Foundations - Cells, organelles and cell boundaries
- 1 Introduction
- 2 About Human Body
- 3 Cell Sizes
- 4 Divisions of Life
- 5 Unicellular and Multicellular
- 6 Prokaryote
- 7 Prokaryotes Cell Wall
- 8 Prokaryote Mycoplasmas
- 9 Virus
- 10 Prion
- 11 Biological Levels
- 12 Eukaryotic Cell Organelles
- 13 Plasma Membrane Images
- 14 Compartments
- 15 Major Cellular Compartments
- 16 Compartments are Dynamic
- 17 Nuclear Compartment
- 18 Cytoplasmic Compartment
- 19 Membrane Functions
- 20 Membrane Components
- 21 Phospholipids
- 22 Membranes History
- 23 Membrane Proteins
- 24 Membrane Glycoproteins
- 25 Membrane Cholesterol
- 26 Bacterial Membranes
- 27 Membrane Fluidity
- 28 Membrane Specializations
- 29 Adhesion Specializations
- 30 Membrane Transport
- 31 Ion Channels
- 32 Some Membrane Issues
- 33 Background Textbook References
2012 Lecture Slides: 14 pages PDF
The 2 major classes of cells are defined by the presence or absence of a nucleus; Eukaryotic (with nucleus) and Prokaryotic (without nucleus).
Eukaryotes can be further divided into unicellular (only one cell, like prokaryotes) and multicellular (like us) organisms.
A major difference between eukayotes and prokaryotes is the presence of physical compartments (membrane bound) and organelles within the cell. These compartments allow the separation/specialization of processes within the cell. There also exist within each of these physical compartments, functional compartments where specific processes may occur or are restricted.
This lecture is also an introduction to cell compartments and describes the structure of membranes forming these compartments.
About Human Body
- 210+ cell types in body
- total number of estimated cells in the body - 1013 (American Ten trillion/British Ten billion)
- bacteria, fungi and archaea
- found on all surfaces exposed to the environment
- skin and eyes, in the mouth, nose, small intestine
- most bacteria live in the large intestine
- 500 to 1000 species of bacteria live in the human gut
- total number of estimated flora ten times as many bacteria 1014 (American One hundred trillion/British One hundred billion)
- Robert Hooke (1635-1703) - used early microscopes to view cork tree bark, first to use the term CELL.
- Robert Brown 1825 - identified nuclei in plant cells.
- Theodor Schwann (1810 - 1882) - together with Matthias Schleiden (plants) developed the cell theory in 1839
- All organisms consist of one or more cells.
- The cell is the basic unit of structure for all cells.
- All cells arise only from preexisting cells.
Divisions of Life
- bacteria and archaea (single-celled microorganisms previously called archaebacteria)
- no cell nucleus or any other organelles within their cells
- organisms that can live in extreme habitats Archaea
- cell nucleus
- plants, animals, fungi, protists
Unicellular and Multicellular
- All prokaryotes and some eukaryotes
- Yeast + budding, non-budding
- Protozoa + classified by means of locomotion: flagellates, amoeboids, sporozoans, ciliates + often "feed" on bacteria
- All prokaryotes and some eukaryotes
- Plants and Animals
- Allowed development of specialized cells
- functions and tissues
Micrococcus luteus bacteria
Bacteria shape (morphology)
- evolutionarily arose first (3.5 billion years ago) Evolution of Cells
- bacteria are smaller, approx 2 x 1 micron (1x10-6 m)
- not all bacteria are dangerous or disease causing
- The adult human in addition bacteria to the skin surface and lining of the respiratory/digestive tract, also has intestines contains trillions of bacteria made up from hundreds of species and thousands of subspecies)
- biochemically diverse
- simple structure, classified by shape (rod-shaped, spherical or spiral-shaped)
- some prokaryotic cells have also been shown to have a "cytoskeleton", which is different from eukaryotic cells.
