Across-species patterns of genetic variation in forest trees of Central Europe

The study focuses on geographical patterns of genetic variation at allozyme loci common for four main tree species of Central Europe (Norway spruce, silver fir, common beech and sessile oak). Moving-window averaging of four indicators of allelic richness and diversity (proportion of polymorphic loci, mean number of alleles per locus, effective number of alleles and expected heterozygosity) with window size of 50 × 50 km was used to identify the patterns. Moreover, local genetic divergence was assessed using the G _ST (Nei, Molecular population genetic and evolution, Amsterdam and Oxford, North-Holland, 1975) and D _j (Gregorius and Roberds, Theor Appl Genet 71:826–834, 1986) statistics for common beech and silver fir, where raw genotype data were available. Spatial patterns of diversity and allelic richness were quite similar. Romanian Carpathians were identified as the most important hotspot of genetic diversity and evolutionary divergence in Central Europe. Implications for genetic conservation are briefly discussed.     

Synthesis and biological activity of a series of tetrasubstituted-imidazoles as P2X7 antagonists

A series of analogues of the pyrazole lead 1 were synthesized in which the heterocyclic core was replaced with an imidazole. A number of potent antagonists were identified and structure–activity relationships (SAR) were investigated both with respect to activity at the P2X₇ receptor and in vitro metabolic stability. Compound 10 was identified as a potent P2X₇ antagonist with reduced in vitro metabolism and high solubility.     

Conservation genetics of the alligator snapping turtle: cytonuclear evidence of range-wide bottleneck effects and unusually pronounced geographic structure

A previous mtDNA study indicated that female-mediated gene flow was extremely rare among alligator snapping turtle populations in different drainages of the Gulf of Mexico. In this study, we used variation at seven microsatellite DNA loci to assess the possibility of male-mediated gene flow, we augmented the mtDNA survey with additional sampling of the large Mississippi River System, and we evaluated the hypothesis that the consistently low within-population mtDNA diversity reflects past population bottlenecks. The results show that dispersal between drainages of the Gulf of Mexico is rare (F _STmsat  = 0.43, Φ_STmtDNA = 0.98). Past range-wide bottlenecks are indicated by several genetic signals, including low diversity for microsatellites (1.1–3.9 alleles/locus; H _e = 0.06–0.53) and mtDNA (h = 0.00 for most drainages; π = 0.000–0.001). Microsatellite data reinforce the conclusion from mtDNA that the Suwannee River population might eventually be recognized as a distinct taxonomic unit. It was the only population showing fixation or near fixation for otherwise rare microsatellite alleles. Six evolutionarily significant units are recommended on the basis of reciprocal mtDNA monophyly and high levels of microsatellite DNA divergence.     

Linking ecology,morphology, and metabolism: Niche differentiation in sympatric populations of closely related species of the genus Littorina (Neritrema)

Divergence of ecological niches in phylogenetically closely related species indicates the importance of ecology in speciation, especially for sympatric species are considered. Such ecological diversification provides an advantage of alleviating interspecies competition and promotes more efficient exploitation of environmental resources, thus being a basis for ecological speciation. We analyzed a group of closely related species from the subgenus Neritrema (genus Littorina, Caenogastropoda) from the gravel‐bouldery shores. In two distant sites at the Barents and Norwegian Sea, we examined the patterns of snail distribution during low tide (quantitative sampling stratified by intertidal level, presence of macrophytes, macrophyte species, and position on them), shell shape and its variability (geometric morphometrics), and metabolic characteristics (metabolomic profiling). The studied species diversified microbiotopes, which imply an important role of ecological specification in the recent evolution of this group. The only exception to this trend was the species pair L. arcana / L. saxatilis, which is specifically discussed. The ecological divergence was accompanied by differences in shell shape and metabolomic characteristics. Significant differences were found between L. obtusata versus L. fabalis and L. saxatilis / L. arcana versus L. compressa both in shell morphology and in metabolomes. L. saxatilis demonstrated a clear variability depending on intertidal level which corresponds to a shift in conditions within the occupied microhabitat. Interestingly, the differences between L. arcana (inhabiting the upper intertidal level) and L. compressa (inhabiting the lower one) were analogous to those between the upper and lower fractions of L. saxatilis. No significant level‐dependent changes were found between the upper and lower fractions of L. obtusata, most probably due to habitat amelioration by fucoid macroalgae. All these results are discussed in the contexts of the role of ecology in speciation, ecological niche dynamics and conservatism, and evolutionary history of the Neritrema species.     

