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Golden algae

Golden algae, scientifically classified as the class Chrysophyceae, are a diverse group of primarily freshwater protists renowned for their golden-brown pigmentation imparted by the carotenoid fucoxanthin alongside chlorophylls a and c.^[1] These algae encompass over 1,200 species distributed across approximately 112 genera, exhibiting a range of morphologies from unicellular flagellates to colonial forms, often featuring two unequal heterokont flagella for motility and, in many cases, intricate siliceous scales or loricae for protection.^[1] As mixotrophs, they combine autotrophy through photosynthesis with heterotrophy via phagocytosis of bacteria and other particles, enabling adaptability in nutrient-variable environments.^[2] Predominantly inhabiting oligotrophic lakes, ponds, and bogs in cold temperate regions, golden algae are key components of freshwater plankton communities, with a few species extending to marine, soil, or snow habitats.^[2] Their ecology is influenced by factors such as pH, temperature, and silica availability, making them valuable bioindicators for water quality and environmental changes; for instance, certain taxa thrive in acidic conditions while others signal acidification trends in paleoecological records via fossilized stomatocysts—siliceous resting cysts that preserve well in sediments.^[1] Reproduction is mainly asexual through longitudinal cell division, though rare sexual processes occur via zygote formation and encystment, contributing to genetic diversity and survival during unfavorable conditions.^[2] Notable genera include Ochromonas, a model for mixotrophic studies, and Dinobryon, which forms stalked colonies in loricae, highlighting the group's morphological versatility.^[1] Ecologically, golden algae contribute to primary production, nutrient cycling, and carbon flux in aquatic systems, occasionally forming blooms that impart off-tastes or odors to water supplies, though they generally pose minimal direct threats compared to some marine counterparts.^[2] Molecular phylogenetics has revealed cryptic speciation within morphotypes, underscoring ongoing taxonomic refinements and the class's evolutionary ties to other stramenopiles like diatoms and brown algae.^[1]

Description

Morphology

Golden algae, or Chrysophyceae, exhibit a range of morphological forms, predominantly unicellular or colonial, with some species forming simple multicellular structures.^[3]^[4] Most are flagellated, possessing two heterokont flagella of unequal length inserted apically: the anterior flagellum is longer, tinsel-like with tubular mastigonemes for propulsion, while the posterior one is smooth and shorter, functioning as a rudder, often accompanied by a heterokont-type photoreceptor and eyespot.^[3]^[4] Cells typically lack a rigid cell wall or possess only a thin one, frequently covered by intricate siliceous scales or bristles that are characteristic of the class and aid in species identification.^[3]^[4] Cell sizes vary from 2 to 100 μm, encompassing nannoplanktonic to larger forms, with shapes ranging from spherical and ovoid to elongated, amoeboid, or stalked configurations.^[5] In certain genera, such as Dinobryon, cells are enclosed in a lorica—a vase-shaped, mucilaginous or siliceous envelope—or surrounded by mucilage, facilitating sessile or colonial lifestyles.^[3]^[6] A defining feature includes statospores, which serve as resting cysts formed endogenously within a silica deposition vesicle during asexual or sexual reproduction.^[3]^[7] These spherical to ovoid structures, typically 3–10 μm in diameter, feature ornate siliceous walls with species-specific patterns of pores, ridges, and spines, often sealed by a polysaccharide plug, making them valuable for taxonomic and paleolimnological studies as durable microfossils.^[7]^[4]

Pigments and Reproduction

Golden algae, belonging to the class Chrysophyceae, derive their distinctive golden-brown coloration from a suite of photosynthetic pigments that optimize light absorption in aquatic environments. The primary pigments include chlorophyll a and chlorophyll c, which facilitate core photosynthetic reactions, alongside the xanthophyll carotenoid fucoxanthin, responsible for the characteristic hue by masking the green tones of chlorophyll.^[8] These organisms also contain β-carotene as an accessory carotenoid, but notably lack chlorophyll b, distinguishing them from green algae.^[9] Fucoxanthin plays a crucial role in broadening the absorption spectrum, with peaks at 510–525 nm in the blue-green to yellow-green range, enabling efficient harvesting of light in the often dim, freshwater habitats where many golden algae thrive.^[10] Complementing their photosynthetic capabilities, most golden algae exhibit mixotrophic nutrition, integrating autotrophy with heterotrophic modes such as phagotrophy—engulfing bacterial prey—or osmotrophy, absorbing dissolved organic compounds.^[11] This dual strategy enhances survival in nutrient-variable environments, where light or inorganic nutrients may be limiting, allowing species like Ochromonas to switch between phototrophy and bacterivory based on conditions.^[12] Reproduction in golden algae is predominantly asexual, occurring via binary fission in vegetative cells or through the release of motile zoospores that disperse and develop into new individuals.^[13] Sexual reproduction is infrequent and poorly documented across the group, but when observed, it typically involves zygotic meiosis with gametes that are isogamous (equal in size) or oogamous (with distinct egg and sperm forms) in certain species.^[13] The life cycle encompasses vegetative cells as the active phase, resting cysts (often siliceous stomatocysts) for dormancy during adverse conditions, and palmelloid stages where non-motile cells aggregate in a gelatinous matrix for protection and propagation.^[14]

Cysts and Identification

Golden algae within the Chrysophyceae produce distinctive endogenous siliceous cysts known as statospores or stomatocysts, which serve as resting stages in their life cycles. These cysts are typically globose, hollow structures with diameters ranging from 2 to 30 μm, though most fall between 5 and 10 μm, and feature a single germination pore often surrounded by a collar. The cyst wall forms within a silica deposition vesicle and consists of an inner unornamented layer overlaid by an outer layer exhibiting species-specific ornamentation, such as spines, ridges, reticulum, scabrae, or patterns like reticulate and scrobiculate designs that aid in taxonomic differentiation.^[15]^[16]^[17] Cyst formation occurs endogenously under adverse environmental conditions, including nutrient limitation, temperature fluctuations, pH changes, or increased population density, acting as a survival mechanism to form a dormant seed bank resistant to dissolution. Excystment is facilitated through the germination pore, allowing the release of viable cells even after prolonged dormancy; for instance, cysts from lake sediments have germinated after at least 60 years. These cysts are taxonomically valuable, with morphology often considered species-specific, though linkages to vegetative stages remain limited for many taxa, leading to an artificial naming system developed by the International Statospore Working Group.^[18]^[15]^[17] Identification of golden algae relies heavily on cyst morphology, particularly through scanning electron microscopy (SEM) to examine fine-scale ornamentation and pore-collar structures, complementing observations of associated silica scales. For example, genera like Mallomonas are distinguished by unique cyst-silica patterns, such as specific spine arrangements or equatorial divisions. Over 200 cyst morphotypes have been described globally, with regional studies documenting up to 253 in Finnish freshwater sediments alone, though many remain unnamed or unlinked to living species, which complicates biodiversity assessments.^[18]^[15]^[17] In paleolimnology, these durable siliceous cysts preserve well in sediments and function as proxies for reconstructing past environmental conditions, such as pH, temperature, salinity, and nutrient levels, with fossil records extending back to the Late Triassic. Their abundance and resistance make them particularly useful for inferring historical aquatic dynamics in oligotrophic or acidic habitats like peatlands and lakes.^[18]^[15]

