Intracellular Symbiosis and Energetic Role of Bacteria in Gill Epithelium of Freshwater Mollusks and Fishes

Penetration of bacteria by endocytosis into gill epithelial cells has been revealed in animals of different evolutionary levels (freshwater mollusks and fishes). These data confirm the leading role of endosymbiosis in the origin of eukaryotes from prokaryotes and in the evolution of animal life.     

Food-storing birds: adaptive specialization in brain and behaviour?

Among the passerine birds, species that store food have an enlarged hippocampal region (dorso-medial cortex), relative to brain and body size, when compared with the non-storers. The volume of one of the major afferent-efferent pathways (the septo-hippocampal pathway) is also greater in food storing species. This specialization of brain structure is discussed in relation to behavioural studies in which the spatial memory of storing and non-storing species has been compared.     

Endosymbiotic bacteria as a source of carotenoids in whiteflies

Although carotenoids serve important biological functions, animals are generally unable to synthesize these pigments and instead obtain them from food. However, many animals, such as sap-feeding insects, may have limited access to carotenoids in their diet, and it was recently shown that aphids have acquired the ability to produce carotenoids by lateral transfer of fungal genes. Whiteflies also contain carotenoids but show no evidence of the fungus-derived genes found in aphids. Because many sap-feeding insects harbour intracellular bacteria, it has long been hypothesized that these endosymbionts could serve as an alternative source of carotenoid biosynthesis. We sequenced the genome of the obligate bacterial endosymbiont Portiera from the whitefly Bemisia tabaci. The genome exhibits typical signatures of obligate endosymbionts in sap-feeding insects, including extensive size reduction (358.2 kb) and enrichment for genes involved in essential amino acid biosynthesis. Unlike other sequenced insect endosymbionts, however, Portiera has bacterial homologues of the fungal carotenoid biosynthesis genes in aphids. Therefore, related lineages of sap-feeding insects appear to have convergently acquired the same functional trait by distinct evolutionary mechanisms—bacterial endosymbiosis versus fungal lateral gene transfer.     

Variation of food spectra of tube-nosed goby <Emphasis Type="Italic">Proterorhinus marmoratus</Emphasis> (Perciformes,Gobiidae)—a new species in the Rybinsk Reservoir

Size-age structure and food composition of tube-nosed goby Proterorhinus marmoratus in the Rybinsk Reservoir have been studied. It was shown that food spectra changed in the process of dispersal of this species over the water body and considerably vary during the season. In the period of naturalization, feeding of the tube-nosed goby is characterized by group specialization; the object of specialization is Gmelinoides. Having dispersed over the water body and naturalized, it manifested itself as a generalist; its food composition became diverse and was determined by the seasonal dynamics of the population and biomass of food items.     

Epizoic bacteria on the foot of the Antarctic bivalve, Lissarca notorcadensis Melville and Standen, 1907 (Filibranchia: Philobryidae)

Specimens of the epizoic bivalve Lissarca notorcadensis Melville and Standen, 1907 (Philobryidae) were collected from the spines of cidaroid sea-urchins in the Weddell Sea during austral summer 1991. Soft tissues were investigated by means of transmission electron microscopy. Epizoic bacteria were discovered on the foot in 14 out of 15 specimens of the bivalve, and in juveniles as well as in adults. The presence of bacteria was restricted to a certain area of the foot's surface, where they were populating the brushborder of the epidermal epithelium. This is the first time that epizoic bacteria have been described, either from an Antarctic bivalve or from the foot epithelium of any bivalve species. Aspects of the fine structure were studied with regard to future work on this symbiosis. The bacteria undergo a full life-cycle in the brushborder. Whereas young or dividing bacteria are found more distally between the microvilli, senescent stages seem to disintegrate and be absorbed between their bases. The bacteria could contribute to the nutrition of their host by breaking down macromolecular or particulate organic matter, which would facilitate parenteral absorption by the bivalve, as well as eventual digestion. The ultrastructural findings suggest that the bacteria are neither sulphidotrophic nor methylotrophic. Based on their appearance, they are classified as sub-cuticular bacteria, which have been recently described from the surface epithelia in various marine invertebrate species. The phenomenon is discussed in respect to seasonal food limitation for Antarctic suspension feeders and the brooding behaviour of the host species and its ecological success. Received: 26 April 1996 / Accepted: 8 September 1996     

