Mitogenic signaling from apoptotic cells in Drosophila

Apoptotic cells of Drosophila not only activate caspases, but also are able to secrete developmental signals like Hedgehog (Hh), Decapentaplegic (Dpp) and Wingless (Wg) before dying. Since Dpp and Wg are secreted in growing tissues and behave as growth factors, it was proposed that they play a role in compensatory proliferation, the process by which a growing blastema can restore normal size after massive apoptosis. We discuss recent results showing that there is normal compensatory proliferation in the absence of Dpp/Wg signaling, thus indicating it has no significant role in the process. Furthermore, we argue that Dpp/Wg signaling is not a resident feature of apoptotic cells, but a side effect of the necessary activation of the JNK pathway. Nevertheless, the ectopic JNK/Dpp/Wg signaling may have an important role in tissue regeneration. Recent work in other organisms suggests that paracrine signaling from apoptotic cells may be of general significance in wound healing and tissue regeneration in metazoans.     

Suboptimal in vitro culture conditions: an epigenetic origin of long-term health effects

The foetal origins of adult diseases or Barker hypothesis suggests that there can be adverse in uterus effects on the foetus that can lead to certain diseases in adults. Extending this hypothesis to the early stages of embryo development, in particular, to preimplantation stages, it was recently demonstrated that, long-term programming of postnatal development, growth and physiology can be irreversibly affected during this period of embryo development by suboptimal in vitro culture (IVC). As an example, it was found in two recent studies that, mice derived from embryos cultured in suboptimal conditions can suffer from obesity, increased anxiety, and deficiencies on their implicit memory system. In addition, it was observed that suboptimal IVC can cause disease in mature animals by promoting alterations in their genetic imprinting during preimplantation development. Imprinting and other epigenetic mechanisms control the establishment and maintenance of gene expression patterns in the embryo, placenta and foetus. The previously described observations, suggest that the loss of epigenetic regulation during preimplantation development may lead to severe long-term effects. Although mostly tested in rodents, the hypothesis that underlies these studies can also fit assisted reproductive technology (ART) procedures in other species, including humans. The lack of information on how epigenetic controls are lost during IVC, and on the long-term consequences of ART, underscore the necessity for sustained epigenetic analysis of embryos produced in vitro and long-term tracking of the health of the human beings conceived using these procedures.     

Land-use and edge effects unbalance seed dispersal and predation interactions under habitat fragmentation

The process of fragmentation can greatly influence plant–animal interactions. To assess the degree to which it affects the balance between two interactions of opposite sign, namely seed dispersal and post-dispersal seed predation, we selected 16 patches of chestnut forest in O Courel and El Bierzo, northwestern Spain. We assessed the effect of fragmentation over two different seed dispersal–predation systems using Helleborus foetidus and Ilex aquifolium as model species. In the first case, field experiments consisted of seed-offering trays with selective exclusion of rodents and ants in a two-way orthogonal design. In the second experiment, we placed experimental branches and trays on the floor to assess seed dispersal and predation. The interactions between several fragment traits and the relative contribution of rodents, ants and birds to seed removal were analyzed by means of generalized linear mixed models. Results show that for H. foetidus, differences in seed dispersal–predation were accounted for by patch shape, which affected mainly the dispersal phase. Major seed dispersal took place in patches with a smaller edge to core ratio and high plant cover (abandoned patches), whilst the latter also showed maximum seed predation. For I. aquifolium, fragmentation effects were significant only for seed predation, which was increased in abandoned patches. This shows that the effects of habitat fragmentation can emerge at different phases depending on specific traits of the interacting animals. It also highlights the importance of traditional land-use practices in species interactions.     

Changes in patch features may exacerbate or compensate for the effect of habitat loss on forest bird populations

One and a half centuries after Darwin visited Chiloe Island, what he described as "…an island covered by one great forest…" has lost two-thirds of its forested areas. At this biodiversity hotspot, forest surface is becoming increasingly fragmented due to unregulated logging, clearing for pastures and replacement by exotic tree plantations. Decrease in patch size, increased isolation and "edge effects" can influence the persistence of forest species in remnant fragments. We assessed how these variables affect local density for six forest birds, chosen to include the most important seed dispersers (four species) and bird pollinators (two species, one of which acts also as seed disperser), plus the most common insectivore (Aphrastura spinicauda). Based on cue-count point surveys (8 points per fragment), we estimated bird densities for each species in 22 forest fragments of varying size, shape, isolation and internal-habitat structure (e.g. tree size and epiphyte cover). Bird densities varied with fragment connectivity (three species) and shape (three species), but none of the species was significantly affected by patch size. Satellite image analyses revealed that, from 1985 to 2008, forested area decreased by 8.8% and the remaining forest fragments became 16% smaller, 58-73% more isolated and 11-50% more regular. During that period, bird density estimates for the northern part of Chiloé (covering an area of 1214.75 km(2)) decreased for one species (elaenia), increased for another two (chucao and hummingbird) and did not vary for three (rayadito, thrust and blackbird). For the first three species, changes in patch features respectively exacerbated, balanced and overcame the effects of forest loss on bird population size (landscape-level abundance). Hence, changes in patch features can modulate the effect of habitat fragmentation on forest birds, suggesting that spatial planning (guided by spatially-explicit models) can be an effective tool to facilitate their conservation.     

