Facilitated diffusion through biological membranes is driven by a difference in solute concentrations. If it were driven by ATP, what you'd have is primary active transport. And it is most certainly specific with regard to substrate. Now, the specificity of a potassium channel for potassium over sodium is mainly the result of the differential interaction of the selectivity filter of the protein. Considering this is an ion channel, it's unlikely that it would be hydrophobic, that it would have a lot of phospholipids or cholesterol for that matter. Because it's going to want to be hydrophilic so it can interact with the ions better. Now, let's do a bit of a throwback problem here to our friend, the enzyme kinetics problem, except now we're masquerading it as a transport problem and looking for \(K_T\) instead of \(K_M\). So, everything has changed. Right? But still, it's good to practice this because it could come up. So, you're going to want to solve this using a Lineweaver-Burk type plot, but we don't actually need to graph it. I'm just drawing a representation of it here to talk about a couple of things in case you forgot. So, this point right here, the y-intercept, that is equal to \( \frac{1}{{V_{\text{max}}}} \), right? And this point right here, the x-intercept is equal to \( -\frac{1}{{K_M}} \) or in this case \( K_T \). So, we don't actually need to graph this, but we do need to use some of the data and a little bit of math. And we're going to have to get the reciprocal for some of these values. So, this is going to become 5, this is going to remain 1, this will be 17.5, and this will be 13. And we're going to need to use our \( y = mx + b \) equation for a line. Alright. So first things first, we need to find \( m \), the slope, and we're going to do that by determining the change in rise over change in run. So that is going to be \( \frac{17.5 - 13}{5 - 1} \) which is equal to \( \frac{4.5}{4} \) or 1.125. Now, to find \( b \), we need to plug in some values to our equation. So let's do \( 13 = 1.125 \times 1 + b \). So \( b \) is equal to \( 13 - 1.125 \) which is equal to 11.875 and remember that equals \( \frac{1}{V_{\text{max}}} \). It's not exactly what we want. What we want is \( V_{\text{max}} \). So \( V_{\text{max}} \) is going to be \( \frac{1}{11.875} \) which turns out is equal to 0.084 micromoles per second. Now to find \( K_T \), we need to substitute 0 in for \( y \), so we're going to say \( 0 = 1.125x + 11.875 \) which is \( b \). And we need to rearrange to get \( x \) by itself, so we get \( \frac{-11.875}{1.125} = x \). And let me just scroll a little bit here so we can see this better. My head doesn't cut it off. Alright. So that is equal to \( x \) and that comes out to about -10.6. Remember that's equal to \( -\frac{1}{{K_T}} \). So \( K_T \) is going to be equal to \( -\frac{1}{{-10.6}} \) which comes out to 0.094 millimolar. Alright, moving on to question 40. The type of membrane transport that uses ion gradients as the energy source is secondary active transport. Primary active transport uses ATP. Secondary active transport uses these gradients often established due to primary active transport. These gradients are usually there because pumps are pumping things actively. Passive transport relies on concentration gradients and includes simple diffusion and facilitated diffusion. Alright. Last problem. And this one is kind of an interesting one, so bear with me on the explanation but here is how to think about it. If you, let's say, have a membrane with 3 transporters in it, right? And one transporter transports all amino acids including lysine and arginine. And then you have another transporter that's specific to arginine and another one that's specific to lysine. And it turns out that this arginine transporter is inhibited by lysine. And this lysine transporter is inhibited by arginine. And by the way, this little symbol that I'm drawing right here, it's kind of like a perpendicular symbol, that's what we use in neuroscience to mean inhibition. So I'm just saying that those are inhibiting those transporters. So anyways, if the arginine transporter is inhibited by lysine, well then only half the lysine is going to get through because it's going to have to go through this other transporter. Likewise, if only, if the arginine is inhibiting this lysine transporter, only half of the lysine is going to get through because it's going to have to just use that other one. So that's why the answer to this question is 3. That's all I have, for this video. If you have any questions, please leave comments on the videos, and I will answer them and good luck on your exam.
