Aldehyde Modification Research Articles

Photocatalytic Aldehyde Allylation for Site‐Specific DNA Functionalization

Comprehensive SummaryEnhancing the DNA toolbox with innovative photochemical reactions is pivotal for advancing nucleic acid‐based technologies. Aldehyde groups, versatile bioorthogonal handles for imine formation under acidic conditions, are particularly valuable due to their roles in nucleic acid epigenetics. Here, we present the first photocatalytic on‐DNA aldehyde allylation, enabling precise DNA functionalization under mild, neutral aqueous conditions. Our approach utilizes a photocatalytic polarity‐reversal reaction between DNA‐conjugated benzaldehydes and allyl sulfones. This reaction demonstrates exceptional chemoselectivity while preserving DNA integrity. By varying allyl sulfones, we achieve site‐specific labeling of non‐native DNA with the aldehyde group and cross‐linking with DNA‐bearing allyl sulfones. Furthermore, our method facilitates selective labeling and pull‐down enrichment of 5‐formylpyrimidine nucleotides among complex cellular DNA. This photocatalytic on‐DNA aldehyde transformation expands the limited bioorthogonal photochemical toolboxes, providing novel avenues for functionalizing both non‐native and native aldehyde modifications on DNA.

Antibacterial and rapidly absorbable hemostatic sponge by aldehyde modification of natural polysaccharide

Massive hemorrhage following tissue trauma has high mortality owing to the lack of timely intervention. However, research on utilizing hemostats for humans is limited; therefore, developing an efficient emergency hemostatic agent is imperative. We developed a hemostatic sponge using natural polysaccharide riclin, theoretically modified with 50% aldehyde content (AR50). The AR50 sponge, with quasi-honeycomb channels and appropriate aldehyde content, exhibits ultra-high blood absorption (59.4 g·g−1) and rapidly targets erythrocytes and platelets to form a stable barrier. It surpasses most commercial hemostats in porcine artery scission (reducing hemostasis time and blood loss by 53 s and 4.2 g), hepatic bleeding laceration (68 s and 2.6 g), and perforation models (140 s and 4.9 g). The AR50 sponge is easily removed post hemostasis, exhibits antibacterial properties by destroying bacterial cell walls, and is safely absorbed by day 5, making it an ideal emergency hemostatic agent for massive hemorrhages in humans.

Facile route to tri-carboxyl chitin nanocrystals from di-aldehyde chitin modified by selective periodate oxidation

Chitin, a kind of polysaccharide mainly obtained from food waste, has emerged as an important biodegradable biopolymer in composite materials. The difficulty of aldehyde modification, which greatly limited the application of chitin nanocrystals, was addressed by applying a facile route of partial deacetylation followed by periodate oxidation in this study. Deacetylation occurred on the surface of both crystalline and amorphous regions, which were significantly degraded in the following periodate oxidation due to the inevitable cleavage of chitin chains, leading to an increase in the crystallinity index of obtained di-aldehyde chitin. The degree of deacetylation and periodate addition had limited improvement in the aldehyde content of di-aldehyde chitin with a maximum value of around 0.42 mmol/g. With further 2,2,6,6-tetramethylpiperidine-1-oxyl-mediated oxidation, the carboxyl content of tri-carboxyl chitin was improved to 1.58 mmol/g, which played a critical role in the dispersion efficiency and morphology of chitin nanocrystals. The obtained rod-like chitin nanocrystals with a ζ-potential value of −42 mV and an average size of 97 nm have potential application in dye-adsorption and emulsion stabilizers.

Covalent Design of Cell Membrane Stationary Phase with Enhanced Stability for Fast Screening P-Glycoprotein Inhibitors.

Cell membrane chromatography (CMC) has been widely used for characterizing the interaction between drugs and membrane receptors to screen target components from herbal medicines. However, the column life, stability, and the efficiency cannot meet the needs of high-throughput screening purpose. In this study, a P-glycoprotein immobilized cell membrane stationary phase (P-gp/CMSP) was prepared with a simple and mild two-step aldehyde modification, realizing the covalent bonding between cell membrane and stationary phase. The column life and stability were significantly enhanced compared with the unmodified columns. The P-gp/CMC column was equipped into a comprehensive 2D P-gp/CMC/Capcell-C18/TOFMS system, which actualizes the automated and high-throughput analytical process and rapid identification of complex chemical samples with no data loss. Five compounds with significant retention were screened out and unambiguously identified by the comprehensive 2D analytical system. Baicalin was confirmed as a P-gp inhibitor with ATP depletion inhibition ratio of 83.4%. Moreover, the reversal index of baicalin on DOX significantly increased to 11.13 when its concentration reached 25 μM, revealing that baicalin could effectively reverse the MDR cell model induced by DOX. The integrated system is a practical drug discovery platform and could be applied to other transmembrane protein models.

