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Oscillatoria

Oscillatoria is a of filamentous in the order Oscillatoriales, characterized by unbranched, motile trichomes that lack sheaths and exhibit gliding or oscillating movement, with cells typically shorter than wide and isodiametric in shape. Named for this distinctive , the includes that form mats in environments and are known for their oxygenic as ancient gram-negative prokaryotic autotrophs. Taxonomically, Oscillatoria belongs to the family Oscillatoriaceae within the Cyanophyceae class, with the type species O. princeps serving as the reference for the genus, which has been emended based on morphological and phylogenetic analyses using 16S rRNA gene sequencing to confirm its monophyletic position; the emended genus currently comprises only two species, O. princeps and O. kawamurae. Over 300 species have been described historically, though many have been reclassified into genera like Phormidium and Geitlerinema due to polyphyletic issues in earlier taxonomy. Morphologically, trichomes range from 7 to 80 μm in width, with thick cell walls featuring large pores, no calyptra, and apical cells that are rounded or slightly bent; reproduction occurs primarily through hormogonia fragmentation. Ecologically, Oscillatoria species inhabit a wide range of environments, from freshwater lakes, rivers, and hot springs to and terrestrial settings, often forming benthic mats or planktonic blooms in oligotrophic to eutrophic waters worldwide. They demonstrate positive phototaxis, enabling rapid migration toward light, and contribute to nutrient cycling by fixing or releasing organic carbon in ecosystems. Some species, such as O. limnetica (now reclassified), are associated with production, including microcystins and anatoxins, posing risks to and human in bloom events. Beyond , Oscillatoria holds significant biotechnological potential due to its production of bioactive metabolites, such as pigments (e.g., , phycobiliproteins, β-carotene), fatty acids, and compounds like oscillapeptins with , cytotoxic, anticancer, and properties, supporting applications in biofuels, nutraceuticals, and pharmaceuticals. These cyanobacteria's high nutritional content—ranging from 21–57% protein and 9–17% —further underscores their value in sustainable resource development, though only a fraction of have been fully characterized.

Description

Morphology

Oscillatoria is characterized by unbranched, filamentous structures known as , consisting of a single row of cylindrical or barrel-shaped cells arranged end-to-end without branching. These range from 0.6 to 80 μm in width and can extend up to several millimeters in length, forming flexible, elongated strands that enable collective behaviors in natural environments. The cells within the are uniform in , typically as long as wide or shorter than wide, contributing to the overall rigidity and of the . A distinctive feature of Oscillatoria is the oscillatory motion of its , which exhibit pendulum-like swinging at the tips while the as a whole glides forward. This movement, reaching speeds of up to 4 μm/s, is powered by the secretion of at the ends and the of underlying fibrillar structures in the , propelling the without the aid of flagella. The apical cells at the ends are typically rounded or slightly tapered, distinguishing them from the more uniform vegetative and facilitating directed . Unlike some other , Oscillatoria species lack specialized heterocysts for or akinetes for , maintaining a simple, undifferentiated cellular organization throughout the , and lack sheaths in natural conditions. In natural settings, Oscillatoria filaments often aggregate to form macroscopic mats or tufts on substrates such as sediments or rocks, creating layered colonies that can appear woolly or caespitose. These structures arise from the entanglement of multiple trichomes, which are prone to fragmentation at irregular intervals, allowing for the dispersal and regeneration of new filaments. This fragmentation contributes to the resilience and spread of Oscillatoria populations without relying on complex reproductive structures. The genus definition has been emended based on morphological and phylogenetic analyses, restricting it to species with wide trichomes (typically 22–80 μm), cells much shorter than wide, and absence of sheaths in natural conditions.

