The decomposition of Shannon's entropy and a confidence interval for beta diversity

Beta diversity is among the most employed theoretical concepts in ecology and biodiversity conservation. Up to date, a self‐contained definition of it, with no reference to alpha and gamma diversity, has never been proposed. Using Kullback‐Leibler divergence, we present the explicit formula of Shannon's β entropy, a bias correction for its estimator and a confidence interval. We also provide the mathematical framework to decompose Shannon diversity into several hierarchical nested levels. From botanical inventories of tropical forest plots in French Guiana, we estimate Shannon diversity at the plot, forest and regional level. We believe this is a complete and usefulness toolbox for ecologists interested in partitioning biodiversity.     

Dispensable role of the human immunodeficiency virus type 2 Vpx protein in viral replication.

Human immunodeficiency virus type 2 (HIV-2) is similar in genetic organization to HIV-1 but contains a unique gene (vpx) that encodes a 16-kDa protein. A replication-competent molecular clone of HIV-2 (HIV-2sbl/isy) that infects human primary cells in vitro and rhesus monkeys was used to generate three mutations in the vpx gene. In the first mutant, the vpx open reading frame was truncated at amino acid 20; the second mutant was tailored to eliminate the proline-rich carboxyl terminus of the protein; and the third mutant was obtained by addition of four amino acids (KDEL) to the carboxyl terminus of the protein to provide a retention signal in the endoplasmic reticulum. The viral infection kinetics of the three mutant viruses and isogeneic HIV-2sbl/isy in the SupT1 cell line were similar. Slight impairment in the early phases of viral replication was observed during infection of primary human peripheral blood mononuclear cells with the vpx mutant viruses. All of the vpx mutant viruses readily infected macrophages, indicating that vpx expression is dispensable for HIV-2 infection and replication in human macrophages.     

Regulation of the plant plasma membrane H+-ATPase by its C-terminal domain: what do we know for sure?

The plant plasma membrane H⁺-ATPase is kept at a low activity level by its C-terminal domain, the inhibitory function of which is thought to be mediated by two regions (region I and II) interacting with cytoplasmic domains essential for the catalytic cycle. The activity of the enzyme is well known to be regulated by 14-3-3 proteins, the association of which requires phosphorylation of the penultimate H⁺-ATPase residue, but can be abolished by phosphorylation of residues close-by. The current knowledge about H⁺-ATPase regulation is briefly summed up here, combined with data that query some of the above statements. Expression of various C-terminal deletion constructs of PMA2, a H⁺-ATPase isoform from Nicotiana plumbaginifolia, in yeast indicates that three regions, which do not correspond to regions I or II, contribute to autoinhibition. Their individual and combined action can be abolished by (mimicking) phosphorylation of three threonine residues located within or close to these regions. With respect to the wild-type PMA2, mimicking phosphorylation of two of these residues increases enzyme activity. However, constitutive activation of wild-type PMA2 requires 14-3-3 association. Altogether, the data suggest that regulation of the plant H⁺-ATPase occurs in progressive steps, mediated by several protein kinases and phosphatases, thus allowing gradual as well as fine-tuned adjustment of its activity. Moreover, mating-based split ubiquitin assays indicate a complex interplay between the C-terminal domain and the rest of the enzyme. Notably, their tight contact does not seem to be the cause of the inactive state of the enzyme.     

Variation in chromosome numbers, CMA bands and 45S rDNA sites in species of Selaginella (Pteridophyta)

BACKGROUND AND AIMS: Selaginella is the largest genus of heterosporous pteridophytes, but karyologically the genus is known only by the occurrence of a dysploid series of n=7-12, and a low frequency of polyploids. Aiming to contribute to a better understanding of the structural chromosomal variability of this genus, different staining methods were applied in species with different chromosome numbers. METHODS: The chromosome complements of seven species of Selaginella were analysed and, in four of them, the distribution of 45S rDNA sites was determined by fluorescent in situ hybridization. Additionally, CMA/DA/DAPI and silver nitrate staining were performed to investigate the correlation between the 45S rDNA sites, the heterochromatic bands and the number of active rDNA sites. KEY RESULTS: The chromosome numbers observed were 2n=18, 20 and 24. The species with 2n=20 exhibited chromosome complement sizes smaller and less variable than those with 2n=18. The only species with 2n=24, S. convoluta, had relatively large and asymmetrical chromosomes. The interphase nuclei in all species were of the chromocentric type. CMA/DA/DAPI staining showed only a weak chromosomal differentiation of heterochromatic bands. In S. willdenowii and S. convoluta eight and six CMA+ bands were observed, respectively, but no DAPI+ bands. The CMA+ bands corresponded in number, size and location to the rDNA sites. In general, the number of rDNA sites correlated with the maximum number of nucleoli per nucleus. Ten rDNA sites were found in S. plana (2n=20), eight in S. willdenowii (2n=18), six in S. convoluta (2n=24) and two in S. producta (2n=20). CONCLUSIONS: The remarkable variation in chromosome size and number and rDNA sites shows that dramatic karyological changes have occurred during the evolution of the genus at the diploid level. These data further suggest that the two putative basic numbers of the genus, x=9 and x=10, may have arisen two or more times independently.     

