardium under pressure overload, may be involved in pressure overload‐induced cardiac injury. The objectives of this study are to determine the role of HMGB1 in cardiac hypertrophy and cardiac dysfunction under pressure overload. Pressure overload was imposed on the heart of male wild‐type mice by transverse aortic constriction (TAC), while recombinant HMGB1, HMGB1 box A (a competitive antagonist of HMGB1) or PBS was injected into the LV wall. Moreover, cardiac myocytes were cultured and given sustained mechanical stress. Transthoracic echocardiography was performed after the operation and sections for histological analyses were generated from paraffin‐embedded hearts. Relevant proteins and genes were detected. Cardiac HMGB1 expression was increased after TAC, which was accompanied by its translocation from nucleus to both cytoplasm and intercellular space. Exogenous HMGB1 aggravated TAC‐induced cardiac hypertrophy and cardiac dysfunction, as demonstrated by echocardiographic analyses, histological analyses and foetal cardiac genes detection. Nevertheless, the aforementioned pathological change induced by TAC could partially be reversed by HMGB1 inhibition. Consistent with the in vivo observations, mechanical stress evoked the release and synthesis of HMGB1 in cultured cardiac myocytes. This study indicates that the activated and up‐regulated HMGB1 in myocardium, which might partially be derived from cardiac myocytes under pressure overload, may be of crucial importance in pressure overload‐induced cardiac hypertrophy and cardiac dysfunction.     

Role of high mobility group box 1 and its signaling pathways in renal diseases

Abstract

The high mobility group box 1 (HMGB1) protein, a member of the high mobility group nuclear protein family and an endogenous ligand for TLR2/4 and RAGE (receptor for advanced glycation end products), is one of the most evolutionarily conserved proteins and it has recently emerged as an extracellular signaling factor with key roles in cell differentiation, proliferation and disease pathogenesis. The present data indicate that HMGB1 is one of most important proinflammatory cytokines, and plays an important role in renal diseases. The literatures were searched extensively and this review was performed to sum up the role of HMGB1 in renal diseases.     

Redox status of high‐mobility group box 1 performs a dual role in angiogenesis of colorectal carcinoma

During inflammation, high‐mobility group box 1 in reduced all‐thiol form (at‐HMGB1) takes charge of chemoattractant activity, whereas only disulfide‐HMGB1 (ds‐HMGB1) has cytokine activity. Also as pro‐angiogenic inducer, the role of HMGB1 in different redox states has never been defined in tumour angiogenesis. To verify which redox states of HMGB1 induces angiogenesis in colorectal carcinoma. To measure the expression of VEGF‐A and angiogenic properties of the endothelial cells (ECs), at‐HMGB1 or ds‐HMGB1 was added to cell medium, further with their special inhibitors (DPH1.1 mAb and 2G7 mAb) and antibodies of corresponding receptors (RAGE Ab and TLR4 Ab). Also, a co‐culture system and conditioned medium from tumour cells were applied to mimic tumour microenvironment. HMGB1 triggered VEGF‐A secretion mainly through its disulfide form interacting with TLR4, while co‐operation of at‐HMGB1 and RAGE mediated migratory capacity of ECs. Functional inhibition of HMGB1 and its receptors abrogated HMGB1‐induced angiogenic properties of ECs co‐cultured with tumour cells. HMGB1 orchestrates the key events of tumour angiogenesis, migration of ECs and their induction to secrete VEGF‐A, by adopting distinct redox states.     

A high mobility group B‐1 box A peptide combined with an artery wall binding peptide targets delivery of nucleic acids to smooth muscle cells

