Why do symbiotic copepods matter?

Currently, less than 10% of the members of the World Association of Copepodologists are working actively on symbiotic copepods. This surprisingly small guild of workers is thought to result from a general lack of understanding of the importance of symbiotic copepods. Symbiotic copepods as a whole comprise more than one-third (4224/11956 or 35.33%) of known copepods. They are found not only in the five major orders of Copepoda (Calanoida, Harpacticoida, Cyclopoida, Poecilostomatoida and Siphonostomatoida), but also in association with all major phyla of marine animals, ranging from sponges up to mammals (cetaceans). Discussion on these subjects is augmented with information on the impact of symbiotic copepods on aquaculture, and their exhibition of unusual biological phenomena. It is concluded that copepodologists today need to pay more attention to the symbiotic copepods, if copepodology is to become a major subject of modern biological sciences.     

A new species of Epichloë symbiotic with Chinese grasses

Epichlo? species are fungal symbionts (endophytes) of grasses, six European and four North American biological species in genus Epichlo? have been described in previous researches. In this study we describe a new Epichlo? species, Epichlo? yangzii Li et Wang, found in natural symbioses with Roegneria kamoji native to China. We investigated the host specificity, morphology, interfertility tests and molecular phylogenetic evidences of this new species. The results indicated that E. yangzii is host specific and seedborne. Most morphological characteristics of this new species are typical in the genus. However differences are evident in several features including size of perithecia, asci and ascospores. In mating tests E. yangzii was not interfertile with E. elymi isolates from related hosts in genera Elymus. Phylogenetic relationships based on sequences of beta-tubulin gene (tub2) introns and translation elongation factor 1-alpha gene (tef1) introns showed that members of the new species grouped into exclusive clades with high bootstrap value.     

Is Necator americanus approaching a mutualistic symbiotic relationship with humans?

The hookworm Necator americanus establishes infections of impressive longevity in the immunologically hostile environment of its human host. In the process, it promotes pronounced T-helper 2 (Th2) cell activity, which in turn seemingly affords the host at least a degree of protection. Given the relatively asymptomatic nature of infection, we argue here that Necator americanus might be approaching a mutualistic symbiotic relationship with humans. In our view, infection is controlled by the immune system while being supported by a subtle immune-evasion strategy that is tolerated and possibly beneficial to the host in certain immunological circumstances, such as in counterbalancing potentially damaging Th1 responses.     

Volatile compounds from the symbiotic system Azolla filiculoides‐Anabaena azollae bacteria

Abstract

Azolla filiculoides is an aquatic pteridophyte that may be used as animal food, biofertilizer and phytoremediation. Its volatile composition was never studied although several phytochemical analyses were performed. The volatile composition of A. filiculoides grown outdoors in a pond at the Botanical Garden of Lisbon University (BGLU) or in culture conditions as well as the effect of different harvesting times and the storage type were evaluated. The volatiles isolated by hydrodistillation and distillation‐extraction were analysed by gas chromatography and gas chromatography‐mass spectrometry. The oil of all the A. filiculoides samples studied affords a yellowish colour and an unpleasant odour in a yield of 0.01% (v/fw). Alcohols, aldehydes, alkanes and ketones dominated the culture samples, while aldehydes, alcohols, terpenoids and alkanes represented the main volatiles of the BGLU samples. Some quantitative differences were detected in seasonal and type of storage (fresh, dry or frozen at ?20°C) studies of A. filiculoides from the BGLU. The BGLU and culture volatiles showed qualitative differences: 2‐ethyl‐1‐hexanol was only identified in the fern culture, whereas acetophenone, pentylfuran, acetylpyridine and 2‐octanone were only detected in BGLU samples. The dendrogram showed two distinct clusters (culture and BGLU samples). The possible biological origin and bioactivity of some of the volatile compounds is discussed.

Abbreviations: FID, flame ionization detector; i.d., internal diameter; v/fw, volume by fresh weight; GC, gas chromatography; GC‐MS, gas chromatography‐mass spectrometry; u, unified atomic mass unit     

Sticky plant captures prey for symbiotic bug: is this digestive mutualism?

