Note Oct 15, 2024 9_12_26 AM - Cell Biology Notes PDF

Summary

This document provides detailed notes on various aspects of cell biology, encompassing topics like lysosomes, mitochondria, glycolysis, the electron transport chain, protein import, and cytoskeleton. It's an excellent resource for students studying cell biology at an undergraduate level.

Full Transcript

Lysosomes synagggmotaxis
optimum pH prawAtp
ATP
drivenH pumpcreates pH
degradeallmacromoleculestaken Ifmf ho matrix
cytosol
byendocytosis
Phagocytosis Autophagy atttifin assemorosslink

ÑEsbd
hjjipia.gg
gopoe cell actin
locomotion myosin
useclathrinindependent
particles
maturate fuse
whysosome
pathway
pg which
release binding stois stroke
power
Odorsanelles orcytosolisenclosed
byinternalmenprangaumo.name stuff
visualallmuscle
centrosome structures
Estense Time functionoftubulin
necea feetmovement
selfrenewalofcellularcomponents kinesin5 goalstructure
justdistinguishAnaphases

Mitochondria
2 membranes
inner outer verydistinctnotconnected
2 spaces
matrix intermembrane space

Inner membrane
1 has
Electrontransportsystem to make gradient across inner membrane
ATPsynthase FFo ATPase
Transporters to incorporatemetabolites AppfAF etc ItPi
2 Inner is full of proteins but not rigid
is flexible continuouslymovingdividing fusing
3 Inner needs large surface area to fold into Cristae
Matrix
4 inside of inner membrane contains enzymes for citricacid
cycle
replication
oxidation mitochondrialDNAribosome Ees growthdivision functions
Outer
5 has porin freepass forsmallmolecules aminoacidpyruvatefattyacid glyterol
Proteinscan't go out throughporin
 NADH
NAD is converted to NADH
During conversion 2 e Nbecomes neutral add acovalentbond
a NAPT seedNADH NADH in cytosolneed extra
energy
NADH is highenergy 60 energyyield

Glycolysis
In cytosol
Glucose 2 pyruvates
2 ATP
Produced per glucose
2 NADH

After Glycolysis
In mitochondrial matrix
Acetylgroupof Pyruvate is transferred to CoA to form Acetyl CoA
CitricAcidCyle oxidizes all carbonto CO2
8NADH 2 FADH 2GTP producedper one glucose

ElectronTransport Chain
Complex 1 recognizesNADH oxidizes it toNADT
transfersze from NADHto ubiquinone
pumps 4H into intermembrane space
Complex 2 recognizesFADH2 FADH
Doesn't pump H
Ubiquinone electron carrier transfers e to Complex3
Complex3 transfers é to CytochromeC oxygen é receiver
needed for process
pumps H into intermembrane space
4 tocontinue
CytochromeC passesté to complex 4
Complex 42 e is used to make 20
Pumps 4 H into intermembrane space

Redoxpotential NADH FADH2 Ubiquinone cytochromeC

oxidized energy 12H per NADH
reduced
energy hashydrogens 8H per FADH 2

Ubiquinone
double bonded Oxygens
become OH reduced
energy
Note Cytochrome C can only bind to 1 é
ATP Synthase
Convert electrochemical gradient of H into ATP
F Fo separate domains components connected
F is exposed to matrix Catalytic component of ATP
F has synthesis
3 units alternate to make spherical
3 Bunits structure
2 unit rotor stalk a stalk

Fo is embedded in membrane transmembrane H
Fo 10 14 subunits Cring carrier
 1 a subunit a ch ed or bunits
2lb subunits anchor stalk

CAB
holds stalls
β head

green parts are
fixed

cring is fixed but
slides relative to a
energy H gradient is converted to rotation of rotor
rotation causesstructuralchangeof protein
inside the vessel to perform chemicalreaction
rotorstalks rotate ATPsynthesis
qgsdnf

