Theories on adaptations to high light intensity in the aquatic moss Fontinalis

Abstract

Fontinalis antipyretica, collected from a cold stream in bright sunlight, served as a model for adaptations of Fontinalis to sun and shade. Sun leaves produced red pigments and had less chlorophyll, greater specific leaf weight, and less specific leaf area than shade leaves. The chlorophyll a/b ratio was not significantly different under high and low light conditions. Except for the relatively constant a/b ratio, Fontinalis behaved like higher plants in its sun/shade differences.     

Adattamenti fisiologici alla vita « aerea » nel genere Tillandsia

Abstract

Physiological adaptations to « aerial » life in the genus Tillandsia.—Ten « atmospheric » Tillandsia species, with different degree of adaptation to drought, were investigated to verify the occurrence of CAM and to determine their daily transpiration pattern.

Most of the species were collected during the Botanical Expeditions of the Accademia dei Lincei in Latin America in 1969 and 1971. All species had been maintained in the greenhouse of the Naples Botanical Garden during the winter months and in the open air during the warmer months, previous to experiments. The diurnal cycle of transpiration, the malic acid content and cell sap pH of the leaves were studied under outdoor conditions. Curves of malic acid and pH variations typical of CAM have been obtained for all the examined species. Moreover, the transpiration data indicate that stomata are open at night. The rates of transpiration appear to be extremely low. The highest transpiration rates refer to the species of the relatively moister habitats, the lowest to the more xeric species. Results indicate that CAM and low rates of transpiration are ecological adaptations to extremely dry habitats.     

Morphophysiological differences in leaves of <Emphasis Type="Italic">Lavoisiera campos</Emphasis>-<Emphasis Type="Italic">portoana</Emphasis> (Melastomataceae) enhance higher drought tolerance in water shortage events

Lavoisiera campos-portoana Barreto (Melastomataceae) has two kinds of leaves, pubescent and glabrous, and branches may have one or both types of leaves at the same moment. The plant is endemic to high altitude rocky fields in Brazil where rainfall is very seasonal. We predicted that these two leaf types are adaptations to different regimes of water availability. In experimental conditions of drought stress, we measured relative water content (RWC), photosynthetic pigments, chlorophyll a fluorescence and osmotic potential, and we counted stomates and measured stomatal conductance on both sides of leaves and compared these between the two leaf types. Stomatal conductance and electron transport rate at a given photosynthetic photon flux were greater in pubescent leaves than in glabrous leaves, and both declined during drought stress. Excessive photon flux density in glabrous leaves was greater during stress and after rehydration. Photosynthetic pigment content and RWC did not change between leaves, and values reduced during the stress period. Both types of leaves showed osmotic adjustment capacity, which occurred earlier in glabrous ones. These morphophysiological differences highlight the adaptation strategies of this plant to withstand drought, since the glabrous portion of the plant presents a preventive behavior, while the pubescent portion only shows the same responses in more advanced stages of drought stress.     

Wood anatomy of some trees with diffuse- and ring-porous wood: Some functional and ecological interpretations

Abstract

The xylem conduit dimensions (i.e. their width and length) have been measured in 1-year-old internodes, nodes and node-to-petiole (N-P) junctions of three species with diffuse-porous wood, namely Ceratonia siliqua L., Laurus nobilis L. and Olea europaea L. as well as of three species with ring-porous wood, namely Quercus ilex L., Q. suber L. and Q. pubescens Willd‥ The xylem conduit diameter and length distributions have been related to the drought resistance strategies adopted by the six species. C. siliqua and Q. ilex (drought avoiding water spenders) showed the widest xylem conduits (each species within its characteristic pattern of wood anatomy). This is consistent with their high demand of efficient water transport to leaves. L. nobilis (drought avoiding water saver) showed relatively narrow xylem conduits, efficient enough, however, to assure water supply to leaves at the reduced transpiration rate exhibited by the species. O. europaea, Q. suber and Q. pubescens (drought tolerants) showed the narrowest xylem conduits but also the longest ones. The xylem system of C. siliqua and Q. ilex represented a good compromise between efficiency and safety of the water transport, the former as due to wide xylem conduits, the latter to the reduced xylem conduit length as well as to the strong «hydraulic constrictions» at their nodes and N-P junctions. The ecological interpretation of such hydraulic architecture is discussed.     