Many plants capture and kill insects but, until relatively recently, only carnivorous plants with digestive enzymes were known to gain directly from the nutrients of those insects. Recent studies show that some carnivorous plants lack digestive enzymes and have evolved digestive mutualisms with symbiotic insects that digest their prey for them. Rhododendron macrosepalum, a plant with sticky leaves that captures insects, has an association with symbiotic Mirid bugs that consume the insects captured. Here, we determine what the nature of the relationship is between Mirid and plant. We find that R. macrosepalum has no digestive enzymes of its own but that it does not seem to have the ability to absorb hemipteran faeces through its leaf cuticle. Naturally occurring levels of ¹⁵N and ¹⁴N were used to determine that R. macrosepalum gains no nitrogen through its association with the Mirid bugs and that it obtains all of its nitrogen from the soil. The Mirids, on the other hand, seem to obtain nitrogen from insects captured by the plant, as well as from plant tissues. The relationship between plant and Mirid is not a digestive mutualism but more likely an antagonistic relationship. This study adds to our understanding of how digestive mutualisms evolve and shows that insect capture alone, or in combination with a symbiotic insect relationship does not necessarily make a plant ‘carnivorous’.     

Does GABA increase the efficiency of symbiotic N2 fixation in legumes?

The ability to regulate the rates of metabolic processes in response to changes in the internal and/or external environment is a fundamental feature which is inherent in all organisms. This adaptability is necessary for conserving the stability of the intercellular environment (homeostasis) which is essential for maintaining an efficient functional state in the organism. Symbiotic nitrogen fixation in legumes is an important process which establishes from the complex interaction between the host plant and microorganism. This process is widely believed to be regulated by the host plant nitrogen demand through a whole plant N feedback mechanism in particular under unfavorable conditions. This mechanism is probably triggered by the impact of shoot-borne, phloem-delivered substances. The precise mechanism of the potential signal is under debate, however, the whole phenomenon is probably related to a constant amino acid cycling within the plant, thereby signaling the shoot nitrogen status. Recent work indicating that there may be a flow of nitrogen to bacteroids is discussed in light of hypothesis that such a flow may be important to nodule function. Large amount of γ-aminobutyric acid (GABA) are cycled through the root nodules of the symbiotic plants. In this paper some recent evidence concerning the possible role of GABA in whole-plant-based upregulation of symbiotic nitrogen fixation will be reviewed.Key words: γ-aminobutyric acid, nitrogen fixation, nodule, symbiosis, translocation, signalingNitrogen (N) is major limiting nutrient for the growth of most plant species in different ecosystems. Acquisition and assimilation of N is second in importance only to photosynthesis for plant growth and development. Elemental N is a key constituent of protein, nucleic acids and other vital cellular components. Most plants acquire N from the soil solution either as nitrate or ammonium ions. In addition, some plants can utilize the atmospheric gaseous nitrogen pool through symbiotic associations with species of bacteria, cyanobacteria or actinomycetes that contain the N₂ fixing enzyme, nitrogenase. Clearly, the crucial role that symbiotic plants play in plant growth requires that physiologists understand the biochemical and molecular events that regulate fixation and subsequent metabolism of nitrogen.Symbiotic N₂ fixation is an important process for increasing the plant available N and thereby the growth capacity of legumes. This process results from the complex interaction between the host plant and microorganism.¹ The host plant provides the microorganism with carbon and a source of energy for growth and functions while the microorganism fixes atmospheric N₂ and provides the plant with a source of reduced nitrogen in the form of ammonium. An adequate supply of carbohydrates is an essential requirement of nodule functioning as N₂ fixation is expensive in terms both of energy and carbon for the synthesis of N-products. Sucrose synthesized in photosynthesis and exported to the nodules via the phloem, is the primary fuel for N₂ fixation.² Sucrose can be metabolized in the cytoplasm of infected, uninfected or interstitial cells with organic acids as the end products. Malate is strongly believed to be the major respiratory substrate for bacteroids.³ This dicarboxylic acid is the major energy source for the bacteroids and plant mitochondria, and is used for NH₄⁺ assimilation as carbon skeleton in the glutamine synthetase/glutamate synthase (GS/GOGAT) pathway.⁴ The products of symbiotic N₂ fixation are exported from the nodules to the rest of the host plant where they are incorporated into essential macro-molecules such as amino acids, proteins that drive plant growth, development and yields. According to the fixation products, root nodules are generally divided into two major groupings:¹ (1) indeterminate nodules that are elongate-cylindrical activity that transport fixed N as amides such as alfalfa, pea and clover; and (2) determinate nodules that are spherical with determinate internal meristematic activity that transport fixed N as ureides, such as soybean and common bean. The complex series of events leading to the formation and functioning of the fixation machinery required controlled coordinated expression of both bacterial and host plant genes.     

