Fact-checked by Grok 2 weeks ago

Sphingomonas

Sphingomonas is a genus of Gram-negative, strictly aerobic, rod-shaped bacteria belonging to the family Sphingomonadaceae within the class Alphaproteobacteria, distinguished by their outer membrane containing glycosphingolipids rather than lipopolysaccharides.^[1] These chemoheterotrophic microbes are typically yellow-pigmented due to carotenoids like nostoxanthin and often exhibit motility via a single polar flagellum, with a G+C content of 61–67 mol%.^[2] As of November 2025, the genus encompasses 181 validly published species, though taxonomic revisions based on genomic analyses have led to reclassifications of some into genera such as Sphingobium and Novosphingobium, reflecting its polyphyletic history since its establishment in 1990 with S. paucimobilis as the type species.^[3]^[4] Members of Sphingomonas are ubiquitous in diverse environments, including soils, freshwater and marine systems, plant rhizospheres, and contaminated sites, where they play crucial ecological roles in carbon cycling and nutrient decomposition.^[5] Notably abundant in litter-degrading microbial communities across ecosystems like deserts, grasslands, and forests, they contribute to organic matter breakdown, including lignin depolymerization, and adapt to climate variations through shifts in clade composition and functional genes related to stress tolerance and resource acquisition.^[5] Many species exhibit bioremediation potential, degrading recalcitrant pollutants such as polycyclic aromatic hydrocarbons (PAHs), polychlorinated biphenyls (PCBs), and pesticides via specialized metabolic pathways, making them valuable for environmental cleanup applications.^[6] Additionally, certain Sphingomonas strains promote plant growth by producing phytohormones like indole-3-acetic acid (IAA) and gibberellins, enhancing root development, nutrient uptake, and stress resistance in crops such as Arabidopsis, spinach, and pea.^[7] They also form biofilms and exopolysaccharides like gellan, which have industrial uses in food and pharmaceuticals.^[1] Although generally non-pathogenic, opportunistic infections, particularly by S. paucimobilis, occur in immunocompromised individuals, causing nosocomial bacteremia, septicemia, and infections in healthcare settings, often linked to contaminated water sources.^[8]

Taxonomy and Description

Classification and History

The genus Sphingomonas belongs to the domain Bacteria, phylum Pseudomonadota, class Alphaproteobacteria, order Sphingomonadales, family Sphingomonadaceae.^[4] ^[9] The genus Sphingomonas was established in 1990 by Yabuuchi et al. to accommodate a group of Gram-negative bacteria previously classified under Pseudomonas, with Sphingomonas paucimobilis designated as the type species based on 16S rRNA sequence analysis and the presence of unique glycosphingolipids in their cellular lipids. In 2001, Takeuchi et al. emended the genus description and proposed a subdivision into Sphingomonas sensu stricto along with three new genera—Sphingobium, Novosphingobium, and Sphingopyxis—drawing on phylogenetic analyses of 16S rRNA genes and chemotaxonomic markers such as ubiquinone types and polyamine profiles to resolve the heterogeneity within the original genus. As of November 2025, the genus Sphingomonas encompasses 181 validly described species, reflecting its expansive phylogenetic and ecological diversity, with notable examples including the type species S. paucimobilis, S. anseongensis described in 2023, and six new species isolated from glaciers on the Tibetan Plateau described in 2025.^[4] ^[10] The name Sphingomonas derives from the New Latin neuter noun sphingosinum (sphingosine), referencing the characteristic glycosphingolipids, combined with the Greek neuter noun monas (a unit or monad), denoting its rod-shaped, motile nature.^[4]