弓背蚁属蚂蚁初级内共生菌Blochmannia的研究进展

昆虫与其体内细菌的互利共生关系是近十余年来生物学家关注的热点领域,也是研究物种间协同进化的理想模型。Blochmannia是蚁科弓背蚁属Camponotus蚂蚁体内的初级内共生菌,作为最早被描述的动物与细菌之间的共生关系,Blochmannia在帮助宿主蚂蚁合成食物中所缺少的必需营养物质、维持生长发育、繁殖和营养代谢等方面发挥重要作用。本文从Blochmannia的分布规律、母系传播、基因组特征及其功能等方面进行综述,以期为相关研究提供参考和借鉴。     

Endosymbionts in paramecium

Paramecium species are extremely valuable organisms to enable experiments for the reestablishment of endosymbiosis. This is investigated in two different systems, the first with Paramecium caudatum and the endonuclear symbiotic bacterium Holospora species. Although most endosymbiotic bacteria cannot grow outside the host cell as a result of their reduced genome size, Holospora species can maintain their infectivity for a limited time. We found that an 89-kDa periplasmic protein has an important function for Holospora's invasion into the target nucleus, and that Holospora alters the host gene expression; the host thereby acquires resistance against various stresses. The second system is the symbiosis between P. bursaria and symbiotic Chlorella. Alga-free P. bursaria and the algae retain the ability to grow without a partner. Consequently, endosymbiosis between the aposymbiotic host cells and the symbiotic algae can be reestablished easily by mixing them. We now found four checkpoints for the reestablishment of the endosymbiosis between P. bursaria and the algae. The findings in the two systems provide excellent opportunities for us to elucidate not only infection processes but also to assess the associations leading to eukaryotic cell evolution. This paper summarizes recent progresses on reestablishment of the primary and the secondary endosymbiosis in Paramecium.     

Production of alkaline phosphatase by epithelial cells and adherent bacteria of the bovine rumen and abomasum

Three distinct bacterial populations have been defined in the bovine rumen: the rumen fluid population; the population associated with food particles; and the population adherent to the rumen epithelium. Alkaline phosphatase activity has been reported in cells of the first two populations and here we report that assays of rumen epithelial samples containing both tissue and bacteria also contain the enzyme. The reaction product technique has localized the enzyme both in adherent bacteria and in cell of the stratified squamous rumen epithelium. The epithelium of the abomasum shows much lower levels of alkaline phosphatase activity.     

Opposed latitudinal patterns of network‐derived and dietary specialization in avian plant–frugivore interaction systems

Latitudinal patterns of biodiversity have been studied for centuries, but it is only during the last decades that species interaction networks have been used to examine the proposed latitudinal gradient of biotic specialization. These studies have given idiosyncratic results, which may either be because of genuine biological differences between systems, different concepts and scales used to quantify biotic specialization or because the methodological approaches used to compare interaction networks were inappropriate. Here we carefully examine the latitudinal specialization gradient using a global dataset of avian plant–frugivore assemblages and interaction networks. In particular, we test whether network‐derived specialization patterns differ from patterns based on assemblage‐level information on avian dietary preferences on specific food types. We found that network‐derived measures of specialization (complementary specialization H₂′ and < d’>, modularity Q) increased with latitude, i.e. frugivorous birds divide the niche of fruiting plants most finely at high latitudes where they also formed more modular interaction networks than at tropical latitudes. However, the strength and significance of the relationship between specialization metrics and latitude was influenced by the methodological approach. On the other hand, assemblage‐level information on avian specialization on fruit diet (i.e. the proportion of obligate frugivorous bird species feeding primarily on fruit) revealed an opposed latitudinal pattern as more bird species were specialized on fruit diet in tropical than in temperate assemblages. This difference in the latitudinal specialization gradient reflects that obligate frugivores require a high diversity of fruit plants, as observed in tropical systems, and fulfil more generalized roles in plant–frugivore networks than bird species feeding on different food types. Future research should focus on revealing the underlying ecological, historical and evolutionary mechanisms shaping these patterns. Our results highlight the necessity of comparing different scales of biotic specialization for a better understanding of geographical patterns of specialization in resource–consumer interactions.     