Classification

Historical Systems

The classification of golden algae, historically encompassed within the class Chrysophyceae, began with Alfred Pascher's foundational work in 1914, where he established the class based on shared morphological features such as heterokont flagellation and the production of siliceous cysts or scales, drawing parallels to series observed in green algae; he divided it into three subclasses—Chrysomonadineae (two flagella, often scaled), Ochromonadineae (one or two flagella, palmelloid stages), and Aphanomonadineae (amoeboid or plasmodial forms)—primarily using light microscopy to assess flagellar arrangement and cyst formation.^[19]^[20] Gilbert M. Smith's 1938 system refined Pascher's framework by emphasizing vegetative forms and motility, dividing the Chrysophyceae into two main orders: Chrysomonadales for primarily flagellate species with silica scales or cysts, and Heterochloridales for those exhibiting amoeboid stages alongside flagellated ones, such as the colorless heterotrophic forms; this approach highlighted the transitional nature between flagellate and amoeboid lifestyles but retained a broad, morphology-driven grouping.^[21] Pierre Bourrelly's 1957 revision further organized the class into orders like Ochromonadales, which included non-walled, biflagellate species capable of forming colonies, alongside other orders for coccoid and heterotrophic forms, incorporating observations of colonial aggregations and cyst development to better accommodate diverse life cycles observed under light microscopy.^[22] By the 1980s, Kazimierz Starmach's 1985 classification introduced more nuanced subclasses within Chrysophyceae, distinguishing Heterochrysophycidae for flagellate-dominated groups with scales or loricae, and Acontochrysophycidae for non-scaled, often amoeboid or palmelloid taxa lacking prominent flagella, based on detailed light microscopic examinations of cell coverings and motility; this system aimed to reduce overlap in prior schemes by prioritizing absence or presence of scales. Subsequent works, such as Jørgen Kristiansen's 1986 review, advanced this by elevating silica-scaled families like Mallomonadaceae to ordinal status as Mallomonadales within Chrysophyceae, separating them from non-scaled ochromonad forms to reflect specialized scale ultrastructure visible under electron microscopy, though still reliant on traditional morphological criteria.^[1] Similarly, C. van den Hoek and colleagues in 1995 proposed distinguishing silica-scaled groups like Synurales as a separate order or even class precursor, underscoring shifts toward recognizing scale-based autapomorphies in late 20th-century morphology-based systems.^[23] These historical classifications, grounded in light and early electron microscopy, often resulted in polyphyletic groupings by conflating convergent traits like flagellation and cyst formation across unrelated heterokont lineages.^[24] This morphology-centric approach laid the groundwork for later transitions to molecular phylogenetics in the 1990s.^[20]

Modern Taxonomy

The modern taxonomy positions golden algae within the class Chrysophyceae, part of the phylum Ochrophyta (synonymous with Heterokontophyta) in the kingdom Chromista. This placement reflects their affiliation with stramenopiles, characterized by heterokont flagellation and chlorophyll c-containing plastids.^[25] The class comprises approximately 1,200 species across about 112 genera, predominantly freshwater forms with a few marine and soil representatives. Post-2000 taxonomic revisions, driven by molecular phylogenetics, have refined the hierarchy by excluding unrelated groups such as pedinellids, now classified in the order Pedinellales within the class Dictyochophyceae in Ochrophyta. Nine orders are currently recognized: Ochromonadales (core heterotrophic and mixotrophic flagellates), Chromulinales (organic-scaled monads), Synurales (colonial scaled forms), Phaeothamiales (filamentous heterotrophs), Apoikiales, Hibberdiales, Hydrurales, Paraphysomonadales (siliceous-scaled choanoflagellate-like forms), and Sarcinochrysidales. Family-level organization includes prominent groups like Dinobryaceae (encompassing genera such as Dinobryon) and Synuraceae (including Synura species). In 2023, the class Synurophyceae was formally synonymized with Chrysophyceae, consolidating scaled colonial taxa under a unified framework.^[26]^[27]^[28] Recent updates documented in AlgaeBase since 2019 emphasize integrative approaches, incorporating ultrastructural and genetic data for genus-level delimitations. A key 2022 revision introduced the family Chrysosphaerellaceae (order Chromulinales), based on the Arctic species Chrysosphaerella septentrionalis, highlighting adaptations in polar environments and resolving ambiguities in scaled chrysomonad taxonomy. These changes underscore the class's paraphyletic nature in earlier schemes, now more robustly delineated through multi-gene analyses.

