Antibodies elicited by yeast glycoproteins recognize HIV-1 virions and potently neutralize virions with high mannose N-glycans.

The glycan shield on the human immunodeficiency virus 1 (HIV-1) envelope (Env) glycoprotein has drawn attention as a target for HIV-1 vaccine design given that an increasing number of potent and broadly neutralizing antibodies (bNAbs) recognize epitopes entirely or partially comprised of high mannose type N-linked glycans. In an attempt to generate immunogens that target the glycan shield of HIV-1, we previously engineered a triple mutant (TM) strain of Saccharomyces cerevisiae that results in exclusive presentation of high mannose type N-glycans, and identified five TM yeast glycoproteins that support strong binding of 2G12, a bNAb that targets a cluster of high mannose glycans on the gp120 subunit of Env. Here, we further analyzed the antigenicity and immunogenicity of these proteins in inducing anti-HIV responses. Our study demonstrated that the 2G12-reactive TM yeast glycoproteins efficiently bound to recently identified bNAbs including PGT125-130 and PGT135 that recognize high mannose glycan-dependent epitopes. Immunization of rabbits with a single TM yeast glycoprotein (Gp38 or Pst1), when conjugated to a promiscuous T-cell epitope peptide and coadministered with a Toll-like receptor 2 agonist, induced glycan-specific HIV-1 Env cross-reactive antibodies. The immune sera bound to both synthetic mannose oligosaccharides and gp120 proteins from a broad range of HIV-1 strains. The purified antibodies recognized and captured virions that contain both complex- and high mannose-type of N-glycans, and potently neutralized virions from different HIV-1 clades but only when the virions were enforced to retain high mannose N-glycans. This study provides insights into the elicitation of anti-carbohydrate, HIV-1 Env-cross reactive antibodies with a heterologous glycoprotein and may have applications in the design and administration of immunogens that target the viral glycan shield for development of an effective HIV-1 vaccine.

Yeast-elicited cross-reactive antibodies to HIV Env glycans efficiently neutralize virions expressing exclusively high-mannose N-linked glycans.

The HIV envelope (Env) protein uses a dense coat of glycans to mask conserved domains and evade host humoral immune responses. The broadly neutralizing antibody 2G12, which binds a specific cluster of high-mannose glycans on HIV Env, shows that the glycan shield can also serve as a target for neutralizing antibodies. We have described a triple mutant Saccharomyces cerevisiae strain that expresses high-mannose glycoproteins that bind to 2G12. When used to immunize rabbits, this yeast elicits antibodies that bind to gp120-associated glycans but fail to neutralize virus. Here we sought to determine the reason for these discordant results. Affinity purification of sera over columns conjugated with three 2G12-reactive yeast glycoproteins showed that these proteins could adsorb 80% of the antibodies that bind to gp120 glycans. Despite binding to monomeric gp120, these mannose-specific antibodies failed to bind cell surface-expressed trimeric Env. However, when Env was expressed in the presence of the mannosidase inhibitor kifunensine to force retention of high-mannose glycans at all sites, the purified antibodies gained the abilities to bind trimeric Env and to strongly and broadly neutralize viruses produced under these conditions. Combined, these data show that the triple mutant yeast strain elicits antibodies that bind to high-mannose glycans presented on the HIV envelope, but only when they are displayed in a manner not found on native Env trimers. This implies that the underlying structure of the protein scaffold used to present the high-mannose glycans may be critical to allow elicitation of antibodies that recognize trimeric Env and neutralize virus.

Protein-protein interactions involving congenital cataract T5P gammaC-crystallin mutant: a confocal fluorescence microscopy study.

