Individual and Coupled Effects of Echinoderm Extracts and Surface Hydrophobicity on Spore Settlement and Germination in the Brown Alga Hincksia irregularis

Marine substrata possess cues that influence the behavior of fouling organisms. Initial adhesion of fouling algal zoospores to surfaces is also theorized to depend primarily upon interactions between substrata and spore cell bodies and flagellar membranes. In an effort to identify cues and surface characteristics that influence spore settlement and early development, the effects of bioactive echinoderm extracts, surface charge, and surface hydrophobicity were examined individually and in tandem on zoospore settlement and germination in Hincksia irregularis. Experiments utilizing 96-well plastic culture plates confirmed that spore settlement and germination were significantly affected by surface charge and hydrophobicity as well as by echinoderm metabolites, both individually and in tandem. Spore settlement rates in the dark over 30?min were >?400% higher on hydrophobic surfaces than on positively and negatively charged surfaces. Spore germling numbers were >?300% higher on hydrophobic surfaces than on positively and negatively charged surfaces when spores were allowed to settle in the light for 30?min and the settled spores allowed to subsequently germinate for 24?h. Spore germling numbers were consistently >?25% higher on hydrophobic surfaces than on positively and negatively charged surfaces when equal numbers of spores were allowed to completely settle in the light and subsequently germinate for 24?h. H. irregularis germ tube lengths were also significantly longer on positively charged plates than on negatively charged plates. All echinoderm extracts tested had significant effects on germination and settlement at levels below those of estimated ecological concentrations. Short-term (30?min) exposure and subsequent germination experiments indicated that higher concentrations of extracts had rapid toxic effects on algal spores. Synchronous effects of echinoderm extracts and plate charge upon spore settlement varied considerably and did not show a strong dose response relationship. Long-term (24?h) exposure of spores to echinoderm extracts had dosage dependent effects on germination and spore survival. The results of this study indicate that H. irregularis spores possess the capacity for complex responses to their environment, utilizing combined cues of surface charge, surface energy and biochemistry to determine where to settle and germinate. These responses may aid spores in the detection of suitable substrata and conditions for settlement in the marine environment.     

Individual and coupled effects of echinoderm extracts and surface hydrophobicity on spore settlement and germination in the brown alga Hincksia irregularis

Marine substrata possess cues that influence the behavior of fouling organisms. Initial adhesion of fouling algal zoospores to surfaces is also theorized to depend primarily upon interactions between substrata and spore cell bodies and flagellar membranes. In an effort to identify cues and surface characteristics that influence spore settlement and early development, the effects of bioactive echinoderm extracts, surface charge, and surface hydrophobicity were examined individually and in tandem on zoospore settlement and germination in Hincksia irregularis. Experiments utilizing 96-well plastic culture plates confirmed that spore settlement and germination were significantly affected by surface charge and hydrophobicity as well as by echinoderm metabolites, both individually and in tandem. Spore settlement rates in the dark over 30 min were > 400% higher on hydrophobic surfaces than on positively and negatively charged surfaces. Spore germling numbers were > 300% higher on hydrophobic surfaces than on positively and negatively charged surfaces when spores were allowed to settle in the light for 30 min and the settled spores allowed to subsequently germinate for 24 h. Spore germling numbers were consistently > 25% higher on hydrophobic surfaces than on positively and negatively charged surfaces when equal numbers of spores were allowed to completely settle in the light and subsequently germinate for 24 h. H. irregularis germ tube lengths were also significantly longer on positively charged plates than on negatively charged plates. All echinoderm extracts tested had significant effects on germination and settlement at levels below those of estimated ecological concentrations. Short-term (30 min) exposure and subsequent germination experiments indicated that higher concentrations of extracts had rapid toxic effects on algal spores. Synchronous effects of echinoderm extracts and plate charge upon spore settlement varied considerably and did not show a strong dose response relationship. Long-term (24 h) exposure of spores to echinoderm extracts had dosage dependent effects on germination and spore survival. The results of this study indicate that H. irregularis spores possess the capacity for complex responses to their environment, utilizing combined cues of surface charge, surface energy and biochemistry to determine where to settle and germinate. These responses may aid spores in the detection of suitable substrata and conditions for settlement in the marine environment.     

