OBSERVATIONS ON CHYTRIDIACEOUS PARASITES OF PHANEROGAMS. XXV. PHYSODERMA JOHNSII SPARROW,A PARASITE OF CALTHA PALUSTRIS L.

The morphology of the endobiotic and epibiotic stages of Physoderma johnsii Sparrow on Caltha palustris is described. Highly characteristic of the endobiotic stage is the formation of numbers of large, narrowly pyriform cells with a tuft of rhizoids at the broader (distal) end. Early developmental features are not included since germination of the resting spore has not as yet been achieved. Reasons for maintaining this taxon distinct from older ones on Caltha palustris are given.     

Pegged and smooth rhizoids in complex thalloid liverworts (Marchantiopsida): structure,function and evolution

Rhizoids played essential roles in the early evolution of land plants. All liverworts, the closest living relatives of the first land plants, produce unicellular rhizoids, except for Haplomitrium. The complex thalloids are uniquely characterized by dimorphic rhizoids: smooth rhizoids like those also produced by the simple thalloid and leafy clades and pegged rhizoids. Although this dimorphism has been long and widely recognized, considerations of its functional basis are few and contradictory. Here we present conclusive cytological and experimental evidence that the function of smooth and pegged rhizoids is markedly different, as reflected by major differences in their structure, physiology and vital status. Mature smooth rhizoids are alive (indeed their main functions in nutrition, anchorage and as conduits for mycobiont entry all depend on living cytoplasm) and dehydration causes irreversible collapse of their cell walls, but pegged rhizoids, which are dead at maturity, function as a highly effective internalized external water‐conducting system, especially within carpocephala. Their cavitation‐resistant, elastic walls ensure retention of functional integrity during periods of desiccation. Our structural and functional data now raise novel hypotheses on patterns of rhizoid evolution in Marchantiopsida and open the way for dissecting the molecular basis of rhizoid morphogenesis in liverworts. © 2013 The Linnean Society of London, Botanical Journal of the Linnean Society, 2014, 174 , 68–92.     

AN ULTRASTRUCTURAL STUDY OF THE GIANT GREEN ALGAL COENOCYTE, CAULERPA PROLIFERA

The general fine structure of the giant coenocyte Caulerpa prolifera (Forsskål) Lamouroux is presented. The cytoplasm forms a parietal layer throughout the plant without any regular membranous separations within organs or between organs. The vacuome is similar in structure. There are distinct patterns of organelle distribution in the highly polar cytoplasm of rhizoids and blades. The organelles are compared to those of other members of the division Chlorophyta and are typical. Amyloplast structure is compared to that of chloroplasts. A possible developmental sequence from chloroplast buds through an unusual circular body is suggested.     

Staining and osmotic properties of young gametophytes ofPolypodium vulgare L. and their bearing on rhizoid function

Summary The rhizoids of gametophytes ofPolypodium vulgare L. rapidly absorb vital stains whereas the protonemal cells are impermeable to these stains, which can only enter the cells from the rhizoids. The protonemal cells which bear rhizoids were found to have a slightly higher osmotic equivalent than did the rhizoids or the protonemal cells on either side. From the results of several staining procedures it was demonstrated that the rhizoid walls contain free carboxyl groups and thus possess cation exchange properties. Most of the carboxyl groups are probably present in a yellow-brown wall matrix substance, which shows high resistance to acid and alkali extraction. The precise nature of this substance has not been determined but it could be an acid mucopolysaccharide. Carboxyl groups are detectable in the protonemal cell walls only after saponification and are probably esterified in the untreated wall. Several other chemical and physiological differences were found between the rhizoids and the protonemal cells and it was concluded that the specific properties of the rhizoids are related to their function as organs of uptake.     

