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Application Area

Fmoc-L-aspartic acid β-methylpentyl ester

* Please kindly note that our products are not to be used for therapeutic purposes and cannot be sold to patients.

Category

Fmoc-Amino Acids

Catalog number

BAT-007671

CAS number

180675-08-5

Molecular Formula

C25H29NO6

Molecular Weight

439.51

Fmoc-L-aspartic acid β-methylpentyl ester

IUPAC Name

(2S)-2-(9H-fluoren-9-ylmethoxycarbonylamino)-4-(3-methylpentan-3-yloxy)-4-oxobutanoic acid

Synonyms

Fmoc-Asp-OMpe; Fmoc-L-Asp(OMpe)-OH; (S)-3-(Fmoc-amino)-4-(4-methylpentyloxy)-4-oxobutyric acid; Fmoc-Asp(Ompe)-OH; N-(9H-Fluoren-9-ylmethoxycarbonyl)-L-aspartic acid 4-(1-methyl-1-ethylpropyl) ester; N-alpha-(9-Fluorenylmethoxycarbonyl)-L-aspartic acid beta-3-methylpent-3-yl ester

Appearance

White to off-white powder

Purity

≥95% by HPLC

Density

1.214±0.06 g/cm3 (Predicted)

Melting Point

100-104 °C

Boiling Point

635.9±55.0°C (Predicted)

Storage

Store at 2-8°C

InChI

InChI=1S/C25H29NO6/c1-4-25(3,5-2)32-22(27)14-21(23(28)29)26-24(30)31-15-20-18-12-8-6-10-16(18)17-11-7-9-13-19(17)20/h6-13,20-21H,4-5,14-15H2,1-3H3,(H,26,30)(H,28,29)/t21-/m0/s1

InChI Key

SYGKUYKLHYQKPL-NRFANRHFSA-N

Canonical SMILES

CCC(C)(CC)OC(=O)CC(C(=O)O)NC(=O)OCC1C2=CC=CC=C2C3=CC=CC=C13

Fmoc-L-aspartic acid β-methylpentyl ester, a chemical reagent commonly employed in peptide synthesis and various biochemical applications, is versatile and finds applications in different fields. Let’s explore four key applications with high perplexity and burstiness:

Peptide Synthesis: In the realm of solid-phase peptide synthesis, Fmoc-L-aspartic acid β-methylpentyl ester plays a pivotal role. Serving as a shielded version of aspartic acid, it seamlessly integrates into evolving peptide chains. The Fmoc protective group shields the amino acid from unintended reactions during synthesis, ensuring meticulous and effective peptide assembly.

Drug Development: In the dynamic landscape of pharmaceutical research, Fmoc-L-aspartic acid β-methylpentyl ester is a cornerstone in crafting peptide-based drugs. Its stable integration into peptide sequences enhances their pharmacokinetic properties, empowering researchers to engineer peptides with heightened therapeutic potential. These peptides pave the way for novel treatments targeting diverse ailments, from cancer to metabolic disorders.

Structural Biology: Delving into the intricate realm of protein structure and function, Fmoc-L-aspartic acid β-methylpentyl ester emerges as a valuable tool in synthetic peptide studies. By infusing this modified aspartic acid into peptides, scientists unlock insights into protein-protein interactions, enzyme-substrate specificity, and receptor binding dynamics. This wealth of information is essential for deciphering complex biological mechanisms and crafting innovative biomolecules.

Bioconjugation: At the intersection of bioconjugation techniques, Fmoc-L-aspartic acid β-methylpentyl ester shines as a key player in linking peptides to diverse biomolecules and surfaces. This tailored amino acid seamlessly integrates into peptides destined for attachment to proteins, nanoparticles, or sensors. Such bioconjugates find applications in diagnostics, targeted drug delivery, and biosensing technologies.

1. Boronate-Based Fluorescent Probes as a Prominent Tool for H2O2 Sensing and Recognition

Ling Wang, Xuben Hou, Hao Fang, Xinying Yang Curr Med Chem. 2022;29(14):2476-2489. doi: 10.2174/0929867328666210902101642.

Given the crucial association of hydrogen peroxide with a wide range of human diseases, this compound has currently earned the reputation of being a popular biomolecular target. Although various analytical methods have attracted our attention, fluorescent probes have been used as prominent tools to determine H2O2 to reflect the physiological and pathological conditions of biological systems. The sensitive responsive part of these probes is the boronate ester and boronic acid groups, which are important reporters for H2O2 recognition. In this review, we summarize boronate ester/boronic acid group-based fluorescent probes for H2O2 reported from 2012 to 2020, and we have generally classified the fluorophores into six categories to exhaustively elaborate the design strategy and comprehensive systematic performance. We hope that this review will inspire the exploration of new fluorescent probes based on boronate ester/boronic acid groups for the detection of H2O2 and other relevant analytes.

2. Tris(pentafluorophenyl)borane-Catalyzed Reactions Using Silanes

Taylor Hackel, Nicholas A McGrath Molecules. 2019 Jan 25;24(3):432. doi: 10.3390/molecules24030432.

The utility of an electron-deficient, air stable, and commercially available Lewis acid tris(pentafluorophenyl)borane has recently been comprehensively explored. While being as reactive as its distant cousin boron trichloride, it has been shown to be much more stable and capable of catalyzing a variety of powerful transformations, even in the presence of water. The focus of this review will be to highlight those catalytic reactions that utilize a silane as a stoichiometric reductant in conjunction with tris(pentafluorophenyl) borane in the reduction of alcohols, carbonyls, or carbonyl-like derivatives.

3. Photocatalytic direct borylation of carboxylic acids

Qiang Wei, Yuhsuan Lee, Weiqiu Liang, Xiaolei Chen, Bo-Shuai Mu, Xi-Yang Cui, Wangsuo Wu, Shuming Bai, Zhibo Liu Nat Commun. 2022 Nov 19;13(1):7112. doi: 10.1038/s41467-022-34833-1.

The preparation of high value-added boronic acids from cheap and plentiful carboxylic acids is desirable. To date, the decarboxylative borylation of carboxylic acids is generally realized through the extra step synthesized redox-active ester intermediate or in situ generated carboxylic acid covalent derivatives above 150 °C reaction temperature. Here, we report a direct decarboxylative borylation method of carboxylic acids enabled by visible-light catalysis and that does not require any extra stoichiometric additives or synthesis steps. This operationally simple process produces CO2 and proceeds under mild reaction conditions, in terms of high step economy and good functional group compatibility. A guanidine-based biomimetic active decarboxylative mechanism is proposed and rationalized by mechanistic studies. The methodology reported herein should see broad application extending beyond borylation.