Substrate (chemistry)

About: Substrate (chemistry) is a research topic. Over the lifetime, 35902 publications have been published within this topic receiving 740722 citations. The topic is also known as: enzyme substrate.

Distribution and properties of angiotensin converting enzyme of rat brain

Abstract: — Angiotensin converting enzyme of rat brain was studied using Hip-His-Leu as substrate. The highest specific activity of the enzyme was associated with the microsomal fraction. The specific activity of the microsomal enzyme in several regions of the rat brain varied significantly. For example, the specific activities of the striatal and pituitary enzymes were about 10-fold greater than that of the cerebral cortical enzyme. The enzyme required chloride ion; moreover, activity was inhibited in the presence of disodium EDTA or O-phenanthroline, effects suggesting that the converting enzyme of brain is a metalloprotein. SQ-20881, a nonapeptide that inhibits converting enzyme in peripheral tissue, was a potent inhibitor of the enzyme of brain. In addition to Hip-His-Leu, the microsomal fraction was capable of liberating C terminal dipeptides from angiotensin I, Hip-Gly-Gly and Z-Gly- Gly-Val. The broad substrate specificity of the enzyme suggests that, in addition to the possible contribution of the enzyme to the brain renin-angiotensin system, other naturally occurring peptides might also be substrates for the enzyme.

Evidence for a Unique Chain Organization in Long Chain Silane Monolayers Deposited on Two Widely Different Solid Substrates

Abstract: We address the longstanding issue of substrate effects in alkylsiloxane monolayer self-assembly. With proper substrate prehydration, we observe formation of identical quality, compact, quasi-crystalline monolayers on oxidized silicon and gold substrates with widely different chemical character, the former capable of covalent bonding to the adsorbed molecules via silanol groups and the latter devoid of reactive surface sites. Infrared spectroscopy, ellipsometry, and wetting measurements show identical average film structures consisting of highly extended chains tilted at 10 (±2)° with significant end-gauche defect content. This observed substrate independence is consistent with our previous hypothesis that substrate-bound water promotes the decoupling of the organic film from the underlying solid surface.

Purification and partial characterization of thermostable serine alkaline protease from a newly isolated Bacillus subtilis PE-11.

Abstract: The purpose of the research was to study the purification and partial characterization of thermostable serine alkaline protease from a newly isolatedBacillus subtilis PE-11. The enzyme was purified in a 2-step procedure involving ammonium sulfate precipitation and Sephadex G-200 gel permeation chromatography. The enzyme was shown to have a relative low molecular weight of 15 kd by sodium dodecyl sulphate polyacrylamide gel electrophoresis (SDS-PAGE) and was purified 21-fold with a yield of 7.5%. It was most active at 60°C, pH 10, with casein as substrate. It was stable between pH 8 and 10. This enzyme was almost 100% stable at 60°C even after 350 minutes of incubation. It was strongly activated by metal ions such as Ca2+, Mg+2, and Mn+2. Enzyme activity was inhibited strongly by phenylmethyl sulphonyl fluoride (PMSF) and diisopropyl fluorophosphates (DFP) but was not inhibited by ethylene diamine tetra acetic acid (EDTA), while a slight inhibition was observed with iodoacetate,p-chloromercuric benzoate (pCMB), and β-mercaptoethanol (β-ME). The compatibility of the enzyme was studied with commercial and local detergents in the presence of 10mM CaCl2 and 1M glycine. The addition of 10mM CaCl2 and 1M glycine, individually and in combination, was found to be very effective in improving the enzyme stability where it retained 52% activity even after 3 hours. This enzyme improved the cleansing power of various detergents. It removed blood stains completely when used with detergents in the presence of 10mM CaCl2 and 1M glycine.

Catalyst-Controlled Aliphatic C–H Oxidations with a Predictive Model for Site-Selectivity

Abstract: Selective aliphatic C-H bond oxidations may have a profound impact on synthesis because these bonds exist across all classes of organic molecules. Central to this goal are catalysts with broad substrate scope (small-molecule-like) that predictably enhance or overturn the substrate’s inherent reactivity preference for oxidation (enzyme-like). We report a simple small-molecule, non-heme iron catalyst that achieves predictable catalyst-controlled site-selectivity in preparative yields over a range of topologically diverse substrates. A catalyst reactivity model quantitatively correlates the innate physical properties of the substrate to the site-selectivities observed as a function of the catalyst.