Project description:Intra Peritoneal Chemo Hyperthermia (IPCH) is a recently validated option for the treatment of peritoneal carcinomatosis from colorectal or ovarian origin. This therapeutic program demonstrated a significant improvement of the late stages (i.e. carcinomatosis) of the disease. From a clinical point of view, within the first 24 hours after IPCH, patients undergo a systemic inflammatory response syndrome, and therefore require to be monitored in an intensive care unit. From a metabolic perspective, preliminary data have been shown a significant "anaerobic style" disturbance of energetic metabolism, suggesting a deep cellular energetic deficit throughout IPCH process. Putative contradictory effects of IPCH, like the increase of chemotherapy-related cellular toxicity due to heat and on the other hand the initiation of a stress protein response (heat shock response) which helps to reduce the cell injuries, leads to conduct a research project on the underlying mechanisms: consequences, in terms of patient’s care and follow-up, are of high relevance. The primary goal is a multimodal assessment of the IPCH-related cell modifications: signaling pathways, apoptosis and antitumoral immune response. The assessment criteria include Heat shock protein expression (blood/cell ratio) compared to baseline values, apoptosis and immune response before/after IPCH. The scheduled sample size is 30 patients having an IPCH and 30 patients contraindicated per surgery.

Project description:This project is meant to document the effect of the negative energetic balance on the embryo quality and as it happens, to identify ways to improve the fertility of dairy bovines. Measurement of the β-Hydroxybutyric acid (BHB) has been taken between 45 and 60 days post-partum on twelve Holstein cows. Cows have been ranked according to the sanguine measurement as high or low in BHB in order to get 6 cows per group. After having synchronized the heat with hormones and an ovarian stimulation, cows have been inseminated and the embryos were selected as so to be transferred in at least two heifers. With this transfer it is possible to isolate the impact of the energetic level of the mother before and during the gestation on the performances of the future progeny.

Project description:This project is meant to document the effect of the negative energetic balance on the embryo quality and as it happens, to identify ways to improve the fertility of dairy bovines. Measurement of the β-Hydroxybutyric acid (BHB) has been taken between 45 and 60 days post-partum on twelve Holstein cows. Cows have been ranked according to the sanguine measurement as high or low in BHB in order to get 6 cows per group. After having synchronized the heat with hormones and an ovarian stimulation, cows have been inseminated and the embryos were selected as so to be transferred in at least two heifers. This project aim at isolating the differences created on the transcriptomic expression in morulas and blastocysts grown in cows with an energetic inbalance.

Project description:Saccharomyces cerevisiae strain BY4741 (MATa his3Δ1 leu2Δ0 met15Δ0 ura3Δ0) was grown in YPD medium. For control conditions, cells were grown in mid-log phase at 30°C for 20 min or 2 hours. Stress conditions were heat shock (37°C for 20 min), diauxic shift (harvested at 2 hours after glucose depletion), DNA damage (harvested after 2 hours of treatment with 5 µg/ml 4-nitroquinoline 1-oxide (Sigma)). Moreover, four conditions of the yeast metabolic cycle were analyzed. S. cerevisiae strain CEN.PK (MATa URA3 TRP1 LEU2 HIS3 MAL2-8C SUC2) was used and cultivated as described elsewhere (Nocetti and Whitehouse, Genes Dev, 2016). The period of metabolic oscillation was approximately 3.2 h. Cells were harvested at 16, 32, 48, and 60 min from the start of each cycle for one oxidative, two reductive/building, and one reductive/charging phase points. Total RNA from each sample was extracted by the hot phenol method and used for library preparation. 3′-seq libraries were prepared as described previously (Lianoglou et al., Genes Dev, 2013). Each condition was sequenced in three biological replicates. The 27 individual libraries were pooled and subjected to sequencing with HiSeq with SR50 at the Integrated Genomics Operation (MSKCC).

