Project description:Environmental reproductive health focuses on the effect of exposure to contaminants considered as endocrine disruptors. Developmental testis is considered as target of these compounds affecting testicular functions in adults and suspected implications in tumor etiology. Comparative analysis of gene expression in mouse testis exposed to five disruptors, three different dosages and three accumulative developmental stages shown defined signature profiles of gene deregulation for MEHP (monoethyl phthalate) and zearalenone (a phytoestrogen) and different to 17β-estradiol exposure. The effects are even detected in postpuberal male offspring from premating exposed mothers. Oxidative stress response, protein ubiquitination and oxidative phosphorylation are the most representative pathways affected. Animal Exposure CD-1 mice were in vivo exposed to several doses of EDs following a defined protocol: mothers were exposed two weeks before mating (exposure A); the same exposure and dose were maintained during pregnancy (exposure B) and four weeks after birth (exposure C). In all exposures, male offspring were sacrificed to obtain the testes. The compounds were administrated in drinking water to a final concentration of: E2(mg/l) BPA(mg/l) Zea(mg/l) MEHP(mg/l) Lindane(mg/l) Dose (1) 0.02 0.5 4 27.85 50 Dose (2) 0.04 50 12 139.17 100 Dose (3) 0.16 200 20 278.34 200 Ethanol was used as vehicle for E2, BPA and Zea and DMSO was for MEHP and Lindane. Control testes were obtained from animals exposed to solvents of EDs: Ethanol and DMSO. Animal care and sacrifice were made following regulations from the CSIC Bioethics Committee. RNA preparation Total RNA from testes of exposed animals and controls was extracted using TRIzol reagent (Invitrogen), according to the manufacturer’s standard protocol. RNA samples were spectrophotometrically quantified using NanoDrop (NanoDrop Technologies). To minimize the effect of inter-individual expression variability we made pools of RNA from at least 3 individual RNA samples from each experimental condition (same quantity of total RNA per sample). Pools of RNA were checked for quality performing Experion analysis (Bio-Rad Laboratories). Total RNA from testes of unexposed four weeks old animals was also extracted with the purpose of making pools to assess the variability at the expression level of the mouse strain used (Ctr). Microarray Processing Starting with total RNA from pools described above, full length cDNAs were synthesized from oligo(dT) primers bearing a T7 promoter. These cDNAs were used as template for in vitro transcription by T7-RNA-Polymerase to amplify the mRNAs; following the Amino Allyl MessageAmp™ aRNA Kit (Ambion, Inc.) protocol. The amplified mRNAs (aRNA) were labeled either with Cy3 or Cy5 dyes, using Amersham CyDye Post-Labeling Reactive Dyes (Amersham Biosciences). The incorporated dye was spectrophotometrically quantified using NanoDrop (NanoDrop Technologies). The same dye signal quantities of labeled experimental and control aRNAs were mixed and hybridized to Mouse Oligoset v3 (OPERON) arrays from Genomics facility-University of Cincinnati (USA). The slides contained 31,769 spotted probes (70 mer oligonucleotides) corresponding to 24,878 expressed or predicted mouse genes. Hybridization and washes of microarrays were performed according to Genomics facility-University of Cincinnati instructions. Dye-Swap replicates were performed: one slide hybridized with experimental and control targets labeled with Cy3 and Cy5, respectively; and the second slide with the same type of targets but inversely labeled. Target refers to labeled aRNA while probe refers to the oligonucleotides spotted on the microarray platform. Imaging and data generation were carried out using a GenePix 4000B (Axon Instruments) and associated software from Axon Instruments, Inc. The microarray slides were scanned with dual lasers with wavelength frequencies to excite Cy3 and Cy5. Images were captured in TIFF files. Information extraction for a given spot was based on the median value for the signal pixels minus the median value for the background pixels to produce a gene set data file for all the DNA spots. The Cy3 and Cy5 fluorescence signal intensities were normalized.