- 1. Introduction to Biochemistry4h 34m
- What is Biochemistry?5m
- Characteristics of Life12m
- Abiogenesis13m
- Nucleic Acids16m
- Proteins12m
- Carbohydrates8m
- Lipids10m
- Taxonomy10m
- Cell Organelles12m
- Endosymbiotic Theory11m
- Central Dogma22m
- Functional Groups15m
- Chemical Bonds13m
- Organic Chemistry31m
- Entropy17m
- Second Law of Thermodynamics11m
- Equilibrium Constant10m
- Gibbs Free Energy37m
- 2. Water3h 23m
- 3. Amino Acids8h 10m
- Amino Acid Groups8m
- Amino Acid Three Letter Code13m
- Amino Acid One Letter Code37m
- Amino Acid Configuration20m
- Essential Amino Acids14m
- Nonpolar Amino Acids21m
- Aromatic Amino Acids14m
- Polar Amino Acids16m
- Charged Amino Acids40m
- How to Memorize Amino Acids1h 7m
- Zwitterion33m
- Non-Ionizable Vs. Ionizable R-Groups11m
- Isoelectric Point10m
- Isoelectric Point of Amino Acids with Ionizable R-Groups51m
- Titrations of Amino Acids with Non-Ionizable R-Groups44m
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- Amino Acids and Henderson-Hasselbalch44m
- 4. Protein Structure10h 4m
- Peptide Bond18m
- Primary Structure of Protein31m
- Altering Primary Protein Structure15m
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- Determining Net Charge of a Peptide42m
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- Approximating Protein Mass7m
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- Ramachandran Plot26m
- Atypical Ramachandran Plots12m
- Alpha Helix15m
- Alpha Helix Pitch and Rise20m
- Alpha Helix Hydrogen Bonding24m
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- Beta Strand12m
- Beta Sheet12m
- Antiparallel and Parallel Beta Sheets39m
- Beta Turns26m
- Tertiary Structure of Protein16m
- Protein Motifs and Domains23m
- Denaturation14m
- Anfinsen Experiment20m
- Protein Folding34m
- Chaperone Proteins19m
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- Simple Vs. Conjugated Proteins10m
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- 5. Protein Techniques14h 5m
- Protein Purification7m
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- Differential Centrifugation15m
- Salting Out18m
- Dialysis9m
- Column Chromatography11m
- Ion-Exchange Chromatography35m
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- Size Exclusion Chromatography28m
- Affinity Chromatography16m
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- HPLC29m
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- Native Gel Electrophoresis23m
- SDS-PAGE34m
- SDS-PAGE Strategies16m
- Isoelectric Focusing17m
- 2D-Electrophoresis23m
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- Mass Spectrometry12m
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- Tandem Mass Spectrometry16m
- Peptide Mass Fingerprinting16m
- Overview of Direct Protein Sequencing30m
- Amino Acid Hydrolysis10m
- FDNB26m
- Chemical Cleavage of Bonds29m
- Peptidases1h 6m
- Edman Degradation30m
- Edman Degradation Sequenator and Sequencing Data Analysis4m
- Edman Degradation Reaction Efficiency20m
- Ordering Cleaved Fragments21m
- Strategy for Ordering Cleaved Fragments58m
- Indirect Protein Sequencing Via Geneomic Analyses24m
- 6. Enzymes and Enzyme Kinetics13h 38m
- Enzymes24m
- Enzyme-Substrate Complex17m
- Lock and Key Vs. Induced Fit Models23m
- Optimal Enzyme Conditions9m
- Activation Energy24m
- Types of Enzymes41m
- Cofactor15m
- Catalysis19m
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- Covalent Catalysis18m
- Reaction Rate10m
- Enzyme Kinetics24m
- Rate Constants and Rate Law35m
- Reaction Orders52m
- Rate Constant Units11m
- Initial Velocity31m
- Vmax Enzyme27m
- Km Enzyme42m
- Steady-State Conditions25m
- Michaelis-Menten Assumptions18m
- Michaelis-Menten Equation52m
- Lineweaver-Burk Plot43m
- Michaelis-Menten vs. Lineweaver-Burk Plots20m
- Shifting Lineweaver-Burk Plots37m
- Calculating Vmax40m
- Calculating Km31m
- Kcat46m
- Specificity Constant1h 1m
- 7. Enzyme Inhibition and Regulation 8h 42m
- Enzyme Inhibition13m
- Irreversible Inhibition12m
- Reversible Inhibition9m
- Inhibition Constant26m
- Degree of Inhibition15m
- Apparent Km and Vmax29m
- Inhibition Effects on Reaction Rate10m
- Competitive Inhibition52m
- Uncompetitive Inhibition33m
- Mixed Inhibition40m
- Noncompetitive Inhibition26m
- Recap of Reversible Inhibition37m
- Allosteric Regulation7m
- Allosteric Kinetics17m
- Allosteric Enzyme Conformations33m
- Allosteric Effectors18m
- Concerted (MWC) Model25m
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- Negative Feedback13m
- Positive Feedback15m
- Post Translational Modification14m
- Ubiquitination19m
- Phosphorylation16m
- Zymogens13m
- 8. Protein Function 9h 41m
- Introduction to Protein-Ligand Interactions15m
- Protein-Ligand Equilibrium Constants22m
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- Myoglobin vs. Hemoglobin27m