The human lens crystallin gene CRYGC T5P is associated with Coppock-like cataract and has a phenotype of a dust-like opacity of the fetal lens nucleus and deep cortical region. Previous in vitro mutation studies indicate that the protein has changed conformation, solubility, and stability, which may make it susceptible to aggregation, as seen in cataractous lens and cell culture expression. To investigate the mechanisms leading to these events, we studied protein-protein interactions using confocal fluorescence resonance energy transfer (FRET) microscopy. The method detects protein-protein interactions in the natural environment of living cells. Crystallin genes (CRYGC T5P, CRYGC, and CRYAA) were fused to either the green fluorescence protein (GFP) or red fluorescence protein (DsRED or RFP) vector. Each of the following GFP-RFP (donor-acceptor) plasmid pairs was cotransfected into HeLa cells: gammaC-gammaC, gammaC-gammaCT5P, gammaCT5P-gammaCT5P, alphaA-gammaC, and alphaA-gammaCT5P. After culture, confocal fluorescence cell images were taken. Protein-protein interactions in the form of net FRET were evaluated. The confocal fluorescence images show that cells expressing T5P gammaC-crystallin contain many protein aggregates, but cells co-expressing with either gammaC- or alphaA-crystallin reduce the aggregation considerably. FRET determination indicates that gammaCT5P-gammaCT5P shows less protein-protein interaction than either gammaC-gammaC or gammaC-gammaCT5P. Cotransfection with alphaA-crystallin (alphaA-gammaC or alphaA-T5PgammaC) increases nFRET compared with gammaC-gammaC or gammaC-T5PgammaC. Our results demonstrate that T5P gammaC-crystallin shows more protein aggregates and less protein-protein interaction than WT gammaC-crystallin. Chaperone alphaA-crystallin can rescue T5P gammaC-crystallin from aggregation through increased protein interaction. The formation of congenital cataract may be due to reduced protein-protein interactions and increased aggregation from an insufficient amount of alpha-crystallin for protection.

Methylglyoxal induces prostaglandin E2 production in rat mesangial cells.

The formation of methylglyoxal (MG), a reactive dicarbonyl compound, is accelerated under hyperglycemia, presumably contributing to tissue injury in diabetes. On the other hand, prostaglandin E2 (PGE2) has been implicated in glomerular hyperfiltration, a characteristic change in the early stage of diabetic nephropathy. We therefore examined whether MG was capable of inducing PGE2 production in rat mesangial cells (RMC) to address a possible mechanism by which hyperglycemia-derived dicarbonyls accelerated the development of diabetic nephropathy. RMC were incubated with 0 - 200 microM of MG, followed by determination of secreted PGE2 by enzyme immunoassay (EIA). We further investigated the intracellular mechanisms mediating the MG-induced PGE2 synthesis, focusing particularly on cyclooxygenase-2 (COX-2) and the MAPK superfamily. Our results indicated that MG induced PGE2 production in a dose-dependent manner, accompanied by augmentation of COX-2 mRNA expression. This MG-induced PGE2 production was significantly suppressed by inhibiting either ERK1/2 or p38 MAPK, implicating involvement of the MAPK superfamily. Our results suggest a potential role of MG in the development of diabetic nephropathy through PGE2 production, and may serve as a novel insight into the therapeutic strategies for diabetic nephropathy.

Protein-protein interactions between lens vimentin and alphaB-crystallin using FRET acceptor photobleaching.

PURPOSE: The R120G mutation of alphaB-crystallin is known to cause desmin-related myopathy, but the mechanisms underlying the formation of cataract are not clearly established. We hypothesize that alteration of protein-protein interaction between R120G alphaB-crystallin and lens intermediate filament proteins is one of the mechanisms of congenital cataract. METHODS: Protein-protein interactions were determined by confocal fluorescence resonance energy transfer (FRET) microscopy using green fluorescence protein (GFP) as the donor and red fluorescence protein (RFP) as the acceptor. The lens vimentin gene was fused into a GFP vector and the alphaB-crystallin (WT or R120G mutant) gene was fused into the RFP vector. The donor-acceptor plasmid pairs of intermediate filament (IF)-GFP and alphaB-RFP were co-transfected into HeLa cells. After incubation, confocal fluorescence images of the transfected cells were taken. FRET was estimated by the acceptor photobleaching method. Protein-protein interaction was evaluated by FRET efficiency. RESULTS: The confocal fluorescence images showed that the cells expressing vimentin and R120G alphaB-crystallin contained large amounts of protein aggregates while few vimentin fibers were observed. FRET efficiency analyses indicated that vimentin had a significantly greater protein-protein interaction with R120G alphaB-crystallin than with WT alphaB-crystallin. CONCLUSIONS: Our results show that the R120G alphaB-crystallin mutant promoted vimentin aggregation through increased protein-protein interaction. This process may contribute to the formation of congenital cataract.

