1. Introduction
There is no other environment on earth as complex as soil [
1,
2]. Microorganisms are crucial for soil fertility and plant productivity by the recycling of carbon, nitrogen, and phosphorus [
3,
4]. For instance, there are some biochemical reactions that are only performed by microorganisms such as nitrogen fixation and cellulose biodegradation. The decomposition of organic compounds in soils is based upon the oxidation of different substances such as carbohydrates, fats, and proteins supporting microbial metabolism to sustain growth and survival in a very dynamic and competitive matrix [
5,
6]. The microbial decomposition of organic matter under aerobic conditions results in the complete mineralization of organic materials to carbon dioxide and water. However, when anaerobic conditions are present, microbial activity is driven by processes such as anaerobic respiration, fermentation, and methanogenesis. Based upon 16S rRNA analyses of soils around the world, bacterial communities in soils are mostly composed of the phyla Acidobacteriota, Actinomycetota, Bacteroidota, and Pseudomonadota. Other phyla such as Bacillota, Chloroflexota, Plantomycetota, and Verrucomicrobiota occurred in lower numbers [
5,
7]. A large percentage of soil bacteria did not match with any known bacterial phylum, nor they have been isolated and biochemically characterized in the laboratory [
5,
6,
7]. Previous studies by our laboratory reported that bacteria belonging to the phyla Acidobacteriota, Actinomycetota, Chloroflexota, Plantomycetota, and Pseudomonadota were the dominant types in soils at Bergen Community College (BCC) [
8]. The phyla Actinomycetota or Pseudomonadota were always the top two types in soils from different locations. The contributions of these bacterial phyla to the cycling of carbon and nitrogen in soils are well documented [
6,
7,
8].
Energy generation around the world mostly relies on non-renewable sources such as fossil fuels [
9]. Unfortunately, the use of fossil fuels has led to serious environmental contamination problems and global warming [
10]. Because of the continuous growth of human populations and the quick industrialization of underdeveloped countries, the demand for fossil fuels has increased. This leads to more energy consumption and the fast depletion of non-renewable energy sources such as coal, gas, and oil. Evidently, there is a need to develop renewable energy sources to reduce the dependance on non-renewable sources and decrease environmental pollution and global warming. Technologies such as wind, hydro, and solar power provide clean and sustainable sources of energy [
10]. One of the technologies that is currently being developed to provide sustainable and renewable energy via the microbial oxidation of organic compounds is microbial fuel cells (MFCs) [
11].
In MFCs, the transfer of electrons to the anode electrodes is carried out by membrane cytochromes, pili, nanowires, and protein complexes [
11]. Furthermore, some microorganisms carry out the transfer indirectly using environmental or self-produced electron mediators [
12]. Once the electrons are transferred to the anode, they flow to the cathode, producing an electrical current. In the cathode, electron acceptors react with both electrons and protons, producing reduced chemical compounds such as water. There are several publications demonstrating electrical productions by soil microbial fuel cells (SMFCs) using different formats [
13,
14,
15,
16]. Aerobic and anaerobic soil microbial fuel cells (SMFCs) have been constructed with single and multiple chambers, optimizing electricity generation and microbial activity. Double-chamber cells consist of two chambers with the anode and cathode separated and joined by a cation-exchange membrane.
Single-chamber cells have the electrodes at opposite ends, with the anode buried in the soil and cathode on top. Different types of graphite felt electrodes have been tested as the anode in an air-cathode and membraneless SMFC [
17]. The composition of the cathode has been also shown to be critical for optimizing electrical production [
18]. For instance, graphite felt electrodes provided optimal electrogenesis with higher voltage and catalytic activity. One of the problems during the SMFC operation is the eventual depletion of the organic carbon present in the soil with the gradual reduction in and termination of electrogenesis. However, hybrid SMFCs with plants and soils have been shown to sustain long-term activity by continuously supplying photosynthetic products to the microbial community [
19]. The depletion of organic matter in the SMFC can also be avoided by the addition of external carbon sources such as compost, cellulose, or glucose to replenish the materials lost during microbial oxidation [
20,
21].
Soil chemistry is one of the major factors affecting electrogenesis in SFMCs [
14,
22,
23]. Certain types of organic compounds such as polyphenols may limit the production of electrical power by bacterial communities. SMFCs developed from forest and agricultural soils were shown to sustain an electrogenic bacterial community where agricultural SMFCs generated 17 times more electricity and 10 times higher respiration rates than forest SMFCs [
14]. High-clay-content SMFCs demonstrated optimal electrogenesis and longer operational times by providing a less porous and permeable matrix, optimizing anaerobic conditions in the anode [
22]. Furthermore, faster start-up times and electrogenic activity were reported with high organic matter. Start-up operational times are defined as the enrichment process when bacteria adapt to anaerobic conditions and develop an optimal biomass on the anode surface, resulting in electrical output through the oxidation of natural substances.