Protection of host anemones by snapping shrimps: a case for symbiotic mutualism?

The sea anemone Bartholomea annulata is an ecologically important member of Caribbean coral reefs which host a variety of symbiotic crustacean associates. Crustacean exosymbionts typically gain protection from predation by dwelling with anemones. Concurrently, some symbionts may provide protection to their host by defending against anemone predators such as the predatory fireworm, Hermodice carunculata, which can severely damage or completely devour prey anemones. Herein we show through both field and laboratory studies that anemones hosting the symbiotic alpheid shrimp Alpheus armatus are significantly less likely to sustain damage by H. carunculata than anemones without this shrimp. Our results suggest that the association between A. armatus and B. annulata, although complex because of the numerous symbionts involved, may be closer to mutualism on the symbiotic continuum.     

Association between Wolbachia and Spiroplasma within Drosophila neotestacea: an emerging symbiotic mutualism?

Interspecific mutualism can evolve when specific lineages of different species tend to be associated with each other from one generation to the next. Different maternally transmitted endosymbionts occurring within the same cytoplasmic lineage fulfil this requirement. Drosophila neotestacea is infected with maternally transmitted Wolbachia and Spiroplasma, which are cotransmitted at high frequency in natural populations. Molecular phylogenetic evidence indicates that both endosymbionts have been present in D. neotestacea for considerable evolutionary periods. Thus, conditions are suitable for the evolution of mutualism between them. In support of this possibility, there is a significant positive association between Wolbachia and Spiroplasma infection in many samples of D. neotestacea from natural populations. Theoretically, such a positive association can result from either mutualism between these endosymbionts or recent spread. Collections from present‐day populations suggest that recent spread and mutualism have both operated to generate the positive association between Wolbachia and Spiroplasma. If selection acts on the combination of these two endosymbionts, they may be in the early stages of evolution of a more complex, cooperative association.     

Polyamine-induced changes in symbiotic parameters of the Galega orientalis–Rhizobium galegae nitrogen-fixing system

Plants of goat's rue (Galega orientalis) inoculated with Rhizobium galegae strain HAMBI 540 were grown in the presence of putrescine (Put), spermidine (Spd) or spermine (Spm), and several symbiotic characteristics were investigated to delineate the influence of polyamines (PA) on this nitrogen-fixing system. All three PA exerted a concentration-dependent effect on the nodule parameters tested. The increment of nodulation ability and nodule biomass accumulation was extreme (from 2.4- to 4.0-fold) when plants were subjected to 10 and 50 M of various PA. However, at 100 M a negative effect was observed. The acetylene-reduction activity of nodulated roots was increased also in response to treatment with the lower PA concentrations. The level of nitrogenase activity supported by succinate was significantly higher in bacteroids isolated from PA-treated nodules than in bacteroids from control nodules. The symbiotic parameters were also dependent on the type of PA used; the most effective being the diamine Put, while Spm showed a smaller physiological effect with respect to the others. Polyamines altered the ultrastructure of Galega nodule infected cells. After treatment with these substances, pronounced changes in the relative volume of the main components of infected cells and their compartments were observed. The significance of the structural observations and morphometric analyses, their relationship to differences in nitrogen fixation and possible modes of action are discussed.     

Outbreak and persistence of opportunistic symbiotic dinoflagellates during the 2005 Caribbean mass coral ‘bleaching’ event

Reef corals are sentinels for the adverse effects of rapid global warming on the planet''s ecosystems. Warming sea surface temperatures have led to frequent episodes of bleaching and mortality among corals that depend on endosymbiotic micro-algae (Symbiodinium) for their survival. However, our understanding of the ecological and evolutionary response of corals to episodes of thermal stress remains inadequate. For the first time, we describe how the symbioses of major reef-building species in the Caribbean respond to severe thermal stress before, during and after a severe bleaching event. Evidence suggests that background populations of Symbiodinium trenchi (D1a) increased in prevalence and abundance, especially among corals that exhibited high sensitivity to stress. Contrary to previous hypotheses, which posit that a change in symbiont occurs subsequent to bleaching, S. trenchi increased in the weeks leading up to and during the bleaching episode and disproportionately dominated colonies that did not bleach. During the bleaching event, approximately 20 per cent of colonies surveyed harboured this symbiont at high densities (calculated at less than 1.0% only months before bleaching began). However, competitive displacement by homologous symbionts significantly reduced S. trenchi''s prevalence and dominance among colonies after a 2-year period following the bleaching event. While the extended duration of thermal stress in 2005 provided an ecological opportunity for a rare host-generalist symbiont, it remains unclear to what extent the rise and fall of S. trenchi was of ecological benefit or whether its increased prevalence was an indicator of weakening coral health.     