- some bacteria are highly motile Movie - Lyme Spirochete moving back and forth along a platelet. Time-lapse (16x normal) phase-contrast videomicroscopy
(Greek, Karyose = kernel, as in a kernel of grain)
Prokaryotes Cell Wall
- Bacterial Shape - Bacterial shapes and cell-surface structures
- Bacterial Membranes - A small section of the double membrane of an E. coli bacterium
- Bacterial outer membranes - outer membrane contains porins
- Bacterial cell walls - Bacterial cell walls
- Gram-negative bacteria surrounded by a thin cell wall beneath the outer membrane
- Gram-positive bacteria lack outer membranes and have thick cell walls
(MH - note that some unicellular eukaryotes can also have a cell wall)
- Antibiotics - inhibit either bacterial protein synthesis or bacterial cell wall synthesis Antibiotic targets Gram-positive and Gram-negative bacteria
- Bacterial Replication - DNA replication and cell division in a prokaryote MCB - DNA replication and cell division in a prokaryote
- Molecular Biology of the Cell
- Medical Microbiology
- smallest self-replicating organisms
- smallest genomes (approx 500 to 1000 genes)
- spherical to filamentous cells
- no cell walls
- surface parasites of the human respiratory and urogenital tracts
- Mycoplasma pneumoniae infect the upper and lower respiratory tract
- Mycoplasma genitalium a prevalent sexually transmitted infection
- Mycoplasma hyorhinis found in patients with AIDS
Prokaryotic and Eukaryotic Cells
The following links describe the major differences between prokaryotic and eukaryotic cells, the way they divide and the way in which antibiotics have their action on prokaryotic cells.
- The Cell- A Molecular Approach | Table 1.1. Prokaryotic and Eukaryotic Cells | Antibiotic Inhibitors of Protein Synthesis
- Molecular Cell Biology Figure 12-6. DNA replication and cell division in a prokaryote
- Biochemistry Figure 28.15. Transcription and Translation two processes are closely coupled in prokaryotes, whereas they are spacially and temporally separate in eukaryotes.
- Virion - virus particle, the infective agent, contains the genetic material, DNA or RNA within a protective protein coat (capsid)
- Bacteriophage - A virus that infects bacteria
- Links: MCB - Viruses: Structure, Function, and Uses | MCB - Retroviral life cycle | NPR - Virus Infection
- no compartments, no membrane
- an infectious prion protein
- not alive
- misfolded normal protein (three-dimensional structure)
- can form aggregates
- Creutzfeldt-Jacob disease (CJD) and Kuru a human neural prion disease
- Bovine spongiform encephalopathyvery (BSE) in cattle, "mad cow disease"
- Scrapie in sheep
- Molecular Biology of the Cell Figure 6-89. Protein aggregates that cause human disease | Prions Are Infectious Proteins
- Gene Reviews Prions
- Neuroscience Prion Disease
Cells can be "broken down" into smaller and smaller constituent "parts"
- Whole cell
- nucleus, mitochondria,
- Biological polymers
- chains of molecules
- consisting of monomer subunits
- DNA, RNA, Protein, sugars, cellulose
- Organic molecules
- monomer subunits
- nucleotides, amino acids, carbohydrate
Eukaryotic Cell Organelles
- Fundamental concept - all cells
- Specialized exceptions
- specialized part of a cell that has its own particular function
- Membrane bound (enclosed)
- forms "compartments" within the cell
Plasma Membrane Images
The cell membrane (plasma membrane or plasmalemma) encloses or covers all cell types and is 7 nanometers thick (1000 times smaller than the RBC). Begin by some different ways of looking microscopically at membranes.
Scanning Electron Micrograph
Transmission Electron Micrograph
Major Cellular Compartments
- Nucleus (nuclear) - contains a single organelle compartment
- Cytoplasm (cytoplasmic) - contains many organelle compartments
- How many organelles?
- How much space within the cell do they occupy?
