Post on 12-Jan-2016
William Terzaghi
Spring 2014
Bio 398: Topics in Plant Biology
COURSE OVERVIEW1) Understanding how plants work.2) Understanding how plant biologists work.
• Method• Technology
COURSE OVERVIEW1) Understanding how plants work.2) Understanding how plant biologists work.
• Method• Technology
http://www.nature.com/nature/journal/vaop/ncurrent/full/nature12914.html
COURSE OVERVIEW1) Understanding how plants work.2) Understanding how plant biologists work.
• Method• Technology
http://www.nature.com/nature/journal/vaop/ncurrent/full/nature12914.htmlhttp://www.cbc.ca/news/technology/older-trees-grow-faster-than-
younger-ones-study-finds-1.2499298
Plan CWe will pick a problem in plant biology and see where it takes us.1.Biofuels 2.Climate/CO2 change3.Stress responses/stress avoidance• Structural• Biochemical (including C3 vs C4 vs CAM)• Other (dormancy, carnivory, etc)
4.Plant products• Defense compounds
5.Improving food production• Breeding: new traits to pick & ways to find them• GMO• New crops
6.Biotechnology7.Phytoremediation 8.Plant movements9.Plant signaling (including neurobiology)
Plan C
1.Pick a problem
Plan C
1.Pick a problem2.Pick some plants to study
Plan C
1.Pick a problem2.Pick some plants to study3.Design some experiments
Plan C
1.Pick a problem2.Pick some plants to study3.Design some experiments4.See where they lead us
Plan C
1.Pick a problem2.Pick some plants to study3.Design some experiments4.See where they lead us
Grading?Combination of papers and presentations
Plan C
1.Pick a problem2.Pick some plants to study3.Design some experiments4.See where they lead us
Grading?Combination of papers and presentationsScavenger hunts?
Plan CGrading?
Combination of papers and presentations•First presentation:10 points •Research presentation: 10 points •Final presentation: 15 points •Assignments: 5 points each•Poster: 10 points•Intermediate report 10 points•Final report: 30 points•Scavenger hunts?
BIO 398- Resource and Policy Information
Instructor: Dr. William TerzaghiOffice: SLC 363/CSC228Office hours: MWF 12-1 in CSC228, T 1-2 in SLC 363, Thurs 1-2 in CSC228, or by appointmentPhone: (570) 408-4762Email: terzaghi@wilkes.edu
BIO 398 - Resource and Policy Information
Instructor: Dr. William TerzaghiOffice: SLC 363/CSC228Office hours: MWF 12-1 in CSC228, T 1-2 in SLC 363, Thurs 1-2 in CSC228, or by appointmentPhone: (570) 408-4762Email: terzaghi@wilkes.edu
Course webpage: http://staffweb.wilkes.edu/william.terzaghi/bio398.html
Vegetative Plants3 Parts
1. Leaf2. Stem3. Root
Vegetative Plants3 tissue types
1. Dermal2. Ground3. Vascular
Plant Development• Cell division = growth
Plant Development• Cell division = growth• Determination = what cell can become
Plant Development• Cell division = growth• Determination = what cell can become• Differentiation = cells become specific types
Plant Development• Cell division = growth• Determination = what cell can become• Differentiation = cells become specific types• Pattern formation: developing specific structures in
specific locations
Plant Development• Cell division = growth• Determination = what cell can become• Differentiation = cells become specific types• Pattern formation• Morphogenesis: organization into tissues & organs
Plant Developmentumbrella term for many processes• embryogenesis
Plant Development
umbrella term for many processes• Embryogenesis• Seed dormancy and germination
Plant Development
umbrella term for many processes• Embryogenesis• Seed dormancy and germination• Seedling Morphogenesis
Plant Developmentumbrella term for many processes• Embryogenesis• Seed dormancy and germination• Seedling Morphogenesis• Transition to flowering, fruit and seed formation
Plant Developmentumbrella term for many processes• Embryogenesis• Seed dormancy and germination• Seedling Morphogenesis• Transition to flowering, fruit and seed formation Many responses to environment
Plant DevelopmentUmbrella term for many processesUnique features of plant development• Cell walls: cells can’t move: Must grow towards/away from signals
Plant DevelopmentUmbrella term for many processesUnique features of plant development• Cell walls: cells can’t move: must grow instead• Plasticity: plants develop in response to environment
Unique features of plant development• Cell walls: cells can’t move• Plasticity: plants develop in response to environment• Totipotency: most plant cells can form an entire new
plant given the correct signals
Unique features of plant development• Cell walls: cells can’t move• Plasticity: plants develop in response to environment• Totipotency: most plant cells can form an entire new
plant given the correct signals• Meristems: plants have perpetually embryonic regions,
and can form new ones
Unique features of plant development• Cell walls: cells can’t move• Plasticity: plants develop in response to environment• Totipotency: most plant cells can form an entire new
plant given the correct signals• Meristems: plants have perpetually embryonic regions,
and can form new ones• No germ line!
