transport and bacterial cells uptake of nutrients and key molecules microbiology 2008
TRANSCRIPT
Transport and Bacterial CellsUptake of Nutrients and Key
molecules
Transport and Bacterial CellsUptake of Nutrients and Key
molecules
Microbiology 2008Microbiology 2008
What molecules are needed by the cell
What molecules are needed by the cell
• Carbon source( CO2, CH4, organic molecules)
• Nitrogen source( nitrogen compounds) amino acids , ammonia or ammonium
• Energy source
• Carbon source( CO2, CH4, organic molecules)
• Nitrogen source( nitrogen compounds) amino acids , ammonia or ammonium
• Energy source
Passive TransportPassive Transport
• A few molecules that are small can pass through the phospholipid bilayer by the process of diffusion
• Passive transport does not require an energy input
• A few molecules that are small can pass through the phospholipid bilayer by the process of diffusion
• Passive transport does not require an energy input
Passive TransportPassive Transport
• The process of diffusion occurs when molecules or ions move from an area of greater concentration to an area of lower concentration
• The movement is down the concentration gradient
• The process of diffusion occurs when molecules or ions move from an area of greater concentration to an area of lower concentration
• The movement is down the concentration gradient
DiffusionDiffusion
• Slow process• Based upon the free energy of the
molecules themselves• Very small molecules such as O2 and
CO2 move in this manner
• Slow process• Based upon the free energy of the
molecules themselves• Very small molecules such as O2 and
CO2 move in this manner
Rate of diffusionRate of diffusion
• The rate of diffusion is determined by the difference in concentration of the nutrients or molecules on the outside and the inside of the membrane
• The rate of diffusion is determined by the difference in concentration of the nutrients or molecules on the outside and the inside of the membrane
OsmosisOsmosis
• The movement of water from an area of higher concentration to an area of lower concentration
• The movement of water from an area of higher concentration to an area of lower concentration
ConcentrationConcentration
• The amount of solute dissolved in an ml or Liter( known volume) of solvent
• Can be measured in moles per 1000 g solvent( water) which is referred to as molality(m)
• Can be measured in % solute/solution• Can be measured in Molarity – moles per liter
of solution( M)
• The amount of solute dissolved in an ml or Liter( known volume) of solvent
• Can be measured in moles per 1000 g solvent( water) which is referred to as molality(m)
• Can be measured in % solute/solution• Can be measured in Molarity – moles per liter
of solution( M)
Water PotentialWater Potential
• Higher potential energy of water• Higher concentration of water
molecules that have free energy of movement
• Higher potential energy of water• Higher concentration of water
molecules that have free energy of movement
Osmosis and cell- membranes- comparative terms
Osmosis and cell- membranes- comparative terms
• Hypertonic – refers to an environment with higher salt concentration and lower water potential
• Hypotonic – higher water concentration( water potential) and lower soluteIsotonic – equal concentration of solute on
both sides of a membrane
• Hypertonic – refers to an environment with higher salt concentration and lower water potential
• Hypotonic – higher water concentration( water potential) and lower soluteIsotonic – equal concentration of solute on
both sides of a membrane
Plasmolysis and RecoveryPlasmolysis and Recovery
• Lysis of cell wall• Lysis of cell wall
Animations for classroom Animations for classroom
• http://www.wiley.com/legacy/college/boyer/0470003790/animations/membrane_transport/membrane_transport.htm
• http://www.wiley.com/legacy/college/boyer/0470003790/animations/membrane_transport/membrane_transport.htm
Membrane Proteins and Transport
Membrane Proteins and Transport
Channels- moves one molecule in one direction across the membrane
without the expenditure of energy
Channels- moves one molecule in one direction across the membrane
without the expenditure of energy
• Ions and larger molecules can also diffuse• Many of these move through proteins that
have a hydrophilic interior or core• They move from high concentration to an area
of lower concentration• No energy is utilized• Channels are specific for just one ion or
molecule
• Ions and larger molecules can also diffuse• Many of these move through proteins that
have a hydrophilic interior or core• They move from high concentration to an area
of lower concentration• No energy is utilized• Channels are specific for just one ion or
molecule
ChannelsChannels
• http://www.cellsalive.com/channels.htm• http://www.cellsalive.com/channels.htm
MembraneMembrane
Facilitated diffusionFacilitated diffusion
• Facilitated diffusion is a type of diffusion which uses a transport molecule .