How it rotates
1 a subunit has 2 half channels for H
2 Each sub unit has a proton acceptorwhich receives
proton from a half channel
3 After accepting proton c ring slides by 1 subunit Then
next H comes through the half channel binds next
subunit
4 After 1 round of rotation H is transferred from
sub unit to another half channel that is open to the
opposite side of the membrane
Note 1 c ring has 12 c subunits
 happens onlywhen protongradient is large enough

How8 stalk makes ATP in F
8 stalk rotates w o ring
B 3 complex in F1 is fixedbystatorstalk b subunit so it
does not rotate with 8 stalk
As 8 stalk rotates in F1 ATPase 3 8 subunits change
conformation
drivenbygradient
209
Open low tight

Open conformation has affinity to ATP can exchange
ATP ADP usuallybindsADP 8
Tight conformation can bind only ATP never releaseit
Low conformation binds to ADP Pi but theycan'tescape
from the protein can'texchangeadpto atp
120 turn
O conformation releasesATPthenbinds ADP Pi
T conformation can convert ADP P 20ATP
120 turn
Every 120 turn 1 ATP is produced make
3ATP are produced per 1 complete turnthffon
ATP
Note 12 H are consumed perturn
ETCpumps 12HNADH 8H FAPH2
Booth

ATPsynthaseisreversible

f
Ér.citFao
1171g canhydrolyzeATPtoproduceH gradient
p byreversereactionofATPsynthesis
 Protein Import
majority of MTproteins are translatedby cytosolic ribosome
transported to MT after translation is done
N terminal 20 to 55 aa seauence presequence serves as a signal
for matrix inner membrane
4destinations
Matrix 4distinct destinations
Inner membrane have adistinctmechanisms
Intermembranespace membranes have own distincttransmembrane
Outermembrane protein channel translocators providechannel for
2 Translocators Polypeptide topassthrough
Outer membrane translocator TOM
Inner membrane translocator TIM

Protein Import steps
1 CytosolicHsp70 unfolds protein
2 TOM complex recognizes signal presequences
3 ATPhydrolysis by hsp70 pushesprotein in TOM
4TOM TIM interact
5 Negative charge attractsthe presequence
6 Some are released as inner membraneproteins
Presequence is cleaved MT Hsp70 pull the proteininto
7
matrix

8 ATPhydrolysis releaseof MTHsp70
NoteHSP 70 is required
binds pulls

MT Evolution Genome structure
 2Aerobicprokaryotemightbeengulfedtoearlyanaerobiceukaryote tobecome
1stmito
2ThensomeMTgenes weretransferred tonucleusduringevolutionofeukaryotes
usuallynot connected wcytoskeleton

Lipid delivered from ER toMTby protein
is
MT doesn't have ability to synthesize itsmembranelipid
phospholipids are synthesized in the ER carried to mito
by phospholipidtransfer proteinsnot by vesicular traffic
outermembrane inner membrane has small contact site where
ipid is exchanged
Ocassionally MT ER interact to transfer lipids

Peroxisome human cells 500 metabolicenzymes
Containoxidation detoxification enzymes some other
some fatty acid oxidation occurs in peroxisome
can replicateby division but doesn'tgrowby itself

Peroxisome Assembly derivedfrom ER butmoststatesizedoffoosomes
Sometransmembrane proteins ofperoxisomes are synthes ed
rough ER
NO Golgi involved
Internal proteins are synthesized on free ribosomes ther
imported by Pex proteins ATP dependent
peroxisome grows by fusion can divideinto 2
Notesomeproteins are embedded in peroxisome some are imported

cytoskeleton Chemotaxis
Protein Filaments mm
Actin Filament very thin plasma membrane
Microtubule Thickest 25mm

