Interaction of prostaglandins and adenosine 5′-triphosphate in the noncholinergic neurotransmission in rabbit detrusor

Part of the excitatory transmission in rabbit detrusor is noncholinergic and nonadrenergic, and prostaglandins (PGs) and adenosine 5′-triphosphate (ATP) have been implicated in this transmission. The present experiments investigate the possibility of an interaction between PGs and ATP in rabbit detrusor. Indomethacin (2.8 μM) depressed the contraction produced by ATP although it did not antagonize the contraction produced by ATP although it did not antagonize the contraction produced by carbachol. Treatment of detrusor strips with 1.5 mM ATP depressed the frequency response curve in field stimulated tissues. This depression was additive with that produced by atropine. In the present experiments indomethacin did not significantly augment the effect of desensitization with ATP. It is suggested that the atropine-resistant neurotransmission in rabbit detrusor may involve both ATP and PGs acting in cooperation.     

Effect of Anti-inflammatory Drug Therapy on Clearance of 133Xe from Knee Joints of Patients with Rheumatoid Arthritis

The degree of joint inflammation in 13 patients with rheumatoid arthritis, as measured by clinical indices, was reduced by both sodium salicylate and indomethacin. The clearance rate of ¹³³Xe was reduced by indomethacin alone, and showed no correlation with the clinical features.     

Ecology,conservation status,and phylogenetic placement of endemic Pristimantis frogs (Anura: Craugastoridae) in Trinidad and Tobago and genetic affinities to northern Venezuela

Trinidad and Tobago are home to three endemic species in the anuran genus Pristimantis, of which two (Pristimantis charlottevillensis and Pristimantis turpinorum) occur in Tobago alone and the third (Pristimantis urichi) is present on both islands. Earlier, the IUCN assessed the conservation status of these species as: P. urichi, Endangered (EN); P. charlottevillensis, Least Concern (LC); P. turpinorum, Vulnerable (VU). However, these assessments were based on very little field-based evidence. Here, we present survey results which contributed to reassessments as LC, VU and Data Deficient for these three species, respectively. Despite the close proximity of Trinidad to northern Venezuela, the islands do not share any Pristimantis species with the mainland, which holds a rich endemicity of Pristimantis regionally. In this study, we used genetic sequencing from several island populations and compared them to northern Venezuelan endemics to assess genetic divergence for the first time. The time tree analyses found that only the northern Tobago species P. turpinorum is closely related to mainland Pristimantis, with a genetic split dating to the Late Miocene, suggesting a vicariant event of mainland and island species. Pristimantis urichi, although identical between the two islands, remains highly divergent from the mainland species. Similar results were found for P. charlottevillensis. In addition, there was a high level of divergence between P. urichi and P. charlottevillensis. These findings indicate different island colonization events by different lineages. Sequencing other Venezuelan species remains pivotal to unravel the complexity of the colonization episodes in the region, likely influenced by the changing topography and multiple connection and isolation episodes of the islands by eustatic sea-level changes.     

The effect of host plant intraspecific genetic variation on the fitness of a monophagous biological control agent

Variation in insect life-history traits when developing on different host plant genotypes with known genetic relationships was tested using the monophagous biological control agent Phenrica guérini Bechyné (Chrysomelidae) and its host plant, Pereskia aculeata Miller (Cactaceae). Differences in insect fitness among tested host plant genotypes were expected because of geographic isolation and large genetic distances between plant genotypes, and because P. guérini has been associated with some of the plant accessions in the field while others have never been exposed to herbivory by the insect. There was little variation in insect life-history traits among plant genotypes and no differences in the insect's ability to utilise different plant genotypes. The results of the study suggest that, in some cases, biological control agents collected from the native genotype most closely related to the target weed population will not always be more effective than those collected from more distantly related genotypes.     

