Glycosyl cations are universally accepted key ionic intermediates in the mechanism of glycosylation, the reaction that covalently links carbohydrates to other molecules. These ions have remained hypothetical species so far because of their extremely short life in organic media as a consequence of their very high reactivity. Here, we report the use of liquid hydrofluoric acid-antimony pentafluoride (HF/SbF5) superacid to generate and stabilize the glycosyl cations derived from peracetylated 2-deoxy and 2-bromoglucopyranose in a condensed phase. Their persistence in this superacid medium allows their three-dimensional structure to be studied by NMR, aided by complementary computations. Their deuteration further confirms the impact of the structure of the glycosyl cation on the stereochemical outcome of its trapping.
The broad application of well-defined
synthetic oligosaccharides
in glycobiology and glycobiotechnology is largely hampered by the
lack of sufficient amounts of synthetic carbohydrate specimens. Insufficient
knowledge of the glycosylation reaction mechanism thwarts the routine
assembly of these materials. Glycosyl cations are key reactive intermediates
in the glycosylation reaction, but their high reactivity and fleeting
nature have precluded the determination of clear structure–reactivity-stereoselectivity
principles for these species. We report a combined experimental and
computational method that connects the stereoselectivity of oxocarbenium
ions to the full ensemble of conformations these species can adopt,
mapped in conformational energy landscapes (CEL), in a quantitative
manner. The detailed description of stereoselective S
N
1-type
glycosylation reactions firmly establishes glycosyl cations as true
reaction intermediates and will enable the generation of new stereoselective
glycosylation methodology.
The neamine part of the aminoglycoside antibiotic neomycin B was conjugated to a 16 mer peptide nucleic acid (PNA) targeting HIV-1 TAR RNA. Attachment of the neamine core allows cellular uptake of the PNA and results in potent inhibition of HIV-1 replication. The polycationic neamine moiety imparts greater solubility to the PNA and also confers a unique RNA cleavage property to the conjugate which is specific to its target site and functional at physiological concentrations of Mg(2+). These properties suggest a potential therapeutic application for this class of compounds.
In earlier studies, we found that a conjugate of neamine-polyamide nucleic acid targeting transactivation response element of HIV-1 RNA genome (HIV-1 TAR) displayed anti-HIV-1 activity and sequence-specific cleavage of the target RNA in vitro. Here we show that both the position of conjugation of polyamide nucleic acid (PNA) on neamine and the length of the spacer are critical parameters for conferring cleavage activity to the conjugate. The conjugation of PNA via a spacer incorporating 11 atoms to the 5-position of ring I of the neamine core conferred sequence-specific RNA cleavage activity on the conjugate, while conjugation to the 4'-position of ring II abolished this activity. Similarly, 5-neamine PNA complementary to TAR sequence of HIV-1 genome (PNA(TAR)) conjugates having either a 23-atom spacer or a bulky dansyl group between PNA and the neamine core also resulted in complete loss of cleavage activity. Based on these observations, we propose a mechanism for the observed RNA cleavage catalyzed by the conjugate involving unprotonated and protonated amino groups at the 3-position of ring I and the 6'-position of ring II of the neamine core, respectively.
Aminoglycosides (AGs) constitute a major family of potent and broad-spectrum antibiotics disturbing protein synthesis through binding to the A site of 16S rRNA. Decades of widespread clinical use of AGs strongly reduced their clinical efficacy through the selection of resistant bacteria. Recently, conjugation of lipophilic groups to AGs generated a novel class of potent antibacterial amphiphilic aminoglycosides (AAGs) with significant improved activities against various sensitive and resistant bacterial strains. We have identified amphiphilic 3',6-dialkyl derivatives of the small aminoglycoside neamine as broad spectrum antibacterial agents targeting bacterial membranes. Here, we report on the synthesis and the activity against sensitive and resistant Gram-negative and/or Gram-positive bacteria of new amphiphilic 3',4'-dialkyl neamine derivatives and of their smaller analogues in the 6-aminoglucosamine (neosamine) series prepared from N-acetylglucosamine.
In this work, a target-specific aptamer chiral stationary phase (CSP) based on the oligonucleotidic selector binding to silica particles through a covalent linkage was developed. An anti-D-adenosine aptamer was coupled, using an in-situ method, by way of an amide bond to macroporous carboxylic acid based silica. Frontal chromatography analysis was performed to evaluate the column properties, i.e., determination of the stationary phase binding capacity and the dissociation constant of the target-immobilized aptamer complex. It was found that such covalent immobilization was able to maintain the aptamer binding properties at a convenient level for an efficient enantioseparation. Subsequently, the separation of adenosine enantiomers was investigated under different operating conditions, including changes in the eluent's ionic strength and the proportion of organic modifiers as well as column temperatures. It was demonstrated that, under various conditions of use and storage, the present CSP was stable over time.
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