A Modified Yeast One-hybrid Sytem to Investigate Protein-protein and Protein: DNA Interactions

Chen, Gang

18 March 2010

A modified yeast one-hybrid (MY1H) system has been developed for in vivo investigation of simultaneous protein-protein and protein:DNA interactions. The traditional yeast one-hybrid assay (Y1H) permits examination of one expressed protein targeting one DNA site, whereas our MY1H allows coexpression of two different proteins and examination of their activity at the DNA target. This single-plasmid based MY1H was validated by use of the DNA-binding protein p53 and its inhibitory partners, large T antigen (LTAg) and 53BP2. The MY1H system could be used to examine proteins that contribute inhibitory, repressive, coactivational or bridging functions to the protein under investigation, as well as potential extension toward library screening for identification of novel accessory proteins. After development and validation of the MY1H with the p53/LTAg/53BP2 system, we applied the MY1H system to investigate the DNA binding activities of heterodimeric proteins, the bHLH/PAS domains of AhR and Arnt that target the xenobiotic response element (XRE). The AhR/Arnt:XRE interaction, which served as our positive control for heterodimeric protein binding of the XRE DNA site, showed negative signals in initial MY1H experiments. These false negative observations were turned into true positives by increasing the number of DNA target sites upstream of the reporter genes and increasing the number of activator domains fused to the two monomers. This methodology may help trouble-shooting false negatives stemming from unproductive transcription in yeast genetic assays, which can be a common problem. In the study of XRE-binding proteins, two bHLHZ-like hybrid proteins, AhRJunD and ArntFos were designed and coexpressed in the MY1H and yeast two-hybrid (Y2H) systems; these proteins comprise the bHLH domains of AhR and Arnt fused to the leucine zipper (LZ) elements from bZIP proteins JunD and Fos, respectively. The in vivo assays revealed that in the absence of the XRE DNA site, heterodimers and homodimers formed, but in the presence of the nonpalindromic XRE, only heterodimers bound to the XRE and activated reporter transcription. The present results provide valuable information on DNA-mediated protein heterodimerization and specific DNA binding, as well as the relationship between protein structure and DNA-binding function.

protein engineering

yeast one-hybrid assay

protein:DNA interaction

protein-protein interaction

0487

A Modified Yeast One-hybrid Sytem to Investigate Protein-protein and Protein: DNA Interactions

Chen, Gang

18 March 2010

A modified yeast one-hybrid (MY1H) system has been developed for in vivo investigation of simultaneous protein-protein and protein:DNA interactions. The traditional yeast one-hybrid assay (Y1H) permits examination of one expressed protein targeting one DNA site, whereas our MY1H allows coexpression of two different proteins and examination of their activity at the DNA target. This single-plasmid based MY1H was validated by use of the DNA-binding protein p53 and its inhibitory partners, large T antigen (LTAg) and 53BP2. The MY1H system could be used to examine proteins that contribute inhibitory, repressive, coactivational or bridging functions to the protein under investigation, as well as potential extension toward library screening for identification of novel accessory proteins. After development and validation of the MY1H with the p53/LTAg/53BP2 system, we applied the MY1H system to investigate the DNA binding activities of heterodimeric proteins, the bHLH/PAS domains of AhR and Arnt that target the xenobiotic response element (XRE). The AhR/Arnt:XRE interaction, which served as our positive control for heterodimeric protein binding of the XRE DNA site, showed negative signals in initial MY1H experiments. These false negative observations were turned into true positives by increasing the number of DNA target sites upstream of the reporter genes and increasing the number of activator domains fused to the two monomers. This methodology may help trouble-shooting false negatives stemming from unproductive transcription in yeast genetic assays, which can be a common problem. In the study of XRE-binding proteins, two bHLHZ-like hybrid proteins, AhRJunD and ArntFos were designed and coexpressed in the MY1H and yeast two-hybrid (Y2H) systems; these proteins comprise the bHLH domains of AhR and Arnt fused to the leucine zipper (LZ) elements from bZIP proteins JunD and Fos, respectively. The in vivo assays revealed that in the absence of the XRE DNA site, heterodimers and homodimers formed, but in the presence of the nonpalindromic XRE, only heterodimers bound to the XRE and activated reporter transcription. The present results provide valuable information on DNA-mediated protein heterodimerization and specific DNA binding, as well as the relationship between protein structure and DNA-binding function.

