On consistency of Kendall's tau under censoring

Necessary and sufficient conditions for consistency of a simpleestimator of Kendall's tau under bivariate censoring are presented.The results are extended to data subject to bivariate left truncationas well as right censoring.     

Effect of humic acids from Leonardite on the stability of soil aggregates and melon roots under greenhouse conditions

Leonardite is an oxidized form of lignite carbon, which is obtained from fossilized organic materials. Such materials are used for the extraction of humic acids (HA). The result of the addition of HA of organic origin on soil structure is known; however, the effects of adding HA of Leonardite on soil structure have been scarcely investigated. The objectives of this research were (1) to determine the influence of humic acids derived from Leonardite in increasing the aggregate stability of an Aridisol under greenhouse conditions, and (2) evaluate the morphology of the root xylem during the phenological development of melon plants (Cucumis melo L.). Three treatments of HA solution application to the soil were used: soil without solution application (HA0), and application of HA solution to the soil with pH 6 (HA6) or (HA7). Aggregate stability (As) and bulk density (Da) were evaluated as soil variables. Development and quantification of xylem area were studied on plants. There were significant differences in aggregate stability. Also, there was an increase in the root xylem area, and the best treatment was when AH7 solution was applied. Humic acids derived from Leonardite increased the stability of soil aggregates when plants grew under greenhouse conditions, and fostered the development of xylem conduits during the fruiting stage.     

Imidazo[1,2-a]pyridines. Part 2: SAR and optimisation of a potent and selective class of cyclin-dependent kinase inhibitors

Exploration of SAR and optimisation of the imidazo[1,2-a]pyridine CDK inhibitors has lead to the discovery of novel, potent and selective inhibitors of the cyclin-dependent kinase CDK2. Understanding of SAR has identified positions of substitution, which allow modification of physical properties and offer the potential for in vivo optimisation.     

Two functional O-polysaccharide polymerase wzy (rfc) genes are present in the rfb gene cluster of Group E1 Salmonella enterica serovar Anatum

Defined regions of the rfb gene cluster of Group E1 Salmonella enterica serovar Anatum were introduced into a mutated derivative of this strain that lacks O-polysaccharide polymerase activity. Three different kinds of assays performed on the various transformants all indicate that two functional wzy (rfc) genes reside within the Group E1 Salmonella rfb gene cluster. The product of ORF9.6, positioned near the center of the rfb gene cluster, joins O-polysaccharide repeat units together by alpha-glycosidic linkages to produce antigen O10, the major serological determinant of Group E1 S. enterica. The product of ORF17.4, positioned at the downstream end of the rfb gene cluster, can join repeat units together by beta-glycosidic linkages to produce antigen O15, the major serological determinant of Group E2 S. enterica.     

The effect of captivity and diet on KLH isoform ratios in Megathura crenulata

Aquaculture of the giant keyhole limpet, Megathura crenulata, may provide a reliable long-term supply of keyhole limpet hemocyanin (KLH) for many promising biomedical applications. However, previous studies have reported a complete loss of the KLH1 isoform under certain cultivation conditions. We examined whether captivity per se and diet caused a significant change in the isoform profile of M. crenulata. Although there was a trend toward a decreasing percentage of KLH1 in some animals, in general isoform profiles were not significantly affected by captivity or dietary limitations. Further, the percentage of KLH1 significantly increased for limpets with previously low levels of KLH1 when fed a supplemental mixed diet. Our results indicate that normal isoform profiles can be maintained in limpets held in captivity even when fed insufficient diets, and that these conditions do not cause a complete loss of either KLH isoform. Notably, the enhancement of abnormally low levels of KLH1 suggests that variability in isoform profiles could potentially be minimized through diet. While there is a need for further research on the factors responsible for the variability of KLH, overall, these results support the premise that culture of M. crenulata may provide a sustainable source of this biomedically important product.     

Tissue-specific developmental expression of OAX, a Xenopus repetitive element

Approximately 1% of the Xenopus laevis genome consists of highly repetitive DNA known alternatively as OAX (for Oocyte Activation in Xenopus), Satellite I, or Repetitive HindIII Monomer 2. Present as tandemly repeated units of approximately 750 base pairs, OAX encodes a family of small RNA species transcribed by RNA polymerase III. Although the subject of many of the classic studies on early embryonic gene regulation, reports on OAX expression remain contradictory and incomplete. Using whole-mount in situ hybridization and RNase protection assays, we have therefore examined in detail the expression pattern of OAX in Xenopus embryos of various stages. OAX is initially expressed during gastrula stages; by tailbud stages embryos display discrete zones of expression at the dorsal boundary of the cement gland, in the developing somites and differentiating skeletal muscle, as well as in the dorsal aspect of the neural tube. These data demonstrate that OAX is expressed in a dynamic pattern under tight spatial and temporal regulation.     

