IV. STRATOSE-RADIATE THALLUS
1. STRATOSE OR PRIMARY THALLUS
A. General Characteristics
Fig. 66. Cladonia pyxidata Hoffm. Basal squamule and podetium. a, apothecia; s, spermogonia (after Krabbe).
This series includes the lichens of one family only, the Cladoniaceae, the genera of which are characterized by the twofold thallus, one portion being primary, horizontal and stratose, the other secondary and radiate, the latter an upright simple or branching structure termed a “podetium” which narrows above, or widens to form a trumpet-shaped cup or “scyphus” ([Fig. 66]). The apothecia are terminal on the podetium or on the margins of the scyphi; in a few species they are developed on the primary thallus. Some degree of primary thallus-formation has been demonstrated in all the genera, if not in all the species of the family. The genus Cladina was established to include those species of Cladonia in which, it was believed, only a secondary podetial thallus was present, but Wainio[389] found in Cladonia sylvatica a granular basal crust and, in Cladonia uncialis, minute round scales with crenate margins measuring from ·5 to 1 mm. in width. In some species (subgenus Cladina) the primary thallus is quickly evanescent, in others it is granular or squamulose and persistent. Where the basal thallus is so much reduced as to be practically non-existent, apothecia are rarely developed and soredia are absent. Renewal of growth in these lichens is secured by the dispersal of fragments of the podetial thallus; they are torn off and scattered by the wind or by animals, and, if suitable conditions are met, a new plant arises.
Cladonia squamules vary in size from very small scales as in Cl. uncialis to the fairly large foliose fronds of Cl. foliacea which extend to 5 cm. in length and about 1 cm. or more in width. It is interesting to note that when the primary thallus is well developed, the podetia are relatively unimportant and frequently are not formed. As a rule the squamules are rounded or somewhat elongate in form with entire or variously cut and crenate margins. They may be very insignificant and sparsely scattered over the substratum, or massed in crowded swards of leaflets which are frequently almost upright. In colour they are bluish-grey, yellowish or brownish above, and white beneath (red in Cl. miniata), frequently becoming very dark-coloured towards the rooting base. These several characteristics are specific and are often of considerable value in diagnosis. In certain conditions of shade or moisture, squamules are formed on the podetium; they repeat the characters of the basal squamules of the species.
B. Tissues of the Primary Thallus
The stratose layers of tissue in the squamules of Cladonia are arranged as in other horizontal thalli.
a. Cortical tissue. In nearly all these squamules the cortex is of the “decomposed” type. In a few species there is a plectenchymatous formation—in Cl. nana, a Brazilian ground species, and in two New Zealand species, Cl. enantia f. dilatata and Cl. Neo-Zelandica. The principal growing area is situated all round the margins though generally there is more activity at the apex. Frequently there is a gradual perishing of the squamule at the base which counterbalances the forward increase.
The upper surface in some species is cracked into minute areolae; the cracks, seen in section, penetrate almost to the base of the decomposed gelatinous cortex. They are largely due to alternate swelling and contraction of the gelatinous surface, or to extension caused, though rarely, by intercalary growth from the hyphae below. The surface is subject to weathering and peeling as in other lichens; but the loss is constantly repaired by the upward growth of the meristematic hyphae from the gonidial zone; they push up between the older cortical filaments and so provide for the expansion as well as for the renewal of the cortical tissue.
b. Gonidial tissue. The gonidia consisting of Protococcaceous algae form a layer immediately below the cortex. Isolated green cells are not unfrequently carried up by the growing hyphae into the cortical region, but they do not long survive in this compact non-aerated tissue. Their empty membranes can however be picked out by the blue stain they take with iodine and sulphuric acid.
Krabbe[390] has described the phases of development in the growing region: he finds that differentiation into pith, gonidial zone and cortex takes place some little way back from the edge. At the extreme apex the hyphae lie fairly parallel to each other; further back, they branch upwards to form the cortex, and to separate the masses of multiplying gonidia, by pushing between them and so spreading them through the whole apical tissue. The gonidia immediately below the upper cortex, where they are well-lighted, continue to increase and gradually form into the gonidial zone; those that lie deeper among the medullary hyphae remain quiescent, and before long disappear altogether.
