M. Auxiliadora Prieto

Although Escherichia coli has long been recognized as the best-understood living organism, little was known about its abilities to use aromatic compounds as sole carbon and energy sources. This review gives an extensive overview of the current knowledge of the catabolism of aromatic compounds by E. coli. After giving a general overview of the aromatic compounds that E. coli strains encounter and mineralize in the different habitats that they colonize, we provide an up-to-date status report on the genes and proteins involved in the catabolism of such compounds, namely, several aromatic acids (phenylacetic acid, 3- and 4-hydroxyphenylacetic acid, phenylpropionic acid, 3-hydroxyphenylpropionic acid, and 3-hydroxycinnamic acid) and amines (phenylethylamine, tyramine, and dopamine). Other enzymatic activities acting on aromatic compounds in E. coli are also reviewed and evaluated. The review also reflects the present impact of genomic research and how the analysis of the whole E. coli genome reveals novel aromatic catabolic functions. Moreover, evolutionary considerations derived from sequence comparisons between the aromatic catabolic clusters of E. coli and homologous clusters from an increasing number of bacteria are also discussed. The recent progress in the understanding of the fundamentals that govern the degradation of aromatic compounds in E. coli makes this bacterium a very useful model system to decipher biochemical, genetic, evolutionary, and ecological aspects of the catabolism of such compounds. In the last part of the review, we discuss strategies and concepts to metabolically engineer E. coli to suit specific needs for biodegradation and biotransformation of aromatics and we provide several examples based on selected studies. Finally, conclusions derived from this review may serve as a lead for future research and applications.

Polyhydroxyalkanoate (PHA) metabolism has been traditionally considered as a futile cycle involved in carbon and energy storage. The use of cutting-edge technologies linked to systems biology has improved our understanding of the interaction between bacterial physiology, PHA metabolism and other cell functions in model bacteria such as Pseudomonas putida KT2440. PHA granules or carbonosomes are supramolecular complexes of biopolyester and proteins that are essential for granule segregation during cell division, and for the functioning of the PHA metabolic route as a continuous cycle. The simultaneous activities of PHA synthase and depolymerase ensure the carbon flow to the transient demand for metabolic intermediates to balance the storage and use of carbon and energy. PHA cycle also determines the number and size of bacterial cells. The importance of PHAs as nutrients for members of the microbial community different to those that produce them is illustrated here via examples of bacterial predators such as Bdellovibrio bacteriovorus that prey on PHA producers and produces specific extra-cellular depolymerases. PHA hydrolysis confers Bdellovibrio ecological advantages in terms of motility and predation efficiency, demonstrating the importance of PHA producers predation in population dynamics. Metabolic modulation strategies for broadening the portfolio of PHAs are summarized and their properties are compiled.

