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Prothallus (prothallium) of the fern Polypodium vulgare seen under a light microscope.

A prothallus, or prothallium, (from Latin pro = forwards and Greek θαλλος (thallos) = twig) is usually the gametophyte stage in the life of a fern or other pteridophyte. Occasionally, the term is also used to describe the young gametophyte of a liverwort or peat moss as well. In lichens, it refers to the region of the thallus that is free of algae.

The prothallus develops from a germinating spore. It is a short-lived and inconspicuous heart-shaped structure typically 2–5 millimeters wide, with a number of rhizoids (root-like hairs) growing underneath, and the sex organs: archegonium (female) and antheridium (male). Appearance varies quite a lot between species. Some are green and conduct photosynthesis while others are colorless and nourish themselves underground as saprotrophs.

Alternation of generations

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Prothallus of the tree fern Dicksonia antarctica (note new moss plants for scale)

Spore-bearing plants, like all plants, go through a life-cycle of alternation of generations. The fully grown sporophyte, what is commonly referred to as the fern, produces genetically unique spores in the sori by meiosis. The haploid spores fall from the sporophyte and germinate by mitosis, given the right conditions, into the gametophyte stage, the prothallus. The prothallus develops independently for several weeks; it grows sex organs that produce ova (archegonia) and flagellated sperm (antheridia). The sperm are able to swim to the ova for fertilization to form a diploid zygote which divides by mitosis to form a multicellular sporophyte. In the early stages of growth, the sporophyte grows out of the prothallus, depending on it for water supply and nutrition, but develops into a new independent fern, which will produce new spores that will grow into new prothallia etc., thus completing the life cycle of the organism.

Theoretical advantages of alternation of generations

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It has been argued that there is an important evolutionary advantages to the alternation of generations plant life-cycle.[1] By forming a multicellular haploid gametophyte rather than limiting the haploid stage to gametes, there is often only one allele for any genetic trait. Thus, alleles are not masked by a dominant counterpart (there is no counterpart).

One benefit of this is that a mutation that causes a lethal, or harmful, trait expression will cause the gametophyte to die; thus, the trait cannot be passed on to future generations, preserving the strength of the gene pool.[1] Furthermore, if individual cells of the gametophyte compete with one another, somatic mutations that reduce cell vigour may prevent a cell lineage from reproducing.[1]

In lichens

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The region of the thallus in lichens that is free of algae (the photobiont partner) and contains only fungus (the mycobiont partner) is called the prothallus. It is typically white, brown, or black in colour. In crustose lichens, the prothallus is visible between areoles and on the growing thallus margin.[2] In the large genus Cladonia, the prothallus may provide a mode of vegetative reproduction, and it may have a role in stabilising the soil.[3] In some genera, such as Coenogonium, the presence of absence of prothalli is an important taxonomic character that is used to help classify species.[4] The term prothallus was first used by German botanist Georg Meyer in 1825, who introduced it in a discussion of lichen growth.[5]

References

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Prothallus

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A prothallus, also spelled prothallium, is the haploid stage in the life cycle of ferns and related pteridophytes, appearing as a small, flat, heart-shaped that develops from a germinating and functions in by producing both and eggs. The term is also used in to refer to a primitive or fungal growth at the edge of structures. This structure is typically green and photosynthetic, measuring 2–10 mm in length and width, and consists of a single layer of cells without , relying on for nutrient transport and supported by rhizoids for anchorage. In the life cycle, which exemplifies , the prothallus represents the reduced phase in seedless vascular plants, contrasting with the dominant, larger diploid that produces spores via . It emerges from homosporous spores shed from the sporangia on the underside of fronds, germinating into a filamentous stage before maturing into the characteristic heart shape under suitable moist, shaded conditions. The prothallus is bisexual, bearing antheridia (male organs that release multiflagellated ) on its lower surface or edges and archegonia (female organs each containing a single ) near the notch of the heart shape, with fertilization requiring a film of for to swim to the . Following fertilization, the resulting diploid develops into a young that remains attached to and nourished by the prothallus until it becomes independent, eventually growing into the familiar leafy plant. This is often short-lived and free-living, though it may associate with mycorrhizal fungi for enhanced nutrient uptake, and its morphology can vary slightly among species, sometimes appearing more kidney-shaped or filamentous in early stages. The term "prothallus" derives from Greek roots meaning "first shoot," reflecting its role as the initial, reproductive body in the cycle.