Confocal fluorescence microscopy study of interaction between lens MIP26/AQP0 and crystallins in living cells.

MIP26/AQP0 is the major lens fiber membrane protein and has been reported to interact with many other lens components including crystallins, lipid, and cytoskeletal proteins. Regarding crystallins, many previous reports indicate that MIP26/AQP0 interacts with either only alpha-crystallin or some specific gamma-crystallins. Considering the possibly important role of MIP26/AQP0 in the reduction of light scattering in the lenses, we have further investigated its interaction with crystallins using confocal fluorescence resonance energy transfer (FRET) microscopy. Specifically, we used MIP26 tagged with a green fluorescence protein (GFP) as a donor and a crystallin (alphaA-, alphaB-, betaB2-, or gammaC-crystallin) tagged with a red fluorescence protein (RFP) as an acceptor. The two plasmids were cotransfected to HeLa cells. After culture, laser scattering microscopy images were taken in each of the three channels: GFP, RFP, and FRET. The net FRET images were then obtained by removing the contribution of spectral bleed-through. The pixels of net FRET were normalized with those of GFP. The results show the presence of measurable interactions between MIP26 and all crystallins, with the extent of interactions decreasing from alphaA- and alphaB-crystallin to betaB2- and gammaC-crystallin. Competitive interaction study using untagged alphaA-crystallin shows decreased net FRET, indicating specificity of the interactions between MIP26 and alphaA-crystallin. We conclude that all crystallins interact with MIP26, the physiological significance of which may be a reduction in the difference of refractive index between membrane and cytoplasm.

Degradation of C-terminal truncated alpha A-crystallins by the ubiquitin-proteasome pathway.

PURPOSE: Calpain-mediated C-terminal cleavage of alpha A-crystallins occurs during aging and cataractogenesis. The objective of the present study was to explore the role of the ubiquitin-proteasome pathway (UPP) in degrading C-terminal truncated alpha A-crystallins. METHODS: Recombinant wild-type (wt) alpha A-crystallin and C-terminal truncated alpha A(1-168)-, alpha A(1-163)-, and alpha A(1-162)-crystallins were expressed in Escherichia coli and purified to homogeneity. The wt and truncated alpha A-crystallins were labeled with (125)I, and proteolytic degradation was determined using both lens fiber lysate and reticulocyte lysate as sources of ubiquitinating and proteolytic enzymes. Far UV circular dichroism, tryptophan fluorescence intensity, and binding to the hydrophobic fluorescence probe Bis-ANS were used to characterize the wt and truncated alpha A-crystallins. Oligomer sizes of these crystallins were determined by multiangle light-scattering. RESULTS: Whereas wt alpha A-crystallin was degraded moderately in both lens fiber and reticulocyte lysates, alpha A(1-168)-crystallin was resistant to degradation. The susceptibility of alpha A(1-163)-crystallin to degradation was comparable to that of wt alpha A-crystallin. However, alpha A(1-162)-crystallin was much more susceptible than wt alpha A-crystallin to degradation in both lens fiber and reticulocyte lysates. The degradation of both wt and C-terminal truncated alpha A(1-162)-crystallins requires adenosine triphosphate (ATP) and was stimulated by addition of a ubiquitin-conjugating enzyme, Ubc4. The degradation was substantially inhibited by the proteasome inhibitor MG132 and a dominant negative mutant of ubiquitin, K6W-Ub, indicating that at least part of the proteolysis was mediated by the UPP. Spectroscopic analyses of wt and C-terminal truncated alpha A-crystallins revealed that C-terminal truncation of alpha A-crystallin resulted in only subtle changes in secondary structures. However, C-terminal truncations resulted in significant changes in surface hydrophobicity and thermal stability. Thus, these conformational changes may reveal or mask the signals for the ubiquitin-dependent degradation. CONCLUSIONS: The present data demonstrate that C-terminal cleavage of alpha A-crystallin not only alters its conformation and thermal stability, but also its susceptibility to degradation by the UPP. The rapid degradation of alpha A(1-162) by the UPP may prevent its accumulation in the lens.

