A new protein immobilization and purification system has been developed based on the use of polyhydroxyalkanoates (PHAs, or bioplastics), which are biodegradable polymers accumulated as reserve granules in the cytoplasm of certain bacteria. The N-terminal domain of the PhaF phasin (a PHA-granule-associated protein) from Pseudomonas putida GPo1 was used as a polypeptide tag (BioF) to anchor fusion proteins to PHAs. This tag provides a novel way to immobilize proteins in vivo by using bioplastics as supports. The granules carrying the BioF fusion proteins can be isolated by a simple centrifugation step and used directly for some applications. Moreover, when required, a practically pure preparation of the soluble BioF fusion protein can be obtained by a mild detergent treatment of the granule. The efficiency of this system has been demonstrated by constructing two BioF fusion products, including a functional BioF--galactosidase. This is the first example of an active bioplastic consisting of a biodegradable matrix carrying an active enzyme.
Cadmium poses a significant threat to human health due to its toxicity. In mammals and in bakers' yeast, cadmium is detoxified by ATP-binding cassette transporters after conjugation to glutathione. In fission yeast, phytochelatins constitute the cosubstrate with cadmium for the transporter SpHMT1. In plants, a detoxification mechanism similar to the one in fission yeast is supposed, but the molecular nature of the transporter is still lacking. To investigate further the relationship between SpHMT1 and its co-substrate, we overexpressed the transporter in a Schizosaccharomyces pombe strain deleted for the phytochelatin synthase gene and heterologously in Saccharomyces cerevisiae and in Escherichia coli. In all organisms, overexpression of SpHMT1 conferred a markedly enhanced tolerance to cadmium but not to Sb(III), AgNO 3 , As(III), As(V), CuSO 4 , or HgCl 2 . Abolishment of the catalytic activity by expression of SpHMT1 K623M mutant suppressed the cadmium tolerance phenotype independently of the presence of phytochelatins. Depletion of the glutathione pool inhibited the SpHMT1 activity but not that of AtHMA4, a P-type ATPase, indicating that GSH is necessary for the SpHMT1-mediated cadmium resistance. In E. coli, SpHMT1 was targeted to the periplasmic membrane and led to an increased amount of cadmium in the periplasm. These results demonstrate that SpHMT1 confers cadmium tolerance in the absence of phytochelatins but depending on the presence of GSH and ATP. Our results challenge the dogma of the two separate cadmium detoxification pathways and demonstrate that a common highly conserved mechanism has been selected during the evolution from bacteria to humans.Cadmium is a trace element, the presence of which in the environment is essentially due to human activities. It is a highly toxic non-biological heavy metal able to enter living cells via transporters usually used for the uptake of essential cations such as calcium, iron, zinc, and so forth (1). The reactivity of cadmium with thiol groups and its ability to displace essential biological metals result in oxidative stress and eventually cell death (2). To cope with cadmium toxicity, living organisms have developed different strategies.In animals, as in the bakers' yeast cytoplasmic cadmium is complexed with the thiol tripeptide glutathione, a general redox regulator (3, 4). Bis(glutathionato)-cadmium complexes (Cd-GS 2 ) 4 are then driven from the cytoplasm to lesser sensitive cellular compartments by dedicated transporters. The prototypical transporter of Cd-GS 2 is the GS-X pump, ScYCF1, in Saccharomyces cerevisiae (5) and, even if still controversial, to a lesser extent HsMRP1 in humans (6). HsMRP1 probably acts as an efflux pump at the plasma membrane, delivering cadmium in the extracellular medium, whereas ScYCF1 allows sequestration of cadmium into the vacuole (5). A study of a deficient Scycf1 strain has shown that it was extremely cadmium-sensitive, pointing to a major role of ScYCF1 in cadmium tolerance and detoxification (5). Additionally, ScYCF1 wa...
A new tool to provide an environmentally friendly way to deliver active proteins to the environment has been developed, based on the use of polyhydroxyalkanoate (PHA, bioplastic) granules. To illustrate this novel approach, a derived Cry1Ab insect-specific toxin protein was in vivo immobilized into PHA granules through the polypeptide tag BioF. The new toxin, named Fk-Bt1, was shown to be active against Sesamia nonagrioides (Lepidoptera: Noctuidae). The dose-mortality responses of the new toxin granule formulation (PFk-Bt1) and purified Cry1Ab have been compared, demonstrating the effectiveness of PFk-Bt1 and suggesting a common mode of action.
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