Botanical Context

Definition and Characteristics

The prothallus is the haploid stage in the life cycle of ferns (Pteridophyta) and related seedless vascular plants, such as horsetails and whisk ferns. It develops from a germinating and serves as the sexual phase, producing both male and female gametes through . This structure is typically a small, independent, free-living organism that is autotrophic and photosynthetic, enabling it to sustain itself without reliance on the sporophyte. It lacks vascular tissue and relies on diffusion for nutrient and water transport, with rhizoids providing anchorage to the substrate. The prothallus is bisexual (monoecious), bearing both antheridia and archegonia, and requires moist conditions for fertilization, as sperm must swim through water to reach the egg.

Morphology and Anatomy

The prothallus, or fern gametophyte, exhibits a distinctive thalloid morphology characterized by a heart- or kidney-shaped flattened structure, typically measuring 3–10 mm in length and 2–8 mm in breadth. This form enables efficient anchorage and nutrient absorption in moist terrestrial environments. The thallus is generally one cell layer thick throughout its biplanar growth phase, though the central region may develop a thickened midrib composed of multiple cell layers in mature specimens, providing structural support without true vascularization. Anchorage and absorption are facilitated by unicellular rhizoids, which emerge as elongated, root-hair-like projections from the underside of the thallus, particularly at its base. These rhizoids lack the complexity of true but effectively secure the prothallus to substrates and uptake water and minerals, compensating for the absence of . The overall organization is simple, with growth driven by an apical that promotes expansion from the notched apex, resulting in a radially symmetrical structure in most species. The prothallus is autotrophic, featuring chlorophyll-containing cells that enable and support independent nutrition. These photosynthetic tissues are distributed across the upper surface of the , with chloroplasts concentrated in the thin cellular layer for optimal light capture. In some species, such as Pteris vittata, mycorrhizal associations with fungi like Glomus intraradices further enhance nutrient uptake, particularly , by colonizing the rhizoids and cortical cells during later developmental stages. Morphological variations occur across fern families, influenced by environmental factors and ; for instance, prothalli in the Dryopteridaceae family, such as Dryopteris species, are typically 2–5 mm wide and may initially appear filamentous before flattening into the characteristic thalloid form. This early filamentous stage transitions to the mature flattened shape through meristematic activity, highlighting the prothallus's adaptive plasticity.

Development from Spore

The development of the prothallus begins with the germination of a haploid released from the of the . Upon absorption of water, the 's outer wall ruptures, and the inner protoplast undergoes mitotic divisions to produce a filamentous , characterized by a basal for anchorage and an apical protonemal cell that elongates through tip growth. This initial thread-like structure typically emerges within 6-10 days under controlled conditions of 23°C, high , and low-intensity (around 1,000 ). The then transitions to the thalloid prothallus through branching and planar expansion, forming a characteristic heart-shaped structure over 1-2 weeks. This shift involves reorientation of planes in the apical cells, driven by photomorphogenic responses where light intensity exceeding 2 µmol m⁻² s⁻¹ promotes flattening from the one-dimensional filament to a two-dimensional lamina. The process is highly sensitive to environmental cues, requiring consistently moist conditions to prevent and shaded habitats with diffuse light to avoid inhibition of growth, alongside optimal temperatures of 20-25°C for efficient cell differentiation. In certain species, such as Anemia phyllitidis, exogenous enhances and early elongation by stimulating protein synthesis and reserve mobilization, though its role varies across taxa. Variations in prothallus development occur among fern species, reflecting adaptations to specific habitats. For instance, in species, the gametophytes often develop tuberous, subterranean forms that facilitate nutrient storage and fungal symbioses, extending the duration to maturity up to 4 weeks while enhancing survival in nutrient-poor soils. Overall, the prothallus reaches within 2-4 weeks post-germination, depending on these factors, marking the completion of early before production.