Phylogenetic Advances

Recent advances in molecular phylogenetics have significantly refined the understanding of relationships within the Chrysophyceae, commonly known as golden algae, through the application of genetic markers such as the small subunit ribosomal RNA (SSU rRNA) and ribulose-1,5-bisphosphate carboxylase/oxygenase large subunit (rbcL) genes. These markers have revealed high cryptic diversity and paraphyly in several orders, including Ochromonadales, by demonstrating that morphologically similar taxa often represent distinct evolutionary lineages. For instance, multigene analyses combining nuclear SSU rRNA and plastid rbcL sequences have shown that traditional order boundaries do not always reflect monophyletic groups, necessitating taxonomic revisions based on genetic evidence.^[29]^[30] Phylogenetic studies place Chrysophyceae within the larger Ochrophyta clade, where they share a close relationship with diatoms (Bacillariophyceae) and brown algae (Phaeophyceae), forming part of the basal heterokonts. This positioning is supported by analyses of multiple plastid and nuclear genes, highlighting shared evolutionary traits such as secondary endosymbiosis-derived plastids. High-throughput sequencing efforts in 2022 further illuminated the extensive diversity within Ochromonadales, identifying numerous novel lineages in freshwater environments and underscoring the group's ecological adaptability. More recently, a 2025 phylogenetic study on Chrysococcus utilized concatenated SSU rRNA and rbcL datasets to establish its loricate position within Chrysophyceae, revealing evolutionary transitions toward colonial forms and implying broader implications for lorica development across the class.^[31]^[26]^[32] Genomic investigations have provided deeper insights into the molecular basis of Chrysophyceae traits, particularly mixotrophy. A 2019 draft genome assembly of the golden alga Hydrurus foetidus, combined with transcriptome data, identified genes associated with phagotrophy and photosynthesis, supporting the prevalence of mixotrophic lifestyles in the group. Comparative pan-genomics of chrysophyte strains, including Ochromonas species, has further shown nutrient-driven expansions in genes for carbon acquisition, reinforcing the adaptive flexibility observed in phylogenetic trees. Additionally, 2024 DNA barcoding using SSU rRNA, large subunit rRNA (LSU rRNA), and rbcL sequences documented new sites of Hydrurus foetidus in Shanxi Province, China, refining biogeographic models for benthic chrysophytes in Asian freshwater systems.^[33]^[34]^[30]

Diversity

Major Orders

The major orders within the Chrysophyceae are distinguished primarily by differences in siliceous scale morphology, cell organization, and motility, reflecting adaptations to varied trophic modes and habitats; the class encompasses approximately 1,274 described species (including 58 fossil forms) across 180 genera.^[35] The class now comprises nine orders, with ongoing discoveries adding to its diversity.^[36] Ochromonadales represent a diverse group of mostly unicellular flagellates, often exhibiting phagotrophic nutrition through pseudopodia or direct engulfment, distributed across multiple genera featuring heterokont flagella and occasional loricae or colonies.^[37]^[38] Synurales comprise colonial forms characterized by intricate siliceous scales covering cells, enabling coordinated swimming in spherical or linear colonies, known for their role in freshwater blooms due to these protective and structural scales.^[37]^[38] Chromulinales include amoeboid or palmelloid organisms, frequently bearing scales or spines, that alternate between flagellate and non-motile stages, emphasizing their transitional morphologies within the class.^[37]^[38] Other notable orders include Apoikiales, a rare group of parasitic heterotrophs.^[36]

Key Genera and Species

Golden algae (class Chrysophyceae) encompass approximately 180 genera and 1,274 species, predominantly freshwater organisms, with genera such as Synura (about 57 species) and Mallomonas (over 220 species) representing a substantial portion of the described diversity, together accounting for roughly 20% of all species.^[35]^[39]^[40] These taxa illustrate the class's morphological and ecological variety, spanning free-living monads to colonial forms across orders like Ochromonadales and Synurales. The genus Dinobryon, belonging to the order Ochromonadales, consists of colonial loricate flagellates that form branching chains within vase-shaped loricae, often dominating plankton in oligotrophic waters. A representative species, Dinobryon divergens, is commonly found in temperate lakes, where it exhibits mixotrophic nutrition by combining photosynthesis and bacterivory.^[29]^[41] Mallomonas, in the order Synurales, includes scaled monads characterized by siliceous scales and bristles that aid in locomotion and protection; these unicellular or loosely colonial forms are widespread in freshwater habitats. For example, Mallomonas caudata features polymorphic scales varying in shape and ornamentation, enabling adaptation to diverse environmental conditions in lakes and ponds globally.^[5]^[42] The genus Synura, also within Synurales, forms spherical colonies of scaled cells connected by cytoplasmic bridges, creating hollow, rotating balls that propel through water. Synura uvella, a common species in temperate and boreal lakes, is notorious for forming blooms that release volatile organic compounds, imparting a fishy odor to affected waters.^[43]^[44] Ochromonas species, assigned to Ochromonadales, are typically free-swimming, biflagellate monads that lack scales or loricae, relying on their golden-brown chloroplasts for phototrophy while often engaging in mixotrophic feeding on bacteria and algae. The species Ochromonas danica exemplifies this lifestyle, thriving in freshwater and marine environments as a versatile predator and primary producer.^[45]^[46] A notable recent addition to the Chrysophyceae is Chrysosphaerella septentrionalis, described in 2022 from a peat bog in the Arctic's Pasvik Nature Reserve, Russia; this colonial species, endemic to high-latitude wetlands, forms small spheres of loricate cells and represents a new family, Chrysosphaerellaceae, highlighting ongoing discoveries in extreme environments.^[47]

Morphological Variation

Golden algae exhibit a wide range of morphological forms, transitioning between flagellate and amoeboid states in certain lineages. Many species are primarily biflagellate, with one long heterokont flagellum for propulsion and a shorter smooth flagellum, enabling motile, planktonic lifestyles. In contrast, amoeboid forms, such as those in the genus Chrysamoeba, feature cells with radiating pseudopodia up to 20 μm long, facilitating substrate attachment and phagotrophy, while retaining the capacity for flagellate stages during dispersal or reproduction. These transitions highlight adaptive plasticity in locomotion and feeding strategies within the group.^[48]^[49] A prominent variation involves the presence or absence of scales, with approximately 250 species bearing intricate siliceous scales that cover the cell surface, comprising about 20% of the ~1,300 described Chrysophyceae.^[35] These scales, formed via silicification in the Golgi apparatus, range from simple plate-like structures to elaborate forms with ribs, pores, spines, or keels, providing protection, buoyancy, or species-specific identification markers visible only under electron microscopy. Unscaled species, predominant in heterotrophic lineages, lack these ornaments and often display smoother, naked protoplasts adapted for rapid movement or osmotrophy. Scale morphology can vary intraspecifically, influenced by environmental factors.^[1]^[49] Colonial adaptations further diversify golden algae morphology, with cells aggregating into structured assemblages for enhanced survival. Stalked colonies, as seen in genera like Poterioochromonas, feature cells attached via mucilaginous stalks to substrates, forming linear or branched arrays that anchor in benthic environments. Free-floating spherical colonies, typical of Synura species, consist of hundreds to thousands of cells embedded in gelatinous matrices, rotating via coordinated flagellar beats to optimize light exposure or nutrient uptake. These colonial forms contrast with solitary cells, emphasizing collective behaviors in resource-limited habitats.^[49]^[1] Morphological complexity spans a broad size spectrum, from naked, unicellular flagellates measuring 2–10 μm in diameter to elaborate colonies reaching 1 mm or more in diameter. For instance, individual Chrysamoeba cells are typically 8–10 μm, while Synura colonies can aggregate up to 1 mm, comprising micron-scale cells in dense, spherical clusters. This variation in scale and organization reflects evolutionary trade-offs between mobility, protection, and metabolic efficiency. A study on Synura petersenii demonstrated that under silica-limited nutrient stress, scales downsized and became malformed, reducing overall cell ornamentation and highlighting environmental modulation of morphological traits.^[50]^[48]^[51]