Protein-protein interactions among human lens acidic and basic beta-crystallins.

Human lens beta-crystallin contains four acidic (betaA1-->betaA4) and three basic (betaB1-->betaB3) subunits. They oligomerize in the lens, but it is uncertain which subunits are involved in the oligomerization. We used a two-hybrid system to detect protein-protein interactions systematically. Proteins were also expressed for some physicochemical studies. The results indicate that all acidic-basic pairs (betaA-betaB) except betaA4-betaBs pairs show strong hetero-molecular interactions. For acidic or basic pairs, only two pairs (betaA1-betaA1 and betaA3-betaA3) show strong self-association. betaA2 and betaA4 show very weak self-association, which arises from their low solubility. Confocal fluorescence microscopy shows enormous protein aggregates in betaA2- or betaA4-crystallin transfected cells. However, coexpression with betaB2-crystallin decreased both the number and size of aggregates. Circular dichroism indicates subtle differences in conformation among beta-crystallins that may have contributed to the differences in interactions.

Confocal fluorescence resonance energy transfer microscopy study of protein-protein interactions of lens crystallins in living cells.

PURPOSE: To determine protein-protein interactions among lens crystallins in living cells. METHODS: Fluorescence resonance energy transfer (FRET) microscopy was used to visualize interactions in living cells directly. Two genes, one (alphaA-crystallin) fused with green fluorescence protein (GFP) and the other (each of the following genes: alphaB-, betaB2-, gammaC-crystallin, and R120G alphaB-crystallin mutant) fused with GFP variant red fluorescence protein (RED), were cotransfected into HeLa cells. After culture, confocal microscopy images were taken and FRET values were calculated. RESULTS: FRET occurs when the two proteins interact. The data show strong interactions between alphaA- and alphaB-crystallin and weak interactions between alphaA- and betaB2- or gammaC-crystallin, which is consistent with our previous two-hybrid system study. The R120G alphaB-crystallin mutant, however, showed significantly less FRET than wild-type alphaB-crystallin. There are also more R120G alphaB-crystallin transfected cells with protein aggregates than wild-type alphaB-crystallin transfected cells. Cotransfection with alphaA-crystallin could not rescue R120G alphaB-crystallin from aggregation. CONCLUSIONS: FRET microscopy gave excellent results on the protein-protein interactions among crystallins. It supports many previous studies and provides a novel technique for further study of protein-protein interactions among lens proteins including membrane and cytoskeletal proteins.

Glutathiolation enhances the degradation of gammaC-crystallin in lens and reticulocyte lysates, partially via the ubiquitin-proteasome pathway.