Morphology and Physiology

Sphingomonas species are Gram-negative, rod-shaped bacteria, typically measuring 0.5–1.0 μm in width and 1.0–2.0 μm in length.^[11] ^[12] Many strains are motile, propelled by one or more polar flagella, although some are non-motile.^[13] On solid media such as agar plates, they form circular, convex colonies that are characteristically yellow-pigmented due to the production of carotenoids or other pigments.^[14] Physiologically, Sphingomonas bacteria are strictly aerobic and chemoheterotrophic, relying on oxygen for respiration and utilizing organic compounds as carbon and energy sources.^[15] Their electron transport chain features ubiquinone-10 (UQ-10) as the predominant respiratory quinone.^[15] A distinctive feature is the composition of their outer membrane, which lacks the typical lipopolysaccharide (LPS) found in most Gram-negative bacteria; instead, it contains glycosphingolipids (GSLs) composed of a ceramide backbone linked to unique oligosaccharide chains, often including sugars like α-L-fucose or 3-O-methyl-α-L-rhamnose.^[16] ^[17]_ These GSLs contribute to membrane stability and may influence interactions with environmental stressors. Metabolically, Sphingomonas species exhibit versatility in oxidizing a broad spectrum of carbon substrates, including simple sugars, amino acids, and complex aromatic compounds such as polycyclic aromatic hydrocarbons, facilitated by an array of oxygenase enzymes like mono- and dioxygenases.^[18] Their genomes, typically ranging from 3 to 4 Mb in size with approximately 3,900 protein-coding genes and around 70 RNA genes (including multiple rRNA and tRNA operons), encode these catabolic pathways, often on large plasmids or chromosomes.^[18] ^[19]_ As oligotrophic organisms, they thrive in nutrient-poor environments, with optimal growth occurring at temperatures of 25–30°C and pH values of 6.5–7.5, though they tolerate broader ranges depending on the strain.^[20] ^[21]_ ^[22]_

Ecology and Habitat

Natural Distribution

Sphingomonas species exhibit a widespread global distribution, occurring ubiquitously in diverse natural environments such as soil, freshwater, marine waters, sediments, air, and rhizospheres, as well as in clinical samples.^[23] These bacteria are frequently isolated from both contaminated and pristine sites, reflecting their adaptability to varying ecological conditions. Their aerobic and oligotrophic physiology contributes to this broad occurrence across nutrient-limited habitats.^[23] Specific locales where Sphingomonas strains have been documented include polluted environments like oil spills and pesticide-contaminated soils, as well as unperturbed oligotrophic waters and plant root zones. For instance, Sphingomonas yanoikuyae was originally isolated from oil-contaminated soil in Japan, highlighting their presence in hydrocarbon-impacted areas.^[24] In marine settings, they are found from polar to temperate oceans, including eutrophic and oligotrophic waters, corals, and sites with natural or artificial hydrocarbons, such as the Sea of Japan where Sphingomonas japonica was identified.^[25] Additionally, strains like Sphingomonas alaskensis have been recovered from pristine Alaskan coastal waters using dilution-to-extinction methods.^[22] Abundance patterns of Sphingomonas show higher prevalence in temperate and tropical regions, with notable detection in biomes such as deserts, grasslands, shrublands, and forests across Southern California.^[26] They are also present in urban aerosols and hospital environments, including water reservoirs, ventilation systems, and clinical specimens like blood and urine.^[24] In contaminated soils, such as those from European coal gasification and railway sites with polycyclic aromatic hydrocarbon levels up to 3,022 mg kg⁻¹, Sphingomonas cell concentrations range from 10⁵ to 10⁶ cells per gram.^[27] Detection of Sphingomonas typically involves culturing on low-nutrient media to mimic oligotrophic conditions, followed by identification via 16S rRNA gene sequencing or PCR-based methods targeting specific primers like Sphingo108f/GC40-Sphingo420r.^[27] These approaches enable sensitive recovery from environmental samples, detecting as few as 10⁴ CFU g⁻¹ in soil.^[27]