Where the squamules assume the upright position (as in Cladonia cervicornis), there is a tendency for the gonidia to pass round to the lower surface, and soredia are occasionally formed.
c. Medullary tissue. The hyphae of the medulla are described by Wainio as having long cells with narrow lumen, and as being encrusted with granulations that may coalesce into more or less detachable granules; in colour they are mostly white, but pale-yellow in Cl. foliacea and blood-red in Cl. miniata, a subtropical species. They are connected at the base of the squamules with a filamentous hypothallus which penetrates the substratum and attaches the plant. In a few species rhizinae are formed, while in others the hyphae of the podetium grow downwards, towards and into the substratum as a short stout rhizoid.
d. Soredia. Though frequent on the podetia, soredia are rare on the squamules, and, according to Wainio[391], always originate at the growing region, from which they spread over the under surface—rather sparsely in Cl. cariosa, Cl. squamosa, etc., but abundantly in Cl. digitata and a few others. In some instances, they develop further into small corticate areolae on the under surface (Cl. coccifera, Cl. pyxidata and Cl. squamosa).
2. RADIATE OR SECONDARY THALLUS
A. Origin of the Podetium
The upright podetium, as described by Wainio[392] and by Krabbe[393], is a secondary product of the basal granule or squamule. It is developed from the hyphae of the gonidial zone, generally where a crack has occurred in the cortex and rather close to the base or more rarely on or near the edge of the squamule (Cl. verticillata, etc.). At these areas, certain meristematic gonidial hyphae increase and unite to form a strand of filaments below the upper cortex but above the gonidial layer, the latter remaining for a time undisturbed as to the arrangement of the algal cells.
This initial tissue—the primordium of the podetium—continues to grow not only in width but in length: the basal portion grows downwards and at length displaces the gonidial zone, while the upper part as a compact cylinder forces its way through the cortex above, the cortical tissue, however, taking no part in its formation; as it advances, the edges of the gonidial and cortical zones bend upwards and form a sheath distinguishable for some time round the base of the emerging podetium.
Even when the primary horizontal thallus is merely crustaceous, the podetia take origin similarly from a subcortical weft of hyphae in an areola or granule.
B. Structure of the Podetium
a. General structure. In the early stages of development the podetium is solid throughout, two layers of tissue being discernible—the hyphae forming the centre of the cylinder being thick-walled and closely compacted, and the hyphae on the exterior loosely branching with numerous air-spaces between the filaments.
In all species, with the exception of Cl. solida, which remains solid during the life of the plant, a central cavity arises while the podetium is still quite short (about 1 to 1·5 mm. in Cl. pyxidata and Cl. degenerans). The first indication of the opening is a narrow split in the internal cylinder, due to the difference in growth tension between the more free and rapid increase of the external medullary layer and the slower elongation of the chondroid tissue at the centre. The cavity gradually widens and becomes more completely tubular with the upward growth of the podetium; it is lined by the chondroid sclerotic band which supports the whole structure ([Fig. 67]).
b. Gonidial tissue. In most species of Cladoniaceae, a layer of gonidial tissue forms a more or less continuous outer covering of the podetium, thus distinguishing it from the purely hyphal stalks of the apothecia in Caliciaceae. Even in the genus Baeomyces, while the podetia of some of the species are without gonidia, neighbouring species are provided with green cells on the upright stalks clearly showing their true affinity with the Cladoniae. In one British species of Cladonia (Cl. caespiticia) the short podetium consists only of the fibrous chondroid cylinder, and thus resembles the apothecial stalk of Baeomyces rufus, but in that species also there are occasional surface gonidia that may give rise to squamules.
Fig. 67. Cladonia squamosa Hoffm. Vertical section of podetium with early stage of central tube and of podetial squamules × 100 (after Krabbe).
Krabbe[394] concluded from his observations that the podetial gonidia of Cladonia arrived from the open, conveyed by wind, water or insects from the loose soredia that are generally so plentiful in any Cladonia colony. They alighted, he held, on the growing stalks and, being secured by the free-growing ends of the exterior hyphae, they increased and became an integral part of the podetium. In more recent times Baur[395] has recalled and supported Krabbe’s view, but Wainio[396], on the contrary, claims to have proved that in the earliest stages of the podetium the gonidia were already present, having been carried up from the gonidial zone of the primary thallus by the primordial hyphae. Increase of these green cells follows normally by cell-division or sporulation.
