Ras proteins are small GTP binding proteins that serve as critical relays in a variety of signal transduction pathways in eukaryotic cells. Like most metazoan Ras proteins, yeast Ras is post-translationally modified by addition of a farnesyl and a palmitoyl moiety, and these modifications are required for targeting the protein to the cytoplasmic face of the plasma membrane and for biological activity of the protein. We have constructed mutants of the yeast (Saccharomyces cerevisiae) Ras that are farnesylated in vivo but are not palmitoylated. These mutant proteins are not localized to the plasma membrane but function in the cell as well as the wild-type protein. Such mutants are viable but fail to induce a transient increase in intracellular cAMP concentration in response to glucose addition, although this deficiency does not yield a marked growth phenotype. These results are consistent with the hypothesis that the essential role of the farnesyl moiety on yeast Ras is to enhance productive interaction between Ras and its essential downstream target, adenylyl cyclase, rather than to localize Ras to the plasma membrane.All Ras proteins undergo a series of post-translational modifications of their carboxyl termini, including farnesylation and in most cases palmitoylation, that are required for partitioning the proteins to the cytoplasmic face of the plasma membrane (1-10). In metazoans, this localization appears to be essential for Ras's role in signal transduction, since signaling through the pathway relies on repartitioning the Ras activating protein, Sos, and the Ras effector protein, Raf, to the membrane compartment at which Ras resides as the means of completing the signaling circuit (11)(12)(13)(14)(15)(16)(17).Yeast Ras proteins participate in a signal transduction pathway that appears to connect glucose availability to the metabolic activity of the cell. The two Ras proteins, encoded by RASI and RAS2, stimulate adenylyl cyclase to yield increased cAMP levels, which in turn activates the cAMPdependent protein kinase (A kinase) (18,19). Phosphorylation of a number of target proteins by activated A kinase results in enhanced glycolysis, mobilization of energy reserves, and specific transcriptional activation. The precise biological signal that activates Ras is not known, but addition of glucose to starved cells yields a transient increase in cAMP levels that is dependent on Ras and on the Ras guanine nucleotide exchange factor, Cdc25p (20-24).Previous observations have established a correlation between post-translational processing of Ras, its membrane localization, and its biological activity. Like metazoan Ras proteins, yeast Ras proteins are post-translationally modified by farnesylation, palmitoylation, proteolytic removal of the terminal three amino acids, and carboxyl methylesterification (2, 6, 9). Yeast Ras proteins are located predominantly in the cell in a membrane compartment, as are other components of the signal transduction pathway with which Ras interacts, including adenylyl cyclase and ...
By differential hybridization, we identified a number of genes in Saccharomyces cerevisiae that are activated by addition of cyclic AMP (cAMP) to cAMP-depleted cells. A majority, but not all, of these genes encode ribosomal proteins. While expression of these genes is also induced by addition of the appropriate nutrient to cells starved for a nitrogen source or for a sulfur source, the pathway for nutrient activation of ribosomal protein gene transcription is distinct from that of cAMP activation: (i) cAMP-mediated transcriptional activation was blocked by prior addition of an inhibitor of protein synthesis whereas nutrient-mediated activation was not, and (ii) cAMP-mediated induction of expression occurred through transcriptional activation whereas nutrient-mediated induction was predominantly a posttranscriptional response. Transcriptional activation of the ribosomal protein gene RPL16A by cAMP is mediated through a upstream activation sequence element consisting of a pair of RAP1 binding sites and sequences between them, suggesting that RAP1 participates in the cAMP activation process. Since RAP1 protein decays during starvation for cAMP, regulation of ribosomal protein genes under these conditions may directly relate to RAP1 protein availability. These results define additional critical targets of the cAMP-dependent protein kinase, suggest a mechanism to couple ribosome production to the metabolic activity of the cell, and emphasize that nutrient regulation is independent of the RAS/cAMP pathway.
Synaptobrevins or VAMPs are vesicle-associated membrane proteins, often called v-SNARES, that are important for vesicle transport and fusion at the plasma membrane. Drosophila has two characterized members of this gene family: synaptobrevin (syb) and neuronal synaptobrevin (n-syb). Mutant phenotypes and gene-expression patterns indicate that n-Syb is exclusively neuronal and required only for synaptic vesicle secretion, whereas Syb is ubiquitous and, as shown here, essential for cell viability. When the eye precursor cells were made homozygous for syb ؊ , the eye failed to develop. In contrast, n-syb ؊ eye clones developed appropriately but failed to activate downstream neurons. To determine whether the two proteins are structurally specialized to accomplish these distinct in vivo functions, we have driven the expression of each gene in the absence of the other to look for phenotypic rescue. We find that expression of n-syb during eye development can rescue the cell lethality of the syb mutations, as can rat VAMP2 and cellubrevin. Expression of syb can restore synaptic transmission to n-syb mutants as assayed both by electroretinogram and recordings of excitatory junctional currents at the neuromuscular junction. Therefore, we find that Syb, which usually is not involved in synaptic function, can mediate Ca 2؉ -triggered synaptic activity and that no particular specialization of the v-SNARE is required to differentiate synaptic exocytosis from other forms.
