Electron Transport ; Electron Transport Complex III ; deficiency ; Humans ; Mitochondria ; metabolism

Exoelectrogens are promising for a wide variety of potential applications in the areas of environment and energy, which convert chemical energy from organic matter into electrical energy by extracellular electrons transfer (EET). Microorganisms with different mechanisms and EET efficiencies have been elucidated. However, the practical applications of exoelectrogens are limited by their fundamental features. At present, it is difficult to realize the extensive application of exoelectrogens in complex and diverse environments by means of traditional engineering strategies such as rational design and directed evolution. The exoelectrogens with excellent performance in environments can be screened with efficient strain identification technologies, which promote the widespread applications of exoelectrogens. The aims of this review are to summarize the methods of screening based on different types of exoelectrogens, and to outline future research directions of strain screening.
Bioelectric Energy Sources ; Electricity ; Electron Transport

Recently many forensic scientists are trying to use the DNA 'barcode' region (upstream portion of mitochondrial cytochrome oxidase subunit I) to identify the species of forensically important fly species. We have analyzed to compare their sequences of the 'barcode' region for twelve blow fly species[A. grahami, C.lata, C. vicina, H.ligurriens, L. ampullaceal, L. Caesar, L. illustris, P. sericata, P. regina, T. calliphoroides, C. megacephala, C. pinguis] collected from the rural and urban regions in Korea. Intra- and interspecies sequence divergences were calculated as 0~0.9% and 0.9~11.4%, respectively. Phylogenetic trees were drawn with Mega 3.1 and Network 4.20 programs. The result illustrates that each genus is grouped as monophyletic group except for T. calliphoroides and all the same species were monophyletic group. This suggests that the 'Barcode' region of COI gene could be a marker for identification of necrophagous blow fly species. But the two closely related species, L.illustris and L.caesar show little differences from each other. Therefore more individuals of these species should be examined for population study.
Diptera* ; DNA ; DNA, Mitochondrial* ; Electron Transport Complex IV ; Korea*

DNA barcoding was recently introduced to molecular identification of forensically important fly species. So, we have analysed the barcode region (687 nucleotides) of mitochondrial cytochrome oxidase subunit I (COI) gene for four species of Muscidae flies collected from Korea. The sequences were aligned and analysed to construct a phylogenetic tree using DNA Star 5.01(DNAStar Inc) and MEGA 3.1 program(Kumar, Tamura, Nei 2004). Intraspecific variation was not noted between M.stabulans individual to each other. Intraspecific variation ranges of other species were 0.1%, 0.1~0.3% and 0.1~0.6% for O.leucostoma, M.angustifrons and M.domestica, respectively. Interspecific percent distance was minimal(9.7~10.0%) between M.stabulans and M.angustifrons. Other species showed above 10% distance from each other. The result showed that four species of Muscidae fly species (Muscina angustifrons, Muscina stabulans, Ophyra leucostoma and Musca domestica) were identifiable from each other with analysis of barcode region of COI gene. Therefore, we conclude that species identification of forensically important Muscidae flies used in this study is possible with percent distance of sequences of COI barcode region, but more species and individuals should be examined to be confident about the conclusion.
Cytochromes* ; Diptera ; DNA* ; Electron Transport Complex IV* ; Korea* ; Muscidae*

Photobiomodulation utilizes monochromatic (or quasimonochromatic) light in the electromagnetic region of 600~1000 nm for the treatment of soft tissues in a nondestructive and nonthermal mode. It is conceivable that photobiomodulation is based upon the ability of the light to alter cell metabolism as it is absorbed by general hemoproteins and cytochrome c oxidase (COX) in particular. Recently it has been suggested radiation of visible and infrared (IR) activates retrograde signaling pathway from mitochondria to nucleus. In this review, the role of COX in the photobiomodulation will be discussed. Further a possible role of water as a photoreceptor will be suggested.
Electron Transport Complex IV ; Magnets ; Metabolism ; Mitochondria ; Phototherapy* ; Water

Although widely studied, the natural diversity of the hard tick is not well known. In this study, we collected 194 sequences from 67 species, covering 7 genera of hard tick. The 5′ region of the mitochondrial cytochrome c oxidase subunit 1 region (586 bp) has been used to investigate intra- and inter-species variation and the phylogenetic tree of neighbor joining method has been used for assessment. As a result, by comparing the K2P-distance of intra- and interspecies, 30 samples (15.2%) shown that interspecies distance was larger than the minimum interspecfic distance. From the phylogenetic analysis, 86.8% (49) of the species were identified correctly at the genus level. On deeper analysis on these species suggested the possibility of presence cryptic species. Therefore, further work is required to delineate species boundaries and to develop a more complete understanding of hard tick diversity over larger scale.
Cytochromes c ; Cytochromes ; Electron Transport Complex IV ; Ixodidae ; Methods ; Trees

