Project description:For malaria transmission, the parasite must undergo sexual differentiation into mature gametocytes. However, the molecular basis for this critical transition in the parasites life cycle is unknown. Six previously uncharacterized genes, Pfg14.744, Pfg14.745, Pfg14.748, Pfg14.763, Pfg14.752 and Pfg6.6 that are members of a 36 gene Plasmodium falciparum-specific subtelomeric superfamily were found to be expressed in parasites that are committed to sexual development as suggested by co-expression of Pfs16 and Pfg27. Northern blots demonstrated that Pfg14.744 and Pfg14.748 were first expressed before the parasites differentiated into morphologically distinct gametocytes, transcription continued to increase until stage II gametocytes were formed and then rapidly decreased. Immunofluorescence assays indicated that both proteins were only produced in the subpopulation of ring stage parasites that are committed to gametocytogenesis and both localized to the parasitophorous vacuole (PV)b of the early ring stage parasites. As the parasites continued to develop Pfg14.748 remained within the parasitophorous vacuole, while Pfg14.744 was detected in the erythrocyte. The 5' flanking region of either gene alone was sufficient to drive early gametocyte specific expression of green fluorescent protein (GFP). In parasites transfected with a plasmid containing the Pfg14.748 5' flanking region immediately upstream of GFP, fluorescence was observed in a small number of schizonts the cycle before stage I gametocytes were observed. This expression pattern is consistent with commitment to sexual differentiation prior to merozoite release and erythrocyte invasion. Further investigation into the role of these genes in the transition from asexual to sexual differentiation could provide new strategies to block malaria transmission. Microarray analysis was used to compare two clones derived from Plasmodium falciparum strain 3D7 parasites that differ in their ability to undergo gametocytogenesis. Clone G+ produces gametocytes and clone G- produces very few if any gametocytes. RNA was harvested from the cultures when the asexual parasitemia was 0.9-1.48% (day 4) (n=4) after setting up the gametocyte cultures and 5.2-5.58% (day 6) (n=4) prior to the appearance of morphologically distinct gametocytes and used to generate cDNA that was labeled with Cy3 or Cy5 and hybridized to the Plasmodium falciparum 70 mer oligonucleotide microarray developed by DeRisi and co-workers.

Project description:Acquired antimalarial drug resistance produces treatment failures and has led to periods of global disease resurgence. In P. falciparum, resistance is known to arise through genome-level changes such as mutations and gene duplications. We now report an epigenetic resistance mechanism involving genes responsible for the plasmodial surface anion channel, a nutrient channel that also transports ions and antimalarial compounds at the host erythrocyte membrane. Two blasticidin S-resistant lines exhibited markedly reduced expression of clag Mutant FCB-br1 and wild-type FCB samples were hybridized to seven arrays (biological repeats) using forward (n=2) and reverse (n=5) fluoro.

Project description:The effects of endogenous elevation of homocysteine on retinal gene expression were screened by microarray analysis, which was performed in triplicate (i.e., three different paired RNA samples) with RNA isolated from neural retinas of cbs+/- HM at 5-weeks after a methionine diet and age-matched wildtype mice. The microarray chips used in this study permitted the screening of 36,212 genes. Of particular interest were those genes in cbs+/- HM mice whose expression levels changed by at least a factor of 2 (increased or decreased expression) compared with the wild-type in each of the replicate experiments. Using these selection criteria, we identified 1219 genes. They were categorized into six functional groups: (1) proapoptosis, (2) antiapoptosis, (3) cell cycle, (4) antioxidant, (5) calcium signaling, and (6) axon growth/guidance, with the remaining genes with marked changes in expression placed in a miscellaneous group. After categorization, relevant genes were further narrowed by SAM analysis; q < 0.06 was considered significant. Microarrays were performed in triplicate as biological repeats and reverse fluoro (i.e., three different paired RNA samples) with RNA isolated from neural retinas of cbs+/- HM at 5-weeks after a methionine diet and age-matched wildtype mice after a methionine diet.

Project description:The plasmacytoid dendritic cell (pDC) is vital to the coordinated action of innate and adaptive immunity. pDC development has not been unequivocally traced, nor has its transcriptional regulatory network been fully clarified. Here we confirm an essential requirement for the BCL11A transcription factor in fetal pDC development, and demonstrate this lineage-specific requirement in the adult organism. Furthermore, we identify BCL11A gene targets and provide a molecular mechanism for its action in pDC commitment. Embryonic germ-line deletion of Bcl11a revealed an absolute cellular, molecular, and functional absence of pDCs in fetal mice. In adults, deletion of Bcl11a in hematopoietic stem cells resulted in perturbed yet continued generation of progenitors, loss of downstream pDC and B-cell lineages, and persisting myeloid, conventional dendritic, and T-cell lineages. Challenge with virus resulted in a marked reduction of antiviral response in conditionally deleted adults. Genome-wide analyses of BCL11A DNA binding and expression revealed that BCL11A regulates transcription of E2-2 and other pDC differentiation modulators, including ID2 and MTG16. Our results identify BCL11A as an essential, lineage- specific factor that regulates pDC development, supporting a model wherein differentiation into pDCs represents a primed &quot;default&quot; pathway for common dendritic cell progenitors. Raji cells were infected with retroviruses containing pXY-PURO (negative control vector) or pXY-BCL11A-XS. BJAB cells were infected with retroviruses containing pXY-PURO (negative control vector) or pXY-BCL11A-XL. Two arrays measured Raji BCL11A-XS expression and two arrays measured BJAB BCL11A-XL expression.

