To clearly distinguish between conductive mineral mediated DIET and direct cell contact DIET, we have subcategorized the pili mediated electron transfer, as biological DIET (bDIET), and the conductive mineral mediated DIET, as mineral DIET (mDIET).
BIOLOGICAL DIET
Biological DIET (Figures 2B,C) was first described in G. metallireducens and G. sulfurreducens co-cultures, growing in a defined minimal medium with ethanol as electron donor and fumarate as electron acceptor (Summers et al., 2010). Tightly associated aggregates were consistently noticed in co-cultures growing via bDIET (Summers et al., 2010; Shrestha et al., 2013a; Rotaru et al., 2014) but not during growth via H2/formate electron transfer (Rotaru et al., 2012). The mechanism for bDIET in Geobacter co-cultures was intensely studied during the past few years, combining phenotypic, genetic, transcriptomics, proteomics analysis (Summers et al., 2010; Shrestha et al., 2013a, b). bDIET might be favored over H2 or formate transfer under certain conditions (Lovley, 2011) as demonstrated using genome-scale models including genomic, transcriptomic and physiological data (Nagarajan et al., 2013). The absence of H2/formate mediated electron transfer in the co-culture was best shown by the ability of G. metallireducens to generate successful syntrophic co-cultures with a double mutant of G. sulfurreducens (ΔhybLΔfdnG) incapable of H2 or formate uptake (Rotaru et al., 2012). Furthermore, bDIET is seemingly capable to produce successful co-cultures in the absence of acetate transfer as supportive mechanism of electron exchange as revealed in a recent study (Shrestha et al., 2013a) in co-cultures of G. metallireducens with strain of G. sulfurreducens depleted in acetate utilization capacity, a citrate synthase mutant (ΔgltA; Ueki and Lovley, 2010). This study clearly revealed that bDIET alone is sufficient for energy conservation in syntrophic co-cultures.
Biological DIET interactions with fumarate as terminal electron acceptors are probably not ecologically relevant, but more recently bDIET was discovered in co-cultures of G. metallireducens with Methanosaeta harudinacea (Rotaru et al., 2014). These two genera of methanogens are responsible for the majority of methane emission in environments such as paddy soils (Grosskopf et al., 1998; Feng et al., 2013) or anaerobic digesters (Vavilin et al., 2008; Morita et al., 2011; Rotaru et al., 2014; Ying et al., 2014). Only these acetoclastic methanogens were capable of bDIET-interactions with G. metallireducens, whereas hydrogenotrophic methanogens were not (Rotaru et al., 2014). Methanosaeta was shown to use electrons directly for the reduction of CO2 to methane because the methanogen converted 1/3 of the 14C-bicarbonate to 14C methane (Rotaru et al., 2014). Other shuttles were excluded as electron transferring mechanisms because a pili-deficient G. metallireducens could not produce successful co-cultures with Methanosaeta or Methanosarcina (Rotaru et al., 2014).