Adaptations to Environments

Sphingomonas species exhibit an oligotrophic lifestyle, enabling survival in nutrient-poor environments through high-affinity, broad-specificity uptake systems that facilitate efficient scavenging of low concentrations of carbon sources. For instance, in marine ultramicrobacterium Sphingomonas sp. strain RB2256, these systems support predicted in situ doubling times of 12 hours to 3 days, crucial for biomass turnover in oligotrophic waters. During starvation, the bacterium maintains ribosomal integrity, retaining up to 10% of maximum ribosomes and protein content, which allows rapid recovery upon nutrient availability without extensive resynthesis. Additionally, production of exopolysaccharides (EPS), such as promonan in Sphingomonas sp. LM7 from freshwater habitats, promotes biofilm formation by creating a gelatinous matrix that traps and concentrates scarce nutrients, enhancing uptake efficiency in low-carbon settings.^[28]^[28]^[29] These bacteria demonstrate robust stress resistance, tolerating heavy metals, UV radiation, desiccation, and low temperatures via specialized cellular components. Tolerance to heavy metals like cadmium (Cd²⁺) in strains such as Sphingomonas sp. M1-B02 involves biosorption on cell surfaces through hydroxyl and nitro groups, coupled with efflux pumps and antioxidant enzymes (e.g., those encoded by mutL and recA genes), achieving up to 80% adsorption efficiency under stress.^[30] Pigment-based antioxidants, including carotenoids like nostoxanthin produced by Sphingomonas nostoxanthinifaciens, scavenge reactive oxygen species (ROS) generated by UV radiation and oxidative damage, providing photoprotection in exposed environments.^[20] Desiccation resistance is evident in species like Sphingomonas desiccabilis, where cellular adaptations maintain viability over extended dry periods.^[31] Membrane glycosphingolipids (GSLs), unique to Sphingomonadaceae and replacing lipopolysaccharides, enhance hydrophobicity and membrane stability, supporting growth at low temperatures down to 8°C and overall resilience to physicochemical stresses.^[32] In response to pollutants, Sphingomonas employs enzymatic pathways for partial degradation of xenobiotics, such as polycyclic aromatic hydrocarbons (PAHs) and pesticides, without relying on complete bioremediation processes. For example, Sphingomonas sp. utilizes chemotaxis and genes for naphthalene and benzopyrene catabolism to target and break down PAHs like fluoranthene and pyrene via dioxygenase-mediated ring cleavage.^[33]^[33] Symbiotic associations with microbial consortia in contaminated sites bolster ecosystem resilience, as Sphingomonas acts as a keystone species dominating PAH-polluted coking soils with up to 6% relative abundance. In these networks, it enhances community stability through metabolic interactions, degrading persistent pollutants like PAHs while coexisting with other degraders to promote overall microbial diversity and soil recovery. Such consortia dynamics underscore Sphingomonas's role in fostering adaptive microbial ecosystems under anthropogenic stress.^[33] Sphingomonas clade composition varies across climate gradients, with different clades adapted to site conditions through shifts in functional genes related to stress tolerance and resource acquisition, as observed in ecosystems from deserts to forests.^[26]

Pathogenicity and Interactions

Role in Human Disease

Sphingomonas paucimobilis is recognized as the primary species within the genus associated with human infections, functioning as an opportunistic nosocomial pathogen that predominantly affects immunocompromised individuals. It causes a range of infections, including bacteremia (reported in approximately 41% of cases), pneumonia (around 14%, often ventilator-associated), and catheter-related bloodstream infections, particularly in patients with indwelling medical devices. These infections arise due to the bacterium's environmental ubiquity, including its presence in hospital water systems and clinical settings, which facilitates transmission in healthcare environments.^[34]^[35] Epidemiologically, S. paucimobilis infections remain rare, accounting for about 1.3% of clinical isolates in large hospital surveys, but mortality rates are low at around 6%, reflecting the organism's generally low virulence, though complications can arise in vulnerable populations such as those with diabetes or undergoing steroid therapy. Antibiotic resistance poses a challenge, mediated by mechanisms including efflux pumps that expel drugs from the cell and intrinsic production of beta-lactamases, conferring resistance to beta-lactams like penicillin and first-generation cephalosporins, as well as variable resistance to colistin (up to 61%).^[34]^[36]^[37] Key virulence factors include the ability to form biofilms on medical devices such as catheters, enhancing persistence and evasion of host defenses. Diagnosis typically involves culture identification followed by confirmation via matrix-assisted laser desorption/ionization-time of flight mass spectrometry (MALDI-TOF MS) or 16S rRNA gene sequencing for accurate speciation. Treatment is guided by susceptibility testing, with most isolates remaining sensitive to carbapenems like meropenem (susceptibility around 67-75%) and fluoroquinolones such as levofloxacin (about 74%), allowing effective management in most cases.^[34]^[35]^[36]