Two hundred and seventy five million tons of plastic waste were produced in 2010 alone (Jambeck et al., 2015), with Europe accounting for about 55 million tons per year. The environmental impact of these, primarily fossil-based, plastics has been broadly discussed. While the vast majority of these polymers are not biodegradable, their strength and light weight provide comparative advantages. Poly(ethylene terephthalate) (PET), for instance, has contributed significantly to reducing energy expenditure during transport, especially in the beverage industry. Due to its thermoplastic nature PET is also easy to recycle. However, recycled PET products struggle to compete with virgin PET on price and quality, leading to an overall European recycling rate of less than 30% (PlasticsEurope, 2015). Polyurethanes (PU) are used extensively in a wide range of applications including construction, transportation, furniture and medicine. Since many PU types have a thermoset nature with covalent cross links, one of the main concerns for this plastic is the notable lack of end-of-life recycling (< 5%). Finally, polyethylene (the most used plastic, ca. 140 million tons per year), is considered to be practically inert and its recycling (other than its downcycling into lumber) is economically unfavourable (Sivan, 2011), thereby creating a phenomenal environmental impact, especially in marine environments (Cozar et al., 2014; 2015). While a few countries manage major fractions of plastic waste through incineration in controlled industrial facilities, release of recalcitrant post-consumer plastic into nature remains a major problem globally. Significant amounts of plastic waste contribute to the large-scale pollution of the oceans (Katsnelson, 2015), with terms such as ‘the Great Pacific Garbage Patch’ and ‘the Trash Vortex’ mobilizing public opinion. The widespread distribution of microplastics in the food chain, with as yet unknown effects on biodiversity and human health is also appearing more in the scientific and general literature (Allsopp et al., 2006; Setala et al., 2014; Avio et al., 2015). The momentum for change away from current practices and towards a sustainable model of exploitation of waste and renewable resources is growing. In order to counteract the pollutant/recycling problems, the revised European Union (EU) Waste Framework Directive has set a minimum plastic recycling target of 50% for household waste and 70% for building and construction waste, which must be reached by all EU member states by 2020. However, without a clear technology roadmap – not to mention an attractive market strategy, the increase in recycling rates will in our opinion not be achievable. Given this background, we propose to use plastic wastes as substrates for the synthesis of added value products, which will empower the recycling industry to a qualitatively new dimension. How can microbial biotechnology contribute now to this enormous challenge? The advances in our understanding of microbial functions from enzyme, to pathways, and entire metabolic networks now allow the engineering of complex metabolic functions in microbes (Blank and Ebert, 2013). With the ever-advancing tools from synthetic biology e.g. for genome editing (Nikel et al., 2014), we can overcome the major challenges for a biotechnological plastic waste-based value chain. Some of the challenges and recent developments are highlighted below. Thermochemical depolymerization of plastics is a rapidly developing field, but often suffers from a lack of added value since the focus lies mostly on liquid and gaseous fuel [synthesis gas (syngas)] production or the re-polymerization to the original polymer. The thermochemical depolymerization of plastic wastes to monomers or syngas, followed by microbial fermentation to generate, for example, higher value biodegradable polymers has emerged as an exciting approach for plastic upcycling (Ward et al., 2006; Goff et al., 2007; Kenny et al., 2008; Guzik et al., 2014; Drzyzga et al., 2015). However improvements in the growth and levels of biodegradable polymer accumulation by bacteria from these substrates are required. Synthetic biology has the potential to address these plastic waste challenges. Several companies are developing technologies based on syngas fermentation from complex wastes, but most of them are still at the pre-commercial stage since various technical and economic challenges must be overcome before commercial-scale plants can be established (e.g. mass transfer limitation). Biology may also be able to offer depolymerization solutions. While PET has previously been considered recalcitrant to biological degradation, recently it has been shown that it can be depolymerized by hydrolytic enzymes, such as cutinases and carboxyl esterases, produced by bacteria and fungi (Wei et al., 2014). In addition, several bacterial species can use PU as a sole carbon source using enzymes (PUase) mainly classified as esterases, lipases and proteases (Howard, 2002). Hydrolytic enzymes, including members of the mentioned classes, are already produced in bulk quantities and low cost for a variety of applications such as stain-removal agents in detergents and biomass depolymerization in second-generation biorefineries. Hence, the design of novel enzymatic degradation modules employing plastic hydrolases with high rates of plastic depolymerization is possible. While microbes can degrade plastics such as polyethylene, the rates of degradation are slow (Yang et al., 2014). One can envisage the emergence of hydrolytic enzymes from nature and advanced genetic engineering with higher rates of depolymerization. In this context, we shall see both natural and tailored plastic-degrading biological agents emerge in the not-so-distant future, which will be able to operate under industrial conditions, where such capabilities can be optimally exploited. Besides hydrolytic activities, pathways for efficient use of the plastic monomers arising from depolymerization are required when using plastic waste as a feedstock. The conundrum is similar to issues encountered with lignocellulosic feedstocks, where the engineering of efficient xylose metabolizing strains was a breakthrough technology (for a recent review see: Kim et al., 2013). One organism that stands out when it comes to degrading plastic and plastic derived monomers is Pseudomonas. This is not surprising in view of the extraordinary metabolic and stress-resistance capabilities growingly found in this type of bacteria (Nikel et al., 2014). In fact, this genus includes some of the most efficient PU degraders known, enabling growth rates on polymeric substrates that rival the rates on many conventional substrates (Howard and Blake, 1998). Although Pseudomonas cannot degrade PET, its metabolic versatility enables it to utilize terephthalic acid as a carbon source in a biotechnological process for converting PET to polyhydroxyalkanoate (PHA) (Kenny et al., 2008). Furthermore, utilization of ethylene glycol, a product of PET depolymerization, was reported for Pseudomonas species (Muckschel et al., 2012). The exploitation of such catabolic routes for the synthesis of biodegradable polymers has been proposed (O'Connor et al., 2013). Pseudomonas is a promising host for biotechnology with a wide variety of possible products including biodegradable polymers (Ward et al., 2006; Goff et al., 2007; Kenny et al., 2008; Guzik et al., 2014; Tiso et al., 2015). Specific opportunities may be found in the increasing bioplastic and biosurfactant markets. Pseudomonas putida is an excellent choice for biopolymer and biosurfactant production, with reported natural PHA (bioplastic) production of up to 75% of the cell dry weight (Sun et al., 2007). In this rapidly developing field, new to nature PHAs can now also be synthesized by engineered microbes (Tortajada et al., 2013; Meng et al., 2014). These novel polyesters can be co-polymerized in vivo or blended during manufacturing, thereby increasing the possible applications. These exciting strategies pave the way to generate high-added value PHAs with applications beyond biodegradable packaging in other fields like nano/biomedicine (Dinjaski et al., 2014; Dinjaski and Prieto, 2015). Similarly, biosurfactants such as rhamnolipids can be produced by Pseudomonas (Muller et al., 2011; Amani et al., 2013). Like PHA, the lipid moiety can originate either from lipid de novo synthesis or from beta-oxidation or from a combination of both pathways. The reported chain length of the lipid chains vary between 8 and 20 carbon atoms (Abdel-Mawgood et al., 2010). In combination with the defined synthesis of mono- and di-rhamnolipids, with one or two rhamnose residues, respectively (Ochsner et al., 1995), the synthesis of designer rhamnolipids is possible allowing the production of molecules tailored for a particular application. When choosing a chassis for recombinant rhamnolipid synthesis, two aspects have to be considered. (i) Rhamnolipids are reported to have an antimicrobial activity (Haba et al., 2014) and hence the host has to be tolerant against high rhamnolipid concentrations. The Gram positive bacteria Bacillus subtilis and Corynebacterium glutamicum can be excluded based on this criterion, while P. putida grows at a high rate at concentrations above 90 g l−1. (ii) Some species of Pseudomonads are (facultative) pathogens, which restrict their application at industrial scale. Pseudomonas putida KT2440, having GRAS status, is an attractive host for recombinant rhamnolipid and PHA production (Ochsner et al., 1995; Wittgens et al., 2011; Tortajada et al., 2013). Previously thought of recalcitrant waste plastics are now amenable to microbial biotechnology for the production of high-value products relevant to the circular economy. We believe that plastic waste can, and should be established as a novel second-generation carbon source for biotechnology. The analogy to the mega-developments in lignocellulosic biotech is clear: like biomass, plastic waste is simply a carbon-rich polymer. In fact, given the relatively simple and defined composition of plastics compared with biomass, as well as their extreme abundance, it is surprising that this resource has thus far gone mostly unnoticed as a biotechnology feedstock. Parallel developments to produce bio-based versions of fossil-based plastic monomers are already in place, e.g., ethylene, terephthalic acid, ethylene glycol, which will further contribute to the sustainability of plastics. When successful, plastic-upcycling through biotechnology will increase resource efficiency through the valorization of high-volume waste streams, while also helping to reduce the burden on terrestrial resources that are needed to supply food to the world's human population. Thus, through microbial biotechnology, the hereto proposed plastic waste to plastic value workflow will enable new value chains across sectors including materials, chemicals and environmental technologies within the framework of a sustainable knowledge-based bio-economy, with tangible benefits to the environment and society. None declared.