Relationship between photosynthetic rate,water use and leaf structure in desert annual and perennial forbs differing in their growth

Specific leaf area (SLA) is a key trait to screen plants for ecological performance and productivity; however, the relationship between SLA and photosynthesis is not always up-scalable to growth when comparing multiple species with different life cycles. We explored leaf anatomy in annual and perennial species of Physaria, and related it to photosynthesis and water loss. The annual Physaria gracilis had higher SLA, thinner leaves, and lower investment in protective tissues, than perennial P. mendocina. Physaria angustifolia (annual), and P. pinetorum (perennial) showed intermediate values. Both perennials had a thicker palisade and high photosynthesis, relative to annuals. The larger leaf veins of perennials should allow high water availability to the mesophyll. The thicker palisade should determine high resistance to water flow and help explain their high water-use efficiency. These leaf functions reflect the construction of long-lived leaves that efficiently use resources under environmental limitations of arid environments.

     

Sun and shade leaves in Betula pubescens and Betula pendula

Summary

Measurements of the net photosynthesis and dark respiration rates of excised twigs from Betula pubescens Ehrh. subsp. odorata (Bechst.) Warburg and B. pendula Roth, at different light intensities were made using infra-red gas analysis. B. pubescens appears to possess leaves which on the basis of physiological responses can be described as sun and shade leaves. In the more open canopy of B. pendula differences between leaf types are less pronounced. The presence of sun and shade leaves is suggested as a means whereby the net assimilation rate of the shrubby growth form of B. pubescens can be increased. This type of mechanism becomes increasingly important at high altitudes and latitudes.     

Observations sur la microflore fongique des feuilles vertes et sénescentes de Loudetia simplex

Abstract

Observations on the mycoflora of green and senescent leaves of Loudetia simplex.—Leaves of Loudetia simplex, a common grass of the moist savannah of Ivory Coast, were collected at different growth stages at the end of the life cycle (December) and during the growing period of the plant (June). The study was carried out by indirect techniques, plating on PDA in Petri dishes aliquots of a suspension 1:1000 (fresh weight/volume) of ground leaves.

The isolates belong mainly to Fungi Imperfecti; the distribution of the Fungi includes 20 Moniliaceae, 13 Dematiaceae, 15 Tuberculariaceae, 4 Melanconiales, 9 Sphaeropsidales, 1 Ascomycetes and a number of sterile hyphae, mainly with dark mycelium.

Most of the isolates are commonly recorded on leaves (Cephalosporium acremonium group, Cladosporium cladosporioides, Fusarium spp., Monodictys, Phoma). Also present Nigrospora sphaerica, which seems a typical phyllosphere inhabitant in tropical regions.

Even if the data correspond only to two sampling periods they show a high specialization of fungal forms and a succession of microfungi from young to senescent leaves of L. simplex.     

Desiccation tolerance of four sympatric tropical intertidal hermit crabs (Decapoda,Anomura)

This study describes and quantifies the air exposure tolerance of four sympatric hermit crabs (Pagurus criniticomis, Clibanarius antillensis, C. sclopetarius, and C. vittatus) in an intertidal area in southeastern Brazil. We report on survivorship, percentage and rate of weight and water loss until death, and overall body water content. The coexisting populations showed similar percentages of overall body water content and weight and water loss until death. Survivorship depended on crab size rather than species, and was positively correlated with crab size within each species (linear relationship) and with the size of all individuals of this hermit crab assemblage (exponential relationship). Each species had a characteristic rate of weight and water loss, indicating the existence of different physiological adaptations to resist desiccation. These differences were directly related to the species’ distribution patterns in the intertidal zone.     