Evolution of signal transduction in intracellular symbiosis

Plant roots form intracellular symbioses with fungi and bacteria resulting in arbuscular mycorrhiza and nitrogen-fixing root nodules, respectively. A novel receptor like-kinase has been discovered that is required for the transduction of both bacterial and fungal symbiotic signals. This kinase defines an ancient signalling pathway that probably evolved in the context of arbuscular mycorrhiza and has been recruited subsequently for endosymbiosis with bacteria. An ancestral symbiotic interaction of roots with intracellular bacteria might have emerged from such a recruitment, in the progenitor of the nodulating clade of plants. Analysis of symbiotic mutants of host plants and bacterial microsymbionts has revealed that present-day endosymbioses require the coordinated induction of more than one signalling pathway for development.     

Implications of feeding specialization on the recruitment processes and community structure of butterflyfishes

Synopsis When settling on coral reefs, fish larvae generally change from zooplanktivory to diverse forms of benthic feeding. Whereas food has not been reported to directly influence settlement, it is hypothesized that food resource might play a major role in the recruitment processes of butterflyfishes. Benthic feeding was found to occur immediatly after settlement, and was related to the degree of specialization of adult diets. Among obligate coral feeders scleractinian polyps were the exclusive diet of new recruits. In non-obligate corallivorous chaetodontids tentacles of sedentarian polychaetes were the preferred prey of juveniles for all the species studied, and represented on average 36.2% of their prey by weight. They formed a transitional food resource for these species which mainly fed on scleratinian polyps when adults (51.6% by weight). Among the chaetodontids studies, some recruited within adult home sites, whereas others exhibited size-specific distributions. The different patterns observed were not closely related to food specialization of the adults. The importance of food resources to the community structure of butterflyfishes on coral reefs is discussed.     

The relationship between species richness of vertebrate mutualists and their food plants in tropical and subtropical communities differs among hemispheres

Non-random statistical patterns have long been of interest to community ecologists. Recent studies of communities of mutualists have revealed non-random patterns in terms of connectance, degree of specialization, and nestedness. Currently unstudied, however, are the detailed statistical relationships between tropical vertebrate mutualists and their food plants in different parts of the world. Here, I review 87 studies that quantify the relationship between species richness of nectar- or fruit-eating birds and bats and species richness of their food plants in New and Old World, mostly tropical, communities. This analysis revealed that in the New World, number of plant-visiting birds and bats per community was significantly correlated with number of food plants and that the slopes of regression equations were the same for nectarivores and frugivores. The New World quantitative assembly rule states that it takes about three species of flowers or fruits to support one species of plant-visiting bird or bat. This relationship does not appear to exist in Old World communities, in which species richness of nectar- or fruit-eating birds or bats was independent of species richness of their food plants. These geographic differences likely reflect a greater degree of feeding specialization in plant-visiting vertebrates in the New World than in the Old World. I hypothesize that hemispheric differences in the spatio-temporal predictability (STP) of food resources ultimately determine levels of dietary specialization and structure in communities of New and Old World plant-visiting vertebrates.     