Calmodulin Activation Limits the Rate of KCNQ2 K+ Channel Exit from the Endoplasmic Reticulum

The potential regulation of protein trafficking by calmodulin (CaM) is a novel concept that remains to be substantiated. We proposed that KCNQ2 K⁺ channel trafficking is regulated by CaM binding to the C-terminal A and B helices. Here we show that the L339R mutation in helix A, which is linked to human benign neonatal convulsions, perturbs CaM binding to KCNQ2 channels and prevents their correct trafficking to the plasma membrane. We used glutathione S-transferase fused to helices A and B to examine the impact of this and other mutations in helix A (I340A, I340E, A343D, and R353G) on the interaction with CaM. The process appears to require at least two steps; the first involves the transient association of CaM with KCNQ2, and in the second, the complex adopts an “active” conformation that is more stable and is that which confers the capacity to exit the endoplasmic reticulum. Significantly, the mutations that we have analyzed mainly affect the stability of the active configuration of the complex, whereas Ca²⁺ alone appears to affect the initial binding step. The spectrum of responses from this collection of mutants revealed a strong correlation between adopting the active conformation and channel trafficking in mammalian cells. These data are entirely consistent with the concept that CaM bound to KCNQ2 acts as a Ca²⁺ sensor, conferring Ca²⁺ dependence to the trafficking of the channel to the plasma membrane and fully explaining the requirement of CaM binding for KCNQ2 function.M-type channels are generated by the KCNQ (Kv7) family of voltage-gated subtypes (1), and they are found throughout the nervous system where they fulfill dominant roles in the control of excitability and neural discharges (2). Like all Kv channels, the KCNQ α subunits share a common core structure of six transmembrane segments with a voltage sensing domain (S1–S4) and a pore domain (S5 and S6; see Fig. 1) (3). Sequence analysis predicts the presence of four helical regions (A–D) in all family members (4), and helices A and B constitute the binding site for calmodulin (CaM).⁸ CaM is a prototypical Ca²⁺ sensor that confers Ca²⁺ sensitivity to a wide array of proteins, including ion channels (5). CaM is thought to mediate Ca²⁺-dependent inhibition of KCNQ channels (6), and in addition, we have postulated that a direct association with CaM is required for KCNQ2 channels to exit the endoplasmic reticulum (7).Open in a separate windowFIGURE 1.Topological representation of a KCNQ subunit. The consensus IQ residues are shown in bold. Circles and squares correspond to the residues mutated here (the squares indicate the mutations causing BFNC). The boxes indicate the regions with a high probability of adopting an α helix configuration, and the thick lines delineate the region fused to GST.To gain a deeper understanding into the involvement of CaM in channel trafficking, we have studied this interaction in vitro with a set of CaM-binding site-specific mutants. Although we had previously explored the impact of some of these mutants on channel trafficking (7), here we have extended this study to the mutant L339R located in helix A. This mutation, as well as the R353G mutation in helix A, has been linked to benign familial neonatal convulsions (BFNC), a human epileptic syndrome of newborn children (2). Accordingly, we demonstrate that there is a strong correlation between the impact of these mutations on the adoption of an “active” conformation by CaM and channel subunit exit from the ER, lending further support to the concept that CaM is a critical regulator for the exit of the channel from the ER.     

Caspase-8 isoform 6 promotes death effector filament formation independent of microtubules

Caspase-8 can trigger cell death following prodomain-mediated recruitment to the ‘death-inducing signaling complex.’ The prodomain consists of two death effector domain (DED) motifs that undergo homotypic interactions within the cell. Aside from mediating recruitment of procaspase-8, the prodomains have also been implicated in regulating cell survival, proliferation, death, senescence, differentiation, and substrate attachment. Here, we perform the initial characterization of a novel isoform of caspase-8, designated caspase-8 isoform 6 (Casp-8.6), which encodes both prodomain DEDs followed by a unique C-terminal tail. Casp-8.6 is detected in cells of the hematopoietic compartment as well as several other tissues. When Casp-8.6 expression is reconstituted in caspase-8-deficient cells, Casp-8.6 does not significantly impact cellular proliferation, contrasting with our previous results using a domain-defined ‘DED-only’ construct that lacks the C-terminal tail. Like the DED-only construct, Casp-8.6 also robustly forms ‘death effector’ filaments, but in contrast to the DED construct, it does not exhibit a dependence upon intact microtubules to scaffold filament formation. Both types of death effector filaments promote apoptosis when expressed in the presence of full length caspase-8 (isoform 1). Together, the results implicate Casp-8.6 as a new physiological modulator of apoptosis.     

Development and validation of an automated high-throughput system for zebrafish in vivo screenings

The zebrafish is a vertebrate model compatible with the paradigms of drug discovery. The small size and transparency of zebrafish embryos make them amenable for the automation necessary in high-throughput screenings. We have developed an automated high-throughput platform for in vivo chemical screenings on zebrafish embryos that includes automated methods for embryo dispensation, compound delivery, incubation, imaging and analysis of the results. At present, two different assays to detect cardiotoxic compounds and angiogenesis inhibitors can be automatically run in the platform, showing the versatility of the system. A validation of these two assays with known positive and negative compounds, as well as a screening for the detection of unknown anti-angiogenic compounds, have been successfully carried out in the system developed. We present a totally automated platform that allows for high-throughput screenings in a vertebrate organism.