Project description:In many metazons, such as humans and Drosophila, homeodomain proteins comprise the second largest family of sequence specific transcription factors. In Drosophila, homeodomains play an important role in development. Many homeodomain proteins display a high level of homology across metazons, presumably due to importance of their functional roles. We comprehensively characterized the DNA binding preferences of all 84 Drosophila homeodomain transcription factors which contain a single DNA binding domain. Previously, we employed a bacterial one hybrid (B1H) assay to select for 20 to 40 high affinity transcription factor binding sites [Noyes et al. (2008). Cell. 133(7):1277-1289]. In this system, E. coli are transfected with two plasmids. One plasmid encodes the DNA binding domain of a homeodomain fused to two zinc finger domains and the omega subunit of RNAP. The other plasmid is drawn from a library of prey plasmids which contain a 10bp randomized transcription factor binding site (TFBS) region in the promoter of the reporter gene His3. The E. coli strain used is a His3 homolog and omega subunit knock out strain. If a transcription factor has high affinity for a TFBS, more His3 will be produced, leading to the production of more histidine and an increase in the growth rate. If the transcription factor does not bind with sufficient affinity to the TFBS, little or no histidine will be produced resulting in little or no growth. The stringency of the B1H system can be tuned using the chemicals IPTG and 3-AT. IPTG induces production of the chimeric transcription factor, and 3-AT is a competitive inhibitor of the enzyme encoded by His3. One of the advantages of the B1H system is that the transcription factor does not have to be purified and that many experiments can be easily conducted in parallel. In this study, in stead of picking 20 to 40 colonies and sequencing their TFBSs, we used high-throughput Illumina sequencing to sequence the selected sites of all of the colonies growing on a plate. This provided quantitative data regarding the growth rate of cells possessing each selected TFBS variant, which is a function of the affinity of the transcription factor for the binding site. With this quantitative data, we can build more accurate models of transcription factor binding.

Project description:Low-affinity protein binders are emerging as valuable domains for therapeutic applications because of their higher specificity when presented in multivalent ligands that increase the overall strength and selectivity of receptor binding. De novo discovery of low-affinity binders would be enhanced by the large library sizes attainable with in vitro selection systems, but these platforms generally maximize recovery of high-affinity monovalent binders. Here, we present a facile technology that uses rolling circle amplification to create homomultivalent libraries. We show proof of principle of this approach in ribosome display with off-rate selections of a bivalent ligand against monovalent and bivalent targets, thereby demonstrating high enrichment (up to 166-fold) against a low-affinity target that is bivalent but not monovalent. This approach to homomultivalent library construction can be applied to any binder tolerant of N- and C-terminal fusions and provides a platform for performing in vitro display selections with controlled protein valency and orientation.

Project description:Suppose that under the conventional randomized clinical trial setting, a new therapy is compared with a standard treatment. In this article, we propose a systematic, 2-stage estimation procedure for the subject-level treatment differences for future patient's disease management and treatment selections. To construct this procedure, we first utilize a parametric or semiparametric method to estimate individual-level treatment differences, and use these estimates to create an index scoring system for grouping patients. We then consistently estimate the average treatment difference for each subgroup of subjects via a nonparametric function estimation method. Furthermore, pointwise and simultaneous interval estimates are constructed to make inferences about such subgroup-specific treatment differences. The new proposal is illustrated with the data from a clinical trial for evaluating the efficacy and toxicity of a 3-drug combination versus a standard 2-drug combination for treating HIV-1-infected patients.

Project description:In many metazons, such as humans and Drosophila, homeodomain proteins comprise the second largest family of sequence specific transcription factors. In Drosophila, homeodomains play an important role in development. Many homeodomain proteins display a high level of homology across metazons, presumably due to importance of their functional roles. We comprehensively characterized the DNA binding preferences of all 84 Drosophila homeodomain transcription factors which contain a single DNA binding domain. Previously, we employed a bacterial one hybrid (B1H) assay to select for 20 to 40 high affinity transcription factor binding sites [Noyes et al. (2008). Cell. 133(7):1277-1289]. In this system, E. coli are transfected with two plasmids. One plasmid encodes the DNA binding domain of a homeodomain fused to two zinc finger domains and the omega subunit of RNAP. The other plasmid is drawn from a library of prey plasmids which contain a 10bp randomized transcription factor binding site (TFBS) region in the promoter of the reporter gene His3. The E. coli strain used is a His3 homolog and omega subunit knock out strain. If a transcription factor has high affinity for a TFBS, more His3 will be produced, leading to the production of more histidine and an increase in the growth rate. If the transcription factor does not bind with sufficient affinity to the TFBS, little or no histidine will be produced resulting in little or no growth. The stringency of the B1H system can be tuned using the chemicals IPTG and 3-AT. IPTG induces production of the chimeric transcription factor, and 3-AT is a competitive inhibitor of the enzyme encoded by His3. One of the advantages of the B1H system is that the transcription factor does not have to be purified and that many experiments can be easily conducted in parallel. In this study, in stead of picking 20 to 40 colonies and sequencing their TFBSs, we used high-throughput Illumina sequencing to sequence the selected sites of all of the colonies growing on a plate. This provided quantitative data regarding the growth rate of cells possessing each selected TFBS variant, which is a function of the affinity of the transcription factor for the binding site. With this quantitative data, we can build more accurate models of transcription factor binding. All 84 of the Drosophila homeodomain proteins that contain a single DNA binding domain were analyzed using the B1H assay. The same selection stringency was used for all experiments (10uM IPTG and 5mM 3-AT). All experiments were run for 36 to 48 hours. 10 mutants were also assayed: 3 Caup, 3 Bcd and 4 En mutants. The bait plasmid omegaUV2zf was used in all but 3 cases. In this instances, a slightly different bait plasmid, omegaUV5zf, with a stronger promoter was used. Thirty different replicates were performed in order to insure that sufficient number of reads were obtained for each protein. In total, 126 experiments were performed.