Project description:Perturbation of the gated-synchrony system in yeast with phenelzine, an antidepressant drug used in the treatment of affective disorders in humans, leads to a rapid lengthening in the period of the genome-wide transcriptional oscillation. The effect is a concerted, genome-scale change in expression that is first seen in genes maximally expressed in the late-reductive phase of the cycle, doubling the length of the reductive phase within two cycles after treatment. Clustering of genes based on their temporal patterns of expression yielded just three super clusters whose trajectories through time could then be mapped into a simple 3D figure. In contrast to transcripts in the late-reductive phase, most transcripts do not show transients in expression relative to others in their temporal cluster but change their period in a concerted fashion. Mapping the trajectories of the transcripts into low-dimensional surfaces that can be represented by simple systems of differential equations provides a readily testable model of the dynamic architecture of phenotype. In this system, period doubling may be a preferred pathway for phenotypic change. As a practical matter, low-amplitude, genome-wide oscillations, a ubiquitous but often unrecognized attribute of phenotype, could be a source of seemingly intractable biological noise in microarray studies. Experiment Overall Design: Phenelzine was added to the system after the first cycle to induce period doubling

Project description:The major objective of our study was to find out what are the extra costs and what optimization and adjustment steps of a high-flow LC-MS system have to be undertaken to identify a comparable number of proteins as on a nanoLC-MS system.

Project description:Many of the pro-tumorigenic functions of the oncogene MYCN are attributed to its regulation of global gene expression programs. Alternative splicing is another important regulator of gene expression and has been implicated in neuroblastoma development, however, the molecular mechanisms behind this remain unknown. We found that MYCN up-regulated the core spliceosomal protein, SNRPD3, in models of neuroblastoma initiation and progression. MYCN directly bound SNRPD3, and the protein arginine methyltransferase, PRMT5. RNA-sequencing revealed a global increase in the number of genes being differentially spliced when MYCN was overexpressed, while depletion of SNPRD3 in the presence of overexpressed MYCN was sufficient to induce additional increases in differential splicing, particularly genes involved in the cell cycle. SNRPD3 knockdown in the presence of MYCN was accompanied with marked loss of cell viability, suggesting that SNRPD3 maintains splicing balance for MYCN, and prevents detrimental differential splicing of cell cycle genes in neuroblastoma. Further analysis revealed BIRC5 and CDK10 to be among the topmost differentially spliced cell cycle genes, both of which play a role in the G2/M phase of the cell cycle. Flow cytometry analysis revealed that depletion of SNRPD3 resulted in G2/M cell cycle arrest. Furthermore, SNRPD3 was an oncogenic co-factor for MYCN in vitro and in vivo. As such, SNRPD3 represents a therapeutic vulnerability for neuroblastoma cells in the presence of high MYCN expression. Indeed, the PRMT5 inhibitor, JNJ-64619178, that prevents SNRPD3 methylation was cytotoxic in neuroblastoma cell lines with high SNRPD3 and MYCN expression. Overall, our findings demonstrate a selective relationship exhibited between MYCN and SNRPD3 and suggest that SNRPD3 plays a vital role in MYCN-driven tumorigenesis and could serve as a novel therapeutic target.

Project description:A green sulfur bacterium used to model the reductive carbolic acid cycle.

Project description:Replacing the Calvin cycle with the reductive glycine pathway in Cupriavidus necator

Project description:Different intensities of high temperatures affect the growth of photosynthetic cells in nature. To elucidate the underlying mechanisms, we cultivated the unicellular green alga Chlamydomonas reinhardtii under highly controlled photobioreactor conditions and revealed systems-wide shared and unique responses to 24-hour moderate (35oC) and acute (40oC) high temperatures and subsequent recovery at 25oC. We identified transcripts/proteins with unique differential regulation at 35oC, uncovering previously overlooked novel elements in response to moderate high temperature. Heat at 35oC increased transcripts/proteins involved in gluconeogensis/glyoxylate-cycle for carbon uptake, promoted growth, and increased starch accumulation. Heat at 40oC inhibited growth, resulting in carbon uptake over usage and increased starch accumulation. Heat at 35oC transiently arrested the cell cycle followed by partial synchronization while 40oC inhibited DNA replication and arrested the cell cycle. Both high temperatures induced photoprotection, while 40oC decreased photosynthetic efficiencies, distorted thylakoid/pyrenoid ultrastructure, and affected the carbon concentrating mechanism. We demonstrated increased transcript/protein correlation during heat, which decreased during recovery, suggesting reduced post-transcriptional regulation during heat may help coordinate heat tolerance activities efficiently. During recovery after both treatments, transcripts/proteins related to DNA synthesis increased while those involved in photosynthetic light reactions decreased. We propose down-regulating photosynthetic light reactions during DNA replication benefits cell cycle resumption by reducing ROS production. Our results provide potential targets to increase thermotolerance in algae and crops.