Drug Synergy Drives Conserved Pathways to Increase Fission Yeast Lifespan

Aging occurs over time with gradual and progressive loss of physiological function. Strategies to reduce the rate of functional loss and mitigate the subsequent onset of deadly age-related diseases are being sought. We demonstrated previously that a combination of rapamycin and myriocin reduces age-related functional loss in the Baker’s yeast Saccharomyces cerevisiae and produces a synergistic increase in lifespan. Here we show that the same drug combination also produces a synergistic increase in the lifespan of the fission yeast Schizosaccharomyces pombe and does so by controlling signal transduction pathways conserved across a wide evolutionary time span ranging from yeasts to mammals. Pathways include the target of rapamycin complex 1 (TORC1) protein kinase, the protein kinase A (PKA) and a stress response pathway, which in fission yeasts contains the Sty1 protein kinase, an ortholog of the mammalian p38 MAP kinase, a type of Stress Activated Protein Kinase (SAPK). These results along with previous studies in S. cerevisiae support the premise that the combination of rapamycin and myriocin enhances lifespan by regulating signaling pathways that couple nutrient and environmental conditions to cellular processes that fine-tune growth and stress protection in ways that foster long term survival. The molecular mechanisms for fine-tuning are probably species-specific, but since they are driven by conserved nutrient and stress sensing pathways, the drug combination may enhance survival in other organisms.     

Identification of a Short Spir Interaction Sequence at the C-terminal End of Formin Subgroup Proteins

The actin nucleation factors Spire and Cappuccino interact with each other and regulate essential cellular events during Drosophila oogenesis in a cooperative fashion. The interaction blocks formin actin nucleation activity and enhances the Spire activity. Analogous to Spire and Cappuccino, the mammalian homologs Spir-1 and formin-2 show a regulatory interaction. To get an understanding of the nature of the Spir-formin cooperation, we have analyzed the interaction biochemically and biophysically. Our data shows that the association of Spir-1 and formin-2 is not significantly mediated by binding of the Spir-1-KIND domain to the formin FH2 core domain. Instead, a short sequence motif C-terminal adjacent to the formin-2-FH2 domain could be characterized that mediates the interaction and is conserved among the members of the Fmn subgroup of formins. In line with this, we found that both mammalian Spir proteins, Spir-1 and Spir-2, interact with mammalian Fmn subgroup proteins formin-1 and formin-2.Basic cell biological functions such as proliferation, migration, division, and vesicle transport rely on the organization of the actin cytoskeleton. The initiation of actin polymerization from free actin monomers is regulated by actin nucleation factors (NF),² which help to overcome the kinetic barrier of spontaneous G-actin nucleation and, thus, catalyze the formation of filamentous actin structures and networks (1). To date, three different classes of NFs are described, the ARP2/3 complex, FH2 domain containing NFs of the formin superfamily, and NFs containing one or multiple WH2 domains (Spire/Cordon-bleu/Leiomodin) (2). The formin superfamily is subdivided into seven subfamilies (Dia, FRL, DAAM, Delphilin, INF, FHOD, Fmn) (3). The mechanisms of actin nucleation as well as the regulation of the NFs vary significantly between the three classes (and also show variances in between the distinct superfamilies). Spire and Cappuccino are NFs that belong to the Spire subfamily of WH2 containing nucleators and to the Fmn subfamily of the FH2 domain containing formins, respectively. In contrast to the Arp2/3 complex that nucleates branched filaments, Spire and the formin Cappuccino nucleate unbranched actin filaments (4).Almost two decades ago it was found that mutants of the two Drosophila NFs (Spire/Cappuccino) have an identical phenotype in early Drosophila oogenesis, i.e. both induce premature ooplasmic streaming (5, 6). Later it was shown that both proteins cooperate in the generation of a dynamic actin mesh in the oocyte that prevents premature ooplasmic streaming (7). Spire and Cappuccino do not solely have the same mutant phenotype; the proteins also physically interact and cross-regulate each other. The Cappuccino C-terminal half, encoding the FH2 domain and flanking sequences, enhances the nucleation activity of Spire, whereas the nucleation activity of Cappuccino is decreased in the presence of the Spire-KIND domain (8).Cappuccino belongs to the Fmn subgroup of formins (3, 9). In mammals, two Fmn subgroup members (formin-1, formin-2) and two Spir proteins (Spir-1, Spir-2) exist (3, 10). The formin-2 and spir-1 genes are coexpressed in the developing and adult nervous system, and the proteins interact analogous to their Drosophila counterparts Spire and Cappuccino (8, 10). Several reports showed the importance of formin-2 in mouse oogenesis and here especially in the positioning of the meiotic spindle (11–14). Recently it was found that a dynamic actin mesh, as during Drosophila oogenesis, is also required for mouse oogenesis (11, 14). The correct localization of the meiotic spindle during mouse oogenesis and the resulting asymmetric division depends on an actin mesh that is built up by formin-2. Myosin-2 generates the pulling forces required for spindle movement (14). Beside the evolutionary conserved roles for the formins Cappuccino and formin-2, Spire family proteins also seem to be evolutionary conserved regulators of oocyte development. Spire genes of the African clawed frog Xenopus (pEg6) and the sea squirt Ciona savignyi (Pem-5) have been identified as maternal genes in the oocyte in analogy to its Drosophila homolog and are proposed to function in polarity during early embryogenesis (15, 16).In an initial characterization it was found that the KIND domains of Spir-1/dSpire interact with the C-terminal sequences of formin-2/Cappuccino, which encode the FH2 domains and flanking sequences (8). To gain a further understanding of the interaction and cross-regulation of the two proteins, we investigated this interaction in detail. The objective of the study was the dissection of the formin-2/Spir-1 interaction and the determination of the structural elements that are responsible for the binding. The dissection revealed a high affinity Spir-1 interaction site of formin-2, which could be mapped to the very C terminus of formin-2 adjacent to its core FH2 domain (formin Spir interaction (FSI) sequence). The FSI sequence is conserved among the members of the Fmn subgroup. Consistently we found that all mammalian members of the two distinct nucleator families, Spir-1/2 and Fmn-1/2, interact with each other.     