- Heme Prosthetic Group31m
- Hemoglobin Cooperativity23m
- Hill Equation21m
- Hill Plot42m
- Hemoglobin Binding in Tissues & Lungs31m
- Hemoglobin Carbonation & Protonation19m
- Bohr Effect23m
- BPG Regulation of Hemoglobin24m
- Fetal Hemoglobin6m
- Sickle Cell Anemia24m
- Chymotrypsin18m
- Chymotrypsin's Catalytic Mechanism38m
- Glycogen Phosphorylase21m
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- Antibody35m
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- Motor Proteins14m
- Skeletal Muscle Anatomy22m
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- 9. Carbohydrates7h 49m
- Carbohydrates19m
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- Stereochemistry of Monosaccharides33m
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- Pyranose Conformations23m
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- Glycosidic Bond48m
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- Chitin8m
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- 10. Lipids5h 49m
- Lipids15m
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- Eicosanoids19m
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- Steroids14m
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- Lipid Vitamins19m
- Comprehensive Final Lipid Map13m
- Biological Membranes16m
- Physical Properties of Biological Membranes18m
- Types of Membrane Proteins8m
- Integral Membrane Proteins16m
- Peripheral Membrane Proteins12m
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- 11. Biological Membranes and Transport 6h 37m
- Biological Membrane Transport21m
- Passive vs. Active Transport18m
- Passive Membrane Transport21m
- Facilitated Diffusion8m
- Erythrocyte Facilitated Transporter Models30m
- Membrane Transport of Ions29m
- Primary Active Membrane Transport15m
- Sodium-Potassium Ion Pump20m
- SERCA: Calcium Ion Pump10m
- ABC Transporters12m
- Secondary Active Membrane Transport12m
- Glucose Active Symporter Model19m
- Endocytosis & Exocytosis18m
- Neurotransmitter Release23m
- Summary of Membrane Transport21m
- Thermodynamics of Membrane Diffusion: Uncharged Molecule51m
- Thermodynamics of Membrane Diffusion: Charged Ion1h 1m
- 12. Biosignaling9h 45m
- Introduction to Biosignaling44m
- G protein-Coupled Receptors32m
- Stimulatory Adenylate Cyclase GPCR Signaling42m
- cAMP & PKA28m
- Inhibitory Adenylate Cyclase GPCR Signaling29m
- Drugs & Toxins Affecting GPCR Signaling20m
- Recap of Adenylate Cyclase GPCR Signaling5m
- Phosphoinositide GPCR Signaling58m
- PSP Secondary Messengers & PKC27m
- Recap of Phosphoinositide Signaling7m
- Receptor Tyrosine Kinases26m
- Insulin28m
- Insulin Receptor23m
- Insulin Signaling on Glucose Metabolism57m
- Recap Of Insulin Signaling in Glucose Metabolism6m
- Insulin Signaling as a Growth Factor1h 1m
- Recap of Insulin Signaling As A Growth Factor9m
- Recap of Insulin Signaling1m
- Jak-Stat Signaling25m
- Lipid Hormone Signaling15m
- Summary of Biosignaling13m
- Signaling Defects & Cancer20m
- Review 1: Nucleic Acids, Lipids, & Membranes2h 47m
- Nucleic Acids 19m
- Nucleic Acids 211m
- Nucleic Acids 34m
- Nucleic Acids 44m
- DNA Sequencing 19m
- DNA Sequencing 211m
- Lipids 111m
- Lipids 24m
- Membrane Structure 110m
- Membrane Structure 29m
- Membrane Transport 18m
- Membrane Transport 24m
- Membrane Transport 36m
- Practice - Nucleic Acids 111m
- Practice - Nucleic Acids 23m
- Practice - Nucleic Acids 39m
- Lipids11m
- Practice - Membrane Structure 17m
- Practice - Membrane Structure 25m
- Practice - Membrane Transport 16m
- Practice - Membrane Transport 26m
- Review 2: Biosignaling, Glycolysis, Gluconeogenesis, & PP-Pathway3h 12m
- Biosignaling 19m
- Biosignaling 219m
- Biosignaling 311m
- Biosignaling 49m
- Glycolysis 17m
- Glycolysis 27m
- Glycolysis 38m
- Glycolysis 410m
- Fermentation6m
- Gluconeogenesis 18m
- Gluconeogenesis 27m
- Pentose Phosphate Pathway15m
- Practice - Biosignaling13m
- Practice - Bioenergetics 110m
- Practice - Bioenergetics 216m
- Practice - Glycolysis 111m
- Practice - Glycolysis 27m
- Practice - Gluconeogenesis5m
- Practice - Pentose Phosphate Path6m
- Review 3: Pyruvate & Fatty Acid Oxidation, Citric Acid Cycle, & Glycogen Metabolism2h 26m
- Pyruvate Oxidation9m
- Citric Acid Cycle 114m
- Citric Acid Cycle 27m
- Citric Acid Cycle 37m
- Citric Acid Cycle 411m
- Metabolic Regulation 18m
- Metabolic Regulation 213m
- Glycogen Metabolism 16m
- Glycogen Metabolism 28m
- Fatty Acid Oxidation 111m
- Fatty Acid Oxidation 28m
- Citric Acid Cycle Practice 17m
- Citric Acid Cycle Practice 26m
- Citric Acid Cycle Practice 32m
- Glucose and Glycogen Regulation Practice 14m
- Glucose and Glycogen Regulation Practice 26m
- Fatty Acid Oxidation Practice 14m
- Fatty Acid Oxidation Practice 27m