Interactions with Plants and Ecosystems

Sphingomonas species frequently colonize the rhizosphere of various plants, where they promote growth through mechanisms such as phosphate solubilization and nitrogen fixation. For instance, Sphingomonas panaciterrae NB5, an endophytic bacterium, enhances root morphology and nutrient uptake in red amaranth by improving soil properties that increase available phosphorus and nitrogen contents, thereby increasing plant biomass and yield.^[38] Similarly, Sphingomonas sediminicola Dae20 acts as a plant growth-promoting rhizobacterium (PGPR) in the rhizosphere, influencing soil microbial communities to facilitate nutrient availability and root development in Brassicaceae crops such as rapeseed and mustard.^[39] These oligotrophic adaptations, which enable survival in nutrient-poor root zones, further support effective colonization. In broader ecosystems, Sphingomonas contributes to nutrient cycling by decomposing organic matter and attenuating pollutants in natural settings. As abundant members of litter-degrading microbial communities in diverse habitats like deserts and grasslands, they participate in carbon and nutrient turnover, serving as key decomposers in microbial food webs. Additionally, their natural capacity to degrade polycyclic aromatic hydrocarbons (PAHs) and other persistent pollutants helps mitigate environmental contamination in soils and sediments, supporting ecosystem resilience without engineered interventions.^[5] Beneficial interactions extend to the production of signaling molecules that facilitate plant-microbe communication, often enhancing agricultural outcomes. Many Sphingomonas strains synthesize phytohormones such as indole-3-acetic acid (IAA) and gibberellins, which regulate plant root architecture and stimulate growth; for example, Sphingomonas sp. LK11 produces these compounds to promote tomato development.^[40] In agriculture, species like Sphingomonas sp. Hbc-6 improve drought tolerance in maize and Arabidopsis by altering plant metabolism and recruiting beneficial rhizosphere microbes, leading to increased biomass under stress conditions.^[41]^[42] A notable case is Sphingomonas melonis, which, as a seed endophyte in rice, induces resistance to bacterial seedling blight caused by Burkholderia plantarii through secretion of antimicrobial compounds that inhibit pathogen virulence factors.^[7] Although predominantly beneficial, rare Sphingomonas strains exhibit phytopathogenic traits, causing diseases in specific crops. Sphingomonas melonis has been identified as the causal agent of brown spot disease on melon fruits, leading to necrotic lesions.^[43] Other isolates, such as Sphingomonas spermidinifaciens, cause bacterial leaf spot on plum trees, while certain Sphingomonas spp. are associated with bacterial leaf blight in rice, resulting in foliar damage and reduced yields.^[44]^[45] These negative impacts are uncommon compared to the genus's symbiotic roles.

Biotechnological Applications

Bioremediation and Degradation

Sphingomonas species exhibit remarkable degradation capabilities for environmental pollutants, primarily through specialized enzymatic mechanisms. These bacteria efficiently break down polycyclic aromatic hydrocarbons (PAHs) such as phenanthrene using ring-hydroxylating dioxygenases, which initiate the oxidative cleavage of aromatic rings. For instance, Sphingobium sp. strain SHPJ-2 demonstrates potent degradation of high-molecular-weight PAHs like fluoranthene, pyrene, and benzoanthracene via diverse pathways involving initial dioxygenase attack followed by ring fission.^[46] Additionally, certain strains degrade pesticides; Sphingobium yanoikuyae XJ effectively metabolizes organophosphate pesticides through hydrolytic enzymes.^[47] In the realm of plastics, Sphingomonas isolates have shown the ability to degrade polyethylene, achieving up to 56% weight loss in black polyethylene films under laboratory conditions via biofilm formation and oxidative enzymes. Sphingobium yanoikuyae strains further contribute by degrading polychlorinated biphenyls (PCBs), utilizing biphenyl as a model substrate through biphenyl dioxygenase and subsequent dechlorination pathways.^[48] The mechanisms underlying these degradations often involve the catechol ortho-cleavage pathway for aromatic compounds, where initial dioxygenase-mediated hydroxylation produces catechol, followed by ortho-cleavage to form muconic acid derivatives that enter central metabolism. In Sphingomonas yanoikuyae B1, this pathway intertwines with meta-cleavage routes for efficient utilization of substituted benzoates derived from PAHs and other aromatics. Sphingomonas bisphenolicum AO1 degrades bisphenol A via a flavin-dependent monooxygenase pathway, achieving complete mineralization.^[49] In field applications, Sphingomonas strains are inoculated into oil spill sites and contaminated soils to accelerate pollutant removal, often in consortia with other bacteria for synergistic effects. A 2020 study in petroleum-hydrocarbon-contaminated soil demonstrated that a Sphingomonas changbaiensis and Pseudomonas stutzeri consortium, augmented with biosurfactants like alkyl polyglycosides, increased total petroleum hydrocarbon degradation by over 70% compared to uninoculated controls, highlighting enhanced bioavailability and microbial activity.^[50] Similarly, in saline soils from industrial sites, biochar-immobilized Sphingomonas sp. PJ2 improved PAH removal to 60.4% over 60 days, outperforming free cells by protecting bacteria from osmotic stress.^[51] Despite these successes, Sphingomonas-based bioremediation shows strong efficacy in lab-scale experiments but variable performance in field settings due to environmental factors such as pH, nutrient availability, and competition from native microbiota. Case studies from the 2020s, including the Shenfu irrigation area in China, reveal that while Sphingomonas isolates degraded PAHs in petroleum-contaminated soils at rates up to 50% in mesocosms, field trials faced limitations from low survival rates and incomplete mineralization, necessitating amendments like biochar for sustained efficacy. Overall, these metabolic versatilities, as noted in physiological studies, underpin their applied potential in pollutant breakdown.