The TAT‐high mobility group box‐1 A box peptide (TAT‐HMGB1A) has been reported previously to be able to deliver DNA into cells without cytotoxicity. In this study, an artery wall smooth muscle cell‐targeting carrier was developed using TAT‐HMGB1A combined with an artery wall binding peptide (ABP). For the production of ABP linked TAT‐HMGB1A (TAT‐HMGB1A‐ABP), pET15b‐TAT‐HMGB1A‐ABP was constructed by inserting the ABP cDNA into pET15b‐TAT‐HMGB1A. TAT‐HMGB1A‐ABP was expressed in E. coli and purified by Nickel chelate chromatography. Gel retardation assays showed that TAT‐HMGB1A‐ABP formed a complex with the plasmid at or above a 5:1 weight ratio (peptide:plasmid). At a 20:1 weight ratio, the zeta‐potential was ～25 mV and the particle size was ～120 nm. TAT‐HMGB1A‐ABP had the highest transfection efficiency in A7R5 smooth muscle cells at a weight ratio of 20:1. TAT‐HMGB1A‐ABP exhibited higher transfection efficiency in A7R5 cells than PLL or TAT‐HMGB1A, while TAT‐HMGB1A‐ABP had lower transfection efficiencies in Hep3B hepatoma, 293 kidney, NIH3T3 fibroblast, and Raw264.7 macrophage cells compared with PLL. Together, these results suggest that the ABP moiety of the peptide increased transfection efficiency specifically in smooth muscle cells. In a competition assay, the transfection efficiency of TAT‐HMGB1A‐ABP in A7R5 cells was reduced by the addition of free ABP. MTT assays showed that TAT‐HMGB1A‐ABP did not produce any cytotoxicity in A7R5 cells. Therefore, TAT‐HMGB1A‐ABP may be useful for a targeting gene delivery to smooth muscle cells. J. Cell. Biochem. 107: 163–170, 2009. © 2009 Wiley‐Liss, Inc.     

Hypoxia‐induced endothelial secretion of macrophage migration inhibitory factor and role in endothelial progenitor cell recruitment

Macrophage migration inhibitory factor (MIF) is a pleiotropic inflammatory cytokine that was recently identified as a non‐cognate ligand of the CXC‐family chemokine receptors 2 and 4 (CXCR2 and CXCR4). MIF is expressed and secreted from endothelial cells (ECs) following atherogenic stimulation, exhibits chemokine‐like properties and promotes the recruitment of leucocytes to atherogenic endothelium. CXCR4 expressed on endothelial progenitor cells (EPCs) and EC‐derived CXCL12, the cognate ligand of CXCR4, have been demonstrated to be critical when EPCs are recruited to ischemic tissues. Here we studied whether hypoxic stimulation triggers MIF secretion from ECs and whether the MIF/CXCR4 axis contributes to EPC recruitment. Exposure of human umbilical vein endothelial cells (HUVECs) and human aortic endothelial cells (HAoECs) to 1% hypoxia led to the specific release of substantial amounts of MIF. Hypoxia‐induced MIF release followed a biphasic behaviour. MIF secretion in the first phase peaked at 60 min. and was inhibited by glyburide, indicating that this MIF pool was secreted by a non‐classical mechanism and originated from pre‐formed MIF stores. Early hypoxia‐triggered MIF secretion was not inhibited by cycloheximide and echinomycin, inhibitors of general and hypoxia‐inducible factor (HIF)‐1α‐induced protein synthesis, respectively. A second phase of MIF secretion peaked around 8 hrs and was likely due to HIF‐1α‐induced de novo synthesis of MIF. To functionally investigate the role of hypoxia‐inducible secreted MIF on the recruitment of EPCs, we subjected human AcLDL⁺ KDR⁺ CD31⁺ EPCs to a chemotactic MIF gradient. MIF potently promoted EPC chemotaxis in a dose‐dependent bell‐shaped manner (peak: 10 ng/ml MIF). Importantly, EPC migration was induced by supernatants of hypoxia‐conditioned HUVECs, an effect that was completely abrogated by anti‐MIF‐ or anti‐CXCR4‐antibodies. Thus, hypoxia‐induced MIF secretion from ECs might play an important role in the recruitment and migration of EPCs to hypoxic tissues such as after ischemia‐induced myocardial damage.     

Diagnostic value of serum concentrations of high‐mobility group‐box protein 1 and soluble hemoglobin scavenger receptor in brucellosis