The species composition of phytoplankton and its consumption at breeding sites for blood-sucking mosquitoes

The phytoplankton specific composition and the character of its consumption by larvae of blood-sucking mosquitoes have been determined. Blue-green (5 species), green (13 species), Euglenophyta (12 species) and diatoms (38 species) algae have been found in the breeding places of Culicidae. The diatoms prevailed in the food of larvae. Trophic specialization to the definite food components have not been found in larvae. Their intestines contained detritus, zooplankton and other components besides phytoplankton.     

Acid-base regulation in fishes: cellular and molecular mechanisms

The mechanisms underlying acid-base transfers across the branchial epithelium of fishes have been studied for more than 70 years. These animals are able to compensate for changes to internal pH following a wide range of acid-base challenges, and the gill epithelium is the primary site of acid-base transfers to the water. This paper reviews recent molecular, immunohistochemical, and functional studies that have begun to define the protein transporters involved in the acid-base relevant ion transfers. Both Na(+)/H(+) exchange (NHE) and vacuolar-type H(+)-ATPase transport H(+) from the fish to the environment. While NHEs have been thought to carry out this function mainly in seawater-adapted animals, these proteins have now been localized to mitochondrial-rich cells in the gill epithelium of both fresh and saltwater-adapted fishes. NHEs have been found in the gill epithelium of elasmobranchs, teleosts, and an agnathan. In several species, apical isoforms (NHE2 and NHE3) appear to be up-regulated following acidosis. In freshwater teleosts, H(+)-ATPase drives H(+) excretion and is indirectly coupled to Na(+) uptake (via Na(+) channels). It has been localized to respiratory pavement cells and chloride cells of the gill epithelium. In the marine elasmobranch, both branchial NHE and H(+)-ATPase have been identified, suggesting that a combination of these mechanisms may be utilized by marine elasmobranchs for acid-base regulation. An apically located Cl(-)/HCO(3)(-) anion exchanger in chloride cells may be responsible for base excretion in fresh and seawater-adapted fishes. While only a few species have been examined to date, new molecular approaches applied to a wider range of fishes will continue to improve our understanding of the roles of the various gill membrane transport processes in acid-base balance.     

Memory and Brain in Food‐Storing Birds: Space Oddities or Adaptive Specializations?

Scatterhoarding birds that cache food items have become an important model system for the study of spatial memory and its correlates in the brain. In particular, it has been suggested that through adaptive specialization, species that cache food have better spatial memory and a relatively larger hippocampus than their non-caching relatives. Critics of this approach, dubbed neuroecology, maintain that neither of these hypotheses has been confirmed. Here, we review the evidence pertaining to a correlation between food-storing capability and the relative volume of the hippocampus. Hippocampal volume has been related to food-storing behaviour in comparisons between species, within species, or within individuals, but the evidence is not consistent. There are several possible reasons for this inconsistency, including: (1) food-hoarding birds may not always use memory for retrieval, (2) there may be systematic differences between data from North American and Eurasian species that affect the analysis, and (3) sample sizes have in many cases been too small. In addition, both the independent variable (degree of food-hoarding specialization) and the dependent variable (relative volume of the hippocampus) are not clearly and consistently defined. Alternatively, it is possible that the neuroecological hypothesis is false. Systematic empirical research is necessary to determine whether or not food-storing birds have evolved adaptive specializations in brain and cognition.     

Asymmetries in specialization in ant-plant mutualistic networks

Mutualistic networks involving plants and their pollinators or frugivores have been shown recently to exhibit a particular asymmetrical organization of interactions among species called nestedness: a core of reciprocal generalists accompanied by specialist species that interact almost exclusively with generalists. This structure contrasts with compartmentalized assemblage structures that have been verified in antagonistic food webs. Here we evaluated whether nestedness is a property of another type of mutualism-the interactions between ants and extrafloral nectary-bearing plants--and whether species richness may lead to differences in degree of nestedness among biological communities. We investigated network structure in four communities in Mexico. Nested patterns in ant-plant networks were very similar to those previously reported for pollination and frugivore systems, indicating that this form of asymmetry in specialization is a common feature of mutualisms between free-living species, but not always present in species-poor systems. Other ecological factors also appeared to contribute to the nested asymmetry in specialization, because some assemblages showed more extreme asymmetry than others even when species richness was held constant. Our results support a promising approach for the development of multispecies coevolutionary theory, leading to the idea that specialization may coevolve in different but simple ways in antagonistic and mutualistic assemblages.     

