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- Creators: Barrett, The Honors College
- Creators: Rittmann, Bruce
Improving cyanobacterial hydrogen production through bioprospecting of natural microbial communities
The production of sustainable biochemicals has been a major topic of discussion in recent years. Using microbial cells for their production through genetic engineering has been a major topic of research. Cyanobacteria have been considered as a viable candidate for such production. However, the slow growth rate of the cells presents a challenge for the possibility of scaling for use in industrial settings. This project focuses on two different solutions for this problem. The first is using four different engineered strains of Synechocystis sp. PCC 6803 that overexpress the proteins in the b6f complex to improve photosynthetic efficiency. It was found that the strains PetB and PetD showed an increase in growth rate compared to wild type cells. This was especially true under mixotrophic conditions and with a light intensity of 100 µmol photons*m-2s-1 for 3 days. The second solution is by using a newly discovered marine strain of cyanobacteria, Synechococcus sp. PCC 11901, which has a higher reported growth rate. Higher growth rates were achieved for this strain when it was grown mixotrophically with glycerol, and when grown in bubble cultures with aeration.
Measuring changes in concentration within a dynamic system can be accomplished with a simple Arduino powered system. Currently, the system is utilized in cyanobacteria CO2 fixation experiments, where the fixation rates of multiple cultures can be measured simultaneously. The system employs solenoids in parallel and can be applied for n number of outlet streams, all are connected to one large manifold which feeds to a CO2 concentration probe. In the future, the system can be modified to fit other simple dynamic gas systems.
In the hopes of providing other researchers with a new tool for markerless genetic engineering of cyanobacteria, the toxin MazF from E. coli was developed as a counter-selection marker in the most widely used cyanobacterium, Synechocystis sp. PCC 6803. The mazF gene from E. coli was cloned and inserted into a plasmid vector for downstream transformation of Synechocystis. The plasmid construct also contained two homologous flanking regions for integration of the insert into the Synechocystis genome, a nickel-inducible response regulator and promoter to control MazF expression, and a kanamycin resistance gene to serve as the antibiotic marker. In order to ensure the mazF plasmids could be cloned in a MazF-sensitive E. coli host even with slight promoter leakage, MazF expression was toned down by decreasing the efficiency of translation initiation by inserting base pairs between the ribosome binding site and the start codon of the mazF gene. Following successful cloning by E. coli, the mazF plasmids were then used to transform Synechocystis to create mazF mutant strains. Genomic analysis confirmed the successful transformation and segregation of mazF mutant strains containing the desired marker cassette. Phenotypic analysis revealed both growth arrest and production of mazF transcripts in mazF mutant strains following the addition of nickel to the cell cultures, indicating successful nickel-induced MazF expression as desired.
The DmJHAMT gene was cloned into a vector that contains neutral sites from the Synechocystis genome, making it suitable for homologous recombination, and a kanamycin resistance gene, for selection. The obtained plasmid was verified using restriction digests and Sanger sequencing. The sequence analysis and comparison of the cDNA in the obtained plasmid and the mRNA transcript of the same gene revealed three amino acid differences. Subsequent comparison with homologous genes in other Drosophila species revealed the differences in the cDNA match those of the other species, and thus, the gene most likely is functional.
The plasmid was transformed into Synechocystis, and PCRs were used to confirm proper integration and segregation. The TE/∆slr1609/DmJHAMT strain produced 62 mg/L methyl laurate in 12 days under a light intensity of 150 µmol photons m-2 s-1, bubbled with 0.5% CO2 at a rate of 30 mL/min, and supplemented with 0.5 mM methionine. The laurate levels did not decrease over time, but instead, remained stagnant after day 3. When the strain was grown in the same conditions without methionine, the laurate concentrations continued to increase above 400 µM, suggesting minimal methyl laurate production and thus a strong need for methionine supplementation. This work provides further evidence of the viability and success of the introduced FAME production pathway, and improved efficiency may be gained in the future.