Protective Efficacy of Novel Engineered Human ACE2-Fc Fusion Protein Against Pan-SARS-CoV-2 Infection In Vitro and in Vivo.

Enduring occurrence of severe COVID-19 for unvaccinated, aged, or immunocompromised individuals remains an urgent need. Soluble human angiotensin-converting enzyme 2 (ACE2) has been used as a decoy receptor to inhibit SARS-CoV-2 infection, which is limited by moderate affinity. We describe an engineered, high-affinity ACE2 that is consistently effective in tissue cultures in neutralizing all strains tested, including Delta and Omicron. We also found that treatment of AC70 hACE2 transgenic mice with hACE2-Fc receptor decoys effectively reduced viral infection, attenuated tissue histopathology, and delayed the onset of morbidity and mortality caused by SARS-CoV-2 infection. We believe that using this ACE2-Fc protein would be less likely to promote the escape mutants of SARS-CoV-2 as frequently as did those neutralizing antibody therapies. Together, our results emphasize the suitability of our newly engineered hACE2-Fc fusion protein for further development as a potent antiviral agent against Pan-SARS-CoV-2 infection.

New-to-nature sophorose analog: a potent inducer for gene expression in Trichoderma reesei.

Controlled hydrolysis of lactonic sophorolipids from Starmerella bombicola yields a previously undescribed sophorose analog that potently induces cellulase in Trichoderma reesei Rut-C30. Acid treatment of natural sophorolipids results in a mixture of monoacetylated, deacetylated, and diacetylated sophorolipids in acidic and lactonic forms. Isolation of the active components of the mixture, followed by structure determination by MS and NMR, reveals a new chemical entity, in which the lactone ring has been opened at the C-1' rather than at the C-4″ position of the sophorose moiety. This sophorose ester is resistant to degradation by the host and is at least 28 times more powerful an inducer than sophorose in shake-flask culture. Even at low concentrations (0.05 mM), the chemically modified sophorolipid effectively induces cellulase. With further improvements, this highly enabling technology can potentially reduce the cost of enzymes produced in T. reesei and can facilitate the rapid deployment of enzyme plants to support the nascent cellulosic biofuels and biochemicals industries.

Antibody-membrane switch (AMS) technology for facile cell line development.

Generation of high-productivity cell lines remains a major bottleneck in therapeutic antibody development. Conventional cell line development often depends on gene amplification methodologies using dihydrofolate reductase or glutamine synthetase. Higher productivity is associated with an increased gene copy number. However, lack of selection pressure under the conditions of large-scale manufacturing leads to clonal instability. We have developed a novel method for cell line development, antibody-membrane switch (AMS) technology, that does not rely on gene amplification. This fluorescence-activated cell sorting (FACS)-based, high-throughput method is facilitated by cell-surface antibody expression to rapidly and efficiently isolate high-producing cells. The switch between membrane expression and secretion is achieved by alternative splicing and specific DNA recombination. The antibody of interest is initially displayed on the cell surface to facilitate FACS. Isolated high-producing cells are then seamlessly transformed into production cells after removing the membrane-anchoring domain sequence with a DNA recombinase. AMS technology has been applied in a number of antibody cell line development projects, which typically last 2-3 months. The top production cell lines exhibit very high specific productivity of 40-60 pg/cell/day resulting in production titers of 2-4 g/l in 10-day batch culture.