Ecology

Habitats and Distribution

Golden algae, belonging to the class Chrysophyceae, are predominantly inhabitants of freshwater environments, comprising nearly all known species in this category, with only a small fraction occurring in marine or brackish settings.^[19] They thrive in oligotrophic waters such as clear lakes, slow-flowing rivers, and peat bogs, where nutrient levels, particularly total phosphorus, remain low (typically below 15 μg L⁻¹).^[19] These algae exhibit a preference for soft, dilute waters with low conductivity (less than 50 μS cm⁻¹) and pH ranges from 5 to 8, often in acidic to circumneutral conditions influenced by humic substances in brown waters.^[19]^[2] Temperature tolerances generally fall between 4°C and 20°C, favoring cold to cool conditions that support their mixotrophic lifestyles.^[26] Their distribution is cosmopolitan, recorded on every continent except Antarctica, though abundance peaks in cold-temperate regions of the Holarctic realm, including boreal forests and subarctic areas.^[19] High diversity is noted in Nordic countries, the Alps, and mountain lakes, where species richness correlates with oligotrophic, low-pH habitats.^[26] Benthic forms, such as Hydrurus foetidus, are characteristic of fast-flowing, cold rivers during snowmelt periods, while planktonic genera like Dinobryon and Ochromonas dominate in temperate lakes.^[52] Rare brackish occurrences include species like Dinobryon balticum in the Baltic Sea.^[2] Biogeographically, golden algae show elevated endemism in ancient lakes, such as Lake Baikal, where over 25 silica-scaled species have been documented, including endemics like Mallomonas kuzminii. Recent studies as of 2025 have expanded the checklist of silica-scaled species in Lake Baikal to 57 taxa.^[53]^[54] Recent expansions in known ranges include the 2024 discovery of Hydrurus foetidus in the Fenhe River of Shanxi Province, China, highlighting their presence in East Asian freshwater systems previously underreported.^[30] Overall, approximately 90% of Chrysophyceae species are confined to freshwater habitats, underscoring their role as indicators of pristine, nutrient-poor aquatic ecosystems.^[19]

Ecological Roles

Golden algae, particularly those in the class Chrysophyceae, serve as primary producers and mixotrophs in aquatic ecosystems, often contributing 10–75% of phytoplankton biomass in oligotrophic and dystrophic waters, where their photosynthetic activity supports overall primary production.^[55] Mixotrophic species, such as Chrysosphaerella multispina, can dominate biomass exceeding 50% in nutrient-poor conditions by combining autotrophy with heterotrophy, enhancing their resilience and role in carbon flow.^[55] A 2022 review highlights Chrysophyceae as key contributors to carbon fixation in humic lakes, where their mixotrophic strategies facilitate efficient nutrient utilization and primary productivity in low-light, organic-rich environments.^[55] In food webs, golden algae occupy a versatile position as both prey and predators; they are grazed by zooplankton such as Daphnia, which can assimilate up to 27% of their resources from species like Mallomonas caudata, thereby transferring energy to higher trophic levels.^[55] Conversely, mixotrophic forms like Dinobryon spp. act as significant predators on bacteria, with grazing rates that can exceed those of other protists and link bacterial production to the broader planktonic food web, accounting for substantial bacterivory in freshwater systems.^[56] Heterotrophic chrysophytes, such as Paraphysomonas, further bridge primary producers and metazoans by consuming organic particles and bacteria.^[55] Golden algae contribute to nutrient dynamics through silicon cycling, as silica-scaled species produce biogenic silica structures like scales and stomatocysts, which deposit in lake sediments and influence local silica availability, though their global impact is minor compared to diatoms.^[55] These scales facilitate silica precipitation, altering sediment composition and supporting biogeochemical processes in freshwater habitats.^[55] Additionally, their mixotrophic feeding enhances cycling of carbon, nitrogen, and phosphorus, with 40–60% of carbon flux passing through bacterial interactions mediated by chrysophytes.^[55] Symbioses involving golden algae are rare but documented. Some species also function as epiphytes, attaching to aquatic plants or substrates; for instance, Lagynion spp. occur epiphytically in oligotrophic lakes, contributing to periphyton communities and localized primary production.^[57] Similarly, Chrysidiastrum epiphyticum exemplifies epiphytic growth on pond substrates, aiding in microhabitat nutrient exchange.^[58]

Environmental Interactions

Golden algae, particularly species within the Chrysophyceae, serve as sensitive bioindicators of environmental changes due to their specific tolerances to water chemistry variables. Chrysophyte cysts in lake sediments have been used to reconstruct historical acidification, with studies showing pH declines in approximately 24% of monitored lakes attributed to acidic deposition, alongside shifts in trophic status from cottage development and eutrophication pressures.^[59] Silica-scaled chrysophytes exhibit defined responses to eutrophic and acidic conditions, with certain taxa declining in polluted waters where pH drops below 5.5 or nutrient levels exceed oligotrophic thresholds, enabling their use in assessing water quality degradation.^[60] While blooms of true Chrysophyceae are rare and generally non-toxic, related golden algae such as Prymnesium parvum (Haptophyta) can form dense, ichthyotoxic blooms in brackish or low-salinity environments, leading to significant fish kills through prymnesin toxins that disrupt gill function and osmoregulation.^[61] These events, often triggered by moderate environmental stress like salinity fluctuations between 1-10 ppt, have been documented in inland waters, highlighting broader vulnerabilities among golden-pigmented algae to anthropogenic alterations.^[62] Climate warming influences golden algae distributions and cyst production, with rising air temperatures altering lake mixing regimes and cyst fluxes in sediments, as observed in northeast Polish lakes where warmer, ice-free winters reduced cyst peaks by limiting nutrient and light availability.^[63] Assemblage shifts toward warmth-tolerant morphotypes have been recorded in Arctic sediments since the early 20th century, with increased cyst concentrations serving as proxies for extended growing seasons and trophic cascades driven by reduced ice cover.^[64] Pollution impacts golden algae through heavy metal exposure, where scaled species like Synura echinulata exhibit tolerance and dominance in contaminated sediments, with assemblages reflecting elevated aluminum, iron, and nickel levels up to 5,000 μg/L during industrial emissions.^[65] Since the 1980s, cyst assemblages of golden algae have been integral to paleoenvironmental reconstructions, providing quantitative insights into past lake pH, productivity, and climate variability through multivariate analyses of sediment cores from diverse regions.^[66]