Project description:mesangical cells exposed to glycated albumin with and without aminoguanidine compared in a loop design with dye swaps and one total replication (total of 12 slides) loop with dye-swaps..arrayed twice

Project description:To study the pathogenicity of Salmonella Typhimurium (ST) in heterophils, a whole Salmonella genome array was used to analyze RNA isolated from Salmonella in vitro encountered with heterophils (30 min, 1 h, 2 h, and 3 h) or medium control (NS). Dual-color, direct comparisons were carried out between heterophils-encountered ST and non-encountered controls (30 min vs. NS (30M/NS), 1 h vs. NS (1HR/NS), 2 h vs. NS (2HR/NS) and 3 h vs. NS (3HR/NS)). Each comparison includes four biological replicates. Out of 4588 genes on an array, there were 605, 758, 944 and 945 genes differentially expressed in the comparisons of 30M/NS, 1HR/NS, 2HR/NS and 3HR/NS, respectively (P < 0.001, fold-change > 2). Most of the Salmonella genes associated with invasion function were found differentially expressed at 2HR/NS and 3HR/NS comparisons. These candidate genes include TypeIII-secreted protein effector sopE2, Invasion proteins (e.g. invA, invE, invG, invH), and Invasion genes tranction activator hilA. The results of continuous transcriptional changes provide important information to elucidate the pathogenicity of ST in heterophils. Dual-color, common reference comparisons were carried out between heterophils-encountered ST and non-encountered controls (30 min vs. NS (30M/NS), 1 h vs. NS (1HR/NS), 2 h vs. NS (2HR/NS) and 3 h vs. NS (3HR/NS)). Four biological replicates, with dye swap labeling, were included in each of comparisons. Background subtracted signal intensity were collected from 16 arrays and normalized before data analysis.

Project description:Gene expression profiling of clostridium perfringens infection in broilers on medicated and non-medicated diets using chicken 44k agilent microarray. To elucidate molecular and ceelular mechanisms of bacitracin effect on CP infection in chickens by microarray technology. A total number of 600 Ross broilers were reared in 12 pens with each hosting 50 birds. Each 6 pens of birds were fed bacitracin-medicated (55 ppm) or non-medicated starter diets immediately after the chicks were placed. At day 18, birds were challenged with CP. Spleens were collected from 12 birds of each group at day 18 (before infection), 19, 20, and 22. Total RNA was labeled by Cy3 or Cy5 with dye swap. Gene signal intensity was globally normalized by LOWESS and expressed on natural log scale. A mixed model including treatment, time, array (random effect), dye, and all interactions among treatment, time was used to identify differentially expressed genes between treatments, at the 1% significance level.

Project description:Chicken Marek’s disease (MD) is a unique naturally occurring model for human herpesvirus-induced lymphomas that over-express the “Hodgkin’s disease antigen” (TNFRSF-8; CD30) on the lymphoma’s neoplastically-transformed cells. We used transcriptomics, proteomics, computational systems biology and reductionist molecular biology to identify the differences between the CD30(hi) lymphoma cells and the non-transformed CD30(lo) MD lymphoma cells. We propose specific mechanisms of neoplastic transformation, genetic resistance to lymphomagenesis and impact of lymphoma microenvironment on CD30(hi) cell development. We demonstrate that: a) in situ, CD30(lo) cells are pre-neoplastic and we identify the proteome involved in transformation as well as potential mechanisms that may be controlled by MDV oncogene Meq; b) MD herpesvirus, (via its Meq oncogene) can drive a feed forward loop that induces CD30 transcription and overexpression, increased CD30 signaling, which then activates NFκB and, in turn, increases Meq transcription; c) Meq transcriptional repression or activation from the CD30 promoter generally correlates with a polymorphism in the CD30 promoter between MD-resistant and -susceptible chicken genotypes and so a herpesvirus has evolved to utilize NFκB as a direct transcriptional activator for its oncogene.

