It is disclosed a process for propagating a yeast capable to ferment glucose and xylose of a lignocellulosic feedstock hydrolyzate, said process comprising propagating the yeast over at least two propagation cycles. The first propagation cycle comprises the steps of: contacting the yeast at a starting yeast density with a first cultivation medium comprising a first portion of the lignocellulosic feedstock hydrolyzate; and allowing the yeast to propagate to create a first populated broth comprising water and a first propagated yeast, wherein at least 50% of the glucose and less than 20% of the xylose in the first cultivation medium are consumed in the first propagation cycle. The second cycle comprises the steps of: separating the first populated broth in at least a first removed portion and a first residual portion, wherein both the first residual portion and the first removed portion comprise some of the first propagated yeast; contacting the first residual portion with a second cultivation medium comprising a second portion of the lignocellulosic feedstock hydrolyzate; and allowing the yeast to propagate to create a second populated broth comprising water and a second propagated yeast, wherein at least 50% of the glucose and less than 20% of the xylose in the second cultivation medium are consumed in the second propagation cycle.

It is disclosed a process for propagating a yeast capable to ferment glucose and xylose of a lignocellulosic feedstock hydrolyzate, said process comprising propagating the yeast over at least two propagation cycles. The first propagation cycle comprises the steps of: contacting the yeast at a starting yeast density with a first cultivation medium comprising a first portion of the lignocellulosic feedstock hydrolyzate; and allowing the yeast to propagate to create a first populated broth comprising water and a first propagated yeast, wherein at least 50% of the glucose and less than 20% of the xylose in the first cultivation medium are consumed in the first propagation cycle. The second cycle comprises the steps of: separating the first populated broth in at least a first removed portion and a first residual portion, wherein both the first residual portion and the first removed portion comprise some of the first propagated yeast; contacting the first residual portion with a second cultivation medium comprising a second portion of the lignocellulosic feedstock hydrolyzate; and allowing the yeast to propagate to create a second populated broth comprising water and a second propagated yeast, wherein at least 50% of the glucose and less than 20% of the xylose in the second cultivation medium are consumed in the second propagation cycle.

Disclosed herein are compositions and methods for treating and immunizing against C. auris infection and colonization. The compositions and methods include polypeptides and fragments derived from the C. albicans Als3 protein, homologs thereof, and antibodies or fragments thereof that specifically bind these polypeptides and fragments. Administration of these compositions confers treatment and resistance against C. auris infection and colonization.

Provided herein are recombinant microorganisms having two or more copies of a nucleic acid sequence encoding xylose isomerase, wherein the nucleic acid encoding the xylose isomerase is an exogenous nucleic acid. Optionally, the recombinant microorganisms include at least one nucleic acid sequence encoding a xylulose kinase and/or at least one nucleic acid sequence encoding a xylose transporter. The provided recombinant microorganisms are capable of growing on xylose as a carbon source.

Provided herein are recombinant microorganisms having two or more copies of a nucleic acid sequence encoding xylose isomerase, wherein the nucleic acid encoding the xylose isomerase is an exogenous nucleic acid. Optionally, the recombinant microorganisms include at least one nucleic acid sequence encoding a xylulose kinase and/or at least one nucleic acid sequence encoding a xylose transporter. The provided recombinant microorganisms are capable of growing on xylose as a carbon source.

This invention is directed to vaccine compositions and methods of using the same to prevent infection.

This invention is directed to vaccine compositions and methods of using the same to prevent infection.

Provided herein are recombinant microorganisms having two or more copies of a nucleic acid sequence encoding xylose isomerase, wherein the nucleic acid encoding the xylose isomerase is an exogenous nucleic acid. Optionally, the recombinant microorganisms include at least one nucleic acid sequence encoding a xylulose kinase and/or at least one nucleic acid sequence encoding a xylose transporter. The provided recombinant microorganisms are capable of growing on xylose as a carbon source.

Provided herein are recombinant microorganisms having two or more copies of a nucleic acid sequence encoding xylose isomerase, wherein the nucleic acid encoding the xylose isomerase is an exogenous nucleic acid. Optionally, the recombinant microorganisms include at least one nucleic acid sequence encoding a xylulose kinase and/or at least one nucleic acid sequence encoding a xylose transporter. The provided recombinant microorganisms are capable of growing on xylose as a carbon source.

The present invention relates to a Candida tropicalis cell line, which comprises a mutant gene, having improved tolerance for cytotoxicity of stromal cells, and a method for producing dicarboxylic acid using the Candida tropicalis cell line. The Candida tropicalis cell line for producing dicarboxylic acid developed according to the present invention has improved tolerance for existing stromal toxicity as well as significantly improved efficiency for producing dicarboxylic acid compared to existing cell lines, thus can be used in biological production of dicarboxylic acid and is expected to have high industrial utility.