A synthetic system for expression of components of a bacterial microcompartment

Frank Sargent,Emelie Johansson,Katarzyna Kozyrska,Ciarán L Kelly,Rachel Montague,Brian Ortmann,Jane Maccallum,Fordyce A Davidson,Alan R Prescott,David Gibson,Lucia Licandro Lado,Sarah J Coulthurst,Rachelle Binny,Tracy Palmer,Lionel Dupuy,Richard Owen,Natasha Christodoulides

doi:10.1099/mic.0.069922-0

Frank Sargent, Emelie Johansson + Show 15 more

Open Access

https://doi.org/10.1099/mic.0.069922-0

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Journal: Microbiology	Publication Date: Sep 6, 2013
Citations: 57	License type: cc-by

Affiliation: University of Dundee, James Hutton Institute

Abstract

In general, prokaryotes are considered to be single-celled organisms that lack internal membrane-bound organelles. However, many bacteria produce proteinaceous microcompartments that serve a similar purpose, i.e. to concentrate specific enzymic reactions together or to shield the wider cytoplasm from toxic metabolic intermediates. In this paper, a synthetic operon encoding the key structural components of a microcompartment was designed based on the genes for the Salmonella propanediol utilization (Pdu) microcompartment. The genes chosen included pduA, -B, -J, -K, -N, -T and -U, and each was shown to produce protein in an Escherichia coli chassis. In parallel, a set of compatible vectors designed to express non-native cargo proteins was also designed and tested. Engineered hexa-His tags allowed isolation of the components of the microcompartments together with co-expressed, untagged, cargo proteins. Finally, an in vivo protease accessibility assay suggested that a PduD–GFP fusion could be protected from proteolysis when co-expressed with the synthetic microcompartment operon. This work gives encouragement that it may be possible to harness the genes encoding a non-native microcompartment for future biotechnological applications.

Highlights

Compartmentalization of biochemical processes is an essential feature of all cellular systems
In enteric bacteria such as Salmonella and Citrobacter freundii, well-characterized bacterial microcompartment (BMC) are used in propanediol utilization, with the rationale for compartmentalization being the protection of the cell from a potentially toxic aldehyde intermediate (Kerfeld et al, 2010)
The Salmonella propanediol utilization (Pdu) BMC is thought to be broadly similar in structure to the carboxysome (Frank et al, 2013), given the conserved nature of the predicted shell proteins, and it is possible that a Pdu-based BMC will assemble to form something close to an icosahedral structure

Summary

Introduction

Compartmentalization of biochemical processes is an essential feature of all cellular systems. The occurrence of membrane-bound organelles is well documented for eukaryotic systems and it is well established that Gramnegative bacteria house specialized biochemical processes in their periplasms. It has become increasingly clear that proteinaceous subcellular compartments akin to organelles are utilized by some prokaryotes and that they serve to partition specific metabolic pathways from the bulk cytoplasm BMCs have been associated with other metabolic processes such as 1,2-propanediol catabolism and ethanolamine degradation (Bobik et al, 1999; Kofoid et al, 1999) – pathways that require the activity of more than five different enzymes plus associated cofactors

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