The mechanism of oxygen sensing by the global transcriptional regulator FNR
Lead Research Organisation:
University of East Anglia
Department Name: Chemistry
Abstract
Bacteria inhabit almost every environmental niche on Earth, including some that are so harsh that many other forms of life cannot survive. This success is at least in part due to the ability of bacteria to adapt to changes in environment, and this adaptation is rooted in their capacity to alter patterns of gene expression in response to external and internal cues. A key environmental parameter that is monitored by many bacteria is oxygen concentration. We are particularly interested in the bacterium Escherichia coli (E. coli). One of its remarkable properties is that it is able to thrive both in the presence and absence of oxygen. To do this it has to dramatically alter its metabolism, but this has consequences because without oxygen the potential for energy conservation and growth are limited compared to when oxygen is present. To test whether oxygen is present E. coli uses a protein called FNR, which acts as an oxygen sensor. It has a special co-factor called an iron-sulfur cluster that reacts with oxygen in a way that switches FNR off. In the 'off-state' (no iron-sulfur cluster) FNR cannot bind to DNA to activate expression of genes that are used during growth in the absence of oxygen. When there is no oxygen the iron-sulfur remains associated with FNR and so the protein can bind to DNA and activate expression of genes that are needed for growth in the absence of oxygen. For the last few years we have studied the reaction of oxygen with the FNR iron-sulfur cluster. These studies have revealed the complex biochemistry of the reaction and how this makes the FNR protein an exquisitely sensitive oxygen sensor. However, our studies have raised even more questions. We now propose to address some of these by determining the molecular choreography of the reaction of oxygen with the FNR iron-sulfur cluster and how this leads to altered DNA-binding properties. We will also investigate how the potentially toxic reaction products are managed by the cell, and why some bacteria have more than one FNR protein; could it be that different FNR proteins have evolved to operate in different ranges of oxygen concentration? The work is important at several levels. It will allow us to understand more about a basic biological process that is fundamental for the virulent properties of many bacterial pathogens, such as Salmonella and E. coli. It will provide new insight and a deeper understanding of an ancient class of proteins that evolved in an anaerobic world. It has wider significance for how signal perception and signal transduction are linked in a ubiquitous family of bacterial gene regulators. And finally, it offers possibilities of designing molecular switches that will respond to changes in oxygen levels for use in biotechnology.
Technical Summary
The bacterial transcriptional regulator FNR, which orchestrates the switch between aerobic and anaerobic respiration, consists of two distinct domains that provide DNA-binding (C-terminal) and sensory (N-terminal) functions. FNR becomes active under anaerobic conditions through the binding of a [4Fe-4S] cluster to the sensory domain, leading to dimerization and DNA-binding. O2 triggers the conversion of the [4Fe-4S] cluster to a [2Fe-2S] form, causing the protein to monomerise with the loss of specific DNA-binding. Recently, we showed that cluster conversion proceeds in two distinct steps, resulting in a [3Fe-4S] intermediate, and that the kinetics of the reaction are modulated by the protein environment. This work has raised a raft of new questions that now need to be addressed. Using electrochemical methods, we will investigate the reaction between the [4Fe-4S]2+ cluster and O2 that initiates cluster conversion and leads to the formation of the [3Fe-4S] intermediate, and with Resonance Raman spectroscopy we will build on highly significant preliminary data indicating that released cluster sulfide may be stored within the protein. We will investigate to what extent the [3Fe-4S] and [2Fe-2S] cluster forms can undergo a reverse reaction leading to repair of the [4Fe-4S] cluster. We will also explore the mechanism of signal transduction from the sensory domain to the DNA-binding domain to address key issues such as the effect of DNA binding on FNR oxygen sensitivity. Some bacteria contain multiple FNR proteins and we have proposed that FNR proteins may have evolved to respond to different oxygen concentrations. We will test this by studying in detail three FNR proteins from the same bacterium. Finally, we have generated a systems-level steady-state model of the dynamics of FNR in the cell, which we propose to test and develop further. Together, this work will provide an unprecedented level of understanding of FNR at a molecular, systems and evolutionary level.
Organisations
Publications
Crack JC
(2013)
Mechanism of [4Fe-4S](Cys)4 cluster nitrosylation is conserved among NO-responsive regulators.
in The Journal of biological chemistry
Crack JC
(2009)
Characterization of [4Fe-4S]-containing and cluster-free forms of Streptomyces WhiD.
in Biochemistry
Crack JC
(2011)
Mechanistic insight into the nitrosylation of the [4Fe-4S] cluster of WhiB-like proteins.
in Journal of the American Chemical Society
Crack JC
(2014)
Influence of association state and DNA binding on the O2-reactivity of [4Fe-4S] fumarate and nitrate reduction (FNR) regulator.
in The Biochemical journal
Crack JC
(2012)
Iron-sulfur cluster sensor-regulators.
in Current opinion in chemical biology
Crack JC
(2019)
Generation of 34S-substituted protein-bound [4Fe-4S] clusters using 34S-L-cysteine.
in Biology methods & protocols
Crack JC
(2014)
Iron-sulfur clusters as biological sensors: the chemistry of reactions with molecular oxygen and nitric oxide.
in Accounts of chemical research
Crack JC
(2014)
Techniques for the production, isolation, and analysis of iron-sulfur proteins.
in Methods in molecular biology (Clifton, N.J.)