Intermediate Filament 10mm

Action Overview
Actin can exist as bundle or network no clear organizing
Actinfilament has polarity
shows dynamic assembly disassembly
involved w cell movement crawling of non flagellar cell
during mitosis Actin forms contractile ring
Biochemically distinct ends 7hm diameter
Plus minus ends
made by non covalent binding of globularproteins G actin
ATP required for actin to assembleinto filaments
canbind to ATP ADP made exclusivelyfromone d
ATP actin is active for filamentformation
 Assembly Disassembly of actin filaments
Plus minus end
ATP actin monomer assembles on filament mainly
at plus end
ATP ishydrolyzed in the filament ADP actin dissociates
from filament mainly from minus end
ADP minus
ATP plus

Bothassembly disassemblyarecrucialforactin functions
Inhibitionof eitherpolymerization ordepolymerization
uses quickstopof cellmovement
certainshapes
proteins
forcertain

Filament
Actin Binding Proteins controls the behavior of
ARP 2 3 binds to minus end iniatesbranch
Tropomyosin mediatesactinmyosin interaction
Formin bindstoplusend extendinggrowth
Cofilin disassembly 1 minusendintomonomers 2splitinto2piecesfromcenter
Profilin facilitatesexchangeforATP ADP
CrosslinkingProtein Ex Need to know
Villin Microvilli
Fimbrin Filopodia
Filamin Lamellipodia
X actin ContractileBundle
motorproteins
Myosin11 mainlymuscle Regulators
Myosin V I non muscle Troponins
Spectrin
Dystrophin
α actinin required for myosin sliding_activatement
regulatorforsomething
Rhofamilyproteins purposelocation recruitsformin
Integrin bind drag cell in movement ARP
talin helps α actinin bind
Cadherin

How cell crawls
1 ell extends protrusions at leadingedge
2 The protrusions adhere to the surface
3The rest of cell is draggedtowards adhesion point

1 a Two types of protrusions
1 Lamellipodia thin sheetlike protrusionwhichcontainsnetwork ofactin
filaments
Plusend of actin filamentis facingtotheleadingedge

2Filopodia thin stiff fingerlike protrusionwhichcontainsbundleofactinfilaments

210 ARP Complex CreatesBranch
1 Actin relatedproteins APR2 3 complexcan assembleat actin ATP
neargrowingend of filament

2 ARP2 3bothhavesimilarstructuretoactin

3 ARP binds toactinfilamentatfixedangle diniatesbranch
1C ActinNetwork at leadingedgepushes cell forward
ARPcontinuouslymakesbranches on preexistingfilament
Plusendsarecappedto preventpolymerization depolymerization
 some requency
Networkgrows towardstheleadingedgeto extendlamellipodium
Cross linking Proteins are involved in actinnetwork
bundle
1 Actinbundlingproteins Fimbrin maketightbundleof
actinfilament in filopodia
2 Otheractincrosslinking proteins filamin makes much
moreflexiblenetwork with randomlyrunningfilaments

Ld Molecular structures of bundling cross linkingproteins
1 Fimbrin bundling has 2
tightlyarranged actin binding
domains ABD
2 Cross
linking protein filamin is homodimer oflong
subunits
3 α actin headto tail dimer is abundlingprotein in
contractile bundle stress fiber muscle at 2 disk
Note actinimportant if you consider frm Hing
myosin required

1 eFormin iniates de novo filament formation
1 Formin can start filament formation from G actins
undercontrol of intracellular signaling via Rho GTP
2Whenactivated formin can assemble ATP actin monomer
into a filament
3 Formin can
stay at growing plus end of the filament
Basically assembles ATP actin monomers
actin attaches changes conformation more actin

1 FMicrovillihavebundledactin filaments
Intestinal epithelial cells have microvilli
surface for absorption
Interacting with myosin 1 on plasmamembrane that can
bend the vilus
 2 a Cellcrawl Cellattachment involves actin bundles
the contactsites
1 Integrins bind to the surface or extracellular matrix
2 Integrinsbundles actin filaments make anchor to
drag other part of cell stress fiber
Contact integrinactivation talin α activationbinding
stress fiber formation at adhesionpoint

