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Phycomyces blakesleeanus

Phycomyces blakesleeanus is a filamentous in the phylum Mucoromycota, class Mucoromycetes, order Mucorales, and family Phycomycetaceae, characterized by its production of tall, unicellular sporangiophores that can grow up to 10 cm in length and culminate in sporangia containing spores. As a saprotroph, it inhabits humid environments worldwide, where its dormant spores are commonly found in dung collected from humid forests, though the fruiting bodies are rarely observed in nature. The fungus reproduces both asexually through sporangiospores and sexually via zygospores formed between compatible mating strains, with spore germination often requiring heat activation such as 3 minutes at 50°C to break . This species is renowned for its acute sensory capabilities, responding to a wide array of environmental cues including light (via across 10 orders of magnitude of intensity), gravity (), mechanical touch (), wind, and the proximity of obstacles, enabling directed growth and avoidance behaviors. These responses are mediated by photoreceptor complexes such as those involving the MADB and MADA proteins, which form the primary light-sensing system in the fungus. P. blakesleeanus has served as a key in fungal since the 1950s, particularly for investigations into photobiology, sensory transduction, and behavioral , with over 50 mad (madness) mutants isolated to dissect these pathways. In addition to its sensory prowess, the fungus produces notable secondary metabolites like , which imparts a yellow coloration to mature sporangia, and has a sequenced that reveals insights into early-diverging fungal evolution, including events and phylogenetic relationships within the Mucorales. Strains exhibit with geographical clustering, such as high variation in the , and all possess functional mating-type genes (sexM and sexP), facilitating laboratory crosses for genetic studies. Its ease of cultivation on simple media and rapid growth have made it invaluable for exploring fungal development, , and applications, including production.

Taxonomy and phylogeny

Classification

Phycomyces blakesleeanus is classified within the kingdom Fungi, Mucoromycota, subphylum Mucoromycotina, class Mucoromycetes, order Mucorales, family Phycomycetaceae, Phycomyces, and species P. blakesleeanus. The binomial name Phycomyces blakesleeanus was established by Hans Burgeff in 1925. No major synonyms are recognized for this species. Phylogenetically, P. blakesleeanus belongs to the subphylum Mucoromycotina, which was formerly grouped under the polyphyletic Zygomycota. It is closely related to other saprotrophic fungi in the order Mucorales, such as species in the genera and . Molecular phylogenetic analyses, including multi-locus datasets with (rDNA) sequences, have confirmed its placement within Mucoromycota, supporting the reclassification from in updated fungal phylogenies post-2018. This hierarchical position is based on shared morphological traits like aseptate hyphae and columellate sporangia, alongside genetic evidence.

Etymology and history

The genus name Phycomyces is derived from the Greek words phykos (referring to or something resembling it) and mykēs (), reflecting the slender, elongated, filamentous sporangiophores that evoke seaweed-like growth. The was established by German botanist Gustav Kunze in , initially encompassing species with prominent aerial sporangiophores in the Mucorales order. The species epithet blakesleeanus commemorates American botanist Albert Francis Blakeslee, who advanced early understanding of fungal sexuality through his studies on Mucorales. In 1904, Blakeslee's doctoral thesis, "Sexual Reproduction in the Mucorineae," detailed the phenomenon of —self-sterility requiring compatible (+ and -)—using strains of what was then classified as Phycomyces nitens, thereby establishing foundational concepts for in these fungi. Phycomyces blakesleeanus was formally described as a separate by mycologist Hans Burgeff in 1925, distinguishing it from P. nitens based on morphological traits like smaller size and reproductive barriers observed in strains. This description drew from collections isolated primarily from dung in (e.g., , ) and during the late 19th and early 20th centuries, highlighting its saprophytic niche on decaying . Earlier contributions to Mucorales , including analyses relevant to Phycomyces, came from Heinrich Anton de Bary's 1880s monographs on fungal , which encompassed the group amid broader investigations into lower fungi.