Evolution

Ancestral Origins

Golden algae, or Chrysophyceae, belong to the heterokont lineage within stramenopiles, where the acquisition of photosynthesis occurred through secondary endosymbiosis involving a red alga. This event is estimated to have taken place between approximately 1300 and 600 million years ago, marking a pivotal step in the evolution of complex plastids in this group. The secondary plastid, surrounded by four membranes, integrated red algal photosynthetic machinery into a previously non-photosynthetic host, enabling the diversification of ochrophytes, the photosynthetic stramenopiles that include golden algae.^[67] The ancestral state of stramenopiles was heterotrophic, with early lineages likely consisting of bacterivorous flagellates that preyed on prokaryotes in aquatic environments. Photosynthesis was acquired later in the ochrophyte branch, following the divergence from aplastidic relatives such as oomycetes and labyrinthulomycetes, indicating that phagotrophy preceded plastid integration by at least tens of millions of years. This heterotrophic ancestry underscores the opportunistic nature of stramenopile evolution, where nutrient acquisition via bacterivory provided a foundational trophic strategy before the endosymbiotic upgrade to autotrophy.^[68]^[69] A defining feature of ochrophyte pigment evolution is the presence of fucoxanthin, a xanthophyll carotenoid that enhances light harvesting in the 500-550 nm range and photoprotection. This pigment originated in the common ancestor of photosynthetic stramenopiles, distinguishing ochrophytes from other chromalveolate groups and contributing to their golden-brown coloration. Fucoxanthin's biosynthesis pathway, involving enzymes like phytoene synthase and lycopene cyclase, was retained across diverse ochrophyte lineages, reflecting its adaptive value in variable aquatic light conditions.^[70] Within ochrophytes, a key evolutionary event was the divergence of major lineages, including the separation of the chrysophyte line from that leading to diatoms, estimated around 250-370 million years ago based on molecular clock analyses. This split occurred hundreds of millions of years after plastid acquisition, allowing independent diversification of siliceous (diatoms) and non-siliceous (chrysophytes) forms. Mixotrophy, combining photosynthesis and phagotrophy, represents a primitive trait in Chrysophyceae, retained in most species as an ancestral condition from which full heterotrophy evolved multiple times through gradual plastid reduction and gene loss.^[71]^[72]

Fossil Record

The fossil record of golden algae (Chrysophyceae) is primarily preserved through siliceous structures such as scales, bristles, and resting cysts (stomatocysts or statospores), which resist degradation in sedimentary environments far better than the fragile organic components of their cells. These silica-based features, often found in lacustrine deposits, provide a robust proxy for reconstructing past algal diversity and ecology, as the soft-bodied vegetative stages rarely fossilize.^[73] The earliest unambiguous fossils attributed to Chrysophyceae are statospores from Late Triassic lacustrine sediments in the Ordos Basin, China, dating to approximately 228–235 million years ago (Ma). These spherical, siliceous cysts exhibit morphological features consistent with modern chrysophyte resting stages, marking the group's initial appearance in the Mesozoic following the Permian-Triassic extinction. Earlier potential records, such as ambiguous microfossils from the Ordovician (~450 Ma), have been proposed but remain unconfirmed due to challenges in taxonomic assignment. Diversity peaked during the Mesozoic, particularly in the Late Cretaceous, with abundant and varied silica scales documented in ancient lake deposits like the Wombat locality in Canada (~83 Ma), where over 100 morphotypes of scales and bristles indicate a thriving scaled-chrysophyte assemblage. Molecular clock analyses estimate the origin of the order Synurales at approximately 157 Ma in the Jurassic, though the fossil record of scales and bristles begins in the Eocene (~48 Ma), with definitive fossils more common from the Cretaceous onward, including structures akin to modern genera like Mallomonas and Synura.^[73]^[20] In the Quaternary, chrysophyte cysts are extensively used in sediment stratigraphy to infer environmental changes, including climate shifts, due to their sensitivity to temperature, pH, and nutrient levels. Assemblages from Holocene lake cores, for instance, reveal submillennial-scale variations in winter-spring conditions in regions like the northwestern Mediterranean, with cyst morphotypes tracking transitions from cooler, oligotrophic phases to warmer periods. A 2023 analysis of scale-bearing lineages documented 29 distinct evolutionary lines in the fossil record, demonstrating remarkable morphological stability since the Cretaceous (~83 Ma), with many taxa showing little change over tens of millions of years despite environmental upheavals.^[73]

