Releasing iron from ferritin protein nanocage by reductive method: The role of electron transfer mediator

Background

Ferritin detoxifies excess of free Fe(II) and concentrates it in the form of ferrihydrite (Fe₂O₃·xH₂O) mineral. When in need, ferritin iron is released for cellular metabolic activities. However, the low solubility of Fe(III) at neutral pH, its encapsulation by stable protein nanocage and presence of dissolved O₂ limits in vitro ferritin iron release.

Methods

Physiological reducing agent, NADH (E_1/2?=??330?mV) was inefficient in releasing the ferritin iron (E_1/2?=?+183?mV), when used alone. Thus, current work investigates the role of low concentration (5–50?μM) of phenazine based electron transfer (ET) mediators such as FMN, PYO - a redox active virulence factor secreted by Pseudomonas aeruginosa and PMS towards iron mobilization from recombinant frog M ferritin.

Results

The presence of dissolved O₂, resulting in initial lag phase and low iron release in FMN, had little impact in case of PMS and PYO, reflecting their better ET relay ability that facilitates iron mobilization. The molecular modeling as well as fluorescence studies provided further structural insight towards interaction of redox mediators on ferritin surface for electron relay.

Conclusions

Reductive mobilization of iron from ferritin is dependent on the relative rate of NADH oxidation, dissolved O₂ consumption and mineral core reduction, which in turn depends on E_1/2 of these mediators and their interaction with ferritin.

General significance

The current mechanism of in vitro iron mobilization from ferritin by using redox mediators involves different ET steps, which may help to understand the iron release pathway in vivo and to check microbial growth.