The ability to generate electricity from the oxidation of organic compounds in soils is widespread through different bacterial phyla. Bacterial belonging to the phyla Pseudomonadota, Bacillota, Actinomycetota, and Bacteroidota were shown to be electrogenic in MFCs [
11]. As of now,
Geobacter sulfurreducens has been shown to be the most electrogenic microorganisms [
11,
24]. Pure and mixed cultures of
G. sulfurreducens have been used to generate electricity in SMFCs.
G. sulforreducens has been shown to reduce Fe
+3 using a variety of organic compounds as electron donors. Bacteria from the phylum Bacillota such as
Bacillus and
Clostridium have been shown to be important members of the electrogenic bacterial community in SMFCs [
8,
11,
14].
Previous studies in our laboratory demonstrated a sustainable electrical production lasting a maximum of 23 days with a power output of 73 microwatts [
8]. The maximum power output by SMFCs was reported to be 80 microwatts, but it lasted only 12 days. 16S rRNA analysis showed that the most abundant bacteria in the anodes were members of Pseudomonadota, Bacillota, Actinomycetota, Chloroflexota, and Planctomycetota. SMFCs lacking large numbers of bacteria belonging to Bacillota did not generate electricity. However, only six soil samples from different locations were used to build the SMFCs. Additional soil locations were later analyzed, and a higher electrical output was reported to be 143 microwatts after 15 days at 37 °C [
25]. The predominant bacteria in the electrogenic community were shown to belong to the phylum Bacillota of the class Clostridia. The major objectives of this study were to continue sampling additional soil locations around BCC to determine if they have the potential to generate higher electrical output and compare and analyze the electrogenic bacterial community using 16S rRNA analysis at different taxonomical levels.
4. Discussion
Fourteen SMFCs were constructed using soils from different locations at BCC. The oxidation of organic compounds in the SMFC’s provided the electrons needed to generate an electrical power to sustain electrical production by most of the cells. However, some SMFCs did not generate any electrical power, and neither did we detect the presence of electrogenic bacteria. Previous studies by our laboratory demonstrated that the presence of a significant number of bacteria belonging to the phylum Bacillota was needed to generate significant electrical output due to the fact that the anaerobic conditions in the SMFC-enriched electrogenic bacteria did not use oxygen as the last electron acceptor for the degradation of organic matter [
8,
25]. Most soil locations tested were able to support the development of a viable and sustainable electrogenic bacterial community. In those samples, the oxidation of organic substances provided electrons to the anode to produce electricity, while protons migrate to the cathode through the soil. For each electron produced as an electrical current, a proton is also produced. Compared to other studies, two new samples, SMFC-B1B and SMFC-B1C, produced higher electrical power and electrogenic bacterial numbers. They produced 6% and 11% more electricity than SMFC-B1, which was previously reported to be the SMFC with the highest electrical output [
25]. Of the three SMFCs, only SMFC-B1C exhibited a sustainable electrical production with double-digit values after 21 days of operational time. This is the first time that we recorded a SMFC with such a high and sustainable electrical production. Electrical production relied on the oxidation of native organic substances in the SMFCs. The addition of leaves (cellulose) to the mud to develop SMFC-B1C might have provided additional carbon sources to sustain a longer operational time and higher electrical output compared to any other SMFC. Furthermore, cellulase genes such as GH48 were found to be significantly increased by qualitative and quantitative analyses such as PCR amplification and the quantitation of the amplified fragment. GH48 genes were widely distributed in soils at BCC, with bacteria from the Pseudomonadota and Actinomycetota comprising most of the community [
28]. Cellulases of the GH48 family are one of the most important GHs responsible for the biodegradation of crystalline cellulose to glucose. Most cellulose in the environment is found in plant material biomass based upon crystalline cellulose bound to hemicellulose and lignin. The presence of GH48 cellulases is essential to breakdown cellulose to glucose. The biodegradation of cellulose will provide additional organic compounds such as cellobiose and glucose for the electrogenic bacteria to enhance electron transfer to the anode. A different carbon source, e.g., blood agar, added to the mud to construct SMFC-B1A and SMFC-2A did not produce a significant increase in sustainable electrical production.
Initial electrogenic activity in the SMFCs might have relied on the oxidation of the native organic substances in soil. But, those substances were significantly depleted, and it was not until other members of the bacterial community were capable of producing metabolic intermediates such as organic acids that electrogenic bacteria had additional organic substances to serve as electron generators to the anode. Soil organic carbon, mineralization rates, and bacterial community structure have been demonstrated to impact the performance of SMFCs [
11,
14,
23]. Because of the closed system used in this study, the depletion of natural substrates led to the eventual reduction in electricity production and electrogenic bacterial numbers. This depletion was overcome in SMFC-B1C through the addition of cellulose, providing additional carbon sources for bacterial oxidation, resulting in higher electrical production and longer operational times. Acetate is a major intermediate to cellulose biodegradation and can be used for electrogenesis [
21]. Future studies in our laboratory will develop new SMFCs with different concentrations of cellulose to optimize electrogenesis. We will also clone the GH48 genes to characterize the bacterial community responsible for cellulose biodegradation in the SMFCs.
