Cell and Tissue Journal

Abstract Introduction: Concerns about fossil energy costs, environmental deterioration, and energy security has created strong motivation for the research and development of routes to provide sustainable and renewable fuels. In recent years, the use of biomass to produce highly valued chemicals has attracted widespread attention. Lignocellulosic biomass, as a promising renewable resource for biofuel production, has distinct advantages in terms of economic and environmental benefits. The conversion of renewable raw materials to hydrocarbon fuels is an attractive alternative to fossil fuels from economic and environmental perspectives. The production process of lignocellulosic biomass mainly consists of biomass accumulation, biomass decomposition, simple sugars, and conversion of sugars to biofuel. One of the crucial steps for the economic success of lignocellulosic biofuels depends on the inhibition of competitive metabolism in microorganisms to achieve high productivity. To date, there has been a growing focus on the use of S. cerevisiae and E. coli as cell lines. These two cellular factories have well known advantages. They are genetically transmissible and several tools are available for genetic manipulation. In order to produce xylonate, the engineered xylose is first converted by a dehydrogenase into the intermediate xylonolactone, which is then slowly converted to xylonate in a nonenzymatic reaction.
Aim: The organic compound D-1,2,4-Butanetriol (BT) is a valuable chemical with wide-ranging applications in various fields such as pharmaceuticals, paper, polymer materials, and military applications. However, the chemical synthesis routes for BT have many drawbacks. By genetically modifying microorganisms, the metabolic pathway for producing many substances, including BT, can be engineered. When D-xylose is supplied to the bacterium, it is first converted into an intermediate compound called xylonolactone. This compound slowly converts into xylonate through a non-enzymatic reaction. To produce xylonate, the engineered bacteria receive xylose, which is initially converted by a dehydrogenase reaction catalysed by the xylose dehydrogenase enzyme into an intermediate compound, xylonolactone. Xylonolactone is slowly converted to xylonate in a nonenzymatic reaction. Xylonate is a five-carbon organic acid. Over the past few years, xylonate has increasingly been considered as an important chemical due to its potential as an important chemical component. Xylonate has many applications in the food, chemical, and pharmaceutical industries. Specifically, xylonate can act as a precursor for the synthesis of D-1,2,4-Butanetriol and as a concrete water reducing agent. E. coli was chosen as the target strain for genetic and metabolic engineering due to its fast growth in inexpensive culture media, the presence of two enzymes for BT synthesis, and product formation in less than 24 hours of fermentation. This study aimed to clone and express xylose dehydrogenase from Caulobacter vibrioides in E.coli.
Materials and Methods: At first, to access the bacterial gene sequence, the genome of the target bacterium was extracted. Then, to create a strain expressing the enzymes xylose dehydrogenase and xylonolactonase, the genes for these proteins were amplified from Caulobacter vibrioides CB1 and transferred into E. coli. For this purpose, the target genes were amplified using specifically designed primers via the Polymerase Chain Reaction (PCR) method and initially cloned into a pTZ57cloning vector and then subcloned into pET 26b expression vector. At the final step, the expression of the enzyme was assessed by SDS-PAGE, and the other confirmation was the reduction of NAD+ to NADH, which was used as an activity indicator of the enzyme, as investigated by a change in NADH absorbance at 340 nm.
Results: Confirmatory tests were performed to ensure the presence of the gene in the vectors (using restriction enzymes and colony PCR for gene amplification). The expression and activity of the enzyme were analyzed. The recombinant protein's presence was confirmed by SDS-PAGE for the xylose dehydrogenase gene, with a molecular weight of 52.2 kDa. The estimated expression level of the recombinant protein was approximately 25%.
Conclusion: The objective of this research was solely to establish the metabolic pathway for xylonate production in E. coli by surface expression of enzymes in this pathway (xylose dehydrogenase). The results obtained in this study confirm that half of the pathway is active at the cell surface, but further experiments are required to determine the precise production levels and complete the pathway.