Crack JC
(2012)
Bacterial iron-sulfur regulatory proteins as biological sensor-switches.
in Antioxidants & redox signaling
Description | Bacteria inhabit almost every environmental niche on Earth, including some that are so harsh that many other forms of life cannot survive. This success is at least in part due to the ability of bacteria to adapt to changes in environment, and this adaptation is rooted in their capacity to alter patterns of gene expression in response to external and internal cues. A key environmental parameter that is monitored by many bacteria is oxygen (O2) concentration. Like many others, the bacterium Escherichia coli (E. coli) can thrive both in the presence and absence of O2. To determine whether O2 is present, E. coli uses a protein called FNR, which acts as an O2 sensor. It has a co-factor (an iron-sulfur cluster) that reacts with O2 in a way that switches FNR off. In the 'off-state' FNR cannot bind to DNA to activate expression of genes that are used during growth in the absence of O2. When there is no O2 the iron-sulfur cluster remains associated with FNR, which can bind DNA and activate expression of genes that are needed for growth in the absence of O2. We have discovered that the sulfide released during conversion of the FNR [4Fe-4S] cluster to the [2Fe-2S] form is retained in the form of cysteine persulfide(s) which coordinates the cluster. This can be used to regenerate the [4Fe-4S] form upon addition of a dithiol reductant and iron, thus representing a novel iron-sulfur cluster repair/assembly pathway. [4Fe-4S] FNR responds to NO in vivo and in vitro where it undergoes a rapid, multi-step reaction with 8 NO molecules, generating iron-nitrosyl species like those observed in Wbl proteins. This work uncovered a common mechanism of cluster nitrosylation in phylogenetically unrelated proteins. Pseudomonas putida FNR proteins operate in distinct O2 ranges in vivo and that this is consistent with the reactivity of their [4Fe-4S] clusters. The proteins exhibit discrete responses to NO in vivo, and whilst retaining a similar reaction mechanism to that established for FNR, apparently react more slowly. This has implications for understanding control of cluster reactivity, signal perception and transduction. As part of this work we developed a novel means to synthesize isotopically labelled Cys for incorporation of sulfur into iron-sulfur clusters. |
Exploitation Route | Our work is fundamental research that has provided unprecedented detail of the mechanisms of iron-sulfur cluster reactivity, including cluster conversion reactions that take place in response to a stimulus. Our discovery of the fate of cluster sulfide, in particular, provides further important insight into the biology of sulfur. These insights are principally of interest to other researchers in a wide range of fields. |
Sectors | Chemicals Manufacturing including Industrial Biotechology Pharmaceuticals and Medical Biotechnology Other |
Description | As part of our research, we developed a novel means to produce isotopically labelled cysteine (which we needed in order to label iron-sulfur clusters). We have subsequently developed this further to explore the possibility of making unnatural sulfur-containing amino acids. This led to a Proof of Concept award from UEA and to a 'Sparking Impact' award from BBSRC. We have continued to use this technology to great effect. Initial investigations into whether it might be possible to broaden the molecules that could be generated by the technology were positive but it remains unclear whether it could be sufficiently broad to attempt to commercialise. |
First Year Of Impact | 2012 |
Description | BBSRC Responsive mode |
Amount | £637,302 (GBP) |
Organisation | Biotechnology and Biological Sciences Research Council (BBSRC) |
Sector | Public |
Country | United Kingdom |
Start | 04/2014 |
End | 05/2017 |
Title | Production of isotopically labelled cysteine |
Description | We devised a novel method for labelling cysteine with 34S - this is not commercially available. |
Type Of Material | Technology assay or reagent |
Year Produced | 2012 |
Provided To Others? | Yes |
Impact | The methodology has been developed to extend production to unnatural sulfur containing amino acids and is being developed for commercial exploitation |
Description | Public lecture |
Form Of Engagement Activity | A talk or presentation |
Part Of Official Scheme? | No |
Geographic Reach | Local |
Primary Audience | Public/other audiences |
Results and Impact | The talk resulted in several questions and discussion continued into a post talk gathering. No direct impacts that I am aware of. |
Year(s) Of Engagement Activity | 2012 |