Cellular Structure

Oscillatoria cells are prokaryotic, characterized by the absence of a membrane-bound nucleus and organelles, with genetic material organized in a nucleoid region consisting of a single circular chromosome of double-stranded DNA, often accompanied by smaller plasmids. This nucleoid is immersed in the cytoplasm without a nuclear envelope, allowing direct interaction between DNA and cellular machinery, a hallmark of prokaryotic organization typical in cyanobacteria. The photosynthetic apparatus in Oscillatoria is housed within thylakoid membranes that are arranged in parallel stacks or lamellae within the peripheral cytoplasm, enabling oxygenic photosynthesis. These thylakoids contain chlorophyll a as the primary photosynthetic pigment, along with accessory phycobiliproteins such as phycocyanin and phycoerythrin, which form phycobilisomes to efficiently absorb light in the 500–650 nm range and transfer energy to the reaction centers. Phycoerythrin is particularly prominent in certain Oscillatoria species adapted to red light environments, enhancing light harvesting in shaded or deeper waters. The of Oscillatoria consists of a multilayered resembling , with an inner layer of providing rigidity and shape, overlaid by an outer membrane. is facilitated by secreted . Inclusions within the cells include gas vacuoles, present in some planktonic , which are proteinaceous structures filled with gas that adjust by collapsing under in response to . Additionally, granules serve as storage reserves for , accumulating under nutrient-rich conditions to support growth during scarcity.

Habitat and Distribution

Environmental Preferences

Oscillatoria species predominantly favor freshwater environments with neutral to slightly alkaline levels between 6.5 and 8.5, conditions that support their metabolic processes and filament integrity. Within this range, optimal growth often occurs near 7, where enzymatic activities and nutrient uptake are maximized, as observed in laboratory cultures of Oscillatoria strains exposed to varying gradients from 6 to 9. Deviations toward acidity below 6.5 or strong above 8.5 can reduce accumulation and disrupt cellular functions, limiting proliferation in such waters. These exhibit a preference for moderate levels, with serving as a critical driver of growth in phosphorus-limited systems. In eutrophic waters enriched with , Oscillatoria demonstrates resilience, forming dense mats that capitalize on elevated availability to outcompete other . This adaptability underscores their role in , though excessive can sometimes shift community dominance away from Oscillatoria toward other bloom-formers. Temperature tolerance varies among species, but many Oscillatoria strains withstand high thermal regimes up to 45°C, particularly thermophilic variants in hot springs and thermal pools where water temperatures exceed 40°C. Such heat resistance enables vertical migrations and survival in stratified waters with diurnal fluctuations, maintaining photosynthetic activity under elevated temperatures that inhibit mesophilic competitors. Oscillatoria thrives under aerobic conditions with ample illumination for oxygenic , relying on I and II to fix . Certain species, such as Geitlerinema sp. (formerly Oscillatoria limnetica), exhibit facultative anaerobiosis, enabling survival in low-oxygen environments through using as an when oxygen levels drop. Despite resilience in nutrient-rich eutrophic settings, Oscillatoria displays sensitivity to , with ions like and inhibiting growth rates and at concentrations as low as 1–5 mg/L. This vulnerability manifests as reduced filament length and , highlighting limits to their tolerance in metal-contaminated waters despite biosorptive capabilities in some strains.

Global Occurrence

Oscillatoria exhibits a widespread in a variety of and terrestrial environments, including freshwater, , and brackish bodies across all continents, as well as moist soils and rock surfaces. In settings, contribute significantly to planktonic communities, such as in the where they comprise a major portion of in surface waters. This genus thrives in diverse systems, from slow-moving streams to stagnant pools, contributing to its ubiquity in various ecosystems worldwide. In North America, Oscillatoria is commonly found in the Great Lakes, where it forms part of cyanobacterial communities in these large freshwater basins. Similarly, in Europe, populations are prevalent in the Baltic Sea region, particularly in associated riverine and coastal inflows supporting filamentous cyanobacteria. In Asia, the genus is abundant in wetlands of the Indian subcontinent, such as those in industrialized districts and paddy fields, where it dominates in nutrient-enriched waters. Oscillatoria also inhabits extreme environments, demonstrating remarkable adaptability. It has been documented in melt ponds, where psychrophilic strains form mats in cold, transient water bodies on shelves. In , the occurs in soda lakes like in , persisting in highly alkaline, saline conditions near hot springs. Seasonal dynamics play a key role in its proliferation, with blooms frequently observed during summer months due to elevated water temperatures that favor growth. These summer peaks are particularly noted in temperate freshwater systems, aligning with broader patterns of cyanobacterial expansion under warming conditions.