Unique features of plant development• Meristems: plants have perpetually embryonic regions,
and can form new ones• No germ line! Cells at apical meristem become flowers: allows Lamarckian evolution!
Unique features of plant development• Meristems: plants have perpetually embryonic regions,
and can form new ones• No germ line! Cells at apical meristem become flowers: allows Lamarckian evolution!• Different parts of the same 2000 year old tree have
different DNA & form different gametes
Plant Cell Theory
1) All organisms are composed of one or more cells
Plant Cell Theory
1) All organisms are composed of one or more cells
2) Cell is smallest living organizational unit
Plant Cell Theory
1) All organisms are composed of one or more cells
2) Cell is smallest living organizational unit
3) Cells arise by division of preexisting cells
Plant Cells1) Highly complex and organized
Plant Cells1) Highly complex and organized
2) Metabolism
Plant Cells1) Highly complex and organized
2) Metabolism
3) Reproduction
Plant Cells1) Highly complex and organized
2) Metabolism
3) Reproduction
4) Heredity
Plant Cells1) Highly complex and organized
2) Metabolism
3) Reproduction
4) Heredity
5) Mechanically active
Plant Cells1) Highly complex and organized
2) Metabolism
3) Reproduction
4) Heredity
5) Mechanically active
6) Respond to stimuli
Plant Cells1) Highly complex and organized
2) Metabolism
3) Reproduction
4) Heredity
5) Mechanically active
6) Respond to stimuli
7) Homeostasis
Plant Cells1) Highly complex and organized
2) Metabolism
3) Reproduction
4) Heredity
5) Mechanically active
6) Respond to stimuli
7) Homeostasis
8) Very small
Why are cells so small?1) many things move inside cells by diffusion
Why are cells so small?1) many things move inside cells by diffusion2)surface/volume ratio
Why are cells so small?1) many things move inside cells by diffusion2) surface/volume ratio
• surface area increases more slowly than volume
Why are cells so small?1) many things move inside cells by diffusion2) surface/volume ratio
• surface area increases more slowly than volume• exchange occurs only at surface• eventually have insufficient exchange for survival
Plant Cells1) Cell walls
• Carbohydrate barriersurrounding cell
Plant Cells1) Cell walls
•Carbohydrate barriersurrounding cell•Protects & gives cell shape
Plant Cells1) Cell walls
• Carbohydrate barriersurrounding cell• Protects & gives cell shape• 1˚ wall made first
• mainly cellulose
Plant Cells1) Cell walls
• Carbohydrate barriersurrounding cell• Protects & gives cell shape• 1˚ wall made first
• mainly cellulose• Can stretch!
Plant Cells1) Cell walls
• Carbohydrate barriersurrounding cell• Protects & gives cell shape• 1˚ wall made first
• mainly cellulose• Can stretch!
• 2˚ wall made after growth stops
Plant Cells1) Cell walls
• Carbohydrate barriersurrounding cell• Protects & gives cell shape• 1˚ wall made first
• mainly cellulose• Can stretch!
• 2˚ wall made after growth stops
• Lignins make it tough
Plant Cells1) Cell walls
• Carbohydrate barriersurrounding cell• Protects & gives cell shape• 1˚ wall made first
• mainly cellulose• Can stretch!
