Cell-cell Communication Networks Research Articles

Artificial cell-cell communication in yeast Saccharomyces cerevisiae using signaling elements from Arabidopsis thaliana

The construction of synthetic cell-cell communication networks can improve our quantitative understanding of naturally occurring signaling pathways and enhance our capabilities to engineer coordinated cellular behavior in cell populations. Towards accomplishing these goals in eukaryotes, we developed and analyzed two artificial cell-cell communication systems in yeast. We integrated Arabidopsis thaliana signal synthesis and receptor components with yeast endogenous protein phosphorylation elements and new response promoters. In the first system, engineered yeast 'sender' cells synthesize the plant hormone cytokinin, which diffuses into the environment and activates a hybrid exogenous/endogenous phosphorylation signaling pathway in nearby engineered yeast 'receiver' cells. For the second system, the sender network was integrated into the receivers under positive-feedback regulation, resulting in population density-dependent gene expression (that is, quorum sensing). The combined experimental work and mathematical modeling of the systems presented here can benefit various biotechnology applications for yeast and higher level eukaryotes, including fermentation processes, biomaterial fabrication and tissue engineering.

Disruption of Gja8 (alpha8 connexin) in mice leads to microphthalmia associated with retardation of lens growth and lens fiber maturation.

The development of the vertebrate lens utilizes a sophisticated cell-cell communication network via gap junction channels, which are made up of at least three connexin isoforms, alpha8 (Cx50), alpha3 (Cx46) and alpha1 (Cx43), and which are encoded by three different genes. In a previous study, we reported that, with a disruption of Gja3 (alpha3 connexin), mice developed nuclear cataracts with a normal sized lens. We show that Gja8tm1 (alpha8-/-) mice develop microphthalmia with small lenses and nuclear cataracts, while the alpha8 heterozygous (+/-) mice have relatively normal eyes and lenses. A comparative study of these alpha3 and alpha8 knockout mice showed that the protein levels of both alpha3 and alpha8 were independently regulated and there was no compensation for either the alpha3 or alpha8 protein from the wild-type allele when the other allele was disrupted. More interestingly, western blotting data indicated that the presence of alpha8 in the lens nucleus is dependent on alpha3 connexin, but not vice versa. The staining of the knock-in lacZ reporter gene showed the promoter activity of alpha8 connexin is much higher than that of alpha3 connexin in embryonic lenses and in adult lens epithelium. More importantly, a delayed denucleation process was observed in the interior fibers of the alpha8-/- lenses. Therefore, alpha8 connexin is required for proper fiber cell maturation and control of lens size.