An object of the present invention is to obtain a fermentative yeast having a highly efficient ethanol production without introducing a foreign gene. A further object is to obtain a fermentative yeast that is resistant to proliferation inhibitors such as organic acids, which prevent the proliferation of the fermentative yeast. A yeast having an improved ethanol production ability was generated by introducing transaldolase and alcohol dehydrogenase genes by self-cloning to Meyerozyma guilliermondii that can produce ethanol effectively from pentose and hexose obtained by breeding, and further breeding the resultant yeast.

An object of the present invention is to obtain a fermentative yeast having a highly efficient ethanol production without introducing a foreign gene. A further object is to obtain a fermentative yeast that is resistant to proliferation inhibitors such as organic acids, which prevent the growth of the fermentative yeast. Yeast having improved ethanol production ability was generated by introducing transaldolase and alcohol dehydrogenase gene by self-cloning to Meyerozyma guilliermondii that can produce ethanol effectively from pentose and hexose obtained by breeding. This fermentative yeast is deposited to NITE Patent Microorganisms Depositary under the accession number NITE ABP-01976.

Provided herein, in some aspects, are methods and compositions for producing large-scale quantities of butanol, including normal butanol (n-butanol), isobutanol, and 2-butanol using a cell-free system.

The invention features methods for producing isoprene from cultured cells. The invention also provides compositions that include these cultured cells.

The present invention discloses a genetically engineered bacterium using glucose as a substrate for de novo synthesis of vanillin and an application thereof, which belongs to the technical field of gene recombination and metabolic engineering. The genetically engineered bacterium using the glucose as the substrate for de novo synthesis of vanillin disclosed by the present invention is recombinant Corynebacterium glutamicum modified by chassis microorganisms and including a vanillin synthesis module and a methyl cyclic regeneration module. The genetically engineered bacteria constructed by the present invention are safe and non-toxic, can use the glucose for de novo synthesis of natural vanillin, and is low in production cost, high in yield, and promising in application prospect.

The present invention relates to a transcription regulatory biopart based on the 3-untranslated region and a metabolic flux control method thereof.

The present invention discloses a modified Cannabis plant exhibiting herbicide resistance (HR) as compared to a Cannabis plant absent of such modification. The modified plant comprises at least one genetically modified HR-related gene comprising at least one mutation conferring herbicide resistance to the plant. The present invention further discloses methods for producing the same.

Genetically modified microorganisms that have the ability to convert carbon substrates into chemical products such as 2,3-BDO; 1,4-BDO; isobutyraldehyde; isobutanol; 1-butanol; n-butanol; ethanol; fatty alcohols; and fatty acid methyl ester are disclosed. For example, genetically modified methanotrophs that are capable of generating 2,3-BDO; 1,4-BDO; isobutyraldehyde; isobutanol; 1-butanol; n-butanol; ethanol; fatty alcohols; and fatty acid methyl ester at high titers from a methane source are disclosed. Methods of making these genetically modified microorganisms and methods of using them are also disclosed. These microorganisms and methods make use of molecular switches to regulate gene expression.

The present invention relates to sesame plants resistant to herbicides that inhibit the plant enzyme acetolactate synthase (ALS), and further to compositions and methods for producing the same.

The invention relates to recombinant microorganisms and methods for producing macrocyclic diterpene or oxidized macrocyclic diterpene.