Both cluster of differentiation (CD)4⁺ and CD8⁺ T lymphocytes play key roles in immunity to Brucella, in part because they secrete interferon (IFN)‐γ and activate bactericidal functions in macrophages. Therefore, use of markers of macrophage activation may have diagnostic and prognostic significance. High‐mobility group‐box 1 protein (HMGB1), a late‐onset pro‐inflammatory cytokine, is secreted by activated macrophages. Soluble hemoglobin scavenger receptor (sCD163) is a specific marker of anti‐inflammatory macrophages. The aim of this study was to investigate the diagnostic value of HMGB1 and sCD163 concentrations in brucellosis and its various clinical forms. Serum HMGB1 and sCD163 concentrations in 49 brucellosis patients were compared with those in 52 healthy control subjects. Both serum HMGB1 and sCD163 concentrations were significantly higher in brucellosis patients than in healthy controls (P < 0.001). There were no statistically significant differences in serum concentrations of HMGB1 and sCD163 between cases of acute, subacute and chronic brucellosis. Additionally, serum HMGB1 concentrations were positively correlated with sCD163 concentrations, whereas neither HMGB1 nor sCD163 concentrations were correlated with C‐reactive protein concentrations, white cell counts or erythrocyte sedimentation rates. Therefore, serum concentrations of HMGB1 and sCD163 may be diagnostic markers for brucellosis, but neither can be used to differentiate the three different forms of this disease (acute, subacute and chronic).     

Potential role of High mobility group box 1 in hepatocellular carcinoma

Hepatocellular carcinoma (HCC) is one of the most common cancers worldwide and is characterized as a typical inflammation-related carcinoma. High mobility group box protein 1 (HMGB1), a non-histone DNA-binding protein, is identified as a potent proinflammatory mediator when presents extracellularly. Recently, a growing body of evidence indicates that HMGB1 plays a potential role in HCC, but many questions remain unanswered about the relationship between HMGB1 and HCC formation and development. This review focuses on the biological effect of HMGB1, and discusses the association of HMGB1 with HCC and potential use of strategies targeting HMGB1 in HCC treatment.     

Ethyl pyruvate attenuates ventilation‐induced diaphragm dysfunction through high‐mobility group box‐1 in a murine endotoxaemia model

Mechanical ventilation (MV) can save the lives of patients with sepsis. However, MV in both animal and human studies has resulted in ventilator‐induced diaphragm dysfunction (VIDD). Sepsis may promote skeletal muscle atrophy in critically ill patients. Elevated high‐mobility group box‐1 (HMGB1) levels are associated with patients requiring long‐term MV. Ethyl pyruvate (EP) has been demonstrated to lengthen survival in patients with severe sepsis. We hypothesized that the administration of HMGB1 inhibitor EP or anti‐HMGB1 antibody could attenuate sepsis‐exacerbated VIDD by repressing HMGB1 signalling. Male C57BL/6 mice with or without endotoxaemia were exposed to MV (10 mL/kg) for 8 hours after administrating either 100 mg/kg of EP or 100 mg/kg of anti‐HMGB1 antibody. Mice exposed to MV with endotoxaemia experienced augmented VIDD, as indicated by elevated proteolytic, apoptotic and autophagic parameters. Additionally, disarrayed myofibrils and disrupted mitochondrial ultrastructures, as well as increased HMGB1 mRNA and protein expression, and plasminogen activator inhibitor‐1 protein, oxidative stress, autophagosomes and myonuclear apoptosis were also observed. However, MV suppressed mitochondrial cytochrome C and diaphragm contractility in mice with endotoxaemia (P < 0.05). These deleterious effects were alleviated by pharmacologic inhibition with EP or anti‐HMGB1 antibody (P < 0.05). Our data suggest that EP attenuates endotoxin‐enhanced VIDD by inhibiting HMGB1 signalling pathway.     

LPS诱导肝细胞L02释放HMGB1蛋白的研究

以人单核巨噬细胞系U937细胞为对照,探讨肝细胞L02分泌晚期炎症介质高迁移率族蛋白HMGB1过程的特点.400μg/L LPS作用于人U937细胞和L02细胞,MTT和荧光TUNEL结果显示0～24 h,两种细胞均未见明显坏死和凋亡.RT-PCR结果表明L02细胞HMGB1 mRNA表达水平高于相应对照组的时相(20 h)晚于U937细胞(16 h).Western blot显示L02细胞上清中检测到HMGB1蛋白的时相(16 h)晚于U937细胞(8h);两者上清HMGBl蛋白水平呈时间依赖性,但U937细胞分泌HMGB1蛋白的量占有绝对优势.细胞免疫荧光观察到两者均有HMGB1从细胞核向胞浆移位的现象,但L02细胞晚于U937细胞.由此可见,LPS诱导肝细胞分泌晚期炎症介质HMGB1具有时相晚、量少的特点,且其分泌HMGB1的过程与HMGB1蛋白移位有关,而并不依赖于细胞坏死与凋亡.