Identification of Heat Shock Factor Binding Sites in the Drosophila Genome

Gonsalves, Sarah E.

12 December 2012

The heat shock response (HSR) is a highly conserved mechanism that enables organisms to survive environmental and pathophysiological stress. In Drosophila, the HSR is regulated by a single transcription factor, heat shock factor (HSF). During stress, HSF trimerizes and binds to over 200 loci on Drosophila polytene chromosomes with only nine mapping to major heat shock (HS) inducible gene loci. The function of HSF binding to the other sites in the genome is currently unknown. Some of these sites may contain yet unidentified “minor” HS genes. Interestingly, the binding of HSF also coincides with puff regression at some sites. Two such sites contain the major developmentally regulated genes Eip74 and Eip75: key regulators in the response to 20-hydroxyecdysone (20E), the main hormone responsible for the temporal co-ordination of post-embryonic development in Drosophila. Previous work in our and other labs indicates that the regression of non-HS puffs during the HSR is dependent on the presence of functional HSF. Using chromatin immunoprecipitation (ChIP) followed by hybridization to genome tiling arrays (Chip), I have identified 434 regions in the Drosophila Kc cell genome that are bound by HSF during HS, and have determined that 57% of these sites are located within the transcribed regions of genes. By examining the transcriptional response to HS in Kc cells and third instar larvae using expression microarrays, I found that only about 10% of all genes within 1250 bp of an HSF binding site are transcriptionally regulated by HS and many genes whose transcript levels change during HS do not appear to be near an HSF binding site. Furthermore, genes with an HSF binding site within their introns are significantly enriched (modified Fisher Exact p-value between 2.0x10-3 and 1.5x10-6) in gene ontology terms related to developmental processes and reproduction. Using expression microarray technology, I characterized the transcriptional response to 20E and its structural analog ponasterone A. I have identified multiple HSF binding sites within Eip74 and Eip75, and show that induction of the HSR correlates with repression of these genes and all other 20E-inducible genes. Taken together, this work provides a basis for further investigation into the role of HSF binding to sites not associated with HS genes and its possible function as a repressor of gene transcription during conditions of stress and as a regulator of developmental genes under stress and non-stress conditions.

HSF

Heat Shock Factor

Heat Shock Response

transcription

gene expression

genomics

ChIP-on-chip

ecdysone

Eip75B

Ponasterone A

20-hydroxyecdysone

ecdysone response

hsf4

transcription factor

models of transcription

genome tiling arrays

Heat Shock Protein

Heat Shock Gene

0307

Identification of Heat Shock Factor Binding Sites in the Drosophila Genome

Gonsalves, Sarah E.

12 December 2012

The heat shock response (HSR) is a highly conserved mechanism that enables organisms to survive environmental and pathophysiological stress. In Drosophila, the HSR is regulated by a single transcription factor, heat shock factor (HSF). During stress, HSF trimerizes and binds to over 200 loci on Drosophila polytene chromosomes with only nine mapping to major heat shock (HS) inducible gene loci. The function of HSF binding to the other sites in the genome is currently unknown. Some of these sites may contain yet unidentified “minor” HS genes. Interestingly, the binding of HSF also coincides with puff regression at some sites. Two such sites contain the major developmentally regulated genes Eip74 and Eip75: key regulators in the response to 20-hydroxyecdysone (20E), the main hormone responsible for the temporal co-ordination of post-embryonic development in Drosophila. Previous work in our and other labs indicates that the regression of non-HS puffs during the HSR is dependent on the presence of functional HSF. Using chromatin immunoprecipitation (ChIP) followed by hybridization to genome tiling arrays (Chip), I have identified 434 regions in the Drosophila Kc cell genome that are bound by HSF during HS, and have determined that 57% of these sites are located within the transcribed regions of genes. By examining the transcriptional response to HS in Kc cells and third instar larvae using expression microarrays, I found that only about 10% of all genes within 1250 bp of an HSF binding site are transcriptionally regulated by HS and many genes whose transcript levels change during HS do not appear to be near an HSF binding site. Furthermore, genes with an HSF binding site within their introns are significantly enriched (modified Fisher Exact p-value between 2.0x10-3 and 1.5x10-6) in gene ontology terms related to developmental processes and reproduction. Using expression microarray technology, I characterized the transcriptional response to 20E and its structural analog ponasterone A. I have identified multiple HSF binding sites within Eip74 and Eip75, and show that induction of the HSR correlates with repression of these genes and all other 20E-inducible genes. Taken together, this work provides a basis for further investigation into the role of HSF binding to sites not associated with HS genes and its possible function as a repressor of gene transcription during conditions of stress and as a regulator of developmental genes under stress and non-stress conditions.

