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Multicomponent reactions (MCRs) encompass an exciting class of chemical transformations that have proven success in almost all fields of synthetic organic chemistry. These convergent procedures incorporate three or more reactants into a final product in one pot, thus combining high levels of complexity and diversity generation with low synthetic cost. Striking applications of these processes are found in heterocycle, peptidomimetic, and natural product syntheses. However, their potential in the preparation of large macro- and biomolecular constructs has been realized just recently. This Account describes the most relevant results of our group in the utilization of MCRs for ligation/conjugation of biomolecules along with significant contributions from other laboratories that validate the utility of this special class of bioconjugation process. Thus, MCRs have proven to be efficient in the ligation of lipids to peptides and oligosaccharides as well as the ligation of steroids, carbohydrates, and fluorescent and affinity tags to peptides and proteins. In the field of glycolipids, we highlight the power of isocyanide-based MCRs with the one-pot double lipidation of glycan fragments functionalized as either the carboxylic acid or amine. In peptide chemistry, the versatility of the multicomponent ligation strategy is demonstrated in both solution-phase lipidation protocols and solid-phase procedures enabling the simultaneous lipidation and biotinylation of peptides. In addition, we show that MCRs are powerful methods for synchronized lipidation/labeling and macrocyclization of peptides, thus accomplishing in one step what usually requires long sequences. In the realm of protein bioconjugation, MCRs have also proven to be effective in labeling, site-selective modification, immobilization, and glycoconjugation processes. For example, we illustrate a successful application of multicomponent polysaccharide-protein conjugation with the preparation of multivalent glycoconjugate vaccine candidates by the ligation of two antigenic capsular polysaccharides of a pathogenic bacterium to carrier proteins. By highlighting the ability to join several biomolecules in only one synthetic operation, we hope to encourage the biomolecular chemistry community to apply this powerful chemistry to novel biomedicinal challenges.
Peptide
stapling is traditionally used to lock peptide conformations
into α-helical structures using a variety of macrocyclization
chemistries. In an endeavor to add a diversity-generating tool to
this repertoire, we introduce a multicomponent stapling approach enabling
the simultaneous stabilization of helical secondary structures and
the exocyclic N-functionalization of the side chain-tethering
lactam bridge. This is accomplished by means of a novel solid-phase
methodology comprising, for the first time, the on-resin Ugi reaction-based
macrocyclization of peptide side chains bearing amino and carboxylic
acid groups. The exocyclic diversity elements arise from the isocyanide
component used in the Ugi multicomponent stapling protocol, which
allows for the incorporation of relevant fragments such as lipids,
sugars, polyethylene glycol, fluorescent labels, and reactive handles.
We prove the utility of such exocyclic reactive groups in the bioconjugation
of a maleimide-armed lactam-bridged peptide to a carrier protein.
The on-resin multicomponent stapling proved efficient for the installation
of not only one, but also two consecutive lactam bridges having either
identical or dissimilar N-functionalities. The easy access to helical
peptides with a diverse set of exocyclic functionalities shows prospect
for applications in peptide drug discovery and chemical biology.
The development of prophylactic vaccines at unprecedented speed is necessary to control the global pandemic due to SARS CoV 2 infection. Vaccines approved for use and those under development intend to block viral sites binding to the hosts cellular receptors by means of neutralizing antibodies. Virus infection is mediated by the spike glycoprotein trimer on the virion surface via its receptor binding domain (RBD). Antibody response against this domain is an important outcome of the immunization and correlates well with viral neutralization. Here we show that macromolecular constructs with recombinant RBD conjugated to tetanus toxoid induce a potent immune response in laboratory animals. Some advantages of the immunization with the viral antigen coupled to tetanus toxoid have become evident such as predominantly IgG immune response due to affinity maturation and long term specific B memory cells. This work demonstrates that subunit conjugate vaccines can be an alternative for COVID19 paving the way for other viral conjugate vaccines based on the use of small viral proteins involved in the infection process.
The diversity-oriented synthesis of novel bis-spirostanic conjugates utilizing two different Ugi four-component reactions (Ugi-4CR) is described. Spirostanic steroids were functionalized with Ugi-reactive groups, that is, amines, isocyanides, and carboxylic acids, and next were subjected to multicomponent ligation approaches leading to bis-steroidal conjugates featuring pseudo-peptidic and heterocyclic linkage moieties. Both the classic Ugi-4CR and its hydrazoic acid variant were implemented, proving good efficiency for the ligation of isocyanosteroids to spirostanic acids and equatorial amines. Axially oriented amines showed poorer results, although model studies proved that chemical efficiency could be significantly improved while increasing reaction times. Overall, the method comprises the rapid generation of molecular diversity at the bis-steroid linkage moiety and, consequently, shows promise toward the production of combinatorial libraries of bis-spirostanes for biological screening.
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