10.1
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Q1: Why do liver cells and neurons express different genes if they contain the same DNA?
Although all cells in an organism contain identical DNA, differential gene expression enables distinct cell types to perform specialized functions. Liver cells express genes for alcohol dehydrogenase to detoxify toxins, while neurons express neurexins for neurotransmission. This selective gene expression, controlled by transcription factors and regulatory mechanisms, allows cells with identical genetic material to develop unique structures and functions.
Q2: How do transcription factors control liver-specific gene expression?
Transcription factors like C/EBPα, C/EBPβ, and Hepatocyte Nuclear Factor-1 bind to DNA regulatory regions to activate liver-specific genes during development. These factors enable hepatocytes to express genes involved in detoxification, bile production, and protein synthesis. Transcription factors are preferred regulatory points because they prevent unnecessary mRNA synthesis, making gene control efficient at the earliest stages.
Q3: What role does glucagon play in regulating gene expression in liver cells?
When blood glucose levels decrease, the pancreas secretes glucagon, signaling liver cells to express phosphoenolpyruvate carboxykinase (PEPCK), a protein required for glucose production from non-carbohydrate sources. Glucagon indirectly stimulates transcription factors C/EBPα and C/EBPβ to bind the PEPCK promoter, activating transcription. This demonstrates how extracellular signals trigger specific gene expression responses to maintain metabolic homeostasis.
Q4: At what stages of development do liver cells express different genes?
During early development, liver cells express genes involved in cell cycle, DNA replication, and proliferation. As differentiation progresses, genes for epithelial differentiation and blood coagulation become highly expressed. Once cells fully differentiate into hepatocytes, liver-specific genes for lipid metabolism and cholesterol regulation are activated, enabling mature liver functions.
Q5: How do histone modifications affect gene accessibility in different cell types?
Histone modifications alter chromatin structure by loosening or tightening DNA, respectively allowing or preventing transcriptional regulators from accessing genes. Different cell types possess distinct covalent modifications and histone variants, creating variation in gene accessibility. This epigenetic regulation enables cells to selectively express genes appropriate to their identity and function without changing DNA sequence.
Q6: How does insulin regulate PEPCK gene expression when blood glucose is high?
When blood glucose levels are elevated, the pancreas secretes insulin, which inhibits PEPCK gene transcription through an insulin-responsive sequence in the gene's regulatory region. This prevents glucose production when glucose is already abundant, maintaining metabolic balance. The PEPCK gene thus responds to opposing hormonal signals—glucagon activates it during low glucose, while insulin suppresses it during high glucose.
Q7: What are the main functions of liver cells that require specific gene expression?
Hepatocytes must express genes enabling detoxification of blood, production of bile for fat metabolism, and synthesis of proteins essential for metabolism. These specialized functions depend on the coordinated expression of liver-specific genes that encode enzymes and proteins like alcohol dehydrogenase. Differential gene expression allows hepatocytes to fulfill these critical metabolic and protective roles.
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