Osser Vazioni Anatomiche su Foglie di Olivo Sane ed Attaccate da Spilocaea Oleagina (Cast.) Hugh.

Abstract

Anatomical observations on sound leaves and by SPILOCAEA OLEAGINA (Cast.) Hug infected leaves in Olive-tree. — The author has studied the anatomical characters comparatively between two cv. of Olive tree growing in Messina district (Sicily): cv. Ogliarola, receptive to Spilocaea oleagina (Cast.) Hug, and cv. Leccino not receptive.

Anatomical differences of the leaf as a whole and particularly of the «cuticular membrane » have been observed between sound leaves and attacked leaves of cv. Ogliarola, and sound leaves of cv. Leccino.

The main conclusions drawn from this study are the following ones:

The mesophyll is thicker in cv. Ogliarola and thinner in cv. Leccino.

The cuticular membrane and its 4 layers are thicker in Ogliarola leaves than in Leccino's ones.

Ogliarola leaves attacked by the fungus show a cuticolar membrane thicker than the sound leaves of the same cultivar.

Hiperplastic and hipertrophic tissues have been observed in Ogliarola leaves attacked by Spilocaea, expecially epidermis and palisade.

The anatomical causes of resistence and receptivity are prospected.     

Stem biomechanics of the giant moss Dendroligotrichum dendroides s.l. and its significance for growth form diversity in mosses

Abstract

The giant moss Dendroligotrichum dendroides s.l. grows as self-supporting plants up to 40 cm in height in forest habitats in Chile and New Zealand. This moss represents one of the tallest self-supporting bryophytes. Biomechanical tests indicate that the stems can develop a high degree of stiffness (Young’s modulus) via a dense hypodermal sterome that is comparable with that of woody stems of vascular plants. A comparison with mechanical properties of other terrestrial and aquatic mosses indicates that different moss growth and life forms can produce very different mechanical architectures. Values of stem stiffness can vary between different growth forms of mosses to a comparable extent to that observed among diverse growth forms of vascular plants. Plants varying profoundly in overall size, development, and phylogenetic position nevertheless appear to develop comparable mechanical adaptations and growth forms in response to certain environmental conditions.     

Water-content components in bryophytes: analysis of pressure-volume relationships

The water associated with a bryophyte can be divided into (a) apoplast water held in cell-wall capillary spaces and by matric forces, (b) osmotic (symplast) water, and (c) external capillary water. In many bryophytes (c) is a large and variable component, preventing easy determination of full-turgor water content and of relative water content (RWC) values physiologically comparable with those for vascular-plant leaves. Pressure-volume (P-V) curves are presented and water-relations parameters estimated for bryophytes, including species with large thin-walled cells (Hookeria lucens and three marchantialian thalloid liverworts), species with notably thick cell walls (Neckera crispa), and species with wettable surfaces and well-developed external capillary water conduction (Tortula ruralis, Anomodon viticulosus), and for the lichen Cladonia convoluta. Full-turgor water content ranged from c. 110% DW. in T. ruralis and Andreaea alpina to 1400% DW or more in Dumortiera hirsuta and Conocephalum conicum. Osmotic potential () at full turgor was between -1.0 and -2.0 MPa in most species, but substantially less negative values were found in the thalloid liverworts (-0.35 to -0.64 MPa). The x-intercept of the P-V curve is not a reliable estimate of apoplast volume and may give negative values; better estimates of apoplast volume may be obtained by vapour equilibration at known low water potentials. Blotting external water from shoots usually gave full-turgor water content estimates in reasonable agreement with those obtained by analysis of P-V curves, but for different reasons they could be either higher or lower than the true value. The importance of knowing full-turgor water content for physiological work on water-stress responses in bryophytes is emphasized.Key words: Thermocouple psychrometry, apoplast fraction, relative water content, osmotic potential, poikilohydry.      

