Infertility and Male Mating Behavior Deficits Associated With Pde1c in Drosophila melanogaster

Pde1c is a calcium/calmodulin-regulated, dual-specificity cyclic nucleotide phosphodiesterase. We have used a transposon insertion line to investigate the physiological function of Pde1c in Drosophila melanogaster and to show that the insertion leads to male sterility and male mating behavior defects that include reduced copulation rates. Sterility appears to be primarily due to elimination of sperm from the female reproductive system. The male mating behavior defects were fully rescued by expression of exogenous Pde1c under the control of either a Pde1c or a pan-neuronal promoter, whereas the sterility could be only partially rescued by expression of exogenous Pde1c under the control of these promoters. We also show that Pde1c has a male-specific expression pattern in the CNS with an increased number of Pde1c-expressing neurons in the abdominal ganglion in males.THE cyclic nucleotides, cyclic AMP (cAMP) and cyclic GMP (cGMP), have been known for many years to regulate a wide variety of physiological processes in all animals (e.g., Siegel et al. 1994). Similarly, there is a large body of research focused on an understanding of the structure and regulation of the enzymes that synthesize cAMP and cGMP, the adenylyl and guanylyl cyclases, respectively. Although the concentrations of cyclic nucleotides within a cell are regulated by both their synthesis and their degradation, less attention has been devoted to the function and regulation of the enzymes that break down cyclic nucleotides, the phosphodiesterases (PDEs).Mammals have >20 genes that code for cyclic nucleotide PDEs, which have been subdivided into 11 families on the basis of their sequences, substrate specificities, and regulatory properties (Conti and Beavo 2007). Insects also have a wide variety of PDEs with Drosophila melanogaster containing 6 genes that code for cyclic nucleotide PDEs (Morton and Hudson 2002; Day et al. 2005). On the basis of their sequence similarity to the mammalian PDEs, these 6 genes have been classified into 6 of the 11 families: Pde1c, Pde4, Pde6, Pde8, Pde9, and Pde11 (Day et al. 2005). When their biochemical properties have been investigated, they match well with other members of the same family (Day et al. 2005).Despite the importance of cyclic nucleotides in insect physiology, only one of the Drosophila PDEs has been associated with a mutant phenotype. This gene, Pde4, also known as dunce, was one of the first learning and memory mutants discovered (Byers et al. 1981; Davis et al. 1995). In this study, we have investigated the phenotypes associated with reduced expression of Pde1c, a PDE that has dual specificity for both cAMP and cGMP and that is stimulated in the presence of calcium and calmodulin (Day et al. 2005). Here we show that Pde1c is required for male fertility and male mating behavior. Male sterility appears to be primarily due to females rejecting sperm or failing to store the sperm from mutant males.     

Diastolic ventricular-vascular stiffness and relaxation relation: elucidation of coupling via pressure phase plane-derived indexes

Because systole and diastole are coupled and systolic ventricular-vascular coupling has been characterized, we hypothesize that diastolic ventricular-vascular coupling (DVVC) exists and can be characterized in terms of relaxation and stiffness. To characterize and elucidate DVVC mechanisms, we introduce time derivative of pressure (dP/dt) vs. time-varying pressure [P(t)] (pressure phase plane, PPP)-derived analogs of ventricular and vascular "stiffness" and relaxation parameters. Although volume change (dV) = 0 during isovolumic periods, and time-varying left ventricular (LV) stiffness, typically expressed as change in pressure per unit change in volume (dP/dV), is undefined, our formulation allows determination of a PPP-derived stiffness analog during isovolumic contraction and relaxation. Similarly, an aortic stiffness analog is also derivable from the PPP. LV relaxation was characterized via tau, the time constant of isovolumic relaxation, and vascular (aortic pressure decay) relaxation was characterized in terms of its equivalent (windkessel) exponential decay time constant kappa. The results show that PPP-derived systolic and diastolic ventricular and vascular stiffness are strongly coupled [K(Ao)(+)=1.71(K(LV)(+)) +154, r=0.86; K(Ao)(-)=0.677(K(LV)(-))-5.53, r=0.86]. In support of the DVVC hypothesis, a strong linear correlation between relaxation (rate of pressure decay) indexes kappa and tau (kappa = 9.89tau - 90.3, r = 0.81) was also observed. The correlations observed underscore the role of long-term, steady-state DVVC as a diastolic function determinant. Awareness of the PPP-derived DVVC parameters provides insight into mechanisms and facilitates quantification of arterial stiffening and associated increase in diastolic chamber stiffness. The PPP method provides a tool for quantitative assessment and determination of the functional coupling of the vasculature to diastolic function.     