Escherichia coli W uses the aromatic compound 4-hydroxyphenylacetate (4-HPA) as a sole source of carbon and energy for growth. The monooxygenase which converts 4-HPA into 3,4-dihydroxyphenylacetate, the first intermediate of the pathway, consists of two components, HpaB (58.7 kDa) and HpaC (18.6 kDa), encoded by the hpaB and hpaC genes, respectively, that form a single transcription unit. Overproduction of the small HpaC component in E. coli K-12 cells has facilitated the purification of the protein, which was revealed to be a homodimer that catalyzes the reduction of free flavins by NADH in preference to NADPH. Subsequently, the reduced flavins diffuse to the large HpaB component or to other electron acceptors such as cytochrome c and ferric ion. Amino acid sequence comparisons revealed that the HpaC reductase could be considered the prototype of a new subfamily of flavin:NAD(P)H reductases. The construction of a fusion protein between the large HpaB oxygenase component and the choline-binding domain of the major autolysin of Streptococcus pneumoniae allowed us to develop a rapid method to efficiently purify this highly unstable enzyme as a chimeric CH-HpaB protein, which exhibited a 4-HPA hydroxylating activity only when it was supplemented with the HpaC reductase. These results suggest the 4-HPA 3-monooxygenase of E. coli W as a representative member of a novel two-component flavin-diffusible monooxygenase (TC-FDM) family. Relevant features on the evolution and structure-function relationships of these TC-FDM proteins are discussed.

The phaC1 gene codes for the medium-chain-length polyhydroxyalkanoate (mcl PHA) synthase of Pseudomonas oleovorans GPo1, which produces mcl PHA when grown in an excess of carbon source and under nitrogen limitation. In this work, we have demonstrated, by constructing a recombinant P. oleovorans strain carrying a phaC1::lacZ reporter system, that the phaC1 gene is expressed efficiently in the presence of octanoic acid while its expression is repressed when glucose or citrate is used as the carbon source. Moreover, a P. oleovorans GPo1 mutant (strain GPG-Tc6) expressing higher levels of the reporter gene than the wild-type strain in the presence of glucose or citrate has been generated by mini-Tn5 insertional mutagenesis. Characterization of this mutant allowed us to conclude that phaF, a gene located downstream of the pha gene cluster, was knocked out in this strain. P. oleovorans GPG-Tc6 regained the ability to control phaC1 gene expression when complemented with the phaF wild-type gene. Sequencing data revealed the presence of three complete open reading frames (ORFs) in this region: ORF1 and phaI and phaF genes. The amino acid sequences of the phaI gene product and the N-terminal half of the PhaF protein showed a significant degree of similarity. Furthermore, the primary structure of the PhaF C terminus identifies this protein as a member of the histone H1-like group of proteins. Northern blot analysis showed two transcription units containing phaF, i.e., phaF and phaIF transcripts. Expression of the phaIF operon is more efficient in the presence of octanoic acid and is enhanced by the lack of the PhaF protein. In addition, it has also been demonstrated that both PhaF and PhaI proteins are bound to PHA granules produced by P. oleovorans. A model for the role of PhaF in regulating PHA synthesis is presented.