Mechanisms of programmed cell death during oogenesis in <Emphasis Type="Italic">Drosophila virilis</Emphasis>

We describe the features of programmed cell death occurring in the egg chambers of Drosophila virilis during mid-oogenesis and late oogenesis. During mid-oogenesis, the spontaneously degenerating egg chambers exhibit typical characteristics of apoptotic cell death. As revealed by propidium iodide, rhodamine-conjugated phalloidin staining, and the TUNEL assay, respectively, the nurse cells contain condensed chromatin, altered actin cytoskeleton, and fragmented DNA. In vitro caspase activity assays and immunostaining procedures demonstrate that the atretic egg chambers possess high levels of caspase activity. Features of autophagic cell death are also observed during D. virilis mid-oogenesis, as shown by monodansylcadaverine staining, together with an ultrastructural examination by transmission electron microscopy. During the late stages of oogenesis in D. virilis, once again, the two mechanisms, viz., nurse cell cluster apoptosis and autophagy, operate together, manifesting features of cell death similar to those detailed above. Moreover, an altered form of cytochrome c seems to be released from the mitochondria in the nurse cells proximal to the oocyte. We propose that apoptosis and autophagy function synergistically during oogenesis in D. virilis in order to achieve a more efficient elimination of the degenerated nurse cells and abnormal egg chambers. The present study was co-financed within Op. Education by the European Social Fund and by National Resources via a grant (HRAKLEITOS 70/3/7164) to Professor L.H. Margaritis.     

An Extended,Boolean Model of the Septation Initiation Network in S.Pombe Provides Insights into Its Regulation

Cytokinesis in fission yeast is controlled by the Septation Initiation Network (SIN), a protein kinase signaling network using the spindle pole body as scaffold. In order to describe the qualitative behavior of the system and predict unknown mutant behaviors we decided to adopt a Boolean modeling approach. In this paper, we report the construction of an extended, Boolean model of the SIN, comprising most SIN components and regulators as individual, experimentally testable nodes. The model uses CDK activity levels as control nodes for the simulation of SIN related events in different stages of the cell cycle. The model was optimized using single knock-out experiments of known phenotypic effect as a training set, and was able to correctly predict a double knock-out test set. Moreover, the model has made in silico predictions that have been validated in vivo, providing new insights into the regulation and hierarchical organization of the SIN.     

Sequential genetic modification of the hprt locus in human ESCs combining gene targeting and recombinase-mediated cassette exchange

Genetic modification of human embryonic stem cells (hESCs) will be an essential tool to allow full exploitation of these cells in regenerative medicine and in the study of hESC biology. Here we report multiple sequential modifications of an endogenous gene (hprt) in hESCs. A selectable marker flanked by heterospecific lox sites was first introduced by homologous recombination (HR) into the hprt gene. In a subsequent step, exchange of the selectable marker with another cassette was achieved by recombinase-mediated cassette exchange (RMCE). We show that 100% of the recovered clones were the result of RMCE using a promoter trap strategy at the hprt locus. hprt-targeted H1 cells maintained a diploid karyotype and expressed hESC surface markers before and after RMCE. Finally, we report a double replacement strategy using two sequential gene targeting steps resulting in the targeted correction of an hprt-mutated hESC line.     

Stable expression of human growth hormone over 50 generations in transgenic insect larvae

Developments in insect transgenesis using transposons combined with available mass rearing technology for insects such as the Medfly, Ceratitis capitata, provide opportunity for the production of protein for industrial, agricultural and healthcare purposes on a very large scale. In this study, we report the germ-line transformation and expression of a cDNA encoding human growth hormone (hGH) in transgenic Drosophila using the Minos transposon. Production and secretion of a bioactive hGH into the haemolymph of transgenic larvae was demonstrated by immunoblot analysis, ELISA and a proliferation bioassay. Stable expression of hGH was observed over 50 generations. The results indicate that mass reared transgenic diptera with a rapid period of larval growth could provide cost effective production systems for the manufacture of therapeutic and other high value proteins.     

Conjugation with polyamines enhances the antibacterial and anticancer activity of chloramphenicol

Chloramphenicol (CAM) is a broad-spectrum antibiotic, limited to occasional only use in developed countries because of its potential toxicity. To explore the influence of polyamines on the uptake and activity of CAM into cells, a series of polyamine–CAM conjugates were synthesized. Both polyamine architecture and the position of CAM-scaffold substitution were crucial in augmenting the antibacterial and anticancer potency of the synthesized conjugates. Compounds 4 and 5, prepared by replacement of dichloro-acetyl group of CAM with succinic acid attached to N4 and N1 positions of N⁸,N⁸-dibenzylspermidine, respectively, exhibited higher activity than CAM in inhibiting the puromycin reaction in a bacterial cell-free system. Kinetic and footprinting analysis revealed that whereas the CAM-scaffold preserved its role in competing with the binding of aminoacyl-tRNA 3′-terminus to ribosomal A-site, the polyamine-tail could interfere with the rotatory motion of aminoacyl-tRNA 3′-terminus toward the P-site. Compared to CAM, compounds 4 and 5 exhibited comparable or improved antibacterial activity, particularly against CAM-resistant strains. Compound 4 also possessed enhanced toxicity against human cancer cells, and lower toxicity against healthy human cells. Thus, the designed conjugates proved to be suitable tools in investigating the ribosomal catalytic center plasticity and some of them exhibited greater efficacy than CAM itself.     

