57 research outputs found
Phenolic compounds and expression of 4CL genes in silver birch clones and Pt4CL1a lines
A small multigene family encodes 4-coumarate:CoA ligases (4CLs) catalyzing the CoA ligation of hydroxycinnamic acids, a branch point step directing metabolites to a flavonoid or monolignol pathway. In the present study, we examined the effect of antisense Populus tremuloides 4CL (Pt4CL1) to the lignin and soluble phenolic compound composition of silver birch (Betula pendula) Pt4CL1a lines in comparison with non-transgenic silver birch clones. The endogenous expression of silver birch 4CL genes was recorded in the stems and leaves and also in leaves that were mechanically injured. In one of the transgenic Pt4CL1a lines, the ratio of syringyl (S) and guaiacyl (G) lignin units was increased. Moreover, the transcript levels of putative silver birch 4CL gene (Bp4CL1) were reduced and contents of cinnamic acid derivatives altered. In the other two Pt4CL1a lines changes were detected in the level of individual phenolic compounds. However, considerable variation was found in the transcript levels of silver birch 4CLs as well as in the concentration of phenolic compounds among the transgenic lines and non-transgenic clones. Wounding induced the expression of Bp4CL1 and Bp4CL2 in leaves in all clones and transgenic lines, whereas the transcript levels of Bp4CL3 and Bp4CL4 remained unchanged. Moreover, minor changes were detected in the concentrations of phenolic compounds caused by wounding. As an overall trend the wounding decreased the flavonoid content in silver birches and increased the content of soluble condensed tannins. The results indicate that by reducing the Bp4CL1 transcript levels lignin composition could be modified. However, the alterations found among the Pt4CL1a lines and the non-transgenic clones were within the natural variation of silver birches, as shown in the present study by the clonal differences in the transcripts levels of 4CL genes, soluble phenolic compounds and condensed tannins
Absorption and birefringence study for reduced optical losses in diamond with high NV concentration
The use of diamond color centers such as the nitrogen-vacancy (NV) center is
increasingly enabling quantum sensing and computing applications. Novel
concepts like cavity coupling and readout, laser threshold magnetometry and
multi-pass geometries allow significantly improved sensitivity and performance
via increased signals and strong light fields. Enabling material properties for
these techniques and their further improvements are low optical material losses
via optical absorption of signal light and low birefringence. Here we study
systematically the behavior of absorption around 700 nm and birefringence with
increasing nitrogen- and NV-doping, as well as their behavior during NV
creation via diamond growth, electron beam irradiation and annealing
treatments. Absorption correlates with increased nitrogen-doping yet
substitutional nitrogen does not seem to be the direct absorber. Birefringence
reduces with increasing nitrogen doping. We identify multiple crystal defect
concentrations via absorption spectroscopy and their changes during the
material processing steps and thus identify potential causes of absorption and
birefringence as well as strategies to fabricate CVD diamonds with high NV
density yet low absorption and low birefringence.Comment: Accepted by Philosophical Transactions A (DOI:
10.1098/rsta.2022.0314
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