Project description:Erythrocyte invasion is an essential step in the life cycle of the malaria parasite Plasmodium falciparum that involves specific interactions between host cell receptors and parasite ligands. How the parasite regulates the expression of invasion-related genes is to date largely unknown. Here we show that a novel, parasite-specific bromodomain protein (PfBDP1) binds to chromatin at the transcriptional start site of invasion-related genes and directly controls their expression. Conditional PfBDP1 knockdown causes a dramatic defect in parasite invasion and growth and results in transcriptional down-regulation of multiple invasion-related genes at a time point critical for invasion. This is the first report of a histone binding protein that activates genes in P. falciparum and our data place PfBDP1 in a central position for controlling the coordinated expression of invasion genes. Bromodomains are emerging therapeutic targets and drugs that specifically inhibit PfBDP1 could be an invaluable tool in the effort to eradicate malaria. P. falciparum 3D7 parasites over-expressing PfBDP1-3xHA (3D7/PfBDP1 OE) [PMID: 23181666] were grown in presence of 5μg/ml BSD-S-HCl. The parasite line 3D7/cam [PMID: 22435676.] grown under the same conditions and expressing hDHFR instead of PfBDP1-3xHA from the same promoter was used as control. RNA extracted from these samples at four consecutive time points each was processed for microarray analysis.

Project description:We investigate the role of a long ncRNA transcribed from an ultraconserved region (T-UCR) in the control of post-transcriptional pri-miRNA processing. The regulation is based on complementarity between the lower stem region in pri-miR-195 transcript and the ultraconserved sequence in Uc.283+A, which prevents pri-miRNA cleavage by Drosha. Mutation of the site in either RNA molecule uncouples regulation in vivo and in vitro. We propose a model in which lower-stem strand invasion by Uc.283+A impairs microprocessor recognition and efficient pri-miRNA cropping. In this work, we characterize a new role for Uc.283+A as a direct interactor and regulator of pri-miRNA-195 maturation at the level of Drosha processing. We combine cellular assays with in vitro biochemical analyses to reveal the first case of RNA-directed downregulation of miRNA biogenesis by a T-UCR In the study presented here, a colorrectal cancer cell line (HCT-116) was transiently transfected with Uc.283+A in order to identify putative miRNA targets for Uc.283+A. Variant 1 represents a SNP variant (8x(T) repeat in the sequence). Variant 2 represents a SNP variant (9x(T) repeat in the sequence).

Project description:This SuperSeries is composed of the SubSeries listed below. Refer to individual Series

Project description:DEAD-box proteins, a family of RNA-dependent ATPases, promote the numerous conformational rearrangements required for spliceosome assembly, activation, and disassembly. Previous work showed that a cold-sensitive substitution in DEAD-box protein Prp28 prevents the switch from U1 to U6 snRNA pairing with the 5’ splice site. Little is known about how Prp28 is regulated, although U5 snRNP protein Prp8 is a potential coordinator of Prp28 and other spliceosomal ATPases. We conducted a targeted selection in Prp8 for cold-insensitive suppressors of prp28-1, then used splicing specific microarrays to assess suppression of the prp28-1 splicing defect. Splicing specific microarrays were used to assess suppression of the prp28-1 splicing defect by a prp8 allele (prp8-tes) that suppresses prp28-1 cold-sensitivity

Project description:From a clinical and molecular perspective, colon cancer (CC) is a heterogeneous disease but to date no classification based on high-density transcriptome data has been established. The aim of this study was to build up a robust molecular classification of mRNA expression profiles (Affymetrix U133Plus2) of a large series of 443 CC and to validate it on an independent serie of 123 CC and 906 public dataset. We identified and validated six molecular subtypes in this large cohort as a combination of multiple molecular processes that complement current disease stratification based on clinicopathological variables and molecular markers. The biological relevance of these subtypes was consolidated by significant differences in survival. These insights open new perspectives for improving prognostic models and targeted therapies. Among a large series of colon cancers collected for the Cartes d'Identité des Tumeurs (CIT) program from the French Ligue Nationale Contre le Cancer (http://cit.ligue-cancer.net), 566 were analyzed for mRNA expression profiles using Affymetrix U133plus2 chip and, among theses, 463 could also be analyzed for DNA alteration profiles using the CGH Array ( CIT-CGHarray V6). The 566 tumors was divided into a discovery dataset of 443 CC and a validation dataset of 123 CC.

Project description:We described the biological role of a putative zinc finger protein (Plasmodb id: PF3D7_1008600), which plays an important role during the initiation and subsequent progression of gametocytogenesis in P. falciparum. Hence we termed the protein P. falciparum Zinc Finger Protein for Gametocytogenesis (PfZnFP-G). During the asexual intraerythrocyic developmental cycle (IDC), PfZnFP-G levels peak during the schizont stage during which it is localized in the nucleus. During the IDC, PfZnFP-G appears to be stochastically expressed in ~3% parasite population. Deactivation of PfZnFP-G appears to suppress, but not fully inhibit, production of gametocytes and vice versa overproduction of PfZnFP-G stimulates gametocytogenesis. In addition, PfZnFP-G is capable of associating with DNA binding preferentially to intergenic, promoter regions of the genome, and this binding correlates positively with transcription, particularly of other gametocyte specific genes. PfZnFP-G is also expressed in the mid-to-late gametocytes where it is present in the cytoplasm. Overall, these results suggest a dual function of PfZnFP-G in gametocytogenesis including: (i) commitment as a transcription factor and (ii) gametocyte maturation as a putative RNA binding protein. Transgenic 3D7 wild type parasite lines were generated with PfZnFP-G tagged, over-expressed and knocked-out. Transcriptional profiles across the parasite life cycle were generated. Genome occupancy of PfZnFP-G were also investigated and compared to the corresponding transcriptional profiles.