Modification of HDL by reactive aldehydes alters select cardioprotective functions of HDL in macrophages.

While increased levels of high-density lipoprotein (HDL)-cholesterol correlate with protection against cardiovascular disease, recent findings demonstrate that HDL function, rather than HDL-cholesterol levels, may be a better indicator of cardiovascular risk. One mechanism by which HDL function can be compromised is through modification by reactive aldehydes such as acrolein (Acro), 4-hydroxynonenal, and malondialdehyde (MDA). In this study, we tested the hypothesis that modification of HDL with reactive aldehydes would impair HDL's athero-protective functions in macrophages. Compared to native HDL, Acro- and MDA-modified HDL have impaired abilities to promote migration of primary peritoneal macrophages isolated from C57BL6/J mice. Incubation of macrophages with MDA-HDL also led to an increased ability to generate reactive oxygen species. Our studies revealed that the changes in HDL function following aldehyde modification are likely not through activation of canonical nuclear factor-kappa B signaling pathways. Consistent with this finding, treatment of either noncholesterol-loaded macrophages or foam cells with modified forms of HDL does not lead to significant changes in expression levels of inflammatory markers. Importantly, our data also demonstrate that changes in HDL function are dependent on the type of modification present on the HDL particle. Our findings suggest that modification of HDL with reactive aldehydes can impair some, but not all, of HDL's athero-protective functions in macrophages.

Cigarette smoke modifies and inactivates SPLUNC1, leading to airway dehydration.

Chronic obstructive pulmonary disease (COPD) is a growing cause of morbidity and mortality worldwide. Cigarette smoke (CS) exposure, a major cause of COPD, dysregulates airway epithelial ion transport and diminishes airway surface liquid (ASL) volume. Short palate lung and nasal epithelial clone 1 (SPLUNC1) is secreted into the airway lumen where it maintains airway hydration via interactions with the epithelial Na+ channel (ENaC). Although ASL hydration is dysregulated in CS-exposed/COPD airways, effects of CS on SPLUNC1 have not been elucidated. We hypothesized that CS alters SPLUNC1 activity, therefore contributing to ASL dehydration. CS exposure caused irreversible SPLUNC1 aggregation and prevented SPLUNC1 from internalizing ENaC and maintaining ASL hydration. Proteomic analysis revealed αβ-unsaturated aldehyde modifications to SPLUNC1's cysteine residues. Removal of these cysteines prevented SPLUNC1 from regulating ENaC/ASL volume. In contrast, SPX-101, a peptide mimetic of natural SPLUNC1, that internalizes ENaC, but does not contain cysteines was unaffected by CS. SPX-101 increased ASL hydration and attenuated ENaC activity in airway cultures after CS exposure and prolonged survival in a chronic airway disease model. These findings suggest that the CS-induced defects in SPLUNC1 can be circumvented, thus making SPX-101 a novel candidate for the treatment of mucus dehydration in COPD. -Moore, P. J., Reidel, B., Ghosh, A., Sesma, J., Kesimer, M., Tarran, R. Cigarette smoke modifies and inactivates SPLUNC1, leading to airway dehydration.

Effect of short-chain aldehydes on the enzymatic activity of pyruvate kinase

The oxidative modification of lipids containing polyunsaturated fatty acids results in a great diversity of reactive products including short-chain aldehydes, which can covalently modify proteins. The cellular effects of some of these oxidative post-translational modifications are yet to be understood, so there is a need to study the effect of small reactive aldehydes on the activity of enzymes. The model proteins lysozyme and human serum albumin were used to map aldehyde modifications by mass spectrometry (MS). The same approach was used to treat pyruvate kinase (PK), an enzyme that catalyses the last step in glycolysis and regulates tumour growth. PK was treated for 10 mins with varying concentrations of acrolein, malondialdehyde and 4-hydroxy-2-hexenal, before assaying the enzymatic activity. In each case, a dose-dependent effect on the activity was observed. Additionally, analysis of tryptic digests of modified PK by LC-MS/MS allowed these modifications to be identified and located. Inhibition of PK has been found to be associated with cancer progression, and this study suggests that reactive short-chain aldehydes could contribute to this and influence cell survival, as well as providing novel information on the structure-function relationship of lipoxidation.