PURPOSE: S-glutathiolated proteins are formed in the lens during aging and cataractogenesis. The objective of this work was to explore the role of the ubiquitin-proteasome pathway in eliminating S-glutathiolated gammaC-crystallin. METHODS: Recombinant human gammaC-crystallin was mixed with various concentrations of glutathione (GSH) and diamide at 25 degrees C for 1 hour. The extent of glutathiolation of the gammaC-crystallin was determined by mass spectrometry. Native and S-glutathiolated gammaC-crystallins were labeled with (125)I, and proteolytic degradation was determined using both lens fiber lysate and reticulocyte lysate as sources of ubiquitinating and proteolytic enzymes. Far UV circular dichroism, tryptophan fluorescence intensity, and binding to the hydrophobic fluorescence probe 4,4'-dianilino-1,1'-binaphthalene-5,5'-disulfonic acid (Bis-ANS), were used to characterize the native and glutathiolated gammaC-crystallins. RESULTS: On average, two and five of the eight cysteines in gammaC-crystallin were glutathiolated when molar ratios of gammaC-crystallin-GSH-diamide were 1:2:5 and 1:10:25, respectively. Native gammaC-crystallin was resistant to degradation in both lens fiber lysate and reticulocyte lysate. However, glutathiolated gammaC-crystallin showed a significant increase in proteolytic degradation in both lens fiber and reticulocyte lysates. Proteolysis was stimulated by addition of adenosine triphosphate (ATP) and Ubc4 and was substantially inhibited by the proteasome inhibitor MG132 and a dominant negative form of ubiquitin, indicating that at least part of the proteolysis was mediated by the ubiquitin-proteasome pathway. Spectroscopic analyses of glutathiolated gammaC-crystallin revealed conformational changes and partial unfolding, which may provide a signal for the ubiquitin-dependent degradation. CONCLUSIONS: The present data demonstrate that oxidative modification by glutathiolation can render lens proteins more susceptible to degradation by the ubiquitin-proteasome pathway. Together with previous results, these data support the concept that the ubiquitin-proteasome pathway serves as a general protein quality-control mechanism.

Fluorescence resonance energy transfer study of subunit exchange in human lens crystallins and congenital cataract crystallin mutants.

Lens alpha-crystallin is an oligomeric protein with a molecular mass of 500-1000 kDa and a polydispersed assembly. It consists of two types of subunits, alphaA and alphaB, each with a molecular mass of 20 kDa. The subunits also form homo-oligomers in some other tissues and in vitro. Their quaternary structures, which are dynamic and characterized by subunit exchange, have been studied by many techniques, including fluorescence resonance energy transfer (FRET) and mass spectrometry analysis. The proposed mechanism of subunit exchange has been either by dissociation/association of monomeric subunits or by rapid equilibrium between oligomers and suboligomers. To explore the nature of subunit exchange further, we performed additional FRET measurements and analyses using a fluorescent dye-labeled W9F alphaA-crystallin as the acceptor probe and Trp in other crystallins (wild-type and R116C alphaA, wild-type and R120G alphaB, wild-type and Q155* betaB2) as the donor probe and calculated the transfer efficiency, Förster distance, and average distance between two probes. The results indicate only slight decreased efficiency and increased distance between two probes for the R116C alphaA and R120G alphaB mutations despite conformational changes.

Effect of methylglyoxal modification and phosphorylation on the chaperone and anti-apoptotic properties of heat shock protein 27.

Heat shock protein 27 (Hsp27) is a stress-inducible protein in cells that functions as a molecular chaperone and also as an anti-apoptotic protein. Methylglyoxal (MGO) is a reactive dicarbonyl compound produced from cellular glycolytic intermediates that reacts non-enzymatically with proteins to form products such as argpyrimidine. We found considerable amount of Hsp27 in phosphorylated form (pHsp27) in human cataractous lenses. pHsp27 was the major argpyrimidine-modified protein in brunescent cataractous lenses. Modification by MGO enhanced the chaperone function of both pHsp27 and native Hsp27, but the effect on Hsp27 was at least three-times greater than on pHsp27. Phosphorylation of Hsp27 abolished its chaperone function. Transfer of Hsp27 using a cationic lipid inhibited staurosporine (SP)-induced apoptotic cell death by 53% in a human lens epithelial cell line (HLE B-3). MGO-modified Hsp27 had an even greater effect (62% inhibition). SP-induced reactive oxygen species in HLE-B3 cells was significantly lower in cells transferred with MGO-modified Hsp27 when compared to native Hsp27. In vitro incubation experiments showed that MGO-modified Hsp27 reduced the activity of caspase-9, and MGO-modified pHsp27 reduced activities of both caspase-9 and caspase-3. Based on these results, we propose that Hsp27 becomes a better anti-apoptotic protein after modification by MGO, which may be due to multiple mechanisms that include enhancement of chaperone function, reduction in oxidative stress, and inhibition of activity of caspases. Our results suggest that MGO modification and phosphorylation of Hsp27 may have important consequences for lens transparency and cataract development.