Innate immune response to human bone marrow fibroblastic cell implantation in CB17 scid/beige mice

Immunocompromised mouse models have been extensively used to assess human cell implantation for evaluation of cytotherapy, gene therapy and tissue engineering strategies, as these mice are deficient in T and B lymphoid cells. However, the innate immune response and its effect on human cell xenotransplantation in these mouse models are mainly unknown. The aim of this study is to characterise the myeloid populations in the spleen and blood of CB17 scid beige (CB17 sb) mice, and to study the inflammatory cell responses to xenogeneic implantation of enhanced green fluorescent protein (GFP)-labelled human bone marrow fibroblastic (HBMF) cells into CB17 sb mice. The results indicate that even though CB17 sb mice are deficient in B- and T-cells, they exhibit some increases in their monocyte (Mo), macrophage (Mphi) and neutrophil (Neu) populations. NK cell and eosinophil populations show no differences compared with wild-type Balb/C mice. An innate immune response, identified by CR3 (CD11b/CD18)-positive myeloid inflammatory cells and F4/80-positive macrophages, was evident in the tissues where HBMF cells were implanted. As a consequence, the majority of implanted HBMF cells were eliminated by 4 weeks after implantation. Interestingly, the mineralised matrix formed by osteogenic HBMF cells was also eroded by multinuclear Mphi-like giant cells. We conclude that CB17 sb mice retain active innate immune cells, which respond to HBMF cell xenotransplantation. This study highlights the importance of the innate immune cells in the anti-xenograft response and suggests that strategies to block the activities of these cells may ameliorate the progressive long-term elimination of xenotransplants.     

Inhibition of cyclic AMP dependent protein kinase by vanadyl sulfate

Vanadium salts influence the activities of a number of mammalian enzymes in vitro but the mechanisms by which low concentrations of vanadium ameliorate the effects of diabetes in vivo remain poorly understood. The hypothesis that vanadium compounds act by inhibiting protein tyrosine phosphatases has attracted most support. The studies described here further evaluate the possibility that vanadyl sulfate trihydrate (VS) can also inhibit 3′,5′-cyclic adenosine monophosphate (cAMP) dependent protein kinase (PKA). Using conventional assay conditions, VS inhibited PKA only at high concentrations (IC₅₀>400 μM); however, PKA inhibition was seen at dramatically lower concentrations of VS (IC₅₀<10 μM) when sequestration of vanadyl ions was minimized. Vanadyl appears to be the effective PKA inhibitor because sodium orthovanadate did not inhibit PKA and inhibition by vanadyl was abolished by potential chelators such as ethylenediaminetetraacetic acid or glycyl peptides. PKA inhibition by vanadyl appears to be mixed rather than strictly competitive or uncompetitive and may replicate the inhibitory effects of high concentrations of Mg²⁺. The effect of vanadyl on PKA provides a possible explanation for the effects of vanadium salts on fat tissue lipolysis and perhaps on other aspects of energy metabolism that are controlled by cAMP-dependent mechanisms. Considering the high degree of conservation of the active sites of protein kinases, vanadyl may also influence other members of this large protein family. Electronic Supplementary Material Supplementary material is available for this article at and is accessible for authorized users.     

Evidence that the SpoIIIE DNA translocase participates in membrane fusion during cytokinesis and engulfment

During Bacillus subtilis sporulation, SpoIIIE is required for translocation of the trapped forespore chromosome across the sporulation septum, for compartmentalization of cell-specific gene expression, and for membrane fusion after engulfment. We isolated mutations within the SpoIIIE membrane domain that block localization and function. One mutant protein initially localizes normally and completes DNA translocation, but shows reduced membrane fusion after engulfment. Fluorescence recovery after photobleaching experiments demonstrate that in this mutant the sporulation septum remains open, allowing cytoplasmic contents to diffuse between daughter cells, suggesting that it blocks membrane fusion after cytokinesis as well as after engulfment. We propose that SpoIIIE catalyses these topologically opposite fusion events by assembling or disassembling a proteinaceous fusion pore. Mutants defective in SpoIIIE assembly also demonstrate that the ability of SpoIIIE to provide a diffusion barrier is directly proportional to its ability to assemble a focus at the septal midpoint during DNA translocation. Thus, SpoIIIE mediates compartmentalization by two distinct mechanisms: the SpoIIIE focus first provides a temporary diffusion barrier during DNA translocation, and then mediates the completion of membrane fusion after division to provide a permanent diffusion barrier. SpoIIIE-like proteins might therefore serve to couple the final step in cytokinesis, septal membrane fusion, to the completion of chromosome segregation.     

Effects of tumor necrosis factor antagonist treatment on hepatitis C-related immunological abnormalities

BACKGROUND: Chronic hepatitis C infection is frequently associated with a mixed cryoglobulinaemia and circulating auto-antibodies, especially anti-smooth muscle cells (SMA) and anti-liver/kidney/microsome type 1 (LKM-1) anti-tissue antibodies. Treatments with TNF antagonists favour the emergence of auto-antibodies, and particularly anti-dsDNA antibodies. OBJECTIVE: To determine the impact of TNF antagonists on hepatitis C-related immune abnormalities. METHODS: We prospectively monitored for 14 weeks, six patients with actively replicating chronic hepatitis C, initiating an anti-TNF treatment for an associated rheumatoid arthritis. RESULTS: Anti-nuclear and anti-dsDNA antibodies were induced in two and three patients, respectively. Treatment had no impact on the production of antibodies against extractable nuclear antigens, and it did not induce anti-tissues antibodies in any patient. Cryoglobulinaemia appeared in 2/6 patients, and it persisted in 2 others. No patient developed any news signs of autoimmunity. HCV viraemia remained unchanged. CONCLUSIONS: Induction of auto-antibodies by TNF antagonist treatments does not involve anti-tissues antibodies, even in patients with actively replicating chronic hepatitis C prone to produce anti-SMA and anti-LKM-1 antibodies. In contrast, TNF antagonists may favour emergence of cryoglobulinaemia in such patients.     