Exoelectrogenic microorganisms are the research basis of microbial electrochemical technologies such as microbial fuel cells, electrolytic cells and electrosynthesis. However, their applications are restricted in organic degradation, power generation, seawater desalination, bioremediation, and biosensors due to the weak ability of biofilm formation and the low extracellular electron transfer (EET) efficiency between exoelectrogenic microorganisms and electrode. Therefore, engineering optimization of interaction between exoelectrogenic microorganisms and electrode interface recently has been the research focus. In this article, we review the updated progress in strategies for enhancing microbe-electrode interactions based on microbial engineering modifications, with a focus on the applicability and limitations of these strategies. In addition, we also address research prospects of enhancing the interaction between electroactive cells and electrodes.
Bioelectric Energy Sources ; Biofilms ; Electrodes ; Electron Transport ; Electrons

Synthetic electroactive microbial consortia, which include exoelectrogenic and electrotrophic communities, catalyze the exchange of chemical and electrical energy in cascade metabolic reactions among different microbial strains. In comparison to a single strain, a community-based organisation that assigns tasks to multiple strains enables a broader feedstock spectrum, faster bi-directional electron transfer, and greater robustness. Therefore, the electroactive microbial consortia held great promise for a variety of applications such as bioelectricity and biohydrogen production, wastewater treatment, bioremediation, carbon and nitrogen fixation, and synthesis of biofuels, inorganic nanomaterials, and polymers. This review firstly summarized the mechanisms of biotic-abiotic interfacial electron transfer as well as biotic-biotic interspecific electron transfer in synthetic electroactive microbial consortia. This was followed by introducing the network of substance and energy metabolism in a synthetic electroactive microbial consortia designed by using the "division-of-labor" principle. Then, the strategies for engineering synthetic electroactive microbial consortiums were explored, which included intercellular communications optimization and ecological niche optimization. We further discussed the specific applications of synthetic electroactive microbial consortia. For instance, the synthetic exoelectrogenic communities were applied to biomass generation power technology, biophotovoltaics for the generation of renewable energy and the fixation of CO₂. Moreover, the synthetic electrotrophic communities were applied to light-driven N₂ fixation. Finally, this review prospected future research of the synthetic electroactive microbial consortia.
Microbial Consortia ; Synthetic Biology ; Electron Transport ; Electricity ; Biodegradation, Environmental

Facing the increasingly severe energy shortage and environmental pollution, electrocatalytic processes using electroactive microorganisms provide a new alternative for achieving environmental-friendly production. Because of its unique respiratory mode and electron transfer ability, Shewanella oneidensis MR-1 has been widely used in the fields of microbial fuel cell, bioelectrosynthesis of value-added chemicals, metal waste treatment and environmental remediation system. The electrochemically active biofilm of S. oneidensis MR-1 is an excellent carrier for transferring the electrons of the electroactive microorganisms. The formation of electrochemically active biofilm is a dynamic and complex process, which is affected by many factors, such as electrode materials, culture conditions, strains and their metabolism. The electrochemically active biofilm plays a very important role in enhancing bacterial environmental stress resistance, improving nutrient uptake and electron transfer efficiency. This paper reviewed the formation process, influencing factors and applications of S. oneidensis MR-1 biofilm in bio-energy, bioremediation and biosensing, with the aim to facilitate and expand its further application.
Bioelectric Energy Sources/microbiology* ; Biofilms ; Electrodes ; Electron Transport ; Shewanella/metabolism*

Ubiquinol cytochrome c reductase binding protein (UQCRB) is important for mitochondrial complex III stability, electron transport, cellular oxygen sensing and angiogenesis. However, its potential as a prognostic marker in colorectal cancer (CRC) remains unclear. The aim of this study was to determine whether UQCRB can be used as a diagnostic molecular marker for CRC. The correlation between the expression of three genes (UQCRB, UQCRFS1 and MT-CYB) in the mitochondrial respiratory chain complex III and clinico-pathological features was determined. Compared to non-tumor tissues, UQCRB gene expression was upregulated in CRC tissues. Gene and protein expression of the genes were positively correlated. Copy number variation (CNV) differences in UQCRB were observed in CRC tissues (1.32-fold) compared to non-tumor tissues. The CNV of UQCRB in CRC tissues increased proportionally with gene expression and clinical stage. Single-nucleotide polymorphisms in the 3′-untranslated region of UQCRB (rs7836698 and rs10504961) were investigated, and the rs7836698 polymorphism was associated with CRC clinical stage. DNA methylation of the UQCRB promoter revealed that most CRC patients had high methylation levels (12/15 patients) in CRC tissues compared to non-tumor tissues. UQCRB overexpression and CNV gain were correlated with specific CRC clinico-pathological features, indicating clinical significance as a prognostic predictor in CRC. Gene structural factors may be more important than gene transcription repression factors with respect to DNA methylation in UQCRB overexpression. Our results provide novel insights into the critical role of UQCRB in regulating CRC, supporting UQCRB as a new candidate for the development of diagnostics for CRC patients.
Carrier Proteins ; Colorectal Neoplasms* ; DNA Methylation ; Electron Transport ; Electron Transport Complex III ; Gene Expression ; Humans* ; Methylation ; Oxygen ; Repression, Psychology