The present invention provides novel Lactococcus lactis lactic acid bacterium strains having improved texturing properties and methods of using the strains for producing food products.

The present disclosure is in the technical field of synthetic biology and metabolic engineering. The disclosure provides engineered viable bacteria. In particular, the disclosure provides viable bacteria with reduced cell wall biosynthesis additionally modified for production of glycosylated product. The disclosure further provides methods of generating viable bacteria and uses thereof. Furthermore, the disclosure in the technical field of fermentation of metabolically engineered microorganisms producing glycosylated product.

The disclosure relates to the field of food ingredients, specifically to sweeteners, more specifically to steviol glycosides and improved isolation thereof.

The present invention concerns an expression system for systemic administration comprising a sequence encoding a FKRP protein, and: —a promoter sequence allowing the expression at a therapeutically acceptable level of FKRP in the skeletal muscles and a target sequence of an miRNA expressed in the heart; or—a promoter sequence allowing the expression at a therapeutically acceptable level of FKRP in the skeletal muscles and presenting a promoter activity at a toxically acceptable level in the heart; and its use for the treatment of various diseases linked to FKRP deficiencies.

Glycosylated biopharmaceuticals are important in the global pharmaceutical market. Despite the importance of their glycan structures, our limited knowledge of the glycosylation machinery still hinders controllability of this critical quality attribute. To facilitate discovery of glycosyltransferase specificity and predict glycoengineering efforts, here we extend an approach to model biosynthetic pathways for all measured glycans, and the Markov chain modeling is used to learn glycosyltransferase isoform activities and predict glycosylation following glycosyltransferase knock-in/knockout. We apply our methodology to four different glycoengineered therapeutics (i.e., Rituximab, erythropoietin, Enbrel, and alpha-1 antitrypsin) produced in CHO cells, along with o-glycosylation and lipid profiles. Our models accurately predict N-linked glycosylation following glycoengineering and further quantified the impact of glycosyltransferase mutations on reactions catalyzed by other glycosyltransferases. By applying these learned GT-GT interaction rules identified from single glycosyltransferase mutants, our model further predicts the outcome of multi-gene glycosyltransferase mutations on the diverse biotherapeutics. We further apply this to study differential O-glycosylation and lipidomics. Thus, this modeling approach enables rational glycoengineering and the elucidation of relationships between glycosyltransferases and other enzyme classes, thereby facilitating biopharmaceutical research and aiding the broader study of glycosylation to elucidate the genetic basis of complex changes in glycosylation and the lipidome.

The present invention relates to a method for producing a glycosyl fluoride of interest, the method comprising providing an internalized exogenous precursor and a genetically modified cell, wherein one or more glycosylation reactions can be performed on the exogenous precursor in the genetically modified cell, the genetically modified cell comprising one or more nucleic acid sequences encoding one or more glycosyltransferase enzymes. The present invention further relates to a compound of the following formula: 2b.

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Disclosed are novel glycosylated psilocybin derivative compounds and pharmaceutical and recreational drug formulations containing the same. The compounds may be produced by reacting a hydroxylated psilocybin derivative with a glycosyl compound.

Provided in this disclosure are methods of treating a bacterial infection comprising administering a formulation comprising an antimicrobial peptide described herein when administered to a subject. Further provided herein are methods of treating a bacterial infection wherein the bacterial infection comprises a bacterium with a mutation in a gene resulting in antibiotic resistance.

The present invention relates to methods for increasing the diversity of monoclonal antibodies produced against an antigen. The methods of the invention utilize immunization of a murine host defective in one or more enzymes involved in a post-translational modification of a polypeptide or a modification of a lipid, wherein said modification is exposed on a cell surface. The invention also relates to monoclonal antibodies produced by these methods and which are not produced when a normal mouse is immunized with the same antigen. The invention further relates to compositions comprising these monoclonal antibodies, as well as to such monoclonal antibodies bound or conjugated to a toxin, a detectable marker or to a solid support.

Provided is a group of new uridine diphosphate (UDP)-glycosyltransferases, which are carbon glycoside glycosyltransferases, wherein the glycosyltransferases can specifically and efficiently catalyze the carbon glycoside glucosylation of a dihydrochalcone(s) compound or a 2-hydroxyflavanone(s) compound, thereby producing a carbon glycoside dihydrochalcone(s) compound or a carbon glycoside-2-hydroxyflavanone(s) compound; and a flavonoid carbon glycoside(s) compound is formed from a carbon glycoside-2-hydroxyflavanone(s) compound by means of a further dehydration reaction. Further provided is the use of said new UDP glycosyltransferases in artificially constructed recombinant expression systems to produce a carbon glycoside dihydrochalcone(s) compound or a flavonoid carbon glycoside(s) compound by means of fermentation engineering.