Reproduction and Life Cycle

Gametogenesis and Structures

The prothallus, as the haploid stage in ferns and related plants, undergoes through mitotic divisions within specialized gametangia to produce gametes, enabling . This process occurs after the prothallus has matured into its characteristic heart-shaped form, typically measuring 2–5 mm in width and attached to the substrate by rhizoids. Environmental cues, particularly the presence of , are essential for initiating and supporting gametogenesis, as they facilitate the development and function of sex organs on the ventral surface of the prothallus. Antheridia, the male gametangia, are multicellular structures that develop on the lower surface of the prothallus, often among the rhizoids, and produce numerous multiflagellated cells. Each consists of a single-layered jacket of sterile cells surrounding fertile spermatogenous cells, which undergo repeated mitotic divisions to generate the motile ; these require a film of to swim toward the female gametes. Development of is triggered by moist conditions and, in many species, by the antheridiogen secreted by nearby maturing prothalli, promoting male differentiation in younger individuals. typically mature first in the sequence of , appearing within weeks of prothallus establishment under suitable low-light and humid environments. Archegonia, the female gametangia, are flask-shaped organs embedded within the tissue of the prothallus, primarily near the apical notch on the ventral side, and each contains a single non-motile . The structure includes a swollen venter the and a narrow neck composed of four rows of cells, including neck canal cells that degenerate upon maturation to form a mucilaginous channel; this channel releases chemical attractants to guide toward the . in archegonia involves mitotic production of the from a central cell within the venter, occurring after antheridial development in most species to stagger reproductive timing. Archegonia form under similar moist conditions as antheridia but often in slightly drier microhabitats relative to release. The prothallus exhibits a hermaphroditic , bearing both antheridia and archegonia on the same individual in most homosporous ferns, which supports potential self-fertilization but is rare due to protandry—the earlier maturation of antheridia followed by archegonia—encouraging between prothalli. This temporal separation, combined with the limited mobility of (requiring films typically under 1 mm thick), minimizes and promotes in populations. In some species, such as Ceratopteris, environmental factors like light intensity further modulate the balance between male and hermaphroditic forms.

Fertilization Process

In the fertilization process of the prothallus, motile, multiflagellated cells are released from mature antheridia on the surface, typically in response to environmental moisture such as or that forms a thin across the prothallus. These , produced through , swim short distances—often to archegonia on the same or a nearby prothallus—relying on the for propulsion and guidance toward the female gametes. The process requires external , as the lack the ability to move without it, limiting fertilization to humid conditions. Upon reaching an , a single enters the neck canal and fuses with the stationary within the venter, restoring the diploid number and forming a . This syngamy event is typically monospermic, with prevented by cytological mechanisms, such as the formation of a large vesicle that blocks additional entry, as observed in some . Following fertilization, the diploid undergoes mitotic divisions to develop into a young , which remains embedded in the and attached to the prothallus for initial nourishment and support via nutrients and water absorbed from the tissue. The embryo gradually emerges, forming rudimentary , a foot for anchorage, and the first leaf (), while drawing sustenance from the prothallus until it achieves photosynthetic independence. Successful fertilization leads to the eventual withering and of the prothallus, as its nutritional resources are depleted in support of the developing . In cases where multiple archegonia are fertilized on a single prothallus, several embryos may initiate development, though typically only one matures into a viable due to resource competition.

Role in Alternation of Generations

In pteridophytes, the prothallus serves as the haploid gametophyte phase within the heteromorphic , bridging the diploid and the restoration of diploidy through . The cycle begins with the mature diploid , which produces haploid spores via in sporangia located on the underside of fronds. These spores germinate and develop into the prothallus through mitotic divisions, forming a small, thalloid structure that is photosynthetic and independent. On the prothallus, gametangia differentiate: antheridia release motile , and archegonia contain eggs. Fertilization occurs when sperm swim to eggs, typically facilitated by , forming a diploid that embryonically develops into a new while nourished by the prothallus until it becomes independent. This alternation is heteromorphic, characterized by stark morphological differences between generations: the prothallus is a flattened, heart-shaped thallus lacking vascular tissue, roots, stems, or leaves, contrasting with the upright, vascular sporophyte that dominates the visible plant body in vascular pteridophytes. The prothallus's simple structure enables rapid development but renders it vulnerable to desiccation and environmental stresses due to its reliance on diffusion for nutrient and water uptake, in contrast to the more robust, independent sporophyte. Compared to bryophytes, where the gametophyte generation is dominant and the sporophyte is nutritionally dependent, the prothallus in pteridophytes represents a reduced phase, underscoring the evolutionary shift toward dominance in vascular plants. This reduction highlights the prothallus's transitional role, emphasizing efficiency in reproduction while the achieves greater terrestrial adaptation through vascular systems.