CLONAL VARIATION IN PHOTOTAXIS AND SETTLEMENT BEHAVIORS OF HINCKSIA IRREGULARIS (PHAEOPHYCEAE) SPORES1

Hincksia irregularis (Kützing) Amsler isolates from North Carolina were used to assess clonal variations in spore swimming behavior and settlement responses within a population. These behaviors were also compared with those previously reported from a Florida panhandle clone to assess differences between geographically distinct populations. Minor variation between morphologies, reproductive responses, and settlement intervals were observed between all clones. Spores from all North Carolina clones exhibited positive phototaxis, but there was significant variation in the lower threshold irradiances that could elicit the behavior. In contrast, spores from the previously studied Florida panhandle clone exhibited negative phototaxis. Hincksia irregularis spore settlement responses to hydrophobic and hydrophilic surfaces were consistent for all clones currently and previously tested. Interactive effects of light and charge on settlement were evident in spores from North Carolina isolates, but these effects differed from the Florida panhandle isolate. Settlement preference and swimming behavior differences may have a considerable effect on an individual's ecological fitness and placement within the marine environment. However, the perceived relevance of these differences needs to be validated further in light of previously reported genetic, physiological, and behavioral variations observed in other algal clones that have called into question traditional assessments of individuality.     

A New Antifouling Bioassay Monitoring Brown Algal Spore Swimming Behaviour in the Presence of Echinoderm Extracts

Epibiosis, the colonization of biogenic surfaces by epibiotic organisms such as bacteria, filamentous algae, and sessile invertebrates, poses a major threat to the fitness and survival of macroorganisms which could potentially be fouled. Fouling of artificial submerged structures can also cause severe economic problems, making the need for refined bioassays to determine the efficacy of potential antifouling compounds even more important. The aim of this study was to use the distinct swimming behaviour of zoospores of the fouling brown alga Hincksia irregularis to develop a new laboratory antifouling bioassay to test the effect of marine natural products. Spores were exposed to different concentrations of aqueous and organic extracts from body walls of sympatric echinoderms (Asteroidea: Luidia clathrata, Astropecten articulatus; Ophiuroidea: Astrocyclus caecilia). Computer-assisted motion analysis was used to distinguish between the straight and fast swimming movements of undisturbed spores (controls) and the helical and erratic swimming patterns of chemically irritated spores, using the quantitative parameters rate of direction change (RCD) and swimming speed (SPD). The ratio RCD/SPD of spore swimming paths at extract treatments compared to controls can be used to quantify the detrimental effect of echinoderm extracts. Echinoderm extracts had significant effects on spore swimming behaviour at concentrations three orders of magnitude lower than that present naturally in the echinoderm body walls (mg extract/dry weight echinoderm body wall). Comparative studies on spore settlement and germination under similar treatment conditions show that changes in spore swimming behaviour reflect decreased fitness and survivourship of algal spores. It is suggested that this bioassay can be used to screen potential antifouling extracts and compounds at very low concentrations, making this assay particularly suitable for detection of concentration dependent effects and for bioassay-guided fractionation of extracts to identify active compounds.     

ROLE OF SETTLEMENT DENSITY ON GAMETOPHYTE GROWTH AND REPRODUCTION IN THE KELPS PTERYGOPHORA CALIFORNICA AND MACROCYSTIS PYRIFERA (PHAEOPHYCEAE)1

Laboratory studies were used to examine how variation in the density of spore settlement influences gametophyte growth, reproduction, and subsequent sporophyte production in the kelps Pterygophora californica Ruprecht and Macrocystis pyrifera (L.) C. Ag. In still (non-aerated) cultures, egg maturation in both species was delayed when spores were seeded at densities 300 · mm^?2. Although the density at which this inhibition was first observed was similar for both species, the age at which their eggs matured was not. P. californica females reached sexual maturity an average of 4 days (or ～ 30%) sooner than did M, pyrifera. As observed previously in field experiments, per capita sporophyte production was negatively density dependent for both species when seeded at spore densities of 10 · mm^?2. Total sporophyte production (i.e. number · cm^?2) for both species, however, was greatest at intermediate densities of spore settlement (～ 50 spores · mm^?2). In contrast, total sporophyte production by P. californica steadily increased with increasing spore density in aerated cultures; highest sporophyte density was observed on slides seeded at a density of 1000 spores · mm^?2. Preliminary experiments with P. californica involving manipulation of aeration and nutrients indicate that inhibition of gametophyte growth and reproduction at higher densities of spore settlement in non-aerated cultures was probably caused by nutrient limitation.     

