Emiliania huxleyi, a ubiquitous marine algae, was cultured under replete and Cu-limiting conditions to investigate Cu uptake strategies involving thiols and associated redox reactions; comparisons to a model diatom, Thalassiosira pseudonana, were also drawn. Cu-limitation increased rates of cell surface reduction of Cu(II) to Cu(I) in E. huxleyi but not in T. pseudonana. Furthermore, Cu-limited E. huxleyi cells took up more Cu when cysteine was present compared to when no ligand was added, although a dependence on cysteine concentration was not observed. In contrast, Cu uptake by replete cells was dependent upon the relative abundance of inorganic species [Cu(I)']. We also show that cysteine can increase the bioavailability of Cu to Cu-limited cells, of both species, through the reductive release of Cu(I) from fairly strong Cu(II) ligands such as EDTA. Finally, support for a mechanism involving uptake of a Cys-Cu complex in E. huxleyi is drawn from the observation that Cu-limitation significantly enhances cysteine uptake by transporters that exhibit Michaelis-Menten kinetics. These Cu uptake strategies help explain the presence and distribution of dissolved thiols in surface seawater and have implications for the biogeochemical cycling of Cu in low Cu environments.
The
composition of cell-free expression systems (TX-TL) is adjusted
by adding macromolecular crowding agents and salts. However, the effects
of these cosolutes on the dynamics of individual gene expression processes
have not been quantified. Here, we carry out kinetic mRNA and protein
level measurements on libraries of genetic constructs using the common
cosolutes PEG-8000, Ficoll-400, and magnesium glutamate. By combining
these measurements with biophysical modeling, we show that cosolutes
have differing effects on transcription initiation, translation initiation,
and translation elongation rates with trade-offs between time delays,
expression tunability, and maximum expression productivity. We also
confirm that biophysical models can predict translation initiation
rates in TX–TL using Escherichia coli lysate. We discuss how cosolute composition can be tuned to maximize
performance across different cell-free applications, including biosensing,
diagnostics, and biomanufacturing.
Sporulated cells have potential as time-delayed expression chassis of proteins for applications such as 'on-demand' biologics production, whole cell biosensors, or oral vaccines. However, the desired attributes of high expression rates and low product variances are difficult to maintain from germinated spores. In this work we study the effect of an integrating vs. theta replicating plasmid in a wild-type Bacillus subtilis and two PolY mutants. The cells were engineered to produce a fluorescent reporter protein (RFP) under the control of a riboswitch activated by theophylline. This allowed for greater sensitivity to point mutations. The fluorescence and cell growth curves were fit with a custom kinetic model and a peak kinetic rate (LKP max ) was extracted for each clonal population (n = 30 for all cell, vector, and growth combinations). Plasmid based expression yields higher (8.7x) expression rates due to an increased copy number of the expression cassette (10x over integrated). The variance of LKP max values increased 2.07x after sporulation for the wild type strain. This increase in variance from sporulation is very similar to what is observed with UV exposure. This effect can be partially mitigated by the use of PolY knockouts observed in suspended cell growths and adherent biofilms.
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