The discovery and enhanced properties of trichain lipids in lipopolyplex gene delivery systems.

The formation of a novel trichain (TC) lipid was discovered when a cationic lipid possessing a terminal hydroxyl group and the helper lipid dioleoyl l-α-phosphatidylethanolamine (DOPE) were formulated as vesicles and stored. Importantly, the transfection efficacies of lipopolyplexes comprised of the TC lipid, a targeting peptide and DNA (LPDs) were found to be higher than when the corresponding dichain (DC) lipid was used. To explore this interesting discovery and determine if this concept can be more generally applied to improve gene delivery efficiencies, the design and synthesis of a series of novel TC cationic lipids and the corresponding DC lipids was undertaken. Transfection efficacies of the LPDs were found to be higher when using the TC lipids compared to the DC analogues, so experiments were carried out to investigate the reasons for this enhancement. Sizing experiments and transmission electron microscopy indicated that there were no major differences in the size and shape of the LPDs prepared using the TC and DC lipids, while circular dichroism spectroscopy showed that the presence of the third acyl chain did not influence the conformation of the DNA within the LPD. In contrast, small angle neutron scattering studies showed a considerable re-arrangement of lipid conformation upon formulation as LPDs, particularly of the TC lipids, while gel electrophoresis studies revealed that the use of a TC lipid in the LPD formulation resulted in enhanced DNA protection properties. Thus, the major enhancement in transfection performance of these novel TC lipids can be attributed to their ability to protect and subsequently release DNA. Importantly, the TC lipids described here highlight a valuable structural template for the generation of gene delivery vectors, based on the use of lipids with three hydrophobic chains.

Design, synthesis and in vitro evaluation of novel SARS-CoV-2 3CLpro covalent inhibitors.

Severe diseases such as the ongoing COVID-19 pandemic, as well as the previous SARS and MERS outbreaks, are the result of coronavirus infections and have demonstrated the urgent need for antiviral drugs to combat these deadly viruses. Due to its essential role in viral replication and function, 3CLpro (main coronaviruses cysteine-protease) has been identified as a promising target for the development of antiviral drugs. Previously reported SARS-CoV 3CLpro non-covalent inhibitors were used as a starting point for the development of covalent inhibitors of SARS-CoV-2 3CLpro. We report herein our efforts in the design and synthesis of submicromolar covalent inhibitors when the enzymatic activity of the viral protease was used as a screening platform.

Synthesis of Chimeric Oligonucleotides Having Modified Internucleotide Linkages via an Automated H-Phosphonate/Phosphoramidite Approach.

This article describes an automated solid-phase approach for the synthesis of chimeric oligonucleotides containing phosphoramidate-modified internucleotide linkages. An optimized H-phosphonate synthetic cycle is combined with the commonly used phosphoramidite approach to obtain oligonucleotides comprising blocks having various types of internucleotide linkages. This article is specific to the synthesis of oligonucleotides having phosphoramidate modifications, but is adaptable to permit the incorporation of other modified linkages accessible through H-phosphonate diester intermediates. © 2018 by John Wiley & Sons, Inc.

Structural Studies and Gene Silencing Activity of siRNAs Containing Cationic Phosphoramidate Linkages.

A series of siRNA duplexes containing cationic non-bridging 3',5'-linked phosphoramidate (PN) linkages was designed and synthesized using a combination of phosphoramidite and H-phosphonate chemistries. Modified oligonucleotides were assayed for their thermal stability, helical structure, and ability to modulate the expression of firefly luciferase. We demonstrate that PN modifications of siRNAs are, in general, minimally destabilizing with respect to duplex thermal stability; destabilization can be mitigated through the incorporation of 2'-modified RNA-like residues or PN conjugates containing ionizable pendant moieties. We also demonstrate that single cationic dimethylethylenediamine PN linkages have little effect on siRNA potency, whether located in the passenger or guide strand of the duplex. Highly modified siRNA passenger strands were further modified with up to four cationic PN linkages, with little effect on duplex potency or helical structure. We envision that PN modifications could be useful in the production of therapeutic siRNAs with optimal biological properties.

Trichain cationic lipids: the potential of their lipoplexes for gene delivery.

Lipoplexes (LDs) have been prepared from DNA and positively charged vesicles composed of the helper lipid, dioleoyl l-α-phosphatidylethanolamine (DOPE) and either a dichain (DC) oxyethylated cationic lipid or their corresponding novel trichain (TC) counterpart. This is the first study using the TC lipids for the preparation of LDs and their application. Here the results of biophysical experiments characterising the LDs have been correlated with the in vitro transfection activity of the complexes. Photon correlation spectroscopy, zeta potential measurements and transmission electron microscopy studies indicated that, regardless of the presence of a third chain, there were little differences between the size and charge of the TC and DC containing LDs. Small angle neutron scattering studies established however that there was a significant conformational re-arrangement of the lipid bilayer when in the form of a LD complex as opposed to the parent vesicles. This re-arrangement was particularly noticeable in LDs containing TC lipids possessing a third chain of C12 or a longer chain. These results suggested that the presence of a third hydrophobic chain had a significant effect on lipid packing in the presence of DNA. Picogreen fluorescence and gel electrophoresis studies showed that the TC lipids containing a third acyl chain of at least C12 were most effective at complexing DNA while the TC lipids containing an octanoyl chain and the DC lipids were least effective. The transfection efficacies of the TC lipids in the form of LDs were found to be higher than for the DC analogues, particularly when the third acyl chain was an octanoyl or oleoyl moeity. Little or no increase in transfection efficiency was observed when the third chain was a methyl, acetyl or dodecanoyl group. The large enhancement in transfection performance of the TC lipids can be attributed to their ability to complex their DNA payload. These studies indicate that presence of a medium or long third acyl chain was especially beneficial for transfection.