HSF

Heat Shock Factor

Heat Shock Response

transcription

gene expression

genomics

ChIP-on-chip

ecdysone

Eip75B

Ponasterone A

20-hydroxyecdysone

ecdysone response

hsf4

transcription factor

models of transcription

genome tiling arrays

Heat Shock Protein

Heat Shock Gene

0307

Small Heat Shock Proteins from Oryza Sativa and Salmonella Enterica

Mani, Nandini

January 2014

Small heat shock proteins (sHSPs) are a ubiquitous family of molecular chaperones that play a vital role in maintaining protein homeostasis in cells. They are the first line of defence against the detrimental effects of cellular stress conditions like fluctuations in temperature, pH, oxidative and osmotic potentials, heavy metal toxicity, drought and anoxia. Many sHSPs are also constitutively expressed during developmental stages of different plant tissues. Members of this family are ATP-independent chaperones, with monomeric masses varying from 12-40 kDa. A characteristic feature of sHSPs is their ability to assemble into large oligomers, ranging from dimers to 48-mers. Under stress conditions, these oligomers dissociate and/or undergo drastic conformational changes to facilitate their binding to misfolded substrate proteins in the cell. This interaction prevents the substrate from aggregating during stress. When physiological conditions are restored, the substrates are transferred to other ATP-dependent heat shock proteins for refolding. Thus sHSPs do not refold their substrates, but instead prevent them from aggregating and maintain them in a „folding-competent‟ state. The clientele of sHSPs includes proteins with a wide range of molecular masses, secondary structures and pIs. This promiscuity has led to sHSPs occupying key positions in the protein quality control network. As molecular chaperones that protect proteins, sHSPs prevent disease. Concomitantly, mutations in sHSPs have also been linked to various human diseases. Till date, high resolution crystal structures are available only for 3 sHSP oligomers. This insufficiency of structural information has hindered our understanding of the mechanism of chaperone function, the link between the oligomeric status and chaperone activity, identification of substrate binding sites and the role of the flexible terminal segments in mediating both the oligomerization and chaperone function. We undertook structural and functional characterization of plant and bacterial sHSPs in order to address some of these questions. Chapter 1 of this thesis gives an overview of the sHSP family, with special emphasis on the oligomeric assemblies of sHSPs of known structures. We highlight what we know about this family through mutational studies, what is as yet unknown, and why it is important to study this family. Chapter 2 describes our efforts at structural and functional characterization of 5 sHSPS in rice, each targeted to a different organelle. We probed the role played by the N-terminal region in mediating oligomer assembly and in the chaperone activity of the protein. Rice sHSPs displayed a wide range of hydrodynamic radii, from 4 nm to 14 nm, suggesting that their oligomeric assemblies are likely to be diverse. In chapter 3, we discuss our attempts at the structural characterization of a bacterial sHSP, Aggregation suppressing protein A, or AgsA from Salmonella enterica. We obtained a high resolution crystal structure of the dimer of the core sHSP domain. We compared this dimer with other known sHSP dimers, reported the deviations that we observed and analysed the structure to account for these differences. We used this dimer structure to successfully obtain solutions for low resolution X-ray diffraction data for oligomers of different truncated constructs of AgsA. We observed that a C-terminal truncated construct formed an octahedral 24¬mer (4.5 Å resolution), whereas a construct truncated at both termini formed a triangular bipyramidal 18-mer (7.7 Å resolution), an assembly hitherto unobserved for any sHSP. A similar 18-mer was obtained when the C-terminal truncated construct was incubated with a dipeptide prior to crystallisation (6.7 Å resolution). The cryo-EM map of the wild type protein (12 Å resolution) could be fitted with a different 18-mer. The low resolution of the data pre-empted an atomic-level description of the interfaces of the assemblies. However, our work highlights the structural plasticity of this protein and probes the sensitivity of the oligomeric assembly to minor differences in construct length.

Small Heat Shock Proteins (sHSPs)

Salmonella Enterica

Molecular Chaperones

Heat Shock Gene AgsA

Oryza Sativa

Cellular Stress Response

Salomonella Enterica Heat Shock Proteins

Heat Shock Proteins

Molecular Biophysics