AP Biology Unit 2: Cell Structure and Function Summary
Summary
TLDRMelanie Kingett's 'APsolute Recap' video offers an in-depth review of Unit 2: Cell Structure and Function, emphasizing the complexity of AP Biology beyond simple memorization. The video covers the organization of macromolecules, the roles of various organelles, the endomembrane system, and the importance of surface area to volume ratios for efficient cellular function. It also discusses the dynamic nature of plasma membranes and the mechanisms of cellular transport, including active and passive methods. Viewers are encouraged to use the accompanying study guide and review packet for practice and deeper understanding.
Takeaways
- 📚 The video recaps Unit 2: Cell Structure and Function, diving deeper than introductory biology courses and focusing on understanding rather than simple fact recall.
- 🧬 All living things are composed of the same macromolecules, allowing for molecular integration and cooperation across different life forms.
- 🛑 Phospholipids form the basis of cell membranes with their polar and non-polar ends, contributing to the compartmentalization of organelles and selective permeability of the plasma membrane.
- 🔬 Ribosomes, found in both prokaryotes and eukaryotes, are essential for protein synthesis during the translation process.
- 🔄 The endomembrane system in eukaryotic cells facilitates the movement of materials through a series of organelles including the nuclear envelope, lysosomes, and the Golgi apparatus.
- 🏭 The endoplasmic reticulum has two types: rough ER for protein production and folding, and smooth ER involved in detoxification and lipid synthesis.
- 📦 The Golgi apparatus sorts and packages materials for transport, distinguishing between the receiving (cis face) and shipping (trans face) sides.
- 🗑️ Lysosomes contain enzymes for cell recycling and apoptosis, while vacuoles serve various roles including osmoregulation and storage in different cell types.
- 🌿 Both mitochondria and chloroplasts are energy transducers with double membranes, the former for cellular respiration and the latter for photosynthesis.
- 🔬 The theory of endosymbiosis suggests that mitochondria and chloroplasts originated from independent prokaryotic cells and now have their own DNA and replication mechanisms.
- 🔄 The surface area to volume ratio is crucial for cellular efficiency, with larger cells facing challenges in maintaining homeostasis due to slower waste removal and nutrient intake.
Q & A
What is the main focus of Unit 2 in AP Biology as discussed in the video?
-Unit 2 of AP Biology focuses on Cell Structure and Function, diving deeper into the material than a typical introductory biology course and emphasizing understanding over simple fact recall.
Why is the Unit 2 study guide recommended for use with the video?
-The Unit 2 study guide is recommended because it helps viewers get the most out of the video by allowing them to pause and complete practice questions in each section, enhancing their understanding of the material.
Outlines
🌐 Cell Structure and Function Overview
Melanie Kingett introduces a comprehensive recap of Unit 2 on Cell Structure and Function for AP Biology. She emphasizes that while the material may be familiar to students with prior biology knowledge, AP Bio goes deeper and requires more than simple memorization. The video aims to assist students in both AP and non-AP biology classes, but it won't reteach everything. Melanie suggests using the Unit 2 study guide and the AP Biology Ultimate Review Packet for practice. She outlines the video's coverage of main topics, including the endomembrane system, organelles, and the importance of surface area to volume ratios for efficient cellular function. The summary also touches on the bilayer structure of cell membranes due to phospholipids and the role of ribosomes in protein synthesis.
🌿 Endomembrane System and Cellular Transport
This paragraph delves into the endomembrane system, detailing its components such as the nuclear envelope, lysosomes, vesicles, endoplasmic reticulum, Golgi apparatus, and plasma membrane. It explains the roles of the rough and smooth endoplasmic reticulum in protein production and detoxification, respectively. The Golgi apparatus's function in lipid and protein processing is highlighted, along with lysosomes' involvement in cell recycling and apoptosis. The paragraph also discusses vacuoles' various roles, including turgor pressure regulation in plant cells and osmotic pressure in paramecia. Energy transduction by mitochondria and chloroplasts is explored, with a focus on their double membranes, matrix, and the processes of cellular respiration and photosynthesis.