APOLAR EMBRYOS OF FUCUS RESULTING FROM OSMOTIC AND CHEMICAL TREATMENT

Embryos of the brown alga Fucus vesiculosas L. were grown as populations in glass petri dishes in seawater at 15 C in continuous low-intensity unilateral fluorescent illumination for periods up to 2 weeks. A quantitative estimate of increase in nuclear number was made from acetocarmine squash preparations of samples taken at 12-or-24 hr intervals. Over the period of 2-6 days embryos showed a doubling time of about 12-18 hr. Under normal seawater culture conditions each embryo formed a single rhizoid. When grown in seawater supplemented with sugar concentrations above 0.4 m , Fucus embryos developed as multicellular spherical embryos lacking rhizoids. In 0.6 m sucrose-seawater, 97% of the embryos were apolar at 2 days; only 37% were apolar at 4 days, many having recovered from the sucrose inhibition. Some embryos remained apolar after growth in 0.6 m sucrose for 2 weeks. Nuclear counts showed that sucrose-seawater markedly inhibited the rate of cell division. Other sugars including D-glucose, D-fructose, D-galactose and the sugar alcohol D-mannitol were also effective. When apolar embryos grown in sucrose-seawater were returned to seawater, embryo growth resumed at the normal seawater rate, judged from nuclear counts. Such embryos formed multiple rhizoids, varying from two to eight rhizoids per embryo, which developed on the embryo quadrant or half away from the unilateral light. Each of the multiple rhizoids originated from a single small cell in the periphery of the multicellular spherica embryo. Thus the rhizoid-forming stimulus apparently had been subdivided among a number of the cells of the apolar embryos. The implications of this finding are discussed. Attempts to produce multiple rhizoids by treatment of embryos with indoleacetic acid or 2,4-dichlorophen-oxyacetic acid failed. However, embryos treated with 10⁻⁴ M or 5 × 10⁻⁵ m 2,3,5-triiodobenzoic acid formed 40 and 30% multiple rhizoids, respectively, suggesting that some chemical, perhaps hormonal, mechanism is involved in polarization and rhizoid initiation in Fucus embryogenesis.     

Orientation and righting behavior of the sand‐dwelling bryozoan Conescharellina catella

Most bryozoan colonies live firmly attached to hard surfaces, but some species live on sandy or muddy bottoms, anchored to the substratum by one or more rhizoids. The small, conical colonies of members of the genus Conescharellina live attached to the substratum by several rhizoids, each produced by a modified, non‐feeding zooid (kenozooid). It was previously thought that these colonies lived prone on the substratum, anchored but not supported by the rhizoids. In this study, I observed the behavior of a living colony of Conescharellina catella collected from the East China Sea and maintained in the laboratory for 2 months. The colony lived apex down, suspended above the substratum by several rhizoids arising in the apical two‐fifths of the colony, to a total height of nearly five times colony height. Starting from an uprooted position lying on the substratum, the colony reattached and righted itself to the erect position using existing or newly produced rhizoids. After I removed all rhizoids, the colony was able to right itself only after it regenerated rhizoids. In each of several series of observations, righting behavior involved similar steps and followed a similar time course, and it can thus be considered a stereotypical behavior. Histological sections showed that the rhizoids lack muscles. I speculate that righting is effected by differential turgor (internal pressure) and differential growth of rhizoids originating from kenozooids in different positions around the central colony axis, although it is unclear how the colony senses orientation and coordinates adjustments to achieve the preferred orientation.     

Obtaining plantlets from apical meristem of the red alga Gelidium sp.

For the first time, plantlets were obtained from fragments and cell aggregates (CA) of apical meristem of the red alga Gelidium sp. After two months of cultivation, an initial weight of 100 mg of fragments and CA from fresh meristem produced 3 g of plantlets without rhizoids. During the same period of cultivation, 100 mg of meristem fragments and CA isolated from thalli by the freezing-thawing procedure produced more than 20 g of plantlets with rhizoids. It is assumed that our methods for obtaining plantlets from fragments and CA of fresh and frozen-thawed meristem could be used to generate mass planting material for cultivation of algae (plantlets with rhizoids) in the sea and for tank-bubbling cultivation (plantlets without rhizoids). We speculate that meristem cells of frozen-thawed algae might be natural “seedstock” in the Arctic and Antarctic seas.     