• 2˚ wall made after growth stops
• Lignins make it tough• Problem for "cellulosic Ethanol" from whole plants
Plant Cells1) Cell walls
• 1˚ wall made first• 2˚ wall made after growth stops
• Lignins make it tough• Problem for "cellulosic Ethanol" from whole plants
• Middle lamella = space between 2 cells
Plant Cells1) Cell walls
• 1˚ wall made first• 2˚ wall made after growth stops• Middle lamella = space between 2 cells• Plasmodesmata = gaps in walls that link cells
Plant Cells• Plasmodesmata = gaps in walls that link cells
• Lined with plasma membrane
Plant Cells• Plasmodesmata = gaps in walls that link cells
• Lined with plasma membrane• Desmotubule joins ER of both cells
Plant Cells• Plasmodesmata = gaps in walls that link cells
• Lined with plasma membrane• Desmotubule joins ER of both cells• Exclude objects > 1000 Dalton, yet viruses move through them!
Types of Organelles1) Endomembrane System2) Putative endosymbionts
Endomembrane systemCommon features
• derived from ER
Endomembrane systemCommon features• derived from ER• transport is in vesicles
Endomembrane systemCommon features• derived from ER• transport is in vesicles• proteins & lipids are glycosylated
Endomembrane systemOrganelles derived from the ER1) ER2) Golgi3) Vacuoles 4) PlasmaMembrane5) Nuclear Envelope6) Endosome7) Oleosomes
ERNetwork of membranes t/out cell2 types: SER & RER
SERtubules that lack ribosomesfns:1) Lipid syn2) Steroid syn3) drug detox4) storing Ca2+
5) Glycogen catabolism
RERFlattened membranes studded with ribosomes1˚ fn = protein synthesis -> ribosomes are making proteins
ERSER & RER make new membrane!
GOLGI COMPLEXFlattened stacks of membranes made from ER
GOLGI COMPLEXIndividual, flattened stacks of membranes made from ERFn: “post office”:collect ER products, process & deliver themAltered in each stack
GOLGI COMPLEXIndividual, flattened stacks of membranes made from ERFn: “post office”:collect ER products, process & deliver themAltered in each stackMakes most cell wall carbohydrates!
GOLGI COMPLEXIndividual, flattened stacks of membranes made from ERFn: “post office”:collect ER products, process & deliver themAltered in each stackMakes most cell wall carbohydrates!Protein’s address isbuilt in
VACUOLESDerived from Golgi; Fns: 1)digestion
a) Organellesb) food particles
VACUOLESDerived from Golgi; Fns:1)digestion
a) Organellesb) food particles
2) storage
VACUOLESDerived from Golgi; Fns:1) digestion
a) Organellesb) food particles
2) storage3) turgor: push plasma membrane against cell wall
VACUOLESVacuoles are subdivided: lytic vacuoles are distinctfrom storage vacuoles!
Endomembrane systemOrganelles derived from the ER1) ER2) Golgi3) Vacuoles 4) PlasmaMembraneRegulates transport in/out of cell
Endomembrane systemOrganelles derived from the ER1) ER2) Golgi3) Vacuoles 4) PlasmaMembraneRegulates transport in/out of cellLipids formbarrierProteins transportobjects & info
Endomembrane System5) Nuclear envelope: regulates transport in/out of nucleusContinuous with ER
Endomembrane System5) Nuclear envelope:regulates transport in/out of nucleusContinuous with ERTransport is only through nuclear pores
Endomembrane System5) Nuclear envelope:regulates transport in/out of nucleusContinuous with ERTransport is only through nuclear poresNeed correct signal& receptor for import
Endomembrane System5) Nuclear envelope: regulates transport in/out of nucleusContinuous with ERTransport is only through nuclear poresNeed correct signal& receptor for import new one for export
Endomembrane SystemNucleus: spherical organelle bounded by 2 membranes and filled with chromatin = mix of DNA and protein
Endomembrane SystemNucleus: spherical organelle bounded by 2 membranes and filled with chromatin fns = information storage & retrievalRibosome assembly (in nucleolus)
Endomembrane SystemEndosomes: vesicles derived from Golgi or Plasma membraneFn: sorting materials & recycling receptors
Endomembrane SystemOleosomes: oil storage bodies derived from SERSurrounded by lipid monolayer!
Endomembrane SystemOleosomes: oil storage bodies derived from SERSurrounded by lipid monolayer!
• filled with lipids: no internal hydrophobic effect!