🔋 Energy Transduction and Membrane Dynamics
The paragraph discusses the structural aspects of chloroplasts and the division of photosynthesis into light and dark reactions. It also touches on the endosymbiotic theory, which posits that mitochondria and chloroplasts originated from prokaryotic cells. The importance of surface area to volume ratios for efficient cellular processes is reiterated, with examples of how cells achieve this through membrane folding or branching. The 'fluid mosaic model' of the plasma membrane is introduced, highlighting its dynamic nature and selective permeability. The paragraph further explains passive and active transport mechanisms, including diffusion, facilitated diffusion, osmosis, and the role of transport proteins in these processes. It concludes with an exploration of water potential and its implications for cellular osmoregulation.
🔬 Cellular Compartmentalization and Homeostasis
The final paragraph wraps up Unit 2 by summarizing the importance of cellular compartmentalization for efficient life processes. It reiterates the unique structures and functions of various organelles and how they contribute to the cell's overall function. The paragraph also underscores the role of membrane chemistry in controlling the rate and exchange of materials through active and passive transport, which is crucial for maintaining homeostasis. Melanie encourages students to practice applying the information learned, using the resources provided in the Ultimate Review Packet, including practice questions, skills videos, and a full-length practice exam. She concludes by inviting viewers to subscribe to her YouTube channel and look forward to the next recap on Cellular Energetics.
Mindmap
Keywords
💡Cell Structure and Function
💡Phospholipids
💡Ribosomes
💡Endomembrane System
💡Mitochondria
💡Chloroplasts
💡Surface Area to Volume Ratio
💡Plasma Membrane
💡Cellular Transport
💡Endocytosis and Exocytosis
💡Facilitated Diffusion
💡Osmosis
💡Prokaryotes and Eukaryotes
Highlights
AP Bio delves deeper than simple fact recall and focuses on understanding organelles and transport processes.
The video provides a comprehensive recap of Unit 2: Cell Structure and Function for both AP and non-AP biology students.
A free Unit 2 study guide and AP Biology Ultimate Review Packet are available for download to enhance learning.
All living things are composed of the same macromolecules, allowing for molecular integration and cooperation.
The phospholipid bilayer structure of cell membranes is crucial for compartmentalization and selective permeability.
Ribosomes, present in both prokaryotes and eukaryotes, are essential for protein synthesis during translation.
The endomembrane system efficiently packages, processes, and transports materials in eukaryotic cells.
The endoplasmic reticulum plays a vital role in protein production and initial folding, as well as detoxification and lipid synthesis.
The Golgi apparatus is responsible for the final stages of protein and lipid processing before transport.
Lysosomes and vacuoles are involved in cell recycling, apoptosis, and maintaining turgor pressure in plant cells.
Mitochondria and chloroplasts are energy transducers with unique structures that facilitate ATP production and photosynthesis.
The concept of endosymbiosis explains the origin of mitochondria and chloroplasts from independent prokaryotes.
The surface area to volume ratio is critical for efficient cellular function and metabolic processes.
Plasma membranes maintain homeostasis through selective permeability and dynamic molecular interactions.
Passive and active transport mechanisms are essential for the movement of molecules across cell membranes.
Membrane pumps, endocytosis, and exocytosis are key active transport processes requiring ATP.
Facilitated diffusion and osmosis are passive transport processes that do not require energy.
Water potential calculations are crucial for understanding osmosis and the movement of water in and out of cells.
Prokaryotic and eukaryotic cells differ in size, complexity, and the presence of a nucleus and membrane-bound organelles.
Cells compartmentalize functions and maintain homeostasis through unique organelle structures and membrane chemistry.
Transcripts
Hey I’m Melanie Kingett from the APsolute Recap and today’s video is going to recap
Unit 2: Cell Structure and Function.
If you took an introduction to biology course before the AP, It’s likely that much of
the material in this unit was familiar to you.
However - AP Bio dives a bit deeper and is very unlikely to ask you for simple fact recall
about an organelle or transport process.
If you're taking a non-AP biology class either in high school or college, this video can
absolutely help you too!
It’s not, however, going to reteach you everything.
If you’re getting confused throughout the video on some of the individual concepts and
you need more information, check out The Apsolute Recap Biology edition podcast and my Youtube
channel.
Before I start, please go get the Unit 2 study guide that accompanies this video and print
it out.
