A major difference between the divergence patterns within the lines-1 families in mice and voles

L1 retroposons are represented in mice by subfamilies of interspersed sequences of varied abundance. Previous analyses have indicated that subfamilies are generated by duplicative transposition of a small number of members of the L1 family, the progeny of which then become a major component of the murine L1 population, and are not due to any active processes generating homology within preexisting groups of elements in a particular species. In mice, more than a third of the L1 elements belong to a clade that became active approximately 5 Mya and whose elements are > or = 95% identical. We have collected sequence information from 13 L1 elements isolated from two species of voles (Rodentia: Microtinae: Microtus and Arvicola) and have found that divergence within the vole L1 population is quite different from that in mice, in that there is no abundant subfamily of homologous elements. Individual L1 elements from voles are very divergent from one another and belong to a clade that began a period of elevated duplicative transposition approximately 13 Mya. Sequence analyses of portions of these divergent L1 elements (approximately 250 bp each) gave no evidence for concerted evolution having acted on the vole L1 elements since the split of the two vole lineages approximately 3.5 Mya; that is, the observed interspecific divergence (6.7%-24.7%) is not larger than the intraspecific divergence (7.9%-27.2%), and phylogenetic analyses showed no clustering into Arvicola and Microtus clades.      

Multifactorial diversity sustains microbial community stability

Maintenance of a high degree of biodiversity in homogeneous environments is poorly understood. A complex cheese starter culture with a long history of use was characterized as a model system to study simple microbial communities. Eight distinct genetic lineages were identified, encompassing two species: Lactococcus lactis and Leuconostoc mesenteroides. The genetic lineages were found to be collections of strains with variable plasmid content and phage sensitivities. Kill-the-winner hypothesis explaining the suppression of the fittest strains by density-dependent phage predation was operational at the strain level. This prevents the eradication of entire genetic lineages from the community during propagation regimes (back-slopping), stabilizing the genetic heterogeneity in the starter culture against environmental uncertainty.     

Immunohistochemical localization of irisin in skin,eye, and thyroid and pineal glands of the crested porcupine (Hystrix cristata)

Irisin was first identified in muscle cells. We detected irisin immunoreactivity in various organs of the crested porcupine (Hystrix cristata). In the epidermis, irisin immunoreactivity was localized mainly in stratum basale, stratum spinosum and stratum granulosum layers; immunoreactivity was not observed in the stratum corneum. In the dermis, irisin was found in the external and internal root sheath, cortex and medulla of hair follicles, and in sebaceous glands. Irisin immunoreactivity was found in the neural retina and skeletal muscle fibers associated with the eye. The pineal and thyroid glands also exhibited irisin immunoreactivity.     

Analysis of the Escherichia coli Alp phenotype: heat shock induction in ssrA mutants

The major phenotypes of lon mutations, UV sensitivity and overproduction of capsule, are due to the stabilization of two substrates, SulA and RcsA. Inactivation of transfer mRNA (tmRNA) (encoded by ssrA), coupled with a multicopy kanamycin resistance determinant, suppressed both lon phenotypes and restored the rapid degradation of SulA. This novel protease activity was named Alp but was never identified further. We report here the identification, mapping, and characterization of a chromosomal mutation, faa (for function affecting Alp), that leads to full suppression of a Deltalon ssrA::cat host and thus bypasses the requirement for multicopy Kan(r); faa and ssrA mutants are additive in their ability to suppress lon mutants. The faa mutation was mapped to the C terminus of dnaJ(G232); dnaJ null mutants have similar effects. The identification of a lon suppressor in dnaJ suggested the possible involvement of heat shock. We find that ssrA mutants alone significantly induce the heat shock response. The suppression of UV sensitivity, both in the original Alp strain and in faa mutants, is reversed by mutations in clpY, encoding a subunit of the heat shock-induced ClpYQ protease that is known to degrade SulA. However, capsule synthesis is not restored by clpY mutants, probably because less RcsA accumulates in the Alp strain and because the RcsA that does accumulate is inactive. Both ssrA effects are partially relieved by ssrA derivatives encoding protease-resistant tags, implicating ribosome stalling as the primary defect. Thus, ssrA and faa each suppress two lon mutant phenotypes but by somewhat different mechanisms, with heat shock induction playing a major role.     

Evidence that the supE44 Mutation of Escherichia coli Is an Amber Suppressor Allele of glnX and that It Also Suppresses Ochre and Opal Nonsense Mutations