Proteomic analysis of SRm160-containing complexes reveals a conserved association with cohesin

In this study, we describe a rapid immunoaffinity purification procedure for gel-free tandem mass spectrometry-based analysis of endogenous protein complexes and apply it to the characterization of complexes containing the SRm160 (serine/arginine repeat-related nuclear matrix protein of 160 kDa) splicing coactivator. In addition to promoting splicing, SRm160 stimulates 3'-end processing via its N-terminal PWI nucleic acid-binding domain and is found in a post-splicing exon junction complex that has been implicated in coupling splicing with mRNA turnover, export, and translation. Consistent with these known functional associations, we found that the majority of proteins identified in SRm160-containing complexes are associated with pre-mRNA processing. Interestingly, SRm160 is also associated with factors involved in chromatin regulation and sister chromatid cohesion, specifically the cohesin subunits SMC1alpha, SMC3, RAD21, and SA2. Gradient fractionation suggested that there are two predominant SRm160-containing complexes, one enriched in splicing components and the other enriched in cohesin subunits. Co-immunoprecipitation and co-localization experiments, as well as combinatorial RNA interference in Caenorhabditis elegans, support the existence of conserved and functional interactions between SRm160 and cohesin.     

Molecular structure,solution chemistry and biological properties of the novel [ImH][trans-IrCl(4)(Im)(DMSO)], (I) and of the orange form of [(DMSO)(2)H][trans-IrCl(4)(DMSO)(2)], (II), complexes

The new iridium(III) complex, imidazolium[trans(DMSO,imidazole)tetrachloroiridate(III)], (I) (DMSO=dimethyl sulfoxide), and the orange form of [(DMSO)(2)H][trans(DMSO)(2)tetrachloroiridate(III)], (II) have been prepared and characterized, both in the solid state and in solution, by X-ray diffraction and by various physicochemical techniques. Single crystal X-ray diffraction studies point out that complex (II) is isomorphous to the ruthenium(III) analogue, [(DMSO)(2)H][trans-RuCl(4)(DMSO)(2)], (III). Crystallographic data are the following: a=16.028(2) A, b=24.699(3) A, c=8.262(1) A, in space group Pbca (Z=8) for (imidazolium)[trans(DMSO,imidazole)tetrachloroiridate(III)], (I); and a=9.189(2) A, b=16.511(4) A, c=14.028(3) A, beta=100.82(2) degrees in space group P2/n (Z=4) for [(DMSO)(2)H][trans(DMSO)(2)tetrachloroiridate(III)], (II). Visible absorption spectra show that both complexes are stable for several days, at pH 7.4, at room temperature. No significant chloride hydrolysis is observed, even at high temperature (70 degrees C), over 24 h. The extreme stability of these iridium(III) complexes within a physiological buffer was further assessed by (1)H NMR; in addition, cyclic voltammetry measurements evidenced a high stability of the oxidation state +3. Preliminary biological studies show that both complexes do not bind appreciably bovine serum albumin nor inhibit significantly the proliferation of representative human tumor cell lines, suggesting that hydrolysis of coordinated chlorides is a crucial feature for the biological properties and the antitumor activity of the parent ruthenium(III) complexes.     

Human-hamster hybrid cells used as models to investigate species-specific factors modulating the efficiency of repair of UV-induced DNA damage

The human-Chinese hamster hybrid cell line XR-C1#8, containing human chromosome 8, was used as a model system to investigate the relative importance of cellular enzymatic environment and chromosomal structure for modulating the efficiency of repair of UV-induced DNA damage. The hybrid cells were irradiated with UVC light and the extent of cytogenetic damage, detected as frequencies of sister chromatid exchanges (SCEs), was compared between the human and the hamster chromosomes. The combination of immunofluorescent staining for SCEs and chromosome painting with fluorescence in situ hybridization allowed the simultaneous analysis of SCEs in the human and hamster chromosomes. The aim of the present study was to determine if the differences in biological response to comparable UV treatments observed between human and hamster cells were maintained in the hybrid cells in which human and hamster chromosomes are exposed in the same cellular environment. The analysis of replication time of human chromosome 8 indicated the active status of this chromosome in XR-C1#8 hybrid cells. The frequencies of SCEs for human chromosome 8 and a hamster chromosome of comparable size were 0.35 +/- 0.52, 0.80 +/- 0.73, 1.24 +/- 2.24 and 0.36 +/- 0.12, 0.71 +/- 0.2, 0.97 +/- 0.27, respectively, after irradiation with 0, 5, and 10 J/m2. The persistence of UV-induced SCEs after three cell cycles was also analyzed, both for the human and hamster chromosomes. The observed frequencies of SCEs were 0.40 +/- 0.57, 0.62 +/- 1.05, 0.58 +/- 0.83 and 0.26 +/- 0.08, 0.67 +/- 0.18, 0.69 +/- 0.24, in human and hamster chromosomes respectively, after treatment with 0, 10, and 20 J/m2 of UVC light. No significant differences could be observed between the human and hamster chromosomes. These results suggest that the enzymatic environment of human and hamster cells has the main role, in comparison to the structural organization of human and hamster chromosomes, for determining the different level of repair of UV-induced DNA damage observed in these two species.