- Are all the cells the same?
Take a typical mammalian liver cell....
Compartments are Dynamic
Movies showing flexibility of membranes and their changing shape and size.
- Nuclear matrix - consisting of Intermediate filaments (lamins)
- Nucleoli (functional compartment - localised transcription DNA of RNA genes)
- Chromosomes (DNA and associated proteins)
(MH - you will not see chromosomes in interphase nuclei only during mitosis)
- Cytoplasmic Organelles
- Membrane bound structures
- Endoplasmic reticulum, golgi apparatus, mitochondria, lysosomes, peroxisomes, vesicles
- 3 filament systems
- Cytoplasmic “structures”
- DNA -> mRNA -> Protein
- Receptors, signaling, metabolism, structural
- Viruses, bacteria, prionsl
- Functional compartments
- occur in nucleus, cytoplasm, in organelles and outside organelles
- signaling, metabolic reactions, processing genetic information, cytoskeleton dynamics, vesicle dynamics
|Cell membrane (Plasma membrane , plasmalemma) encloses or covers all cell types.
- phospholipids, proteins and cholesterol
- first compartment formed
- prokaryotes (bacteria) just this 1 compartment
- eukaryotic cells many different compartments
- membranes contain phospholipids, glycolipids, and steroids
- The main lipid components include: phosphatidylcholine (~50%), phosphatidylethanolamine (~10%), phosphatidylserine (~15%), sphingolipids (~10%),cholesterol (~10%), phosphatidylinositol (1%).
- A liposome (lipid vesicle) is a small aqueous compartment surrounded by a lipid bilayer.
- A micelle is a small compartment surrounded by a single lipid layer.
(Background only, you do not need to know the details)
- 1890 Charles Overton - selective permeation of membranes, non-polar pass through (lipid soluble), polar refractory
- 1905 Irving Langmuir - lipids faced with heads towards water away from organic solvents
- 1925 Gorter and Grendel - monolayer of lipid isolated from rbc
- 1930-40 Danielle-Davson - Proteins coat a bilayer with polar “pores”
- 1960s Robertson - Modification with glycoprotein on one side, therefore asymmetric
- 1972 Singer and Nicholson - proteins “floating” within lipid bilayer like a “liquid” surface
- 1975 Unwin and Henderson - integral membrane proteins, glycoprotein carbohydrate groups on outer surface
- 1997 Simons - cholesterol to form "rafts" that move within the fluid bilayer PMID 9177342
- 20-30% of the genome encodes membrane proteins PMID 9568909
- Proteins can be embedded in the inner phospholipid layer, outer phospholipid layer or span both layers
- Some proteins are folded such that they span the membrane in a series of “loops”
Two major protein transmembrane structures
- α-helical - ubiquitously distributed
- β-barrel - outer membranes of Gram-negative bacteria, chloroplasts, and mitochondria
Membrane Protein Functions
- transport channels
- enzyme reactions
- cytoskeleton link
- cell adhesion
- cell identity
- Glycoproteins are proteins which have carbohydrate groups (sugars) attached
- to produce these proteins go through a very specific cellular pathway of organelles (secretory pathway)
- to reach the cell surface where they are either secreted (form part of the extracellular matrix)
- or are embedded in the membrane with the carbohydrate grouped on the outside surface (integral membrane protein)
- Small molecule embedded between the phospholipid molecules and regulates lipid mobility (MH - see rafts)
- Cholesterol can be at different concentrations in different regions of plasma membrane
- lateral organization of membranes and free volume distribution
- may control membrane protein activity and "raft” formation
- fine tuning of membrane lipid composition, organization/dynamics, function
- bacterial membranes (except for Mycoplasma and some methylotrophic bacteria) have no sterols, they lack the enzymes required for sterol biosynthesis.
(Named after - Hans Christian Gram (1853–1938), a Danish scientist.)
