Manipulating intradiol dioxygenases by C-terminus truncation.

Intradiol dioxygenases (EC 1.13.11.1) are bacterial enzymes that catalyze the ring cleavage of catechols which is a central step in the aerobic degradation of aromatic compounds. Some members of this enzyme group have a C-terminus which is 4-5% longer (an additional 13-18 amino acids) compared to the majority of known sequences. The longer C-terminus itself is not highly conserved and appears to be poorly integrated in the protein structural models developed for representative intradiol dioxygenases. Using a protein engineering approach variant intradiol dioxygenases were produced by truncating the C-terminus to a size comparable to the shorter versions of the enzyme. Three enzymes were selected and were originally described from the model organisms; Burkholderia xenovorans LB400, Pseudomonas putida KT2440 and Acinetobacter baylyi ADP1. The activity of the truncated enzymes were compared to the unmodified enzymes which revealed that truncation of the C-terminus could alter the enzyme activity; increasing the LB400 enzyme activity by as much as five fold, but reducing the activity of the intradiol dioxygenases from KT2440 and ADP1. The difference in effect is explained by the presence of a greater number of amino acid residues that can contribute to forming stable protein structures in the KT2440 and ADP1 enzymes. It is hypothesized that C-terminal truncation could in some cases provide a useful strategy for increasing intradiol dioxygenase activity for biotechnological production of muconic and adipic acids.

Versatile catechol dioxygenases in Sphingobium scionense WP01T.

The objective was to understand the roles of multiple catechol dioxygenases in the type strain Sphingobium scionense WP01T (Liang and Lloyd-Jones in Int J Syst Evol Microbiol 60:413-416, 2010a) that was isolated from severely contaminated sawmill soil. The dioxygenases were identified by sequencing, examined by determining the substrate specificities of the recombinant enzymes, and by quantifying gene expression following exposure to model priority pollutants. Catechol dioxygenase genes encoding an extradiol xylE and two intradiol dioxygenases catA and clcA that are highly similar to sequences described in other sphingomonads are described in S. scionense WP01T. The distinct substrate specificities determined for the recombinant enzymes confirm the annotated gene functions and suggest different catabolic roles for each enzyme. The role of the three enzymes was evaluated by analysis of enzyme activity in crude cell extracts from cells grown on meta-toluate, benzoate, biphenyl, naphthalene and phenanthrene which revealed the co-induction of each enzyme by different substrates. This was corroborated by quantifying gene expression when cells were induced by biphenyl, naphthalene and pentachlorophenol. It is concluded that the ClcA and XylE enzymes are recruited in pathways that are involved in the degradation of chlorinated aromatic compounds such as pentachlorophenol, the XylE and ClcA enzymes will also play a role in degradation pathways that produce alkylcatechols, while the three enzymes ClcA, XylE and CatA will be simultaneously involved in pathways that generate catechol as a degradation pathway intermediate.

The crystal structures of dystrophin and utrophin spectrin repeats: implications for domain boundaries.

Dystrophin and utrophin link the F-actin cytoskeleton to the cell membrane via an associated glycoprotein complex. This functionality results from their domain organization having an N-terminal actin-binding domain followed by multiple spectrin-repeat domains and then C-terminal protein-binding motifs. Therapeutic strategies to replace defective dystrophin with utrophin in patients with Duchenne muscular dystrophy require full-characterization of both these proteins to assess their degree of structural and functional equivalence. Here the high resolution structures of the first spectrin repeats (N-terminal repeat 1) from both dystrophin and utrophin have been determined by x-ray crystallography. The repeat structures both display a three-helix bundle fold very similar to one another and to homologous domains from spectrin, α-actinin and plectin. The utrophin and dystrophin repeat structures reveal the relationship between the structural domain and the canonical spectrin repeat domain sequence motif, showing the compact structural domain of spectrin repeat one to be extended at the C-terminus relative to its previously defined sequence repeat. These structures explain previous in vitro biochemical studies in which extending dystrophin spectrin repeat domain length leads to increased protein stability. Furthermore we show that the first dystrophin and utrophin spectrin repeats have no affinity for F-actin in the absence of other domains.