Reproduction

Asexual Reproduction

Oscillatoria, a of filamentous , reproduces asexually through binary fission of individual cells, which occurs perpendicular to the longitudinal axis of the , leading to elongation of the . This process involves transverse division without a distinct mitotic apparatus, typical of prokaryotic organisms, where daughter cells grow to mature size before subsequent divisions. The primary mode of propagation involves fragmentation of the into shorter segments known as hormogonia, which are motile fragments consisting of a few to several cells. These hormogonia detach from the parent filament, often facilitated by the formation of separation discs or necridia (), and glide away using mechanisms to establish new colonies. Hormogonia formation allows for rapid dispersal and colonization, enabling the development of independent filaments under favorable conditions. Oscillatoria lacks sexual reproduction and does not produce spores such as akinetes or endospores, relying exclusively on this vegetative propagation for population expansion. The rate of cell division and hormogonia production is influenced by environmental factors, particularly light intensity and nutrient availability.

Life Cycle Characteristics

Oscillatoria exhibits a simple life cycle dominated by a continuous growth phase, where filaments elongate through repeated binary cell divisions without the development of distinct juvenile or adult stages. Cell division occurs perpendicular to the longitudinal axis of the trichome, with each daughter cell expanding to the size of the parent cell before the next division, enabling steady filament extension under favorable conditions. This vegetative mode of development underscores the genus's unicellular-like behavior despite its multicellular filamentous organization, allowing for efficient resource utilization in dynamic aquatic environments. Population dynamics of Oscillatoria are marked by rapid clonal expansion during blooms, driven by fragmentation into hormogonia that disperse and initiate new growth, leading to increases in under nutrient-rich, warm waters.

Taxonomy

Classification History

The Oscillatoria was first established by Jean-Pierre-Étienne Vaucher in as a encompassing filamentous characterized by their oscillating . Initially grouped with blue-green algae (Cyanophyceae) due to superficial resemblances to eukaryotic , the underwent a major reclassification in the mid-1970s when the prokaryotic nature of these organisms was firmly recognized through ultrastructural and biochemical studies, leading to their designation as within the bacterial kingdom; this shift was prominently articulated in the influential review by Stanier and Cohen-Bazire (1977), which proposed the term "cyanobacteria" to replace "blue-green algae" and emphasized their monophyletic prokaryotic lineage. During the and , morphological and ultrastructural analyses prompted significant taxonomic revisions that fragmented the broadly defined Oscillatoria, with many reassigned to distinct genera such as Lyngbya (for sheathed, non-motile forms), Planktothrix, Leptolyngbya, and Limnothrix based on criteria like filament sheaths, cell dimensions, and ecological adaptations; these changes were systematically outlined in the comprehensive treatment by Anagnostidis and Komárek (1988), which redefined the order Oscillatoriales and reduced the core Oscillatoria to unsheathed, motile trichomes. Post-2000 molecular phylogenetic studies, particularly those employing 16S rRNA sequencing, further revealed the polyphyletic nature of Oscillatoria, demonstrating that its clustered into multiple lineages across the cyanobacterial tree rather than forming a single , which necessitated additional generic reassignments and highlighted the limitations of alone; a pivotal by et al. (2002) exemplified this by examining water-bloom-forming strains and proposing new taxa like Planktothricoides to resolve paraphyletic groupings.

Current Taxonomic Status

Oscillatoria is classified within the phylum Cyanobacteriota, order Oscillatoriales, and family Oscillatoriaceae. This placement reflects its position among non-heterocystous filamentous , as established through phylogenomic analyses of cultivated strains. The genus is morphologically defined by unbranched, often motile trichomes consisting of short, cylindrical to discoid cells without heterocysts or akinetes, with the distinctive oscillatory serving as a key diagnostic trait. This motility, observed in living filaments, arises from cellular contractions and expansions, distinguishing Oscillatoria from similar genera lacking such movement. While earlier phylogenetic studies based on 16S rRNA and other molecular markers demonstrated that Oscillatoria was polyphyletic, with strains distributed across multiple clades within Oscillatoriales, a 2018 emendation redefined the genus sensu stricto as monophyletic, centered on the O. . This revision, based on an epitype (strain CCALA 1115) and 16S rRNA sequencing, limits the genus to two : O. and O. kawamurae, with many former reclassified into other genera. For instance, certain previously assigned to Oscillatoria have been reclassified into the genus Pseudoscillatoria based on genomic and phenotypic evidence, such as in the case of Pseudoscillatoria coralii, which exhibits distinct pigmentation and growth optima adapted to marine environments. Modern classification of Oscillatoria relies on a polyphasic that integrates morphological features, ecological niches, and molecular data, particularly sequences of the rpoC1 alongside 16S rRNA, to ensure monophyletic groupings. The sequencing of the epitype for O. princeps has provided a reliable phylogenetic reference point for the .