Buffering Capacity Explains Signal Variation in Symbiotic Calcium Oscillations

Legumes form symbioses with rhizobial bacteria and arbuscular mycorrhizal fungi that aid plant nutrition. A critical component in the establishment of these symbioses is nuclear-localized calcium (Ca2+) oscillations. Different components on the nuclear envelope have been identified as being required for the generation of the Ca2+ oscillations. Among these an ion channel, Doesn''t Make Infections1, is preferentially localized on the inner nuclear envelope and a Ca2+ ATPase is localized on both the inner and outer nuclear envelopes. Doesn''t Make Infections1 is conserved across plants and has a weak but broad similarity to bacterial potassium channels. A possible role for this cation channel could be hyperpolarization of the nuclear envelope to counterbalance the charge caused by the influx of Ca2+ into the nucleus. Ca2+ channels and Ca2+ pumps are needed for the release and reuptake of Ca2+ from the internal store, which is hypothesized to be the nuclear envelope lumen and endoplasmic reticulum, but the release mechanism of Ca2+ remains to be identified and characterized. Here, we develop a mathematical model based on these components to describe the observed symbiotic Ca2+ oscillations. This model can recapitulate Ca2+ oscillations, and with the inclusion of Ca2+-binding proteins it offers a simple explanation for several previously unexplained phenomena. These include long periods of frequency variation, changes in spike shape, and the initiation and termination of oscillations. The model also predicts that an increase in buffering capacity in the nucleoplasm would cause a period of rapid oscillations. This phenomenon was observed experimentally by adding more of the inducing signal.Plant growth is frequently limited by the essential nutrients nitrogen and phosphorus. Several plant species have established symbiotic relationships with microorganisms to overcome such limitations. In addition to the symbiotic relationship with arbuscular mycorrhizal fungi that many plants establish in order to secure their uptake of water, phosphorus, and other nutrients (Harrison, 2005; Parniske, 2008), legumes have developed interactions with bacteria called rhizobia, resulting in the fixation of atmospheric nitrogen within the plant root (Lhuissier et al., 2001; Gage, 2004; Riely et al., 2006).Root symbioses initiate with signal exchanges in the soil. Plant signals are perceived by the symbionts, triggering the successive release of microbial signals. For rhizobia, the signal molecules are lipochitooligosaccharides termed Nod factors (Dénarié et al., 1996), and the release of lipochitooligosaccharides has also been found in the fungal interaction (Maillet et al., 2011). Upon receiving diffusible signals from the microsymbionts, the plant roots initiate developmental programs that lead to infection by rhizobia or arbuscular mycorrhizal fungi. Both programs employ the same signaling pathway with several components being common to both mycorrhizal and rhizobial interactions (Kistner and Parniske, 2002; Lima et al., 2009). In particular, both the symbioses show characteristic perinuclear and nucleoplasmic localized calcium (Ca2+) oscillations, so-called Ca2+ spiking (Oldroyd and Downie, 2006; Sieberer et al., 2009). It has been suggested that Ca2+ is released from an internal store, most likely the nuclear lumen and associated endoplasmic reticulum (ER; Matzke et al., 2009), with targeted release in the nuclear region (Capoen et al., 2011).Genetic screens in the model legume Medicago truncatula have identified several genes that are required for the plant in the establishment of both symbioses. Two of these, Doesn’t Make Infections1 (DMI1) and DMI2, are essential for the induction of the Ca2+ oscillations, yet the precise roles and mechanisms of these components remain to be determined. DMI2 codes for a plasma membrane receptor-like kinase (Endre et al., 2002; Stracke et al., 2002) that is required to facilitate further signal transduction in the cell (Bersoult et al., 2005). DMI1 is a cation channel located preferentially on the inner nuclear envelope (Ané et al., 2004; Edwards et al., 2007; Riely et al., 2007; Charpentier et al., 2008; Capoen et al., 2011; Venkateshwaran et al., 2012). DMI3 encodes a calcium calmodulin-dependent protein kinase that interacts with downstream components and is thought to be the decoder of the Ca2+ oscillations (Lévy et al., 2004; Mitra et al., 2004; Hayashi et al., 2010). Additional genes coding for three nucleoporins called NUP85, NUP133, and NENA are also required for Ca2+ oscillations (Kanamori et al., 2006; Saito et al., 2007; Groth et al., 2010). The nuclear pore might be involved in trafficking secondary signals and/or ion channels to the inner nuclear membrane. These shared signaling components are collectively referred to as the common Sym pathway.DMI1 plays a key role in the production of Ca2+ oscillations, but its exact mechanism is still unknown. Orthologs of DMI1 have been found; in Lotus japonicus, they are called CASTOR and POLLUX (Charpentier et al., 2008), and in pea (Pisum sativum), SYM8 (Edwards et al., 2007). CASTOR and POLLUX, as well as calcium calmodulin-dependent protein kinase, are highly conserved both in legumes and nonlegumes (Banba et al., 2008; Chen et al., 2009). This highlights the essential role of the Ca2+ oscillations in mycorrhizal signaling.DMI1 is not the channel responsible for the release of Ca2+ (Charpentier et al., 2008; Parniske, 2008; Venkateshwaran et al., 2012) but probably influences the activity of Ca2+ channels. This is similar to how some K⁺ channels act in other plants and yeast (Peiter et al., 2007). Indeed, DMI1 is possibly a K⁺-permeable channel, based on the observation that POLLUX complements K⁺ transport in yeast (Charpentier et al., 2008). In symbiosis, the mode of action of DMI1 could be to allow cations into the nuclear envelope and in that way counterbalance the transmembrane charge that would occur following the release of Ca2+ into the nucleoplasm and cytoplasm. The cation channel could thus change the electrical potential across the nuclear membranes, affecting the opening of the voltage-activated Ca2+ channels (Edwards et al., 2007). This hypothesis is supported by a study reporting a membrane potential over the nuclear envelope in plants (Matzke and Matzke, 1986).Pharmacological evidence and the characteristics of the Ca2+ oscillations supports the involvement of Ca2+ pumps and Ca2+ channels (Engstrom et al., 2002). The pumps are needed to resequester Ca2+ after each release event, actively transporting Ca2+ against the concentration gradient using ATP. A recent study found a SERCA-type Ca2+ ATPase, MCA8, that is located on the inner and outer nuclear envelope of M. truncatula and is required for the symbiotic Ca2+ oscillations (Capoen et al., 2011). Such SERCA pumps are widely distributed on plant membranes, and the variation in their structure points to them being differentially regulated (Sze et al., 2000).Ca2+ channels release Ca2+ from the store, and the mechanism of activating these Ca2+ channels has been hypothesized to be voltage gated (Edwards et al., 2007; Oldroyd and Downie, 2008), but this remains to be verified experimentally. After release of Ca2+ into the cytosol and nucleoplasm, buffers quickly bind to and remove these free ions due to their toxicity to the cell (Sanders et al., 2002). Buffers, i.e. molecules that can bind Ca2+, may play an important role in determining the nonlinear behavior of the oscillatory system for Ca2+ signaling (Falcke, 2004). As numerous Ca2+ buffers are present in cells, it is important to take their contribution into account. Such buffers can also include experimentally introduced dyes and Ca2+ chelators.In Capoen et al. (2011), we investigated the establishment and transmission of spatial waves across the nuclear envelope and demonstrated that the key components for Ca2+ spiking reside on the inner and outer surface of the nuclear membrane. The computational framework we employed for this analysis makes a number of approximations in order to provide the computational efficiency required to perform spatiotemporal simulations. Here, a main focus is to understand the effect of buffers on the Ca2+ oscillations.In this article, we propose a mathematical model based on three key proteins; a Ca2+ ATPase, a voltage-gated Ca2+ channel, and the cation channel DMI1. The model reproduces the symbiotic Ca2+ oscillations, and we further demonstrate that Ca2+-binding proteins can explain initiation, termination, and experimentally observed variation in oscillation patterns. Furthermore, the model predicts that increases in buffering capacity can cause a period of rapid oscillations, and these were observed experimentally.     