A mass spectrometry approach for the identification and localization of small aldehyde modifications of proteins

Lipids containing polyunsaturated fatty acids are primary targets of oxidation, which produces reactive short-chain aldehydes that can covalently modify proteins, a process called lipoxidation. Improved mass spectrometry (MS) methods for the analysis of these adducts in complex biological systems are needed. Lysozyme and human serum albumin (HSA) were used as model proteins to investigate lipoxidation products formed by two short-chain aldehydes, acrolein and pentanal, which are unsaturated and saturated aldehydes respectively. The adducts formed were stabilized by NaBH4 or NaBH3CN reduction and analysed by MS. Analysis of intact modified lysozyme showed a pentanal modification resulting from Schiff's base formation (+70 Da), and up to 8 acrolein adducts, all resulting from Michael addition (+58 Da). Analysis of tryptic digests identified specific histidine, cysteine and lysine residues modified in both lysozyme and HSA, and determined characteristic amino acid-specific fragmentations. Eight different internal fragment ions were found that could be used as general diagnostic ions for pentanal- and acrolein-modified amino acids. The combined use of intact protein analysis and LC-MS/MS methods provided a powerful tool for the identification and localization of aldehyde-protein adducts, and the diagnostic ions will facilitate the development of targeted MS methods for analysis of adducts in more complex samples.

Asymmetric Synthesis of 3,4-Disubstituted 2-(Trifluoromethyl)pyrrolidines through Rearrangement of Chiral 2-(2,2,2-Trifluoro-1-hydroxyethyl)azetidines.

Enantiopure 4-formyl-β-lactams were deployed as synthons for the diastereoselective formation of chiral 2-(2,2,2-trifluoro-1-hydroxyethyl)azetidines via trifluoromethylation through aldehyde modification followed by reductive removal of the β-lactam carbonyl moiety. Subsequent treatment of the (in situ) activated 2-trifluoroethylated azetidines with a variety of nitrogen, oxygen, sulfur, and fluorine nucleophiles afforded chiral 3,4-disubstituted 2-(trifluoromethyl)pyrrolidines in good to excellent yields (45-99%) and high diastereoselectivities (dr >99/1, 1H NMR) via interception of bicyclic aziridinium intermediates. Furthermore, representative pyrrolidines were N,O-debenzylated in a selective way and used for further synthetic elaboration to produce, for example, a CF3-substituted 2-oxa-4,7-diazabicyclo[3.3.0]octan-3-one system.

Conjugation with 20 kDa dextran decreases the autoxidation rate of bovine hemoglobin

Haemoglobin-based oxygen carrier (HBOC) is highly susceptible to autoxidation that renders a series of tissue and cellular toxicities. HBOC is prepared by chemical modification of haemoglobin (Hb), which typically increases the autoxidation rate of Hb. Thus, it is necessary to decrease the autoxidation of HBOC. In the present study, two dextran-bHb conjugates (dex20-bHb and dex40-bHb) were prepared by conjugation with 20 kDa or 40 kDa dextrans, where the thiol group of Cys-93(β) was reversibly protected. The autoxidation rate of bHb was decreased by conjugation with 20 kDa dextran and maintained by conjugation with 40 kDa dextran. In order to understand the low autoxidation rate of dex20-bHb, the effects of aldehyde modification and dextran on the autoxidation rate of dex20-bHb were investigated. The high oxygen affinity, high tetramer stability and dextran itself were found to decrease the autoxidation rate of dex20-bHb. The conjugated dextran had a predominant effect on decreasing the autoxidation rate of bHb, which was particularly promising for the potential development of safe HBOCs. Conjugation with dextran is of general significance to decrease the oxidation process of the heme-containing proteins, such as Hb and myoglobin.

Aldehyde Approach to Hydrophobic Modification of Chitosan Aerogels.