Species Diversity

Notable Species

Oscillatoria is a diverse of filamentous encompassing approximately 100 accepted , though taxonomic revisions continue due to molecular and morphological analyses revealing cryptic diversity. Oscillatoria princeps, the of the , is distinguished by its exceptionally large filaments, with cell widths reaching up to 55 μm, making it one of the largest . These robust trichomes are commonly found in tropical and subtropical freshwater and brackish environments, contributing to benthic mats in warm, nutrient-enriched waters.

Intraspecific Variation

Within species of Oscillatoria, morphological variation is prominent, particularly in filament width and cell shape, often attributable to environmental plasticity. Strains exhibit trichome widths ranging from 2.3 to 9.8 µm and cell lengths from 1.3 to 5.1 µm, with overlapping dimensions that preclude clear morphological distinctions among variants. These differences arise from adaptations to fluctuating conditions such as temperature (optimal growth between 10–40°C) and light intensity, allowing filaments to adjust shape and motility for better resource acquisition in diverse aquatic habitats. In Antarctic populations, intraspecific morphotypes of O. priestleyi are recognized primarily by variations in trichome width, reflecting local environmental pressures like low temperatures and nutrient scarcity. Genetic diversity within Oscillatoria species is substantial, as demonstrated by molecular analyses that uncover cryptic lineages. Sequencing of 16S rDNA and DNA-DNA hybridization of 75 strains revealed high intraspecific similarity (>99.2%) within groups but distinct subgroups differentiated by pigment composition and hybridization values (<55% between subgroups), indicating hidden genetic variation not apparent from morphology alone. Restriction fragment length polymorphism analysis of 16S rDNA further highlights genotypic diversity among oscillatoriacean strains, suggesting the presence of cryptic species adapted to specific niches. This genetic heterogeneity contributes to the genus's adaptability but complicates taxonomic delineation. Ecotypes of Oscillatoria display specialized adaptations to abiotic stressors, such as salinity and temperature gradients. Halotolerant strains, including O. earlei, thrive in brackish waters with salinities up to 3% NaCl, achieving maximum growth at intermediate levels while maintaining viability in freshwater to hypersaline conditions. Similarly, isolates from oil-contaminated brackish environments tolerate up to 5% NaCl, enabling persistence in transitional ecosystems. Temperature-adapted ecotypes, such as those in thermal springs, exhibit enhanced motility and filament coiling under heat stress, optimizing photosynthetic efficiency. Low inter-strain gene flow fosters the development of localized populations within Oscillatoria species, driven by limited dispersal of filamentous forms and physical barriers in aquatic environments. Genomic studies of related oscillatoriales show high differentiation (F_ST >0.5) between populations, with recombination rates insufficient to homogenize alleles across strains. This isolation promotes divergence, as seen in benthic versus planktonic variants, where exchange is rare due to habitat specificity.

Ecology

Ecological Roles

Oscillatoria species serve as key primary producers in freshwater and sometimes ecosystems, utilizing oxygenic to fix atmospheric into organic compounds. This process is fundamental to the base of aquatic webs, where Oscillatoria filaments often dominate in nutrient-rich environments such as hypertrophic lakes. In certain shallow eutrophic lakes, populations of Oscillatoria, particularly species like Planktothrix agardhii (formerly O. agardhii), can account for a substantial portion of the total biomass, reaching up to 50% in cases of heavy dominance during seasonal peaks. As non-heterocystous , Oscillatoria species are capable of , converting atmospheric dinitrogen (N₂) into bioavailable forms that support ecosystem productivity. This activity occurs primarily under microaerobic conditions, often during dark periods or in low-oxygen microenvironments within dense mats, allowing enzyme function without inhibition by oxygen produced during . Such fixation enhances nutrient availability in nitrogen-limited waters, contributing to nutrient cycling and potentially fueling further by Oscillatoria and other organisms. Through , Oscillatoria releases oxygen into the water column, which sustains aerobic for heterotrophic organisms and maintains oxygenated zones in otherwise stratified or hypoxic habitats. Upon or , the of Oscillatoria releases dissolved , enriching detrital pools and supporting microbial processes that recycle nutrients back into the . This dual role in oxygenation and input underscores its influence on overall and dynamics. The proliferation of Oscillatoria into dense blooms serves as a reliable indicator of in nutrient-enriched waters, where elevated and levels promote rapid growth and mat formation. Such blooms, often observed in polluted or agriculturally influenced lakes, signal advanced trophic status and potential shifts toward hypoxic conditions upon decay.

