Studies of the Carbon and Energy Metabolism in the Moss Physcomitrella patens

Nilsson, Anders

January 2009

Since a proper balance between anabolic and catabolic reactions is essential for all eukaryotes, the basic mechanisms for regulation of the energy and carbon metabolism have been conserved throughout evolution. The moss Physcomitrella patens, which belongs to one of the basal clades among land plants, has many unique properties that make it an excellent plant model system. We have used a yeast two-hybrid system to identify novel possible regulators or targets of the moss Snf1-related kinases, previously shown to regulate energy homeostasis. The function of the identified interactors PpSki1 and PpSki2 was analyzed in order to better understand the biological role of plant Snf1-related kinases. The recently completed genome sequence of Physcomitrella was used in a comparative approach to study to what extent key enzyme and gene families involved in transport and metabolism of sugars and in regulation of the energy and carbon metabolism are conserved between mosses and vascular plants. It has long been known that transformed DNA can replicate episomally in Physcomitrella. We have now shown that such DNA can be rescued back into E. coli. Surprisingly, we found that the original plasmid can be recovered from moss transformants obtained with circular DNA. Plasmids rescued from transformants obtained with linearized DNA had been repaired either by homologous recombination or by cohesive end re-ligation. These findings suggest that methods using shuttle plasmids are feasible in Physcomitrella. Hexokinase, a key enzyme in the carbon metabolism, catalyzes the first step in hexose metabolism, but is also involved in sugar sensing and signaling. We have now made an initial characterization of the complete hexokinase family in Physcomitrella which is encoded by 11 genes. Two new types of plant hexokinases, types C and D, were found in addition to the previously described types A and B.

Hexokinase

SnRK1

sugar signaling

carbon metabolism

Physcomitrella patens

shuttle vector

subcellular localization

model organism

Molecular biology

Molekylärbiologi

DEVELOPMENT OF AN ADVANCED GENETIC TOOLBOX TO ENABLE GENOME SCALE ENGINEERING IN SINORHIZOBIUM MELILOTI

MacLeod, Michael R.

January 2018

Synthetic biology has ushered in a new age of molecular biology with the aim towards practical developments in disciplines ranging from medicine, agriculture, and industry. Presently, it remains difficult to manipulate the genomes of many organisms due to lack of genetic tools. These problems can be circumvented by cloning large fragments of DNA into strains where many genetic tools are in place, such as Saccharomyces cerevisiae. However, this organism is unable to directly transfer cloned DNA to other organisms and is unable to stably maintain DNA with a G+C content >40%. Many organisms relevant in biotechnology often have G+C content DNA >60%, and therefore are difficult to engineer. Here, the soil bacteria Sinorhizobium meliloti was chosen as a host strain to clone and manipulate large fragments of high G+C content DNA. S. meliloti is a Gram-negativeα-proteobacteria that forms symbiotic relationships with legumes to fix nitrogen. It has a multi-partite genome with a G+C content of 62.7% that includes a chromosome (3.65 Mb), the pSymA (1.35 Mb), and pSymB (1.68 Mb) replicons. A restriction endonuclease hsdR mutant strain lacking pSymA and pSymB was created and used in this study. Multi-host shuttle (MHS) vectors were constructed that allow for direct transfer and maintenance of DNA in E. coli, S. cerevisiae, and P. tricornutum. Characterization of strains was conducted to determine transduction, conjugation, and transformation frequencies, as well as stability of MHS plasmids. Furthermore, a proof-of-concept experiment was conducted to clone large plasmids (70-205 kb) with G+C content >58% via site-specific recombination at a landing pad in the MHS vector, which was then verified using colony PCR. This work demonstrates the usefulness of S. meliloti containing a MHS vector for cloning of large fragments with high G+C content DNA, a technology that may be used for several applications in both applied and basic research. / Thesis / Master of Science (MSc) / Synthetic biology is an emerging field that incorporates principles of molecular biology and engineering for the design and construction of biological systems for application in medicine, agriculture, and industry. Presently, it remains difficult to modify genomes of several organisms due to lack of available techniques. Yeast is currently used for the modification of large DNA pieces, however it is unable to transfer and maintain modified DNA with high G+C content. Here, the bacteria Sinorhizobium meliloti was used as a host organism to conduct genetic engineering due to its ability to maintain large DNA pieces with a high G+C content. Characterization experiments were conducted to assess the efficiency of this organism for this task. Using this strain, a proof-of-concept experiment to demonstrate the uptake and maintenance of large, high G+C DNA pieces was completed. This technology may be useful in biotechnology applications for engineering of large DNA pieces from industrially relevant organisms.

Synthetic biology

Genetic engineering

high G+C content

Sinorhizobium meliloti

multi-host shuttle vector

site-specific recombination

biotechnology

S. cerevisiae

P. tricornutum