Rhodovulum sulfidophilum is a gram-negative purple nonsulfur bacteria.[1] The cells are rod-shaped, and range in size from 0.6 to 0.9 μm wide and 0.9 to 2.0 μm long, and have a polar flagella. These cells reproduce asexually by binary fission. This bacterium can grow anaerobically (photoautotrophic or photoheterotrophic) when light is present, or aerobically (chemoheterotrophic) under dark conditions.[2] [3] It contains the photosynthetic pigments bacteriochlorophyll a and of carotenoids.
There is interest in R. sulfidophilum for its applications in producing artificial spider silk and biocompounds, waste remediation and for its use in aquaculture.[4]
Rhodovulum sulfidophilum was first reported by Hansen and Veldkamp in 1973, and given the name Rhodopseudomonas sulfidophila. The bacterium was later reclassified to the Rhodovulum genus in 1994 by Hiraishi and Ueda, as all marine Rhodobacter and Rhodopseudomonas species were transferred to the genus Rhodovulum due to marine Rhodobacter species being able to be differentiated phenotypically from the freshwater species. The Rhodovulum genus have been described with additional properties of G+C content of the DNA that ranges from 66.3 to 66.6 mol% in type strain DSM 1374.[5]
A genome draft for R. sulfidophilum DSM 1374 was published in 2013, and was predicted to have a chromosome with 3983 genes that code for protein, and two circular plasmids with 93 and 84 genes respectively. The first complete genome was published for strain DSM 2351, revealing a circular chromosome and three circular plasmids of differing DNA base-pair size.[6] Additionally, draft genomes of the AB14, AB26 and AB30 strains were published, and when compared showed diversity between the different strains of R. sulfidophilum. These draft genomes also revealed that they contained genes confirmed to be involved in cellular processes, such as carbon dioxide fixation and sulfur oxidation. Strain AB26 was discovered to have a unique 100 kb plasmid sequence homologous to plasmid 3 that contain genes related to metal metabolism and transport (e.g. manganese, nickel and zinc transport proteins). A later study that analyzed isolates of R. sulfidophilum found that AB26 reserved around 16% of its entire 4,380,746 base pair genome to transport and also had 20 response regulators, and 22 histidine kinases. Another study that genetically characterized R. sulfidophilum discovered that the bacterium contained one copy of pucA and pucB (α- and β- genes) each within the puc operon. In addition, it was found that there were no Integration Host Factor (IHF) and Fumerate and Nitrate Reductase (FNR) regulation protein binding sites in this bacterial species like with Rhodobacter sphaeroides. It was speculated that the lack of binding sites for these proteins are indicative of why the puc operon is expressed when oxygen is present. It was also discovered that while the mRNA sequences between R. sphaeroides and R. sulfidophilum were homologous, a regulatory region exhibited an exchange of TGT to CGT in R. sulfidophilum. Studying the genome of R. sulfidophilum is of particular interest for better understanding relevant metabolic pathways.
When analysing evolution and horizontal gene transfer of Proteobacteria photosynthetic gene clusters, it was shown that R. sulfidophilum shares regions of genetic similarity to a group of other species that range from Roseibacterium elongatum to Dineoroseobacter shibae.[7]
Rhodovulum sulfidophilum is metabolically versatile and can adapt to various environmental conditions by using various metabolic pathways under anaerobic conditions. Primary sources of energy for R. sulfidophilum consist of light, organic compounds and inorganic sulfur compounds.[8]
When provided with a light source and nitrogen, using either malate as a carbon source or sulfide as an electron source, it can undergo photosynthesis to produce ATP.[9] Rhodovulum sulfidophilum is capable of oxidizing sulfide or thiosulfate to yield sulfates in the ecosystem without accumulating intermediates and have an unusual tri-heme cytochrome subunit bound to the reaction center, therefore allowing for photolithoautotrophic growth.[10] Oxidation of thiosulfate is done by the SoxAX protein, which is a heterodimeric c-type cytochrome.[11] Additionally, unlike other nonsulfur purple bacteria, R. sulfidophilum is able to synthesize its peripheral antenna complex under dark aerobic conditions. Rhodovulum sulfidophilum can utilize a wide variety of organic compunds, and grows both photoorganotrophically and heterotrophically.[12]
Multiple strains of R. sulfidophilum have also been shown to be capable of photoferrotrophy, a process that fixes inorganic carbon to organic material using light and Fe(II) as the electron donor.[13] [14] Rhodovulum sulfidophilum DSM 2351 is found to produce and excrete high levels of nucleic acids, which causes cell aggregates to form.[15] Additionally, photoferrotrophic organisms like R. sulfidophilum are capable of using specific conductive minerals as electron donors through phototrophic extracellular electron uptake (pEEu).[16]
Rhodovulum sulfidophilum has been found in a variety of aquatic environments, including freshwater pelagic and benthic habitats. Rhodovulum sulfidophilum was originally isolated from the mud of the marine floor of the intertidal flats of the Dutch Waddenzee, north of the province of Groningen, Netherlands.