Low pH dye decolorization with ascomycete Lamprospora wrightii laccase

In a screening of saprotrophic, ectomycorrhizal and plant pathogen ascomycetes a frequent occurrence of laccase was observed. Lamprospora wrightii, the best producing organism, was chosen to elucidate the properties of a laccase from a moss-associated, saprotrophic ascomycete. The expression of laccase by this bryophilic fungus could be increased by the addition of tomato juice or copper sulfate to the medium. The obtained volumetric activity after optimization was 420 U/mL in either shaking flask or bioreactor-based cultivations. The purified laccase has a molecular mass of 68 kDa and an isoelectric point of 3.4. Although of ascomycete origin, its catalytic properties are similar to typical basidiomycte laccases, and an excellent activity and stability was observed at low pH, which makes it suitable for bioremediation in acidic environments. As an example, the decolorization reactions of azo-, anthraquinone-, trimethylmethane- and indigoid dyes at pH 3.0 and 5.0 were investigated. All ten selected dyes were decolorized, five of them very efficiently. Depending on the dye, the decolorization was found to be a combination of two reactions, degradation of the chromophore and formation of polymerized products, which contributed to the overall process in a dye-specific pattern.     

Application of Quantitative Real-Time Polymerase Chain Reaction for Noninvasive Genetic Monitoring

ABSTRACT Noninvasive genetic monitoring of animal populations has become a widely used method in animal conservation and wildlife management due to its known advantages in sample availability of endangered or elusive species. A variety of methods have been suggested to overcome the difficulties of collecting reliable genetic data despite poor DNA quality and quantity of samples. We used quantitative real-time polymerase chain reaction (qPCR) to quantify DNA contents and preselect extracts suitable for microsatellite genotyping of noninvasive samples from 2 carnivore species, wolf (Canis lupus) and Eurasian otter (Lutra lutra). We tested 2 concentration thresholds for DNA extracts containing either 5 pg/μL or 25 pg/μL at minimum and evaluated the effect of excluding samples from genotyping falling below either of these DNA concentrations. Depending on species and threshold concentration applied, we reduced the genotyping effort by 21% to 47% and genotyping errors by 7% to 45%, yet we could still detect 82% to 99% of available genotypes. Thus, qPCR may potentially reduce genotyping effort and enhance data reliability in noninvasive genetic studies. Genetic laboratories working on noninvasive population genetic studies could transfer this approach to other species, streamline genetic analyses and, thus, more efficiently provide wildlife managers with reliable genetic data of wild populations.     

Quantitative Site-specific Phosphorylation Dynamics of Human Protein Kinases during Mitotic Progression