Morphology and growth

Vegetative structures

The vegetative body of Phycomyces blakesleeanus consists primarily of coenocytic (aseptate) hyphae that form a sparse aerial on solid such as or . These hyphae lack cross-walls, allowing a continuous cytoplasmic network with multiple nuclei, and produce rhizoids at the base for anchorage to the . The serves as the foundational structure from which sporangiophores emerge, typically developing slowly under standard laboratory conditions. Sporangiophores are the prominent elongating stalks of the vegetative phase, reaching heights of up to 10-15 cm and exhibiting a transparent, cylindrical form with rapid apical growth rates of 10-60 μm/min. Their cell walls are composed mainly of microfibrils and β-glucans embedded in an amorphous matrix, providing while permitting extension in the apical growth zone. Sporangiophores often display subapical branching, particularly in response to environmental cues, and their elongation can involve bending as a vegetative to stimuli like or . Optimal growth of vegetative structures occurs at temperatures of 20-25°C and a range centered around 4.0-6.0, where mycelial expansion and sporangiophore elongation proceed most efficiently. Development begins with , which produces short germ tubes that develop into a coenocytic within 12-24 hours under suitable conditions. The then differentiates to form through sequential stages: Stage I involves initial outgrowth and elongation to 1-2 mm with helical growth; Stage II features cessation of elongation as the forms at the apex; Stage III shows no growth during maturation inside the ; and Stage IV represents the post-formation elongating phase below the , subdivided into IVa (accelerating growth), IVb (constant rapid growth of ~35 μm/min), and IVc (decelerating growth in older sporangiophores >10 cm). Stage V is the final cessation of growth. These stages highlight the transition from mycelial proliferation to aerial stalk formation, enabling efficient environmental sensing and resource allocation.

Reproductive structures

Phycomyces blakesleeanus produces distinct and sexual reproductive structures adapted for dispersal and . The structures are primarily , which develop at the apex of elongated sporangiophores. Each is globose and initially translucent, becoming opaque and black-walled as it matures, with a typically around 500 μm (0.5 mm). At the center of the lies the , a pear-shaped, swollen structure formed by an internal that separates the from the sporangiophore below. This serves as a supportive within the -filled cavity. The contains numerous sporangiospores, which are in shape, measuring 8–13 μm in length and 5–7.5 μm in width, with thick walls and a dark coloration in mature forms; microscopically, these spores feature multiple nuclei and droplets that contribute to their and . Sexual reproduction involves the formation of s between compatible strains of opposite (+ and -). Zygospores arise from the fusion of progametangia, which develop into gametangia that merge, producing a thick-walled zygospore suspended between tongs-like suspensors. These zygospores are spherical, dark brown, and can reach up to ~500 μm in diameter, featuring an ornamented exospore layer with stellate ridges for protection and identification. The outer wall is robust and black, often surrounded by ornamented appendages on the suspensors. Microscopically, zygospores contain thousands of nuclei from both parental types, initially uniformly distributed but later grouping peripherally, and they exhibit prolonged , with mechanisms including heat activation to break quiescence after several months.

Reproduction and life cycle

Asexual reproduction

Asexual reproduction in Phycomyces blakesleeanus occurs through the production of sporangiospores within atop elongated sporangiophores, enabling rapid clonal propagation without . The process begins with the maturation of sporangiophores, which develop in five distinct stages (I to Vb). In stage I, initial occurs at rates of 1-2 mm per hour, followed by stage II where the apical tip swells to form the , initially yellow and . By stage IVa, the darkens as sporangiospores (8-13 × 5-7.5 μm, thick-walled, , and nonmotile) differentiate from peripheral masses containing random samples, with no further divisions during formation. peaks in stage IVb at up to 3 mm per hour, allowing sporangiophores to reach up to 10-15 cm in height, positioning the for effective dispersal. Sporangiospores are released through mechanical dehiscence of the , triggered by contact with a solid surface or a drop, after which the ruptured becomes sticky. These lightweight spores facilitate passive dispersal primarily by wind, though or can also contribute to their spread. Viability remains high under optimal conditions, supporting efficient . Germination of sporangiospores requires prior to break and occurs under aerobic conditions, typically completing in 4-6 hours at 20°C. is achieved via heat shock (e.g., 48-53°C for 3 minutes, yielding ~95% ) or chemical treatments such as monocarboxylic acids (e.g., 0.1 M ) or n-alcohols (from to octanol), which lower the required temperature. Following , spores swell within 1 hour, and germ tubes emerge by 5 hours, developing into new that initiates the next reproductive cycle. Environmental factors modulate sporulation rates, with light and nutrient availability playing key roles; for instance, promotes sporangiophore initiation, while nutrient-rich conditions support higher sporulation, though can accelerate development. High density further enhances formation, whereas elevated retards it.