QUALITATIVE AND QUANTITATIVE STUDIES OF THE SWIMMING BEHAVIOR OF HINCKSIA IRREGULARIS SPORES (PHAEOPHYCEAE)

The swimming behavior of spores of the brown alga Hincksia irregularis was analyzed using computer-assisted motion analysis. We distinguished five main swimming patterns: straight paths, search circles, orientation, gyration, and wobbling. We suggest different functional values for the individual swimming patterns. Straight paths, search circles, and orientation are different but all may be important in small-scale movements in the benthic boundary layer. As such, they could enable a spore to find a suitable microenvironment for germination and growth. Gyration occurs during the initial reversible phase of adhesion that can lead to settlement. Wobbling is typical for irritated or mechanically damaged spores and does not seem to be a typical pattern associated to settlement. The dominant swimming patterns changed with spore age (10 ± 5 to 60 ± 5 min of spore age), with young spores mainly swimming in straight paths and search circles and older spores in orientation and gyration. This change in swimming patterns can be quantified by speed (decrease over time) and rate of change of direction (increase over time). Based on these results, we suggest that computer-assisted motion analysis of the swimming behavior of H. irregularis spores can be used to develop bioassays with both ecological and technological relevance.     

The physico-chemical characterization of casein-modified surfaces and their influence on the adhesion of spores from a Geobacillus species

To gain a better understanding of the factors influencing spore adhesion in dairy manufacturing plants, casein-modified glass surfaces were prepared and characterized and their effect on the adhesion kinetics of spores from a Geobacillus sp., isolated from a dairy manufacturing plant (DMP) was assessed using a flow chamber. Surfaces were produced by initially silanizing glass using (3-glycidyloxypropyl) trimethoxysilane (GPS) or (3-aminopropyl) triethoxysilane to form epoxy-functionalized (G-GPS) or amino-functionalized glass (G-NH₂) substrata. Casein was grafted to the G-GPS directly by its primary amino groups (G-GPS-casein) or to G-NH₂ by employing glutaraldehyde as a linking agent (G-NH₂-glutar-casein). The surfaces were characterised using streaming potential measurements, contact angle goniometry, infrared spectroscopy and scanning electron microscopy. The attachment rate of spores suspended in 0.1 M KCl at pH 6.8, was highest on the positively charged (+14 mV) G-NH₂ surface (333 spores cm^?2 s^?1) compared to the negatively charged glass (?22 mV), G-GPS (?20 mV) or G-GPS-casein (?21 mV) surfaces (162, 17 or 6 spores cm^?2 s^?1 respectively). Whilst there was a clear decrease in attachment rate to negatively charged casein-modified surfaces compared to the positively charged amine surface, there was no clear relationship between surface hydrophobicity and spore attachment rate.     

Engineered antifouling microtopographies: mapping preferential and inhibitory microenvironments for zoospore attachment

An algorithm was developed and implemented to map the locations of attached spores of Ulva linza on patterned surfaces. Using this mapping algorithm, spore preference among regions within a pattern can be detected and quantified. Settlement maps of spores on patterned topographies from several assays showed clear preferences in spore settlement. Over 94% of the spores attached within the depressed regions on the surfaces, including a surface containing pits instead of protruding features. The spores attached primarily at the intersections of several features, with over half and up to 96% of spores settling in these regions. The highest spore densities occurred at intersections where the features were most dissimilar. In contrast, the location of attached beads on the surfaces was nearly uniform across the surface. Identification of preferential attachment locations allows for the study of localized properties that influence cell behavior and aids in the development of new surfaces to control cell–surface interactions.     