- fusion of 2 cells
- membrane domains (polarized cells)
- epithelia - apical, basal and lateral domains
(cytonemes and tunneling nanotubes, TNTs) - New membrane structures identified that can facilitate transfer of cellular signals and components over large distances (hundreds of microns) representing the longest direct connections between cells in vitro and in vivo. File:Bronchial epithelial bridge.mov
- plasma membrane cytoskeleton
- different directly under membranes
- adhesion complexes
- absorbtive and secretory
- synaptic junctions
A series of different types of proteins and cytoskeleton associations forming different classes of adhesion junctions
- Desmosomes ( = macula adherens)
- Adherens Junctions ( = zonula adherens)
- Septate Junctions
- Tight Junctions
- Gap Junctions
Three major forms of transport across the membrane
- Passive - Simple diffusion
- Facilitated - transport proteins
- Active - transport proteins for nutrient uptake, secretion, ion balance
- membrane phospholipid impermeable to ions in aqueous solution
- protein channels permit rapid ion flux
- 1960’s structure and function, ionophores (simple ion channels)
- 75 + different ion channels, opening/closing, “gating” of ions
Ion Channel Types
- 3 rapid + 1 slow gate (gap junction)
- Voltage-gated - propogation of electrical signals along nerve, muscle
- Ligand-gated - opened by non-covalent, reversible binding of ligand between nerve cells, nerve-muscle, gland cells
- Mechanical-gated - regulated by mechanical deformation
- Gap junction - allow ions to flow between adjacent cells open/close in response to Ca2+ and protons
Some Membrane Issues
Cell Apoptosis - programmed cell death
- membrane "blebbing" encloses cellular component fragments
- do not stimulate inflammatory response, easy removal by macrophages.
Link: Time-lapse movie of human HeLa cells undergoing apoptosis | Example of early apoptotic blebbing | PMID 16129889 | PMID 18073771
Cystic Fibrosis - membrane transport disease
- 1989 Collins (US), Tsui and Riordan (Canada)
- Chloride channel - protein mutation point mutant, folded improperly, trapped and degraded in ER
Background Textbook References
- Molecular Biology of the Cell: Some Important Discoveries in the History of Light Microscopy | The evolution of higher animals and plants (Figure 1-38) | From Procaryotes to Eucaryotes | From Single Cells to Multicellular Organisms | Some of the different types of cells present in the vertebrate body | Chapter 10 - Membrane Structure | Three views of a cell membrane | The evolution of higher animals and plants (Figure 1-38) | From Procaryotes to Eucaryotes | From Single Cells to Multicellular Organisms | Some of the different types of cells present in the vertebrate body
- Molecular Cell Biology: The Dynamic Cell | The Architecture of Cells | Microscopy and Cell Architecture
Search Online Textbooks
- "prokaryote" Molecular Biology of the Cell | Molecular Cell Biology | The Cell- A molecular Approach
- "eukaryote" Molecular Biology of the Cell | Molecular Cell Biology | The Cell- A molecular Approach
- "cell compartments" Molecular Biology of the Cell | Molecular Cell Biology | The Cell- A molecular Approach
- "cell membrane" Molecular Biology of the Cell | Molecular Cell Biology | The Cell- A molecular Approach
Below are some example historical research finding related to cell membranes from the JCB Archive and other sources.
- 1957 The invention of freeze fracture EM and the determination of membrane structure Russell Steere introduces his home-made contraption for freeze fracture electron microscopy (EM), and Daniel Branton uses it to conclude that membranes are bilayers.
- 1971 Spectrin is peripheral S. Jonathan Singer, Garth Nicolson, and Vincent Marchesi use red cell ghosts to provide strong evidence for the existence of peripheral membrane proteins.
- 1992 Lipid raft idea is floated Gerrit van Meer and Kai Simons get the first hints of lipid rafts based on lipid sorting experiments.
"Sometimes you eat the bacteria and sometimes... well, he eats you"