Biobased nanofiber aerogels are ones of the attractive emerging materials in the fields of biochemistry and materials chemistry, but their poor humidity stability due to high hydrophilicity has limited their practical uses. In this paper, a new series of hydrophobic nanofibrous aerogels made from regenerated chitosan and alkyl aldehydes were prepared via a simple one-pot reaction followed by supercritical drying. Hexanal-modified chitosan aerogel shows excellent hydrophobicity with a water contact angle of ∼136°, a low density of 0.04-0.07 g cm-3, and structurally homogeneous three-dimensional nanofiber network at the nanoscale. Systematic investigations using various alkyl aldehydes revealed that pentanal-modified aerogel has similar high hydrophobicity and low density compared to the hexanal-modified material, while heptanal- and octanal-modified aerogels show drastic shrinkage during gelation. The aldehyde modification also suppresses permeation of water droplets into aerogel monoliths as well as reducing shrinkage under high humidity conditions.

Universal surface modification by aldehydes on polymeric membranes for isopropanol dehydration via pervaporation

This work reports a novel and facile aldehyde modification method to transform polymeric hollow fiber membranes for pervaporation dehydration of alcohols and biofuels with much enhanced separation performance and chemical stability. A universal approach consisting of hyper-branched polyethyleneimine (HPEI) pre-treatment and aldehyde modification was proposed and successfully applied to various polymeric membranes such as Torlon®, Ultem®, and PES hollow fibers with greatly improved separation performance. The surface modified hollow fibers were characterized by positron annihilation spectroscopy, Fourier transform infrared spectroscopy, X-ray photoelectron spectroscopy, and water contact angle measurements, etc. Results show the HPEI pre-treatment not only mitigates surface defects but also augments membrane hydrophilicity favoring water transport, while the cross-linking reaction between HPEI and aldehydes tightens polymeric chains and enhances selectivity. Besides, the newly molecularly designed membranes display satisfactory separation performance at various feed temperatures and compositions as well as good long-term stability. This study may open up new perspectives to design advanced pervaporation membranes by synergistic combination of the super reactivity and unique chemical interactions from HPEI and aldehydes.

Detection of circulating IgG antibodies to apolipoprotein B100 in acute myocardial infarction

A number of studies have reported an association between increased levels of antibodies against oxidized low-density lipoprotein (oxLDL) and cardiovascular disease, but the anti-oxLDL antibody has not been confirmed to serve as an effective biomarker for prediction of acute myocardial infarction (AMI). Apolipoprotein B100 (ApoB100)-derived peptide fragments generated by proteolytic degradation and aldehyde modification are the major antigens in oxLDL, and so the present work was undertaken to detect circulating IgG for Apo-B100-derived peptide antigens. An in-house enzyme-linked immunosorbent assay (ELISA) was developed with eight ApoB100-derived peptide antigens (Ag1–Ag8) to detect circulating anti-ApoB100 IgG levels in 267 patients with AMI and 201 control subjects. Binary logistic regression analysis revealed that circulating IgG for Ag1 was significantly higher in the patient group than the control group (P<0.001) after adjustment for age, gender, smoking, hypertension, diabetes and circulating levels of cholesterol, HDL, LDL, ApoA and ApoB100. None of the other seven antigens detected an increase in IgG levels in AMI patients compared with control subjects. Spearman correlation analysis showed no correlation between IgG antibody for Ag1 and clinical characteristics. In conclusion, the linear peptide antigens derived from ApoB100 may be suitable for the development of an ELISA antibody test for prediction of AMI, although further confirmation is still needed in large-scale clinical studies.

Aldehyde modification and alum coadjuvancy enhance anti-TNF-α autovaccination and mitigate arthritis in rat.

Experimental vaccination to induce antibodies (Abs) capable of cytokine antagonism shows promise as a novel immunotherapy for chronic inflammatory disease. We prepared a hybrid antigen consisting of residues 141-235 of rat TNF-α fused to the C-terminus of glutathione-S-transferase (GST), chemically modified to incorporate aldehyde residues, for development of an auto-vaccine eliciting anti-rTNF-α Abs. In rat immunization the soluble aldehyde-modified fusion protein did not generate observable Ab responses. By contrast, vaccination with the aldehyde-modified fusion protein adsorbed on alum induced anti-TNF-α autoAbs with high titer and neutralizing activity. Induction of adjuvant arthritis in rats pre-immunized with unmodified fusion protein or a control protein in alum resulted in severe inflammation and joint damage, whereas the disease induced in rats immunized with the aldehyde-bearing fusion protein in alum was markedly attenuated. Similar results were obtained in a collagen-induced rat arthritis model. Anti-collagen II IgG Ab titers did not deviate significantly in groups pre-immunized with modified fusion protein and control protein, suggesting that anti-TNF vaccination did not skew the immune response related to disease induction. This study demonstrates synergy between particulate alum and protein bound carbonyl residues for enhancement of protein immunogenicity. The antigen-specific co-adjuvant system could prove advantageous for breaking tolerance in emerging auto-vaccination therapies targeting inflammatory cytokines as well as for enhancing a broader category of subunit vaccines. Aldehyde adduction introduces a minimal modification which, together with the established use of alum as a safe adjuvant for human use, could be favorable for further vaccine development.

