Daily Cleaning Activity and Diversity of Clients of the Barber Goby, Elacatinus figaro, on Rocky Reefs in Southeastern Brazil

Gobies of the genus Elacatinus are regarded as the most specialised cleaner fishes in the western tropical Atlantic, yet there are no studies on these cleaners in the southern portion of West Atlantic. We studied the diversity of clients and the daily cleaning activity of the barber goby, Elacatinus figaro, on rocky reefs in southeastern Brazil (23–24°S). A total of 34 fish client species in 16 families were recorded over 484 cleaning events. The most frequent clients were damselfishes, Pomacentridae (37.9% of cleaning events) and grunts, Haemulidae (16.9%). Planktivores were the most frequently attended trophic category, and two species in that category accounted for about a half (44%) of the total cleaning events. Size of clients ranged 4.5–55cm and most individuals were medium-sized (12–30cm); as the barber goby ranged 2–4.5cm, clients were 1.5 to 15 times larger than the cleaner was. Cleaning activity started at dawn and ended shortly before nightfall, the highest frequency of interactions occurring at early morning (nocturnal clients) and mid-afternoon (diurnal clients). By midday the frequency of cleaning events decreased and their duration increased. A total of 109±3 cleaning events and 30±1min of cleaning activity were estimated per cleaning station per day, both figures low when compared to those recorded for cleaner fishes in tropical areas of the western Atlantic and Indo-Pacific.     

Trehalose Is Not Relevant for In Vivo Activity of ςS-Containing RNA Polymerase in Escherichia coli

The ς^S- and ς⁷⁰-associated forms of RNA polymerase core enzyme (E) of Escherichia coli have very similar promoter recognition specificities in vitro. Nevertheless, the in vivo expression of many stress response genes is strongly dependent on ς^S. Based on in vitro assays, it has recently been proposed that the disaccharide trehalose specifically stimulates the formation and activity of Eς^S and thereby contributes to promoter selectivity (S. Kusano and A. Ishihama, J. Bacteriol. 179:3649–3654, 1997). However, we demonstrate here that a trehalose-free otsA mutant exhibits growth phase-related and osmotic induction of various ς^S-dependent genes which is indistinguishable from that of an otherwise isogenic wild-type strain and that stationary-phase cells do not accumulate trehalose (even though the trehalose-synthesizing enzymes are induced). We conclude that in vivo trehalose does not play a role in the expression of ς^S-dependent genes and therefore also not in sigma factor selectivity at the promoters of these genes.     

Mitochondrial Membrane Potential and DNA Stainability in Human Sperm Cells: A Flow Cytometry Analysis with Implications for Male Infertility

Sperm cells from control donors of proven fertility and men from barren couples were studied by conventional procedures, i.e., light microscopy as well as flow cytometry. Light microscopy analysis of semen included the measurement of spermatozoa concentration, morphology, and motility. All the men from barren couples were asthenozoospermic at the conventional analysis of semen samples. Flow cytometry was applied to study two important parameters of sperm cells: mitochondrial membrane potential (MMP) assessed by the cationic dye JC-1 and DNA stainability with propidium iodide (PI). JC-1 staining was more reliable than the classical procedure used for this purpose, i.e., rhodamine 123 (Rh123) staining, and allowed us to show a positive correlation between MMP and spermatozoa motility. Regarding DNA analysis, a higher relative percentage of immature spermatozoa, showing a high accessibility of DNA to the intercalating PI fluorochrome, was found in men from barren couples compared to donors of proven fertility. The relative percentage of immature spermatozoa was significantly higher in semen from oligoasthenozoospermic subjects. Moreover, a positive correlation was found between immature spermatozoa, as evaluated by PI staining, and cells with depolarized mitochondria, as evaluated by JC-1 staining, suggesting that spermatozoa defective for nuclear maturity could be functionally defective cells. No correlation between immature spermatozoa determined by FCM and immature spermatozoa determined by light microscopy was found, suggesting that these two techniques assess sperm cell maturity at different levels.     