3A Rest of cell is pulledby actin myosinsliding
myosin 1 muscle myosin actinin is required forpulling
myosin11 contracts bottom
myosin l shortenprotrusionbyslidingactin filament
edge
pushesittowardsleading
plusendsoverlappingmyosinmakesthe ringsmaller
extensionadhesionpulling prob3distinctmechanismsinto1 singlemotion

also
note

where to move
Attractant for neutrophils f MetLeuPhe
Local activation of Rho GEF
Local Production of Rho GTP
 recruits formin ARP
Formin starts actin filament ARP makes branch
Local lamellipodia formation
move towards the attractant

Rho Ras superfamily member
cytoskeleton cellularmovement

1 Rho GTP is associatedw membrane
2 Formin associate w Rho GTP
3 Formin iniates Actin Polymer

Association of actin filaments w plasma membrane
action other filaments from networks
underlyingplasma
membrane cell cortex
1 Determine tell shape
2 well demonstrated
by RBC studies
3 Shortactinfilament is anchored to plasmamembrane
with glycophorin
4 Actin filament is connected to spectrinfilament
spectrinishomologousto otheractinbinding proteins likedystrophin
majoraetoskeleton associatingproteinwhichbinds to actinring
majorityis underneath plasmamembrane

Duchenne Muscular Dystrophy X linkedrecessive
genedystrophin onXchromosome
Dystrophinanchorsactinfilamentw plasmamembraneofmuscletissue
 Adherensjunction adhesion belt
epithelialsheet is enforcedbyseveral cell celljunctions
1adhesionbeltcancontracttochangetheshapeofeachcell
2 actinfilamentoftheadhesionbelt is associatedwithcadherinthatconnects
adjacentcells adherensjunction

SkeletalMuscle motorproteins
Musclefiber is onelongmultinuclear cellcontainingbunch of miofiblils
Each myofibril cylindricalbundles of actin myosin I
1 Sarcomere is a 2.5 m unit of contraction
2 Myosin 1protein is made by 2 heavychains 2 2
lightchains
3 Heavy chains dimerized by coiled coil tail
4 Several 100s of myosin l proteins form a bipolar stack
5 Large bipolar filament of myosin 11 slide in actinfilaments
6 Heads of heavychain has ATPase domain that can bindattainment
7 ATPhydrolysis heads allows actin
by myosin sliding
a
what are these steps for

1 No ATPformstaysboundon actinfilament
2Binding to ATP causes dissociation ofhead from actinfilament
3 ATPhydrolysischanges conformation of neckboth
ADP phosphate arestill
boundto myosinhead
4 Head ADP binds to actinfilament releasephosphate
5 ADPisreleased neck bends powerstroke
6Headstays on actinfilament untilnextATPcomes
 cart
aceteichaineincreasescytosolic
a controlsactin myosin contact in skeletalt.ggigitt
1 Actinfilament in skeletalmuscle are associatedwithtropomyosin troponin
complex troponinC I T

2 W o castmyosinhead can't bindactin becausetropomyosin is
blocking
myosin binding site on actinfilament
3 Lastbindsto troponin changethestructure oftropomyosin sothat the
myosinbinding site is exposed for myosin
4 Because lastchanges rapidly myosinsliding occurs
very quicklyto generat
trongforce of contraction

smoothmusclecontraction
Lastactivates protein kinase
2 differences
Notraponins in smoothmuscle
actinfilament isready for contact withmyosin
myosincan'tmake bipolar filament w out stimulus Cart
nosarcomere in smoothmuscle
 ᵗ
Calmodulin a dependentmodulatorof proteinkinases
1 smoothmuscle Castbindscalmodulin
2 Lastcalmodulincomplexbinds activatesmyosinlightchainkinase phosphorylates

alightchain ofmyosin
3Thisphosphorylationchanges structure ofheavychains allowthemto make
oipolarfilament y
4 Bipolarfilament canslideon actinfilament
contractilering
celldivisionismediatedby