Evolutionary and Ecological Aspects

Theoretical Advantages

The prothallus, as the free-living haploid in the life cycle of ferns and related plants, confers a key genetic advantage by exposing recessive deleterious alleles to direct selection, allowing for their efficient purging from the . In the haploid state, unlike the diploid where such alleles can be masked by dominant counterparts, harmful mutations are phenotypically expressed, enabling to eliminate weak individuals early in the life cycle. This enhances overall fitness by reducing the accumulation of genetic defects over generations. This haploid selection mechanism contributes to a broader reduction in , maintaining the robustness of the diploid phase by filtering out inferior genotypes at the stage before they can contribute to the next generation. Theoretical models demonstrate that longer haploid phases are particularly beneficial under conditions of low recombination or high selfing rates, as they double the opportunity for exposure compared to purely diploid cycles, leading to lower equilibrium loads. By eliminating weak haploids, the prothallus stage ensures that only viable zygotes develop into , thereby optimizing in the . Seminal work on haploid-diploid cycles highlights how this balance evolves to minimize deleterious effects while preserving adaptive potential. Ecologically, the prothallus provides adaptive flexibility through its compact size and photosynthetic , enabling rapid of ephemeral moist microhabitats that may be unsuitable for the larger . As an independent, chlorophyll-containing structure, it can establish itself via lightweight spores dispersed over long distances, exploiting transient wet conditions without relying on the for nutrients or support, which alleviates developmental burdens on the dominant diploid phase. This independence facilitates quicker establishment in diverse, often shaded or disturbed environments, promoting species persistence and across fragmented landscapes.

Occurrence in Plant Groups

The prothallus is primarily associated with pteridophytes, particularly ferns, where it represents the free-living, haploid gametophyte generation in the alternation of generations life cycle. In leptosporangiate ferns, such as Polypodium species, the prothallus typically develops as a small, heart-shaped, photosynthetic thallus measuring 3–10 mm in length, featuring rhizoids for anchorage and a single layer of cells for nutrient absorption./06%3A_Seedless_Vascular_Plants/6.02%3A_Ferns_and_Horsetails/6.2.02%3A_Ferns) In eusporangiate ferns, exemplified by Osmunda species, the prothalli are larger and often ribbon-shaped or flat, remaining photosynthetic and capable of supporting early sporophyte development, though variations exist with some forms exhibiting thickened, storage-rich structures in related taxa. In lycophytes (clubmosses, spikemosses, and quillworts), the gametophyte generation is notably reduced compared to ferns; for example, in genera like Isoetes, the gametophytes are endosporic, developing inside the spores as small, non-photosynthetic structures that rely on mycorrhizal fungi for carbon and nutrients, highlighting a heterotrophic adaptation in this group. This subterranean or endosporic morphology contrasts with the more exposed forms in ferns and underscores the diversity in gametophyte independence across vascular plants. In horsetails (), the prothallus takes an elongated, irregularly lobed form composed of delicate, photosynthetic lamellae a few cells thick, enabling it to thrive in moist, shaded environments while producing gametes. These variations in prothallus shape and nutrition—from cordate and autotrophic in leptosporangiate to mycorrhiza-dependent in lycophytes—illustrate adaptive diversity tied to habitat and evolutionary lineage. The term prothallus is rarely and non-standardly applied to bryophytes; in liverworts like , it may describe the early discoid formed from , but the conventional term is simply thallus, while mosses lack a prothallus entirely, instead featuring a filamentous as the initial stage. Among modern , over 10,500 worldwide exhibit the prothallus stage, representing the majority of extant diversity and emphasizing its central role in their reproduction.

Evolutionary History

The prothallus, representing the free-living stage in the life cycle of early vascular plants, originated approximately 400 million years ago during the period, coinciding with the initial diversification of land plants. Fossil evidence from the in , dated to about 407 million years ago, preserves associated with early vascular plants such as Aglaophyton major, whose prothallial counterpart is identified as Lyonophyton rhyniensis. These fossils reveal tubular, mycorrhiza-like fungal associations within the gametophyte tissues, suggesting early symbiotic relationships for nutrient uptake in nutrient-poor terrestrial environments. The evolutionary trajectory of the prothallus traces back to the in charophycean , where isomorphic haploid and diploid phases predominated, but transitioned to heteromorphic generations in early pteridophytes by the , with the becoming photosynthetic and independent yet subordinate to the emerging . This shift occurred during the , a key event spanning roughly 443 to 359 million years ago, when vascular colonized land, evolving from simple axial forms to more complex structures supported by the prothallus for . In seed , including gymnosperms and angiosperms that arose in the late and periods, the prothallus underwent further reduction, evolving into microscopic, endosporic structures embedded within spores and no longer free-living, thereby eliminating the vulnerable independent phase. A prominent trend in prothallus evolution was the increasing dominance of the generation across lineages, driven by adaptations for upright growth and vascular transport that enhanced terrestrial fitness, while the diminished in size and autonomy from bryophytes to seed plants. Ancient prothalli, as evidenced in fossils, commonly harbored mycorrhizal symbioses with glomeromycotan fungi, facilitating acquisition in early soils and representing one of the oldest known plant-fungal mutualisms back over 400 million years. However, studies of prothallus evolution remain constrained by the sparsity of fossils, attributable to their delicate, non-lignified tissues that decay rapidly and preserve poorly compared to robust sporophytes.

