Eukaryotic phylotypes in aquatic moss pillars inhabiting a freshwater lake in East Antarctica, based on 18S rRNA gene analysis

Aquatic mosses of Leptobryum species form unique tower-like pillars of vegetation termed “moss pillars” in Antarctic lakes. Moss pillars have distinct redox-affected sections: oxidative exteriors and reductive interiors. We have proposed that a “pillar” is a community and habitat of functionally interdependent organisms and may represent a mini-biosphere. Batteries of 16S rRNA genotypes, or phylotypes, of eubacteria and cyanobacteria, but no archaea, have been identified in moss pillars. However, detailed identification or phylogenetic analyses of the moss and their associated eukaryotic microbiota have not been performed. This study analyzed near-full-length 18S rRNA gene sequences obtained from two whole moss pillars. In total, 28 PCR clone libraries from two whole moss pillars were constructed, and 96 clones from each library (total 2,688 clones) were randomly selected and sequenced. Molecular phylogenetic analysis revealed that the phylotype belonging to Bryophyta, considered to be derived from moss, was closely related (99.9?%) to the 18S rRNA gene sequence from Leptobryum pyriforme. Unexpectedly, phylotypes belonging to a novel clade of fungi dominated (approximately 27–75?%) the moss pillar libraries. This suggests that fungi may contribute to carbon cycling in the moss pillar as parasites or decomposers. In addition, phylotypes related to ciliates and tardigrades were subdominant in the exterior, while the phylotype of the ameba-like, single-celled eukaryote, Cercomonas (Cercozoa), was detected only in the interior. These features were shared by both moss pillars. The 18S rRNA gene-based profiles demonstrated that redox-related factors may control distribution of some eukaryotic microbes in a whole moss pillar.     

Srs2 Plays a Critical Role in Reversible G2 Arrest upon Chronic and Low Doses of UV Irradiation via Two Distinct Homologous Recombination-Dependent Mechanisms in Postreplication Repair-Deficient Cells