Fluorescent and magnetic dual-responsive coreshell imprinting microspheres strategy for recognition and detection of phycocyanin

Molecular imprinting as a versatile technology is emerging for diverse species in various fields; however protein imprinting faces several problems related to the size, structural complexity, conformational flexibility, and compatibility with solvents. Herein, by using phycocyanin as a model, with physiological significance and fluorescence characteristics, we developed a facile and highly efficient approach to obtain fluorescent and magnetic dual-responsive coreshell imprinting microspheres. Twostage miniemulsion polymerization was employed, based on surface immobilization of phycocyanin with aminolysis and aldehyde modification on superparamagnetic support particles. The dual-responsive imprinting microspheres exhibited high adsorption capacity of 10.53 mg g−1, excellent binding selectivity toward phycocyanin with a high imprinting factor of 2.41, and good reproducibility with standard error within 10%. Furthermore, fast simple magnetic separation and sensitive fluorescent detection in a wide pH range was offered for phycocyanin, showing a good linearity within 0.01–1.0 mg L−1 (R2 = 0.9970) and a favorable detectability up to 1.5 ng mL−1. Consequently, the imprinting microspheres were successfully applied as sorbents for selective isolation of phycocyanin from protein mixtures and special imaging recognition. Taking advantages of dual-responsive polymers and surface imprinting, the developed strategy provides great application potentials for convenient, rapid targeting identification/enrichment and separation of proteins and thereby contributing to targeting drug delivery and protein research.

Mild and Efficient Strategy for Site-Selective Aldehyde Modification of Glycosaminoglycans: Tailoring Hydrogels with Tunable Release of Growth Factor

Aldehydes have been used as an important bioorthogonal chemical reporter for conjugation of large polymers and bioactive substances. However, generating aldehyde functionality on carbohydrate-based biopolymers without changing its native chemical structure has always persisted as a challenging task. The common methods employed to achieve this require harsh reaction conditions, which often compromise the structural integrity and biological function of these sensitive molecules. Here we report a mild and simple method to graft aldehydes groups on glycosaminoglycans (GAGs) in a site-selective manner without compromising the structural integrity of the biopolymer. This regio-selective modification was achieved by conjugating the amino-glycerol moiety on the carboxylate residue of the polymer, which allowed selective cleavage of pendent diol groups without interfering with the C2-C3 diol groups of the native glucopyranose residue. Kinetic evaluation of this reaction demonstrated significant differences in second-order reaction rate for periodate oxidation (by four-orders of magnitude) between the two types of vicinal diols. We employed this chemistry to develop aldehyde modifications of sulfated and nonsulfated GAGs such as hyaluronic acid (HA), heparin (HP), and chondroitin sulfate (CS). We further utilized these aldehyde grafted GAGs to tailor extracellular matrix mimetic injectable hydrogels and evaluated its rheological properties. The composition of the hydrogels was also found to modulate release of therapeutic protein such as FGF-2, demonstrating controlled release (60%) for over 14 days. In short, our result clearly demonstrates a versatile strategy to graft aldehyde groups on sensitive biopolymers under mild conditions that could be applied for various bioconjugation and biomedical applications such as drug delivery and regenerative medicine.

