Effects of Energy and Protein Levels and Antibiotics on Growing Turkeys

Much attention has been given recently to the use and value of high energy rations for poultry, particularly for broilers and to a limited extent for laying hens and young turkeys. Although the general fundamentals of the findings may appear applicable in formulation of diets for growing turkeys beyond the age of 8 weeks, little direct evidence has been available to justify such application. Actually, there is some evidence to indicate that the higher energy diets may not necessarily promote a more rapid rate of gain for the older birds. The current study considers the possible effects of protein and antibiotics on the problem

Genomic characteristics and prognostic significance of co-mutated ASXL1/SRSF2 acute myeloid leukemia.

The ASXL1 and SRSF2 mutations in AML are frequently found in patients with preexisting myeloid malignancies and are individually associated with poor outcomes. In this multi-institutional retrospective analysis, we assessed the genetic features and clinical outcomes of 43 patients with ASXL1mut SRSF2mut AML and compared outcomes to patients with either ASXL1 (n = 57) or SRSF2 (n = 70) mutations. Twenty-six (60%) had secondary-AML (s-AML). Variant allele fractions suggested that SRSF2 mutations preceded ASXL1 mutational events. Median overall survival (OS) was 7.0 months (95% CI:3.8,15.3) and was significantly longer in patients with de novo vs s-AML (15.3 vs 6.4 months, respectively; P = .04 on adjusted analysis). Compared to ASXL1mut SRSF2wt and ASXL1wt SRSF2mut , co-mutated patients had a 1.4 and 1.6 times increase in the probability of death, respectively (P = .049), with a trend towards inferior OS (median OS = 7.0 vs 11.5 vs 10.9 months, respectively; P = .10). Multivariable analysis suggests this difference in OS is attributable to the high proportion of s-AML patients in the co-mutated cohort (60% vs 32% and 23%, respectively). Although this study is limited by the retrospective data collection and the relatively small sample size, these data suggest that ASXL1mut SRSF2mut AML is a distinct subgroup of AML frequently associated with s-AML and differs from ASXL1mut SRSF2wt /ASXL1wt SRSF2mut with respect to etiology and leukemogenesis

Comparison of Acquisition Parameters and Breast Dose in Digital Mammography and Screen-Film Mammography in the American College of Radiology Imaging Network Digital Mammographic Imaging Screening Trial

The purpose of our study was to compare the technical performance of full-field digital mammography (FFDM) and screen-film mammography

A sensorimotor control framework for understanding emotional communication and regulation

JHGW and CFH are supported by the Northwood Trust. TEVR was supported by a National Health and Medical Research Council (NHMRC) Early Career Fellowship (1088785). RP and MW were supported by the the Australian Research Council (ARC) Centre of Excellence for Cognition and its Disorders (CE110001021)Peer reviewedPublisher PD

Role of HDAC5 depletion induced autophagy on cancer cell death

Introduction: Histone deacetylases (HDAC) is a family of eighteen enzymes which modulates the acetylation level of histones and non-histone proteins to regulate gene expression and chromatin structure. Broad spectrum inhibitors of these enzymes can inhibit tumor growth both in vitro and in vivo and are currently used in clinic as anti-cancer agents. For many years, we are investigating the specific role of individual HDAC members in cancer biology and we have recently demonstrated that depletion of HDAC5 using siRNA technology triggered cancer cells to both autophagy and apoptosis. The study of autophagy in cancer is a new research field that has recently generated tremendous attention due to the recognition that autophagy can have either pro-survival or pro-death functions depending on its level of activation. In addition, more and more studies indicate that a complex relationship exists between autophagy and apoptosis, and that the interplay between these two processes determines whether a cell will live or die. - Aims: The aim of this study is to further understand the role of autophagy induced by HDAC5 depletion. Current investigations include determining the molecular mechanisms of HDAC5 depletion-mediated autophagy and exploring regulatory relationships between autophagy and apoptosis on cancer cell death in absence of HDAC5. - Methods and results : The set up of the autophagy in absence of HDAC5 occurs trough a non-canonical pathway which depends on the JNK activation. This activation could be induced by an inappropriate ROS production. Indeed, a transcriptomic analysis performed in HDAC5 depleted Hela cells highlighted a deregulation of a set of genes implicated in ROS detoxification. This deregulation has been validated by FACS analysis. - Conclusion: Through this study we determined the molecular mechanism implicated in the autophagy induction after HDAC5 silencing. This phenomenon appears dependent of an accumulation of ROS into the cells that activates JNK and mediate cell death by autophagy and apoptosis. Now, in we hope to determine whether manipulation of autophagy may provide a useful way to increase the efficacy of treatments with HDAC inhibitors, and limit tumor progression

