Optimizing the wavelength response in one‐dimensional p‐Si Schottky barrier optical PSDs

Functional analyses of the different proteins involved in the synthesis and accumulation of polyhydroxyalkanoates (PHAs) in P. putida U were performed using a mutant in which the pha locus had been deleted (PpUDeltapha). These studies showed that: (i) Pha enzymes cannot be replaced by other proteins in this bacterium, (ii) the transformation of PpDeltapha with a plasmid containing the locus pha fully restores the synthesis of bioplastics, (iii) the transformation of PpDeltapha with a plasmid harbouring the gene encoding the polymerase PhaC1 (pMCphaC1) permits the synthesis of polyesters (even in absence of phaC2ZDFI); however, in this strain (PpUDeltapha-pMCphaC1) the number of PHAs granules was higher than in the wild type, (iv) the expression of phaF in PpUDeltapha-pMCphaC1 restores the original phenotype, showing that PhaF is involved in the coalescence of the PHAs granules. Furthermore, the deletion of the phaDFI genes in P. putida U considerably decreases (> 70%) the biosynthesis of PHAs consisting of hydroxyalkanoates with aliphatic constituents, and completely prevents the synthesis of those ones containing aromatic monomers. Additional experiments revealed that the deletion of phaD in P. putida U strongly reduces the synthesis of PHA, this effect being restored by PhaF. Moreover, the overexpression of phaF in P. putida U, or in its DeltafadBA mutant, led to the collection of PHA over-producer strains.

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Production of 3-hydroxy-n-phenylalkanoic acids by a genetically engineered strain of Pseudomonas putida

Sandoval

Arias-Barrau

Bermejo

et al. 2004

Appl Microbiol Biotechnol

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Overexpression of the gene encoding the poly-3-hydroxy-n-phenylalkanoate (PHPhA) depolymerase (phaZ) in Pseudomonas putida U avoids the accumulation of these polymers as storage granules. In this recombinant strain, the 3-OH-acyl-CoA derivatives released from the different aliphatic or aromatic poly-3-hydroxyalkanoates (PHAs) are catabolized through the beta-oxidation pathway and transformed into general metabolites (acetyl-CoA, succinyl-CoA, phenylacetyl-CoA) or into non-metabolizable end-products (cinnamoyl-CoA). Taking into account the biochemical, pharmaceutical and industrial interest of some PHA catabolites (i.e., 3-OH-PhAs), we designed a genetically engineered strain of P. putida U (P. putida U DeltafadBA-phaZ) that efficiently bioconverts (more than 80%) different n-phenylalkanoic acids into their 3-hydroxyderivatives and excretes these compounds into the culture broth.

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A Two-component Hydroxylase Involved in the Assimilation of 3-Hydroxyphenyl Acetate in Pseudomonas putida

Arias-Barrau

Sandoval

Naharro

et al. 2005

Journal of Biological Chemistry

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The complete catabolic pathway involved in the assimilation of 3-hydroxyphenylacetic acid (3-OH-PhAc) in Pseudomonas putida U has been established. This pathway is integrated by the following: (i) a specific route (upper pathway), which catalyzes the conversion of 3-OH-PhAc into 2,5-dihydroxyphenylacetic acid (2,5-diOH-PhAc) (homogentisic acid, Hmg), and (ii) a central route (convergent route), which catalyzes the transformation of the Hmg generated from 3-OH-PhAc, L-Phe, and L-Tyr into fumarate and acetoacetate (HmgABC). Thus, in a first step the degradation of 3-OH-PhAc requires the uptake of 3-OH-PhAc by means of an active transport system that involves the participation of a permease (MhaC) together with phosphoenolpyruvate as the energy source. Once incorporated, 3-OH-PhAc is hydroxylated to 2,5-diOH-PhAc through an enzymatic reaction catalyzed by a novel two-component flavoprotein aromatic hydroxylase (MhaAB). The large component (MhaA, 62,719 Da) is a flavoprotein, and the small component (MhaB, 6,348 Da) is a coupling protein that is essential for the hydroxylation of 3-OH-PhAc to 2,5-diOH-PhAc. Sequence analyses and molecular biology studies revealed that homogentisic acid synthase (MhaAB) is different from the aromatic hydroxylases reported to date, accounting for its specific involvement in the catabolism of 3-OH-PhAc. Additionally, an ABC transport system (HmgDEFGHI) involved in the uptake of homogentisic acid and two regulatory elements (mhaSR and hmgR) have been identified. Furthermore, the cloning and the expression of some of the catabolic genes in different microbes presented them with the ability to synthesize Hmg (mhaAB) or allowed them to grow in chemically defined media containing 3-OHPhAc as the sole carbon source (mhaAB and hmgABC).

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Ángel Sandoval

Bioplastics from microorganisms

Persistence and molecular evolution of Mycobacterium bovis population from cattle and wildlife in Doñana National Park revealed by genotype variation

Genetic and ultrastructural analysis of different mutants of Pseudomonas putida affected in the poly‐3‐hydroxy‐n‐alkanoate gene cluster

Production of 3-hydroxy-n-phenylalkanoic acids by a genetically engineered strain of Pseudomonas putida

A Two-component Hydroxylase Involved in the Assimilation of 3-Hydroxyphenyl Acetate in Pseudomonas putida

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