Recent Molecular Studies

Recent molecular studies on golden algae (Chrysophyceae) have advanced understanding of their evolutionary dynamics through genomic and phylogenomic approaches. A notable genome project is the 2019 draft assembly of Hydrurus foetidus, a benthic chrysophyte, which produced a 171 Mb genome from hybrid short- and long-read sequencing, achieving 77% completeness based on BUSCO analysis.^[33] This assembly provides a foundation for exploring mixotrophic pathways, as H. foetidus exhibits combined phototrophy, phagotrophy, and osmotrophy, with transcriptomic data revealing gene expression patterns linked to nutrient acquisition and environmental adaptation.^[33] Complementary transcriptomic studies on related mixotrophic species like Ochromonas spp. have identified upregulated genes for phagocytosis and carbon metabolism under varying light and prey conditions, highlighting evolutionary adaptations in nutritional flexibility.^[74] Phylogeographic analyses using high-throughput metabarcoding have uncovered substantial cryptic diversity within inland water populations of Chrysophyceae. A 2022 study analyzing 2,370 environmental sequences from 218 European lakes revealed a large, previously overlooked diversity in unscaled chrysophytes, with phylogenetic affiliations indicating widespread cryptic speciation driven by habitat-specific adaptations.^[26] This metabarcoding effort estimated that undescribed diversity could be at least twice the known taxa, emphasizing the role of molecular tools in resolving hidden evolutionary lineages.^[26] Similarly, multigene phylogenies in genera like Dinobryon have confirmed cryptic species complexes, with integrative morphological and molecular data describing five new species and suggesting biogeographic patterns tied to freshwater dispersal.^[29] Evolutionary implications from recent phylogenomics include insights into morphological innovations, such as scale formation. A 2025 phylogenetic analysis of Chrysococcus, incorporating its type species C. rufescens, resolved key transitions within Chrysophyceae, implying that silica scale evolution may involve gene duplication events in structural protein families, though direct genomic evidence remains pending.^[75] Evidence for horizontal gene transfer (HGT) further shapes these trajectories, with bacterial-derived ice-binding protein genes integrated into chrysophyte genomes, enhancing cold adaptation in snow algae like Chloromonas nivalis relatives.^[76] Such HGT events, likely from bacterial prey, also support osmotrophic capabilities by bolstering extracellular degradation pathways, as inferred from comparative genomics across protistan osmotrophs.^[77] These findings collectively refine post-2020 views on chrysophyte evolution, integrating genomic plasticity with ecological niches.