A novel alphaB-crystallin mutation associated with autosomal dominant congenital lamellar cataract.

PURPOSE: To identify the mutation and the underlying mechanism of cataractogenesis in a five-generation autosomal dominant congenital lamellar cataract family. METHODS: Nineteen mutation hot spots associated with autosomal dominant congenital cataract have been screened by PCR-based DNA sequencing. Recombinant wild-type and mutant human alphaB-crystallin were expressed in Escherichia coli and purified to homogeneity. The recombinant proteins were characterized by far UV circular dichroism, intrinsic tryptophan fluorescence, Bis-ANS fluorescence, multiangle light-scattering, and the measurement of chaperone activity. RESULTS: A novel missense mutation in the third exon of the alphaB-crystallin gene (CRYAB) was found to cosegregate with the disease phenotype in a five-generation autosomal dominant congenital lamellar cataract family. The single-base substitution (G-->A) results in the replacement of the aspartic acid residue by asparagine at codon 140. Far UV circular dichroism spectra indicated that the mutation did not significantly alter the secondary structure. However, intrinsic tryptophan fluorescence spectra and Bis-ANS fluorescence spectra indicated that the mutation resulted in alterations in tertiary and/or quaternary structures and surface hydrophobicity of alphaB-crystallin. Multiangle light-scattering measurement showed that the mutant alphaB-crystallin tended to aggregate into a larger complex than did the wild-type. The mutant alphaB-crystallin was more susceptible than wild-type to thermal denaturation. Furthermore, the mutant alphaB-crystallin not only lost its chaperone-like activity, it also behaved as a dominant negative which inhibited the chaperone-like activity of wild-type alphaB-crystallin. CONCLUSIONS: These data indicate that the altered tertiary and/or quaternary structures and the dominant negative effect of D140N mutant alphaB-crystallin underlie the molecular mechanism of cataractogenesis of this pedigree.

Domain interaction sites of human lens betaB2-crystallin.

betaB2-crystallin, the major component of beta-crystallin, is a dimer at low concentrations but can form oligomers under physiological conditions. The interaction domains have been speculated to be the beta-sheets, each of which is formed by two or more beta-strands. betaB2-crystallin consists of 16 beta-strands, 8 in the N-terminal domain and 8 in the C-terminal domain. Domain interaction sites may be removed by destroying the beta-strands, which can be done by site-specific mutations, substituting the beta-formers (Val, Phe, Leu) with Glu or Asn, strong beta-breakers. We have cloned the following beta-strand-deleted mutants, I20E, L34E, V54E, V60E, V73E, L97E, I109E, I124E, V144E, V152E, L162E, L165E, and V187E and their corresponding X --> Asn mutants. We also made two mutants, V46E and V129E, that were not on the beta-strand as controls. Disruption of protein-protein interactions was screened by a mammalian two-hybrid system assay. Protein-protein interactions decreased for all beta-strand-deleted mutants except I20E, L34E, and L162E mutants; this effect was not seen in the two mutant controls, V46E and V129E. The sequences around Val-54, Val-60, Val-73, and Leu-97 in the N-terminal region and Ile-109, Ile-124, Val-144, Val-152, Leu-165, and Val-187 in the C-terminal region that formed beta-strands appear to be important in dimerization. Some selected mutant proteins that showed strong (V46E and V129E) and reduced (V60E, V144E, V60N, and V144N) interactions were expressed in bacterial culture and were studied with spectroscopy and chromatography. The V60E and V144E mutants were found to be partially unfolded and incapable of forming a complete dimer.

Dicarbonyl stress and apoptosis of vascular cells: prevention by alphaB-crystallin.