Dissociation of color and figure-ground effects in the watercolor illusion

Two phenomena can be observed in the watercolor illusion: illusory color spreading and figure-ground organization. We performed experiments to determine whether the figure-ground effect is a consequence of the color illusion or due to an independent mechanism. Subjects were tested with displays consisting of six adjacent compartments--three that generated the illusion alternating with three that served for comparison. In a first set of experiments, the illusory color was measured by finding the matching physical color in the alternate compartments. Figureness (probability of 'figure' responses, 2AFC) of the watercolor compartments was then determined with and without the matching color in the alternate compartments. The color match reduced figureness, but did not abolish it. There was a range of colors in which the watercolor compartments dominated as figures over the alternate compartments although the latter appeared more saturated in color. In another experiment, the effect of tinting alternate compartments was measured in displays without watercolor illusion. Figureness increased with color contrast, but its value at the equivalent contrast fell short of the figureness value obtained for the watercolor pattern. Thus, in both experiments, figureness produced by the watercolor pattern was stronger than expected from the color effect, suggesting independent mechanisms. Considering the neurophysiology, we propose that the color illusion follows from the principles of representation of surface color in the visual cortex, while the figure-ground effect results from two mechanisms of border ownership assignment, one that is sensitive to asymmetric shape of edge profile, the other to consistency of color borders.     

Population genomics in natural microbial communities

Little is known about the evolutionary processes that structure and maintain microbial diversity because, until recently, it was difficult to explore individual-level patterns of variation at the microbial scale. Now, community-genomic sequence data enable such variation to be assessed across large segments of microbial genomes. Here, we discuss how population-genomic analysis of these data can be used to determine how selection and genetic exchange shape the evolution of new microbial lineages. We show that once independent lineages have been identified, such analyses enable the identification of genome changes that drive niche differentiation and promote the coexistence of closely related lineages within the same environment. We suggest that understanding the evolutionary ecology of natural microbial populations through population-genomic analyses will enhance our understanding of genome evolution across all domains of life.     

Current and future approaches using genetically modified mice in endocrine research

Genetically modified mouse models have been used widely to advance our knowledge in the field of endocrinology and metabolism. A number of different approaches to generate genetically modified mice are now available, which provide the power to analyze the role of individual proteins in vivo. However, there are a number of points to be considered in the use and interpretation of these models. This review discusses the advantages and disadvantages involved in the generation and use of different genetically modified mouse models in endocrine research, including conventional techniques (e.g., overexpression, knockout, and knock-in models), tissue- and/or time-specific deletion of target genes [e.g., Cre-loxP and short interfering (si)RNA transgenic approaches], and gene-trap approaches to undertake functional genomics. This review also highlights the many factors that should be considered when assessing the phenotype of these mouse models, many of which are relevant to all murine physiological studies. These approaches are a powerful means by which to dissect the function of genes and are revolutionizing our understanding of endocrine physiology and metabolism.     

Exposing pepper plants to high day temperatures prevents the adverse low night temperature symptoms

Exposing pepper ( Capsicum annuum ) plants to extremely high day temperatures (HDT) (day/night temperatures of 36 ± 2/10 ± 2°C), obtained by keeping the greenhouse closed during the day to exploit solar heating, prevented the development of low night temperature (LNT) symptoms. Plants of cultivars Fiesta and Selica grown under LNTs (10 ± 2°C) and moderate day temperatures (25 ± 2°C) during winter exhibited retarded growth, reduced leaf numbers, and deformed fruits with few or no seeds. LNT caused a reduction in the number and quality of pollen grains: the reduction in pollen quality was associated with reduced starch accumulation in pollen grains at 3 days before anthesis (DBA) and a decrease of more than two-fold in total soluble sugars in the mature pollen grains. This inhibitory effect was associated with more than 50% reduction in the enzymatic activities of the cell wall-bound and soluble acid invertases that catalyze the hydrolysis of incoming sucrose molecules. All these symptoms were prevented by HDT treatment which matched the vegetative and reproductive performance of the plants to those of plants grown under optimal night temperature (ONT) conditions (day/night temperatures of 23 ± 2/18 ± 2°C). HDT also prevented the inhibitory effect of LNT on enzymatic activities of both invertases in pollen at 5 DBA and brought about the accumulation of high levels of starch in pollen at 3 DBA. The results presented could support the development of a novel procedure for producing greenhouse crops with minimum or even with no fuel consumption for heating during the winter nights in regions with bright and sunny days.