Suppression of epithelial–mesenchymal transition and apoptotic pathways by miR-294/302 family synergistically blocks let-7-induced silencing of self-renewal in embryonic stem cells

The embryonic stem cell (ESC)-enriched miR-294/302 family and the somatic cell-enriched let-7 family stabilizes the self-renewing and differentiated cell fates, respectively. The mechanisms underlying these processes remain unknown. Here we show that among many pathways regulated by miR-294/302, the combinatorial suppression of epithelial–mesenchymal transition (EMT) and apoptotic pathways is sufficient in maintaining the self-renewal of ESCs. The silencing of ESC self-renewal by let-7 was accompanied by the upregulation of several EMT regulators and the induction of apoptosis. The ectopic activation of either EMT or apoptotic program is sufficient in silencing ESC self-renewal. However, only combined but not separate suppression of the two programs inhibited the silencing of ESC self-renewal by let-7 and several other differentiation-inducing miRNAs. These findings demonstrate that combined repression of the EMT and apoptotic pathways by miR-294/302 imposes a synergistic barrier to the silencing of ESC self-renewal, supporting a model whereby miRNAs regulate complicated cellular processes through synergistic repression of multiple targets or pathways.Embryonic stem cells (ESCs) can self-renew indefinitely and differentiate into any cell type.¹ Therefore, they hold great potential for clinical applications in regenerative medicine. However, the molecular mechanisms regulating the self-renewal and differentiation of ESCs are still not fully understood. miRNAs are an important class of short non-coding RNAs that regulate ESC self-renewal and differentiation.² miRNA-deficient ESCs proliferate at a slower rate with a slight accumulation of cells in the G1 phase, and they cannot silence the self-renewal program when induced to differentiate.^{3, 4, 5} Introducing individual members from an miRNA family highly expressed in ESCs partially rescues the proliferation defect and reverses the G1 accumulation.⁶ The family shares a seed sequence (5′-AAGUGCU-3′) and has eight members, including miR-294 and miR-302a-d. Because of their role in influencing the ESC Cell Cycle, they have been called the ESCC family of miRNAs. In addition, ESC cell cycle regulating miRNAs (ESCC miRNAs) suppress the G1 restriction point by inhibiting retinoblastoma (Rb) family proteins, preventing ESCs from exiting the cell cycle during serum starvation or contact inhibition.⁷ In contrast to ESCC miRNAs, the introduction of let-7 family miRNAs that are enriched in somatic cells as well as several other lineage-specific miRNAs such as miR-26a, miR-99b, miR-193, miR-199a-5p, and miR-218 silences self-renewal in Dgcr8−/− (DiGeorge syndrome critical region gene 8−/−) ESCs but not wild-type ESCs.^{7, 8} Interestingly, the ESCC miRNAs prevent these miRNAs from silencing ESC self-renewal. Consistent with their roles in promoting self-renewal, ESCC miRNAs dramatically enhance the de-differentiation of human and mouse fibroblasts to induced pluripotent stem cells (iPSCs).^{9, 10, 11, 12, 13}How ESCC miRNAs maintain self-renewal in the presence of differentiation-inducing miRNAs is not clearly understood. Genomic studies have shown that these miRNAs target hundreds of mRNAs enriched in many biological processes.^{8, 14, 15, 16} Functional analysis of a small number of targets chosen based on their known roles has begun to give some insights into their functions in reprogramming somatic cells to iPSCs.^{10, 11, 17} However, due to the inherent differences between the maintenance and establishment of pluripotency,¹⁸ what targets or pathways underlie the antagonism between the two opposing families of miRNAs in regulating ESC self-renewal remains unknown. Recent work showed that while the miR-294/302 family suppresses and let-7 induces the G1/S restriction point, this cell cycle function cannot explain their antagonistic roles in maintaining pluripotency.⁷ Therefore, we set out to search for additional functions of the two miRNA families that directly underlie their opposing roles in regulating pluripotency. In this study, we found that combined repression of epithelial–mesenchymal transition (EMT) and apoptotic pathways by miR-294/302 forms a synergistic barrier to block the silencing of ESC self-renewal by let-7 and other differentiation-inducing miRNAs.     

Transient DNMT1 suppression reveals hidden heritable marks in the genome

Genome-wide demethylation and remethylation of DNA during early embryogenesis is essential for development. Imprinted germline differentially methylated domains (gDMDs) established by sex-specific methylation in either male or female germ cells, must escape these dynamic changes and sustain precise inheritance of both methylated and unmethylated parental alleles. To identify other, gDMD-like sequences with the same epigenetic inheritance properties, we used a modified embryonic stem (ES) cell line that emulates the early embryonic demethylation and remethylation waves. Transient DNMT1 suppression revealed gDMD-like sequences requiring continuous DNMT1 activity to sustain a highly methylated state. Remethylation of these sequences was also compromised in vivo in a mouse model of transient DNMT1 loss in the preimplantation embryo. These novel regions, possessing heritable epigenetic features similar to imprinted-gDMDs are required for normal physiological and developmental processes and when disrupted are associated with disorders such as cancer and autism spectrum disorders. This study presents new perspectives on DNA methylation heritability during early embryo development that extend beyond conventional imprinted-gDMDs.