Disclosed herein are genetically engineered hematopoietic cells, which express one or more lactate-modulating factors (e.g., polypeptides), and optionally a chimeric receptor polypeptide (e.g., an antibody-coupled T cell receptor (ACTR) polypeptide or a chimeric antigen receptor (CAR) polypeptide) capable of binding to a target antigen of interest. Also disclosed herein are uses of the engineered hematopoietic cells for inhibiting cells expressing a target antigen in a subject in need thereof.

The present disclosure provides populations of synchronized post-mitotic migratory cortical interneurons (cINS) derived from pluripotent stem cells and cell culture methods for generating said populations of cINs. The disclosure also provides efficient methods for cryopreservation of the derived cINs.

The present disclosure relates to single and/or multi-stage, biological processes and systems for converting C5, C6, and/or disaccharide carbon sources to desirable products including monoethylene glycol (MEG) and one or more three-carbon compounds such as acetone, isopropanol or propene. The MEG and one or more three-carbon compounds described herein are useful as starting material for production of other compounds or as end products for industrial and household use. The disclosure further relates to the processes carrying out fermentations of substrates in a single phase bioreactor or in a multiphase bioreactor comprising growth and production phases. Additionally, the processes and systems described herein result in high productivity and yield of the desired products due to intermittent or continuous removal of products to avoid inhibitory effects.

An expression system and process for the production of Diphtheria toxin polypeptides or mutated forms thereof, such as the toxoid CRM197 polypeptide, in genetically-modified E. coli with high yield is described. The system and process is based on the uncoupling of biomass growth from recombinant protein induction, i.e. using an inducer of protein production that cannot be used as a carbon source for growth by the bacteria. The use of specific components and conditions that improve protein yields are also described.

The present invention refers to a freeze-dried composition consisting of an isolated microorganism belonging to the Mycobacterium tuberucolosis complex, preferably a M. tuberculos clinical isolate, more preferably M. tuberculosis clinical isolate, characterized in that it comprises a PhoP− phenotype by the inactivation by a genetic deletion of the Rv0757 gene and the deletion of a second gene, Rv2930 (fadD26), that prevents PDIM production (PDIM− phenotype) (the MTBVAC strain), and sucrose and sodium glutamate as stabilizers or excipients. The present invention further refers to the reconstituted composition obtained by adding water, preferably sterilized water for injection, to the freeze-dried composition as well as uses thereof, in particular for use as a prophylactic agent to those at risk of infection with M. tuberulosis or those at risk of developing tuberculosis disease, or as secondary agents for treating infected tuberculosis patients.

Methods of making neuronal stem cells and exosomes of diencephalon lineage are disclosed. Also provided are compositions comprising neuronal stem cells or exosomes of diencephalon lineage, which may be formulated as pharmaceutical formulations for the treatment and prevention of disorders associated with the neuroendocrine system and the control of behavioral and physiological processes.

The disclosure is in the technical field of synthetic biology and metabolic engineering. More particularly, the disclosure is in the technical field of cultivation or fermentation of metabolically engineered cells. The disclosure describes a method for the production of a di- or oligosaccharide with an N-acetylglucosamine at the reducing end by a cell as well as the purification of the di- or oligosaccharide from the cultivation. Furthermore, the disclosure provides a cell metabolically engineered for production of a di- or oligosaccharide with an N-acetylglucosamine at the reducing end.

The invention provides novel methods and compositions for microspore embryogenesis and the production of doubled haploid embryos. For example, the methods provided include the steps of sterilization of pepper buds, microspore isolation from sterilized buds, liquid culture of microspores, a double-layer subculture, embryo harvest for germination and conversion to plantlets, and acclimatization of cultured plantlets.

This disclosure is in the technical field of synthetic biology and metabolic engineering. More particularly, this disclosure is in the technical field of cultivation or fermentation of metabolically engineered cells. This disclosure provides a method for the production of a mixture of at least two different oligosaccharides by a cell as well as the purification of at least one of the oligosaccharides from the cultivation. In addition, this disclosure provides a method for the production of a mixture of at least two different oligosaccharides by a metabolically engineered cell as well as the purification of at least one of the oligosaccharides from the cultivation.

The disclosure is in the technical field of synthetic biology and metabolic engineering. More particularly, the disclosure is in the technical field of cultivation or fermentation of metabolically engineered cells. The disclosure describes a cell metabolically engineered for production of an alpha-1,3 glycosylated form of fucose-alpha1,2-galactose-R (Fuc-a1,2-Gal-R). Furthermore, the disclosure provides a method for the production of an alpha-1,3 glycosylated form of Fuc-a1,2-Gal-R by a cell as well as the purification of the alpha-1,3 glycosylated form Fuc-a1,2-Gal-R from the cultivation.