Team:Freiburg Calcium Imaging

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<div style="font-size:18pt;">
<div style="font-size:18pt;">
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<font face="Arial Rounded MT Bold" style="color:#010369">_calcium imaging</font></div>
+
<font face="Arial Rounded MT Bold" style="color:#010369">_Cell Stability, Ca<sup>2+</sup> Signaling and DNA-Origami Binding to Cells</font></div>
-
[[Image:CalciumImaging_teamfreiburg2008.jpg]]
+
 
 +
<h1>Introduction</h1>
 +
To test receptor activation in a natural context, it was also tried to
 +
activate T-cells (B12.7.5) with the NIP-linked DNA-origami. Those
 +
T-cells have a NIP Fab-fragment genetically fused to their receptor.
 +
During these tests many problems were faced which could emerge as
 +
obstacles in the main project, the artificial receptor, which is
 +
expressed by 293T-cells.<br>
 +
One problem was to find a medium in which the T-cells survive, the
 +
DNA-Origami structures are stable and which is also suitable for the
 +
fluorescent measurement on the microsope). Normally, the cells were kept
 +
in RPMI (10% FCS), but the phenol red itself is an electron acceptor
 +
and would disturb the measurement. Another complication was, that the
 +
Origami need a high Mg<sup>2+</sup> concentration (12.5 mM), which stabilizes the
 +
DNA backbone, but low concentration of other bivalent cations, which
 +
could disrupt the Origami. None of the common cell culture medium does
 +
achieve these conditions. In order to solve the cell culture problem
 +
the stability of the Origami in different media were tested (see
 +
DNA-Origami). On the other hand we also had to test if our cells
 +
survive 12.5 mM Mg<sup>2+</sup>, which we tested with an MTT-Assay. <br>
 +
As explained before, we also wanted to use the Origami to activate
 +
T-cell receptors (TCR) by clustering. For this experiment we measured
 +
the calcium influx with a FACS, as described earlier (Susana Minguet,
 +
Immunity Vol. 26, Page 43-54). But in this publication much higher
 +
concentration of the stimulus were used than we were able to produce.
 +
Therefore we were looking for another method to measure the calcium
 +
influx. One very commonly used method is to stain the cells with
 +
Fura-2AM and measure the changes in calcium concentration with a
 +
confocal laser scanning microscope. Usually this measurement is only
 +
suitable for adherent cells, because by giving the stimulus to the
 +
cells the cells would move. To avoid this problem we used Poly-L-Lysin
 +
coated µ-Slides(ibidi). <br>
 +
To&nbsp;check, that the DNA-Origami really bind specifically to the
 +
cells(T-cells and B-cells), Alexa 488 linked Origamis with and without
 +
NIP were given to the cells and the fluorescence was visualized with a
 +
LSM.<br>
 +
<br>
 +
<br>
 +
<h1>Material and Methods</h1>
 +
<br>
 +
<h2>Cell stability in the presence of Mg<sup>2+</sup> measured by MTT-Assay</h2>
 +
To test the Mg<sup>2+</sup> tolerance of the T-cells (cell line
 +
B.12.7.5),&nbsp;100 µl cellsuspension was mixed with 800 µl RPMI
 +
medium&nbsp; and 100 µl &nbsp;MgCl2 or MgAc, respectively
 +
containing various concentrations of Mg<sup>2+</sup> in a 24-well plate. 3 days
 +
later&nbsp;cells of each well were spun down, the supernatant was
 +
discarded and the cells were resuspended in 200 µl new RPMI medium. 50
 +
µl 3-(4,5-Dimethylthiazol-2-yl)-2,5-diphenyltetrazoliumbromid (MTT) was
 +
added to each sample. After 4 h of incubation at 37°C the cells were
 +
spun down again and after discarding the medium the pellet was resolved
 +
in 400 µl DMSO and 50 µl Soerensens’ reagent. The reduced blue MTT was
 +
detected in a photometer at 570nm.<br>
 +
<br>
 +
B-cells (cell line j558lδmmb1nfleck)&nbsp; from 10 ml dishes were
 +
spun down and resuspended in 9ml Krebs-Ringer-Hepes (12.5mM MgAc).
 +
After incubation for 45 min the cells were spun down again and resolved
 +
in 1 ml PBS. 5 µl of the suspension was mixed with 45 µl Trypan blue and
 +
the cells were counted in a “Neubauer cell chamber”.<br>
 +
<br>
 +
 