Contractile ring in Cytokinesis
1 Rho activation occurs in the mid cell at
elophase
formin
2 Actinfilament is assembledunderneaththe plasmamembrane by
3 Rhoalsoactivates myosinlight chain phosphorylation indirectly
4 Myosin11bipolar filamentcontracts the ring plasmamembrane is
pulledwiththering
myosin vs basics
Myosin I can move membrane vesicle
1 Myosin I has singlehead short tail monomer
2 Tail canbindmembrane
3Involved in somevesiculartraffic endocytosis of yeast
transporting organelles
4 Alsoinvolved in microvillimovement

MyosinV involved in membrane traffic organelle traffic in
neurons NoteMitority ofvesiculartraffic depends on microtubule bitsmotor
Microtubule MT Overview
Typical non dividing cellhas 1 centrosome nearnucleus enter
MTorganizing
motorproteinsmove on MT
to transport ofvesicles
for cilia flagellatobeat or vend
forchromosomemovement celldivision

MT is made bytubulins
microtubule is made by 2tubulinmonomers α B tubulin
Both are globularproteinwhichhaveGTPbindingsites
tubulin alwayshas GTP
tubulin has GTPase activity
filamentformation dissociation is controlledby GTPGDPformof_tubulin
NoteTubulinDimer isbuildingunitofmicrotuble

MTstructure
α B tubulinheterodimerworks as a buildingunit diameter 25mm
α B stackalterativelyto form protofilament
13protofilamentsÉhollowfilament MT
Allprotein proteininteraction are non covalent

Mothas InpurifiedMTplusendgrowsfasterthanminusend
polarity
tubulin endisboundtothecentrosome
In vivominus
 tubulin

Polarity of Microtublegrowth
GTPtubulindimersassociatewgrowing endswhilethey're in a flatsheetthenstreetzips
up intothematuremicrotuble
Shortlyafterpolymerization the_tubulin hydrolyzesGTPtoGDP

GDPtubulin is stable in microtubule dissociates fromtheminus end

Notubulincan dissociatefromthemiddle ofthemicrotuble
NoteInvivo most ends areanchoredtocentrosome

centrosomecontains apool of tubulins pair of centrioles
alsohas motorproteins manyother MTassociating proteins

Centrosome start site of microtubulegrowth
MTstartgrowingfromthefixedpoint

Centrosome
major MT organizing center
Centrosomesurface has multiple ring like assembly site of MT
eachof theringsare madeby_tubulin otherfactors

tubulinbinds to_tubulin ofdimer starts MT fromthe centrosome
Assembly disassemblyof end areblocked by_tubulin normally
tendsarepointing outward association dissociationof tubulinsubunits
occur at mostly the tend

DyamicInstabilityof MT
1 OnlyGTP form oftubulindimer canassembleinto filament butafter
assembly GTPis hydrolyzed toGDP
2GDP form ofthefilament stable but candisassembleonlyfromthe
 freeend
3Whenfilamentisgrowingnewly assembled tubulins are GTPforms sothat
thefilamentis stable it can keepgrowing
4 Onceitstopsgrowing tabulins end becomeGDP form easily
disassembled
5 Growingandgrows fast shrinkingendshrinks fast dynamicinstability

Note Dynamicinstability
MT rapidly
Growing grows butonceitstops itstartsshrinkingrapidly thenstop thenagainstartgrowing
forrandomseeking
idealmechanism
Dynamicinstabilityis

Microtubule associatedproteins MAPS regulatethedynamicbehavior of
microtubules
manyMAPScontrolMTstructure stability

Organizationof MTw inneuron

Axonstructureis supportedby MT intermediate
filament
1 MTinaxoniscrucialtotransportvesiclestonerveterminal
2 AllMTinaxonarepointing endoutwardbutnotconnectedtocentrosome
3They'renotcontinuous capped bothends
4Taustabilizesmicrotubules inaxon
axonspecificMAP involvedin the Alzheimerdisease
Dendrites
1 MTsareorientedtobothdirections exceptional