Role of pili in bDIET
Pili are known to have an important role in biofilm formation (Moreira et al., 2006; Reguera et al., 2007; Oxaran et al., 2012; Snider et al., 2012), but also for the conductive properties of Geobacter biofilms (Summers et al., 2010; Malvankar et al., 2011; Malvankar and Lovley, 2012, 2014; Vargas et al., 2013). Co-cultures do not grow when initiated with a strain of either G. metallireducens (Summers et al., 2010) or G. sulfurreducens (Rotaru et al., 2014) in which the gene for PilA is deleted, confirming the importance of conductive pili (Reguera et al., 2005, 2006; Lovley, 2011; Malvankar et al., 2011) networks for bDIET. It has been proposed that the stacking of π–π orbitals of five aromatic amino-acids in the carboxyl-terminus of PilA, the pilin monomer, contribute to the metallic-like conductivity similar to that of conductive organic polymers (Vargas et al., 2013). A G. sulfurreducens strain deficient in the five aromatic amino acids (ARO5), the pili were still produced with properly localized OmcS and yet the biofilms of ARO5 showed greatly diminished conductivity (Vargas et al., 2013). In another study, the gene for conductive pili in G. sulfurreducens was replaced with the non-conductive pilA gene of Pseudomonas aeruginosa PAO1 (Liu et al., 2013) generating a mutant strain PAO1, which can express properly assembled P. aeruginosa pili ornamented by outer surface c-type cytochromes. However, PAO1 biofilms had significantly lower conductivity than wild type G. sulfurreducens and was unable to reduce Fe3+-oxides or produce current (Liu et al., 2013). The lack of conductivity in PAO1 biofilms indicates that three out of five aromatic amino acids at the C-terminus domain are necessary for conductivity (Liu et al., 2013). These findings validated that OmcS alone on scaffold-pili is insufficient to confer conductivity to Geobacter biofilms, in contrast to a recent hypothesis, which suggested that conductivity is the result of electron-hopping via cytochromes aligned on the pili of G. sulfurreducens (Strycharz-Glaven et al., 2011).
Role of cytochromes in bDIET
Geobacter sulfurreducens was used as model organism for the study of extracellular electron transfer, and several studies revealed that besides pili, G. sulfurreducens require a multitude of extracellular and periplasmic cytochromes for insoluble Fe3+ oxide reduction (Lloyd et al., 2003; Butler et al., 2004; Qian et al., 2007, 2011; Aklujkar et al., 2009; Lovley et al., 2011; Lovley, 2012), current production (Nevin et al., 2009; Inoue et al., 2010), or current uptake on electrodes (Holmes et al., 2006; Strycharz et al., 2011). However, there are slight differences in the types of cytochromes expressed during growth in electron-donating and electron up-taking modes (Strycharz et al., 2011).
Geobacter sulfurreducens growing via bDIET with G. metallireducens highly expresses an extracellular c-type cytochrome, OmcS (Summers et al., 2010; Shrestha et al., 2013a, b). OmcS decorates the pili of G. sulfurreducens (Leang et al., 2010; Summers et al., 2010) and is required for bDIET and Fe3+ reduction (Mehta et al., 2005; Ding et al., 2008; Qian et al., 2011) but not for current production (Nevin et al., 2009). OmcS is not necessary while growing via H2 interspecies transfer with P. carbinolicus (Rotaru et al., 2012).
Another extracellular cytochrome OmcZ, which helps G. sulfurreducens achieve high current densities in single species biofilms (Nevin et al., 2009; Richter et al., 2009), was not required for bDIET in G. sulfurreducens – G. metallireducens co-cultures (Shrestha et al., 2013b) or during iron oxide reduction (Nevin et al., 2009).
There is no correspondence between the well studied extracellular cytochromes in G. sulfurreducens and G. metallireducens, and today we have yet no clear understanding, about the exact role of each cytochrome in G. metallireducens during extracellular electron transfer processes. And yet it must be noted that extracellular cytochrome like OmcS in the electron acceptor strain, G. sulfurreducens were highly relevant for the interspecies association. How exactly they aid the electron transfer process is yet to be uncovered.
bDIET in environmental communities
The possible existence of bDIET in the natural ecosystem was first reported by Morita et al. (2011), while studying the mechanism of interspecies electron exchange in the natural methanogenic communities that formed conductive aggregates in a simulated anaerobic wastewater digester converting brewery wastes to methane. The microbial community structure in up-flow anaerobic sludge blanket digester aggregates showed the predominance of Geobacter spp. (Morita et al., 2011; Rotaru et al., 2014). It is interesting to note that in most of the methanogenic environments where bDIET is reported, Geobacter spp. are abundant (Kato et al., 2012a; Aulenta et al., 2013; Zhou et al., 2013a; Rotaru et al., 2014), which is probably because Geobacter spp. form conductive networks using pili (Malvankar et al., 2011; Malvankar and Lovley, 2012) and transfer electrons to methanogens such as Methanosaeta (Morita et al., 2011; Rotaru et al., 2014). Similar species abundance has also been reported in enrichment culture converting coal to methane, where Geobacter and Methanosaeta were the dominant genera (Jones et al., 2010) possibly using coal as an electron donor and an electron transfer mediator.