Breeding phenology,reproductive traits and apparent survival of sympatric Marsh Warbler Acrocephalus palustris and Blyth’s Reed Warbler Acrocephalus dumetorum

Capsule: Sympatric Marsh Warblers Acrocephalus palustris and Blyth’s Reed Warblers Acrocephalus dumetorum differ significantly in their life history traits.

Aims: To provide a direct comparison of demographic parameters among two sympatric populations of the closely related Marsh Warbler and Blyth’s Reed Warbler.

Methods: We examined breeding phenology and reproductive traits at a 25?ha study plot. We use program MARK to estimate daily nest survival and adult apparent survival rates.

Results: On average, Marsh Warblers laid the first eggs 3 days later than Blyth’s Reed Warblers. Mean clutch size in the Marsh Warbler was significantly lower than in the Blyth’s Reed Warbler. There are no significant differences between the two species for nest daily survival, duration of incubation and nestling periods. Apparent survival of adults was slightly higher in Marsh Warblers than in Blyth’s Reed Warblers.

Conclusion: Our findings suggest that two ecologically similar sympatric species differ significantly in terms of life history traits. We assume that observed differences could be the result of adaptations to environmental factors in the central parts of the species’ ranges or due to differences in mortality on migratory pathways or wintering grounds.     

Physiological and morphological characterisation of Limonium species in their natural habitats: Insights into their abiotic stress responses

Background and aims

Morphological and biochemical traits of four halophytes of the genus Limonium were analysed in plants sampled from salt marshes in SE Spain. This work aimed to explore the mechanism(s) behind the adaptation of these species to stressful habitats, with particular emphasis on responses to drought.

Methods

Plants of each species together with soil samples were collected in summer, which is the most stressful season in the Mediterranean. Soil parameters and plant morphological traits were determined, and the levels of several biochemical stress markers in plants were measured using spectrophotometric assays. A multivariate analysis was performed to correlate soil and plant data.

Results

Morphological characteristics regarding the underground system topology and several biochemical traits (higher foliar Ca²⁺, sucrose and glucose, and lower proline, glycine-betaine and fructose) clearly separate L. santapolense individuals from plants of the other three species.

Conclusions

Drought tolerance of L. santapolense in the field is mostly dependent on morphological adaptations: when growing in an arid location, plants of this species develop long taproots that can extract water from the deep, moist layers of the soil.

     

Plant functional identity as the predictor of carbon storage in semi-arid ecosystems

Background: There is an increasing consensus that ecosystem processes are governed by functional identity and trait variation rather than species richness. Despite its importance, the relative effect of relevant functional traits for carbon storage has remained mostly untested in different bioclimatic regions.

Aims: In this study, different components of functional diversity such as community-weighted means of trait values (CWM), functional trait diversity (Rao’s quadratic diversity), functional richness (FRi), functional evenness (FEv) and functional divergence (FDiv) were used to associate carbon content of above-ground biomass, litter and soil in four bioclimatic regions including warm and cold-steppe, semi-steppe rangelands and oak dry forest in the south-west of Iran.

Methods: Several key important traits highly associated with carbon storage including specific leaf area (SLA), height (H), leaf dry matter content, leaf nitrogen and phosphorus content (LNC and LPC), leaf longevity, wood specific gravity and life form were determined to quantify single and multiple traits that contribute to different components of plant functional diversity.

Results: The results showed that CWM of H, Chamaephyte life form, LNC and LPC were among the most important aspects of functional diversity that positively predicted carbon storage in above-ground biomass and soil. We also observed the negative association of carbon storage with FEv of LNC, Rao of LNC and FEv of multiple traits in the rangelands and the negative association of carbon storage with FDiv of SLA in the forest.

Conclusions: Our results indicate that different components of functional diversity are essential for a mechanistic understanding of the role of plant diversity for carbon storage. The negative associations between FDiv and FEv and carbon storage do not provide support for the complementarity niche hypothesis. Our results suggest that in the more functionally diverse ecosystems dominated by functionally important species with key traits, the so-called functional identity does indeed promote carbon storage, at least in these semi-arid ecosystems.     

