In various aspects and embodiments, the invention provides microbial cells and methods for producing advanced glycosylation products from lower glycosylated intermediates. The microbial cell expresses one or more UDP-dependent glycosyl transferase enzymes in the cytoplasm, for glycosylation of the intermediates. When incubating the microbial strain with a plant extract or fraction thereof comprising the intermediates, these glycosylated intermediates are available for further glycosylation by the cell, and the advanced glycosylation products can be recovered from the media and/or microbial cells.

Methods of and system for growing and maintaining an optimized/ideal active yeast solution in the yeast tank and fermenter tank during the fermentation filling cycle are provided. A new yeast stage tank is used between the yeast tank and the fermenter tank allowing yeast to rapidly produce a huge amount of active young yeast cells for a fermenter during the filling period. A measurable and useful controlling factor, % DT/% Yeast by weight ratio (or “food” to yeast ratio), is used (e.g., % DT=glucose), which offers information on the health status of the yeast. The controlling factor is used to control the status of the yeast throughout the entire process.

The subject invention provides compositions and methods for reducing the carbon footprint of producing livestock. Microbe-based soil treatment compositions reduce greenhouse gas emissions from producing livestock feed, and in turn, improve the health and productivity of livestock animals.

The subject invention provides materials and methods for reducing deleterious atmospheric gases, such as greenhouse gases (GHGs) by enhancing utilization and storage of carbon in plants, as well as increasing the sequestration of carbon in plant and soil matter in the form of degradation-resistant organic polymers.

The invention relates to a mutant of Saccharomyces eubayanus that is able to ferment maltotriose, and to the use of this mutant for producing hybrid yeast and the resulting hybrid yeast. The invention relates to methods of producing a fermented beer product by employing said mutant and/or said hybrid yeast.

Strains of yeast genetically engineered to produce increased amounts of non-hydroxylated collagen or hydroxylated collagen are described. An all-in-one vector including the DNA necessary to produce collagen, promotors, and hydroxylating enzymes is also described. Methods for producing non-hydroxylated or hydroxylated collagen are also provided.

The subject invention provides compositions and methods for reducing deleterious atmospheric gases and/or precursors thereof using livestock feed additives and/or supplements. In preferred embodiments, a multi-purpose composition comprising one or more beneficial microorganisms and/or one or more microbial growth by-products is applied to livestock animals' feed and/or to a field or pasture where livestock animals graze. In some embodiments, the composition controls methanogenic bacteria. In some embodiments, the composition enhances carbon sequestration in the field or pasture by promoting plant health and/or growth.

In various aspects and embodiments, the invention provides microbial cells and methods for producing advanced glycosylation products from lower glycosylated intermediates. The microbial cell expresses one or more UDP-dependent glycosyl transferase enzymes in the cytoplasm, for glycosylation of the intermediates. When incubating the microbial strain with a plant extract or fraction thereof comprising the intermediates, these glycosylated intermediates are available for further glycosylation by the cell, and the advanced glycosylation products can be recovered from the media and/or microbial cells.

The subject invention provides compositions and methods for reducing deleterious atmospheric gases and/or precursors thereof using livestock feed additives and/or supplements. In preferred embodiments, a multi-purpose composition comprising one or more beneficial microorganisms and/or one or more microbial growth by-products is applied to livestock animals' feed and/or to a field or pasture where livestock animals graze. In some embodiments, the composition controls methanogenic bacteria. In some embodiments, the composition enhances carbon sequestration in the field or pasture by promoting plant health and/or growth.

The present invention is directed to methods and apparatus for and products from disrupting, removing intracellular proteins, enzymes and nucleic acids, spray drying, lipid extraction, and making nanoparticles of Saccharomyces cerevisiae (yeast) cell wall followed by acid and/or enzymatic hydrolysis to produce Beta (β)-glucans, chitin and mannans (mannoproteins). The process and apparatus feature critical, supercritical, or near critical fluids for disruption of yeast and making yeast cell wall nanoparticles. The product materials retain full activity and are devoid of residual processing chemicals such as solvents, salts, or surfactants.