Time-resolved NMR metabolomics of plant cells based on a microfluidic chip.

The plant secondary metabolism generates numerous compounds harbouring pharmaceutical activity. In plants, these compounds are typically formed by different and specialised cell types that have to interact constituting a metabolic process chain. This interactivity impedes biotechnological production of secondary compounds, because cell differentiation is suppressed under the conditions of a batch bio-fermenter. We present a novel strategy to address this limitation using a biomimetic approach, where we simulate the situation in a real tissue by a microfluidic chamber system, where plant cells can be integrated into a process flow. We show that walled cells of the plant model tobacco BY-2 can be successfully cultivated in this system and that physiological parameters (such as cell viability, mitotic index and division synchrony) can be preserved over several days. The microfluidic design allows to resolve dynamic changes of specific metabolites over different stages of culture development. These results serve as proof-of-principle that a microfluidic organisation of cultivated plant cells can mimic the metabolic flows in a real plant tissue.

Naturally occurring biodegradable polymers as the basis of chiral gels for the distinction of enantiomers by partially oriented NMR spectroscopy.

INTRODUCTION: In modern, high resolution NMR spectroscopy, anisotropic parameters play an important role. They can be measured with the help of liquid crystalline mesophases or stretched polymer gels as so-called alignment media. Biologically occurring chiral polymers are of special interest as alignment media for this technique because they allow enantiomers to be distinguished. METHODS: Biopolymers have been studied by deuterium 1D and J-BIRDd,X-HSQC NMR experiments with respect to their ability to distinguish enantiomers and a summary of existing biopolymers for the task is given. RESULTS: Gelatin is shown to distinguish D-proline from L-proline and next to already known biopolymers, gellan gum is introduced as a novel biologically derived polymer that is able to partially align solute molecules. CONCLUSIONS: Biologically occurring and biodegradable polymers are well suited as alignment media and in many cases are able to distinguish enantiomers. As the orienting properties are different for different media and solute molecules, the bandwidth of corresponding polymers will be further increased in the future.