The present disclosure describes the generation and the use of Ad variants (Ad) possessing any combination of mutations in genes that code for the hexon, penton, fiber, and non-structural proteins, where simultaneous modification of hexon and penton are made to avoid the trapping of Ad in the liver and to reduce toxicity after intravascular virus administration. Such liver de-targeted Ad can be useful tool for selective and specific gene delivery to extra-hepatic tissues and cells, including disseminated metastatic cancer cells.

The present disclosure describes the generation and the use of Ad variants (Ad) possessing any combination of mutations in genes that code for the hexon, penton, fiber, and non-structural proteins, where simultaneous modification of hexon and penton are made to avoid the trapping of Ad in the liver and to reduce toxicity after intravascular virus administration. Such liver de-targeted Ad can be useful tool for selective and specific gene delivery to extra-hepatic tissues and cells, including disseminated metastatic cancer cells.

Described herein are Zika virus vaccines and compositions and methods of producing and administering said vaccines to subjects in need thereof.

Described herein are Zika virus vaccines and compositions and methods of producing and administering said vaccines to subjects in need thereof.

Disclosed herein are methods and composition producing a viral vaccine with reduced particle size, particularly for use in the production of influenza virus vaccines.

Disclosed herein are methods and composition producing a viral vaccine with reduced particle size, particularly for use in the production of influenza virus vaccines.

Described herein are processes for purifying infectious virus particles and uses of protamine in such processes.

Described herein are processes for purifying infectious virus particles and uses of protamine in such processes.

Live attenuated viruses for protection against the novel coronavirus, designated as Sars-CoV-2 by the World Health Organization (WHO) are provided. The live attenuated chimeric virus strains are based on a live attenuated influenza B virus (LAIVB), used a master backbone, which includes deletion of the viral virulence element, the NS1 (non-structural protein 1) (DeLNS1-B), engineered to express one or more antigens of the Sars-CoV-2 (herein, CoV2Ag). The chimeric virus strain is referred to generally herein, as DelNS1-B-Sars-CoV-2-CoV2Ag. The DelNS1-B-Sars-CoV-2-CoV2Ag strain preferably shows spontaneous cold adaption with preference to grow at 30-33° C. The DelNS1-B-Sars-CoV-2-CoV2Ag strain can be used to protect a subject in need thereof, against a challenge of Sars-CoV-2. DelNS1-B-Sars-CoV-2-CoV2Ag is an important strategy for making highly attenuated and immunogenic live attenuated vaccines with the ability to induce protective immunity against Sars-CoV-2.

Live attenuated viruses for protection against the novel coronavirus, designated as Sars-CoV-2 by the World Health Organization (WHO) are provided. The live attenuated chimeric virus strains are based on a live attenuated influenza B virus (LAIVB), used a master backbone, which includes deletion of the viral virulence element, the NS1 (non-structural protein 1) (DeLNS1-B), engineered to express one or more antigens of the Sars-CoV-2 (herein, CoV2Ag). The chimeric virus strain is referred to generally herein, as DelNS1-B-Sars-CoV-2-CoV2Ag. The DelNS1-B-Sars-CoV-2-CoV2Ag strain preferably shows spontaneous cold adaption with preference to grow at 30-33° C. The DelNS1-B-Sars-CoV-2-CoV2Ag strain can be used to protect a subject in need thereof, against a challenge of Sars-CoV-2. DelNS1-B-Sars-CoV-2-CoV2Ag is an important strategy for making highly attenuated and immunogenic live attenuated vaccines with the ability to induce protective immunity against Sars-CoV-2.