Gelatin hydrogels find broad medical application. The current materials, however, are from animal sources, and their molecular structure and thermal properties cannot be controlled. This study describes recombinant gelatin-like polymers with a general design that inherently offers independent tuning of the cross-link density, melting temperature, and biocompatibility of the gel. The polymers contain small blocks with thermoreversible trimerization capacity and defined melting temperature, separated by hydrophilic nontrimerizing blocks defining the distance between the knot-forming domains. As an example, we report the secreted production in yeast at several g/L of two nonhydroxylated approximately 42 kDa triblock copolymers with terminal trimerizing blocks. Because only the end blocks formed cross-links, the molecular architecture of the gels is much more defined than that of traditional gelatins. The novel hydrogels had a approximately 37 degrees C melting temperature, and the dynamic elasticity was independent of the thermal history. The concept allows to produce custom-made precision gels for biomedical applications.
The microalgae Tetradesmus obliquus is able to maintain a high photosynthetic efficiency under nitrogen limitation and is considered a promising green microalgae for sustainable production of diverse compounds, including biofuels. Here, we report the first draft whole-genome shotgun sequencing of T. obliquus. The final assembly comprises 108,715,903 bp with over 1,368 scaffolds.
The gene encoding green fluorescent protein (GFP) from Aequorea victoria was resynthesized to adapt its codon usage for expression in plants by increasing the frequency of codons with a C or a G in the third position from 32 to 60%. The strategy for constructing the synthetic gfp gene was based on the overlap extension PCR method using 12 long oligonucleotides as the starting material and as primers. The new gene contains 101 silent nucleotide changes compared to its wild-type counterpart used in this study. Several transgenic tobacco lines containing the wild-type gfp gene contained minute amounts of a smaller protein cross-reacting with GFP antiserum, whereas only one protein of the expected size was found in transgenics with the synthetic gfp gene. The smaller protein was probably encoded by a truncated gfp mRNA created by splicing of a 84 bp cryptic intron as detected by a reverse transcription-PCR technique. A comparison of GFP production in transgenics with the wild-type and the synthetic gfp gene under the control of the enhanced CaMV 35S promoter showed that the large-scale alterations in the gfp gene increased the frequency of high expressors in the transgenic population but hardly changed the maximum GFP concentrations. The latter phenomenon may be attributed to a reduced regeneration capacity of transformed cells with higher GFP concentrations.
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