NORTH CAROLINA MARINE ALGAE. XI. A NEW SPECIES OF HELMINTHOCLADIA (LIAGORACEAE,NEMALIALES, RHODOPHYTA) WITH A REAPPRAISAL OF THE GENERIC LIMITS OF HELMINTHOCLADIA AND HELMINTHORA1

A new species in the Liagoraceae (Nemaliales) having vegetative and male reproductive characteristics usually associated with the genus Helminthora is assigned to Helminthocladia (as Helminthocladia andersonii Searles & Lewis) on the basis of the shape of the conical carpogonial protoplast, three-celled carpogonial filament, development of the carposporophyte from both cells formed by division of the zygote and development of the involucre without the formation of a bridge around the zygote or formation of rhizoids from the involucre. All of these are consistent characteristics of Helminthocladia and distinguish its species from those of Helminthora.     

OBSERVATIONS ON CHYTRIDIACEOUS PARASITES OF PHANEROGAMS. XIV. PHYSODERMA CALAMI

Physoderma calami, a chytrid (Phycomycetes), has not been studied or apparently even collected in Europe since 1895 and has never been recorded in this hemisphere. Material widely distributed in herbaria indicated it was a Physoderma but no details save color, shape, and size of resting spores were known. A study of living material from Vermont indicates resting spore germination occurs by dehiscence of a lid and production of a sporangium with zoospores. The latter may form either an epibiotic or “ephemeral” sporangial stage and zoospores, or an endobiotic one, with extensive polycentric thallus bearing turbinate cells along the rhizoids, and, as outgrowths of these turbinate cells, straw-colored, thick-walled resting spores. The latter stage produces dark-brown spots on infected parts of the host.     

Forced calcium entry and polarized growth of Funaria spores

We have used both steady electric fields, and gradients of the divalent ionophore, A23187, to control the point at which rhizoids emerge from spores of the common moss Funaria hygrometrica. The spores were grown in a medium containing calcium nitrate as the only major salt. Spores tend to form rhizoids towards the positive electrode, with a half maximal response to a difference of 4–8 mV across each cell. They also tend to form rhizoids towards the end of higher ionophore concentration in response to A23187 gradients. Both of these responses are the same at pH 5.5 and 8.0. Our tentative explanation is that Funaria spores tend to form rhizoids where most calcium enters. However, the point of chloronema emergence is scarcely affected by steady fields of up to 45 mV/cell. Moreover, when steady fields are applied across already developed rhizoids or chloronemata, their subsequent growth is directed towards the negative electrode in both cases, with rhizoids giving a 50% response at only 3—5 mV/cell, and chloronemata being less responsive.From Tsung-Hsien Chen's Ph.D. thesis, Purdue University     

Growth and Dormancy in Lunularia cruciata (L.) Dum.: IV. LIGHT AND TEMPERATURE CONTROL OF RHIZOID FORMATION IN GEMMAE

The first sign of initiation of growth in dormant gemmae ofL. cruciata is the formation of rhizoids. Gemmae in the cupcannot ‘germinate‘ until exposed to substrate conditionsallowing the outward diffusion of a growth inhibitor. Rhizoidproduction depends on temperature and light. With long lightperiods rhizoids are formed over a wide range of temperatures.Transference to darkness after 2 h white light causes about50 per cent of gemmae to produce rhizoids, and these are formedonly between 20 and 25 °C. Outside these temperature limitsthe percentage of gemmae with rhizoids soon drops to zero. Althoughrhizoid production is prevented in total darkness, gemmae remainalive for well over 6 months. Red light for as little as 5 spromoted, and far-red light inhibited, rhizoid formation inthe dark. Coumarin and indol-3yl-acetic acid can substitutefor light and partly reverse the effect of far-red irradiation.     

