Devoting a few sentences to each, describe the following structures or complexes and their effects on eukaryotic gene expression:

Promoter

Devoting a few sentences to each, describe the following structures or complexes and their effects on eukaryotic gene expression:

Enhancer

Devoting a few sentences to each, describe the following structures or complexes and their effects on eukaryotic gene expression:

Silencer

Devoting a few sentences to each, describe the following structures or complexes and their effects on eukaryotic gene expression:

RISC

Devoting a few sentences to each, describe the following structures or complexes and their effects on eukaryotic gene expression:

Dicer

Describe and give an example (real or hypothetical) of each of the following:

Upstream activator sequence (UAS)

Describe and give an example (real or hypothetical) of each of the following:

Insulator sequence action

Describe and give an example (real or hypothetical) of each of the following:

Silencer sequence action

Describe and give an example (real or hypothetical) of each of the following:

Enhanceosome action

Describe and give an example (real or hypothetical) of each of the following:

RNA interference

What is meant by the term chromatin remodeling? Describe the importance of this process to transcription.

What general role does acetylation of histone protein amino acids play in the transcription of eukaryotic genes?

Describe the roles of writers, readers, and erasers in eukaryotic gene regulation.

Outline the roles of RNA in eukaryotic gene regulation.

What are the roles of the Polycomb and Trithorax complexes in eukaryotic gene regulation?

Compare and contrast the transcriptional regulation of GAL genes in yeast with that of the lac genes in bacteria.

The term heterochromatin refers to heavily condensed regions of chromosomes that are largely devoid of genes. Since few genes exist there, these regions almost never decondense for transcription. At what point during the cell cycle would you expect to observe the decondensation of heterochromatic regions? Why?

Compare and contrast promoters and enhancers with respect to their location (upstream versus downstream), orientation, and distance (in base pairs) relative to a gene they regulate.

What are the different chromatin classifications, and what is their relationship to gene expression?

Define epigenetics, and provide examples illustrating your definition.

What is one proposed role for lncRNAs?

What are the sources of dsRNA? Diagram the mechanisms by which dsRNAs are produced and processed into small RNAs.

How does dsRNA lead to posttranscriptonal gene silencing?

A hereditary disease is inherited as an autosomal recessive trait1. The wild-type allele of the disease gene produces a mature mRNA that is 1250 nucleotides (nt) long. Molecular analysis shows that the mature mRNA consists of four exons that measure 400 nt (exon 1), 320 nt (exon 2), 230 nt (exon 3), and 300 nt (exon 4). A mother and father with two healthy children and two children with the disease have northern blot analysis performed in a medical genetics laboratory. The results of the northern blot for each family member are shown here. Identify the genotype of each family member, using the sizes of mRNAs to indicate each allele. (For example, a person who is homozygous wild type is indicated as '1250/1250.')

A hereditary disease is inherited as an autosomal recessive trait1. The wild-type allele of the disease gene produces a mature mRNA that is 1250 nucleotides (nt) long. Molecular analysis shows that the mature mRNA consists of four exons that measure 400 nt (exon 1), 320 nt (exon 2), 230 nt (exon 3), and 300 nt (exon 4). A mother and father with two healthy children and two children with the disease have northern blot analysis performed in a medical genetics laboratory. The results of the northern blot for each family member are shown here. Based on your analysis, what is the most likely molecular abnormality causing the disease allele?

The UG4 gene is expressed in stem tissue and leaf tissue of the plant Arabidopsis thaliana. To study mechanisms regulating UG4 expression, six small deletions of the DNA sequence upstream of the gene-coding sequence are made. The locations of deletions and their effect on UG4 expression are shown here. Explain the differential effects of deletions B and F on expression in the two tissues.

The UG4 gene is expressed in stem tissue and leaf tissue of the plant Arabidopsis thaliana. To study mechanisms regulating UG4 expression, six small deletions of DNA sequence upstream of the gene-coding sequence are made. The locations of deletions and their effect on UG4 expression are shown here. Why does deletion D raise UG4 expression in leaf tissue but not in stem tissue?

The UG4 gene is expressed in stem tissue and leaf tissue of the plant Arabidopsis thaliana. To study mechanisms regulating UG4 expression, six small deletions of DNA sequence upstream of the gene-coding sequence are made. The locations of deletions and their effect on UG4 expression are shown here. Why does deletion E lower expression of UG4 in leaf tissue but not in stem tissue?

Diagram and explain how the inducibility of a gene—for instance in response to an environmental cue—could be mediated by an activator. Then show how it could be mediated by a repressor.

A muscle enzyme called ME1 is produced by transcription and translation of the ME1 gene in several muscles during mouse development, including heart muscle, in a highly regulated manner. Production of ME1 appears to be turned on and turned off at different times during development. To test the possible role of enhancers and silencers in ME1 transcription, a biologist creates a recombinant genetic system that fuses the ME1 promoter, along with DNA that is upstream of the promoter, to the bacterial lacZ (β-galactosidase) gene. The lacZ gene is chosen for the ease and simplicity of assaying production of the encoded enzyme. The diagram shows bars that indicate the extent of six deletions the biologist makes to the ME1 promoter and upstream sequences. The blue deletion labeled D is within the promoter whereas the gray bars span potential enhancer/silencer modules. The table displays the percentage of β-galactosidase activity in each deletion mutant in comparison with the recombinant gene system without any deletions.

Does this information indicate the presence of enhancer and/or silencer sequences in the ME1 upstream sequence? If so, where is/are the sequences located?