The present disclosure provides methods of modulating the flux of carbon through the monoethylene glycol (MEG) biosynthesis pathway and one or more C3 compound biosynthesis pathways by expressing enzymes that are essential for improving C3 compounds and modulating other genetic aspects of MEG and C3 compound biosynthesis. The disclosure is further drawn to modified microbes comprising the disrupted sequences and overexpressed sequences, and compositions thereof.

Described are 3-hydroxyisovalerate (HIV) synthase variants having improved activity in converting acetone and a compound which provides an activated acetyl group into 3-hydroxyisovalerate (HIV). Moreover, described are in particular methods for the production of 3-hydroxyisovalerate and methods for the production of isobutene from acetone utilizing the HIV synthase variants of the present invention.

Describes is a fermentation method for producing a hydrocarbon compound comprising the culturing of an organism in a liquid fermentation medium, wherein said organism produces a desired hydrocarbon compound by an enzymatic pathway, said enzymatic pathway comprising an intermediate which evaporates into the gaseous phase and wherein said intermediate is recovered from the gaseous phase and is reintroduced into the liquid fermentation medium.

Provided is a composition containing an agent capable of inhibiting the expression of HMGCLL1 IS3, and a method for treating or preventing a malignant tumor. The malignant tumor expresses HMGCLL1 IS3. The malignant tumors may show resistance to tyrosine kinase inhibitors. A method, composition, and kit for determining the expression level of HMGCLL1 IS3, for diagnosing drug resistance, for determining the probability of developing a malignant tumor, and for predicting prognosis of malignant tumors are provided.

Described is a method for the production of 3-hydroxy-3-methylbutyric acid by enzyme-catalyzed covalent bond formation between the carbon atom of the oxo group of acetone and the methyl group of a compound which provides an activated acetyl group. Also described are recombinant organisms which produce 3-hydroxy-3-methylbutyric acid, and related compositions and methods.

The present invention provides for a method to increase production of isoprenol by a genetically modified Pseudomonas cell, the method comprising: (a) providing a genetically modified Pseudomonas cell comprising one or more of heterologous genes encoding: MvaE, AtoB, MvaS, MK, PMD.sub.HKQ, AphA, and PhoA; and (b) culturing or growing the genetically modified Pseudomonas cell in a medium to produce isoprenol; wherein (i) the genetically modified Pseudomonas cell is deleted, knocked out, or reduced in expression of one or more of the following endogenous genes: a gene at PP_2675 locus (or a deletion of the PP_2675 locus), phaABC, mvaB, hbdH, ldhA, gntZ, ppsA, pycAB, gltA, and aceA, and/or (ii) the medium comprises one or more amino acids that reduce the catabolism of isoprenol.