Differential posttranslational modification of proliferating cell nuclear antigen (PCNA) by ubiquitin or SUMO plays an important role in coordinating the processes of DNA replication and DNA damage tolerance. Previously it was shown that the loss of RAD6-dependent error-free postreplication repair (PRR) results in DNA damage checkpoint-mediated G₂ arrest in cells exposed to chronic low-dose UV radiation (CLUV), whereas wild-type and nucleotide excision repair-deficient cells are largely unaffected. In this study, we report that suppression of homologous recombination (HR) in PRR-deficient cells by Srs2 and PCNA sumoylation is required for checkpoint activation and checkpoint maintenance during CLUV irradiation. Cyclin-dependent kinase (CDK1)-dependent phosphorylation of Srs2 did not influence checkpoint-mediated G₂ arrest or maintenance in PRR-deficient cells but was critical for HR-dependent checkpoint recovery following release from CLUV exposure. These results indicate that Srs2 plays an important role in checkpoint-mediated reversible G₂ arrest in PRR-deficient cells via two separate HR-dependent mechanisms. The first (required to suppress HR during PRR) is regulated by PCNA sumoylation, whereas the second (required for HR-dependent recovery following CLUV exposure) is regulated by CDK1-dependent phosphorylation.DNA damage occurs frequently in all organisms as a consequence of both endogenous metabolic processes and exogenous DNA-damaging agents. In nature, the steady-state level of DNA damage is usually very low. However, chronic low-level DNA damage can lead to age-related genome instability as a consequence of the accumulation of DNA damage (12, 27). Increasing evidence implicates DNA damage-related replication stress in genome instability (7, 21). Replication stress occurs when an active fork encounters DNA lesions or proteins tightly bound to DNA. These obstacles pose a threat to the integrity of the replication fork and are thus a potential source of genome instability, which can contribute to tumorigenesis and aging in humans (4, 11). Confronted with this risk, cells have developed fundamental DNA damage response mechanisms in order to faithfully complete DNA replication (8).In budding yeast Saccharomyces cerevisiae, the Rad6-dependent postreplication repair (PRR) pathway is subdivided into three subpathways, which allow replication to resume by bypassing the lesion without repairing the damage (3, 22, 33). Translesion synthesis (TLS) pathways dependent on the DNA polymerases eta and zeta promote error-free or mutagenic bypass depending on the DNA lesion and are activated upon monoubiquitination of proliferating cell nuclear antigen (PCNA) at Lys164 (K164) (5, 16, 37). The Rad5 (E3) and Ubc13 (E2)/Mms2 (E2 variant)-dependent pathway promotes error-free bypass by template switching and is activated by polyubiquitination of PCNA via a Lys63-linked ubiquitin chain (16, 38, 41). It remains mechanistically unclear how polyubiquitinated PCNA promotes template switching at the molecular level. In addition to its ubiquitin E3 activity, Rad5 also has a helicase domain and was recently shown to unwind and reanneal fork structures in vitro (6). This led to the proposal that Rad5 helicase activity is required at replication forks to promote fork regression and subsequent template switching. It is possible that PCNA polyubiquitination acts to facilitate Rad5-dependent template switching by inhibiting monoubiquitination-dependent TLS activity and/or by recruiting alternative proteins to the fork.In addition to modification by ubiquitin, PCNA can also be sumoylated on Lys164 by the SUMO E3 ligase Siz1 (16). A second sumoylation site, Lys127, is also targeted by an alternative SUMO E3 ligase, Siz2, albeit with lower efficiency (16, 30). PCNA SUMO modification results in recruitment of the Srs2 helicase and subsequent inhibition of Rad51-dependent recombination events (29, 32). The modification can therefore allow the replicative bypass of lesions by promoting the RAD6 pathway. Srs2 is known to act as an antirecombinase by eliminating recombination intermediates. This can occur independently of PCNA sumoylation, and when srs2Δ cells are UV irradiated or other antirecombinases, such as Sgs1, are concomitantly deleted, toxic recombination structures accumulate (1, 10). Such genetic data are consistent with the ability of Srs2 to disassemble the Rad51 nucleoprotein filaments formed on single-stranded DNA (ssDNA) in vitro (20, 40). In addition to directly inhibiting homologous recombination (HR), Srs2 is also involved in regulating HR outcomes to not produce crossover recombinants in the mitotic cell cycle (18, 34, 35).The UV spectrum present in sunlight is a primary environmental cause of exogenous DNA damage. Sunlight is a potent and ubiquitous carcinogen responsible for much of the skin cancer in humans (17). In the natural environment, organisms are exposed to chronic low-dose UV light (CLUV), as opposed to the acute high doses commonly used in laboratory experiments. Hence, understanding the cellular response to CLUV exposure is an important approach complementary to the more traditional laboratory approaches for clarifying the biological significance of specific DNA damage response pathways. A recently developed experimental assay for the analysis of CLUV-induced DNA damage responses was used to show that the PCNA polyubiquitination-dependent error-free PRR pathway plays a critical role in tolerance of CLUV exposure by preventing the generation of excessive ssDNA when replication forks arrest, thus suppressing counterproductive checkpoint activation (13).Mutants of SRS2 were first isolated by their ability to suppress the radiation sensitivity of rad6 and rad18 mutants (defective in PRR) by a mechanism that requires a functional HR pathway (23, 36). In this study, we analyzed the function of Srs2 in CLUV-exposed PRR-deficient cells. We established that Srs2 acts in conjunction with SUMO-modified PCNA to lower the threshold for checkpoint activation and maintenance by suppressing the function of HR in rad18Δ cells exposed to CLUV. We also showed that Srs2 is separately involved in an HR-dependent recovery process following cessation of CLUV exposure and that this second role for Srs2, unlike its primary role in checkpoint activation and maintenance, is regulated by CDK1-dependent phosphorylation. Thus, Srs2 is involved in both CLUV-induced checkpoint-mediated arrest and recovery from CLUV exposure in PRR-deficient cells, and these two functions, while both involving HR, are separable and thus independent.     