Industrial and Fermentation Uses

Sphingomonas species are exploited in industrial biotechnology primarily for the microbial production of sphingans, a class of exopolysaccharides with valuable rheological properties. Gellan gum, biosynthesized by Sphingomonas elodea (ATCC 31461), serves as a gelling agent and stabilizer in food products such as desserts and beverages, as well as in pharmaceutical formulations for controlled drug release. Industrial fermentation processes typically employ batch or fed-batch strategies in simplified media containing glucose as the carbon source, achieving yields of up to 17.71 g/L under optimized conditions at 30°C and pH 7.0.^[52] The global market for gellan gum, reflecting its annual production scale, was valued at approximately USD 63.2 million in 2025, driven by demand in the food and beverage sector.^[53] Welan gum, produced by Sphingomonas sp. strains such as RW and ATCC 31555, functions similarly as a thickener in food emulsions and a suspending agent in pharmaceuticals, with engineered variants yielding up to 25.11 g/L using low-cost substrates like whey and tofu wastewater.^[54] Beyond biopolymers, Sphingomonas strains contribute to enzyme production for industrial applications, including detergent-compatible lipases and esterases that enhance stain removal under cold-wash conditions. For instance, cold-adapted esterases from Sphingomonas glacialis exhibit stability in organic solvents and surfactants, supporting their integration into eco-friendly laundry formulations.^[55] Emerging post-2020 research highlights Sphingomonas' role in green nanotechnology, where strains like S. paucimobilis BDS1 extracellularly synthesize silver nanoparticles (50-80 nm) via reduction of AgNO₃, forming stable dispersions suitable for antimicrobial coatings and potential drug delivery systems.^[56] Similarly, Sphingomonas sp. enables biomimetic synthesis of TiO₂ nanoparticles, which show promise in targeted therapeutic delivery due to their biocompatibility and low toxicity.^[57] In fermentation processes, Sphingomonas participates in wine production, influencing microbial terroir and contributing to the sensory profile of red wines through its presence during spontaneous or early-stage fermentations. Strains such as Sphingomonas sp. are detected in grape must and evolving wines, where they correlate with volatile metabolites like esters and aldehydes that impart fruity and complex aromas, though their exact contributions remain under study.^[58] Commercial exploitation involves engineered Sphingomonas variants, such as IrrE-overexpressing strains of Sphingomonas sp. NX-3, which boost welan gum yields to 20.26 g/L at elevated temperatures (40°C) without pH adjustment, reducing production costs by minimizing energy and chemical inputs.^[59] Gellan gum-producing strains hold Generally Recognized as Safe (GRAS) status from the FDA since 1992, enabling their safe use in food-grade applications following rigorous safety assessments of genomic stability and absence of virulence factors.