Lichen Context

Definition and Characteristics

In lichens, the term prothallus refers to the region of the thallus composed exclusively of fungal hyphae, lacking the photobiont (typically algae or cyanobacteria), and often appearing as a crust-like fringe or mat. Coined by German botanist Georg Meyer in 1825 during a discussion of lichen growth patterns, it describes these non-lichenized fungal zones that extend beyond or underlie the symbiotic portions of the thallus. This structural feature serves as a diagnostic trait in lichen identification, particularly in species where it forms a visible boundary or connector between lichenized areas. The term is sometimes confused with "hypothallus," an alternative introduced by Elias Fries in 1831, but both denote similar non-lichenized fungal extensions. Prothalli exhibit distinct characteristics, including a non-photosynthetic due to the absence of photobionts, relying instead on the fungal for growth, which may operate in a saprotrophic mode by deriving nutrients from the substrate. They commonly appear white, brown, or black—often melanized for —and develop at the margins of the or in interstices, such as between areoles in crustose forms. In these positions, the prothallus can act as a growth barrier, preventing adjacent lichens from encroaching on each other's space while facilitating expansion. Unlike the prothallus in botanical contexts, which denotes the independent, gametophytic stage of ferns and allied , the lichen prothallus is not reproductive but rather an anatomical extension of the mycobiont, emphasizing the fungal dominance in lichen structure. It is especially visible and prominent in crustose , where it underlies or borders areoles (e.g., in Lecanora circumborealis and Buellia disciformis), and in squamulose lichens, where it surrounds small, scale-like units.

Structure and Function

The prothallus in lichens is composed primarily of dense fungal hyphae derived from or, less commonly, , forming a non-lichenized zone that lacks algal or cyanobacterial cells. In some species, these hyphae are embedded within a gelatinous matrix secreted by the , which contributes to structural cohesion. Internally, the prothallus exhibits either a prosenchymatous organization, characterized by loosely interwoven hyphae that allow flexibility, or a pseudoparenchymatous arrangement, where hyphae are compactly aggregated to resemble cellular tissue. This dual structure provides a protective barrier against environmental stresses, including desiccation, by limiting water loss and shielding underlying thallus tissues. Functionally, the prothallus facilitates vegetative propagation, as seen in the podetia of species, where it enables fungal extension and fragmentation for dispersal. It also serves in storage, accumulating reserves that support initial growth before photobiont integration, and plays a key role in boundary formation during thallus expansion, delineating territories to prevent overlap with adjacent lichens. In genera such as Coenogonium, the prothallus—often appearing as a white or dark marginal rim—is a taxonomically significant feature, aiding identification based on its presence, color, and extent. Studies, including Hammer's 1996 examination of , highlight considerable variability in prothallus morphology across taxa, with multiple forms per influenced by substrate and developmental stage, underscoring its adaptive histological diversity.

Ecological Significance

The lichen prothallus contributes significantly to stabilization in pioneer communities by secreting materials that bind fungal hyphae to particles and substrates, thereby preventing and aiding in . In ecosystems, species form extensive mats that loose soils, buffering against and erosion while moderating microclimatic extremes like fluctuations; the prothallus may play a role in this stabilization. Biological soil crusts, which include crustose lichens, reduce and stabilize arid or exposed terrains by physically adhering to rock and surfaces. The prothallus also aids lichen reproduction by facilitating thallus fragmentation and dispersal, as its non-lichenized fungal structure enables vegetative propagation through hyphal extension beyond the symbiotic portion of the thallus. This allows fragments to detach and establish new colonies, particularly effective in short-distance dispersal within open habitats. In terms of symbiotic interactions, the prothallus serves as a critical interface for fungal-algal recolonization, permitting the fungus to advance into unoccupied areas where photobionts can later integrate to form mature ; it demonstrates notable tolerance to extreme environmental stresses, including high radiation and prolonged dryness, which enhances survival in harsh conditions. Lichens featuring prominent prothalli occur across a wide range of biomes, from tundras to tropical forests, underscoring their role in succession and resilience.

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