Construction of à la carte QconCAT protein standards for multiplexed quantification of user-specified target proteins

Background QconCATs are quantitative concatamers for proteomic applications that yield stoichiometric quantities of sets of stable isotope-labelled internal standards. However, changing a QconCAT design, for example, to replace poorly performing peptide standards has been a protracted process. Results We report a new approach to the assembly and construction of QconCATs, based on synthetic biology precepts of biobricks, making use of loop assembly to construct larger entities from individual biobricks. The basic building block (a Qbrick) is a segment of DNA that encodes two or more quantification peptides for a single protein, readily held in a repository as a library resource. These Qbricks are then assembled in a one tube ligation reaction that enforces the order of assembly, to yield short QconCATs that are useable for small quantification products. However, the DNA context of the short construct also allows a second cycle of loop assembly such that five different short QconCATs can be assembled into a longer QconCAT in a second, single tube ligation. From a library of Qbricks, a bespoke QconCAT can be assembled quickly and efficiently in a form suitable for expression and labelling in vivo or in vitro. Conclusions We refer to this approach as the ALACAT strategy as it permits à la carte design of quantification standards. ALACAT methodology is a major gain in flexibility of QconCAT implementation as it supports rapid editing and improvement of QconCATs and permits, for example, substitution of one peptide by another.

Parameterization of regulatory nodes for engineering broad host range heterologous gene expression

By building on the SEVA (Standard European Vector Architecture) format we have refactored a number of regulatory nodes recruited from both Gram-negative and Gram-positive bacteria for rigorously comparing and parameterizing five expression devices that respond to diverse and unrelated chemical inducers, i.e. LacIq-Ptrc, XylS-Pm, AlkS-PalkB, CprK-PDB3 and ChnR-PchnB. These were assembled as cargoes following the SEVA standard within exactly the same vector backbone and bearing the different functional segments arrayed in an invariable DNA scaffold. Their performance in an Escherichia coli strain of reference were then analyzed through the readout a fluorescence reporter gene that contained strictly identical translation signal elements in all cases and in the same DNA context. This study allowed us to describe and compare the cognate expression systems with unprecedented quantitative detail. The systems under scrutiny diverged considerably in their capacity, expression noise, inducibility and OFF/ON ratios. These features, along with the absence of physiological effects caused by the inducers and the lack of cross regulation offer a panoply of choices to potential users and help interoperability of the specific constructs.

Synthetic biology meets proteomics: Construction of a la carte QconCATs for absolute protein quantification

We report a new approach to the assembly and construction of QconCATs, quantitative concatamers for proteomic applications that yield stoichiometric quantities of sets of stable isotope-labelled internal standards. The new approach is based on synthetic biology precepts of biobricks, making use of loop assembly to construct larger entities from individual biobricks. It offers a major gain in flexibility of QconCAT implementation and enables rapid and efficient editability that permits, for example, substitution of one peptide for another. The basic building block (a Qbrick) is a segment of DNA that encodes two or more quantification peptides for a single protein, readily held in a repository as a library resource. These Qbricks are then assembled in a one tube ligation reaction that enforces the order of assembly, to yield short QconCATs that are useable for small quantification products. However, the DNA context of the short also allows a second cycle of assembly such that five different short QconCATs can be assembled into a longer QconCAT in a second, single tube ligation. From a library of Qbricks, a bespoke QconCAT can be assembled quickly and efficiently in a form suitable for expression and labelling in vivo or in vitro. We refer to this approach as the ALACAT strategy as it permits a la carte design of quantification standards.