Effects of environmental heterogeneity on species diversity and composition of terrestrial bryophyte assemblages in tropical montane forests of southern Ecuador

Background: Most studies on tropical bryophytes deal with epiphytic species. This is the first ecological study of tropical forests that focuses specifically on terrestrial bryophytes.

Aim: To investigate the differences between slope and ridge environments in upper montane forests of southern Ecuador in terms of species diversity (richness, abundance), species composition and life forms of terrestrial bryophytes.

Methods: We used Non-metric Multidimensional Scaling (NMDS) to group bryophyte relevés by study location, habitat type and exposure class. Species indicator values were calculated and compared for different habitats.

Results: In total, 140 species were recorded, the majority being liverworts. NMDS analyses and Mantel correlations clearly separated between slope and ridge relevés, and between sunny and shaded microhabitats on ridges. Bryophyte life forms also showed different distribution patterns in slope and in ridge habitats. Mosses were more prominent in sunny than in shaded microhabitats.

Conclusions: Environmental differentiation between ridges and slopes, and small-scale variation in microclimatic conditions caused by differences in exposure, were stronger predictors of species richness and composition than geographical distance between study sites.     

Photosynthesis on individual leaves of sugar beet (Beta vulgaris) during the ontogeny at variable water regimes

It is well known that the extent of yield reduction depends not only on the severity of water stress but also on the stage of plant development. Assessing photosynthetic response of individual leaves to water deficit during the ontogeny may, therefore, offer a clue to better understand the whole plant behaviour. This research aimed at investigating the influence of early and late water stress on net photosynthesis (P_n), carbon‐isotope discrimination and other related traits on individual leaves during ontogeny. Sugar beet plants were grown in rain‐sheltered soil columns of relevant volume (300 L), subdivided into well‐watered (WW); early (S1) and late (S2) stress. In general, water stress significantly reduced leaf lifespan and P_n. Relieving the stress at about one‐third and two‐thirds of potential leaf life substantially restored P_n at the levels of WW. Stressing a previously WW leaf brought about a comparatively heavier loss than stressing a leaf since the beginning. As for leaves at different phenological times, the early leaves had higher initial photosynthetic peaks but steeper falls during their lives. An insight into the relationships between P_n and substomatal CO₂ concentration (C_i) shows that in mature leaves the photosynthetic restoration following stress relief did not entail a full recovery of the electron transport rate, the parameter most severely affected by the stress. The partial reversibility of the effects of water deficiency, associated to the anticipated leaf senescence and to the natural slow‐down of net assimilation during leaf life, may be seen as a key factor in predicting to what extent the plant can tolerate drought and the damages caused by water stress.     

Characterizing Se transfer in the soil-crop systems under field condition

Aims

A comparison was performed between plant species to study Se accumulation and translocation in the crops under field condition.

Methods

Wheat, rice and canola were sampled with respective cultivated soils from the Yangtze River Delta area. The concentrations of total Se and bio-available Se and a number of parameters (N, P, S, Fe, Ca, Mg, Al, K, Mn, pH and organic carbon) were analyzed, and the net translocation coefficients of Se in the soil-crop systems were calculated.

Results

The concentrations of Se in plants significantly differed between crop species, in spite of concentrations of total Se and bio-available Se and related parameters in the soils showing no significant difference among the wheat, rice and canola sampled sites. With regard to the seeds, wheat exhibited significantly higher Se concentration than rice and canola; whereas for the straw and root, wheat showed lower Se concentration than canola and rice. The net translocation coefficients of Se in different soil-crop systems exhibited different patterns, suggesting that the difference is mainly caused by a discrepancy in Se translocation from straw to grain.

Conclusions

Wheat has a weaker capability to accumulate Se compared with rice and canola, but a significantly stronger capability to transport Se from its straw to seed. These differences might be related to the influence of S on Se differences, comparing the biochemical behavior and transport of S and Se in plants of different plant species. Selenium follows sulfur during accumulation in wheat and rice because both elements are accumulated in plant tissues mainly in the form of amino acids; whereas in canola, the influence of S on Se accumulation is not as obvious as in wheat and rice because the seeds contain more non-amino acid organic S compounds.