Sexual reproduction

Phycomyces blakesleeanus exhibits a heterothallic , requiring compatible strains of opposite , designated as (+) and (−), for . This system was first discovered by Albert F. Blakeslee in 1904, who observed that zygospores formed only when mycelia of different types interacted, establishing the foundation for understanding sexual compatibility in the Mucorales. The process begins with hyphal contact between opposite , leading to the formation of zygophores—specialized hyphae that grow toward each other and interlock. These zygophores then undergo a series of morphological changes: they form twisted suspensors, develop tong-shaped structures, and produce progametangia that fuse to delimit gametangia. The gametangia subsequently merge, forming a prozygote that matures into a thick-walled , with presumed to occur during subsequent . Optimal conditions for zygospore initiation and development include under low light at around 17°C with on media such as 1% extract , where continuous diffuse light (about 100 foot-candles) can support the process but intense light inhibits it. or low temperatures (e.g., 1°C) may reduce zygospore size and number but still allow formation, while temperatures above 22°C lead to abnormalities. Mature zygospores enter a dormant lasting from months to years, often requiring cold storage (e.g., 8 months at 1°C) and heat shock (50°C for 30 minutes) to stimulate . Upon , they produce a germ sporangiophore bearing a germ sporangium that releases germ spores, which develop into mycelia of both (+) and (−) , thereby completing the sexual cycle and enabling .

Ecology and distribution

Natural habitat

Phycomyces blakesleeanus is a saprotrophic primarily inhabiting humid environments worldwide, where it colonizes nitrogen-rich, moist organic substrates such as dung from small mammals like mice and rabbits, and larger s like deer and horses. It has also been isolated from decaying fruits, , debris, and , thriving on these materials as a coprophilous that contributes to the of . The fungus prefers temperate to subtropical climates with temperatures ranging from 15°C to 30°C, optimally around (up to a maximum of 28°C), and moist conditions that support its rapid growth. It occurs in environments such as grasslands, forests, and agricultural areas, often in with neutral to slightly acidic (around 5-7), though specific field measurements are limited due to its ephemeral nature. Globally, P. blakesleeanus is widespread but rarely observed in the wild, with records from (including since 1817, , and the ), (, including and ; ), (e.g., ), and (e.g., , ). Its isolation from natural sources dates back to the early 1900s, but it is infrequently detected in surveys because its fast growth allows it to outcompete slower-colonizing organisms during sampling. In its natural niches, P. blakesleeanus interacts with bacterial and fungal communities on dung substrates, competing for resources while facilitating nutrient recycling through decomposition. It disperses spores via animal vectors, with no known pathogenic interactions toward plants, animals, or humans. In humid forest settings, it coexists with diverse genotypes and mating types, suggesting active sexual reproduction in localized populations.

Laboratory cultivation

Phycomyces blakesleeanus is routinely cultivated in laboratory settings using solid media such as (PDA) or malt extract agar, which support robust mycelial growth and sporangiophore development. Bread slices serve as a simple, alternative for production, particularly in preliminary experiments. For auxotrophic mutant strains, media are supplemented with essential vitamins, such as , to enable growth on minimal formulations like glucose-asparagine broth. These nutrient-rich setups parallel the organic matter requirements observed in natural habitats, ensuring comparable metabolic activity. Cultures are incubated at 20-25°C to achieve optimal growth rates, with a 12-hour light/dark cycle often employed to induce sporulation. conditions must be avoided, as reduced oxygen levels inhibit sporangiophore elongation and overall development. Liquid cultures in shake flasks can be used for scaling, typically at similar temperatures and with to maintain . Strain maintenance involves storing stock cultures on slants at 4°C for short-term use, while long-term preservation employs at -80°C or in vapor phase. For zygospore production, compatible + and - strains are crossed by co-culturing on or similar media under controlled humidity and light. Common challenges include bacterial , addressed through sterile techniques, and ensuring adequate oxygen transfer in larger-scale liquid setups.