The role of α-amylase of symbiotic microflora in digestion by lower cestodes and their fish hosts

The symbiotic microflora associated with the digestive-transport surfaces of the pike intestine and the parasitic cestodes Triaenophorus nodulosus proved capable of the initial stages of carbohydrate hydrolysis mediated by -amylase. The products of hydrolysis by -amylase can be used by both the host and the parasite, which decreases energy expenditures of the macroorganisms. The levels of the bacterial -amylase activity are comparable to those of the analogous enzyme absorbed on the mucosa of the intestine and on the cestode tegument, which indicates a considerable contribution of enzymes of the symbiotic microflora to digestion by the host and the parasite. Apparently, this contribution depends on the fish diet.Translated from Izvestiya Akademii Nauk, Seriya Biologicheskaya, No. 2, 2005, pp. 208–213.Original Russian Text Copyright © 2005 by Izvekova, Komova.     

A symbiotic relationship of energy metabolism between a ‘non-glycolytic’ mammalian red cell and the liver

The red cell of newborn pig loses the ability to carry out glycolysis within a month after birth. The metabolic energy source for this ‘non-glycolytic’ mammalian red cell is unknown. Hepatectomy of an adult pig results in the loss of red cell ATP with a characteristic half-time of 7–8 h which is identical to the rate with which ATP disappears in the pig cells under in vitro substrate-free incubation. Exposure of pig red cells with either normal or depleted levels of ATP to isolated hepatocytes causes a net synthesis of red cell ATP during a 12 h incubation. These findings suggest that a symbiotic relationship of energy metabolism may exist between the red cell and the liver of the pig.     

Cell cycle propagation is driven by light–dark stimulation in a cultured symbiotic dinoflagellate isolated from corals

Endosymbiosis is an intriguing plant–animal interaction in the dinoflagellate–Cnidaria association. Throughout the life span of the majority of corals, the dinoflagellate Symbiodinium sp. is a common symbiont residing inside host gastrodermal cells. The mechanism of regulating the cell proliferation of host cells and their intracellular symbionts is critical for a stable endosymbiotic association. In the present study, the cell cycle of a cultured Symbiodinium sp. (clade B) isolated from the hermatypic coral Euphyllia glabrescens was investigated using flow cytometry. The results showed that the external light–dark (L:D) stimulation played a pivotal role in regulating the cell cycle process. The sequential light (40–100 μmol m⁻² s⁻¹ ~ 12 h) followed by dark (0 μmol m⁻² s⁻¹ ~ 12 h) treatment entrained a single cell cycle from the G₁ to the S phase, and then to the G₂/M phase, within 24 h. Blue light (~450 nm) alone mimicked regular white light, while lights of wavelengths in the red and infrared area of the spectrum had little or no effect in entraining the cell cycle. This diel pattern of the cell cycle was consistent with changes in cell motility, morphology, and photosynthetic efficiency (F _v /F _m ). Light treatment drove cells to enter the growing/DNA synthesis stage (i.e., G₁ to S to G₂/M), accompanied by increasing motility and photosynthetic efficiency. Inhibition of photosynthesis by 3-(3, 4-dichlorophenyl)-1, 1-dimethyl-urea (DCMU) treatment blocked the cell proliferation process. Dark treatment was required for the mitotic division stage, where cells return from G₂/M to G₁. Two different pools of adenylyl cyclase (AC) activities were shown to be involved in the growing/DNA synthesis and mitotic division states, respectively. Communicated by Biology Editor Dr Michael Lesser     

Plant hydrolytic enzymes (chitinases and β-1,3-glucanases) in root reactions to pathogenic and symbiotic microorganisms

Within the last decade, a great deal of attention has been devoted to the role of chitinases and -1,3-glucanases in plant/microbe interactions. While there is strong evidence that these hydrolases are antifungal proteins, there are also recent indications of roles in both plant morphogenesis and plant/microbe signal perception. This paper reviews recent findings pertinent to root/microbe interactions, and discusses the nature and significance of specific hydrolase isoforms in symbioses with arbuscular mycorrhizal (AM) fungi.     