Cartilage boundary lubricating ability of aldehyde modified proteoglycan 4 (PRG4-CHO)

Proteoglycan 4 (PRG4), also known as lubricin1 and superficial zone protein2, is a mucinous glycoprotein that is present in synovial fluid (SF) and at the surface of articular cartilage, where it functions as a critical boundary lubricant necessary for joint health3. High friction and high wear are amongst many factors that may contribute to cartilage degeneration4. PRG4 is critical in reducing friction and minimising surface tissue shear5 at the surface of cartilage, thus preventing the degradation of cartilage through boundary lubrication. Indeed, an increased coefficient of friction in PRG4-knockout mice is associated with increased wear of the articular surface6. Furthermore, intra-articular injection of PRG4 has been shown to prevent cartilage degradation in post-injury rat models of osteoarthritis (OA)7. A recent study, motivated by diminished PRG4 levels in SF associated with early OA, demonstrated aldehyde modification of PRG4 (PRG4-CHO) significantly enhanced its binding to a depleted articular surface8. Such modification may contribute to an improved biotherapeutic treatment of early OA with PRG4 through enhanced residence time within the joint and/or binding to the articular cartilage surface. However, it remains to be determined if PRG4-CHO maintains the friction-reducing ability of unmodified PRG4. Therefore, the objective of this study was to assess the cartilage boundary lubricating ability of PRG4-CHO versus unmodified PRG4 using a previously described in-vitro cartilage-cartilage friction test5,9. The findings of this study indicate that aldehyde modification does not significantly affect the protein structure or lubricating function of PRG4, and PRG4-CHO is an effective friction reducing cartilage boundary lubricant. These results, together with previously published data8, collectively suggest PRG4-CHO may be useful in molecular resurfacing strategies for tissue surfaces requiring lubrication, and potentially other biointerfaces or biomaterials as well.

Focus on Molecules: Lysyl oxidase

1. StructureLysyl Oxidase (LOX, also called protein-lysine 6-oxidase)(Genbank accession numbers: Nucleotide NM_002317.5, ProteinNP_002308.2, EC 1.4.3.13) is one of the five LOX family members(LOX and LOX Like1-4). The human LOX gene is located onchromosome 5q23.2. LOX is synthesized as a 50 kDa pre-proteincontaining 3 domains; the N-terminal signal peptide sequence(aa1-21), the N-terminal pro-peptide domain (aa 22-162), and theC-terminal catalytic domain (aa 162-417). The signal peptide isremoved by cleavage at the Cys21-Ala22 bond and the pro-peptidedomain is N-glycosylated in the endoplasmic reticulum and Golgiapparatus yielding a pro-enzyme, which is then secreted fromcells as a catalytically inactive protein. The 32 kDa active enzyme(C-terminal domain) is released by proteolytic cleavage of thepro-peptide at Gly162eAsp163 by procollagen C-proteinase (bonemorphogenetic protein 1; BMP-1) (Kagan and Li, 2003)(Fig. 1).2. FunctionLOX belongs to a family of amine oxidases. LOX was initiallyreported to be expressed andsecreted by fibrogenic cells but is nowknown to be expressed in several other cell types. LOX oxidizespeptidyl lysine and hydroxylysine residues in collagen and lysineresidues in elastin to produce peptidyl alpha-aminoadipic-delta-semialdehydes. These aldehyde modifications can spontaneouslycombine with vicinal peptidyl aldehydes or with epsilon-aminogroups of peptidyl lysine to form covalent cross-links that stabilizeand cause collagen and elastin fibers to be insoluble in the extra-cellular matrix (ECM). The significance of LOX was demonstrated inthe LOX knockout mouse, which could not survive at birth, due torupture of the aorta and diaphragm from incomplete elastin cross-linking. LOX is also essential for development of the distal andproximal airways, and the formation of alveoli in the lungs. LOX isalso critical for notochord formation and muscle development. LOXaffects differentiation of osteoblasts by forming cross-links in thesurrounding collagen matrix. These results underline the impor-tance of LOX in the morphogenesis and repair of connective tissuesof the cardiovascular, respiratory, skeletal, and other organ systems(Fongetal.,2009).LOXcanalsoinducecross-linkingbetweenlysinesin histones in the nucleus (Kagan and Li, 2003). LOX has also beenreported as a potent chemotactic agent for monocytes and vascularsmooth muscle cells.3. Disease involvementDuetotherangeofLOXbiologicalfunctions,abnormalitiesofLOXexpression underlie the development of a number of pathologicalprocesses related with an imbalance in ECM synthesis/degradation.LOX is expressed in several ocular tissues, and the followingdiseases of the eye have been linked with LOX:A. Keratoconus: Keratoconus is a corneal degeneration in whichthe extracellular matrix of the cornea loses its integrity, slowlychanging from the normal round shape to a cone shape. Onestudy reported that corneal LOX mRNA expression was signif-icantly lower in keratoconus patients when compared to theirage-matched controls. Another study showed that reducingcopper levels in tears results in keratoconus in an animalmodel. Copper is an essential cofactor for LOX activity.B. Diabetic retinopathy (DR): There are a number of reports oflower expression of LOX co-factors in DR retina samples andlower LOX cross-linking activity in vitreous samples of patientswith DR. However, theeffectofhigh glucose onLOXexpressionand enzymatic activity in cultured human retinal endothelialcells is less clear, with conflicting evidence suggesting eitherincreased or decreased LOX expression. Although discrepant,these studies indicate a potential involvement of LOX in theobserved DR phenotype.