Sensory physiology

Phototropism

Phycomyces blakesleeanus exhibits positive , in which its sporangiophores bend toward unilateral illumination by in the 400-500 nm range. This response enables the to orient its spore-dispersing structures toward sources, optimizing dispersal. The bending occurs primarily in stage IV sporangiophores, which are elongated aerial hyphae that grow at rates up to 60 μm/min. The mechanism of involves differential growth between the lighted and shaded sides of the , driven by a lens-like focusing effect in the transparent growing zone. This zone, located 0.2-3 mm below the , acts as a that concentrates incoming light onto the shaded flank, stimulating greater elongation there and causing the sporangiophore to curve toward the light source. The process is mediated by changes in fluxes, including H⁺ and Ca²⁺, which regulate extension and asymmetry across the sporangiophore diameter. Ca²⁺ signaling, in particular, plays a key role in early , linking photoreception to cytoskeletal rearrangements and vesicle trafficking for localized growth. Electrical signals propagate from the perception site to modulate these fluxes, ensuring coordinated bending. The action spectrum for peaks at approximately 450 , corresponding to , with sensitivity extending into near-UV wavelengths around 380-400 . This spectrum is shaped by flavin-based photoreceptors, such as the , which may involve photochromic properties allowing across intensities. Recent studies have identified additional white collar-1 homologs, such as WcoA and WcoB, which contribute to alongside the madA-encoded MadA protein, enhancing sensitivity at high irradiances and . The threshold is extremely low, around 10⁻⁹ W/m² (approximately 10⁻⁸ for at 450 ), enabling detection of faint sources like , though effective bending typically requires intensities above 0.001 . At higher intensities (up to 10² W/m²), multiple interacting pigments contribute, broadening the . Phototropism proceeds in distinct stages: light perception occurs at the sporangiophore and growing zone via dichroic photoreceptors in the plasma membrane and ; transmission involves rapid electrical potentials and ion gradients traveling basipetally; the response manifests as unequal cell extension, with bending initiating after a 4-5 minute and peaking at rates of 1-1.3°/min. follows, with sensitivity recovering over 5-10 minutes in dark conditions or adjusting to steady illumination, preventing over-response. This temporal patterning ensures precise orientation without overshooting. The madA gene, encoding a white-collar-like flavin-binding protein, is essential for perception in this pathway. Experimentally, the bending angle in steady unilateral reaches an proportional to the logarithm of , reflecting a balance between phototropic torque and elastic restoring forces in the . The bending rate, or , can be modeled as proportional to the across the sporangiophore, with equations like \dot{\theta} = k \cdot \nabla I, where \dot{\theta} is the bending rate, k is a constant, and \nabla I is the intensity ; this quantifies how spatial patterns drive directional . Such metrics have been pivotal in dissecting sensory limits.

Other tropisms

Phycomyces blakesleeanus sporangiophores display through an avoidance response, in which they bend away from nearby solid objects without physical contact. This response is triggered when an object is placed approximately 1 mm from the growing zone, causing the sporangiophore to curve away from the barrier. The mechanism involves the emission of a volatile avoidance gas from the growing zone, which accumulates on the side facing the object and inhibits growth there, leading to bending; candidates for this gas include or . The response latency is typically 1-3 minutes, allowing rapid redirection of growth. Gravitropism in P. blakesleeanus is negative, with sporangiophores orienting upward against to optimize spore dispersal. This response manifests with a of 5-15 minutes after reorientation and follows the sine law, similar to patterns observed in plant tropisms. The sensory mechanism relies on statolith-like structures, including octahedral protein crystals in the that sediment under and trigger asymmetric growth, as well as buoyant lipid globules that contribute to gravisusception in earlier developmental stages. Chemotropism enables P. blakesleeanus to respond to chemical gradients, showing attraction toward nutrients that promote growth and repellence from toxins. A specific form, autochemotropism, underlies the avoidance response, where the sporangiophore detects its own emitted volatiles like , leading to self-avoidance and curvature away from barriers. Additionally, the exhibits mechanosensitivity to through positive anemotropism, bending toward via mechanical deflection of the sporangiophore, which modulates growth direction in response to environmental currents. These tropisms integrate in a hierarchical manner to guide sporangiophore orientation, with mechanical and chemical cues like avoidance often overriding when objects are in close proximity (within 1-2 mm), ensuring collision avoidance takes precedence over light-directed growth. This multi-sensory modulation allows P. blakesleeanus to navigate complex environments effectively, balancing inputs from touch, , chemicals, and wind.