2DendritecontainsotherMAPS
Normalcells
1 MTofordinallycell is stemmedfromthe centrosome stabilizedby
MAP1,2

tau MAP 1,2
y tubulin
stabilizers
 Dynein Kinesin Overview Motors
Dynein walks on MTtoend v14 msec
Kinesin walks on MT to tend 2.3 m sec
Bothhave at least 2heavy chains 82 or more lightchains

Eachheavy chain has MTbindingsite ATPbindingsitein large
globulardomain head
In both cases ATPbinding hydrolysis release are coupledwith
structural change
humanhas 40 Kinesins 2dyneins
Vesicles are transported to nerve terminal by kinesin I
Vesicleswhich are moving back to cellbody are connected to dynei
cytoplasmicdynein

MicrotubuleMotors Movement
ATPbindinghydrolysis release head domains are coupled w
structural change

Howkinesin1 moves on MT
Note Eachhead can bindtoATPhydrolyzeit thenreleaseADP in 1step
ofwalking
1 ATPbinding of 1head makes anotherhead ADPform thrown
forward to facilitatewalking
2 ADP formbinds MTat new position
3 ADP formreleasesADP ATP formhydrolyzes intoADP
4 WhenATP freeformbinds ATPanotherhead w ADP isthrown
forward
 9 generates power stroke

Motors move vesides
145diffkinesinshavebeenfoundinnumans
found
least2cytoplasmicdyneinare
2At
diffcargos gotodiffdestinations regulation
carry

Kinesins extends ER Dynein pulls Golgi
Smith ER is extended to near plasmamembrane Golgi islocated near
centrosome
ERmembrane is linkedto kinesin Golgimembraneislinked to dynein
IfsuchcellistreatedbycolchicineERcollapseGolgiisfragmented
Lysosome is alsolinked w kinesin dynein
mitochondria hasbothdynein kinesin

Cilia flagella are attached to basal body
9 doublets of cilium are directextensionofbasalbodytriplets
Basalbodylookssimilarto a single centriole atripletstructure
There's not
y tubulin sing on thebasalbody
 Cilium flagellum have identicalstructure
9 doubletMT are arranged in central pair of MT 9 2
a ring
with protein Nexin
Adjacent doublet is is permanently connected

Dynein tail is attached to one doublet headis facingto adjacent
doublet
Dyneinin flagellum AxonemalDynein

Dynein makes doublets slide
Axonemal Dynein locates btwn 2 doublets
Dynein is fixed to 1 doublet by the energy of ATPhydrolysis
However doublets can'tslide freely because they are connected
by other
protein nexin

Note Local slidingof doublets makes flagellum band

Note Local slidingof doublets makes flagellumband

Flagella motion is coordinated
sliding is coordinated to enable organized
action of flagellumbut the mechanism of the coordination is not well
understood
Recognition of microtubles during mitosis
1 Mitoticspindleis derived from microtubules
Mphase
2 In S phase centrosomeduplicates but remain together until
3 In prophase
a 2 centrosomes pusheach other to separate
b microtubules become shorter more dynamic
4 Centrosomes move to opposite poles to create spindle
5 In metaphase
some MTs catchkinetochores of condensedchromosomes
Kinetochore microtubule
Some MTS overlap with oppositely oriented MTs Overlapping
mtg have kinesin like proteins
interpolar microtubule
Some MTs reach cell periphery to connect cell cortex
Astral microtubule

Mechanism of centrosome separation role of interpolarmicrotubules
bipolar kinesin is loaded on the interpolar MT
Kinetochoremicrotubule bond at end
Interpolar MTpush centrosomes away tend can extend

sisterchromatidconnection is
cut atthebeginning of anaphase