Adaptive advantages of patterns of growth and asexual reproduction of the sea anemone Metridium senile (L.) in intertidal and submerged populations

Individual size, rate of growth, and mode and frequency of asexual reproduction are life-history traits of primary importance for sea anemones. These traits determine sexual reproductive output, affect an individual's probability of survival, and are crucial in adapting an individual to its environmental surroundings. The sea anemone Metridium senile (L.) is highly variable in ecological distribution and life history, including rate of growth, individual size, and rate of asexual reproduction. Gonad size (measured as cross-sectional area of gonadal tissue) increases with body weight, so individuals should grow as large and as rapidly as possible to maximize individual sexual reproductive output. Cessation of growth and small body size in intertidal populations suggest that growth is constrained by genetic or environmental conditions. The growth of intertidal individuals transplanted to harbor-float panels demonstrated that growth limits are imposed by environmental factors, most probably limited food and feeding time and damage from wave exposure (which stimulates fragmentation). Individuals in harbor-float populations, which are continuously immersed, grow much larger, and large individuals comprise a greater proportion of the population than in the intertidal zone. The highest rate of fragmentation observed was on harbor-float panels. Patterns of growth and asexual reproduction provide adaptive advantages for M. senile. For harborfloat individuals, large individual size increases gamete production and may increase feeding efficiency. For intertidal individuals, asexual reproduction allows growth despite individual size constraints and rapid population growth, with specific advantages resulting from clone formation.     

Bacterial aggregates in the tentacles of the sea anemone <Emphasis Type="Italic">Metridium senile</Emphasis>

This paper provides first information on organ-like bacterial aggregates in the tentacles of the sea anemone Metridium senile. The specimens were collected from waters near Helgoland (German Bight, North Sea) and the Orkney Islands. Tentacles were prepared for morphological inspection by light and scanning electron microscopy as well as for the phylogenetic analysis of endocytic bacteria. Bacterial aggregates are located in caverns of the tentacles’ epidermis. The aggregates are enwrapped in thin envelopes, which contain coccoid and/or rod-shaped tightly packed bacteria of different division states. Most of the bacterial cells are connected by fine filamentous structures. The phylogenetic determination is based on the sequence data of the 16S rDNA derived from tentacle material. Sequence analysis revealed three different subgroups of intratentacular proteobacteria. The dominant band, detected in all of the samples tested, showed a close relationship (98%) to a gram-negative Endozoicimonas elysicola. Two bands, only detected in tentacles of M. senile from Helgoland were assigned to Pseudomonas saccherophilia (99%), a knallgas bacterium, and to Ralstonia pickettii (100%). The bacteria represent a specific bacterial community. Their DGGE profiles do not correspond to the profiles of the planktonic bacteria generated from seawater close to the habitats of the anemones. The allocation of DNA sequences to the different morphotypes, their isolation, culturing and the elucidation of the physiological functions of intratentacular bacteria are in progress.     

Structural organization of collagen in Metridium senile

The structure and distribution of collagen fibres in Metridium senile mesoglea has been investigated using high and small angle X-ray diffraction techniques on conventional and synchrotron sources. The mesoglea collagen axial spacing appears very close to that of rat tail tendon, which is at variance with the values previously obtained from electron microscopic observations. The different intensity distribution of the small angle X-ray diffraction maxima recorded for mesoglea and rat tail tendon indicates a different distribution of electron density inside the repeating period. Furthermore the absence of the first order, the weak second order and the strong third and sixth orders in the patterns of wet and dry mesogleal collagen could explain that only a periodicity of 20–22 nm corresponding to one-third of the true axial period observed in the electron micrographs. The analysis of the reflections at 0.29 and 1.1–1.4 nm characteristics of the collagen molecular structure have been used to determine the distribution and orientation of the collagen fibres in unstretched and stretched samples     

Evolutionary genetics of Metridium senile. I. Kinetic differences in phosphoglucose isomerase allozymes

Populations of the sea anemone Metridium senile from the northeast coast of the United States exhibit a one-locus, two-allele polymorphism for phosphoglucose isomerase. No additional hidden variation is exposed by changes in pH, gel pore size, or heat denaturation. The allozymes are similar in pH optimum, sensitivity of K _m to pH, and sensitivity of K _m and V _max to temperature. In other respects they are functionally different, with the fast allozyme having a 3.5-fold higher specific activity and a slightly higher K _m of fructose-6-phosphate than the slow form. In these respects, heterozygotes produce a mixture of enzymes that appears to function roughly as the sum of its component parts. Comparisons of V _max/K _m ratios reveal significant differences among genotypes, with the fast form having higher values at all temperatures than the slow form and heterozygotes falling intermediate. In addition, there is a significant difference among genotypes in sensitivity of this parameter to temperature, with the fast homozygote and heterozygote displaying greater sensitivity than the slow homozygote. Temperature is probably an important selective agent in maintaining this polymorphism.Supported by Grant T-4 from the Health Research and Services Foundation, NSF DEB77-14442, NIH GM25809, and NIH GM28024.     