Methylglyoxal (MGO) is an alpha-dicarbonyl compound produced from triose phosphate intermediates of glycolysis. It reacts rapidly with proteins to produce advanced glycation products. We have studied the effect of MGO modification of fibronectin on retinal capillary cell viability. Our studies show that pericytes grown on MGO-modified fibronectin (FN) undergo enhanced apoptosis through the p38MAPK-mediated oxidative pathway and that alphaB-crystallin, a stress protein present in pericytes, can protect them from MGO-mediated apoptosis. Our studies with vascular endothelial cells show that hyperglycemia-induced apoptosis is inhibited by overexpression of alphaB-crystallin. These observations suggest a novel role of alphaB-crystallin in hyperglycemia-mediated damage to vascular cells in diabetes.

Interaction and biophysical properties of human lens Q155* betaB2-crystallin mutant.

PURPOSE: Missense mutations in crystallin genes have been identified in autosomal dominant congenital cataracts. A truncation in the CRYBB2 gene (Q155*) has been associated with cerulean cataract, however its effects on biophysical properties have not been reported. We sought to determine the changes in conformation and protein-protein interactions brought about by this mutation. METHODS: Site specific mutations were performed to obtain the Q155* betaB2-crystallin mutant. Protein-protein interactions were screened by a mammalian two-hybrid system assay. Conformational changes were studied with spectroscopy (circular dichroism and fluorescence) and FPLC chromatography. RESULTS: We detected a decrease in protein-protein interactions for the Q155* betaB2-crystallin mutant. The Q155* mutant shows decreased ordered structure and stability but the partially unfolded protein retains some dimer structure. CONCLUSIONS: The Q155* mutation in betaB2-crystallin causes changes in biophysical properties that might contribute to cataract formation.

AlphaB-crystallin inhibits glucose-induced apoptosis in vascular endothelial cells.

Recent studies implicate hyperglycemia as a cause of vascular complications in diabetes. Our study confirmed that high concentration of glucose (30 mM) induces apoptosis in cultures of human umbilical vein endothelial cells. After 5 days of culture TUNEL positive cells in high concentration of glucose were nearly 63% higher when compared to normal concentration of glucose (5 mM). Transfection of pcDNA3-rat alphaB-crystallin into these cells inhibited high glucose-induced apoptosis by approximately 36%, such an effect was not observed when cells were transfected with an empty vector. AlphaB-crystallin transfection inhibited by about 35% of high glucose induced activation of caspase-3. High concentration of glucose enhanced formation of reactive oxygen species (ROS) in these cells but this was significantly (p < 0.001) curtailed by transfection of alphaB-crystallin. Results of our study indicate that alphaB-crystallin effectively inhibits both ROS formation and apoptosis in cultured vascular endothelial cells and provide a basis for future therapeutic interventions in diabetic vascular complications.

Effect of dicarbonyl modification of fibronectin on retinal capillary pericytes.

PURPOSE: To determine effects of alpha-dicarbonyl modification of an extracellular matrix protein on retinal capillary pericyte attachment and viability. METHODS: Primary cultures of bovine retinal pericytes (BRPs) were seeded on either normal fibronectin (FN) or FN modified by methylglyoxal (MGO) and glyoxal (GO). Apoptosis was measured by flow cytometry along with caspase-3 activity. Phosphorylation of p38 mitogen-activated protein kinase (MAPK) and Akt/PKB were evaluated by Western blot analysis. Cellular glutathione and reactive oxygen species were measured. alphaB-crystallin was measured by Western blot analysis and, to determine its role in apoptosis, experiments were conducted using BRPs that were transiently transfected with alphaB-crystallin. RESULTS: Cultures seeded on MGO- or GO-modified FN showed a significant reduction in the number of viable cells, an increase in the number of apoptotic cells, and increased caspase-3 activity, which correlated with the extent of FN modification. Pericytes seeded on either type of modified FN showed phosphorylation of p38 MAPK and dephosphorylation of Akt/PKB. Cultures seeded on dicarbonyl-modified FN had reduced glutathione and increased levels of reactive oxygen species compared with those on a normal matrix. Cells on the altered matrices had reduced alphaB-crystallin levels as well. Transient transfection of rat alphaB-crystallin into BRPs significantly reduced the apoptosis triggered by alpha-dicarbonyl-modified FN. CONCLUSIONS: These observations indicate that modification of FN by alpha-dicarbonyl compounds triggers apoptosis through a combination of increased oxidative stress and reduction of alphaB-crystallin. This mechanism may contribute to loss of pericytes in diabetic retinopathy and contribute to the resultant vascular lesions.