Spermatogonia-specific proteins expressed in prepubertal buffalo (Bubalus bubalis) testis and their utilization for isolation and in vitro cultivation of spermatogonia

Buffalo is an economically important livestock species in Asia. Little is known about male germ line technology owing to lack of sufficient understanding regarding expression of germ- and somatic-cell specific-proteins in the testis. In this study, we identified UCHL-1 (PGP 9.5) and lectin- Dolichos biflorus agglutinin (DBA) as specific markers for spermatogonia in buffalo testis. Expression of germ-cell and pluripotency-specific proteins such as DDX4 (VASA) and POU5F1 (OCT3/4) were also present in spermatogonia. Interestingly, the expression of somatic cell-specific proteins such as VIMENTIN and GATA4 were also detected in germ cells. Using two-step enzymatic digestion followed by differential plating and Percoll density-gradient centrifugation, an approximately 55% spermatogonia-enriched cell population could be obtained from the prepubertal buffalo testis. Isolated spermatogonia could survive and proliferate in vitro in DMEM/F12 medium containing 10% fetal bovine serum in the absence of any specific growth factors for a week. Cultured spermatogonia showed DBA affinity and expressed DDX4 and POU5F1. These results may help to establish a long-term culture system for buffalo spermatogonia.     

Effects of population density, sex morph, and tree size on reproduction in a heterodichogamous maple, Acer mono, in a temperate forest of Japan

The effects of local population density, sex morph [protogynous (PG) or protandrous (PA)], and individual tree size on the demographic processes of seed production were investigated in a heterodichogamous maple, Acer mono Maxim. var. Marmoratum (Nichols.) Hara f. dissectum, in a temperate forest of Japan. As the distance from conspecific reproductive adults increased, the percentage of immature seed fall and empty seeds increased significantly, indicating higher pollination success along with local population density. Although the difference was not distinct, pollination success was affected by the local population density of the reciprocal sex morph rather than that of both sex morphs. The trees at higher local population density sites suffered higher seed mortality due to predation and decay, and tended to produce smaller seeds. Thus, the impacts of local population density operated both positively and negatively on reproduction. As a factor of individual traits, tree size scarcely affected any demographic processes. On the other hand, sex morph did affect pollination success. Trees of PG type had lower immature seed fall than those of PA type, suggesting that the former has higher efficiency of pollen acceptance than the latter. The results on seed demography presented here partly support previous suggestions that heterodichogamous plants exhibit reciprocal cross-pollination and gender specialization as reproductive traits.     

Optimization and validation of a high-performance liquid chromatographic method with UV detection for the determination of pyrrole-imidazole polyamides in rat plasma

A simple and sensitive high-performance liquid chromatography (HPLC) method utilizing UV detection was developed for the determination of plasma pyrrole (Py)-imidazole (Im) polyamides in rats and applied to the pharmacokinetic study of compounds. After deproteinization of plasma with methanol, Py-Im polyamides were analyzed with a reversed-phase TSK-GEL ODS-80TM (4.6 mmx15.0 cm TOSOH Co., Japan) column maintained at 40 degrees C. The mobile phase solvent A was 0.1% acetic acid and the solvent B was HPLC-grade acetonitrile (0-10 min, A: 100-20%, B: 0-80% linear gradient; 10-15 min, A: 40%, B: 60%). The flow rate was 1.0 ml/min. The detection wavelength was set at 310 nm. The method was used to determine the plasma concentration time profiles of Py-Im polyamides after intravenous injection.     