ORIGIN AND BIOGEOGRAPHY OF AESCULUS L. (HIPPOCASTANACEAE): A MOLECULAR PHYLOGENETIC PERSPECTIVE

Sequences of chloroplast gene matK and internal transcribed spacers of nuclear ribosomal RNA genes were used for phylogenetic analyses of Aesculus, a genus currently distributed in eastern Asia, eastern and western North America, and southeastern Europe. Phylogenetic relationships inferred from these molecular data are highly correlated with the geographic distributions of species. The identified lineages closely correspond to the five sections previously recognized on the basis of morphology. Ancestral character-state reconstruction, a molecular clock, and fossil evidence were used to infer the origin and biogeographic history of the genus within a phylogenetic framework. Based on the molecular phylogenetic reconstruction of the genus, sequence divergence, and paleontological evidence, we infer that the genus originated during the transition from the Cretaceous to the Tertiary (~65 M.Y.B.P.) at a high latitude in eastern Asia and spread into North America and Europe as an element of the “boreotropical flora”; the current disjunct distribution of the genus resulted from geological and climatic changes during the Tertiary.     

Glucoamylase from Thermoanaerobacterium thermosaccharolyticum: Sequence studies and analysis of the macromolecular architecture of the enzyme

A chromosomal DNA fragment with a length of 2,025 bp, carrying the structural gene coding for glucoamylase in Thermoanaerobacterium thermosaccharolyticum, was cloned and sequenced. It coded for 695 amino acids, representing a polypeptide with a predicted molecular mass of 77.5 kDa. The deduced amino acid sequence exhibited high homologies with the glucoamylase sequence of another bacterial glucoamylase (Clostridium sp. G0005) and with fungal glucoamylases. The catalytic domain (amino acids 271 to 695) of the T. thermosaccharolyticum enzyme shared a high degree of similarity (five conserved regions) with the catalytic domain of Aspergillus awamori glucoamylase. By comparing the secondary structure of the sequence of the catalytic domain of the T. thermosaccharolyticum enzyme with that of glucoamylase from A. awamori, and on the basis of X-ray crystallographic data available for the A. awamori enzyme, it turned out that, most probably, both enzymes have a catalytic domain organized into an "(alpha/alpha)(6)-barrel" and an overall size and shape that is very similar. These findings confirm and extend our working model for the macromolecular architecture of the T. thermosaccharolyticum glucoamylase obtained, in earlier experiments, by electron microscopy of negatively stained isolated enzyme molecules. Antibodies for an enzyme-specific peptide located near the active site were successfully applied for inhibition studies of enzyme activity and for electron microscopic epitope mapping. A study comparing the site of attachment of this kind of antibody to the T. thermosaccharolyticum glucoamylase molecule with the expected attachment site as deduced from the A. awamori enzyme structure confirmed the close similarity of both glucoamylases regarding the macromolecular architecture of that part of the enzyme carrying the catalytic center, though helices H9, H10, and H11 in peripheral parts of the A. awamori enzyme are missing in the T. thermosaccharolyticum enzyme.     

Intergeneric Transfer of Conjugative and Mobilizable Plasmids Harbored by Escherichia coli in the Gut of the Soil Microarthropod Folsomia candida (Collembola)