Spore discharge in Entomophthora grylli

Entomophthora grylli Fres. has been found on larvae of Bradysia (Sciaridae, Diptera) on wood in Kansas State University greenhouses since November 1967. Infected larvae crawled to an exposed site in the night and by morning spores of E. grylli were being discharged. In the greenhouse and under controlled environments spore discharge showed a marked periodicity; spore discharge occurred in the light with peaks in the first 1–4 h; discharge then gradually declined but extended into the dark. On the second and third days peaks occurred in the light but were progressively smaller. In a greenhouse under fluctuating conditions twin peaks occurred at 10·00 and 22·00; in a growth chamber, at constant 21° C. 90% r.h., alternating 12 h light and dark periods, spore discharge was similar, with maximum numbers about 21/2 h after the onset of the photo-period. In continuous dark and continuous light no endogenous pattern was evident. Temperature range for spore discharge was 2–28·, with optimum at 15·. Decreasing humidities resulted in decreased spore production and cessation of discharge below 40% r.h.     

NUTRIENTS DO NOT INFLUENCE SWIMMING BEHAVIOR OR SETTLEMENT RATES OF ECTOCARPUS SILICULOSUS (PHAEOPHYCEAE) SPORES

Spores newly released from plurilocular sporangia of Ectocarpus siliculosus (Dillw.) Lyngb. sporophytes were assayed for chemotaxis to nutrients and for settlement stimulation by nutrients. To enable these measurements with relatively small volumes and numbers of released spores, we developed a computer-assisted motion-analysis assay for spore chemotaxis and verified the results with a more standard, capillary tube chemotaxis assay. The presence of a nutrient gradient did not influence the swimming behavior of E. siliculosus spores in the motion-analysis assay, and likewise no chemotactic effect was measured in the capillary tube assay. Microplate settlement assays previously utilized with bacteria and invertebrates were adapted for use with algal spores. E. siliculosus spores settled at higher rates on a hydrophobic plastic surface than on surfaces with either positively or negatively charged hydrophilic coatings. Nutrient mixtures had no effect on the rate of spore settlement on hydrophobic surfaces.     

The spore‐associated protein BclA1 affects the susceptibility of animals to colonization and infection by Clostridium difficile

The BclA protein is a major component of the outermost layer of spores of a number of bacterial species and Clostridium difficile carries three bclA genes. Using insertional mutagenesis each gene was characterized and spores devoid of these proteins had surface aberrations, reduced hydrophobicity and germinated faster than wild‐type spores. Therefore the BclA proteins were likely major components of the spore surface and when absent impaired the protective shield effect of this outermost layer. Analysis of infection and colonization in mice and hamsters revealed that the 50% infectious dose (ID₅₀) of spores was significantly higher (2‐logs) in the bclA1^? mutant compared to the isogenic wild‐type control, but that levels of toxins (A and B) were indistinguishable from animals dosed with wild‐type spores. bclA1^? spores germinated faster than wild‐type spores yet mice were less susceptible to infection suggesting that BclA1 must play a key role in the initial (i.e. pre‐spore germination) stages of infection. We also show that the ID₅₀ was higher in mice infected with R20291, a ‘hypervirulent’ 027 strain, that carries a truncated BclA1 protein.     

Spore morphology and wall ultrastructure of Hymenophyllaceae Link (Pteridophyta) from north-west Argentina

The family Hymenophyllaceae is represented in the study area by six species in two genera, Hymenophyllum J. E. Smith and Trichomanes L. The study was based on herbarium material and spores were studied under light microscope (LM), scanning electron microscope (SEM) and transmission electron microscope (TEM). Both genera have trilete spores, 23 to 45 μm in equatorial diameter, with an ornamentation of echinulae and cones in Hymenophyllum and of verrucae, gemmae and granules in Trichomanes. Mature spores have a sporoderm composed of a perispore, an exospore and a fibrillar endospore; the exospore is 0.5 to 2.5 μm thick, compact and with an irregular margin. In some cases radial channels and other channels associated with the middle and inner parts of the laesurae were evident. A series of cavities filled with an opaque content line the inner margin of the exospore. The perispore is 20 to 400 nm thick and unevenly differentiated along the surface of a same spore. Under TEM, two main differentially contrasted portions could be distinguished: a dark massive portion with structural components could not be distinguished, and a light portion with several plates arranged in piles. The inner surface of the perispore exhibit short scales. Globules are immersed within the perispore at some depth from the perispore surface and others connected to it by structural threads. The spore characters observed including shape, ornamentation, laesurae length and wall structure are useful in distinguishing the two genera studied, but less useful in differentiation at the species level.     