Noncanonical Role of the 9-1-1 Clamp in the Error-Free DNA Damage Tolerance Pathway

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Highlights? 9-1-1 and Exo1 are components of the error-free RAD6 pathway ? 9-1-1 promotes postreplicative template switching ? Polyubiquitylated PCNA and 9-1-1 cooperate in the error-free RAD6 pathway ? 9-1-1’s role in the error-free RAD6 pathway is uncoupled from checkpoint functions     

Enhancement of cytochrome c catalytic behaviour by affecting the heme environment using functionalized carbon-based nanomaterials

The effect of carbon-based nanomaterials (CBNs), such as multi-wall carbon nanotubes (CNTs) and graphene oxide (GO) nanomaterials functionalized with carboxyl, alkyl and amine groups, on the peroxidase-like activity and structure of cytochrome c (cyt c) was investigated. The catalytic efficiency of cyt c increases up to 78-fold in the presence of graphene oxide and up to 2.5-fold in the presence of other functionalized CBNs. Moreover, the use of functionalized CBNs enhances the thermal stability of the protein as well as its tolerance against hydrogen peroxide up to 2.5-fold. UV–vis and circular dichroism spectroscopy studies suggest that the increase in the peroxidase activity of cyt c in the presence of some functionalized GO nanomaterials, correlates to perturbations of the heme microenvironment, while the secondary structure of the enzyme remains intact. These results indicate that the beneficial effect the functionalized CBNs have on the activity and on the stability of cyt c depends on CBNs geometry and surface functionalization.     

Microalgal process-monitoring based on high-selectivity spectroscopy tools: status and future perspectives

Microalgae are well known for their ability to accumulate lipids intracellularly, which can be used for biofuels and mitigate CO₂ emissions. However, due to economic challenges, microalgae bioprocesses have maneuvered towards the simultaneous production of food, feed, fuel, and various high-value chemicals in a biorefinery concept. On-line and in-line monitoring of macromolecules such as lipids, proteins, carbohydrates, and high-value pigments will be more critical to maintain product quality and consistency for downstream processing in a biorefinery to maintain and valorize these markets. The main contribution of this review is to present current and prospective advances of on-line and in-line process analytical technology (PAT), with high-selectivity – the capability of monitoring several analytes simultaneously – in the interest of improving product quality, productivity, and process automation of a microalgal biorefinery. The high-selectivity PAT under consideration are mid-infrared (MIR), near-infrared (NIR), and Raman vibrational spectroscopies. The current review contains a critical assessment of these technologies in the context of recent advances in software and hardware in order to move microalgae production towards process automation through multivariate process control (MVPC) and software sensors trained on “big data”. The paper will also include a comprehensive overview of off-line implementations of vibrational spectroscopy in microalgal research as it pertains to spectral interpretation and process automation to aid and motivate development.     

NK cells in allogeneic bone marrow transplantation

NK cells, until recently an ignored subset of lymphocytes, have begun to emerge as important cytotoxic effectors. It is now accepted that NK cells together with T cells constitute major actors in graft-versus-leukemia reaction after allogeneic bone marrow transplantation (BMT). Over the last several years the mechanisms regulating the activation of NK cells have been the subject of intense investigations encouraged by the clinical implications that these studies will have. This article provides a general overview of NK-cells biology and regulation pertinent to their function in allogeneic BMT, followed by a review of the in vivo preclinical and clinical evidence for the beneficial effect of NK cells in the adoptive immunotherapy of leukemia.     

Neuropeptide-inducible upregulation of proteasome activity precedes nuclear factor kappa B activation in androgen-independent prostate cancer cells

Background

Upregulation of nuclear factor kappa B (NF??B) activity and neuroendocrine differentiation are two mechanisms known to be involved in prostate cancer (PC) progression to castration resistance. We have observed that major components of these pathways, including NF??B, proteasome, neutral endopeptidase (NEP) and endothelin 1 (ET-1), exhibit an inverse and mirror image pattern in androgen-dependent (AD) and -independent (AI) states in vitro.

Methods

We have now investigated for evidence of a direct mechanistic connection between these pathways with the use of immunocytochemistry (ICC), western blot analysis, electrophoretic mobility shift assay (EMSA) and proteasome activity assessment.

Results

Neuropeptide (NP) stimulation induced nuclear translocation of NF??B in a dose-dependent manner in AI cells, also evident as reduced total inhibitor ??B (I??B) levels and increased DNA binding in EMSA. These effects were preceded by increased 20?S proteasome activity at lower doses and at earlier times and were at least partially reversed under conditions of NP deprivation induced by specific NP receptor inhibitors, as well as NF??B, I??B kinase (IKK) and proteasome inhibitors. AD cells showed no appreciable nuclear translocation upon NP stimulation, with less intense DNA binding signal on EMSA.

Conclusions

Our results support evidence for a direct mechanistic connection between the NPs and NF??B/proteasome signaling pathways, with a distinct NP-induced profile in the more aggressive AI cancer state.