The gut of the soil microarthropod Folsomia candida provides a habitat for a high density of bacterial cells (T. Thimm, A. Hoffmann, H. Borkott, J. C. Munch, and C. C. Tebbe, Appl. Environ. Microbiol. 64:2660–2669, 1998). We investigated whether these gut bacteria act as recipients for plasmids from Escherichia coli. Filter mating with E. coli donor cells and collected feces of F. candida revealed that the broad-host-range conjugative plasmid pRP4-luc (pRP4 with a luciferase marker gene) transferred to fecal bacteria at estimated frequencies of 5.4 × 10⁻¹ transconjugants per donor. The mobilizable plasmid pSUP104-luc was transferred from the IncQ mobilizing strain E. coli S17-1 and less efficiently from the IncF1 mobilizing strain NM522 but not from the nonmobilizing strain HB101. When S17-1 donor strains were fed to F. candida, transconjugants of pRP4-luc and pSUP104-luc were isolated from feces. Additionally, the narrow-host-range plasmid pSUP202-luc was transferred to indigenous bacteria, which, however, could not maintain this plasmid. Inhibition experiments with nalidixic acid indicated that pRP4-luc plasmid transfer took place in the gut rather than in the feces. A remarkable diversity of transconjugants was isolated in this study: from a total of 264 transconjugants, 15 strains belonging to the alpha, beta, or gamma subclass of the class Proteobacteria were identified by DNA sequencing of the PCR-amplified 16S rRNA genes and substrate utilization assays (Biolog). Except for Alcaligenes faecalis, which was identified by the Biolog assay, none of the isolates was identical to reference strains from data banks. This study indicates the importance of the microarthropod gut for enhanced conjugative gene transfer in soil microbial communities.Gene transfer is a process by which bacterial populations substantially increase their rates of evolution and adaptation (12, 59). Particularly, plasmid-located genes, which are transferred by conjugation from donor to recipient cells, can disseminate rapidly between even phylogenetically different bacterial groups (17, 36, 41) and microbial communities in different spatial habitats (34, 71). Such microbial genetic networks should be considered in risk assessments of releases of genetically engineered microorganisms into the environment (22, 37, 43). The probability and rate of plasmid transfer from a donor to indigenous microorganisms in a given habitat are influenced by plasmid-borne genes which determine the type of transfer mechanism (self-transmissible or mobilizable) and the host range of autonomous plasmid replication. Additionally, specific physicochemical conditions, such as temperature, water potential, and the availability of energy (substrates) for donor and recipient cells, are important factors influencing gene transfer rates in terrestrial and aquatic environments (23, 53, 64).The spread of plasmid-borne genes is still extremely difficult to predict for terrestrial habitats, since a large variety of microhabitat conditions which are not well characterized exists. In bulk soil under laboratory conditions, conjugative gene transfer from recombinant bacterial donor strains to indigenous soil bacteria has been found only under specific selective conditions or on rare occasions (11, 20, 24, 27, 50, 61). Several studies failed to detect such transfer events, and it was concluded that heterogeneity and low densities of recipient cells, as well as a lack of substrates for microbial metabolism, prevented efficient plasmid transfer in bulk soil (19, 49, 54, 75). Plant exudates increased rates of gene transfer in soil (33, 48), and higher rates of gene transfer were found in rhizospheres than in bulk soil (50, 61). It was assumed that other microsites which favor gene transfer in terrestrial habitats are associated with soil invertebrates (74). However, to date little experimental evidence to prove this assumption is available.Intraspecies transconjugants of added Enterobacter cloacae donor and recipient cells could be isolated from microcosm experiments with the variegated cutworm, Peridroma saucia, and plant material (2). The investigators in that study concluded that gene transfer events happened, most likely, in the digestive tracts or in the feces of the insects. Another recent report demonstrated that a conjugative plasmid was transferred between fed Escherichia coli strains in the guts of Rhabditis nematodes (1). Earthworms mediated transport and enhanced plasmid transfer from added donor cells to added recipients and to indigenous bacteria in soil (14, 15). High rates of intraspecies plasmid transfer, comparable to those obtained in pure broth cultures, were detected with Bacillus thuringiensis in infected lepidopterous larvae (31).Microarthropods (collembolans and mites) are the most abundant invertebrate group in the majority of soils (5) but have not been recognized, so far, for their impact on microbial gene transfer. There are some indications that microarthropods harbor a large variety of microorganisms in their guts and thereby contribute to microbial biodiversity in terrestrial environments (7, 9, 57). In the accompanying paper, we have described the gut of Folsomia candida (Collembola) as a habitat and species-specific vector for microorganisms (67). The gut of this soil-dwelling insect, which has a volume of only several nanoliters, was found to be densely colonized, predominantly by rod-shaped bacterial cells. We were interested to know whether such bacterial cells act as recipients for plasmids and thereby promote gene transfer in microbial communities. F. candida feeds, under natural conditions, on bacteria (3), fungal mycelia (6, 66), and nematodes (35). Here, we report on the results of experiments in which plasmid-bearing E. coli strains were fed to F. candida in microcosms. Self-transferable plasmids, as well as mobilizable plasmids with different host ranges, and a nonmobilizable plasmid were included in this study in order to determine the specific capacities of these different classes of plasmids to spread into indigenous bacterial populations. For detection purposes, all plasmids were engineered by the insertion of the luciferase-encoding marker gene luc or lux (30, 47).     

The Interleukin-17 Gene of Herpesvirus Saimiri

In comparison to wild-type herpesvirus saimiri, viral interleukin-17 gene knockout mutants have unaltered behavior regarding viral replication, T-cell transformation in vitro, and pathogenicity in cottontop tamarins. Thus, this gene is not required for T-cell lymphoma induction but may contribute to apathogenic viral persistence in the natural host, the squirrel monkey.