- Review 4: Amino Acid Oxidation, Oxidative Phosphorylation, & Photophosphorylation1h 48m
- Amino Acid Oxidation 15m
- Amino Acid Oxidation 211m
- Oxidative Phosphorylation 18m
- Oxidative Phosphorylation 210m
- Oxidative Phosphorylation 310m
- Oxidative Phosphorylation 47m
- Photophosphorylation 15m
- Photophosphorylation 29m
- Photophosphorylation 310m
- Practice: Amino Acid Oxidation 12m
- Practice: Amino Acid Oxidation 22m
- Practice: Oxidative Phosphorylation 15m
- Practice: Oxidative Phosphorylation 24m
- Practice: Oxidative Phosphorylation 35m
- Practice: Photophosphorylation 15m
- Practice: Photophosphorylation 21m
Practice - Membrane Transport 2: Study with Video Lessons, Practice Problems & Examples
Facilitated diffusion across biological membranes relies on solute concentration differences, while primary active transport uses ATP. Ion channels, like potassium channels, exhibit substrate specificity due to their selectivity filters. Secondary active transport utilizes ion gradients established by primary active transport. Understanding enzyme kinetics through Lineweaver-Burk plots aids in calculating Vmax and KT. Inhibition can occur between transporters, affecting the transport efficiency of amino acids. Key equations include the slope-intercept form for determining transport rates and constants.
Practice - Membrane Transport 2
Video transcript
Here’s what students ask on this topic:
What is the difference between facilitated diffusion and primary active transport?
Facilitated diffusion and primary active transport are both mechanisms for moving substances across cell membranes, but they differ significantly. Facilitated diffusion relies on the concentration gradient of the solute and does not require energy input. It uses specific transport proteins to move substances from an area of higher concentration to an area of lower concentration. In contrast, primary active transport requires energy in the form of ATP to move substances against their concentration gradient, from an area of lower concentration to an area of higher concentration. This process involves transport proteins known as pumps.
How do potassium channels achieve specificity for potassium over sodium?
Potassium channels achieve specificity for potassium (K+) over sodium (Na+) primarily through the selectivity filter of the protein. The selectivity filter is a narrow region within the channel that interacts differently with K+ and Na+. The filter is designed to stabilize the dehydrated K+ ion through specific interactions, such as coordination with carbonyl oxygen atoms. Sodium ions, being smaller, do not fit as well into the selectivity filter and are not stabilized in the same way, thus preventing their passage through the channel.
What is secondary active transport and how does it differ from primary active transport?
Secondary active transport uses the energy stored in ion gradients, which are typically established by primary active transport, to move substances across the membrane. Unlike primary active transport, which directly uses ATP to pump ions against their concentration gradient, secondary active transport relies on the energy from the movement of one ion down its gradient to drive the transport of another substance against its gradient. This process often involves symporters or antiporters, which move ions and other molecules in the same or opposite directions, respectively.
How can Lineweaver-Burk plots be used to determine Vmax and KT in membrane transport studies?
Lineweaver-Burk plots are double reciprocal plots used to linearize the hyperbolic relationship between substrate concentration and reaction rate in enzyme kinetics. In membrane transport studies, these plots can be adapted to determine Vmax (maximum transport rate) and KT (transport constant). The y-intercept of the Lineweaver-Burk plot is equal to 1/Vmax, and the x-intercept is equal to -1/KT. By plotting 1/transport rate (1/v) against 1/substrate concentration (1/[S]), one can determine these constants from the intercepts and slope of the resulting straight line.
What role do ion gradients play in secondary active transport?
Ion gradients play a crucial role in secondary active transport by providing the energy needed to move substances across the membrane. These gradients are typically established by primary active transport, which uses ATP to pump ions like Na+ or H+ out of the cell, creating a high concentration outside and a low concentration inside. Secondary active transporters, such as symporters and antiporters, use the energy released when ions move back down their concentration gradient to transport other molecules against their gradient. This coupling allows cells to efficiently import or export essential substances without directly using ATP.