Identification of two putative adhesive polypeptides in Caulerpa prolifera rhizoids using an adhesion model system

The rhizoid section of the green alga Caulerpa prolifera (Cp) is active in attaching the developing plant to the substratum. A model system for the study of the adhesion of Cp rhizoids has been developed and identification of two putative adhesive polypeptides of Caulerpa (Vn-Cp) was revealed by immunodetection. A method for fast induction of new rhizoids was established using blade-base cutting followed by a few days of incubation. The new rhizoids were gently enclosed between two cover glasses and incubated until firm attachment developed. While analyzing protein extracts, two ∼60–70 kDa polypeptides (Vn-Cp I and Vn-Cp II) were identified by immunodetection with monoclonal antibodies to human vitronectin (Vn). The relative concentration values of the Vn-Cp proteins increased significantly in the ‘cell-wall’ fraction of the attached rhizoids during the incubation period. However, Vn-Cp proteins were not detected in non-attached rhizoids. Furthermore, the Vn-Cp proteins were also detectable on glass substratum subsequent to attached rhizoid removal. The induction and accumulation of Vn-Cp proteins on the ‘cell-wall’ of Caulerpa rhizoids and the firm attachment of the rhizoids to the glass substratum during the incubation period suggest that Vn-Cp proteins play a significant role in adhesion, which may be similar to the function of vitronectin in other adhesion systems. Furthermore, the high accumulation of Vn-Cp proteins on the glass substratum during attachment of new rhizoids suggests that the Vn-Cp proteins are secreted to the extracellular matrix and directly connect rhizoids to the glass substratum as an intermediate compound. These unique properties of Cp make it an excellent model system for the establishment of high amounts of adhesive material for future research. This revised version was published online in August 2006 with corrections to the Cover Date.     

MORPHOLOGY, REPRODUCTION, AND THE 18S rRNA GENE SEQUENCE OF PIHIELLA LIAGORACIPHILA GEN. ET SP. NOV. (RHODOPHYTA), THE SO-CALLED 'MONOSPORANGIAL DISCS' ASSOCIATED WITH MEMBERS OF THE LIAGORACEAE (RHODOPHYTA), AND PROPOSAL OF THE PIHIELLALES ORD. NOV.

Pihiella liagoraciphila gen. et sp. nov. (Rhodophyta) is described for a minute endo/epiphyte that is commonly associated with members of the Liagoraceae ( Nemaliales, Rhodophyta). Algae are discoid or subspherical and grow to a maximum diameter of 400 μm. Attachment is via isolated elongate rhizoids that penetrate into the loosely filamentous structure of the host or by a pad of several coalesced rhizoids where the host has a more cohesive cortex. Elongate surface hairs are common. Gametophytes are dioecious, the spermatangia arising on surface cells, and carpogonia with elongate trichogynes borne directly on undifferentiated surface supporting cells. Large sporangia form on stalk cells across the upper surface of the plants, these appearing to be either monosporangial or the result of fertilization of the carpogonia and equivalent to undivided zygotosporangia. Carposporophytes and tetrasporangia are unknown. 18S rRNA gene sequence analyses indicate that Pihiella constitutes a clade of long branch length most closely related to the Ahnfeltiales. The unique morphology and reproduction of Pihiella , combined with a substantial genetic divergence from the Ahnfeltiales, suggest that it is sufficiently distinct to warrant placement in a new family and order. We therefore describe the family Pihiellaceae and the order Pihiellales to accommodate the new genus.     