Algal cells have been found to be common to different lichens, but in Cladoniae Chodat[397] claims to have proved by cultures that each species tested has a special gonidium, determined by him as a species of Cystococcus, which would render colonization by algae from the open much less probable. In addition, the fungal hyphae are specific, and any soredia (with their combined symbionts) that alighted on the podetium could only be utilized if they originated from the same species; or, if they were incorporated, the hyphae belonging to any other species would of necessity die off and be replaced by those of the podetium.
c. Cortical tissue. In some species a cortex of the decomposed type of thick-walled conglutinate hyphae is present, either continuous over the whole surface of the podetium, as in Cl. gracilis ([Fig. 68]), or in interrupted areas or granules as in Cl. pyxidata ([Fig. 69]) and others. In Cl. degenerans, the spaces between the corticated areolae are filled in by loose filaments without any green cells. Cl. rangiferina, Cl. sylvatica, etc. are non-corticate, being covered all over with a loose felt of intricate hyphae.
Fig. 68. Cladonia gracilis Hoffm. (S. H., Photo.).
Fig. 69. Cladonia pyxidata Hoffm. (S. H., Photo.).
In the section Clathrinae (Cl. retepora, etc.) the cortex is formed of longitudinal hyphae with thick gelatinous walls.
d. Soredia. Frequently the podetium is coated in whole or in part by granules of a sorediate character—coarsely granular in Cl. pyxidata, finely pulverulent in Cl. fimbriata. Though fairly constant to type in the different species, they are subject to climatic influences, and, when there is abundant moisture, both soredia and areolae develop into squamules on the podetium. A considerable number of species have thus a more or less densely squamulose “form” or “variety.”
C. Development of the Scyphus
Two types of podetia occur in Cladonia: those that end abruptly and are crowned when fertile by the apothecia or spermogonia (pycnidia), or if sterile grow indefinitely tapering gradually to a point ([Fig. 70]); and those that widen out into the trumpet-shaped or cup-like expansion called the scyphus ([Fig. 69]). Species may be constantly scyphiferous or as constantly ascyphous; in a few species, and even in individual tufts, both types of podetium may be present.
Fig. 70. Cladonia furcata Schrad. Sterile thallus (S.H., Photo.).
Wainio[398], who has studied every stage of development in the Cladoniae, has described the scyphus as originating in several different ways:
a. From abortive Apothecia. In certain species the apothecium appears at a very early stage in the development of the podetium of which it occupies the apical region. Owing to the subsequent formation of the tubular cavity in the centre of the stalk, the base of the apothecium may eventually lie directly over the hollow space and, therefore, out of touch with the growing assimilating tissues; or even before the appearance of the tube, the wide separation between the primordium of the apothecium and the gonidia, entailing deficient nutrition, may have produced a similar effect. In either case central degeneration of the apothecium sets in, and the hypothecial filaments, having begun to grow radially, continue to travel in the same direction both outwards and upwards so that gradually a cup-shaped structure is evolved—the amphithecium of the fruit without the thecium.
The whole or only a part of the apothecium may be abortive, and the scyphus may therefore be entirely sterile or the fruits may survive at the edges. The apothecia may even be entirely abortive after a fertile commencement, but in that case also the primordial hyphae retain the primitive impulse not only to radial direction, but also to the more copious branching, and a scyphus is formed as in the previous case. It must also be borne in mind that the tendency in many Cladonia species to scyphiform has become hereditary.
Baur[399], in his study of Cl. pyxidata, has taken the view that the origin of the scyphus was due to a stronger apical growth of the hyphae at the circumference than over the central tubular portion of the podetium, and that considerable intercalary growth added to the expanding sides of the cup.
Scyphi originating from an abortive apothecium are characteristic of species in which the base is closed (Wainio’s Section Clausae), the tissue in that case being continuous over the inside of the cup as in Cl. pyxidata, Cl. coccifera and many others.
b. From polytomous Branching. Another method of scyphus formation occurs in Cl. amaurocrea and a few other species in which the branching is polytomous (several members rising from about the same level). Concrescence of the tissues at the base of these branches produces a scyphus; it is normally closed by a diaphragm that has spread out from the different bases, but frequently there is a perforation due to stretching. These species belong to the Section Perviae.
c. From arrested Growth. In most cases however where the scyphus is open as in Cl. furcata, Cl. squamosa, etc., development of the cup follows on cessation of growth, or on perforation at the summit of the podetium. Round this quiescent portion there rises a circle of minute prominences which carry on the apical development. As they increase in size, the spaces between them are bridged over by lateral growth, and the scyphus thus formed is large or small according to the number of these outgrowths. Apothecia or spermogonia may be produced at their tips, or the vegetative development may continue. Scyphi formed in this manner are also open or “pervious.”
