A Concise Asymmetric Total Synthesis of (+)-Epilupinine

Dipole-Transmissive 1,3-Dipolar Cycloadditions: Modular, Diversity-Oriented Synthesis of Polycyclic Alkaloid Scaffolds

This report establishes dipole-transmissive 1,3-dipolar cycloaddition methodology that enables the rapid, modular, and diastereoselective construction of privileged alkaloid scaffolds via a diversity-oriented synthetic strategy. In addition to furnishing assorted functionalized pyrrolizidine, indolizidine, quinolizidine, and pyrazoline frameworks from simple building blocks, these tools facilitated formal syntheses of alkaloid natural products isoretronecanol, elaeokanine A, and grandisine D.

New Analytical Approach to Quinolizidine Alkaloids and Their Assumed Biosynthesis Pathways in Lupin Seeds

Alkaloids play an essential role in protecting plants against herbivores. Humans can also benefit from the pharmacological effects of these compounds. Plants produce an immense variety of structurally different alkaloids, including quinolizidine alkaloids, a group of bi-, tri-, and tetracyclic compounds produced by Lupinus species. Various lupin species produce different alkaloid profiles. To study the composition of quinolizidine alkaloids in lupin seeds, we collected 31 populations of two wild species native to Israel, L. pilosus and L. palaestinus, and analyzed their quinolizidine alkaloid contents. Our goal was to study the alkaloid profiles of these two wild species to better understand the challenges and prospective uses of wild lupins. We compared their profiles with those of other commercial and wild lupin species. To this end, a straightforward method for extracting alkaloids from seeds and determining the quinolizidine alkaloid profile by LC-MS/MS was developed and validated in-house. For the quantification of quinolizidine alkaloids, 15 analytical reference standards were used. We used GC-MS to verify and cross-reference the identity of certain alkaloids for which no analytical standards were available. The results enabled further exploration of quinolizidine alkaloid biosynthesis. We reviewed and re-analyzed the suggested quinolizidine alkaloid biosynthesis pathway, including the relationship between the amino acid precursor l-lysine and the different quinolizidine alkaloids occurring in seeds of lupin species. Revealing alkaloid compositions and highlighting some aspects of their formation pathway are important steps in evaluating the use of wild lupins as a novel legume crop.