Functional assembly of the Na+/H+ antiporter of Helicobacter pylori from partial fragments in vivo

Functional assembly of the Helicobacter pylori Na+/H+ antiporter (HPNhaA) from partial fragments was studied. Expression plasmids encoding a series of complementary N- and C-terminal fragment pairs containing the transmembrane domains (TMs) were constructed by inserting a stop or a start codon into each of the loop regions of NhaA. HPNhaA fragments alone or complementary fragment pairs were expressed in DeltanhaA Escherichia coli, and fragment integration into the membrane and antiporter activity were measured. TM1-10, TM1-11, TM2-12, TM6-12, and TM10-12 were found in the membrane fraction, while the other fragments were not. While no single fragment displayed antiporter activity, simultaneous expression of fragments in certain pairs, such as TM1-2 + TM3-12, TM1-8 + TM9-12, or TM1-11 + TM12, reconstituted antiporter activity. With the exception of TM12, all of the fragments in the pairs were detected in the membrane. No single fragments expressed alone for these pairs were found in the membrane, except for TM1-11, suggesting that the interaction between the fragments in these pairs stabilized the fragments and enabled reconstitution of HPNhaA. We also found that the simultaneous expression of three complementary fragments (TM1-2 + TM3-8 + TM9-12) reconstituted HPNhaA activity. Other pairs that were found in the membrane (TM1-5 + TM6-12, TM1-10 + TM11-12, and TM1 + TM2-12) did not reconstitute antiporter activity, suggesting that they may not have the proper conformation. These results revealed that the ability to reconstitute antiporter activity depends on the split position in the loop regions and the interaction between complementary fragment pairs. We propose that formation of the active HPNhaA molecule is initiated by the interaction of short-lived intermediates and maintained by the increased stability of the intermediates within the resulting complex.     

Structural analysis of an acidic, fatty acid ester-bonded extracellular polysaccharide produced by a pristane-assimilating marine bacterium, Rhodococcus erythropolis PR4

Rhodococcus erythropolis PR4 is a marine bacterium that can degrade various alkanes including pristane, a C(19) branched alkane. This strain produces a large quantity of extracellular polysaccharides, which are assumed to play an important role in the hydrocarbon tolerance of this bacterium. The strain produced two acidic extracellular polysaccharides, FR1 and FR2, and the latter showed emulsifying activity toward clove oil, whereas the former did not. FR2 was composed of D-galactose, D-glucose, D-mannose, D-glucuronic acid, and pyruvic acid at a molar ratio of 1:1:1:1:1, and contained 2.9% (w/w) stearic acid and 4.3% (w/w) palmitic acid attached via ester bonds. Therefore, we designated FR2 as a PR4 fatty acid-containing extracellular polysaccharide or FACEPS. The chemical structure of the PR4 FACEPS polysaccharide chain was determined by 1D (1)H and (13)C NMR spectroscopies as well as by 2D DQF-COSY, TOCSY, HMQC, HMBC, and NOESY experiments. The sugar chain of PR4 FACEPS was shown to consist of tetrasaccharide repeating units having the following structure: [structure: see text].     

Embryology of Siparunaceae (Laurales): characteristics and character evolution

Embryological characters of Siparunaceae, which are poorly understood, were studied on the basis of two constituent genera, an African Glossocalyx and a South American Siparuna, to better understand their evolution within Laurales. These two genera have many embryological characteristics in common with the other lauralean families. Noticeably, they share the multi-celled ovule archesporium (uncertain in Glossocalyx) as a synapomorphy with all the other lauralean families except Lauraceae, the anthers dehisced by valves as a synspomorphy with all the other lauralean families except Calycanthaceae and Monimiaceae, and the bisporangiate anther as a synapomorphy with Gomortegaceae and Atherospermataceae. Siparunaceae are, however, distinct from all other laularean families in having unitegmic ovules that were derived from bitegmic ovules, probably due to an elimination of the outer integument. Likewise, the lack of the testa (i.e., developed outer integument), the "endotegmic" seed coat, and the perichalazal seed at maturity are also characteristics of Siparunaceae. Within the family, Siparuna differs from Glossocalyx in having plural tetrads of megaspores and plural, starchy-rich, one-nucleate, tubular embryo sacs (autapomorphies). On the other hand, Glossocalyx is characterized by having bilaterally flattened seeds (autapomorphy). Although functional aspects of those autapomorphies are uncertain, both Glossocalyx and Siparuna show evolution in different embryological characters.