Silencing the activity and proliferative properties of the human EagI Potassium Channel by RNA Interference

EagI potassium channels are natively expressed in the mammalian brain as well as in many cancer cell lines and tumor tissues. The role of EagI in malignant transformation has been suggested by several experiments, but the lack of specific EagI inhibitors has made it difficult to examine the influence of the channel on oncogenesis and its potential as a therapeutic target. We have used short interfering RNA to test the effects of EagI reduction on the behavior of tumor cells in vitro. By generating and optimizing an EagI-specific short interfering RNA system, we were able to study the effects of EagI depletion on several cancer cell lines that endogenously express this protein. We show here that our short interfering RNA sequences act specifically on EagI, reproducibly induce a significant decrease in the proliferation of tumor cell lines, and do not trigger any observable nonspecific responses.     

Surface ciliation of anuran amphibian larvae: persistence to late stages in some species but not others

Scanning electron microscopy was used to examine the surfaces of 21 species of tadpoles from six families, from Gosner Stage 25/26 until close to metamorphosis. Contrary to most previous reports, ciliated epidermal cells persisted until late stages in many but not all species and not at all locations examined. The commonest location for ciliated cells was around the nostrils, suggesting a role in chemosensation. Ciliated cells also occurred around the circumference of the eye, suggesting a cleaning role. Several species had ciliated cells on the tail. The densest, most regular arrays of ciliated cells occurred in species that tend to hang motionless in still-water pools, suggesting a respiratory function for these cells.     

Identification of symbiotically defective mutants of Lotus japonicus affected in infection thread growth

During the symbiotic interaction between legumes and rhizobia, the host cell plasma membrane and associated plant cell wall invaginate to form a tunnel-like infection thread, a structure in which bacteria divide to reach the plant root cortex. We isolated four Lotus japonicus mutants that make infection pockets in root hairs but form very few infection threads after inoculation with Mesorhizobium loti. The few infection threads that did initiate in the mutants usually did not progress further than the root hair cell. These infection-thread deficient (itd) mutants were unaffected for early symbiotic responses such as calcium spiking, root hair deformation, and curling, as well as for the induction of cortical cell division and the arbuscular mycorrhizal symbiosis. Complementation tests and genetic mapping indicate that itd2 is allelic to Ljsym7, whereas the itdl, itd3, and itd4 mutations identified novel loci. Bacterial release into host cells did occur occasionally in the itdl, itd2, and itd3 mutants suggesting that some infections may succeed after a long period and that infection of nodule cells could occur normally if the few abnormal infection threads that were formed reached the appropriate nodule cells.