Seven-membered ring “septanose” sugars have been used as surrogates of pyranoses in biochemical investigations. Septanoses are homologs of pyranoses in the same way that beta amino acids are for alpha amino acids or hexose nucleosides for deoxyribose nucleosides. Methods for their synthesis have undergone significant development recently, following two complementary strategies. In one, glycals are cyclopropanated which are later opened in addition reactions with nucleophiles. The other follows traditional glycosylation strategies where electrophilic donors are prepared and reacted with nucleophiles. Unsaturated seven membered ring oxepines play a key role in both of the approaches, which are highlighted.

Shape is an inherent trait of a molecule that dictates how it interacts with other molecules, either in binding events or intermolecular reactions. Large-ring macrocyclic compounds in particular leverage their shape when they are selectively bound by biomolecules and also when they exhibit macrocyclic diastereoselectivity. Nonetheless, rules that link structural parameters to the conformation of a macrocycle are still rudimentary. Here we use a structural investigation of a family of [13]-macrodilactones as a case study to develop rules that can be applied generally to macrocycles of different sizes and with a variety of functionality. A characteristic “ribbon” shape is adopted by the [13]-macrodilactones in the absence of stereogenic centres, which exhibits planar chirality. When one stereogenic centre at key positions on the backbone is incorporated into the structure, the planar chirality is dictated by the configuration of the centre. In cases where two stereogenic centres are present, their relationships can either reinforce the characteristic ribbon shape or induce alternative shapes to be adopted. The rules established in the case study are then applied to the analysis of a structure of the natural product migrastatin. They lay the groundwork for the development of models to understand macrocycle-biomolecule interactions and for the preparation of macrocycles with designed properties and activities.

Invited for this month's cover picture is the group of Professor Mark Peczuh at the University of Connecticut. The cover picture compares the rearrangement of a small molecule to the process of turning a stuffed animal inside out. The recycled, inside-out stuffed animals are both artistic and philosophically provocative. They capture the essence of the rearrangement reaction because the compounds themselves turn inside out over the course of the reaction, extending the diversity of products that can arise from simple starting materials. Small molecules often have functional groups with latent reactivity; under the appropriate conditions, those groups can react with other compounds (e.g., reagents) and also with other groups in the same molecule in an intramolecular reaction. The research team found that the epoxidation of some highly functionalized spiroketal compounds promoted rearrangements of their structures that turned them inside out. Some of the features of the products led them to use X-ray crystallography or a combination of computer-assisted structure elucidation, computation, and a new version of the 1,1-ADEQUATE NMR experiment to determine their structures. For more details, see the Communication on p. 577 ff.

Spiroketals organize small molecule structures into well-defined, three-dimensional configurations that make them good ligands of proteins. We recently discovered a tandem cycloisomerization–dimerization reaction of alkynyl hemiketals that delivered polycyclic, enol-ether-containing spiroketals. Here we describe rearrangements of those compounds, triggered by epoxidation of their enol ethers that completely remodel their structures, essentially turning them “inside out”. Due to the high level of substitution on the carbon skeletons of the substrates and products, characterization resorted to X-ray crystallography and advanced computation and NMR techniques to solve the structures of representative compounds. In particular, a new proton-detected ADEQUATE NMR experiment (1,1-HD-ADEQUATE) enabled the unequivocal assignment of the carbon skeleton of one of the new compounds. Solution of the structures of the representative compounds allowed for the assignment of product structures for the other compounds in two separate series. Both the rearrangement and the methods used for structural determination of the products are valuable tools for the preparation of characterization of new small molecule compounds.

A general strategy amenable to the strerocontrolled synthesis of complex, ring-expanded analogues of natural aminoglycosides has been developed. Central to the method is the utilization of septanosyl fluorides as glycosyl donors in facile and selective glycosylation reactions. The septanosyl fluorides proved to be the best choice for the glycosylations because of their accessibility and the scope of aglycones that they could glycosylate. Moreover, a high degree of stereoselectivity was observed in the glycosylations, exclusively giving 1,2-trans-glycosides. 2-Amino septanosyl fluorides were prepared from D-glucose, D-galactose, and D-mannose. Other routes to the septanosyl glyconjugates, especially with regard to alternate donor types, were systematically investigated. Since routes to the individual donor types were being explored, factors that exert a controlling influence on the acid-mediated cyclization of 1,6-hydroxy-aldehydes were determined. The newly prepared 2-amino septanosyl glycoconjugates illustrate the scope of the reaction and how it may be utilized for the preparation of other ring-expanded analogues of glycosylated natural products.