A genetically modified phototrophic cell for in-vivo production of hydrogen. The phototrophic cell has been genetically modified to the effect that a) at least one of the native photosystem I components has been deleted, b) the native hydrogenase has been deleted, and c) at least one fusion protein is expressed, comprising i. a hydrogenase or hydrogenase component and ii. at least one PSI component, with the proviso that the PSI is complemented by expression of the at least one fusion protein, and the hydrogenase component itself, or together with at least one further hydrogenase component expressibly introduced into the cell, has hydrogenase activity.

Described herein are recombinant host organisms expressing a sugar transporter and an active pentose fermentation pathway. Also described are processes for producing a fermentation product, such as ethanol, from starch or cellulosic-containing material with the recombinant host organisms.

The present invention belongs to the field of genetic engineering. Specifically, the present invention relates to a gene editing system derived from Flavobacterium and uses thereof.

The present invention belongs to the field of genetic engineering. Specifically, the present invention relates to a gene editing system derived from Flavobacterium and uses thereof.

Provided are SpdE polypeptides and variants and nucleic acids encoding the SpdE polypeptides and variants. Also provided are vectors including one or more nucleic acids encoding a SpdE polypeptide or variant and cells including a nucleic acid encoding the SpdE polypeptide or variant, as well as cells expressing a SpdE polypeptide or variant and compositions including such cells and a pharmaceutically acceptable carrier. Finally, methods of detecting presence and/or amount of one or more amino acids in a sample are provided. The methods include contacting the sample with a SpdE protein, measuring diguanylate cyclase activity of the SpdE protein; and comparing the diguanylate cyclase activity of the SpdE protein to a control. The methods can utilize isolated SpdE protein or a cell expressing a SpdE protein.

Provided are SpdE polypeptides and variants and nucleic acids encoding the SpdE polypeptides and variants. Also provided are vectors including one or more nucleic acids encoding a SpdE polypeptide or variant and cells including a nucleic acid encoding the SpdE polypeptide or variant, as well as cells expressing a SpdE polypeptide or variant and compositions including such cells and a pharmaceutically acceptable carrier. Finally, methods of detecting presence and/or amount of one or more amino acids in a sample are provided. The methods include contacting the sample with a SpdE protein, measuring diguanylate cyclase activity of the SpdE protein; and comparing the diguanylate cyclase activity of the SpdE protein to a control. The methods can utilize isolated SpdE protein or a cell expressing a SpdE protein.

Described herein are expression vectors encoding the Wolbachia protein WalE1. Also described are insects transformed with an expression vector of the present disclosure, and progeny thereof. Also described are methods for improving Wolbachia replication and transmission in its insect host by overexpressing WalE1 in the insect host. Improved Wolbachia replication and transmission provides for insect population control and pathogen resistance in insects, which can reduce disease transmission.

Described herein are expression vectors encoding the Wolbachia protein WalE1. Also described are insects transformed with an expression vector of the present disclosure, and progeny thereof. Also described are methods for improving Wolbachia replication and transmission in its insect host by overexpressing WalE1 in the insect host. Improved Wolbachia replication and transmission provides for insect population control and pathogen resistance in insects, which can reduce disease transmission.

Provided herein, in some embodiments, are enzymatic methods for producing an oligonucleotide comprising phosphoramidate-linked nucleotides, and compositions comprising the oligonucleotide thus produced.

Combination therapies for the treatment of cancers are provided. In some embodiments, a flagellin derivative such as CBLB502 is administered in combination with an immune checkpoint therapy (e.g., an anti-PD 1 antibody and an anti-CTLA4 antibody) to treat a cancer in a mammalian subject. In some embodiments, the combination therapy is administered intratumorally or peritumorally.