Another strategy to overcome the depletion or carbon sources is the development of self-contained hybrid plant–soil MFCs (PSMFCs). These PSMFCs were shown to provide continuous addition of carbon substances via photosynthesis to compensate for the loss of organic matter and subsequent decay of electrical production [
19]. Other studies demonstrated that electrode spacing and the addition of external organic carbon can also optimize electrical output and electrogenic bacterial numbers [
22,
29,
30]. Substrate addition into the SMFC to compensate for the loss of organic material was observed to be better applied when electricity generation was decreasing instead of having a continuous system [
22,
29]. The quality of the available organic matter in soil affected the performance of SMFCs constructed from agricultural and forest soils [
14]. SMFCs from agricultural soils showed 17 times more electricity than forest soils with respiration rates 10 times higher. Higher concentration of water-soluble polyphenols in forest soils compared to agricultural soils may have reduced the availability of organic matter to optimize microbial activity. Furthermore, in another study, soils with high clay contents and organic matter concentrations supported faster and higher electrogenic activity [
22]. High clay content provided a stronger barrier to prevent the diffusion of oxygen into the anode, facilitating the development of anaerobic conditions. Soil characteristics related to electrical production by electrogenic bacteria will be further investigated by analyzing the chemical and physical compositions of the soils used to generate SMFC-B1B and SMFC-B1C.
To understand the compositions of the electrogenic bacteria communities enriched in SMFC-B1, SMFC-B1B, and SMFC-B1C, 16S rRNA analysis was performed on extracted microbial DNA from all anodes. Bacterial communities in soils at BCC were shown to be predominantly composed of the phyla Actinomycetota, Pseudomonadota, Chloroflexota, Acidobacteriota, and Planctomycetota [
8]. These soils never showed a significant number of bacteria belonging to the phylum Bacillota. The highest percentage ever reported in soils at BCC was 1.23% [
8]. We used single-chamber cells with the anode buried in the SMFC and the cathode on top. Samples were taken from the biofilm on the anode. The bacterial diversity in SMFC-B1C was the highest, followed by SMFC-B1B and SMFC-B1. We detected 20 bacteria and archaea phyla with the phylum Bacillota representing more than half of the bacteria in all cells. The only other bacterial phylum with double-digit numbers was the Pseudomonadota in SMFC-B1C. Bacteria belonging to the phylum Bacillota were the predominant classes, orders, families, and genera in SMFC-B1, SMFC-B1B, and SMFC-B1C. We found similar results with other SMFCs previously reported, where the increase in Bacillota bacteria compared to soils was required to generate electricity [
8,
25]. The 16S rRNA sequences with the highest frequencies in SMFC-B1 were unclassified bacteria, demonstrating the inability of current databases to identify some environmental communities [
31,
32]. The predominant bacteria in SFMC-B1B were found to be members of the class Clostridia family Ruminococcaceae. Unfortunately, no matches were found at lower taxonomical levels. In SMFC-B1C, the most abundant bacteria were found to be members of the Pseudomonadota genus
Azospira. The genus
Azospira showed significant frequencies in the anodes of a wastewater MFC [
33]. They can denitrify under anaerobic conditions with very high electrogenic activity. An uncultured
Azospira sp. clone accounted for 65% of the community in MFCs with anodes built with granular graphite [
34]. Different anode materials such as granulated activated carbon and carbon felt cube led to a bacterial community that consisted mostly of the genus
Geobacter. The chemical composition of the electrodes influenced the formation of biofilms, affecting the adhesion and growth of electrogenic bacteria.
Overall, members of Bacillota, class Clostridia, family Ruminococcaceae were widely distributed in the three SFMCs. Bacteria from the class Clostridia were previously shown to be important contributors in SMFCs during electricity generation, either by directly generating electrons transferred to the anode via the oxidation of organic substances or by producing organic acids that were subsequently oxidized by other electrogenic bacteria within the anerobic environment of the SMFCs [
8,
14,
15,
21,
24,
25,
30,
35]. Furthermore, the isolation of electrogenic bacteria from SMFCs built with soils from seven sites in China demonstrated that 11 of the 15 bacteria were phylogenetically related to the genus
Clostridium [
35].
In addition to bacteria from the phylum Bacillota, two other Pseudomonadota genera were found to be very important members of the electrogenic bacterial community in SMFC-B1 and SMFC-B1C. They were
Magnetospirillum sp. and
Bdellovibrio.