Phosphatidylethanolamines Modified by γ-Ketoaldehyde (γKA) Induce Endoplasmic Reticulum Stress and Endothelial Activation

Peroxidation of plasma lipoproteins has been implicated in the endothelial cell activation and monocyte adhesion that initiate atherosclerosis, but the exact mechanisms underlying this activation remain unclear. Lipid peroxidation generates lipid aldehydes, including the γ-ketoaldehydes (γKA), also termed isoketals or isolevuglandins, that readily modify the amine headgroup of phosphatidylethanolamine (PE). We hypothesized that aldehyde modification of PE could mediate some of the proinflammatory effects of lipid peroxidation. We found that PE modified by γKA (γKA-PE) induced THP-1 monocyte adhesion to human umbilical cord endothelial cells. γKA-PE also induced expression of adhesion molecules and increased MCP-1 and IL-8 mRNA in human umbilical cord endothelial cells. To determine the structural requirements for γKA-PE activity, we tested several related compounds. PE modified by 4-oxo-pentanal induced THP-1 adhesion, but N-glutaroyl-PE and C(18:0)N-acyl-PE did not, suggesting that an N-pyrrole moiety was essential for cellular activity. As the N-pyrrole headgroup might distort the membrane, we tested the effect of the pyrrole-PEs on membrane parameters. γKA-PE and 4-oxo-pentanal significantly reduced the temperature for the liquid crystalline to hexagonal phase transition in artificial bilayers, suggesting that these pyrrole-PE markedly altered membrane curvature. Additionally, fluorescently labeled γKA-PE rapidly internalized to the endoplasmic reticulum (ER); γKA-PE induced C/EBP homologous protein CHOP and BiP expression and p38 MAPK activity, and inhibitors of ER stress reduced γKA-PE-induced C/EBP homologous protein CHOP and BiP expression as well as EC activation, consistent with γKA-PE inducing ER stress responses that have been previously linked to inflammatory chemokine expression. Thus, γKA-PE is a potential mediator of the inflammation induced by lipid peroxidation.

Immune responses against aldehyde-modified laminin accelerate atherosclerosis in Apoe−/− mice

Background LDL oxidation in the vascular wall is associated with aldehyde modification of surrounding extracellular matrix proteins that may target autoimmune responses against vascular tissues. Here we investigated the possible influence of immunity against a malondialdehyde (MDA)-modified form of the basement membrane protein laminin on atherosclerosis. Methods and results IgM and IgG autoantibodies were present in human plasma and a prospective clinical study demonstrated that individuals who later suffered from acute cardiovascular events had lower levels of MDA-laminin antibodies compared to those in the control group. Immunohistochemical analysis of atherosclerotic plaques from Apoe −/− mice demonstrated co-localization between laminin and MDA epitopes, however MDA-laminin IgG was absent in mouse plasma. To determine the effect of MDA-laminin immunity, Apoe −/− mice were immunized with MDA-laminin. Analysis of circulating leukocytes at 12 weeks demonstrated increased T-cell activation, expansion of Th17 cells and a lower fraction of regulatory T cells (Tregs) in mice immunized with MDA-laminin. At 25 weeks, aortic atherosclerosis was increased by more than 60% in mice immunized with MDA-laminin, together with increased levels of MDA-laminin IgG1 and MDA-laminin-specific T-cells expressing IL-2, IL-4 and IL-6 in the spleen. Conclusion The clinical observations suggest that immune responses against MDA-laminin may be involved in the development of cardiovascular disease in humans. Furthermore, observations in mice provide evidence for the presence of aldehyde-modified laminin in atherosclerotic lesions and demonstrate that induction of an immune response against these structures is associated with activation of Th17 cells, reduced fraction of Tregs and a more aggressive development of atherosclerosis.