References

[1]
[PDF] The genus Sphingomonas: physiology and ecology
These Gram-negative aerobic bacteria are characterized by an outer membrane that contains glycosphingolipids, but lacks lipopolysaccharide. Their distribution ...
[2]
Variation in Sphingomonas traits across habitats and phylogenetic ...
Apr 16, 2023 · Within the Proteobacteria phylum, the Sphingomonas genus contains gram-negative, strictly aerobic, chemoheterotrophic, yellow-pigmented bacteria ...Abstract · Introduction · Materials and methods · Discussion
[3]
Diverse biofilm-forming Sphingomonadaceae represent twelve ...
Sep 8, 2025 · Recent genomic-based taxonomic revisions have reclassified some Sphingomonas species into new genera, such as Parasphingomonas and ...
[4]
https://lpsn.dsmz.de/genus/sphingomonas
[5]
Sphingomonas: from diversity and genomics to functional role in ...
In this review, we elucidated the prospective role and function of this genus for improved utilization during environmental biotechnology. Keywords: ...
[6]
Genomic Characterization of Potential Plant Growth-Promoting ...
Jan 12, 2022 · This study describes the isolation and identification of Sphingomonas members from the ISS, which are capable of producing the phytohormone indole-3-acetic ...Missing: ecology | Show results with:ecology
[7]
Genus: Sphingomonas - LPSN
Sphingomonas is a genus of a sphingosine-containing monad, with the type species being Sphingomonas paucimobilis.
[8]
Sphingomonas sp. - NCBI - NIH
THE NCBI Taxonomy database allows browsing of the taxonomy tree, which contains a classification of organisms.Missing: hierarchy | Show results with:hierarchy
[9]
Diverse biofilm-forming Sphingomonadaceae represent twelve ... - NIH
Sep 8, 2025 · At the time of writing this manuscript (July 2025), the genus Sphingomonas comprised 171 species with validly published names [8], highlighting ...
[10]
A nostoxanthin-producing bacterium, Sphingomonas ... - NIH
Feb 10, 2023 · Cells are Gram-negative, catalase-, oxidase-positive, non-motile, and rod-shaped (0.3–0.5 μm in width and 0.9–1.2 μm in length), without ...
[11]
Sphingomonas abietis sp. nov., an Endophytic Bacterium Isolated ...
In 2001, further classification based on phylogenetic and chemotaxonomic analyses subdivided the genus Sphingomonas into three new genera: Sphingobium ...
[12]
Sphingomonas - an overview | ScienceDirect Topics
Sphingomonas is a group of gram negative, rod shaped, chemoheterotrophic, strictly aerobic bacteria containing glycosphingolipids (GSLs) in their cell envelopes ...
[13]
Sphingomonas - an overview | ScienceDirect Topics
Sphingomonas spp. refers to a group of microorganisms that are generally not human pathogens but can occasionally cause nosocomial infections and septic shock ...
[14]
Characterization and identification of a chlorine-resistant bacterium ...
Members of the Sphingomonas genus are a group of Gram-negative, rod-shaped, chemoheterotrophic and strictly aerobic bacteria.
[15]
The genus Sphingomonas: physiology and ecology - ScienceDirect
This paper proposes the reclassification of two previously existing species (A. rhizogenes and C. lividum) as Sphingomonas sp. on the basis of phenotypic and ...
[16]
Biopolymers Produced by Sphingomonas Strains and Their ...
May 9, 2022 · All Sphingomonas cell membranes contain glycosphingolipids instead of lipopolysaccharide. Glycosphingolipids are composed of dihydrosphingosine, ...
[17]
Comparison of 26 Sphingomonad Genomes Reveals Diverse ...
We find that many of the sphingomonad genomes encode numerous oxygenases and glycoside hydrolases, which are likely responsible for their ability to degrade ...Missing: traits | Show results with:traits
[18]
Complete Genome Sequence of Sphingomonas paucimobilis Strain ...
The genome of S. paucimobilis strain Kira consists of 3,917,410 bp, with a G+C content of 65.7%, harboring 3,672 protein-coding sequences, 9 rRNAs, 60 tRNAs ...Missing: type | Show results with:type
[19]
A nostoxanthin-producing bacterium, Sphingomonas ... - Frontiers
Strain AK-PDB1-5T had a genome size of 4,298,284 bp with a 67.8% G + C content, and digital DNA–DNA hybridization and OrthoANI values with the most closely ...