The particular geographic region or climate were Rhodovulum sulfidophilum can be located is dependent on growth dependent factors such as salinity, temperature, and other environmental conditions. One study discovered this species of bacteria to be abundant in the sediment surface layer of a freshwater pond while another experiment isolated it from the anaerobic sludge of Hongdao shrimp pond, located in Qingdao, China.[17] Another study isolated Rhodovulum sulfidophilum from a microbial mat within a brackish estuary in Massachusetts, USA. Additional studies also discovered R. sulfidophilum in seashore sediment samples from Osaka Bay and tidal water samples from a beach at Visakhapatnam in coastal areas of Andhra Pradesh, India.[18] [19]
Due to its metabolic flexibility, Rhodovulum sulfidophilum exhibits a relatively wide distribution and is found in a variety of aquatic habitats, especially anaerobic environments with high sulfide concentrations. The main environmental factor governing the growth of purple bacteria species such as Rhodovulum sulfidophilum. is the presence and concentration of sulfide.[20] While other Purple Non-Sulfur Bacteria (PNSB) species are incapable of surviving in sulfur-rich areas, these conditions are ideal for R.sulfidophilum as it utilizes sulfide as the donor for electrons when conducting photolithotrophic metabolic processes. Another factor contributing to the proliferation of this bacterium is organic matter concentrations in water, since it can also undergo photoorganotrophic growth. Therefore in wastewater regions with a large chemical oxygen demand, Rhodovulum sulfidophilum is still capable of growth. Based on these conditions, R. sulfidophilum is typically found in marine environments with sulfidic conditions, such as marine sediments, seawater pools, mud flats, tidal areas, and sulfur-rich coastal waters.
R. sulfidophilum has been discovered to optimally grow in areas that have a temperature range of 30-35 °C and at a pH of around 7.0.[21] Anaerobic conditions are necessary for Rhodovulum sulfidophilum's growth and to use a variety of organic compounds such as lactic, butyric, and acetic acid as carbon and energy sources in low oxygen conditions with available light. It can also use bacteriochlorophyll a and sulfur oxidation to perform photosynthesis as an adaptation to anaerobic climates with high sulfide concentrations.
Much of the greenhouse gas produced by anthropogenic activities is stored within the ocean, which is the largest existing reservoir of carbon dioxide on earth.[22] Since metabolically flexible microbes such as Rhodovulum sulfidophilum are capable of fixing carbon using multiple different pathways (e.g. ferrous iron oxidation, pEEu), researchers have begun conducting studies concerning the extent by which photoferrotrophic freshwater microbes contribute to mitigating fluctuations in marine carbon concentrations via carbon sequestration. Considering that marine sediments account for about fifty percent of global primary production, it may be worthwhile looking into how photoferrotrophic organisms such as R. sulfidophilum could contribute to reducing the amount of excess carbon within the ocean.[23]
Rhodovulum sulfidophilum contains a prophage.[24] It has been used as a model organism for lysogenic bacteria in studies regarding the role of viruses in marine biogeochemical cycles. Viruses that infect Rhodovulum sulfidophilum include bacteriophage members of the Siphoviridae family, such as Rhodovulum phage RS1 (GenBank: JF974307.1) that has a tail length of 100 nm and a capsid diameter of 46 nm.[25] Rhodovulum sulfidophilum strain P122 A, which has been cultured from deep-subseafloor sediments, has two known phages with 36kb genomes and a head/tail of 46/100 mm.