Microtubules,organelle movement,and cross-wall formation at the sporangial-rhizoidal interface in the fungus,Chytridium confervae

Summary Chytridium confervae is a eucarpic, monocentric chytrid. We have used light and electron microscopy to study the relationship between the nutrient absorbing rhizoids and the asexually reproductive sporangium during growth. We have also examined the induction of zoosporogenesis by starvation, and subsequent differentiation until zoospore release. During growth the cytoplasm of the rhizoids and the developing sporangium was continuous and similar. At the start of starvation a bundle of fibers that were visible with light microscopy appeared at the junction between the rhizoids and the sporangium. Two hours after initiation of starvation a wall, that was also visible with light microscopy, formed to separate the rhizoids from the sporangium. Electron microscopy revealed a large, ordered array of microtubules in the thallus at the same time that the fibers appeared, and a sharp difference in the density of ribosomes in the cytoplasm of the sporangium and that of the rhizoids that was apparent immediately after starvation. This cytoplasmic difference was preserved by the formation of a cross-wall that was penetrated by plasmodesmata. After the wall was formed the cytoplasm of the rhizoids senesced. Comparison ofC. confervae with other organisms that use arrays of microtubules to move organelles is made and speculation on the role of the microtubules in organelle movement and wall formation inC. confervae is offered.     

THE GAMETOPHYTES OF OPHIOGLOSSUM PALMATUM L.

Gametophytes of the epiphytic species Ophioglossum palmatum L. are described for the first time, bringing the number of Ophioglossum species with known gametophytes to 11. Although somewhat unusual in terms of (a) degree of branching, (b) the marked expansion of the basically cylindrical axis in some cases, and (c) production of stout, papilla-like rhizoids, the gametophytes of O. palmatum are more similar to other Ophioglossum gametophytes than they are to the gametophytes of Botrychium or Helminthostachys. Gametophyte characters do not provide strong evidence for placing O. palmatum into a separate genus, viz., Cheiroglossa. The gametophytes of O. palmatum most closely resemble those of the other epiphytic species in the genus, O. pendulum. This similarity suggests a need for a revaluation of modern taxonomies which, in general, treat the two species as only distantly related.     

Limited period of graviresponsiveness in germinating spores of Ceratopteris richardii

Rhizoids of the fern Ceratopteris richardii Brogn. usually emerge 40 h after germination is initiated by light, and more than 90% of them emerge growing in a downward direction. However, when the spores are germinated on a clinostat, the emerging rhizoids show no preferential orientation. This indicates that under normal 1 · g conditions the initial growth direction of rhizoids can be oriented by gravity. If the orientation of the spores is changed 3 h or less after the start of germination, the growth direction of most emerging rhizoids becomes downward relative to the new orientation. However, if the orientation of the spores is changed by 180° 8 h or more after germination is initiated by light, most rhizoids emerge growing upward; i.e., the same direction as if there had been no orientation change. Emerged rhizoids also do not change their direction of growth if their orientation is changed. These results indicate that the growth direction of emerging rhizoids is set by gravity prior to actual emergence, and that the time of full orientation responsiveness is limited to a period ranging from the initiation of germination to about 3–4 h after the start of germination. There is a gravity-oriented nuclear movement beginning at about 13 h after germination, and this movement appears to predict the initial growth direction of rhizoids.These studies were made possible by grant NAGW 1519 to S.J.R. and grant NGT-51065 to E.S.E., both from the National Aeronautics and Space Administration.     

光照对蕨类植物配子体假根向重力性的影响

对８种蕨类植物配子体假根向重力性反应的研究结果表明,除卷柏Ｓｅｌａｇｉｎｅｌｌａ ｔａｍａｒｉｓｃｉｎａ Ｓｐｒｉｎｇ配子体假根无向重力性反应并且其生长方向与光照方向无关外,其它７种的配子体假根均有向重力性反应,并且假根的向重力性反应在配子体发育初期,因光照的方向不同而异,表现为负向光性。随着配子体发育至片状体阶段,光对其向重力性反应的影响逐渐减弱,而重力的影响增强。在蕨类植物配子体发育初期,光对     

