Staphylococcus aureus (S. aureus) is an asymptomatic colonizer of 30% of all human beings. It is also the most dangerous of all Staphylococcal bacteria.
Alongside
Edward, Lemieux was among the earliest researchers studying
negative hyperconjugation (i.e., the anomeric effect) or the preference
for gauche conformations about the C1–O5 bond in carbohydrates.
Lemieux also studied an esoteric, if not controversial, theory known
as the reverse anomeric effect (RAE). This theory is used to rationalize
scenarios where predicted anomeric stabilization does not occur. One
such example is the Kochetkov amination where reducing end amines
exist solely as the β-anomer. Herein, we provide a brief account
of Lemieux’s contributions to the field of stereoelectronics
and apply this knowledge toward the synthesis of β-amino human
milk oligosaccharides (βΑ-HMOs). These molecules were
evaluated for their ability to inhibit growth and biofilm production
in Group B Streptococcus (GBS) and Staphylococcus aureus. While the parent HMOs lacked antimicrobial and antibiofilm activity,
their β-amino derivatives significantly inhibited biofilm formation
in both species. Field emission gun-scanning single electron microscopy
(FEG-SEM) revealed that treatment with β-amino HMOs significantly
inhibits bacterial adherence and eliminates the ability of both microbes
to form biofilms.
Zwitterionic carbohydrate modifications, such as phosphoethanolamine (PEtN), govern host−pathogen interactions. Whereas it is recognized that these modifications stimulate the host immune system, the purpose of PEtN modification remains largely descriptive. As an enabling step toward studying this carbohydrate modification, we report a synthesis of the P. temperata zwitterionic trisaccharide repeating unit. The 32-step synthesis was enabled by H-phosphonate chemistry to install the PEtN arm on a poorly reactive and sterically hindered C4alcohol.Letter pubs.acs.org/OrgLett
Chemical synthesis of natural products is typically inspired by the structure and function of a target molecule. When both factors are of interest, such as in the case of taxane diterpenoids, a synthesis can both serve as a platform for synthetic strategy development and enable new biological exploration. Guided by this paradigm, we present here a unified enantiospecific approach to diverse taxane cores from the feedstock monoterpenoid (S)-carvone. Key to the success of our approach was the use of a skeletal remodeling strategy which began with the divergent reorganization and convergent coupling of two carvonederived fragments, facilitated by Pd-catalyzed C−C bond cleavage tactics. This coupling was followed by additional restructuring using a Sm(II)-mediated rearrangement and a bioinspired, visiblelight induced, transannular [2 + 2] photocycloaddition. Overall, this divergent monoterpenoid remodeling/convergent fragment coupling approach to complex diterpenoid synthesis provides access to structurally disparate taxane cores which have set the stage for the preparation of a wide range of taxanes.
The catalytic enantioselective synthesis of αchiral alkenes and alkynes represents a powerful strategy for rapid generation of molecular complexity. Herein, we report a transient directing group (TDG) strategy to facilitate site-selective palladium-catalyzed reductive Heck-type hydroalkenylation and hydroalkynylation of alkenylaldehyes using alkenyl and alkynyl bromides, respectively, allowing for construction of a stereocenter at the δ-position with respect to the aldehyde. Computational studies reveal the dual beneficial roles of rigid TDGs, such as L-tert-leucine, in promoting TDG binding and inducing high levels of enantioselectivity in alkene insertion with a variety of migrating groups.
The catalytic enantioselective synthesis of α-chiral alkenes and alkynes represents a powerful strategy for rapid generation of molecular complexity. Herein, we report a transient directing group facilitated site-selective palladium-catalyzed reductive Heck-type hydroalkenylation and hydroalkynylation of alkenylaldehyes using alkenyl and alkynyl bromides, respectively, allowing for construction of a stereocenters at the δ position with respect to the aldehyde.
Urinary tract infections (UTIs) are caused by bacteria growing in complex, multicellular enclosed aggregates known as biofilms. Recently, a zwitterionic cellulose derivative produced in Escherichia coli (E. coli) was determined to play an important role in the formation and assembly of biofilms. In order to produce a minimal, yet structurally defined tool compound to probe the biology of the naturally occurring polymer, we have synthesized a zwitterionic phosphoethanolamine cellobiose (pEtN cellobiose) and evaluated its biofilm activity in the Gram‐negative bacterium E. coli, a pathogen implicated in the pathogenesis of UTIs. The impact of synthetic pEtN cellobiose on biofilm formation was examined via colorimetric assays which revealed an increase in cellular adhesion to an abiotic substrate compared to untreated samples. Additionally, Congo red binding assays indicate that culturing E. coli in the presence of pEtN cellobiose enhances Congo Red binding to bacterial cells. These results reveal new opportunities to study the impact glycopolymers have on cellular adhesion in Gram‐negative pathogens.
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