Translational readthrough of nonsense codons is seen not only in organisms possessing one or more tRNA suppressors but also in strains lacking suppressors. Amber suppressor tRNAs have been reported to suppress only amber nonsense mutations, unlike ochre suppressors, which can suppress both amber and ochre mutations, essentially due to wobble base pairing. In an Escherichia coli strain carrying the lacZU118 episome (an ochre mutation in the lacZ gene) and harboring the supE44 allele, suppression of the ochre mutation was observed after 7 days of incubation. The presence of the supE44 lesion in the relevant strains was confirmed by sequencing, and it was found to be in the duplicate copy of the glnV tRNA gene, glnX. To investigate this further, an in vivo luciferase assay developed by D. W. Schultz and M. Yarus (J. Bacteriol. 172:595-602, 1990) was employed to evaluate the efficiency of suppression of amber (UAG), ochre (UAA), and opal (UGA) mutations by supE44. We have shown here that supE44 suppresses ochre as well as opal nonsense mutations, with comparable efficiencies. The readthrough of nonsense mutations in a wild-type E. coli strain was much lower than that in a supE44 strain when measured by the luciferase assay. Increased suppression of nonsense mutations, especially ochre and opal, by supE44 was found to be growth phase dependent, as this phenomenon was only observed in stationary phase and not in logarithmic phase. These results have implications for the decoding accuracy of the translational machinery, particularly in stationary growth phase.Translation termination is mediated by one of the three stop codons (UAA, UAG, or UGA). When such stop codons arise in coding sequences due to mutations, referred to as nonsense mutations, they lead to abrupt arrest of the translation process. However, the termination efficiency of such nonsense codons is not 100%, as certain tRNAs have the ability to read these nonsense codons. Genetic code ambiguity is seen in several organisms. Stop codons have been shown to have alternate roles apart from translation termination. In organisms from all three domains of life, UGA encodes selenocysteine through a specialized mechanism. In Methanosarcinaceae, UAG encodes pyrrolysine (3). UAA and UAG are read as glutamine codons in some green algae and ciliates such as Tetrahymena and Diplomonads (24), and UAG alone encodes glutamine in Moloney murine leukemia virus (32). UGA encodes cysteine in Euplotes; tryptophan in some ciliates, Mycoplasma species, Spiroplasma citri, Bacillus, and tobacco rattle virus; and an unidentified amino acid in Pseudomicrothorax dubius and Nyctotherus ovalis (30). In certain cases the context of the stop codon in translational readthrough has been shown to play a role; for example, it has been reported that in vitro in tobacco mosaic virus, UAG and UAA are misread by tRNA^Tyr in a highly context-dependent manner (34, 9).Termination suppressors are of three types, i.e., amber, ochre, and opal suppressors, which are named based on their ability to suppress the three stop codons. Amber suppressors can suppress only amber codons, whereas ochre suppressors can suppress ochre codons (by normal base pairing) as well as amber codons (by wobbling) and opal suppressors can read opal and UGG tryptophan codon in certain cases. As described by Sambrook et al. (27), a few amber suppressors can also suppress ochre mutations by wobbling. The suppression efficiency varies among these suppressors, with amber suppressors generally showing increased efficiency over ochre and opal suppressors. supE44, an amber suppressor tRNA, is an allele of and is found in many commonly used strains of Escherichia coli K-12. Earlier studies have shown that supE44 is a weak amber suppressor and that its efficiency varies up to 35-fold depending on the reading context of the stop codon (8).Translational accuracy depends on several factors, which include charging of tRNAs with specific amino acids, mRNA decoding, and the presence of antibiotics such as streptomycin and mutations in ribosomal proteins which modulate the fidelity of the translational machinery. Among these, mRNA decoding errors have been reported to occur at a frequency ranging from about 10⁻³ to 10⁻⁴ per codon. Translational misreading errors also largely depend on the competition between cognate and near-cognate tRNA species. Poor availability of cognate tRNAs increases misreading (18).Several studies with E. coli and Saccharomyces cerevisiae have shown the readthrough of nonsense codons in suppressor-free cells. In a suppressor-free E. coli strain, it has been shown in vitro that glutamine is incorporated at the nonsense codons UAG and UAA (26). It has been reported that overexpression of wild-type tRNA^Gln in yeast suppresses amber as well as ochre mutations (25). In this study, we have confirmed the presence of an amber suppressor mutation in the glnX gene in a supE44 strain by sequence analysis. This was done essentially because we observed that supE44 could also suppress lacZ ochre mutations, albeit inefficiently. On further investigation using an in vivo luciferase reporter assay system for tRNA-mediated nonsense suppression (28), we found that the efficiency of suppression of amber lesion by supE44 is significantly higher than that reported previously in the literature. An increased ability to suppress ochre and opal nonsense mutations was observed in cells bearing supE44 compared to in the wild type. Such an effect was observed only in the stationary phase and was abolished in logarithmic phase.     

Estuarine fouling communities are dominated by nonindigenous species in the presence of an invasive crab

Interactions between anthropogenic disturbances and introduced and native species can shift ecological communities, potentially leading to the successful establishment of additional invaders. Since its discovery in New Jersey in 1988, the Asian shore crab (Hemigrapsus sanguineus) has continued to expand its range, invading estuarine and coastal habitats in eastern North America. In estuarine environments, H. sanguineus occupies similar habitats to native, panopeid mud crabs. These crabs, and a variety of fouling organisms (both NIS and native), often inhabit man-made substrates (like piers and riprap) and anthropogenic debris. In a series of in situ experiments at a closed dock in southwestern Long Island (New York, USA), we documented the impacts of these native and introduced crabs on hard-substrate fouling communities. We found that while the presence of native mud crabs did not significantly influence the succession of fouling communities compared to caged and uncaged controls, the presence of introduced H. sanguineus reduced the biomass of native tunicates (particularly Molgula manhattensis), relative to caged controls. Moreover, the presence of H. sanguineus favored fouling communities dominated by introduced tunicates (especially Botrylloides violaceous and Diplosoma listerianum). Altogether, our results suggest that H. sanguineus could help facilitate introduced fouling tunicates in the region, particularly in locations where additional solid substrates have created novel habitats.