It's absolutely free and available with the AP Biology Ultimate Review Packet linked in
the description below.
You'll get the most out of this video if you pause it periodically and complete the practice
questions in each section.
Plus - there's an answer key in the ultimate review packet with a ton of other great opportunities
for practice with multiple choice questions, FRQS and additional videos modeling some of
the harder concepts and skills.
This summary video is going to review all of the main unit 2 topics according to the
college board curriculum (insert) - Many of the subtopics for unit 2 have overlapping
themes, so sometimes I’ll have multiple titles listed at the same time.
You can use these timestamps listed to jump ahead to a specific subtopic at any time.
Let’s Zoom out All living things are made of the same macromolecules
- proteins, lipids, nucleic acids, and carbohydrates - and so there is a lot of opportunity for
integration, cooperation, and molecular exchanges.
Phospholipids have polar heads and non-polar fatty acid tails and since both the intracellular
and extracellular cellular environments are aqueous, all membranes are bilayered with
hydrophobic tails facing inwards.
This chemical orientation causes organelles to be compartmentalized in their function,
the endomembrane system to integrate seamlessly, and the plasma membrane to have selective
permeability.
Let’s zoom in
Living things are organized into subcellular components – all of which contribute to
the function and ultimate success of the cell.
One organelle that is found in prokaryotes and eukaryotes are ribosomes.
Ribosomes are made of rRNA and protein and can be found free floating in the cytoplasm
and embedded on the rough endoplasmic reticulum.
The primary role of a ribosome is to produce proteins during translation of the central
dogma.
The movement of materials through the endomembrane system is consistent through all eukaryotic
cells.
Products are packaged, processed, and transported throughout the system.
The endomembrane system includes the nuclear envelope, lysosomes, vesicles, endoplasmic
reticulum, Golgi apparatus and plasma membrane.
The endoplasmic reticulum is a series of interconnected folded membranous sacs that is continuous
with the nuclear envelope.
There are two types - the rough ER is named such because it's studded with ribosomes and
so its is involved in protein production and initial folding.
It also compartmentalizes the cell and aids in intracellular transport.
I”ll cover protein production in depth in Unit 6.
The smooth ER is primarily involved in detoxification and lipid synthesis, but you don’t need
to know how lipids are synthesized for the exam.
Next is the Golgi Complex - a membrane bound organelle with a series of flattened stacks
involved with packaging, processing, sorting, and shipping of lipids and proteins.
The receiving side of the golgi is called the cis face while the opposite side is called
the trans face, where secretory vesicles bud off.
These next two smaller organelles are sac structures.
The lysosome has hydrolytic enzymes and is involved in cell recycling and apoptosis,
or scheduled cell death.
A vacuole is sometimes larger and has a variety of roles depending upon the cell that it's
found in.
For example, in a plant cell, there is a large central vacuole that holds the extra water
and dissolved solutes.
Turgor pressure will increase as the vacuole fills with water.
When vacuoles are empty in a plant cell, the plant will wilt.
Paramecia can have vacuoles as well, but these are contractile vacuoles which help to regulate
osmotic pressure, pumping water into and out of the cell.
The following two organelles are energy transducers with double membranes.
The mitochondria has a smooth outer layer, an inner layer folded into cristae and a fluid
matrix.
The mitochondria performs cellular respiration which produces ATP for the cell.
The greater folding of the inner membrane creates a greater surface area which means
more ATP can be produced!
The Krebs cycle oxidizes sugars in the matrix while the electron transport chain and ATP
synthesis occurs in the cristae.
The second energy transducer is the Chloroplast.
The purpose of the chloroplast is to perform photosynthesis, which will harness energy
from the sun and store it in sugars.
Structurally, it has inner thylakoid membranes stacked into grana surrounded by liquid stroma.
The compartmentalization of the chloroplast divides this process into light and dark reactions.
The light reaction occurs in the thylakoid membrane with the pigment chlorophyll and
electron transport chain while the Calvin cycle forms sugars in the stroma.
Both mitochondria and chloroplasts are theorized to have formed from independent prokaryotes
through endosymbiosis.
Not only do they have a double membrane, their own DNA, ribosomes, and replicate independently
– but they are approximately the size of existing prokaryotic cells.