protein engineering

yeast one-hybrid assay

protein:DNA interaction

protein-protein interaction

0487

Studies on Baltic Sea mysids

Ogonowski, Martin

January 2012

Mysid shrimps (Mysidacea, Crustacea) are efficient zooplanktivores in both marine and freshwater systems as well as lipid rich prey for many species of fish.  Although some efforts have been made to study the role of mysids in the Baltic Sea, very few studies have been carried out in recent time and there are still knowledge gaps regarding various aspects of mysid ecology. This thesis aims to explore some of these gaps by covering a mixture of topics. Using multifrequency hydroacoustics we explored the possibility to separate mysids from fish echoes and successfully established a promising and effective method for obtaining mysid abundance/biomass estimates (paper I). An investigation of the current mysid community in a coastal area of the northern Baltic proper (paper II) demonstrated that the formerly dominant, pelagic mysid Mysis mixta had decreased substantially (~50%) in favor for phytoplanktivorous, juvenile Neomysis integer and Mysis relicta sp. By examining different aspects of mysid behavior, we studied the vertical size distribution of mysids in the field and found that size increased with depth/declining light, irrespective of temperature; indicating that their vertical size distribution primarily is a response to predation (paper II). In paper III, a combination of ecological and genetic markers was used to investigate intraspecific differences in migratory tendency. Both marker types indicated that some part of the Mysis salemaai population is sedentary on the bottom and that this strategy is a phenotypically plastic but persistent trait, analogous to the partial migrations seen in many birds and fishes. In paper IV a temperature and weight specific respiration model was developed for the littoral Praunus flexuosus. Routine respiration was moreover elevated by post-prandial effects (specific dynamic action) for longer times than previously suggested. Consequently, ignoring such effects could significantly bias respiration measurements. / At the time of doctoral defence the following papers were unpublished and had a status as follows: Paper  2: Accepted; Paper 3: Submitted; Paper  4: Accepted

Mysids

hydroacoustics

Baltic Sea

abundance

stable isotopes

specific dynamic action (SDA)

diel vertical migration

partial migration

trophic interactions

physiology

benthic-pelagic coupling

protein:DNA

C:N ratio

genetic structure

In vitro and In vivo High-throughput Analysis of Protein:DNA Interactions

Shahravan, Seyed Hesam

06 December 2012

In this thesis, emphasis has been placed on development of new approaches for high-throughput analysis of protein:DNA interactions in vitro and in vivo. In vitro strategies for detection of protein:DNA interaction require isolation of active and soluble protein. However, current methodologies for purification of proteins often fail to provide high yield of pure and tag-free protein mainly because enzymatic cleavage reactions for tag removal do not exhibit stringent sequence specificity. Solving this problem is an important step towards high-throughput in vitro analysis of protein:DNA interactions. As a result, parts of this thesis are devoted to developing new approaches to enhance the specificity of a proteolysis reaction. The first approach was through manipulation of experimental conditions to maximize the yield of the desired protein products from enterokinase proteolysis reactions of two His-tagged proteins. Because it was suspected that accessibility of the EK site was impeded, that is, a structural problem due to multimerization of proteins, focus was based on use of denaturants as a way to open the structure, thereby essentially increasing the stoichiometry of the canonical recognition site over noncanonical, adventitious sites. Promoting accessibility of the canonical EK target site can increase proteolytic specificity and cleavage yield, and general strategies promoting a more open structure should be useful for preparation of proteins requiring endoprotease treatment. One such strategy for efficient EK proteolysis is proposed: by heterodimerizing with a separate leucine zipper, the bZIP basic region and amino-terminus can become more open and potentially more accessible to enterokinase. In vivo strategies have the advantage over their in vitro counterparts of providing a native-like environment for assessing protein:DNA interactions, yet the most frequently used techniques often suffer from high false-positive and false-negative rates. In this thesis, a new bioprobe system for high-throughput detection of protein:DNA interactions in vivo is presented. This system offers higher levels of accuracy and sensitivity as well as accessibility and ease of manipulation in comparison with existing technologies.

transcription factors

protein:DNA interactions

Yeast hybrid assays

Fluorescent proteins

Enterokinase

proteolysis specificity

DNA-binding proteins

bZIP

Affinity tag

Tag removal

Protein purification

Bioprobe

0486

0487

0491

In vitro and In vivo High-throughput Analysis of Protein:DNA Interactions

Shahravan, Seyed Hesam

06 December 2012

In this thesis, emphasis has been placed on development of new approaches for high-throughput analysis of protein:DNA interactions in vitro and in vivo. In vitro strategies for detection of protein:DNA interaction require isolation of active and soluble protein. However, current methodologies for purification of proteins often fail to provide high yield of pure and tag-free protein mainly because enzymatic cleavage reactions for tag removal do not exhibit stringent sequence specificity. Solving this problem is an important step towards high-throughput in vitro analysis of protein:DNA interactions. As a result, parts of this thesis are devoted to developing new approaches to enhance the specificity of a proteolysis reaction. The first approach was through manipulation of experimental conditions to maximize the yield of the desired protein products from enterokinase proteolysis reactions of two His-tagged proteins. Because it was suspected that accessibility of the EK site was impeded, that is, a structural problem due to multimerization of proteins, focus was based on use of denaturants as a way to open the structure, thereby essentially increasing the stoichiometry of the canonical recognition site over noncanonical, adventitious sites. Promoting accessibility of the canonical EK target site can increase proteolytic specificity and cleavage yield, and general strategies promoting a more open structure should be useful for preparation of proteins requiring endoprotease treatment. One such strategy for efficient EK proteolysis is proposed: by heterodimerizing with a separate leucine zipper, the bZIP basic region and amino-terminus can become more open and potentially more accessible to enterokinase. In vivo strategies have the advantage over their in vitro counterparts of providing a native-like environment for assessing protein:DNA interactions, yet the most frequently used techniques often suffer from high false-positive and false-negative rates. In this thesis, a new bioprobe system for high-throughput detection of protein:DNA interactions in vivo is presented. This system offers higher levels of accuracy and sensitivity as well as accessibility and ease of manipulation in comparison with existing technologies.

transcription factors

protein:DNA interactions

Yeast hybrid assays

Fluorescent proteins

Enterokinase

proteolysis specificity

DNA-binding proteins

bZIP

Affinity tag

Tag removal

Protein purification

Bioprobe

0486

0487

0491