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The lorica of Dinobryon - ScienceDirect.com
The structure and composition of the lorica of the colony-forming chrysoflagellate alga Dinobryon divergens IMHOF was investigated with light and electron ...
[7]
Chrysophycean microfossils in paleolimnological studies
A characteristic feature of this class is the endogenous formation of a siliceous resting stage, known as a statospore. Vegetative cells in the family ...
[8]
Algae Classification - Smithsonian National Museum of Natural History
Chrysophytes contain chlorophylls a and c, which are masked by the accessory pigment fucoxanthin, a carotenoid. In many ways, golden algae are, biochemically ...
[9]
Chrysophyta - an overview | ScienceDirect Topics
Under the broad designation 'chrysophytes' there are two main classes – the Chrysophyceae and the Synurophyceae. ... Reproduction takes place by longitudinal cell ...The Planktonic Marine... · Chromophyta · Chrysophyceae
[10]
Fucoxanthin - an overview | ScienceDirect Topics
... spectrum, peaking at 510–525 nm, giving them a brown or brownish-green color. Fucoxanthin is synthesized in the low light/dark phase of the xanthophyll ...
[11]
A tale of two mixotrophic chrysophytes: Insights into the metabolisms ...
Feb 13, 2018 · Ochromonas is a genus of mixotrophic chrysophytes consisting of > 100 described species that exhibit a variety of nutritional strategies [6].
[12]
Autotrophic and heterotrophic acquisition of carbon and nitrogen by ...
May 19, 2017 · More than 100 mixotrophic species of Chrysophyceae have been described, and sequence-based surveys of natural samples point to potentially ...Materials And Methods · Ochromonas Cultures And... · Growth Of Ochromonas Sp...
[13]
Chrysophyceae - microbewiki - Kenyon College
Aug 7, 2010 · Chrysophyceae · Contents · Classification · Description and Significance · Genome Structure · Cell Structure and Metabolism · Ecology · References.Missing: statospores | Show results with:statospores
[14]
Chrysophyte reproduction and resting cysts: A paleolimnologist's ...
This paper provides a review of the role that stomatocysts play in the life cycle and reproductive ecology of freshwater planktonic chrysophytes.
[15]
Remarkably preserved cysts of the extinct synurophyte, Mallomonas ...
Mar 23, 2020 · Chrysophyte algae produce a siliceous stage in their life cycle, through either asexual or sexual reproduction, known as a cyst.
[16]
Chrysophyte cysts - Nannotax3 - Mikrotax
The surface of mature cysts may be ornamented with different structural elements and are useful to distinguish species. [Wikipedia - Golden Algae page] The ...
[17]
Chrysophyte stomatocysts and their associations with environmental ...
Chrysophyte stomatocysts, siliceous resting stages of golden-brown algae, are widely distributed in acidic and oligotrophic environments of peatlands.
[18]
Biogeography and ecology of freshwater chrysophyte cysts in Finland
Nov 2, 2019 · All chrysophytes produce siliceous resting stages, often previously referred to as statospores, but now more properly called stomatocysts or ...
[19]
Chrysophyta - an overview | ScienceDirect Topics
CHRYSOPHYCEAN ALGAE Pascher (1914) erected the class Chrysophyceae, based primarily on a morphological series paralleling those observed within the green algae ...
[20]
Assessing the evolutionary history of the class Synurophyceae ...
Jun 1, 2015 · Heterokont algae with siliceous scales covering the cell were historically classified within the class Chrysophyceae (Pascher, 1914; Bourrelly, ...
[21]
Smith system - Wikipedia
Division Chrysophyta · Order 1. Heterochloridales · Order 2. Rhizochloridales · Order 3. Heterocapsales · Order 4. Heterotrichales · Order 5. Heterococcales · Order 6 ...
[22]
Present-Day Classification of Algae - jstor
Smith, 1933, 1938 Fritsch, 1935 Pascher, 19314. Volvocales Volvocales ... Chrysophyceae. B. Diatomeae (Bacillariales of other authors). C. Heterokontae ...
[23]
Ochromonadales - Wikipedia
In a 1957 classification of golden algae, French phycologist Pierre Bourrelly included in the order Ochromonadales all species that lack a cell wall and ...
[24]
Some remarks concerning the class Chrysophyceae
Bourrelly's (1957) theory that in the Ochromonadales there is a gradual reduction in the size of the acronematic flagellum, until in Mallo,nonas it persists ...
[25]
Chrysophyceae - Wikispecies - Wikimedia
Sep 13, 2024 · Class Phéophycées; Class Xanthophycées; Class Diatomophycées (= Bacillariophycées). Starmach (1985). edit. Starmach, K. (1985). Chrysophyceae ...
[26]
(PDF) Chrysophyta - ResearchGate
The chrysophytes (more than 1,200 described species) are unicellular or colonial algae characterized by heterokont flagella and chloroplasts with ...
[27]
Chrysophyceae - Taxonomy browser Taxonomy Browser () - NIH
Lineage (full): cellular organisms; Eukaryota; Sar; Stramenopiles; Ochrophyta · Chrysophyceae (golden algae). Apoikiaceae · Chromulinales.
[28]
Phylogenetic and functional diversity of Chrysophyceae in inland ...
Apr 25, 2022 · In our study, we analyzed the distribution patterns of the different Chrysophyceae lineages on a European scale. Based on an extensive ...
[29]
Molecular Phylogeny and Taxonomy of the Genus Spumella ...
Oct 25, 2021 · ... cell size and simple morphology. Instead, the morphology of the ... Chrysophyceae to identify the molecular signatures unique to the ...
[30]
[PDF] Unravelling the hidden complexity in diversity and pigment ... - Fottea
Synura sphagnicola (Korshikov) Korshikov (Chrysophyceae, Synurales) is a colonial, cosmopolitan, silica–scaled flagellate originally described from peat bogs ...
[31]
Multigene phylogeny reveals a cryptic diversity in the genus ...
Apr 17, 2023 · Dinobryon is a mixotrophic lineage within Chrysophyceae and its species are widely distributed in marine and freshwater environments, ranging ...Introduction · Materials and methods · Results · Discussion
[32]
New molecular evidence of the genus Hydrurus (Chrysophyceae ...
Nov 1, 2024 · ... μm × 4.28–9.28 μm in size ( Fig. 3 j and k). The branch cells were 5.88–19.99 μm × 4.41–9.34 μm ( Fig. 3 f–i). The branch cells were further ...<|control11|><|separator|>
[33]
Updating algal evolutionary relationships through plastid genome ...
May 28, 2015 · Diatoms (Bacillariophyceae) and multicellular brown algae (Phaeophyceae) are the best characterized ochrophytes, but at least 15 separate ...
[34]
Revisiting Chrysococcus (Chrysophyceae): new phylogenetic ...
Sep 9, 2025 · So far, insufficient molecular characterization appears to be the most significant brake on the modern taxonomic revision of this ecologically ...
[35]
Draft genome assembly and transcriptome sequencing of the golden ...
Apr 8, 2019 · It has several morphological traits reminiscent of single-celled eukaryotes, but can also form macroscopic thalli. Despite its ability to ...
[36]
Nutrient-driven genome evolution revealed by comparative ... - Nature
Mar 12, 2021 · Recent hypotheses suggest that the shift from photo- to mixotrophy was one way to overcome nutrient limitations while the shift towards ...<|control11|><|separator|>
[37]
(PDF) Chrysophyta - ResearchGate
Currently, the golden-brown algae are classified within a single class, Chrysophyceae, and nine orders, namely Ochromonadales, Chromulinales, Apoikiales, ...
[38]
https://doi.org/10.1007/978-3-319-32669-6_43-1
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Golden algae Definition and Examples - Biology Online Dictionary
Feb 27, 2021 · The golden algae are algal species that are found mostly in freshwater. They are also called the chrysophytes. They belong to the phylum Chrysophyta.
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World Register of Marine Species - Phaeothamniales - WoRMS
Phaeothamniales ; Rank. Order ; Parent. Phaeothamniophyceae ; Environment. marine, brackish, fresh, terrestrial ; Original description. Not documented ; Taxonomic ...Missing: Phaeothamiales | Show results with:Phaeothamiales
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[PDF] Journal-of-Phycology-2024-Guiry.pdf - AlgaeBase
The structure and reproduction of the algae. Volume I. Introduction, Chlorophyceae. Xanthophyceae,. Chrysophyceae,. Bacillariophyceae,. Cryptophyceae,.<|control11|><|separator|>
[42]
Morphological and Molecular Characterizations of Three Species of ...
Dec 9, 2022 · There are currently 57 species accepted in the AlgaeBase taxonomy, and molecular evidence is accessible for 34 species [3,4]. The cells of ...
[43]
Diversity of Silica-Scaled Chrysophytes in the Steppe Zone of the ...
Nov 16, 2023 · Cell dimensions unknown. The body scales are oval, often slightly asymmetrical, 4.6–6.2 × 2.5–3.3 μm, tripartite, with a dome, a V-rib, ...
[44]
https://atrium.lib.uoguelph.ca/bitstream/10214/15533/1/OME_chrysophyte_blooms_plankton92.pdf