Early phase changes by concurrent endurance and strength training

To compare regimens of concurrent strength and endurance training, 26 male basketball players were matched for stature, body composition, and physical activity level. Subjects completed different training programs for 7 weeks, 4 days per week. Groups were as follows: (a) the strength group (S; n = 7) did strength training; (b) the endurance group (E; n = 7) did endurance training; (c) the strength and endurance group (S + E; n = 7) combined strength and endurance training; and (d) the control group (C; n = 5) had no training. The S + E group showed greater gains in Vo(2)max than the E group did (12.9% vs. 6.8%), whereas the S group showed a decline (8.8%). Gains were noted in strength and vertical jump performance for the S + E and S groups. The S + E group had better posttraining anaerobic power than the S group did (6.2% vs. 2.9%). No strength, power, or anaerobic power gains were present for the E and C groups. We conclude that concurrent endurance and strength training is more effective in terms of improving athletic performance than are endurance and strength training apart.     

Healthy individuals that control a latent infection with Mycobacterium tuberculosis express high levels of Th1 cytokines and the IL-4 antagonist IL-4delta2

The majority of healthy individuals exposed to Mycobacterium tuberculosis will not develop disease and identifying what constitutes "protective immunity" is one of the holy grails of M. tuberculosis immunology. It is known that IFN-gamma is essential for protection, but it is also apparent that IFN-gamma levels alone do not explain the immunity/susceptibility dichotomy. The controversy regarding correlates of immunity persists because identifying infected but healthy individuals (those who are immune) has been problematic. We have therefore used recognition of the M. tuberculosis virulence factor early secretory antigenic target 6 to identify healthy, but infected individuals from tuberculosis (TB)-endemic and nonendemic regions (Ethiopia and Denmark) and have compared signals for cytokines expressed directly ex vivo with the pattern found in TB patients. We find that TB patients are characterized by decreased levels of Th1 cytokines and increased levels of IL-10 compared with the healthy infected and noninfected community controls. Interestingly, the healthy infected subjects exhibited a selective increase of message for the IL-4 antagonist, IL-4delta2, compared with both TB patients or noninfected individuals. These data suggest that long-term control of M. tuberculosis infection is associated not just with elevated Th1 responses but also with inhibition of the Th2 response.     

Cumulative hydropathic topology of a voltage-gated sodium channel at atomic resolution

Voltage-gated sodium channels (NavChs) are biological pores that control the flow of sodium ions through the cell membrane. In humans, mutations in genes encoding NavChs can disrupt physiological cellular activity thus leading to a wide spectrum of diseases. Here, we present a topological connection between the functional architecture of a NavAb bacterial channel and accumulation of atomic hydropathicity around its pore. This connection is established via a scaling analysis methodology that elucidates how intrachannel hydropathic density variations translate into hydropathic dipole field configurations along the pore. Our findings suggest the existence of a nonrandom cumulative hydropathic topology that is organized parallel to the membrane surface so that pore's stability, as well as, gating behavior are guaranteed. Given the biophysical significance of the hydropathic effect, our study seeks to provide a computational framework for studying cumulative hydropathic topological properties of NavChs and pore-forming proteins in general.     

Collagen fibre orientation in human bridging veins

Biomechanics and Modeling in Mechanobiology - Bridging veins (BVs) drain the blood from the cerebral cortex into dural sinuses. BVs have one end attached to the brain and the other to the superior...     