Project description:The availability of the complete genome sequences has facilitated access to essential information to identify proteins. The determination of Arabidopsis genome sequence has had a great impact to annotate data. The genome sequencing of Sorghum bicolor has been only recently completed and hither to the global response to abiotic stresses in this important crop remains largely unexplored. We used 2-D gel electrophoresis based proteomic approach refined with MALDI-TOF to analyze drought-stress response proteins in sorghum. Major changes in protein complement of sorghum were observed in hydroponic cultures at 96 hours under drought stress. Six most highly expressed proteins were excised for functional identification. Here, we developed a method to obtain functional distances between GO terms and analyzed distance values to allocate shortest path (SP) in GO hierarchy. The shortest paths for expressed proteins were noted for most informative common ancestor (MICA) terms, viz. binding, catalytic activity and primary metabolic process. We observed the expressed proteins belonged to the functional group of signal transduction mechanisms, carbohydrate transport and metabolism. These identified functions of proteins suggest a different mechanism of drought-stress tolerant in sorghum. The novel approach applied in this study may have great importance in further identifying proteins involved in abiotic and biotic stress conditions in crops.

Project description:Synthetic antibody (Ab) technologies are efficient and cost-effective platforms for the generation of monoclonal Abs against human antigens. Yet, they typically depend on purified proteins, which exclude integral membrane proteins that require the lipid bilayers to support their native structure and function. Here, we present an Ab discovery strategy, termed CellectSeq, for targeting integral membrane proteins on native cells in complex environment. As proof of concept, we targeted three transmembrane proteins linked to cancer, tetraspanin CD151, carbonic anhydrase 9, and integrin-α11. First, we performed in situ cell-based selections to enrich phage-displayed synthetic Ab pools for antigen-specific binders. Then, we designed next-generation sequencing procedures to explore Ab diversities and abundances. Finally, we developed motif-based scoring and sequencing error-filtering algorithms for the comprehensive interrogation of next-generation sequencing pools to identify Abs with high diversities and specificities, even at extremely low abundances, which are very difficult to identify using manual sampling or sequence abundances.

Project description:In a typical randomized clinical study to compare a new treatment with a control, oftentimes each study subject may experience any of several distinct outcomes during the study period, which collectively define the "risk-benefit" profile. To assess the effect of treatment, it is desirable to utilize the entirety of such outcome information. The times to these events, however, may not be observed completely due to, for example, competing risks or administrative censoring. The standard analyses based on the time to the first event, or individual component analyses with respect to each event time, are not ideal. In this paper, we classify each patient's risk-benefit profile, by considering all event times during follow-up, into several clinically meaningful ordinal categories. We first show how to make inferences for the treatment difference in a two-sample setting where categorical data are incomplete due to censoring. We then present a systematic procedure to identify patients who would benefit from a specific treatment using baseline covariate information. To obtain a valid and efficient system for personalized medicine, we utilize a cross-validation method for model building and evaluation and then make inferences using the final selected prediction procedure with an independent data set. The proposal is illustrated with the data from a clinical trial to evaluate a beta-blocker for treating chronic heart failure patients.

Project description:Spatial selections are a ubiquitous concept in visualization. By localizing particular features, they can be analysed and compared in different views. However, the semantics of such selections often depend on specific parameter settings and it can be difficult to reconstruct them without additional information. In this paper, we present the concept of contextual snapshots as an effective means for managing spatial selections in visualized data. The selections are automatically associated with the context in which they have been created. Contextual snapshots can also be used as the basis for interactive integrated and linked views, which enable in-place investigation and comparison of multiple visual representations of data. Our approach is implemented as a flexible toolkit with well-defined interfaces for integration into existing systems. We demonstrate the power and generality of our techniques by applying them to several distinct scenarios such as the visualization of simulation data, the analysis of historical documents and the display of anatomical data.

Project description:In many high complexity systems (cells, organisms, institutions, societies, economies, etc.), it is unclear which components should be regulated to affect overall performance. To identify and prioritize molecular targets which impact cellular phenotypes, we have developed a selection procedure ("SPI"-single promoting/inhibiting target identification) which monitors the abundance of ectopic cDNAs. We have used this approach to identify growth regulators. For this purpose, complex pools of S. cerevisiae cDNA transformants were established and we quantitated the evolution of the spectrum of cDNAs which was initially present. These data emphasized the importance of translation initiation and ER-Golgi traffic for growth. SPI provides functional insight into the stability of cellular phenotypes under circumstances in which established genetic approaches cannot be implemented. It provides a functional "synthetic genetic signature" for each state of the cell (i.e. genotype and environment) by surveying complex genetic libraries, and does not require specialized arrays of cDNAs/shRNAs, deletion strains, direct assessment of clonal growth or even a conditional phenotype. Moreover, it establishes a hierarchy of importance of those targets which can contribute, either positively or negatively, to modify the prevailing phenotype. Extensions of these proof-of-principle experiments to other cell types should provide a novel and powerful approach to analyze multiple aspects of the basic biology of yeast and animal cells as well as clinically-relevant issues.

Project description:The aim was to identify differentially expressed genes in Drosophila neural tumors caused by the combined knock-down of prospero and Syncrip, compared to tumors caused by the knock-down of prospero.