JNK/ROS Signaling Pathway Is Responsible for Induction of Autophagy in HDAC5 depleted Cancer Cells

Introduction: Histone deacetylases (HDAC) is a family of eighteen enzymes which modulates the acetylation level of histones and non-histone proteins to regulate gene expression and chromatin structure. Broad spectrum inhibitors of these enzymes such as SAHA can inhibit tumor growth both in vitro and in vivo and are currently used as anti-cancer agents in clinic. For many years, we are investigating the specific role of individual HDAC members in cancer biology and we have recently demonstrated that depletion of HDAC5 using siRNA technology triggered cancer cells to both autophagy and apoptosis (ref papier). The study of autophagy in cancer is a new research field that has recently generated tremendous attention due to the recognition that autophagy can have either pro-survival or pro-death functions depending on its level of activation. In addition, more and more studies indicate that a complex relationship exists between autophagy and apoptosis, and that the interplay between these two processes determines whether a cell will live or die. Aims: The goal of this study is to further understand the role of autophagy induced by HDAC5 depletion. Current investigations include determining the molecular mechanisms by which HDAC5 depletion induces autophagy and exploring regulatory relationship between autophagy and apoptosis on cancer cell death in absence of HDAC5. Results: The set up of the autophagy in absence of HDAC5 was demonstrated by the conversion of LC3 and development of autophagosomes by electronic microscopy. Transcriptomic study demonstrated a deregulation of a set of genes involved in ROS detoxification in HDAC5 depleted cancer cells leading to significant increase of ROS levels. Further investigations showed that pretreatment with NAC, a ROS scavenger, effectively blocked the accumulation of ROS and autopahgy triggered by HDAC5 silencing. Moreover, HDAC5 depletion induces activation of JNK, and knockdown of JNK by siRNA inhibited ROS production and autophagy, but antioxidant NAC failed to block JNK activation induced by HDAC5 depletion indicating that JNK activation may be a upstream signaling of ROS and should be a core component in HDAC5 silencing-induced autophagic signaling pathway. Finally, blocking of autophagy induced by HDAC5 silencing with NAC or chloroquine and bafilomycin enhanced pro-apoptotic effect. Conclusion: Autophagy functions as a prosurvival mechanism to mitigate HDAC5 depletion-induced apoptotic cell death, suggesting that targeting autophagy might improve the therapeutic effects of specific HDAC5 inhibition

JNK/ROS signaling pathway is responsible for induction of autophagy in HDAC5 depleted cancer cells

Introduction: Histone deacetylases (HDAC) is a family of eighteen enzymes which modulates the acetylation level of histones and non-histone proteins to regulate gene expression and chromatin structure. Broad spectrum inhibitors of these enzymes such as SAHA can inhibit tumor growth both in vitro and in vivo and are currently used as anti-cancer agents in clinic. For many years, we are investigating the specific role of individual HDAC members in cancer biology and we have recently demonstrated that depletion of HDAC5 using siRNA technology triggered cancer cells to both autophagy and apoptosis (ref papier). The study of autophagy in cancer is a new research field that has recently generated tremendous attention due to the recognition that autophagy can have either pro-survival or pro-death functions depending on its level of activation. In addition, more and more studies indicate that a complex relationship exists between autophagy and apoptosis, and that the interplay between these two processes determines whether a cell will live or die. Aims: The goal of this study is to further understand the role of autophagy induced by HDAC5 depletion. Current investigations include determining the molecular mechanisms by which HDAC5 depletion induces autophagy and exploring regulatory relationship between autophagy and apoptosis on cancer cell death in absence of HDAC5. Results: The set up of the autophagy in absence of HDAC5 was demonstrated by the conversion of LC3 and development of autophagosomes by electronic microscopy. Transcriptomic study demonstrated a deregulation of a set of genes involved in ROS detoxification in HDAC5 depleted cancer cells leading to significant increase of ROS levels. Further investigations showed that pretreatment with NAC, a ROS scavenger, effectively blocked the accumulation of ROS and autopahgy triggered by HDAC5 silencing. Moreover, HDAC5 depletion induces activation of JNK, and knockdown of JNK by siRNA inhibited ROS production and autophagy, but antioxidant NAC failed to block JNK activation induced by HDAC5 depletion indicating that JNK activation may be a upstream signaling of ROS and should be a core component in HDAC5 silencing-induced autophagic signaling pathway. Finally, blocking of autophagy induced by HDAC5 silencing with NAC or chloroquine and bafilomycin enhanced pro-apoptotic effect. Conclusion: Autophagy functions as a prosurvival mechanism to mitigate HDAC5 depletion-induced apoptotic cell death, suggesting that targeting autophagy might improve the therapeutic effects of specific HDAC5 inhibition

