Intracellular Delivery via Noncharged Sequence-Defined Cell-Penetrating Oligomers.

Intracellular drug delivery systems are often limited by their poor serum stability and delivery efficiency. Cell-penetrating peptides (CPPs), particularly those derived from basic protein subunits, have been studied extensively in this regard and used for the delivery of a variety of cargoes in vitro. Although promising, traditional cationic CPPs have some drawbacks that hinder their therapeutic application such as rapid proteolytic degradation and undesired interactions with the biological milieu. To overcome these limitations, this article details the discovery of a new class of noncharged cell-penetrating oligoTEAs (CPOTs) that undergo extensive and rapid cellular entry across different cell lines with low cytotoxicity. CPOTs outperform a widely used CPP, R9 peptide. This new class of highly efficient noncharged macromolecular transporters are distinct from their cationic counterparts and show strong promise for the intracellular delivery of hydrophilic small-molecule therapeutics.

Effect of Composition on Antibacterial Activity of Sequence-Defined Cationic Oligothioetheramides.

In response to the urgent need for new antibiotic development strategies, antimicrobial peptides and their synthetic mimetics are being investigated as promising alternatives to traditional antibiotics. To facilitate their development into clinically viable candidates, we need to understand what molecular features and physicochemical properties are needed to induce cell death. Within the context of sequence-defined oligothioetheramides (oligoTEAs), we explore the impact of the cationic pendant group and backbone hydrophobicity on the potency and selectivity of antibacterial oligoTEAs. Through antibacterial, cytotoxicity, membrane destabilization, and membrane depolarization assays, we find a strong dependency on the nature of the cationic group and improved selectivity toward bacteria by tuning backbone hydrophobicity. In particular, compounds with the guanidinium headgroup are more potent than those with amines. Finally, we identify a promising oligoTEA, PDT-4G, with enhanced activity in vitro (minimum inhibitory concentration (MIC) ∼ 0.78 µM) and moderate activity in a mouse thigh infection model of methicillin-resistant Staphylococcus aureus. The studies outlined in this work provide insights into the effect of macromolecular physicochemical properties on antibacterial potency. This knowledge base will be vital for researchers engaged in the ongoing development of clinically viable antibacterial agents.

Sequence-defined bioactive macrocycles via an acid-catalysed cascade reaction.

Synthetic macrocycles derived from sequence-defined oligomers are a unique structural class whose ring size, sequence and structure can be tuned via precise organization of the primary sequence. Similar to peptides and other peptidomimetics, these well-defined synthetic macromolecules become pharmacologically relevant when bioactive side chains are incorporated into their primary sequence. In this article, we report the synthesis of oligothioetheramide (oligoTEA) macrocycles via a one-pot acid-catalysed cascade reaction. The versatility of the cyclization chemistry and modularity of the assembly process was demonstrated via the synthesis of >20 diverse oligoTEA macrocycles. Structural characterization via NMR spectroscopy revealed the presence of conformational isomers, which enabled the determination of local chain dynamics within the macromolecular structure. Finally, we demonstrate the biological activity of oligoTEA macrocycles designed to mimic facially amphiphilic antimicrobial peptides. The preliminary results indicate that macrocyclic oligoTEAs with just two-to-three cationic charge centres can elicit potent antibacterial activity against Gram-positive and Gram-negative bacteria.

Fatty acid synthesis enzyme clans.

Ketoacyl reductases (KRs), hydroxyacyl dehydratases (HDs), and enoyl reductases (ERs) are part of the fatty acid/polyketide synthesis cycle. They are known as acyl dehydrogenases, enoyl hydratases, and hydroxyacyl dehydrogenases, respectively, when catalyzing their reverse reactions. Earlier, we classified these enzymes into four KR, eight HD, and five ER families by statistical criteria. Members of all four KR families and three ER families have Rossmann folds, while five HD family members have HotDog folds. This suggests that those proteins with the same folds in different families may be distantly related, and therefore in clans, even though their amino acid sequences may not be homologous. We have now defined two clans containing three of the four KR families and two of the eight HD families, using manual and statistical tests. One of the ER families is related to the KR clan.

Carbohydrate-binding module tribes.

At present, 69 families of carbohydrate-binding modules (CBMs) have been isolated by statistically significant differences in the amino acid sequences (primary structures) of their members, with most members of different families showing little if any homology. On the other hand, members of the same family have primary and tertiary (three-dimensional) structures that can be computationally aligned, suggesting that they are descended from common protein ancestors. Members of the large majority of CBM families are ß-sandwiches. This raises the question of whether members of different families are descended from distant common ancestors, and therefore are members of the same tribe. We have attacked this problem by attempting to computationally superimpose tertiary structure representatives of each of the 53 CBM families that have members with known tertiary structures. When successful, we have aligned locations of secondary structure elements and determined root mean square deviations and percentages of similarity between adjacent amino acid residues in structures from similar families. Further criteria leading to tribal membership are amino acid chain lengths and bound ligands. These considerations have led us to assign 27 families to nine tribes. Eight of the tribes have members with ß-sandwich structures, while the ninth is composed of structures with ß-trefoils.