d. Gonidia of the Scyphus. Gonidia are absent in the early stages of scyphus formation when it arises from degeneration of the apical tissues, either fertile or vegetative; but gradually they migrate from the podetium, from the base of young outgrowths, or by furrows at the edge, and so spread over the surface of the cup. Soredia may possibly alight, as Krabbe insists that they do, and may aid in colonizing the naked area. Their presence, however, would only be accidental; they are not essential, and scyphi are formed in many non-sorediate species such as Cl. verticillata. The cortex of the scyphus becomes in the end continuous with that of the podetium and is always similar in type.
e. Species without Scyphi. In species where the whole summit of the podetium is occupied by an apothecium, as in Cl. bellidiflora, no scyphus is formed. There is also an absence of scyphi in podetia that taper to a point. In those podetia the hyphae are parallel to the long axis and remain in connection with the external gonidial layer so that they are unaffected by the central cavity. Instances of tapering growth are also to be found in species that are normally scyphiferous such as Cl. fimbriata subsp. fibula, and Cl. cornuta, as well as in species like Cl. rangiferina that are constantly ascyphous.
The scyphus is considered by Wainio[400] to represent an advanced stage of development in the species or in the individual, and any conditions that act unfavourably on growth, such as excessive dryness, would also hinder the formation of this peculiar lichen structure.
D. Branching of the Podetium
Though branching is a constant feature in many species, regular dichotomy is rare: more often there is an irregular form of polytomy in which one of the members grows more vigorously than the others and branches again, so that a kind of sympodium arises, as in Cl. rangiferina, Cl. sylvatica, etc.
Adventitious branches may also arise from the podetium, owing to some disturbance of the normal growth, some undue exposure to wind or to too great light, or owing to some external injury. They originate from the gonidial tissue in the same way as does the podetium from the primary thallus; the parallel hyphae of the main axis take no part in their development.
In a number of species secondary podetia arise from the centre of the scyphus—constantly in Cl. verticillata and Cl. cervicornis, etc., accidentally or rarely in Cl. foliacea, Cl. pyxidata, Cl. fimbriata, etc. Wainio[401] has stated that they arise when the scyphus is already at an advanced stage of growth and that they are to be regarded as adventitious branches.
The proliferations from the borders of the scyphus are in a different category. They represent the continuity of apical growth, as the edges of the scyphus are but an enlarged apex. These marginal proliferations thus correspond to polytomous branching. In many instances their advance is soon stopped by the formation of an apothecium and they figure more as fruit stalks than as podetial branches.
E. Perforations and Reticulation of the Podetium
Perforations in the podetial wall at the axils of the branches are constant in certain species such as Cl. rangiferina, Cl. uncialis, etc. They are caused by the tension of the branches as they emerge from the main stalk. A tearing of the tissue may also arise in the base of the scyphus, due to its increase in size, which causes the splitting of the diaphragm at the bottom of the cup.
Among the Cladoniae the reticulate condition recurs now and again. In our native Cladonia cariosa the splitting of the podetial wall is a constant character of the species, the carious condition being caused by unequal growth which tears apart the longitudinal fibres that surround the central hollow.
A more advanced type of reticulation arises in the group of the Clathrinae in which there is no inner chondroid cylinder. In Cladonia aggregata, in which the perforations are somewhat irregular, two types of podetia have been described by Lindsay[402] from Falkland Island specimens: those bearing apothecia are short and broad, fastigiately branched upwards and with reticulate perforations, while podetia bearing spermogonia are slender, elongate and branched, with fewer reticulations. An imperfect network is also characteristic of Cl. Sullivani, a Brazilian species. But the most marvellous and regular form of reticulation occurs in Cl. retepora, an Australian lichen ([Fig. 71]): towards the tips of the podetia the ellipsoid meshes are small, but they gradually become larger towards the base. In this species the outer tissue, though of parallel hyphae, is closely interwoven and forms a continuous growth at the edges of the perforations, giving an unbroken smooth surface and checking any irregular tearing. The enlargement of the walls is solely due to intercalary growth. The origin of the reticulate structure in the Clathrinae is unknown, though it is doubtless associated with wide podetia and rendered possible by the absence of an internal chondroid layer. The reticulate structure is marvellously adapted for the absorption of water: Cl. retepora, more especially, imbibes and holds moisture like a sponge.
Fig. 71. Cladonia retepora Fr. From Tasmania.