Reversible protein phosphorylation is a key regulatory mechanism of mitotic progression. Importantly, protein kinases themselves are also regulated by phosphorylation-dephosphorylation processes; hence, phosphorylation dynamics of kinases hold a wealth of information about phosphorylation networks. Here, we investigated the site-specific phosphorylation dynamics of human kinases during mitosis using synchronization of HeLa suspension cells, kinase enrichment, and high resolution mass spectrometry. In biological triplicate analyses, we identified 206 protein kinases and more than 900 protein kinase phosphorylation sites, including 61 phosphorylation sites on activation segments, and quantified their relative abundances across three specific mitotic stages. Around 25% of the kinase phosphorylation site ratios were found to be changed by at least 50% during mitotic progression. Further network analysis of jointly regulated kinase groups suggested that Cyclin-dependent kinase- and mitogen-activated kinase-centered interaction networks are coordinately down- and up-regulated in late mitosis, respectively. Importantly, our data cover most of the already known mitotic kinases and, moreover, identify attractive candidates for future studies of phosphorylation-based mitotic signaling. Thus, the results of this study provide a valuable resource for cell biologists and provide insight into the system properties of the mitotic phosphokinome.Reversible phosphorylation is a ubiquitous posttranslational protein modification that is involved in the regulation of almost all biological processes (1–3). In human, 518 protein kinases have been identified in the genome that phosphorylate the majority of cellular proteins and increase the diversity of the proteome by severalfold (4). Addition of a phosphate group to a protein can alter its structural, catalytic, and functional properties; hence, kinases require tight regulation to avoid unspecific phosphorylation, which can be deleterious to cells (5–7). As a result, cells use a variety of mechanisms to ensure proper regulation of kinase activities (8). Importantly, most kinases are also in turn regulated through autophosphorylation and phosphorylation by other kinases, thus generating complex phosphorylation networks. In particular, phosphorylation on activation segments is a common mechanism to modulate kinase activities (9–11), but additional phosphorylation sites are also frequently required for fine tuning of kinase localizations and functions (12). Some kinases contain phosphopeptide binding domains that recognize prephosphorylated sites on other kinases, resulting in processive phosphorylation and/or targeting of kinases to distinct cellular locations (13–16). Because such priming phosphorylation events depend on the activities of the priming kinases, these motifs act as conditional docking sites and restrict the interaction with docking kinases to a particular point in time and physiological state. In addition, phosphorylation sites may act through combinatorial mechanisms or through cross-talk with other posttranslational modifications (PTMs)¹ (17, 18), thus further increasing the complexity of kinase regulatory networks.Regulation of kinases is of particular interest in mitosis as most of the mitotic events are regulated by reversible protein phosphorylation (19). During mitosis, error-free segregation of sister chromatids into the two daughter cells is essential to ensure genomic stability. Physically, this process is carried out by the mitotic spindle, a highly dynamic microtubule-based structure. After entry into mitosis, the major microtubule-organizing centers in animal cells, the centrosomes, start to increase microtubule nucleation and move to opposite poles of the cell. Throughout prometaphase, microtubules emanating from centrosomes are captured by kinetochores, protein complexes assembled on centromeric chromosomal DNA. This eventually leads to the alignment of all chromosomes in a metaphase plate. Because proper bipolar attachment of chromosomes to spindle microtubules is essential for the correct segregation of chromosomes, this critical step is monitored by a signaling pathway known as the spindle assembly checkpoint (SAC) (20). This checkpoint is silenced only after all chromosomes have attached to the spindle in a bioriented fashion, resulting in the synchronous segregation of sister chromatids during anaphase. Simultaneously, a so-called central spindle is formed between the separating chromatids, and the formation of a contractile ring initiates cytokinesis. Finally, in telophase, the chromosomes decondense and reassemble into nuclei, whereas remnants of the central spindle form the midbody, marking the site of abscission. Cyclin-dependent kinase 1 (Cdk1), an evolutionarily conserved master mitotic kinase, is activated prior to mitosis and initiates most of the mitotic events. Cdk1 works in close association with other essential mitotic kinases such as Plk1, Aurora A, and Aurora B for the regulation of mitotic progression (19, 21–24). Plk1 and Aurora kinases dynamically localize to different subcellular locations to perform multiple functions during mitosis and are phosphorylated at several conserved sites. Although little is known about the precise roles of these phosphorylation sites, emerging data indicate that they are involved in regulating localization-specific functions (25, 26). Furthermore, the kinases Bub1, BubR1, and TTK (Mps1) and kinases of the Nek family play important roles in maintaining the fidelity and robustness of mitosis (19). Recently, a genome-wide RNA-mediated interference screen identified M phase phenotypes for many kinases that have not previously been implicated in cell cycle functions, indicating that additional kinases have important mitotic functions (27).Although protein phosphorylation plays a pivotal role in the regulation of cellular networks, many phosphorylation events remain undiscovered mainly because of technical limitations (28). The advent of mass spectrometry-based proteomics along with developments in phosphopeptide enrichment methods has enabled large scale global phosphoproteomics studies (29, 30). However, the number of phosphorylation sites identified on kinases is limited compared with other proteins because of their frequently low expression levels. To overcome this problem, small inhibitor-based kinase enrichment strategies were developed, resulting in the identification of more than 200 kinases from HeLa cell lysates (31, 32). This method was also used recently to compare the phosphokinomes during S phase and M phase of the cell cycle, resulting in the identification of several hundreds of M phase-specific kinase phosphorylation sites (31). In the present study, we address the dynamics of the phosphokinome during mitotic progression using large scale cell synchronization at three distinct mitotic stages, small inhibitor-based kinase enrichment, and stable isotope labeling by amino acids in cell culture (SILAC)-based quantitative mass spectrometry. Thus, we determined the mitotic phosphorylation dynamics of more than 900 kinase phosphorylation sites and identified distinctly regulated kinase interaction networks. Our results provide a valuable resource for the dynamics of the kinome during mitotic progression and give insight into the system properties of kinase interaction networks.     

Increased frequency of chromatid breaks in lymphocytes of heterozygotes of ataxia telangiectasia after in vitro treatment with caffeine

The frequencies of caffeine-induced chromosomal aberrations (CA), mainly chromatid (CdB) and chromosome (CB) breaks, were studied in lymphocyte cultures derived from 6 obligatory heterozygotes and 1 homozygote of ataxia telangiectasia (AT), and from 4 control adult healthy persons. Caffeine (CF, 1 mM) was added at the beginning of the cultures exposed to CF the frequency of CB was 1.9% and of CdB 1.3%. In cells of the AT homozygote, the frequency of CdB was 6.8% in the absence and 8.7% in the presence of caffeine, the frequencies of CB being 3.4 and 10.9%, respectively. In AT heterozygous cells treated with CF, CdB increased 13-fold as compared to a less than 3-fold increase in control cells. Comparing the frequencies of CF-induced chromosomal lesions in control and AT heterozygous cells, potentiation factors (Pf) for the effect of 1 AT gene on cell sensitivity of CF (Pf [AT]) were 3.5 for CB, 6.6 for CdB and 5.5 for CA. These data demonstrate that lymphocytes of AT heterozygotes are significantly more sensitive to caffeine treatment in vitro in terms of increased frequency of CdB than normala cells, which may be useful for the diagnosis of carriers of this defective gene.