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https://journals.plos.org/plosone/article?id=10.1371/journal.pone.0192439
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[PDF] Records of the chrysophyte alga Synura uvella Ehrenberg 1834 ...
Many chrysophytes can be a nuisance when in bloom and impart a fishy odour and unpleasant taste to water. I report here that S. uvella has been recently ...Missing: odors | Show results with:odors
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[PDF] Chrysophyte Blooms in the Plankton and Neuston of Marine and ...
Odours from blooms of Dinobryon, Synura, and Uroglena have most often been described as fishy, but other descriptors include "cod liver oil" and "muskmelon" or.
[48]
A tale of two mixotrophic chrysophytes: Insights into the metabolisms ...
Ochromonas is a genus of mixotrophic chrysophytes consisting of > 100 described species that exhibit a variety of nutritional strategies [6]. Many Ochromonas ...
[49]
Ochromonas danica E.G.Pringsheim - AlgaeBase
The type species (lectotype) of the genus Ochromonas is Ochromonas triangulata Vysotskii. This name is currently regarded as a synonym of Chlorochromonas ...
[50]
Chrysosphaerella septentrionalis sp. nov. (Chrysophyceae ... - MDPI
Plate-like scales oval to subcircular, 2.4–3.0 × 1.8–3.0 µm, consist of a raised and smooth central area (cupola), a plain smooth marginal rim and radial ribs ...
[51]
Chrysamoeba Morphology
Chrysamoeba ... Flagellated form measures 8 by 3.5 um; amoeboid form stage about 8-10 by 3-4 um, with 10-20 um long radiating pseudopodia; cyst 7 um in diameter.
[52]
(PDF) Chrysophycean Algae - ResearchGate
common species based on cell size and shape, flagella length, and stomatocyst morphology. Chrysamoeba Klebs (Figs. 6S and 13A). Cells are amoeboid with fine ...
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[PDF] Algae Identification - à www.publications.gc.ca
Individuals of this genus join to form complex, spherical colonies that at their largest are visible to the naked eye. (about 1 millimeter in diameter) and are ...
[54]
Siliceous scale production in Chrysophyte and Synurophyte algae. I ...
Aug 7, 2025 · Concentrations of less than 1 μM silicate greatly decreased the growth rate of Synura petersenii Korshikov and caused morphological changes.
[55]
Hydrurus foetidus (Chrysophyceae): an update and request for ...
Mar 15, 2019 · Hydrurus foetidus is a cold-water golden alga (Chrysophyceae) found in fast-flowing rivers mainly during time of snowmelt.
[56]
(PDF) Silica-scaled chrysophytes of Lake Baikal - ResearchGate
Aug 10, 2025 · According to our data, the list of silica-scaled chrysophytes of Lake Baikal includes 25 species and intra-species taxa: Chrysosphaerella – 3, ...
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Contribution of silica-scaled chrysophytes to ecosystems services
Nov 29, 2022 · Chrysophytes are important components of phytoplankton biomass (usually around 10–75% of the total biomass) in small oligotrophic or dystrophic ...
[58]
https://www.tandfonline.com/doi/abs/10.2216/i0031-8884-8-3-199.1
[59]
A yellow–green algal symbiont in the freshwater sponge ...
A previously undescribed symbiotic relationship is reported between the freshwater sponge Corvomeyenia everetti, which occurs throughout eastern North America, ...Missing: golden epiphytes
[60]
Phycokey - Lagynion (Chrysophyceae)
Epiphytic in generally oligotrophic and slightly acidic freshwater lakes. A Mediterranean endemic species, Lagynion janei (Chrysophyta), occurs in ...<|separator|>
[61]
Chrysidiastrum epiphyticum sp. nov. (Chrysophyceae): Phycologia
Mar 6, 2019 · Abstract. A new epiphytic species of Chrysidiastrum (C. epiphyticum) has been collected in a Cumberland County, North Carolina pond.Missing: epiphytes | Show results with:epiphytes
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Chrysophyte cysts as paleolimnological indicators of environmental ...
The identification of lakewater pH and trophic status as important determinants of cyst assemblage structure allowed for the reconstruction of acidification ...
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Silica-scale bearing Chrysophytes as environmental indicators
This paper gives a survey on the use of silica-scaled chrysophytes as ecological indicators of present and fossil environments with special regard to ...
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Prymnesins: Toxic Metabolites of the Golden Alga, Prymnesium ...
Mar 16, 2010 · Toxicity of this alga is attributed to a collection of compounds known as prymnesins, which exhibit potent cytotoxic, hemolytic, neurotoxic and ichthyotoxic ...
[65]
golden algae (Prymnesium parvum) - Species Profile
Prymnesium parvum, or golden algae, is a microscopic, single-celled algae with four forms, and cells are 6 to 12 µm long and 3.5 to 8 µm wide.Missing: colonies | Show results with:colonies
[66]
The relationship between chrysophyte cyst assemblages and ...
This study explores the potential of chrysophyte cysts as indicators of seasonal and interannual changes in meteorological conditions in Lakes Łazduny and Rzęś ...Missing: Chrysophyceae | Show results with:Chrysophyceae
[67]
Chrysophyte microfossils record marked responses to recent ...
In Sawtooth Lake on the Fosheim Peninsula, concentrations of chrysophycean stomatocysts increase dramatically in sediments deposited since AD 1920. Only trace ...Missing: cysts | Show results with:cysts
[68]
Scaled-chrysophyte assemblage changes in the sediment records of ...
Scaled-chrysophyte assemblage changes in the sediment records of lakes recovering from marked acidification and metal contamination near Wawa, Ontario, Canada ...
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Impacts of polyethylene microplastics on the microalga, Spirulina ...
Jun 15, 2023 · Among the most widely used microalgae in this respect are Cyanophyceae (blue-green algae), Chlorophyceae, Bacillariophyceae and Chrysophyceae ( ...
[70]
[PDF] CHRYSOPHYTE STOMATOCYSTS AND THEIR BIOGEOGRAPHY ...
Oct 23, 2020 · Chrysophyte cysts started gaining more attention in the 80's ... chrysophyte cyst assemblages have been linked to ice-cover times. At ...
[71]
A molecular timescale for eukaryote evolution with implications for ...
Mar 25, 2021 · We establish a timeframe for the origin of red algal-derived plastids under scenarios of serial endosymbiosis, using Bayesian molecular clock analyses.
[72]
Chimeric origins of ochrophytes and haptophytes revealed ... - eLife
May 12, 2017 · Our dataset indicates that the ochrophyte plastid was acquired late in stramenopile evolution, following the divergence of extant aplastidic ...Missing: timeline | Show results with:timeline
[73]
Integrated overview of stramenopile ecology, taxonomy, and ...
In the first scenario, the ancestor of the SAR lineage had already acquired a secondary red plastid, which was subsequently lost in all related heterotrophic ...Introduction · Stramenopiles are the “S” in SAR · Ochrophytes are the only...
[74]
Green diatom mutants reveal an intricate biosynthetic pathway of ...
Physiological and evolutionary implications of the two fucoxanthin pathways. The findings in this research provide biochemical and genetic evidence that ...
[75]
A Molecular Genetic Timescale for the Diversification of Autotrophic ...
Sep 16, 2010 · Divergence time estimates, assuming a lognormally-distributed relaxed ... diatoms are morphologically rather different from modern diatoms.<|separator|>
[76]
Evolution of heterotrophy in chrysophytes as reflected by ...
Mar 6, 2018 · Shifts in the nutritional mode between phototrophy, mixotrophy and heterotrophy are a widespread phenomenon in the evolution of eukaryotic ...
[77]
[PDF] Tracing lineages of scale-bearing Chrysophyceae over geologic time
Historically, heterokont algae with siliceous scale coverings were classified within the class Chrysophyceae (Pascher 1914; Bourrelly 1957).<|control11|><|separator|>
[78]
Effect of light and prey availability on gene expression of the ...
Feb 14, 2017 · Ochromonas is a genus of mixotrophic chrysophytes that is found ubiquitously in many aquatic environments. Species in this genus can be ...
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https://fottea.czechphycology.cz/artkey/fot-202502-0001_revisiting_chrysococcus_chrysophyceae_new_phylogenetic_evidence_and_evolutionary_implications.php
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Ice-Binding Proteins in a Chrysophycean Snow Alga - Frontiers
Nov 27, 2019 · Previous studies have suggested that algal IBP genes were acquired by horizontal transfer from other microorganisms (probably bacteria).
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Horizontal gene transfer in osmotrophs: playing with public goods
In this Opinion article, we propose that horizontal gene transfer (HGT) has played a key part in shaping both the repertoire of proteins required for osmotrophy ...