     

A biomimetic platform for studying root-environment interaction

Aims

Microstructure plays an important role in biological systems. Microstructural features are critical in the interaction between two biological organisms, for example, a microorganism and the surface of a plant. However, isolating the structural effect of the interaction from all other parameters is challenging when working directly with the natural system. Replicating microstructure of leaves was recently shown to be a powerful research tool for studying leaf-environment interaction. However, no such tool exists for roots. Roots present a special challenge because of their delicacy (specifically of root hairs) and their 3D structure. We aim at developing such a tool for roots.

Methods

Biomimetics use synthetic systems to mimic the structure of biological systems, enabling the isolation of structural function. Here we present a method which adapts tools from leaf microstructure replication to roots. We introduce new polymers for this replication.

Results

We find that Polyurethane methacrylate (PUMA) with fast UV curing gives a reliable replication of the tomato root surface microstructure. We show that our system is compatible with the pathogenic soilborne bacterium Ralstonia solanacearum.

Conclusions

This newly developed tool may be used to study the effect of microstructure, isolated from all other effects, on the interaction of roots with their environment.

     

Transcallosal conduction in paroxysmal kinesigenic dyskinesia

Objectives: Detecting whether a possible disequilibrium between the excitatory and inhibitory interhemispheric interactions in paroxysmal kinesigenic dyskinesia (PKD) exists.

Methods: This study assessed measures of motor threshold, motor evoked potential latency, the cortical silent period, the ipsilateral silent period and the transcallosal conduction time (TCT) in PKD patients. Data were compared between the clinically affected hemisphere (aH) and the fellow hemisphere (fH).

Results: The transcallosal conduction time from the aH to the fH was 11.8?ms (range?=?2.3–20.7) and 13.6?ms (range?=?2.8–67.7) from the fH to the aH. The difference in TCT in the affected side was significant (p?=?.019).

Conclusion: The findings demonstrated that, although inhibitory interneurons act normally and symmetrically between the motor cortices and transcallosal inhibition was normal and symmetrical between both sides, the onset of transcallosal inhibition was asymmetrical. The affected hemisphere’s inhibition toward the unaffected hemisphere is faster compared to the inhibition provided by the fellow hemisphere. These results are consistent with an inhibitory deficit in the level of interhemispheric interactions.

Significance: This study revealed a defect in inhibition of the motor axis could be responsible in the pathological mechanisms of kinesigenic dyskinesia.     

Use of 1H NMR to study transport processes in porous biosystems

The operation of bioreactors and the metabolism of microorganisms in biofilms or soil/sediment systems are strongly dictated by the transport processes therein. Nuclear magnetic resonance (NMR) spectroscopy or magnetic resonance imaging (MRI) allow nondestructive and noninvasive quantification and visualisation (in case of MRI) of both static and dynamic water transport phenomena. Flow, mass transfer and transport processes can be measured by mapping the (proton) displacement in a defined time interval directly in a so-called pulsed field gradient (PFG) experiment. Other methods follow the local intensity in time-controlled sequential images of water or labelled molecules, or map the effect of contrast agents. Combining transport measurements with relaxation-time information allows the discrimination of transport processes in different environments or of different fluids, even within a single picture element in an image of the porous biosystem under study. By proper choice of the applied NMR method, a time window ranging from milliseconds to weeks (or longer) can be covered. In this paper, we present an overview of the principles of NMR and MRI techniques to visualise and unravel complex, heterogeneous transport processes in porous biological systems. Applications and limitations will be discussed, based on results obtained in (model) biofilms, bioreactors, microbial mats and sediments. Journal of Industrial Microbiology & Biotechnology (2001) 26, 43–52. Received 20 April 2000/ Accepted in revised form 14 August 2000