The effect of alphaxalone-alphadolone, propofol, and pentobarbitone anaesthesia on the β-endorphin and ACTH response to haemorrhage in the pig

In the literature there appears to be variability in reported levels of certain hormones during haemorrhage, specifically adrenocorticotrophic hormone (ACTH) and β-endorphin. It is possible that this variability may be due to the choice of anaesthetic. Therefore, the effect of 3 common research-only anaesthetic agents (alphaxalone-alphadolone, propofol, and pentobarbitone) on ACTH and β-endorphin levels during haemorrhage was assessed in pigs. Animals were divided into 3 groups: group I received alphaxalone-alphadolone (n = 5), group II received propofol (n = 6), and group III received pentobarbitone (n = 6). Pigs were subjected to a continuous fixed-volume haemorrhage under one of the above anaesthetics while being mechanically ventilated. ACTH and β-endorphin levels increased significantly during haemorrhage under propofol and pentobarbitone anaesthesia but not with alphaxalone-alphadolone. For ACTH there was no significant difference between the groups, whereas for β-endorphin there was a significant difference between the propofol- and pentobarbitone-anaesthetized pigs. The increase in heart rate during haemorrhage was significantly different between the alphaxalone-alphadolone and propofol as well as between the propofol and pentobarbitone groups. The drop in blood pressure was only significantly different between the alphaxalone-alphadolone- and propofol-anaesthetized pigs. These results indicate that the choice of anaesthetic agent can affect the hormone response to haemorrhage and may account for the variable hormone levels reported in the published literature to date.     

T-Cell Regulation in Lepromatous Leprosy

Regulatory T (T_reg) cells are known for their role in maintaining self-tolerance and balancing immune reactions in autoimmune diseases and chronic infections. However, regulatory mechanisms can also lead to prolonged survival of pathogens in chronic infections like leprosy and tuberculosis (TB). Despite high humoral responses against Mycobacterium leprae (M. leprae), lepromatous leprosy (LL) patients have the characteristic inability to generate T helper 1 (Th1) responses against the bacterium. In this study, we investigated the unresponsiveness to M. leprae in peripheral blood mononuclear cells (PBMC) of LL patients by analysis of IFN-γ responses to M. leprae before and after depletion of CD25⁺ cells, by cell subsets analysis of PBMC and by immunohistochemistry of patients'' skin lesions. Depletion of CD25⁺ cells from total PBMC identified two groups of LL patients: 7/18 (38.8%) gained in vitro responsiveness towards M. leprae after depletion of CD25⁺ cells, which was reversed to M. leprae-specific T-cell unresponsiveness by addition of autologous CD25⁺ cells. In contrast, 11/18 (61.1%) remained anergic in the absence of CD25⁺ T-cells. For both groups mitogen-induced IFN-γ was, however, not affected by depletion of CD25⁺ cells. In M. leprae responding healthy controls, treated lepromatous leprosy (LL) and borderline tuberculoid leprosy (BT) patients, depletion of CD25⁺ cells only slightly increased the IFN-γ response. Furthermore, cell subset analysis showed significantly higher (p = 0.02) numbers of FoxP3⁺ CD8⁺CD25⁺ T-cells in LL compared to BT patients, whereas confocal microscopy of skin biopsies revealed increased numbers of CD68⁺CD163⁺ as well as FoxP3⁺ cells in lesions of LL compared to tuberculoid and borderline tuberculoid leprosy (TT/BT) lesions. Thus, these data show that CD25⁺ T_reg cells play a role in M. leprae-Th1 unresponsiveness in LL.     

Shared ancestry influences community stability by altering competitive interactions: evidence from a laboratory microcosm experiment using freshwater green algae

The impact of biodiversity on the stability of ecological communities has been debated among biologists for more than a century. Recently summarized empirical evidence suggests that biodiversity tends to enhance the temporal stability of community-level properties such as biomass; however, the underlying mechanisms driving this relationship remain poorly understood. Here, we report the results of a microcosm study in which we used simplified systems of freshwater microalgae to explore how the phylogenetic relatedness of species influences the temporal stability of community biomass by altering the nature of their competitive interactions. We show that combinations of two species that are more evolutionarily divergent tend to have lower temporal stability of biomass. In part, this is due to negative ‘selection effects’ in which bicultures composed of distantly related species are more likely to contain strong competitors that achieve low biomass. In addition, bicultures of distantly related species had on average weaker competitive interactions, which reduced compensatory dynamics and decreased the stability of community biomass. Our results demonstrate that evolutionary history plays a key role in controlling the mechanisms, which give rise to diversity–stability relationships. As such, patterns of shared ancestry may help us predict the ecosystem-level consequences of biodiversity loss.