The present disclosure concerns recombinant yeast host cells having a first genetic modification for downregulating a first metabolic pathway that converts NADP.sup.+ to NADPH, as well as a second genetic modification for upregulating a second metabolic pathway that converts NADP.sup.+ to NADPH. The second genetic modification allows the expression of a glyceraldehyde-3-phosphate dehydrogenase lacking phosphorylating activity, which can, in some embodiments, be from enzyme commission 1.2.1.9 or 1.2.1.90. The second pathway is distinct from the first metabolic pathway. The present disclosure also concerns a process for making and improving the yield of a fermented product, such as ethanol, using the recombinant yeast host cell.

Methods for increasing carbon-based chemical product yield in an organism by genetically modifying one or more genes involved in a stringent response and/or in a regulatory network, nonnaturally occurring organisms having increased carbon-based chemical product yield, and methods for use in production of carbon-based chemical products are provided.

The present invention discloses mutant strains of Amycolatopsis sp. ATCC 39116 suitable for the production of natural vanillin using ferulic acid as a feedstock. More specifically, the present invention discloses mutant strains having mutations that reduce the degradation of vanillin to vanillic acid.

Methods for increasing carbon-based chemical product yield in an organism by genetically modifying one or more genes involved in a stringent response and/or in a regulatory network, nonnaturally occurring organisms having increased carbon-based chemical product yield, and methods for use in production of carbon-based chemical products are provided.

Methods and materials for the biosynthesis of compounds involved in glutamate metabolism, and derivatives and compounds related thereto are provided. Also provided are products produced in accordance with these methods and materials.

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.