THE EFFECT OF HYDROGEN ION CONCENTRATION UPON THE INDUCTION OF POLARITY IN FUCUS EGGS : I. INCREASED HYDROGEN ION CONCENTRATION AND THE INTENSITY OF MUTUAL INDUCTIONS BY NEIGHBORING EGGS OF FUCUS FURCATUS

1. The eggs of Fucus furcatus develop perfectly in sea water acidified to pH 6.0. They are retarded at pH 5.5. At pH 5.0 they do not develop, nor do they cytolize. 2. In normal sea water in the dark at 15°C., eggs develop rhizoids on the sides in the resultant direction of a mass of neighboring eggs. The polarity and the whole developmental pattern of the embryo is thereby induced. This inductive effect does not operate, however, unless the directing mass is an appreciable aggregation of cells (10 or more), or unless there are numerous other eggs in the dish. A group of five eggs alone in a dish do not carry out mutual inductions. Two eggs alone in a dish do not develop rhizoids toward each other. 3. When the sea water is acidified to pH 6.0 all sizes of aggregations carry out mutual inductions. Two eggs alone in a dish now develop rhizoids on the sides toward each other, provided they are not more than about 4 egg diameters apart. 4. Increased hydrogen ion concentration thus augments or intensifies the mutual inductive effect. 5. This may explain why only larger masses of eggs show inductions in normal sea water, since presumably the larger masses considerably increase the hydrogen ion concentration locally. 6. The nature of the inductive action is discussed. 7. In acidified sea water at pH 6.0, compared with normal sea water at pH 7.8–8.0, the rhizoids originate and extend with a strongly increased downward component. The substrate then forces further extension or growth of the rhizoid to be in the plane of the substrate.     

Melanothamnus maniticola sp. nov. (Ceramiales,Rhodophyta): an epizoic species evolved for living on the West Indian Manatee

Over 35 macroalgae have been documented growing epizoically on sea turtles, and macroalgae are also known to grow on the West Indian Manatee, but the number and identity of these latter species have not been determined. Analysis of DNA sequences of 12 samples collected from different manatees captured in three areas of Florida indicated that they represented a single undescribed species within the Rhodomelaceae genus Melanothamnus. Morphological analysis revealed Melanothamnus characteristics but also a previously undescribed combination of character states. These include eight to nine, but as many as 11, pericentral cells; heavy cortication restricted to the base of thalli, and a sharp transition between the corticated and ecorticate sections of the thallus; cells surrounding the ostiole being similar in size to the outer pericarp cells immediately below, and robust rhizoids that have no terminal lobes and develop from central axial cell filaments instead of pericentral cells. The unique characteristics of the rhizoids may be evolutionary adaptations for anchoring the thalli to manatee epidermis. This species is described as M. maniticola sp. nov.     

槲蕨配子体形态发育的扫描电镜观察

该研究以水龙骨科(Polypodiaceae)槲蕨(Drynaria roosii Nakaike)为研究对象,在人工培养条件下,采用扫描电镜观察其配子体发育的全过程,以期从三维立体角度揭示槲蕨配子体各发育阶段中的一些精细结构,为进一步补充部分经典形态学理论提供依据。结果显示:(1)槲蕨孢子萌发过程中原叶体母细胞的初生假根存在两条同时生长的现象。(2)槲蕨配子体的假根膨大及分叉现象普遍,且具有2层细胞壁,基部呈圆孔状结构。(3)槲蕨的原叶体腹面及边缘处毛状体非常发达,且乳突状单细胞毛状体和针状单细胞毛状体混生。(4)精子器释放精子时,盖细胞前后呈不同开裂状态。(5)发现精细胞向游动精子转化可能的限制性结构是细胞膜,细胞膜表面附着有碎屑状物质。(6)观察到腹沟细胞的解体过程是从近颈卵器开口处的细胞膜开始逐渐向四周及其后下方扩展。(7)发现了颈壁细胞在排列顺序和数量上都不稳定的畸形颈卵器、体积正常但无法区分雌雄的性器及体积显著增大呈锥形的泡状败育性器。