F. Rooting Structures of Cladoniae
The squamules of the primary thallus are attached, as are most squamules, to the supporting substance by strands of hyphae which may be combined into simple or branching rhizinae and penetrate the soil or the wood on which the lichen grows. There is frequently but one of these rooting structures and it branches repeatedly until the ultimate branchlets end in delicate mycelium. Generally they are grey or brown and are not easily traced, but when they are orange-coloured, as according to Wainio[403] they frequently are in Cladonia miniata and Cl. digitata, they are more readily observed, especially if the habitat be a mossy one.
In Cl. alpicola it has been found that the rooting structure is frequently as thick as the podetium itself. If the podetium originates from the basal portion of the squamule, the hyphae from the chondroid layer, surrounding the hollow centre, take a downward direction and become continuous with the rhizoid. Should the point of insertion be near the apex of the squamule, these hyphae form a nerve within the squamule or along the under surface, and finally also unite with the rhizoid at the base, a form of rooting characteristic of Cl. cartilaginea, Cl. digitata and several other species.
Mycelium may spread from the rhizinae along the surface of the substratum and give rise to new squamules and new tufts of podetia, a method of reproduction that is of considerable importance in species that are generally sterile and that form no soredia.
Many species, especially those of the section Cladina, soon lose all connection with the substratum, there being a continual decay of the lower part of the podetia. As apical growth may continue for centuries, the perishing of the base is not to be wondered at.
G. Haptera
The presence of haptera in Cladoniae has already been alluded to. They occur usually in the form of cilia or rhizinae[404], but differ from the latter in their more simple regular growth being composed of conglutinate parallel hyphae. They arise on the edges of the squamules or of the scyphus, but in Cl. foliacea and Cl. ceratophylla they are formed at the points of the podetial branches (more rarely in Cl. cervicornis and Cl. gracilis). By the aid of these rhizinose haptera the squamule or branch becomes attached to any substance within reach. They also aid in the production of new individuals by anchoring some fragment of the thallus to a support until it has grown to independent existence and has produced new rhizinae or hold-fasts. They are a very prominent feature of Cl. verticillaris f. penicillata in which they form a thick fringe on the edges of the squamules, or frequently grow out as branched cilia from the proliferations on the margins of the scyphus.
H. Morphology of the Podetium
In the above account, the podetia have been treated as part of the vegetative thallus, seeing that, partly or entirely, they are assimilative and absorptive organs. This view does not, however, take into account their origin and development, in consideration of which Wainio[405] and later Krabbe[406] considered them as part of the sporiferous organ. This view was also held by some of the earliest lichenologists: Necker[407], for instance, constantly referred to the upright structure as “stipes”; Persoon[408] included it, under the term “pedunculus,” as part of the “inflorescence” of the lichen, and Acharius[409] established the name “podetium” to describe the stalk of the apothecium in Baeomyces.
Later lichenologists, such as Wallroth[410], looked on the podetia as advanced stages of the thallus, or as forming a supplementary thallus. Tulasne[411] described them as branching upright processes from the horizontal form, and Koerber[412] considered them as the true thallus, the primary squamule being merely a protothallus. By them and by succeeding students of lichens the twofold character of the thallus was accepted until Wainio and Krabbe by their more exact researches discovered the endogenous origin of the podetium, which they considered was conclusive evidence of its apothecial character: they claimed that the primordium of the podetium was homologous with the primordium of the apothecium. Reinke[413] and Wainio are in accord with Krabbe as to the probable morphological significance of the podetium, but they both insist on its modified thalline character. Wainio sums up that: “the podetium is an apothecial stalk, that is to say an elongation of the conceptacle most frequently transformed by metamorphosis to a vertical thallus, though visibly retaining its stalk character.” Sättler[414], one of the most recent students of Cladonia, regards the podetium as evolved with reference to spore-dissemination, and therefore of apothecial character. His views are described and discussed in the chapter on phylogeny.
Reinke and others sought for a solution of the problem in Baeomyces, one of the more primitive genera of the Cladoniaceae. The thallus, except in a few mostly exotic species, scarcely advances beyond the crustaceous condition; the podetia are short and so varied in character that species have been assigned by systematists to several different genera. In one of them, Baeomyces roseus, the podetium or stalk originates according to Nienburg[415] deep down in the medulla of a fertile granule as a specialized weft of tissue; there is no carpogonium nor trichogyne formed; the hyphae that grow upward and form the podetium are generative filaments and give rise to asci and paraphyses. In a second species, B. rufus (Sphyridium), the gonidial zone and outer cortex of a thalline granule swell out to form a thalline protuberance; the carpogonium arises close to the apex, and from it branch the generative filaments. Nienburg regards the stalk of B. roseus as apothecial and as representing an extension of the proper margin[416] (excipulum proprium), that of B. rufus as a typical vegetative podetium.
