Genetic determinant of Bacillus pumilus lipase lethality and its application as positive selection cloning vector in Escherichia coli.

Positive selection vectors carry genes that upon expression produce proteins that cause host cell deaths. Insertion of foreign DNA fragments within the ORF of the gene disrupts the lethal effect of the expressed protein. This study described the cloning of Family I.4 Bacillus pumilus lipase gene whose expressed protein is toxic and lethal to Escherichia coli JM109 (DE3) cells. The determinant of toxicity was identified through Error-prone PCR to be the nature of amino acid residue resident at position 28 of the mature lipase protein. The presence of Thr/Ser28 within the mature lipases of B. pumilus and B. licheniformis resulted in lethality to E. coli cells. However, the Thr28Ala or Thr28Gly mutations relieved the lethal phenotype of mature Family I.4 Bacillus lipases. The toxic effect of the expressed mature B. pumilus lipase protein was exploited in the development of a positive selection cloning vector. The B. pumilus lipase gene was synthesised to contain 13 unique silent restriction sites within the ORF, and placed under the regulation of T7 promoter of the pET expression system. Insertional inactivation of the gene's toxic protein was achieved by cloning DNA fragments of different sizes within the designed multiple cloning sites. The toxic effect of the lipase protein was disrupted indicating the potential of the gene for application in suicidal positive selection cloning vectors. The results revealed that protein expression and engineering studies aimed at optimal production of mature Family I.4 Bacillus lipases in E. coli should take into consideration the nature of amino acid 28 resident.

Accessing carboxylesterase diversity from termite hindgut symbionts through metagenomics.

A shotgun metagenomic library was constructed from termite hindgut symbionts and subsequently screened for esterase activities. A total of 68 recombinant clones conferring esterolytic phenotypes were identified, of which the 14 most active were subcloned and sequenced. The nucleotide lengths of the esterase-encoding open reading frames (ORFs) ranged from 783 to 2,592 bp and encoded proteins with predicted molecular masses of between 28.8 and 97.5 kDa. The highest identity scores in the GenBank database, from a global amino acid alignment ranged from 39 to 83%. The identified ORFs revealed the presence of the G-X-S-X-D, G-D-S-X, and S-X-X-K sequence motifs that have been reported to harbour a catalytic serine residue in other previously reported esterase primary structures. Five of the ORFs (EstT5, EstT7, EstT9, EstT10, and EstT12) could not be classified into any of the original eight esterase families. One of the ORFs (EstT9) showed a unique primary structure consisting of an amidohydrolase-esterase fusion. Six of the 14 esterase-encoding genes were recombinantly expressed in Escherichia coli and the purified enzymes exhibited temperature optima of between 40-50°C. Substrate-profiling studies revealed that the characterised enzymes were 'true' carboxylesterases based on their preferences for short to medium chain length p-nitrophenyl ester substrates. This study has demonstrated a successful application of a metagenomic approach in accessing novel esterase-encoding genes from the gut of termites that could otherwise have been missed by classical culture enrichment approaches.