The disclosure provides materials in the form of flavivirus variants that each encode a Non-Structural Protein-1 (NS1) variant, wherein the coding region is a chimera of at least two different NS1 coding regions, or wherein the coding region has at least one mutation in a codon of a canonical Asn-Xxx-Ser/Thr N-linked glycosylation site, wherein Asn is asparagine, Xxx is any amino acid, and Ser/Thr is either serine or threonine, or wherein the coding region is both a chimera and has at least one mutation in a codon of a canonical N-liked glycosylation site, wherein Asn is asparagine, Xxx is any amino acid, and Ser/Thr is either serine or threonine. The disclosure also provides methods of using such flavivirus variants to inhibit the transmission of infectious flavivirus.

The disclosure provides materials in the form of flavivirus variants that each encode a Non-Structural Protein-1 (NS1) variant, wherein the coding region is a chimera of at least two different NS1 coding regions, or wherein the coding region has at least one mutation in a codon of a canonical Asn-Xxx-Ser/Thr N-linked glycosylation site, wherein Asn is asparagine, Xxx is any amino acid, and Ser/Thr is either serine or threonine, or wherein the coding region is both a chimera and has at least one mutation in a codon of a canonical N-liked glycosylation site, wherein Asn is asparagine, Xxx is any amino acid, and Ser/Thr is either serine or threonine. The disclosure also provides methods of using such flavivirus variants to inhibit the transmission of infectious flavivirus.

The present invention relates to a macromolecule-based nanostructure, such as a DNA-based nanostructure, for encapsulating a virus or viral particle, to a composition comprising a virus or viral particle encapsulated by such a macromolecule-based nanostructure according to the present invention, and to a method for encapsulating a virus or viral particle by using such a macromolecule-based nanostructure

The disclosure provides cyclic dinucleotides that are useful as STING agonists, pharmaceutical compositions and vaccines comprising the cyclic dinucleotides, and methods of treating diseases and disorders using the cyclic dinucleotides, pharmaceutical compositions, and vaccines.

The disclosure provides cyclic dinucleotides that are useful as STING agonists, pharmaceutical compositions and vaccines comprising the cyclic dinucleotides, and methods of treating diseases and disorders using the cyclic dinucleotides, pharmaceutical compositions, and vaccines.

The present invention relates to a method for producing a compound represented by general formula [C-1-1], which comprises: a step for reacting a compound represented by general formula [B-1-1] with a compound represented by general formula [P] to form a compound represented by general formula [B-1-2]; and a step for reacting the compound represented by general formula [B-1-2] with a compound represented by general formula [A-1] to form the compound represented by general formula [C-1-1].

The present invention relates to a method for producing a compound represented by general formula [C-1-1], which comprises: a step for reacting a compound represented by general formula [B-1-1] with a compound represented by general formula [P] to form a compound represented by general formula [B-1-2]; and a step for reacting the compound represented by general formula [B-1-2] with a compound represented by general formula [A-1] to form the compound represented by general formula [C-1-1].

The present invention features compositions and methods for amplifying a target oligonucleotide in a sample, including detection of the target oligonucleotide in real time.

Compositions and methods for modulating expression of target nucleic acids using a single strand oligoribonucleotide ss-siRNA compound are disclosed.

Compositions and methods for modulating expression of target nucleic acids using a single strand oligoribonucleotide ss-siRNA compound are disclosed.