In the genus Cladonia, differentiation of the generative hyphae may take place at a very early stage. Wainio[417] observed, in Cl. caespiticia, a trichogyne in a still solid podetium only 90µ in height; usually they appear later, and, where scyphi are formed, the carpogonium often arises at the edge of the scyphus. Baur[418] and Wolff[419] have furnished conclusive evidence of the late appearance of the carpogonium in Cl. pyxidata, Cl. degenerans, Cl. furcata and Cl. gracilis: in all of these species carpogonia with trichogynes were observed on the edge of well-developed scyphi. Baur draws the conclusion that the podetium is merely a vertical thallus, citing as additional evidence that it also bears the spermogonia (or pycnidia), though at the same time he allows that the apothecium may have played an important part in its phylogenetic development. He agrees also with the account of the first appearance of the podetium as described by Krabbe, who found that it began with the hyphae of the gonidial zone branching upwards in a quite normal manner, only that there were more of them, and that they finally pierced the cortex. Krabbe also asserted that in the early stages the podetia were without gonidia and that these arrived later from the open as colonists, in this contradicting Wainio’s statement that gonidia were carried up from the primary thallus.
It seems probable that the podetium—as Wainio and Baur both have stated—is homologous with the apothecial stalk, though in most cases it is completely transformed into a vertical thallus. If the view of their formation from the gonidial zone is accepted, then they differ widely in origin from normal branches in which the tissues of the main axis are repeated in the secondary structures, whereas in this vertical thallus, hyphae from the gonidial zone alone take part in the development. It must be admitted that Baur’s view of the podetium as essentially thalline seems to be strengthened by the formation of podetia at the centre of the scyphus, as in Cl. verticillata, which are new structures and are not an elongation of the original conceptacular tissue. It can however equally be argued that the acquired thalline character is complete and, therefore, includes the possibility of giving rise to new podetia.
The relegation of the carpogonium to a position far removed from the base or primordium of the apothecium need not necessarily interfere with the conception of the primordial tissue as homologous with the conceptacle; but more research is needed, as Baur dealt only with one species, Cl. pyxidata, and Gertrude Wolff confined her attention to the carpogonial stages at the edge of the scyphus.
The Cladoniae require light, and inhabit by preference open moorlands, naked clay walls, borders of ditches, exposed sand-dunes, etc. Those with large and persistent squamules can live in arid situations, probably because the primary thallus is able to retain moisture for a long time[420]. When the primary thallus is small and feeble the podetia are generally much branched and live in close colonies which retain moisture. Sterile podetia are long-lived and grow indefinitely at the apex though the base as continually perishes and changes into humus. Wainio[421] cites an instance in which the bases of a tuft of Cl. alpestris had formed a gelatinous mass more than a decimetre in thickness.
I. Pilophorus and Stereocaulon
These two genera are usually included in Cladoniaceae on account of their twofold thallus and their somewhat similar fruit formation. They differ from Cladonia in the development of the podetia which are not endogenous in origin as in that genus, but are formed by the growth upwards of a primary granule or squamule and correspond more nearly to Tulasne’s conception of the podetium as a process from the horizontal thallus. In Pilophorus the primary granular thallus persists during the life of the plants; the short podetium is unbranched, and consists of a somewhat compact medulla of parallel hyphae surrounded by a looser cortical tissue, such as that of the basal granule, in which are embedded the algal cells. The black colour of the apothecium is due to the thick dark hypothecium.
Stereocaulon is also a direct growth from a short-lived primary squamule[422]. The podetia, called “pseudopodetia” by Wainio, are usually very much branched. They possess a central strand of hyphae not entirely solid, and an outer layer of loose felted hyphae in which the gonidia find place. A coating of mucilage on the outside gives a glabrous shiny surface, or, if that is absent, the surface is tomentose as in St. tomentosum. In all the species the podetia are more or less thickly beset with small variously divided squamules similar in form to the primary evanescent thallus. Gall-like cephalodia are associated with most of the species and aid in the work of assimilation.
Stereocaulon cannot depend on the evanescent primary thallus for attachment to the soil. The podetia of the different species have developed various rooting bases: in St. ramulosum there is a basal sheath formed, in St. coralloides a well-developed system of rhizoids[423].