Project description:To determine the host response to Salmonella Typhimurium (ST) in heterophils, a whole chicken genome array was used to analyze RNA isolated from heterophils stimulated in vitro with ST (30 min, 1 h, 2 h, and 3 h) or medium control (NS). Dual-color, direct comparisons were carried between ST-stimulated and non-stimulated controls (30 min vs. NS (30M/NS), 1 h vs. NS (1HR/NS), 2 h vs. NS (2HR/NS) and 3 h vs. NS (3HR/NS)). Each comparison includes four biological replicates. There were 2791, 3744, 12947 and 12482 genes differentially expressed in the comparisons of 30M/NS, 1HR/NS, 2HR/NS and 3HR/NS, respectively (P < 0.001) , while 50, 82, 153, and 146 genes were related to immune function, respectively. More than 80% of immune-related genes overlapped between the comparisons (30M/NS vs. 1HR/NS, 1HR/NS vs. 2HR/NS, and 2HR/NS vs. 3HR/NS). These candidate genes include cytokines (e.g. Interleukin (IL) 1β, -6, -10B and -12B), chemokines (e.g. IL-8, CCL4, K60 and K203) and cluster of differentiation (CD) markers (e.g. CD44, -47 and -83). A relatively large increase in the number of differentially expressed immune-related genes was observed between 1 h and 2 h post-stimulation. The results of continuous transcriptional change provide important information to elucidate both the cellular and molecular mechanisms of ST stimulation in chickens. Dual-color, common reference comparisons were carried between ST-stimulated (30M, 1HR, 2HR and 3HR) and non-stimulated controls (NS). Four biological replicates, with dye swap labeling, were included in the comparisons of each post-stimulation time point (30M/NS, 1HR/NS, 2HR/NS and 3HR/NS). Background subtracted signal intensity were collected from 16 arrays and normalized before data analysis.

Project description:Chicken 60-mer oligonucleotide microarray, including 39854 cDNA and ESTs, entire Marek’s disease virus and avian influenza virus genomes, and 150 chicken microRNAs, was developed. Cecal tonsil, ileum, liver and spleen from 6 chickens were selected for hybridization to validate the microarray performance. There are 2886, 2886, 2660, 358, 3208 3355, and 3710 genes significantly expressed between liver and spleen, spleen and cecal tonsil, cecal tonsil and ileum, liver and cecal tonsil, liver and ileum, spleen and ileum at the P<10-7. Number of tissue specific genes for cecal tonsil, ileum, liver and spleen was 95, 71, 535, and 108, respectively with p < 10-7. More than 95% of spots had high SNR (>10). Keywords: characteristics of newly developed microarray using different normal tissue Loop design was carried on for all of tissue samples from the six chickens. Samples of four tissues from a chicken were used in each loop. The order of the tissues in each loop was changed so that all pairs of tissues were combined on an array with an equal number of times. Dye swap was used so that each tissue was measured an equal number of times with each dye. Data from 12 measurements for each tissue were collected, in total, 48 measurements from 24 arrays.

Project description:The effect of dietary immunostimulation in the portals of entry, intestine and gills, of rainbow trout (Oncorhynchus mykiss), was investigated using a salmonid-specific microarray platform enriched with immune-related genes. IS-diet feeding significantly changed transcriptomic expression profiles: larger reduction rather than induction was observed, with significant changes in genes and functional GO categories related to remodeling processes and antigen presentation. The results revealed that one of the main effects of IS-diets in trout is the increase of genes involved in antigen recognition in epithelial cells of gills. Adult rainbow trout (Oncorhynchus mykiss) were randomly distributed in four fibreglass tanks (25 fish per tank). During the feeding trial, trouts were hand-fed once a day with either the control diet or the immunodiet, in duplicate tanks, following manufacturer’s indication of 1 g food/fish for 4 weeks. After the 4 weeks, 4 fish of each tank (8 for each diet) were sampled for microarray analysis. Tissues removed for RNA extraction were frozen in liquid nitrogen and stored at -80 ºC. Total RNA was extracted from the organs using 1 ml of Tri Reagent (Sigma) per 100 mg of tissue, following the manufacturer’s instructions and quantity and integrity was analyzed by Experion RNA StdSens Analysis Kit (Bio-Rad). The design of the microarray posses 1818 genes printed in six replicates each, including random clones from common and subtracted cDNA libraries which were compared with known vertebrate proteins using blastx. The platform was enriched in immune-related genes. RNA was pooled within treatments (n=8), and 15 µg of control and test were labeled with Cy3- and Cy5-dCTP (Amersham Pharmacia) using SuperScript III reverse transcriptase (Invitrogen) and oligo(dT) primer (Promega), and cDNA was purified with Microcon YM30 (Millipore). Dye swap method was used, therefore each sample was hybridized to two microarrays. For the first slide, test and control cDNA were labeled with Cy5 and Cy3 respectively, and for the second array dye assignments were reversed. Scanning was performed with Axon scanner 4000B and images were processed with GenePix Pro 6.0. After subtraction of mean background, and LOWESS normalization was performed. To assess differential expression of genes, the normalized log intensity ratios were analyzed with Student’s t-test (p<0.01) and genes were ranked by log(p-level). The Bayesian modification to the false discovery rate (FDR) was used to correct for multiple comparison tests, estimating the q-value for the set of differentially expressed genes. The functional categories of Gene Ontology were compared with regulated genes (p<0.01) by the sums of ranks (Student’s t-test, p<0.05) and the statistical significance of over represented functional categories was assessed using the Yates correction to Chi square test (corrected p<0.05).