Biotic Interactions

Oscillatoria species engage in competitive interactions with and within benthic microbial , primarily vying for light and nutrients in nutrient-limited environments. In phototrophic , non-heterocystous like Oscillatoria outcompete diatoms and chlorophytes under phosphorus-enriched conditions by enhancing ratios such as myxoxanthophyll/chlorophyll-a, which improves light harvesting efficiency and allows dominance in vertical stratification. Similarly, in sub-Arctic ponds, Phormidium chalybeum (formerly O. chalybea) contributes to high cyanobacterial biomass (up to 59% of total algal biomass) alongside diatoms and , though positive biomass correlations suggest shared resource use rather than exclusion; however, cyanobacteria's nitrogen-fixing capability provides a competitive edge in low-nutrient settings. These dynamics underscore Oscillatoria's adaptability in mat communities, where efficient nutrient uptake and light utilization limit diatom and green algal proliferation. Predation on Oscillatoria by grazers such as Daphnia species exerts selective pressure, prompting defensive responses including toxin production in certain strains. Daphnia galeata effectively grazes on Pseudanabaena limnetica (formerly O. limnetica) filaments, breaking them into smaller fragments that enhance digestibility, but this feeding can induce stress responses in the cyanobacteria. In response to grazing cues from Daphnia, Oscillatoria strains increase production of neurotoxins like anatoxin-a, which deter further herbivory by impairing zooplankton mobility and survival; for instance, exposure to Planktothrix agardhii (formerly O. agardhii) extracts containing anatoxin-a reduces Daphnia feeding rates and reproduction. This inducible defense mechanism highlights how predation drives chemical adaptations in Oscillatoria, balancing growth costs with protection against common benthic and planktonic grazers. Symbiotic associations between Oscillatoria and sponges facilitate mutualistic exchanges, particularly through provision in oligotrophic waters. The cyanobacterium Hormoscilla spongeliae (formerly O. spongeliae) forms host-specific symbioses with Dysidea sponges (e.g., Dysidea herbacea), where it fixes atmospheric intracellularly, supplying the sponge host with bioavailable while receiving and nutrients in return. These interactions enhance sponge in -poor environments, with Oscillatoria contributing up to significant portions of the host's budget via diazotrophy. Although less documented, occasional associations with lichens may involve similar nitrogen-fixing roles, though primary examples center on sponge symbioses. Oscillatoria exhibits pathogenic potential in cyanobacterial harmful algal blooms (CyanoHABs), particularly benthic proliferations that impact fish via anatoxin production. Benthic blooms of Anagnostidinema acutissimum (formerly O. acutissima) in coastal harbors, such as Alexandria's Eastern Harbour, have been linked to mass fish mortalities in Siganus rivulatus, with filament densities exceeding 10^6 g^{-1} wet weight correlating to neurotoxic effects from anatoxin-a. These anatoxins disrupt fish neuromuscular function, leading to paralysis and death, and amplify in dense mats attached to macroalgae like Ulva spp., exacerbating CyanoHAB risks in eutrophic systems. Such events underscore Oscillatoria's role in toxin-mediated biotic disruptions within aquatic food webs.

