3-Maleimidopropionic acid

Glucagon-like peptide-1 (GLP-1) receptor agonists modified with albumin ligands which can specificity bind to the human serum albumin (HSA) was an efficient strategy to prolong the half-time of GLP-1. Herein, we investigated the effect of small-molecule albumin ligand modification on the hypoglycemic activities of GLP-1 derivatives. Two GLP-1 derivatives MPA-C12-GLP-1 and Rhein-C12-GLP-1 were achieved by modification of the side chain amino of lysine in position 26 of the Arg34-GLP-1(7-37)-OH with Rhein and 3-Maleimidopropionic acid respectively using 12-aminolauric acid as a linker, and its specific albumin-conjugating characteristics, pharmaceutical characterization, and the antidiabetic effects were investigated. In vitro level, two GLP-1 derivatives demonstrated a higher binding capacity to GLP-1 receptor than that of Arg34-GLP-1(7-37)-OH. Interestingly, although the binding ability of MPA-C12-GLP-1 was equal to liraglutide, the binding ability of Rhein-C12-GLP-1 was 10-fold higher than liraglutide. In vivo level, the two GLP-1 derivatives can significantly increase their glucose tolerance and prolong their half-life in ICR mice, and they were also superior to GLP-1 in controlling glucose homeostasis and suppression of food intake and water consumption in db/db mice. Importantly, the two GLP-1 derivatives showed comparable efficacy to liraglutide for the therapy of type 2 diabetes mellitus. The in vitro INS-1 cells toxicity and the in vivo hepatotoxicity indicated that the Rhein-C12-GLP-1 was a safe candidate for the therapy of type 2 diabetes, and the serum biomarkers determination results showed that the Rhein-modified GLP-1 could significantly improve the HbA1c and blood lipids, and the H&E stain exhibited that the Rhein-C12-GLP-1 can effectively promote β-cell proliferation and differentiation. In conclusion, the 3-Maleimidopropionic acid or Rhein-modified GLP-1derivatives have great potential for development as a Type 2 diabetes mellitus therapeutic drug.

Hydrogen sulfide (H2S) is endogenously produced by enzymes and via reactive persulfide/polysulfide degradation; it participates in a variety of biological processes under physiological and pathological conditions. H2S levels in biological fluids, such as plasma and serum, are correlated with the severity of various diseases. Therefore, development of a simple and selective H2S measurement method would be advantageous. This study aimed to generate antibodies specifically recognizing H2S derivatives and develop a colorimetric immunoassay for measuring H2S in biological samples. We used N-ethylmaleimide (NEM) as an H2S detection agent that forms a stable bis-S-adduct (NEM-S-NEM). We also prepared bis-S-heteroadduct with 3-maleimidopropionic acid, which, in conjugation with bovine serum albumin, was to immunize Japanese white rabbits and Wistar rats to enable generation of polyclonal and monoclonal antibodies, respectively. The generated antibodies were evaluated by competitive enzyme-linked immunosorbent assay. We could obtain two stable hybridoma cell lines producing monoclonal antibodies specific for NEM-S-NEM. By immunoassay with the monoclonal antibody, the H2S level in mouse plasma was determined as 0.2 μM, which was identical to the level detected by mass spectrometry. Taken together, these monoclonal antibodies can be a useful tool for a simple and highly selective immunoassay to detect H2S in biological samples.

An oxidase-based glucose sensor has been developed that uses a mercaptosilane-modified platinum electrode to achieve selectivity of electrochemical interferants. A platinum-iridium (9:1) wire (0.178 mm o.d., sensing area of 1.12 mm2) is modified with (3-mercaptopropyl)trimethoxysilane. The modified sensors show excellent operational stability for more than 5 days. Glucose oxidase is immobilized on the modified surface (i) by using 3-maleimidopropionic acid as a linker or (ii) by cross-liking with bovine serum albumin using glutaraldehyde. Sensitivities in the range of 9.97 nA/mM glucose are observed when the enzyme is immobilized by method ii. Lower sensitivities (1.13 x 10(-1) nA/mM glucose) are observed when immobilization method i is employed. In terms of linear response range, the sensor enzyme-immobilized by method i is superior to that immobilized by method ii. The linearity is improved upon coating the enzyme layer with polyurethane. The sensor immobilized by method ii and coated with polyurethane exhibits a linear range to 15 mM glucose and excellent selectivity to glucose (0.47 nA/mM) against interferants such as ascorbic acid, uric acid, and acetaminophen.