Spider silk is a strong biodegradable material well-suited for biomedical uses. However, due to the cannibalistic nature of spiders and low silk potential in spider glands, silk yields are low. Genetic approaches to increase silk production yields have been attempted.[26] The required spider genes have been successfully recombined i
In 2020, a research team in Japan identified R. sulfidophilum as a sustainable and low cost silk producing microbial cell factory. Genetically modified R. sulfidophilum can produce the hydrophobic repetitive sequence of major ampullate spidroin (MaSp), the major protein in spider silk. After constructing a plasmid containing the necessary genetic information for the MaSp1 gene, researchers conjugated the plasmid into R. sulfidophilum and observed gene expression and spider silk fiber formation in heterotrophic and autotrophic growth conditions.[27] Notably, as a photoautotroph, the marine bacteria uses low-cost, abundant and renewable resources to make the silk: CO2 as a carbon source, light as an energy source and N2 as a nitrogen source. While more work is necessary, R. sulfidophilum proves to be a sustainable, cost-effective photosynthetic microbial cell factory for artificial silk production.[28]
Given that petroleum-derived plastics are expected to persist within the environment when discarded and therefore pose a threat as a widespread pollutant, continuous research is being conducted on the production bioplastic materials as a sustainable alternative.[29] Biopolyesters, such as polyhydroxyalkanoates (PHAs), are sustainable alternatives to petroleum-based plastics as they are biodegradable, biocompatible, and can also be produced biologically.[30] [31] PHAs are a metabolic result of excess carbon.[32] This production is normally costly due to high carbon demands, however R. sulfidophilum proves to be an effective alternative as it generates its own carbon source through photosynthesis.
Rhodovulum sulfidophilum has the ability to synthesize polyhydroxyalkanoate (PHA) within bacterial cells.[33] This bacterium does so via photo-fermentation which allows it to transform specific organic acids (OAs) such as succinate, lactate, and malate as single carbon sources into the following well known polymers of the PHA family, P3HB (poly-3-hydroxybutyrate) and P3HB-co-3 HV (3-hydroxybutyrateco-3-hydroxyvalerate). Additionally, a PHA synthase (PhaC) gene is present in the R. sulfidophilum genome. Anoxygenic photosynthetic bacteria have been shown to produce higher amounts of PHA compared to oxygenic phototrophs, such as plants and cyanobacteria.
As a photoheterotrophic bacteria, R. sulfidophilum can anaerobically produce H2 from low cost organic materials in presence of light. This is reaction is catalyzed by nitrogenase which is inhibited by oxygen, ammonia and a high N:C ratio. H2 is an emerging, but controversial form of renewable energy. This process can also be used in the treatment of waste from agriculture, forestry and food processing. Additionally, the hydrogen production rate of R. sulfidophilum be maximized by rapid degradation and use of endogenous substrate poly(3-hydroxybutyrate) (PHB) which is one of the most preferable substrates for hydrogen production in this strain. It can be achieved in high-density suspension under external-substrate-depleted conditions after aerobic cultivation in the presence of an excess amount of acetate.[34]
As an anoxygenic sulfate reducing phototroph, R. sulfidophilum is used for bioremediation as it can grow in polluted environments, such as industrial fish processing wastewater.[35] Organic contamination often depletes oxygen and other terminal electron acceptors (TEA) in water and soil environments. Because of its low solubility, it is difficult to add sufficient oxygen to serve as a TEA in contaminated waters. The use of microbes to help metabolise the pollutant is an effective solution. The metabolism of the nutrients can provide substances that confer useful advantages to other organisms in the environment, which ultimately increases productivity.[36]
Aptamers are used as biosensors to detect diseases and act as therapeutics, such as in fisheries.[37] Rodovulum sulfidophilum can produce RNA antiviral aptamers against fish infecting viruses, such as hemorrhagic septicemia virus (VHSV) and hirame rhabdovirus.[38] These aptamers have been shown to reduce Japanese flounder mortality from 90% to 10% in 10 days post-infection. Rhodovulum sulfidophilum
Purple non-sulphur bacteria, such as R. sulfidophilum, have been used in aquaculture as probiotics, which are microorganisms that have health benefits.[40] Kuruma shrimp (Marsupenaeus japonicus) is an important species in the global aquaculture industry, most notably being cultured in Japan and China. Probiotics have been used as an eco-friendly, low-cost approach to boost shrimp survival by upregulating immune system genes, such as antimicrobial peptides, and moulting-related genes, including cuticle and calcification proteins. Rhodovulum sulfidophilum can be effective as a probiotic at a low concentration (10^3 cfu/mL) in rearing waters. After the addition of R. sulfidophilum various features of shrimp growth are improved: body weight (by 1.76-fold), survival rate (by 8.3%), and the feed conversion ratio (by 10%). Additionally, R. sulfidophilum has been shown to enhance the larval survival of marble goby (Oxyeleotris marmorat) and the performance of milkfish (Chanos chanos). Use of the beneficial bacteria, R. sulfidophilum, confers ammonia reduction and total phosphorus stabilization. This can help reduce the proliferation of cyanobacteria and algae blooms and eutrophication and promote the growth of other helpful bacteria, such as Acidobacteria.[41] Ultimately, R. sulfidophilum is used a probiotic to increase aquaculture efficiency and improve management.