Genetics and

overview

The of Phycomyces blakesleeanus measures approximately 59 Mb, featuring a low of 36% and an estimated repeat content of around 20%, which contributes to its expanded size relative to earlier estimates. It is predicted to encode roughly 12,773 protein-coding genes, reflecting the influence of whole-genome duplication events common in Mucoromycotina. Initial genomic studies in the provided partial assemblies and basic organization data, estimating a smaller size of about 30 Mb with 35% . A full draft was sequenced and assembled post-2010 through the Joint Genome Institute (JGI), with the latest version (v4.1 for NRRL1555) available via MycoCosm, highlighting Mucorales-specific expansions, particularly in pathways such as G-protein subunits and kinases.30361-X) The genome is organized into 9–12 chromosomes, as inferred from mapping of 134 markers across progeny from strain crosses. Introns are consistent with patterns in basal fungi, while mRNA involves poly-A tails for stability and translational control.30361-X) Epigenetic in P. blakesleeanus includes modifications that influence during development and environmental responses, alongside RNAi pathways that mediate , with evidence of small antisense RNAs in related Mucorales suggesting analogous mechanisms like quelling in mutants.30361-X)

Key mutants and genes

Phycomyces blakesleeanus exhibits a range of well-characterized genetic mutants, particularly those affecting sensory responses and . The mad mutants, isolated primarily through UV and chemical , number over 100 alleles distributed across 10 complementation groups (madA through madJ), which disrupt and related light responses. These mutants were first systematically isolated in the late and early using to target abnormal bending toward unilateral light. The madA and madB genes encode blue-light photoreceptors homologous to the White Collar-1 (WC-1) and White Collar-2 (WC-2) proteins of , respectively; madA functions as a containing a LOV for flavin binding, while madB interacts with madA to form the primary photoreceptor complex essential for perception. Mutations in madC through madJ primarily impair downstream of photoreception; for instance, madC encodes a Ras GTPase-activating protein () that regulates -mediated signaling in response to stimuli. Mating in P. blakesleeanus involves heterothallic + and - strains that differ at the sex locus, where the sexM allele (in - strains) and sexP allele (in + strains) each encode a single high-mobility-group (HMG) domain determining specificity. A map, constructed from crosses yielding 121 progeny, incorporates 134 markers (including AFLPs and gene-based markers) across 11 linkage groups totaling 1037.8 cM, facilitating ; several mad loci are positioned on distinct groups, such as madC on linkage group . Other notable mutants include those in carotenoid biosynthesis, governed by genes carA through carS, which control the accumulation of β-carotene; wild-type strains produce up to 0.05 mg/g dry weight, but regulatory mutants like carS overproduce up to 1% dry weight (10 mg/g), enhancing yellow pigmentation and serving as models for biosynthetic pathway regulation. Spore dormancy mutants, selected via density gradient separation of dormant and germinating cells or temperature-sensitive screens for heat-shock activation, reveal defects in constitutive dormancy mechanisms, altering germination rates under environmental cues. Genetic manipulation in P. blakesleeanus relies on tools like UV mutagenesis for generating mad variants and transformation systems; electroporation of protoplasts or spores with plasmids conferring hygromycin B resistance enables stable integration and expression of foreign genes, supporting functional genomics studies.