Why are there no elephant sized amoebas?
A supersized amoeba would either starve or be poisoned by its own waste products because
as cells get larger, their volume increases at a faster rate than their surface area.
Surface area is a measurement of how much exposed space an object has in 2D space while
volume is a measurement of the amount of 3D space an object occupies.
The main idea here is that cells function best with the greatest surface area to volume
ratio.
There are alot of things that need to cross membranes for metabolism to function efficiently,
like proteins, carbs, gasses, wastes, ions, and ligands.
And while membranes do have a say in what can cross and when, the greatest surface area
per volume of space will always accomplish the task best.
This is often achieved through a lot of membrane folding, like with the microvilli of your
gut or through branching, as with root hairs.
Plasma membranes establish and maintain internal environments that are different from external
environments through molecular interactions.
We often refer to the plasma membrane as a “fluid mosaic model” because it has multiple
components that are constantly in motion.
It is composed of a bilayer of amphipathic phospholipids with embedded proteins, cholesterol,
and carbohydrate chains - some continuously shifting around the surface of the cell membrane.
The plasma membrane is very dynamic.
And because each of the plasma membrane components has unique chemistry and classifies as hydrophobic
or hydrophilic, the molecules that it interacts with for transport will also be chemically
distinct.
It's important that cell membranes establish and maintain their internal environments through
selective permeability.
After all, homeostasis is the maintenance of constant internal conditions, despite external
changes.
And environments are always changing!
One of ways that cells accomplish this is through the strategic movement of molecules.
Small, non-polar molecules like oxygen and carbon dioxide can pass freely and directly
through the phospholipid membrane since the fatty acid tails are also nonpolar.
Large or charged molecules like glucose or sodium pass through embedded proteins.
Cell walls can also provide permeability barriers, but are primarily used for structural support
and composed of different polysaccharides in plants, prokaryotes and fungi.
There are two types of cellular transport – passive, and active.
These categories are divided by the use of energy and the direction of molecular movement.
Passive transport is the net movement of molecules from high to low concentration without the
use of ATP.
We say net movement because molecules don’t have an agenda.
And even though it is more likely that molecules will bump into each other and spread out,
a few will also bounce over to the more concentrated area.
Remember - small, uncharged, non-polar molecules diffuse directly through the membrane while
large or charged molecules must move through a carrier or channel protein.
In contrast, the movement of molecules from regions of low concentration to high concentration
is known as active transport and requires the spending of ATP.
There are three main types of active transport - membrane pumps, endocytosis and exocytosis.
Let’s start with membrane pumps which are transmembrane carrier proteins.
Transport proteins are solute specific due to their unique chemical folding and R-group
interactions.
When ATP is hydrolyzed, a phosphate group is removed and often attached to the pump
itself.
Phosphorylation causes a conformational change in the protein's shape, adjusting the microenvironment
within the protein channel and shuttling the solutes across the membrane.
Two common examples of active transport are the sodium potassium pump and the proton pump.
Both the sodium potassium pump and the proton pump work to accumulate ions on one side of
a membrane, which the cell may later use during cotransport or with ATP synthase.
Molecules rarely stay concentrated for long.
The two other types of active transport involve vesicle formation for endo and exocytosis.
Since all membranes are primarily composed of phospholipids, the formation and fusion
of vesicles is a fairly seamless process.
Endocytosis is the process of bringing substances into the cell in larger quantities and has
three types.
Phagocytosis, commonly referred to as cell eating, pinocytosis, or cell drinking, and
receptor mediated endocytosis, where specific ligands bind to cell surface receptors, causing
vesicle formation.
Exocytosis involves the fusion of a vesicle with the plasma membrane for molecules to
exit the cell.
These might be intentional products that were shipped out by the Golgi or waste products
that the cell is removing.
The movement of molecules from high to low concentration through a transport protein
embedded in the membrane is called facilitated diffusion – or literally diffusion made
facil, easy.
By now you know that anything large or charged needs the use of a transport protein - either
carrier or channel.
Since proteins are composed of amino acids with distinct R groups and folding patterns,
it is safe to assume that these transport proteins will be chemically picky about the
types of molecules that use them.
Carrier proteins are integral glycoproteins that bind with specific solutes and undergo
a physical conformational change to move the molecule across the membrane.