SUMMARY The evolutionary success of parasitoid wasps, a highly diverse group of insects widely used in biocontrol, depends on a variety of life history strategies in conflict with those of their hosts [1]. Drosophila melanogaster is a natural host of parasitic wasps of the genus Leptopilina. Attack by L. boulardi (Lb), a specialist wasp to flies of the melanogaster group, activates NF-κB-mediated humoral and cellular immunity. Inflammatory blood cells mobilize and encapsulate Lb eggs and embryos [2–5]. L. heterotoma (Lh), a generalist wasp, kills larval blood cells and actively suppresses immune responses. Spiked virus-like particles (VLPs) in wasp venom have clearly been linked to its successful parasitism of Drosophila [6], but VLP composition and their biotic nature have remained mysterious. Our proteomics studies reveal that VLPs lack viral coat proteins but possess a pharmacopoeia of (a) eukaryotic vesicular transport system, (b) immunity, and (c) previously unknown proteins. These novel proteins distinguish Lh from Lb VLPs; notably, some proteins specific to Lh VLPs possess sequence similarities with bacterial secretion system proteins. Structure-informed analyses of an abundant Lh VLP surface/spike-tip protein, p40, reveal similarities to the needle-tip invasin proteins SipD/IpaD of Gram negative bacterial type 3 secretion systems that breach immune barriers and deliver virulence factors into mammalian cells. Our studies suggest that Lh VLPs represent a new class of extracellular organelles and share pathways for protein delivery with both eukaryotic microvesicles and bacterial surface secretion systems. Given their mixed prokaryotic/eukaryotic properties, we propose the term Mixed Strategy Extracellular Vesicles (MSEVs) to replace VLP.
The hindlimb unloading (HU) model has been used extensively to simulate the cephalad fluid shift and musculoskeletal disuse observed in spaceflight with its application expanding to study immune, cardiovascular and central nervous system responses, among others. Most HU studies are performed with singly housed animals, although social isolation also can substantially impact behavior and physiology, and therefore may confound HU experimental results. Other HU variants that allow for paired housing have been developed although no systematic assessment has been made to understand the effects of social isolation on HU outcomes. Hence, we aimed to determine the contribution of social isolation to tissue responses to HU. To accomplish this, we developed a refinement to the traditional NASA Ames single housing HU system to accommodate social housing in pairs, retaining desirable features of the original design. We conducted a 30-day HU experiment with adult, female mice that were either singly or socially housed. HU animals in both single and social housing displayed expected musculoskeletal deficits versus housing matched, normally loaded (NL) controls. However, select immune and hypothalamic-pituitary-adrenal (HPA) axis responses were differentially impacted by the HU social environment relative to matched NL controls. HU led to a reduction in % CD4+ T cells in singly housed, but not in socially housed mice. Unexpectedly, HU increased adrenal gland mass in socially housed but not singly housed mice, while social isolation increased adrenal gland mass in NL controls. HU also led to elevated plasma corticosterone levels at day 30 in both singly and socially housed mice. Thus, musculoskeletal responses to simulated weightlessness are similar regardless of social environment with a few differences in adrenal and immune responses. Our findings show that combined stressors can mask, not only exacerbate, select responses to HU. These findings further expand the utility of the HU model for studying possible combined effects of spaceflight stressors.
While it has been shown that astronauts suffer immune disorders after spaceflight, the underlying causes are still poorly understood and there are many variables to consider when investigating the immune system in a complex environment. Additionally, there is growing evidence that suggests that not only is the immune system being altered, but the pathogens that infect the host are significantly influenced by spaceflight and ground-based spaceflight conditions. In this study, we demonstrate that Serratia marcescens (strain Db11) was significantly more lethal to Drosophila melanogaster after growth on the International Space Station than ground-based controls, but the increased virulence phenotype of S. marcescens did not persist after the bacterial cultures were passaged on the ground. Increased virulence was also observed in bacteria that were grown in simulated microgravity conditions on the ground using the rotating wall vessel. Increased virulence of the space-flown bacteria was similar in magnitude between wild-type flies and those that were mutants for the well-characterized immune pathways Imd and Toll, suggesting that changes to the host immune system after infection are likely not a major factor contributing towards increased susceptibility of ground-reared flies infected with space-flown bacteria. Characterization of the bacteria shows that at later timepoints spaceflight bacteria grew at a greater rate than ground controls in vitro, and in the host. These results suggest complex physiological changes occurring in pathogenic bacteria in space environments, and there may be novel mechanisms mediating these physiological effects that need to be characterized.
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