JNK/ROS signaling pathway is responsible for induction of autophagy in HDAC5 depleted cancer cells

Introduction: Histone deacetylases (HDAC) is a family of eighteen enzymes which modulates the acetylation level of histones and non-histone proteins to regulate gene expression and chromatin structure. Broad spectrum inhibitors of these enzymes such as SAHA can inhibit tumor growth both in vitro and in vivo and are currently used as anti-cancer agents in clinic. For many years, we are investigating the specific role of individual HDAC members in cancer biology and we have recently demonstrated that depletion of HDAC5 using siRNA technology triggered cancer cells to both autophagy and apoptosis (ref papier). The study of autophagy in cancer is a new research field that has recently generated tremendous attention due to the recognition that autophagy can have either pro-survival or pro-death functions depending on its level of activation. In addition, more and more studies indicate that a complex relationship exists between autophagy and apoptosis, and that the interplay between these two processes determines whether a cell will live or die. Aims: The goal of this study is to further understand the role of autophagy induced by HDAC5 depletion. Current investigations include determining the molecular mechanisms by which HDAC5 depletion induces autophagy and exploring regulatory relationship between autophagy and apoptosis on cancer cell death in absence of HDAC5. Results: The set up of the autophagy in absence of HDAC5 was demonstrated by the conversion of LC3 and development of autophagosomes by electronic microscopy. Transcriptomic study demonstrated a deregulation of a set of genes involved in ROS detoxification in HDAC5 depleted cancer cells leading to significant increase of ROS levels. Further investigations showed that pretreatment with NAC, a ROS scavenger, effectively blocked the accumulation of ROS and autopahgy triggered by HDAC5 silencing. Moreover, HDAC5 depletion induces activation of JNK, and knockdown of JNK by siRNA inhibited ROS production and autophagy, but antioxidant NAC failed to block JNK activation induced by HDAC5 depletion indicating that JNK activation may be a upstream signaling of ROS and should be a core component in HDAC5 silencing-induced autophagic signaling pathway. Finally, blocking of autophagy induced by HDAC5 silencing with NAC or chloroquine and bafilomycin enhanced pro-apoptotic effect. Conclusion: Autophagy functions as a prosurvival mechanism to mitigate HDAC5 depletion-induced apoptotic cell death, suggesting that targeting autophagy might improve the therapeutic effects of specific HDAC5 inhibition

Mitochondrial dysfunction in HDAC5-depleted cancer cells induces glucose-dependent metabolic adaptation

Introduction: Histone deacetylases (HDAC) is a family of eighteen enzymes, which modulates the acetylation level of histones and non-histone proteins to regulate gene expression and chromatin structure. Broad-spectrum inhibitors of these enzymes such as SAHA can inhibit tumor growth both in vitro and in vivo and are currently used as anti-cancer agents in clinic. For many years, we are investigating the specific role of individual HDAC members in cancer biology and we have recently demonstrated that depletion of HDAC5 using siRNA technology triggered cancer cells to both autophagy and apoptosis1. Aims: The goal of this study is to further investigate the molecular mechanisms by which HDAC5 depletion induces both autophagy and apoptosis in cancer cells. Results: Screening transcriptomic study demonstrated that HDAC5 depletion induces a deregulation of genes encoding subunits of complex I of the mitochondrial respiratory chain leading to a significant increase of ROS production. This ROS accumulation promotes autophagy including mitophagy. Indeed, pretreatment with NAC, a ROS scavenger, blocked autophagy triggered by HDAC5 silencing. This autophagy seems to be protective as its blocking with NAC, chloroquine or bafilomycin A1 enhances pro-apoptotic effect of HDAC5 depletion. In addition, mitochondrial dysfunction provokes metabolism adaptation associated with increase of the importance of glucose metabolism in HDAC5 depleted cancer cells. Indeed, low-glucose culture of HDAC5-depleted cells significantly increases apoptotic cell death suggesting that glucose deprivation might be combined to HDAC5 inhibition as a therapeutic strategy to kill cancer cells. Conclusion: Our study demonstrated for the first time that specific HDAC5 inhibition induces alteration of gene expression encoding mitochondrial proteins in cancer cells and provide insight into a valuable experimental strategy for manipulation of specific HDAC5 inhibition and glucose metabolism in therapy against cancer. 1.Peixoto, P. et al. HDAC5 is required for maintenance of pericentric heterochromatin, and controls cell-cycle progression and survival of human cancer cells. Cell death and differentiation, 2012; 1-14