In contrast, channel proteins are lipoproteins that have a pore (which is sometimes gated)
allowing specific ions to cross.
Membranes may become polarized from the movement of ions.
When water moves in larger quantities, it passes through a channel protein known as
aquaporins.
In general, channel proteins have a much greater rate of transport than carrier proteins.
Small polar molecules like water can also pass through the membrane, but in smaller
amounts.
This is known as osmosis, the passive diffusion of water.
Same rules apply - water will flow from high concentration to low, down its own water concentration
gradient without the input of ATP.
The prefixes hyper and hypo refer to the relative amount of dissolved solutes in a solution.
Areas that have a greater concentration of solutes are hypertonic compared to areas with
a lesser concentration of solutes.
Since hypertonic solutions have more solutes, they have a lower water concentration and
a lower water potential.
Assuming that two solutions are separated by a semipermeable membrane, water will flow
from a hypotonic solution, an area of high water potential to a hypertonic solution,
an area of low water potential.
This movement will continue until the water concentrations on either side of the membrane
are equal, or isotonic.
Water is still moving between the isotonic areas, but at an equal rate and in both directions.
But be careful - equal concentrations does not mean equal amounts.
This means that water will enter or exit a cell whether there is room for the water volume
or not, which could result in cytolysis.
Vacuoles, both contractile and storage, are cellular organelles which contribute to osmoregulation.
Water potential calculations allow us to predict the movement of water, due to osmosis, pressure,
surface tension, or gravity.
If you’re struggling with water potential problems and applications, you’ll want to
check out the Unit 2 practice video where I do a complete deep dive with step by step
explanations.
You can access the unit 2 practice video and the water potential practice sheet with the
answer key in the Ultimate Review Packet linked below.
Last topic for Unit 2!
The cell is the most basic unit of life, which for some multicellular organisms become highly
specialized and combine to form tissues, organs, and organ systems.
Prokaryotes are smaller, evolved earlier, do not contain a nucleus or membrane bound
organelles and organize their DNA in a circular loop.
Eukaryotes are larger, evolved approximately 2.7 billion years ago, have a nucleus and
membrane bound organelles and organize their DNA linearly in multiple chromosomes.
Both cell types have ribosomes, DNA, cytoplasm and a plasma membrane.
Prokaryotes include bacteria and archaea while eukaryotes include protists, fungi, plants
and animals.
To Recap Cells make life possible and more efficient
by separating processes and compartmentalizing functions with membranes.
Some organelles integrate seamlessly through the endomembrane system while others stand
alone.
However all organelles have unique structures for specific functions and utilize a large
surface area to volume ratio.
And finally, membrane chemistry controls the rate and exchange of materials by active and
passive transport so that homeostasis is maintained.
And thats it!
Well that's the main concepts you need to know for Unit 2, but definitely not the end.
It’s time for you to practice applying this information!
If you’ve finished the Unit 2 study guide for this video then definitely check your
responses with my answer key in the Ultimate Review Packet.
Then, you’ll want to take the Unit 2 practice multiple choice questions.
You’ll get instant feedback on your answers with an explanation for why the answers are
correct and why the other choices weren’t.
The Ultimate Review packet also has unit specific skills videos, practice sheets, and a full
length practice exam that you can take once you’ve finished the entire course.
So what are you waiting for?
Grab your copy of the AP Biology Ultimate Review packet now so you can do your APsolute
Best on the exam in May.
Thank you so much for watching and supporting my content - Please make sure to subscribe
to my youtube channel, like those videos, and tell your friends about the Ultimate Review
Packet.
I”ll see you next recap for Unit 3: Cellular Energetics.
Ver Más Videos Relacionados
AP Bio Speed Review - ALL 8 Units in Under 15 Minutes!
All of BIOLOGY PAPER 1 in 20 mins - GCSE Science Revision Mindmap 9-1 AQA
Active vs. Passive Transport: Compare and Contrast
CORSO DI BIOLOGIA - Lezione 03 - La Cellula
STRUKTUR DAN FUNGSI SEL - BIOLOGI KELAS 11 SMA
AP Biology Unit 2 Review: Cell Structure and Function
5.0 / 5 (0 votes)