• Permease are proteins which are embedded in the cell membrane
• They assist in the movement of other molecules across the membrane
• This is a speedier process than regular diffusion, but again is highly specific
• No energy is spent in the process
• Facilitated diffusion is a type of diffusion which uses a transport molecule .
• Permease are proteins which are embedded in the cell membrane
• They assist in the movement of other molecules across the membrane
• This is a speedier process than regular diffusion, but again is highly specific
• No energy is spent in the process
Facilitated DiffusionFacilitated Diffusion
AquaporinsAquaporins
• A major permease in bacteria is an aquaporin that helps to move water in and out of the cell
• A major permease in bacteria is an aquaporin that helps to move water in and out of the cell
MIPs - Major Intrinisic proteins
MIPs - Major Intrinisic proteins
• Group of proteins- They facilitate transport by changining their shape or conformation when they pick up the molecule
• When they move the molecule to the opposite side of the membrane they again change their shape upon release of the molecule they have transported
• Group of proteins- They facilitate transport by changining their shape or conformation when they pick up the molecule
• When they move the molecule to the opposite side of the membrane they again change their shape upon release of the molecule they have transported
Active Transporthttp://staff.jccc.net/PDECELL/cells/activet.html
Active Transporthttp://staff.jccc.net/PDECELL/cells/activet.html
• Transport of molecules and ions against the concentration gradient from low concentration to high concentration
• Requires the input of energy in the form of ATP
• ATP ADP + P + energy
• Transport of molecules and ions against the concentration gradient from low concentration to high concentration
• Requires the input of energy in the form of ATP
• ATP ADP + P + energy
ATP Binding Cassette Transporters( ABC
Transporters)
ATP Binding Cassette Transporters( ABC
Transporters)
• Transporters are proteins that span the membrane
• They bind to the ATP and hydrolyze or break down ATP to produce energy
• Transporters are proteins that span the membrane
• They bind to the ATP and hydrolyze or break down ATP to produce energy
SymportsSymports
• Move two molecules or a molecule and an ion in the same direction
• Both can move in the same direction• Usually one moves with the concentration
gradient• The other is pulled across the membrane
against the concentration gradient by the free energy of the molecules that are moving
• Move two molecules or a molecule and an ion in the same direction
• Both can move in the same direction• Usually one moves with the concentration
gradient• The other is pulled across the membrane
against the concentration gradient by the free energy of the molecules that are moving
AntiportsAntiports
• Two molecules are moving across the membrane
• One molecule is moving against the concentration gradient in one direction
• The other is moving with the concentration gradient
• Two molecules are moving across the membrane
• One molecule is moving against the concentration gradient in one direction
• The other is moving with the concentration gradient
SiderophoresSiderophores
• Iron is a very important nutritional ion for the bacterial cell
• Siderophores are small molecules that are able to form a complex with iron to bring it into the cell
• Iron is a very important nutritional ion for the bacterial cell
• Siderophores are small molecules that are able to form a complex with iron to bring it into the cell
PorinsPorins
• Porins are proteins located in the outer cell membranes ( the outer lipid membane)
• They are responsible for moving molecules through the outer membrane in Gram negative bacteria
• Molecules are moved into the periplasmic space and then into the cell
• Porins are proteins located in the outer cell membranes ( the outer lipid membane)
• They are responsible for moving molecules through the outer membrane in Gram negative bacteria
• Molecules are moved into the periplasmic space and then into the cell
Group Translocation Group Translocation
• In this process the molecules are modified as they are transported across the cell membrane or into the cell
• Group Translocation is a type of active transport
• Many vital molecules are brought into the cell in this manner
• In this process the molecules are modified as they are transported across the cell membrane or into the cell
• Group Translocation is a type of active transport
• Many vital molecules are brought into the cell in this manner
Group Translocation Group Translocation
• Group Translocation involves the transfer of a phosphate group
• This energizes the molecule so that it can be transported into the cell
• Group Translocation involves the transfer of a phosphate group
• This energizes the molecule so that it can be transported into the cell
Protein Transport Systems in the Cell Membrane
Protein Transport Systems in the Cell Membrane