[20]
Sustainability in the Production of Gellan Gum From Sphingomonas ...
Sep 12, 2024 · The genus Sphingomonas belongs to the family Sphingomonadaceae, first diagnosed in 1990, it is a gram-negative bacillus bacterium, positive for catalase and ...
[21]
Sphingomonas alaskensis Strain AFO1, an Abundant Oligotrophic ...
The cellular morphology of strain AFO1 was examined by AFM, the cells were oval or rod shaped, and flagella were not detected. Lack of flagella was consistent ...
[22]
Variation in Sphingomonas traits across habitats and phylogenetic ...
Apr 17, 2023 · Moreover, the Sphingomonas genus classification is still evolving; Sphingomonas has five sub-genus classifications, and although additional ...Missing: review | Show results with:review
[23]
Sphingomonas - an overview | ScienceDirect Topics
Sphingomonas is a newly named genus of uncommon, aerobic, Gram-negative bacilli found in moist areas of hospital environment and occasionally as a cause of ...<|separator|>
[24]
Sphingomonads from marine environments - PubMed
In addition they are found in oceans spanning temperature ranges from polar to temperate waters. While less is known about marine sphingomonads in comparison to ...Missing: distribution | Show results with:distribution
[25]
Sphingomonas clade and functional distribution with simulated ... - NIH
Apr 4, 2024 · Sphingomonas is the most abundant gram-negative bacterial genus in litter-degrading microbial communities of desert, grassland, shrubland, and ...
[26]
Occurrence and Phylogenetic Diversity of Sphingomonas Strains in ...
All cultures were incubated in the dark on an orbital horizontal shaker at 200 rpm at a constant temperature of 30°C. TABLE 1. Bacterial strains used in this ...
[27]
Physiological Responses to Starvation in the Marine Oligotrophic ...
While this class of bacteria is well adapted for growth with low concentrations of nutrients, their ability to respond to complete nutrient deprivation has not ...Missing: scarcity exopolysaccharides<|control11|><|separator|>
[28]
An exopolysaccharide pathway from a freshwater Sphingomonas ...
We studied a novel polysaccharide called promonan that is produced by Sphingomonas sp. LM7, a bacterium we isolated from Lake Michigan.
[29]
UV-C Exposure Enhanced the Cd2+ Adsorption Capability of ... - NIH
Dec 18, 2024 · It was demonstrated that exposure to Cd2+ induces oxidative stress in microorganisms, and Sphingomonas sp. responds to Cd2+ stress by enhancing ...Missing: carotenoids GSLs
[30]
Isolation and characterization of Sphingomonadaceae from fouled ...
Jan 25, 2019 · Their growth conditions ranged from temperatures between 8 and 42 oC, salinity between 0.0 and 5.0% w/v NaCl, pH from 4 and 10, and all ...
[31]
Sphingomonas Relies on Chemotaxis to Degrade Polycyclic ... - NIH
May 27, 2022 · We found that Sphingomonas sp. contained 4110 predicted genes. The genome size was 2.52 Mb and the GC content was 67.70%. The gene density was ...<|separator|>
[32]
Regulation of quorum sensing activities by the stringent response ...
Apr 4, 2024 · This study extends the current knowledge on the intricate networks between stringent response and QS system in sphingomonads, which would help to understand ...
[33]
Evaluation of Sphingomonas paucimobilis as an emerging ...
This study aimed to investigate the clinical features, associated co-morbidities, and antimicrobial susceptibility patterns of S. paucimobilis infection in a ...
[34]
Sphingomonas Paucimobilis: A Rare Infectious Agent Found ... - NIH
Jul 31, 2017 · So far, a variety of infections have been reported, including sepsis, septic pulmonary embolism, septic arthritis, peritonitis, and ...
[35]
[PDF] Sphingomonas Paucimobilis Bacteria Isolation From Different ...
Feb 1, 2025 · Sphingomonas paucimobilis isolates were screened for their resistance to ten widely used antibiotics ... efflux pumps. Growing beta ...
[36]
Sphingomonas paucimobilis - an overview | ScienceDirect Topics
Mechanisms of resistance include altered outer membrane permeability (altered protein porins or lack of protein porin OprD), production of β-lactamases, ...