Short-range spatial variability of soil δ15N natural abundance – effects on symbiotic N2-fixation estimates in pea

The δ¹⁵N natural abundance (‰) of the total soil N pool varies at the landscape level, but knowledge on short-range variability and consequences for the reliability of isotopic methods are poorly understood. The short-range spatial variability of soil δ¹⁵N natural abundance as revealed by the ¹⁵N abundance in spring barley and N₂-fixing pea was measured within the 0.15–4 m scale at flowering and at maturity. The short-range spatial variability of soil δ¹⁵N natural abundance and symbiotic nitrogen fixation were high at both growth stages. Along a 4-m row, the δ¹⁵N natural abundance in barley reference plants varied up to 3.9‰, and sometimes this variability was observed even between plants grown only 30 cm apart. The δ¹⁵N natural abundance in pea varied up to 1.4‰ within the 4-m row. The estimated percentage of nitrogen derived from the atmosphere (%Ndfa) varied from 73–89% at flowering and from 57–95% at maturity. When increasing the sampling area from 0.01 m² (single plants) and up to 0.6 m² (14 plants) the %Ndfa coefficient of variation (CV) declined from 5 to 2% at flowering and from 12 to 2% at maturity. The implications of the short-range variability in δ¹⁵N natural-abundance are that estimates of symbiotic N₂-fixation can be obtained from the natural abundance method if at least half a square meter of crop and reference plants is sampled for the isotopic analysis. In fields with small amounts of representative reference crops (weeds) it might be necessary to sow in reference crop species to secure satisfying N₂-fixation estimates.     

Isolation and identification of entomopathogenic nematodes and their symbiotic bacteria from Hérault and Gard (Southern France)

Isolation and identification of native nematode-bacterial associations in the field are necessary for successful control of endemic pests in a particular location. No study has yet been undertaken to recover and identify EPN in metropolitan France. In the present paper, we provide results of a survey of EPN and their symbiotic bacteria conducted in Hérault and Gard regions in Southern France. Molecular characterization of isolated nematodes depicted three different Steinernema species and one Heterorhabditis species, H. bacteriophora. Steinernema species recovered were identified as: S. feltiae and S. affine and an undescribed species. Xenorhabdus symbionts were identified as X. bovienii for both S. feltiae and S. affine. Phylogenetic analysis placed the new undescribed Steinernema sp. as closely related to S. arenarium but divergent enough to postulate that it belongs to a new species within the “glaseri-group”. The Xenorhabdus symbiont from this Steinernema sp. was identified as X. kozodoii. All Heterorhabditis isolates recovered were diagnosed as H. bacteriophora and their bacterial symbionts were identified as Photorhabdus luminescens. Molecular characterization of these nematodes enabled the distinction of two different H. bacteriophora strains. Bacterial symbiontic strains of these two H. bacteriophora strains were identified as P. luminescens ssp. kayaii and P. luminescens ssp. laumondii.     

Chlorobium chlorochromatii sp. nov., a symbiotic green sulfur bacterium isolated from the phototrophic consortium “Chlorochromatium aggregatum”

A symbiotic green sulfur bacterium, strain CaD, was isolated from an enrichment culture of the phototrophic consortium “Chlorochromatium aggregatum”. The capability of the epibiont to grow in pure culture indicates that it is not obligately symbiotic. Cells are Gram-negative, nonmotile, rod-shaped and contain chlorosomes. Strain CaD is obligately anaerobic and photolithoautotrophic, using sulfide as electron donor. Acetate and peptone are photoassimilated in the presence of sulfide and hydrogencarbonate. Photosynthetic pigments contain bacteriochlorophylls a and c, and γ-carotene and OH-γ-carotene glucoside laurate as the dominant carotenoids. In cells from pure cultures, chlorosomes are equally distributed along the inner face of the cytoplasmic membrane. In contrast, the distribution of the chlorosomes in symbiotic epibiont cells is uneven, with chlorosomes being entirely absent at the site of attachment to the central bacterium. The symbiotic epibiont cells display a conspicuous additional layered structure at the attachment site. The G + C content of genomic DNA of strain CaD is 46.7 mol%. On the basis of 16S rRNA sequence comparison, the strain is distantly related to Chlorobium species within the green sulfur bacteria phylum (≤94.6% sequence homology). The novel isolate is therefore described as a novel species within the genus Chlorobium, Chlorobium chlorochromatii.