BIO 2250 Exam #2 Study Guide PDF

Summary

This study guide covers various biological concepts, including gene expression, cellular energy production, and membrane structure. It details processes like transcription, differentiation, and the function of key organelles like mitochondria and chloroplasts. It also explains key biological techniques such as PCR and Sanger Sequencing.

Full Transcript

BIO 2250 Exam #2 Study Guide

Chapter 8: Control of Gene Expression

1. Why different cell types arise from the same genome:

- The genome carries the complete set of instructions, but different cell types are formed through

selective gene expression. Each cell type expresses only a specific subset of genes based on

regulatory factors.

2. Stages of gene regulation:

- Most common and easiest stage for regulation: Transcription. Regulating gene expression at the

transcription level is the most efficient since it prevents unnecessary downstream processing.

3. Differentiation of cells:

- Differentiation is controlled by regulatory proteins, which activate tissue-specific genes, driving

cells to specialized states.

4. Three minimum transcription factors for iPS cells:

- Oct4, Sox2, and Klf4 are sufficient to reprogram differentiated cells into pluripotent stem cells.

Chapter 10: Analyzing the Structure and Function of Genes

1. Key Technologies:

- PCR: Amplifies specific DNA sequences, crucial for molecular cloning and diagnostics (e.g.,

detecting pathogens).

- Sanger Sequencing: Uses dideoxynucleotides to terminate DNA synthesis, creating fragments

that can be sequenced to determine nucleotide order.
 - Restriction Enzymes: Enzymes that cut DNA at specific sites, allowing scientists to construct

recombinant plasmids.

2. Reporter Gene Assay:

- Reporter genes are linked to regulatory sequences of interest to monitor gene expression. A

common reporter is GFP, which fluoresces under certain conditions.

Chapter 13: How Cells Obtain Energy from Food

1. Where is most ATP generated?

- Mitochondria, through oxidative phosphorylation.

2. Location of three steps in glucose catabolism:

- Glycolysis: Cytosol.

- Pyruvate to Acetyl-CoA conversion: Mitochondrial matrix.

- TCA Cycle: Mitochondrial matrix.

3. Fermentation (Muscle vs. Yeast):

- Muscle: Pyruvate is reduced to lactate, producing 2 ATP per glucose.

- Yeast: Pyruvate is converted to ethanol and CO2, also producing 2 ATP per glucose.

4. b-Oxidation and energy from fatty acids:

- Fatty acids are broken down to produce acetyl-CoA, which enters the TCA cycle for energy

production. Each cycle of b-oxidation generates multiple acetyl-CoA molecules.

5. Amino acids in the TCA cycle:

- Amino acids can be converted to intermediates that enter the TCA cycle for energy production.
Chapter 14: Energy Generation in Mitochondria and Chloroplasts

1. Proton Gradient:

- A proton gradient is established across the mitochondrial inner membrane during the electron

transport chain, driving ATP synthesis.

2. What enzyme produces ATP?

- ATP synthase, driven by the proton gradient, synthesizes ATP during oxidative phosphorylation.

3. Structure of mitochondria and chloroplasts:

- Mitochondria: Double membrane, with the inner membrane folded into cristae.

- Chloroplasts: Contain thylakoid membranes (site of light reactions) and stroma (site of the Calvin

cycle).

4. More mitochondria in energy-consuming cells:

- Muscle and sperm cells contain more mitochondria due to high energy demands.

5. Role of Acetyl-CoA:

- Acetyl-CoA is a central metabolite in both catabolism (TCA cycle) and anabolism (lipid

biosynthesis).

6. Oxygen's role in energy production:

- Oxygen is the final electron acceptor in the electron transport chain, allowing for efficient ATP

production.

7. Difference between mitochondria and chloroplasts (sending energy to cytosol):

- In mitochondria, ATP is directly exported to the cytosol for cellular use, while in chloroplasts, ATP
is used within the chloroplast to synthesize carbohydrates.

8. Order of Photosystems:

- Photosystem II occurs first, producing O2 and ATP, followed by Photosystem I, which produces

NADPH.

9. ATP and NADPH in the Calvin Cycle:

- Each turn of the Calvin cycle consumes 9 ATP and 6 NADPH.

10. Calvin Cycle Product:

- The main product is glyceraldehyde 3-phosphate (G3P), which is used to form glucose and

other carbohydrates.

Chapter 11: Membrane Structure

1. Naming of membrane organelles:

- Organelles like the nucleus, ER, Golgi apparatus, and mitochondria are part of the membrane

system.

2. Most common phospholipid species:

- Phosphatidylcholine is the most abundant phospholipid in the cell membrane.

3. Role of cholesterol:

- Cholesterol modulates membrane fluidity, providing stiffness to the membrane.

4. Lipid synthesis and membrane assembly:

- Lipid synthesis occurs in the smooth ER, with enzymes like scramblase and flippase facilitating
the distribution of lipids between membrane leaflets.

5. Orientation of the membrane (topology):

- Membranes are asymmetric, with distinct lipid compositions on the inner and outer leaflets.

6. Types of membrane proteins and their functions:

- Membrane proteins include transporters, anchors, receptors, and enzymes, each facilitating

specific cellular functions.

7. Membrane association of proteins:

- Proteins can be transmembrane (span the bilayer), lipid-linked, or protein-attached, with varying

degrees of mobility within the membrane.

8. Dynamic nature of the membrane:

- Membrane proteins and lipids can move laterally, contributing to the fluidity of the membrane.

9. Lateral mobility restrictions:

- Membrane protein mobility can be restricted by tight junctions, anchoring proteins, or interactions

with the cytoskeleton.

10. Membrane protein modification (glycosylation):

- Proteins can be glycosylated, meaning sugars are covalently attached, playing a role in cell

recognition and signaling.