Magnetospirillum sp. was previously reported to be an important member of the electrogenic bacterial community in SMFC-B1 [
25].
Magnetospirillum sp. can ingest iron and proteins inside the cells, interacting with it to produce magnetite that is located inside membranous structures called magnetosomes. Most electrogenic bacteria such as
Clostridium sp. and
Magnetospirillum sp. showed the ability to reduce Fe(III). However, some can also reduce nitrate.
Magnetospirillum sp. was also shown to be predominantly present in the anodic biofilms developed by an anaerobic sludge-MFC [
36]. Furthermore, when present along with
Clostridium sp. these bacteria optimized electricity generation. SMFCs developed from Chinese soils showed a predominantly electrogenic bacterial community composed of bacteria belonging to the class Clostridia that were capable of reducing Fe(III) [
35]. They reported that the family Clostridiaceae were the predominant electrogenic bacteria in soils. SMFCs constructed with German soils also showed an increase in the abundance of bacteria belonging to the Bacillota phylum when electricity production was the highest [
30]. In that study, they found that the electrode materials were the most important factor for sustainable electrical generation. Modified stainless steel produced optimal electrical generation compared to carbon felt. They concluded that microbial diversity and soil chemistry were not as important during the optimization of electrical production.
The other bacterial genus belonging to the phylum Pseudomonadota found to be a predominant member of the electrogenic bacterial community in the anode of SMFC-B1C was
Bdellovibrio. This is the first report of these bacteria to be members of electrogenic bacterial communities in SMFCs generating significant electrical outputs.
Bdellovibrio species are predatory bacteria that are widely distributed in soil and aquatic systems that prey upon Gram-negative bacteria [
37]. However, Gram-positive bacteria are not affected by them. The high frequency of these bacteria in some environments was positively correlated with higher microbial alpha-diversity in activate sludge. They might have been actively preyed on highly abundant bacterial species opening up specific niches for rare taxa in SMFC-B1C [
38]. The lysis of Gram-negative bacteria by
Bdellovibrio might have also increased the carbon and nitrogen concentration in the cell. Opposite results were reported with the protozoan grazing of bacteria in MFCs built from marine sediments where electricity generation and community diversity were reduced [
39]. Protozoa were consuming
Geobacter sufurreducens, reducing the electrical output by up to 91%. However, protozoa are not as selective as
Bdellovibrio and prey on both Gram-negative and Gram-positive bacteria. Therefore,
Bdellovibrio is a more selective predator of specific types of bacteria such as Gram-negative bacteria, allowing Gram-positive bacteria such as the Bacillota phylum to occupy different niches in the SMFCs.
Different taxonomical levels of archaea were detected as part of the predominant electrogenic community in all SMFCs. Most of them were methanogenic bacteria. Methanogenesis is a form of anaerobic respiration that produces methane as the final product. In hydrogenotrophic methanogenesis, hydrogen is used for the reduction of carbon dioxide to produce methane. However, in acetoclastic methanogenesis, hydrogen is used to reduce acetate and produce methane. Most of the archaea detected in the SFMCs are acetoclastic methanogens such as
Methanosarcina and
Methanobacterium, with only the genus
Methanocella capable of hydrogenotrophic methanogenesis. Because of the anaerobic conditions detected in SMFCs, organic substances were decomposed by either hydrolysis, acidification, fermentation, or methanogenesis. Methanogenesis was previously shown to compete for electrons against electrogenesis in MFCs [
21,
40,
41,
42]. A high frequency of
Methanobacterium spp. was frequently detected in SMFCs fed with cellulose [
21]. However, a higher concentration of archaea in SMFCs may not be beneficial to electrogenesis. Furthermore, the final product of the anaerobic decomposition of organic substrates in soils is methane, but partial decomposition during fermentation or methane oxidation by methanotrophic bacteria produced compounds such as formate and acetate that are used by either methanogens to produce methane or by electrogenic bacteria from the class Clostridia, which will oxidize these compounds and transfer the electrons to the anode [
21,
41,
43]. Furthermore, reverse methanogenesis was previously demonstrated with different genera of archaea such as
Methanobacterium,
Methanosarcina, and
Methanospirillum [
43,
44]. This resulted in the production of acetate, which can be used by bacteria of the class Clostridia to oxidize these compounds for electrogenesis. Anaerobic methanotrophic archaea were cultivated in bioelectrical systems with methane-dependent currents related to the enrichment of
Methanoperedens on the anode [
45]. Extracellular electron transfer (EET) to an electrode was demonstrated through the use of multiheme c-type cytochromes. Our results showed that
Methanoperedens was capable of the electrogenic anaerobic oxidation of methane with or without the collaboration of other electrogenic bacteria such as
Geobacter [
45].