Mitochondrial DNA of the sea anemone,Metridium senile (Cnidaria): Prokaryote-like genes for tRNAf-Met and small-subunit ribosomal RNA,and standard genetic code specificities for AGR and ATA codons

The nucleotide sequence of a segment of the mitochondrial DNA (mtDNA) molecule of the sea anemone Metridium senile (phylum Cnidaria, class Anthozoa, order Actiniaria) has been determined, within which have been identified the genes for respiratory chain NADH dehydrogenase subunit 2 (ND2), the small-subunit rRNA (s-rRNA), cytochrome c oxidase subunit II(COII), ND4, ND6, cytochrome b (Cyt b), tRNA^f-Met, and the large-subunit rRNA (1-rRNA). The eight genes are arranged in the order given and are all transcribed from the same strand of the molecule. The overall order of the M. senile mt-genes differs from that of other metazoan mtDNAs. In M. senile mt-protein genes, AGA and AGG codons appear to have the standard genetic code specification of arginine, rather than serine as found for other invertebrate mt-genetic codes. Also, ATA has the standard genetic code specification of isoleucine. TGA occurs in three M. senile mt-protein genes and may specify tryptophan as in other metazoan, protozoan, and some fungal mt-genetic codes. The M. senile mt-rRNA^f-Met gene has primary and secondary structure features closely resembling those of the Escherichia coli initiator tRNA, including standard dihydrouridine and TC loop sequences and a mismatch pair at the top of the aminoacyl stem. Determinations of the 5 and 3 end nucleotides of the M. senile mt-srRNAs indicated that these molecules have a homogenous size of 1,081 ntp, larger than any other known metazoan mt-s-rRNAs. Consistent with its larger size, the M. senile mt-s-rRNA can be folded into a secondary structure that more closely resembles that of the E. coli 16S rRNA than can any other metazoan mt-s-rRNA. These findings concerning M. senile mtDNA indicate that most of the unusual features regarding metazoan mt-genetic codes, rRNAs, and probably tRNAs developed after divergence of the Cnidarian line from the ancestral line common to other metazoa.Correspondence to: D.R. Wolstenholme     

Effects of long-term ultraviolet radiation: the white form of Metridium senile (Anthozoa: Actiniaria) as a potential biological indicator for ultraviolet

Genetically identical individuals of the white form of Metridium senile were kept in the laboratory for 40 months, during almost 2 years of which they were irradiated with ultraviolet (UV) radiation simulating the shape of the solar UV spectrum. The living and experimental conditions were largely matched to the conditions in the sea anemones' natural habitat on the North Sea coast. Controls were shielded from direct radiation or irradiated with only the visible range of the spectrum; for the UV tests, the UV component corresponded either to the conditions in the natural habitat or to twice or 4 times this dose. All experiments were preceded by a several-month settling-in period, and UV irradiation was always begun at a low intensity. Under these conditions UV was not lethal but produced many parameter changes, of which only those that were irreversible for the entire duration of the experiment, from September 1992 to August 1994, are described here. The body mass fell significantly in all three UV-radiation modes. All irradiated animals positioned themselves so as to be less exposed to the radiation, and all changed colour from white to brown. These responses are discussed with reference to the potential of M. senile as an indicator or monitor for UV in the northern European coastal region. Field analyses are currently being conducted to demonstrate the extent to which the present results apply to field conditions. Received in revised form: 30 May 2000 Electronic Publication     

Evolutionary genetics of Metridium senile. II. Geographic patterns of allozyme variation

Electrophoretic surveys have demonstrated that populations of the sea anemone Metridium senile along the northeast coast of the United States are polymorphic at four enzyme loci. Phosphoglucose isomerase (PGI) has two alleles in most populations, phosphoglucomutase (PGM) has three alleles, and two leucine aminopeptidase loci have two common alleles each. Phosphoglucose isomerase displays clinal variation and an apparent association with environmental temperature. Phosphoglucomutase shows clinal variation north of Cape Cod for two of the three alleles, while the two leucine aminopeptidase loci are not clinal. All loci show a great deal of variation in populations on Cape Cod, but there is no apparent systematic pattern to this variation. Temperature may be a selective agent in the maintenance of the PGI and PGM clines, although other possibilities cannot presently be completely excluded.Supported by Grant T-4 from the Health Research and Services Foundation, NSF DEB77-14442, NIH GM25809, and NIH GM28024.     

Cladistic and phenetic analysis of allozyme data for nine species of sea anemones of the family Actiniidae (Cnidaria: Anthozoa)

The aim of this study was to infer from allozyme data the phylogenetic relationships of nine species of actiniid sea anemones, and also use these data to assess the various methods (phenetic and cladistic) available for phylogenetic analysis. Starch gel electrophoresis was used to obtain genetic data from 13 gene loci. The anemone Metridium senile, from the family Metridiidae, was used as an outgroup. For the phenetic analysis a matrix of pairwise unbiased genetic distances was computed and, from this, dendrograms were produced both by the Wagner distance and the UPGMA methods. For the cladistic analyses three different approaches were used: the first was to treat the allele as a binary character; this was investigated using a Wagner parsimony algorithm. Another approach used was to consider the locus as an unordered character, using the alleles as states. Finally, we used the locus as an ordered multistate character, where mutation, fixation and elimination of each allele were treated as evolutionary novelties, and the heterozygotes were used as cues for the construction of transformation series. The trees produced by the phenetic and cladistic methods were highly congruent. This result suggests that allozymes can be used to produce phylogenetic hypotheses at higher taxonomic levels than those at which they are more usually employed. The Solé difference between the various trees was the relative positions of Bunodosoma caissarum and Bunodactis verrucosa in relation to the two species of Urticina. This difference was probably due to a high rate of anagenic change in B. verrucosa, which distorted the UPGMA dendrogram. The genera Actinia and Urticina appeared monophyletic in all of the trees produced. Also, the sea anemones with specialized column structures such as verrucae and vesicles (U.felina, U. eques, B. verrucosa, B. caissarum) formed a monophyletic cluster, a result compatible with the suggestion that these structures may have appeared only once in the evolutionary history of the Actiniidae.