Disclosed is producing recombinant SARS-CoV-2 spike protein in a pre-fusion state, using furin knock out or knockdown mammalian cells (such as HEK293, CHO or other mammalian cells) and using them to generate antibodies and related binding agents. The antibodies/binding agents can be used in SARS-CoV-2 detection assays or in diagnosis of active or prior infection with SARS-CoV-2; in prophylaxis or as a therapeutic; or for prophylactic or therapeutic use against coronaviruses related to SARS-CoV-2.

Disclosed is producing recombinant SARS-CoV-2 spike protein in a pre-fusion state, using furin knock out or knockdown mammalian cells (such as HEK293, CHO or other mammalian cells) and using them to generate antibodies and related binding agents. The antibodies/binding agents can be used in SARS-CoV-2 detection assays or in diagnosis of active or prior infection with SARS-CoV-2; in prophylaxis or as a therapeutic; or for prophylactic or therapeutic use against coronaviruses related to SARS-CoV-2.

This disclosure describes isolated protein complexes including a Wnt and a sFRP; compositions including a Wnt; a cell overexpressing a Wnt and a sFRP; compositions including a cell overexpressing a Wnt and a cell overexpressing a sFRP; methods of making the protein complexes, compositions, and cells; and methods of using the isolated protein complexes, compositions, and cells. This disclosure further describes methods of forming a complex including a Wnt and a sFRP and methods for isolating a Wnt. Also described herein are methods that may be used to purify a Wnt without the use of a detergent.

A method for reducing renal tissue toxicity in a subject caused by a kidney damaging agent is disclosed. The method comprises administering to the subject: (i) a kidney damaging agent; and (ii) an inhibitor of glucose reabsorption.

Alternative antibodies to screen for SARS-CoV-2 are disclosed. One alternative antibody is Mouse Species Coronavirus (COVID-19, MERS, and SARS-CoV NP) Antibody, Catalog Number HM1056 (“E3-Antibody” or “E3”), from EastCoast Bio, Inc., PO Box 489, North Berwick, Me. 03906, USA (“EastCoast Bio”). Another alternative antibody is a combination of the E3-Antibody and Mouse Species Coronavirus (COVID-19, MERS, and SARS-CoV NP) Antibody, Catalog Number HM1057 (“E1-Antibody” or “E1”), from EastCoast Bio (the combination of the E1-Antibody and the E3-Antibody is designated as “E1/E3-Antibody” or simply “E1/E3”). Yet another alternative antibody is a combination of Mouse Species Anti-SARS-CoV-2 NP mAb, clone 4B21, Catalog Number CABT-CS027 (“C4-Antibody” or “C4”), from Creative Diagnostics, 45-1 Ramsey Road, Shirley, N.Y. 11967, USA (“Creative Diagnostics”), and Mouse Species Anti-SARS-CoV-2 NP mAb, clone 7G21, Catalog Number CABT-CS026 (“C5-Antibody” or “C5”), also from Creative Diagnostics (the combination of the C4-Antibody and the C5-Antibody is designated as “C4/C5-Antibody” or simply “C4/C5”).

The present invention concerns enriched heterogeneous mammalian renal cell populations characterized by biomarkers, and methods of making and using the same.

It is provided a technique capable of noninvasively and quantitatively evaluating the state of cultured three-dimensional cell-based structure. A method of evaluating a three-dimensional cell-based structure according to the present invention comprises: performing tomography of the cultured three-dimensional cell-based structure (step S103); generating stereoscopic data indicating the three-dimensional shape of the three-dimensional cell-based structure based on image data acquired by the tomography (step S104); and counting the number of structures isolated from each other in the three-dimensional cell-based structure based on the stereoscopic data (step S105).

Disclosed is a process for growing adherent cells in a containment box of a multi-parallel bioreactor, including: seeding the adherent cells on a carrier held in a culture dish; transferring the adherent cells on the carrier to a containment box of the multi-parallel bioreactor; and growing the adherent cells at a containment box while agitating the media at an impeller speed between 200 rpm to a 1200 rpm.

Disclosed is a method for inducing direct reprogramming of urine cells into renal progenitor cells and a pharmaceutical composition including the renal progenitor cells reprogrammed by the method for preventing or treating renal cell injury disease. The method can make the mass production of customized reprogrammed renal progenitor cells by using urine cells, which are somatic cells easily and repeatedly obtainable without inconvenience and pain and as such, can be applied to incurable disease fields expandable to the renal injury therapy and kidney regeneration fields and to the production of cell therapy products.

The present invention provides a robust single clone Master Cell Bank (MCB) for an optimized production of H-1 parvovirus (H-1 PV) which is suitable to increase infectious parvovirus production compared to standard producer NB-324K mixed cells.