Project description:Rainbow trout (Oncorhynchus mykiss) were fed during 4 weeks with either a control diet or an immunostimulant diet and then injected with LPS to investigate the effect of dietary immunostimulation in the portals of entry, intestine and gills, using a salmonid-specific microarray platform enriched with immune-related genes. IS-diet feeding significantly changed transcriptomic expression profiles in response to LPS: significant changes in genes and functional GO categories related to remodeling processes and antigen presentation were different for both diets. The results revealed that one of the main effects of IS-diets in trout is the increase of genes involved in antigen recognition and in adaptive immunity. Keywords: gills, intestine, immunostimulats, transcriptomic response, trout Adult rainbow trout (Oncorhynchus mykiss) were randomly distributed in four fibreglass tanks (25 fish per tank). During the feeding trial, trouts were hand-fed once a day with either the control diet or the immunodiet, in duplicate tanks, following manufacturerâ??s indication of 1 g food/fish for 4 weeks. After the 4 weeks, 5 fish were injected with LPS and 5 fish were injected with PBS. After 24h, samples were taken for microarray analysis. Tissues were removed for RNA extraction and frozen in liquid nitrogen, then stored at -80 ºC. Total RNA was extracted from the organs using 1 ml of Tri Reagent (Sigma) per 100 mg of tissue, following the manufacturerâ??s instructions and quantity and integrity was analyzed by Experion RNA StdSens Analysis Kit (Bio-Rad). The design of the microarray posses 1818 genes printed in six replicates each, including random clones from common and subtracted cDNA libraries which were compared with known vertebrate proteins using blastx. The platform was enriched in immune-related genes. RNA was pooled within treatments (n=5), and 15 µg of control and test were labeled with Cy3- and Cy5-dCTP (Amersham Pharmacia) using SuperScript III reverse transcriptase (Invitrogen) and oligo(dT) primer (Promega), and cDNA was purified with Microcon YM30 (Millipore). Dye swap method was used, therefore each sample was hybridized to two microarrays. For the first slide, test and control cDNA were labeled with Cy5 and Cy3 respectively, and for the second array dye assignments were reversed. Scanning was performed with Axon scanner 4000B and images were processed with GenePix Pro 6.0. After subtraction of mean background, and LOWESS normalization was performed. To assess differential expression of genes, the normalized log intensity ratios were analyzed with Studentâ??s t-test (p<0.01) and genes were ranked by log(p-level). The Bayesian modification to the false discovery rate (FDR) was used to correct for multiple comparison tests, estimating the q-value for the set of differentially expressed genes. The functional categories of Gene Ontology were compared with regulated genes (p<0.01) by the sums of ranks (Studentâ??s t-test, p<0.05) and the statistical significance of over represented functional categories was assessed using the Yates correction to Chi square test (corrected p<0.05).

Project description:We designed a large scale gene expression study in Ts1Cje mice between P0 and P10 in order to measure the effects of trisomy 21 on a large number of samples (56 in total) in a tissue that is affected in Down syndrome (the cerebellum) and to quantify the defect during development in order to correlate gene expression changes to the phenotype observed. Keywords: Down syndrome, Ts1Cje, cerebellum, development, hypoplasia We analyzed gene expression in the cerebellum of Ts1Cje and euploid mice at P0, P3, P7 and P10 using pangenomic two colors microarrays containing 25 344 probes representing approximately 15 574 mouse genes. 56 samples from individual cerebellum were hybridized on 28 microarrays. On each microarray we hybridized a Ts1Cje sample versus an euploid sample and always a male versus a female. In addition on the same microarray we always compared samples from mice of the same age or with a maximum difference of 4 days (P0 versus P3, P3 versus P7 or P7 versus P10).