Recombinant carbazole-degrading strains for enhanced petroleum processing

Biotechnological upgrading of fossil fuels is of increasing interest as remaining stocks of petroleum show increasing levels of contaminants such as heavy metals, sulfur and nitrogen-containing heteroaromatic compounds. Carbazole is of particular interest as a major petroleum component known to reduce refining yields through catalyst poisoning. In this study, the biotransformation of carbazole was successfully demonstrated in a liquid two-phase system, when solubilized in either 1-methylnaphthalene or in diesel fuel. The effects of solvent toxicity were investigated by expressing the carbazole-transformation genes from MB1332, a rifampicin-resistant derivative of Pseudomonas sp. LD2, in a solvent-resistant heterologous host, P. putida Idaho [1]. This solvent-resistant strain successfully degraded carbazole solubilized in 1-methylnaphthalene and in the presence of 10 vol% xylenes similar to the non-recombinant strain Pseudomonas sp. LD2. Identification of a suitable recombinant host, however, was essential for further investigations of partial pathway transformations. Recombinant P. putida Idaho expressing only the initial dioxygenase enzymes transformed carbazole to an intermediate well retained in the oil phase. Partial carbazole transformation converts carbazole to non-aromatic species; their effect is unknown on refinery catalyst poisoning, but would allow almost complete retention of carbon content and fuel value. Electronic Publication     

Genome mining of cyanide-degrading nitrilases from filamentous fungi

A variety of fungal species are known to degrade cyanide through the action of cyanide hydratases, a specialized subset of nitrilases which hydrolyze cyanide to formamide. In this paper, we report on two previously unknown and uncharacterized cyanide hydratases from Neurospora crassa and Aspergillus nidulans. Recombinant forms of four cyanide hydratases from N. crassa, A. nidulans, Gibberella zeae, and Gloeocercospora sorghi were prepared after their genes were cloned with N-terminal hexahistidine purification tags, expressed in Escherichia coli, and purified using immobilized metal affinity chromatography. These enzymes were compared according to their relative specific activity, pH activity profiles, thermal stability, and ability to remediate cyanide contaminated waste water from silver and copper electroplating baths. Although all four were similar, the N. crassa cyanide hydratase (CHT) has the greatest thermal stability and widest pH range of >50% activity. N. crassa also demonstrated the highest rate of cyanide degradation in the presence of both heavy metals. The CHT of A. nidulans has the highest reaction rate of the four fungal nitrilases evaluated in this work. These data will help determine optimization procedures for the possible use of these enzymes in the bioremediation of cyanide-containing waste. Similar to known plant pathogenic fungi, both N. crassa and A. nidulans were induced to express CHT by growth in the presence of KCN.     

Alterations in the amino-terminal third of mouse interleukin 2: effects on biological activity and immunoreactivity

In this report, we describe plasmids that direct the expression of active mouse interleukin 2 (mIL 2) in Escherichia coli, and the use of this expression system to perform a mutational analysis of the N-terminal region of the mIL 2 protein. We found that the N-terminus was tolerant to the addition of a few amino acids, and even the addition of 20 amino acids resulted in only a modest decrease in activity of the protein. The bioactivity of mIL 2 as defined by its ability to sustain the proliferation of cloned T cells was also only minimally affected by deletion of up to 13 N-terminal amino acids, or of the entire poly-GLN stretch (amino acids 15-26). Deletion of the 30 N-terminal amino acids drastically reduced but did not abolish activity. Deletion of the 41 N-terminal amino acids completely abolished activity, whereas certain changes in the initial 37 amino acids drastically reduced the biological activity of the protein. We also analyzed the immunoreactivity of the mutant proteins with the anti-IL 2 monoclonal antibodies S4B6 and DMS-1. This analysis showed that the determinant recognized by S4B6 required that the N-terminal mIL 2 amino acids 26-45 be intact, whereas the DMS-1 determinant was located to the C-terminal side of amino acid 46.     

Cyanide bioremediation: the potential of engineered nitrilases

The cyanide-degrading nitrilases are of notable interest for their potential to remediate cyanide contaminated waste streams, especially as generated in the gold mining, pharmaceutical, and electroplating industries. This review provides a brief overview of cyanide remediation in general but with a particular focus on the cyanide-degrading nitrilases. These are of special interest as the hydrolysis reaction does not require secondary substrates or cofactors, making these enzymes particularly good candidates for industrial remediation processes. The genetic approaches that have been used to date for engineering improved enzymes are described; however, recent structural insights provide a promising new approach.

     

The cyanide hydratase from <Emphasis Type="Italic">Neurospora crassa</Emphasis> forms a helix which has a dimeric repeat

The fungal cyanide hydratases form a functionally specialized subset of the nitrilases which catalyze the hydrolysis of cyanide to formamide with high specificity. These hold great promise for the bioremediation of cyanide wastes. The low resolution (3.0 nm) three-dimensional reconstruction of negatively stained recombinant cyanide hydratase fibers from the saprophytic fungus Neurospora crassa by iterative helical real space reconstruction reveals that enzyme fibers display left-handed D₁ S_5.4 symmetry with a helical rise of 1.36 nm. This arrangement differs from previously characterized microbial nitrilases which demonstrate a structure built along similar principles but with a reduced helical twist. The cyanide hydratase assembly is stabilized by two dyadic interactions between dimers across the one-start helical groove. Docking of a homology-derived atomic model into the experimentally determined negative stain envelope suggests the location of charged residues which may form salt bridges and stabilize the helix.     

Secretion of nuclease across the outer membrane of Serratia marcescens and its energy requirements.

Extracellular secretion of Serratia marcescens nuclease occurs as a two-step process via a periplasmic intermediate. Unlike other extracellular proteins secreted by gram-negative bacteria by the general secretory pathway, nuclease accumulates in the periplasm in its active form for an unusually long time before its export into the growth medium. The energy requirements for extracellular secretion of nuclease from the periplasm were investigated. Our results suggest that the second step of secretion across the outer membrane is dependent upon the external pH; acidic pH effectively but reversibly blocks extracellular secretion. However, electrochemical proton gradient, and possibly ATP hydrolysis, are not required for this step. We suggest that nuclease uses a novel mechanism for the second step of secretion in S. marcescens.