Relation between serum 3-deoxyglucosone and development of diabetic microangiopathy.

OBJECTIVE: 3-Deoxyglucosone (3-DG), a highly reactive intermediate of the glycation reaction, has been suggested to contribute to the development of diabetes complications. To verify this hypothesis, we assessed the relation between serum 3-DG concentrations and the severity of diabetic microangiopathy in diabetic patients. RESEARCH DESIGN AND METHODS: We conducted a high-performance liquid chromatography assay to determine the serum 3-DG concentrations of 110 diabetic patients with different degrees of severity of diabetic microangiopathy and 57 age-matched control subjects. RESULTS: The fasting serum 3-DG level in diabetic patients was significantly (P < 0.001) higher than that in control subjects (353 +/- 110 vs. 199 +/- 53 nmol/l). The 3-DG levels were significantly (P < 0.001) elevated even in the diabetic patients showing normoalbuminuria (n = 62, 322 +/- 79 nmol/l) compared with control subjects. The 3-DG levels were further elevated in the patients with microalbuminuria (n = 30, 383 +/- 146 nmol/l) and overt proteinuria (n = 18, 410 +/- 100 nmol/l) (P = 0.027 and P < 0.001 vs. normoalbuminuria group, respectively). This phenomenon was basically reproduced in a category of retinopathy. Furthermore, the diabetic patients with low nerve conduction velocity showed a tendency to display higher 3-DG levels. CONCLUSIONS: The present results show that the fasting serum 3-DG level is elevated in diabetic patients and that the patients with relatively higher 3-DG levels were prone to suffer from more severe complications, indicating a possible association of 3-DG with diabetic microangiopathy.

Methylglyoxal induces apoptosis through activation of p38 mitogen-activated protein kinase in rat mesangial cells.

BACKGROUND: The formation of methylglyoxal (MG), a highly reactive dicarbonyl compound, is accelerated through several pathways, including the glycation reaction under diabetic conditions, presumably contributing to tissue injury in diabetes. On the other hand, apoptotic cell death of glomerular cells has been suggested to play a role in the development of glomerulosclerosis in various types of glomerular injuries. We therefore examined whether MG was capable of inducing apoptosis in rat mesangial cells to address the possible mechanism by which hyperglycemia-related products accelerated pathologic changes in diabetic glomerulosclerosis. METHODS: Rat mesangial cells were incubated with 0 to 400 micromol/L MG, followed by the detection of apoptosis by both TUNEL method and electrophoretic analysis for DNA fragmentation. In addition, we investigated intracellular mechanisms mediating MG-induced apoptosis, focusing especially on the p38 mitogen-activated protein kinase (MAPK) pathway. RESULTS: MG induced apoptosis in rat mesangial cells in a dose-dependent manner and was accompanied by the activation of p38alpha isoform. Aminoguanidine and N-acetyl-l-cysteine inhibited the MG-induced p38 MAPK activation, as well as apoptosis in rat mesangial cells, suggesting the involvement of oxidative stress in these phenomena. SB203580, a specific inhibitor of p38 MAPK also suppressed the MG-induced apoptosis in rat mesangial cells. CONCLUSIONS: These results suggest a potential role for MG in glomerular injury through p38 MAPK activation under diabetic conditions and may serve as a novel insight into the therapeutic strategies for diabetic nephropathy.