Ultraviolet vision and foraging in terrestrial vertebrates

Tetrachromatic colour vision, based on four ‘main’ colours and their combinations, is probably the original colour vision in terrestrial vertebrates. In addition to human visible waveband of light (400–700 nm) and three main colours, it also includes the near ultraviolet part of light spectrum (320–400 nm). The ecological importance of ultraviolet (UV) vision in animals has mainly been studied in the context of intra‐ and inter‐sexual signalling, but recently the importance of UV vision in foraging has received more attention. Foraging animals may use either UV cues (reflectance or absorbance) of food items or UV cues of the environment. So far, all diurnal birds studied (at least 35 species), some rodents (4 species), many reptilians (11 species) and amphibians (2 species) are likely able to see near UV light. This probably allows e.g. diurnal raptors as well as frugivorous, nectarivorous and insectivorous birds to use foraging cues invisible to humans. The possible role of UV cues and existing light conditions should be taken into account when food selection of vertebrate animals is studied, particularly, in experiments with artificial food items.     

Formation of the photosensing system function in early development

The function of simple prototypic eyes in two planarian species, the two ocular Girardia tigrina and the multiocular Polycelis tenuis, has been studied. When exposed to light, planarians display the light avoidance reaction known as negative phototaxis. This reaction has been investigated in intact animals and in head and tail fragments after their section in the course of eye regeneration. Specific features of the phototaxis reaction have been described in all groups of animals. The differences in light response recovery were shown between two planarian species and two regenerating fragments. No correlation between phototaxic reactions and the restoration of the eye structure, the number of eyes, the maturation of ganglion, the growth of regenerative blastema, and motor system has been found. The phototaxic response occurred two days after the recovery of the morphology of eyes and their connection with the brain. The participation of conserved and novel genes in early development of the eye function is discussed.     

Formation of the function of the photosensing system in early development

The function of simple eyes in two planarian species, two-eyed Girardia tigrina and multi-eyed Polycelis tenuis, has been studied. When exposed to light, planarians display a light avoidance reaction known as negative phototaxis. This reaction has been investigated in intact animals and in head and tail fragments in the course of eye regeneration after their section. Specific features of the phototaxis reaction have been described in all groups of animals. The differences in light response recovery were shown between two planarian species and two regenerating fragments. No correlation has been found between phototactic reactions and restoration of eye structure, the number of eyes, maturation of the ganglion, growth of regenerative blastema, and motor system. The phototactic response occurred two days after the recovery of the morphology of eyes and their connection with the brain. The participation of conserved and novel genes in early development of the eye function is discussed.     

Distribution and localization of the digestive laminarinases in animals

The presence of laminarinases in the digestive system of a number of invertebrate and vertebrate species has been investigated. The enzymes were detected in coelenterates, annelids, sipunculids, bryozoans, molluscs, arthropods (crustaceans and insects), echinoderms, tunicates and fishes. Since it could be demonstrated that, in fishes, at least, laminarinases are secreted by the intestinal mucosa rather than by associated gut bacteria, an attempt was made to correlate the distribution of these digestive enzymes with the feeding habits of the animals. The correlation is particularly evident among fishes where in the genus Leuciscus carnivores lack laminarinases in contrast to omnivores. From an evolutionary point of view, we can postulate that the possession of laminarinases is ancient in Metazoa and has been either kept or lost by more evolved taxa depending on their feeding specialization, as has already been demonstrated for chitinases and cellulases.