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Title: Nanopores: fundamental science


1
Lecture 19 Nanopores fundamental science and
biotech prospects
2
Outline
  • Tethered functional polymers
  • under confinement

2. Elementary secondary structures in a nanopore
3. Temperature-responsive pore
Aksimentiev Schulten, 2005
3
Song, L., Hobaugh, M.R., Shustak, C., Cheley, S.,
Bayley, H., Gouaux, J. E. 1996, Science
2741869-1865.
- seven subunits -each subunit contributing with
two ?-strands to form a 14-stranded ?-barrel
protein pore - cis entrance is 70 Ã… above the
bilayer - total of 100 Ã… - long lumen -average
20 Ã… in internal diameter -the trans entrance is
close to the bilayer surface
4
AFM view
with Jie Yang, U Vermont
5
Motivation to work with ?-hemolysin versatility
and robustness
1. Structural It has a known crystal structure
(Song et al., 1996)
2. Biochemical It is a robust membrane
proteinaceous complex stable in SDS preparative
Gels easy to carry out genetic engineering of
the channel.
  • 3. Biophysical
  • Large single-channel conductance pretty signal
  • The channel remains open indefinitely for extreme
    environmental
  • conditions (pH, salt, T, ??V)
  • Bayley and coworkers, Angew. Chem. Int, January
    2005.
  • ?-barrel is intact up to 95 C!

6
Single channel electrical recording
DV 40 mV 700 pS 30 pA 1 M NaCl
cis
trans
In this talk various DV, salt,
filtering, timescales etc.
7
Single-channel current signature for the
wild-type protein
100 Hz
?V100 mV cKCl 300 mM
WT7
Current (pA)
10 s
Number of Points
Quiet ionic flow
Current (pA)
8
COMBINATIONS and PERMUTATIONS
WT7
WT6-(CM-PEG)1
WT5-(CM-PEG)2
WT4-(CM-PEG)3
WT3-(CM-PEG)4
WT2-(CM-PEG)5
WT1-(CM-PEG)6
-(CM-PEG)7
9
Pre-formed heteroheptamers with different number
of PEGs
10
a
H6S106C-PEG3.4k-biotin1
Current (pA)
1 sec
b
Number of Points
Current (pA)
11
3.4 kDa biotinylated PEG
12
C. Jeppesen et al., Science 293 (2001) 465-471
T. P. Russell, Science 293 (2001) 446-447
13
Experimental design
A
Analyte/cis
B
Analyte/trans
14
b
a
WT streptavidin/(trans)
WT streptavidin/(cis)
Current (pA)
Current (pA)
2 s
2 s
c
d
W120A streptavidin/(trans)
W120A streptavidin/(cis)
Current (pA)
Current (pA)
500 ms
10 s
.
15
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16
PEG can be trapped out in both sides of the
bilayer (in the same experiment!)
W120A streptavidin/(cistrans)
W120A (cis)/WT streptavidin(trans)
Current (pA)
Current (pA)
10 s
10 s
1. Transient captures/cis 2. Permanent
capture/trans
1. Transient captures/cis 2. Transient
captures/trans

17
Stochastic sensing provides kinetic information
ton 1/konA
toff 1/koff
Kd koff / kon
18
Quantification of the protein analyte at nM
concentration
0 nM
14.5 nM
1/? (s-1)
Current (pA)
W120A streptavidin (nM)
43.5 nM
Get kon, koff, Kd
Events are detected in the microsecond timescale
10 s

19
Detection of an unknown protein - anti-biotin
monoclonal antibody
mAb/(trans)
Current (pA)
5 s
W120A streptavidin(cis)/mAb(trans)
Current (pA)
5 s

20
Other applications
Single-polymer dynamics
Design of other nanostructures with movable
polymeric arms
Single-molecule detection of other macromolecules
21

22
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23
Thermodynamics and kinetics of duplex DNA
formation probed at the single molecule level
24
A
B
M113
S106
T129
E111
L135
T117
K8
lipid bilayer
cis
trans
polymer
transmembrane pore
constriction
? barrel
vestibule
100 Ã…

25
4 mM OPSS-PEG/trans - Reaction monitored at -40 mV
Apparent reaction rate constant (s-1)
PEG repeat units, N
26
What is the polymer concentration within the pore?
PcaHL/csolution
27
Subunit combinations permutations
1 mM MePEG-OPSS-1kDa/cis
0
1
2
3
4
5
Current (pA)
6
7
modified
unmodified
K8C7
Time (s)
e.g., determination of pore stoichiometry for
other barrel proteins
28
Current (pA)
4 s
Current (pA)
2 s
T117C7100mV(n)10kHzOPSS-PEG1k/cis10 mM DTTcis
29
3. A targeted built-in temperature-responsive
gating mechanism
(VPGGG)m
? 410-5 atoliters
30
Temperature-dependent single-channel activity of
ELP-engineered ?HL pores
A
E101W6
31
GS-rich peptide loop engineered ?HL pores
L651W6
20 C
40 C
60 C
32
Kinetic model for temperature-dependent
ELP-induced closures
Low conductance
High conductance
open
hydrated (unfolded)
collapsed (folded)
open
T
Low T
High T
- T
Low conductance
High conductance
hydrated (unfolded)
collapsed (folded)
closed
closed
Full current blockade
Small current blockade
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