Research and Applications

Historical Research

The Oscillatoria was formally established in 1803 by French Jean-Pierre Vaucher in his seminal work Histoire des conferves d'eau douce, where he described the O. princeps as forming floating mats in freshwater and highlighted its distinctive oscillating , with filaments back and forth in a wave-like manner. This description built on earlier 18th-century microscopic observations of motile filamentous microorganisms in aquatic environments, akin to those reported by , who in the 1670s and 1680s documented the wriggling movements of "animalcules" including elongated, thread-like forms in pond water and infusions, though without naming the . Throughout the , increasingly classified Oscillatoria among due to its photosynthetic capabilities and filamentous structure, with studies emphasizing its prevalence in freshwater habitats and its as a key diagnostic trait distinguishing it from non-motile confervae. In the early 20th century, Theodor Engelmann advanced understanding of photosynthesis through his pioneering 1882 experiments, using a prism to project a spectrum of light onto filaments of a filamentous green alga such as Cladophora and observing the accumulation of aerobic bacteria drawn to oxygen-rich zones, demonstrating that the alga produced oxygen most efficiently in the red and blue wavelengths and establishing the action spectrum of photosynthesis. Engelmann's subsequent studies on phototaxis in prokaryotes, including cyanobacteria like Oscillatoria, linked motility to optimization of light exposure. These findings underscored Oscillatoria as a model organism for studying oxygenic photosynthesis in prokaryotes, with its gliding allowing filaments to reposition toward favorable light conditions. Research on the gliding mechanisms of Oscillatoria intensified from to the , relying primarily on light microscopy to analyze filament movement. In 1924, W.J. Crozier and H. Federighi quantified the dependence of gliding in Oscillatoria , reporting speeds up to several micrometers per second and a critical increment that influenced frequencies, suggesting metabolic control over . By , P.R. Burkholder reviewed in Cyanophyceae, including Oscillatoria, noting that occurred without visible appendages and was likely driven by slime extrusion or internal contractions observable under phase-contrast illumination. Mid-century studies used time-lapse light microscopy to document phototactic s in Oscillatoria filaments, where leading ends bent sharply upon changes, implying a fibrillar or contractile system beneath the for . These investigations established as a non-flagellar process integral to Oscillatoria's ecological positioning, though the exact biophysical mechanisms remained elusive until later ultrastructural analyses.

Modern Studies and Uses

Since the , genomic studies on Oscillatoria species have advanced understanding of their metabolic versatility, particularly pathways relevant to production. Draft genome sequencing of strains like Oscillatoria sp. PCC 10802 has revealed diverse gene clusters, including those for synthases and non-ribosomal synthetases that support and biosynthesis, key precursors for biofuels. In the , research on Oscillatoria acuminata highlighted its potential for production through dark , achieving yields up to 3254 mL H₂/L via nanoparticle-enhanced pretreatment and coculture with like , demonstrating efficient carbohydrate conversion to hydrogen gas. Ecological monitoring of Oscillatoria blooms has integrated and molecular tools for early detection and risk assessment. , such as Landsat-5, has identified Oscillatoria-dominated hyperscum crusts in lakes like , , where blooms exceed 50 m in diameter and form visible white patterns under hyperspectral analysis. Complementary qPCR assays targeting synthase genes (mcyA, mcyB, mcyD) have quantified gene transcription in these blooms, revealing low but detectable expression under low-light conditions (<0.93 µmol photons m⁻² s⁻¹), enabling up to 7-day early warnings for risks. Biotechnological applications of Oscillatoria leverage its bioactive compounds for industrial uses. Phycocyanin extracted from Oscillatoria minima, purified to a ratio of 8.91 (A620/A280), serves as a natural blue dye in cosmetics and food additives, offering antioxidant properties with 95% ABTS scavenging at 1 mg/mL while inhibiting bacteria like Escherichia coli at 16 µg/mL. Phenolic extracts from indigenous Oscillatoria spp. exhibit strong antimicrobial activity, with inhibition zones up to 34.06 mm against Staphylococcus sp., surpassing commercial antibiotics and targeting fish pathogens more effectively in filamentous forms. Additionally, Oscillatoria limosa has shown promise in wastewater bioremediation, removing up to 82% of organic matter from industrial effluents over 15 days through nutrient uptake and biosorption. Recent 2025 studies position Oscillatoria spp. as sustainable bio-factories for eco-friendly innovations. Indigenous strains from freshwater and ecosystems yield high (0.28 g/L) and metabolites like phycobiliproteins (121.42 mg/g), with monounsaturated fatty acids comprising up to 60.96% of total . These advancements emphasize Oscillatoria's role in applications, integrating valorization for reduced environmental impact. As of November 2025, ongoing research explores Oscillatoria's potential in for climate mitigation in aquatic ecosystems.

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