Research and applications

Historical studies

The discovery of heterothallism in Phycomyces blakesleeanus is attributed to Albert Francis Blakeslee, who began studying sexual reproduction in the Mucorales in 1904 and continued through the 1920s. Blakeslee identified two mating types in the fungus, requiring opposite strains for zygospore formation, and utilized isolates that were later designated as the standard wild-type strains NRRL 1555 (mating type -) and NRRL 1556 (mating type +) for his crosses. These studies established the genetic basis for mating in Phycomyces, demonstrating that self-fertile (homothallic) and self-sterile (heterothallic) behaviors could be distinguished through controlled pairings. In 1925, Hans Burgeff formalized the of the as Phycomyces blakesleeanus Burgeff, honoring Blakeslee's contributions while classifying it within the Mucorales based on morphological and reproductive characteristics. Burgeff's work refined the understanding of as a distinct heterothallic , building on earlier descriptions and emphasizing its sporangiophore development and . Research on tropisms in gained momentum in the 1920s with experiments by E.S. Castle, who investigated in the sporangiophores, revealing their high sensitivity to and wavelengths. Castle's studies demonstrated that unilateral exposure induced bending toward the source, with action spectra peaking around 450 nm, laying groundwork for interpreting the physical and physiological mechanisms of -directed growth. In , Erwin Bünning extended this by linking pigments to phototropic responses, proposing their role in during experiments on fungal fruiting bodies. The mid-20th century marked a pivotal shift when , a Nobel laureate in physiology or medicine for phage work, initiated systematic studies on Phycomyces at the in the 1950s, viewing it as an ideal model for sensory transduction due to its robust phototropic responses. Delbrück's team focused on isolating mutants with defects in light perception, known as "mad" (for Max) mutants, to dissect the pathway. The first night-blind mutant, madA, was isolated in the 1960s, exhibiting reduced sensitivity to and confirming genetic control over . Key publications from Delbrück's group in the detailed the -growth response, a transient in sporangiophore elongation following light pulses, with spectra aligning to flavin . These works, including analyses of and , quantified the system's and shifts, establishing as a quantitative model for photoreception. By 1960, was firmly recognized as a for studying sensory biology, and by the 1970s, over 50 mutants—including multiple alleles in mad and genes—had been characterized, enabling detailed genetic of light responses.

Modern research

Since the 1990s, molecular studies on Phycomyces blakesleeanus have advanced through gene cloning efforts, building on earlier mutant analyses to identify key components of sensory pathways. The madA gene, essential for blue-light perception and phototropism, was cloned in 2006 using degenerate PCR primers based on homologs from Neurospora crassa, revealing it encodes a LOV-domain photoreceptor protein similar to WC-1 that regulates light responses including phototropism and sporangiophore development. Complementary work cloned the interacting madB gene in 2009, demonstrating it forms a heterodimeric complex with MadA analogous to the Neurospora White Collar complex, which is required for all known light responses in the fungus. Genome sequencing efforts in the 2010s, led by the U.S. Department of Energy Joint Genome Institute (DOE-JGI), provided a comprehensive view of the P. blakesleeanus genome, estimated at approximately 50 Mb with low , enabling comparative analyses across Mucoromycotina. This sequencing, completed around , highlighted expansions in gene families, such as G-protein coupled receptors and kinases, which underpin the fungus's environmental sensing capabilities and offer insights into early-diverging fungal . More recent genetic tools, including a high-density linkage map constructed in from 134 markers across 121 progeny, have facilitated map-based of additional s involved in sensory and metabolic pathways. In applications, P. blakesleeanus continues to serve as a model for fungal sensory transduction, with its well-characterized phototropism and avoidance responses informing broader studies on light signaling in early-diverging fungi. Biotechnologically, the fungus has been engineered for carotenoid production, with mutants like strain S556 yielding up to 9 mg of β-carotene per gram of dry biomass under optimized conditions, positioning it as a potential source for natural antioxidants and pigments in food and pharmaceutical industries. Its sensory mutants also provide analogs for investigating fungal pathogenesis mechanisms in related Mucorales species, such as signal transduction disruptions that mimic virulence factor regulation. Recent findings in the 2020s have explored finer details of sensory mechanisms and ecological interactions. A study detailed the helical growth dynamics during phototropic and avoidance responses, using high-resolution imaging to quantify bending rates and linking them to cytoskeletal rearrangements in sporangiophores. bioinformatics of Mucorales genomes, including P. blakesleeanus, has revealed evolutionary expansions in two-component signaling systems, aiding understanding of how basal fungi adapt to diverse environments. Additionally, metagenomic surveys have uncovered bacterial microbiomes associated with P. blakesleeanus, including Bacillus cereus strains that share recent common ancestry with bacteria from other fungal hosts, suggesting symbiotic interactions that may influence sporulation and nutrient cycling in ecosystems. A 2024 analysis identified multiple white collar-like genes mediating light reception, expanding the known photoreceptor repertoire beyond MadA/MadB and highlighting sex-specific light inhibition of mating. In 2025, further research examined sexual crosses for advancing genetic studies, refined models of helical growth in tropisms, and explored its use in selenite , demonstrating metabolic adaptations for environmental cleanup. Future directions leverage these advances for , where P. blakesleeanus photoreceptors could inspire light-responsive fungal materials for environmental sensing, though current efforts focus on refining genetic tools for targeted edits in sensory genes.

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