Mutational analysis of the lac regulatory region: second-site changes that activate mutant promoters

Combinatorial assembly platform enabling engineering of genetically stable metabolic pathways in cyanobacteria

Cyanobacteria are simple, efficient, genetically-tractable photosynthetic microorganisms which in principle represent ideal biocatalysts for CO2 capture and conversion. However, in practice, genetic instability and low productivity are key, linked problems in engineered cyanobacteria. We took a massively parallel approach, generating and characterising libraries of synthetic promoters and RBSs for the cyanobacterium Synechocystis sp. PCC 6803, and assembling a sparse combinatorial library of millions of metabolic pathway-encoding construct variants. Genetic instability was observed for some variants, which is expected when variants cause metabolic burden. Surprisingly however, in a single combinatorial round without iterative optimisation, 80% of variants chosen at random and cultured photoautotrophically over many generations accumulated the target terpenoid lycopene from atmospheric CO2, apparently overcoming genetic instability. This large-scale parallel metabolic engineering of cyanobacteria provides a new platform for development of genetically stable cyanobacterial biocatalysts for sustainable light-driven production of valuable products directly from CO2, avoiding fossil carbon or competition with food production.

DNA watermarks in non-coding regulatory sequences

Background

DNA watermarks can be applied to identify the unauthorized use of genetically modified organisms. It has been shown that coding regions can be used to encrypt information into living organisms by using the DNA-Crypt algorithm. Yet, if the sequence of interest presents a non-coding DNA sequence, either the function of a resulting functional RNA molecule or a regulatory sequence, such as a promoter, could be affected. For our studies we used the small cytoplasmic RNA 1 in yeast and the lac promoter region of Escherichia coli.

Findings

The lac promoter was deactivated by the integrated watermark. In addition, the RNA molecules displayed altered configurations after introducing a watermark, but surprisingly were functionally intact, which has been verified by analyzing the growth characteristics of both wild type and watermarked scR1 transformed yeast cells. In a third approach we introduced a second overlapping watermark into the lac promoter, which did not affect the promoter activity.

Conclusion

Even though the watermarked RNA and one of the watermarked promoters did not show any significant differences compared to the wild type RNA and wild type promoter region, respectively, it cannot be generalized that other RNA molecules or regulatory sequences behave accordingly. Therefore, we do not recommend integrating watermark sequences into regulatory regions.

Open complex formation during transcription initiation at the Escherichia coli galP1 promoter: the role of the RNA polymerase alpha subunit at promoters lacking an UP-element

We have studied the role of the C-terminal domain of the alpha subunit (alphaCTD) of Escherichia coli RNA polymerase during transcription initiation at promoters lacking an UP-element. The temperature requirement for open complex formation was used as an indication of the kinetics of this process. We have previously shown that alphaCTD is required for transcription initiation at low temperature at the galP1 promoter, a promoter containing an UP-element. DNase I footprinting has been used to reveal the structure of open promoter complexes and the temperature requirement for open complex formation has been determined using potassium permanganate as a probe. In this work we show that, although alphaCTD is not absolutely required for transcription initiation at promoters lacking an UP-element, it does play a role during transcription initiation. This role is independent of the sequence of the promoter upstream from the -35 region and does not require stable alphaCTD-DNA interactions as determined by DNase I footprinting. The role of alphaCTD at promoters lacking an UP-element is discussed.

Intracellular chitinase gene from Rhizopus oligosporus: molecular cloning and characterization

Multiple chitinases have been found in hyphae of filamentous fungi, which are presumed to have various functions during hyphal growth. Here it is reported, for the first time, the primary structure of one such intracellular chitinase, named chitinase III, from Rhizopus oligosporus, a zygomycete filamentous fungus. Chitinase III was purified to homogeneity from actively growing mycelia of R. oligosporus using three steps of column chromatography. Its molecular mass was 43.5 kDa and the pH optimum was 6.0 when p-nitrophenyl N,N',N"-beta-D-triacetylchitotrioside was used as a substrate. Chitinase III also hydrolysed chromogenic derivatives of chitobiose, but had no N-acetylglucosaminidase activity. The gene encoding chitinase III (chi3) was cloned using PCR with degenerate oligonucleotide primers from the partial amino acid sequence of the enzyme. The deduced amino acid sequence of chi3 was similar to that of bacterial chitinases and chitinases from mycoparasitic fungi, such as Aphanocladium album and Trichoderma harzianum, but it had no potential secretory signal sequence in its amino terminus. Northern blot analysis showed that chi3 was transcribed during hyphal growth. These results suggest that chitinase III may function during morphogenesis in R. oligosporus.

The lactose operon-controlling elements: a complex paradigm

The lactose-controlling elements have been considered to be the simple paradigm of a cis-acting genetic regulatory system, containing a promoter whose activity is modulated by an operator and a catabolite gene activator protein (CAP)-binding site. The reality is considerably more complex. We now know that transcription is negatively regulated as a result of the repressor binding to three binding sites: the operator, a secondary repressor-binding site within the lacZ gene and a tertiary repressor-binding site upstream near lacI. In addition to the promoter, the lac-controlling elements contain five promoter-like elements. The physiological role, if any, of these promoter-like elements is not clear, although three of them can be activated by single base pair changes to give high levels of in vivo expression. Finally, the positive activator protein CAP has been found to bind to a secondary site which is coincident with the operator. No role has been identified for this secondary CAP-DNA complex.

Transcriptional regulation of the cytR repressor gene of Escherichia coli: autoregulation and positive control by the cAMP/CAP complex

The Escherichia coli cytR-encoded repressor protein (CytR) controls the expression of several genes involved in nucleoside and deoxynucleoside uptake and metabolism. The cytR promoter was identified by determining the transcriptional initiation site of the cytR gene. A chromosomal cytR-lacZ+ operon fusion was isolated and used to study the regulation of cytR. We show that cytR expression is negatively controlled by the CytR protein and positively affected by the cAMP/CAP complex. Footprinting studies with purified CAP protein revealed two CAP binding sites upstream of the cytR promoter. A previously described mutation (cytR*) in the cloned cytR gene, which results in the phenotypic suppression of a CytR operator mutation in the tsx P2 promoter, was analysed. DNA sequence analysis of the cytR* mutation revealed a G-C to an A-T base pair transition at position -34 bp relative to the translational initiation site of cytR. This point mutation activates a cryptic promoter that is stronger than the wild-type cytR promoter and leads to overproduction of the CytR repressor.

Identification of nucleotides critical for activity of the Pseudomonas putida catBC promoter

Pseudomonas putida utilizes the catBC operon, which encodes cis,cis-muconate lactonizing enzyme I (MLEI; EC 5.5.1.1) and muconolactone isomerase (MI; EC 5.3.3.4), for growth on benzoate as a sole carbon source. This operon is positively regulated, and the promoter is located 64 bp upstream of the catB translational start site. Using site-specific mutagenesis, we identified nucleotides that influenced the induction of this promoter. Promoter activity was monitored with the promoter probe vector pKT240. Transcription of mRNA from mutant promoters was determined by primer extension mapping. Comparison of the initiation start site of mutant promoters with that of the wild-type promoter identified a single functional promoter.