Effects of the sporulation conditions on the lovastatin production by Aspergillus terreus

The production of biomass and lovastatin by spore-initiated submerged fermentations of Aspergillus terreus ATCC 20542 was shown to depend on the age of the spores used for inoculation. Cultures started from older spores produced significantly higher titers of lovastatin. For example, the lovastatin titer increased by 52% when the spore age at inoculation rose from 9 to 16 days. The lovastatin titer for a spore age of 16 days was 186.5±20.1 mg L⁻¹. The time to sporulation on surface cultures was sensitive to the light exposure history of the fungus and the spore inoculation concentration levels. A light exposure level of 140 μE m⁻² s⁻¹ and a spore concentration of 1,320 spore cm⁻² produced the greatest extent of sporulation within about 50 h of inoculation. Sporulation was slowed in the dark and with diluted inoculants. A rigorous analysis of the data of statistically designed experiments showed the above observations to be highly reproducible.     

THE LIFE CYCLE OF BANGIA FUSCOPURPUREA IN CULTURE. I. EFFECTS OF TEMPERATURE AND PHOTOPERIOD ON THE MORPHOLOGY AND REPRODUCTION OF THE BANGIA PHASE12

The Bangia phase of Bangia fuscopurpurea was grown in laboratory culture in a variety of photoperiod and temperature regimes. Plants of the Bangia phase grown from 2 types of asexual spores, monospores and conchospores, exhibited growth differences under similar growing conditions. Plants derived from monospores grew more rapidly and matured earlier than those derived from carpospores. Day length and temperature were found to significantly influence growth rule, maturation, and plant size. Long day lengths resulted in more rapid growth in filament length and diameter and earlier spore formation and spore release. Maximum filament length was observed in a 12/12 hr light-dark cycle at 15 C. Spore formation and release were delayed by decreasing day length or temperature. Temperature and photoperiod were also found to influence the type of spores produced by the Bangia phase. When grown at 22 C, the Bangia phase produced only monospores, which reproduced the Bangia phase. At 9 C, with photoperiods of 11 hr or more of light, the Bangia phase produced carpospores which gave rise to the alternating Conchocelis phase. The conditions under which sporogenesis occurred determined the spore type differentiated.     

Airborne fungi in an Italian rice mill

Summary Studies employing volumetric spore trap (VSP) and gravity settling culture plates (GSC) were conducted in order to analyse the air spora of a rice mill at Pavia, Italy, from October-December 1988. Results revealed a variety of fungal spores belonging to different genera and including recognized rice pathogenic fungi. The most frequent genera by GSC method includedAcremonium, Alternaria, Aspergillus, Aureobasidium, Cladosporium, Epicoccum, Fusarium, Helminthosporium, Mucor, Nigrospora, Penicillium, Rhizopus, Trichoderma, Trichothecium, and some unidentified fungi. Environmental assessment of fungal spores by VSP revealed that the most prevalent fungi were:Alternaria, Cladosporium, Epicoccum, Helminthosporium, Nigrospora, Pyricularia, Tilletia and hyaline, dark and coloured types of ascospores and basidiospores. Airborne fungal spore concentrations were particularly high (5,000–6,000 spores/m³) in the rooms of the rice mill where the initial stages of rough rice transformation take place, and dropped to 2,500 spores/m³ in the last room, where workers are. During a temporary interruption of the working processes, air spora concentration dropped below 1,000 spores/m³.Cladosporium, Epicoccum andNigrospora spores were predominant in all subdivisions of the indoor environments of the rice mill.     