MINERAL MEDIATED DIET (mDIET)
The need to produce biological conductive molecular networks can be averted by the addition of conductive minerals (Liu et al., 2012, 2014). mDIET could take place via non-biological conductive networks of semi-conductive minerals (Figures 2D,E) like nano-magnetite (Kato et al., 2012a, b; Liu et al., 2014), granulated activated carbon (GAC; Liu et al., 2012) or biochar (Chen et al., 2014) in the absence of molecular conduits.
For example, electrically conductive magnetite nano-particles facilitate mDIET from G. sulfurreducens to Thiobacillus denitrificans, accomplishing acetate oxidation coupled to nitrate reduction (Kato et al., 2012b). Recently, magnetite nano-particles were shown to compensate for the absence of OmcS on the pili of a deficient G. sulfurreducens co-cultured with G. metallireducens in the presence of ethanol and fumarate (Liu et al., 2014; Figure 2D). Another conductive material, GAC promotes mDIET, bypassing biologically produced electrical conduits (Liu et al., 2012), as evident from the ability to restore syntrophic metabolism in co-cultures deficient in pili or cytochromes (Liu et al., 2012).
mDIET in environmental communities
Although extracellular appendages are required for the respiration of extracellular electron acceptors (Reguera et al., 2005; Tremblay et al., 2012), they can be replaced with conductive materials which can mediate electron transfer between cells during mDIET. Naturally occurring minerals could offer ecological advantages because of their abundance in natural ecosystems (Kato et al., 2012b), where they could aid mDIET in the absence of pre-evolved molecular conduits. Iron is one of the most ubiquitous metals in Earth’s crust (Braunschweig et al., 2013) and could act as conductive mediator for mDIET, demanding less energetic investment from the species exchanging electrons because there would be no need to produce extracellular components for biological electrical connections (Kato et al., 2012b). For example, magnetite, a conductive iron (II&III)-oxide, stimulated methane production in rice paddy soils and enriched for Geobacter and Methanosarcina species, which likely exchanged electrons via magnetite minerals (Kato et al., 2012a; Zhou et al., 2013b). Electrically conductive magnetite (Fe3O4) nano-particles could also enhance reductive dechlorination of trichloroethane, an ubiquitous groundwater pollutant, by allowing electrons to be transferred extracellular from acetate oxidizing microorganisms to trichloroethane dechlorinating microorganisms (Aulenta et al., 2013). In this study the abundant microorganisms were also Geobacter spp., which accounted for 50% of the total bacterial population (Aulenta et al., 2013).
Similarly, it has been reported that poorly crystalline akaganeite (β-polymorph of FeOOH) enhanced mDIET to methanogens in slurries from river sediments (Jiang et al., 2013). In such slurries, Clostridium coupled Fe3+-akaganeite reduction to Fe2+ with acetate oxidation. Partly, electrons from Fe2+ were used by the methanogen to convert bicarbonate to methane. Partly, Fe2+ ions were re-adsorbed onto akaganeite nano-rods, followed by re-precipitation as structural Fe3+ with the simultaneous formation of goethite (α-polymorph of FeOOH) nanofibres (Jiang et al., 2013).
Anthraquinone disulphonate was also suggested to facilitate mDIET between Geobacter spp. and Methanosarcina spp. in rice paddies (Zhou et al., 2013b). The impact of AQDS on methanogenesis is in contrast with studies in defined co-cultures of Geobacter and Methanosarcina (Liu et al., 2012). However, soils are not well-defined systems, and it is possible that in soil other interactions happen between humics and soil components, which should be further investigated.