Antifouling Potential of Lubricious,Micro-engineered,PDMS Elastomers against Zoospores of the Green Fouling Alga Ulva (Enteromorpha)

The settlement and release of Ulva spores from chemically modified, micro-engineered surface topographies have been investigated using poly(dimethyl siloxane) elastomers (PDMSe) with varying additions of non-network forming poly(dimethyl siloxane) based oils. The topographic features were based on 5?μm wide pillars or ridges separated by 5, 10, or 20?μm wide channels. Pattern depths were 5 or 1.5?μm. Swimming spores showed no marked difference in settlement on smooth surfaces covered with excess PDMS oils. However, incorporation of oils significantly reduced settlement density on many of the surfaces with topographic features, in particular, the 5?μm wide and deep channels. Previous results, confirmed here, demonstrate preferences by the spores to settle in channels and against pillars with spatial dimensions of 5?μm, 10?μm and 20?μm. The combination of lubricity and pillars significantly reduced the number of attached spores compared to the control, smooth, unmodified PDMSe surfaces when exposed to turbulent flow in a flow channel. The results are discussed in relation to the energy needs for spores to adhere to various surface features and the concepts of ultrahydrophobic surfaces. A factorial, multi-level experimental design was analyzed and a 2nd order polynomial model was regressed for statistically significant effects and interactions to determine the magnitude and direction of influence on the spore density measurements between factor levels.     

Electron microscopy of sporulation inSchwanniomyces alluvius

Sporulation inSchwanniomyces alluvius appeared to be preceded by fusion of a mother and a daughter cell. Meiosis probably occurred in the mother cell and one or two spores were formed in the latter. A study of thin sections showed that the spore wall developed from a prospore wall. The mature spore wall consisted of a broad light inner layer and a thinner dark outer layer including warts. An equatorial ledge was present. During germination in the ascus, a new light inner layer was formed and the old layers of the spore wall partly broke up. Ascospores in a strain ofS. persoonii had a different wall structure in that the dark layer had changed into light areas separated by dark material which formed bulges at the surface.     

Effects of plant micro-environment on movement of <Emphasis Type="Italic">Helicoverpa armigera</Emphasis> (Hübner) larvae and the relationship to a hierarchy of stimuli

Locomotory behaviour of 1st instar Helicoverpa armigera is influenced by a complex of micro-attributes, the leaf “environment”, comprising odours, wax chemistry, trichomes and grip texture. Larval movement speeds on leaves of different types varied more than eight fold. On garden pea, Pisum sativum, there is a hierarchy of stimuli perceived by larvae resulting in differing behavioural responses. Light and angle are paramount in responses to micro-environment. These influence responses to local stimuli. Experiments in darkness produce different responses from those under laboratory light. In darkness, on horizontal surfaces as found for most leaves, preference for leaf surface is driven by micro-environment associated with leaf waxes. Larvae prefer the abaxial surface. In light, on horizontal surfaces, larvae seek enclosed spaces and foray under leaf surfaces. They wander more openly in the dark. Such information is important in building a model of larval behaviour and predicting behaviour on differing plant architectures.     

SPORE DEVELOPMENT IN THE LIVERWORT RICCARDIA PINGUIS

The ontogeny of spores of the liverwort Riccardia pinguis was studied at the light and electron microscope levels. Three stages of development were arbitrarily defined: spore mother cell (SMC); early tetrad with nonpigmented and unsculptured walls; and mature tetrad with pigmented and sculptured spore walls. The SMC is quadrilobed with a two-layered SMC wall, containing a central nucleus, many chloroplasts, spherosomes, and other organelles. During and following meiosis cell plates form from coalescing Golgi vesicles. These plates by continued coalescence eventually form a septum, completing the tetrad. This septum comprises middle lamella and primexine; within the latter the exine forms. By continued addition of vesicle contents to the septum and dorsal surfaces of the tetrad, the exine (sexine and nexine) and intine layers of the spore wall are laid down. The contents of the vesicles change successively during wall formation, corresponding to the different wall layers being formed. It is concluded that wall formation is under the exclusive control of the spore protoplast, and that the pattern of the mature exine is determined by the primexine. Rearrangement of organelles and other cellular components during sporogenesis is described.