 +
293T cells were scraped off an 10 ml dish, spun down and resolved in 10 ml new DMEM medium. 500 µl of this suspension was given in each plate of a 6-well plate containing 4500 µl DMEM medium with different concentrations of Mg<sup>2+</sup>. 3 days later the media of 3 wells was sucked off and the cells were washed in PBS, then TA-buffer (Tris-Acetat buffer) was given to these wells. After 1h the TA-buffer was removed, the cells of all dishes were washed in PBS and 2ml new DMEM medium plus 500 µl MTT was added. After incubation for 3.5h at 37°C the cells were scraped off the wells and spun down at 13000 rpm for 5min. Then the pellet was resolved in 4 ml DMSO and 500 µl Soerensens’ reagent. Detection took place at 570 nm.<br>
 +
<br>
 +
<h2>Media</h2>
 +
<br>
 +
Medium for&nbsp;B- and T-cell&nbsp;:<br>
 +
<ul>
 +
  <li>RPMI</li>
 +
  <li>10% FCS&nbsp;</li>
 +
  <li>HEPES (10mM)&nbsp;</li>
 +
  <li>β-mercaptoethanol (50µM)&nbsp;</li>
 +
  <li>L-Glutamine (2 mM)</li>
 +
  <li>1% Pen-Strep</li>
 +
</ul>
 +
<br>
 +
Medium for 293T:<br>
 +
<ul>
 +
  <li>DMEM</li>
 +
  <li>10% FCS&nbsp;</li>
 +
  <li>5% PenStrep&nbsp;</li>
 +
  <li>L-Glutamine (1.5 mM) <br>
 +
  </li>
 +
</ul>
 +
<br>
 +
Krebs-Ringer-Hepes (12.5 mM Mg<sup>2+</sup>):<br>
 +
<ul>
 +
  <li>NaCl (155 mM)</li>
 +
  <li>KCl (4.5 mM)</li>
 +
  <li>CaCl2 (2 mM)</li>
 +
  <li>MgCl2 (1 mM)</li>
 +
  <li>MgAcetat (11.5 mM)</li>
 +
  <li>D-glucose (10 mM)</li>
 +
  <li>Hepes (5 mM)</li>
 +
</ul>
 +
-&gt;&nbsp; pH 7.4 with NaOH<br>
 +
<br>
 +
Soerensens’ reagent:<br>
 +
<ul>
 +
  <li>10 ml glycine (0.1 M)</li>
 +
  <li>10 ml NaCl (0.1 M)</li>
 +
  <li>80 ml Aqua dest.</li>
 +
</ul>
 +
-&gt;&nbsp; pH 10.5 with NaOH<br>
 +
<br>
 +
<h2>Binding measurement</h2>
 +
To test the binding between origamis and T-cells/B-cells 15 µl cell
 +
suspension in Ringer (12.5 mM Mg<sup>2+</sup>) or TA-buffer (12.5 mM Mg<sup>2+</sup>) was mixed
 +
with 15 µl of origamis on a µ-Slide (ibidi, µ-Slides 18 well-flat, Cat.
 +
No: 81824). Those slides are coated with Poly-L-Lysine, which fixes the
 +
cells on the bottom of the slide. So the suspensions cells could be
 +
measured on a microscope. <br>
 +
<br>
 +
<br>
 +
<h2>Calcium<sup>2+</sup> measurement</h2>
 +
<br>
 +
<h3>Ca<sup>2+</sup> measurement with microscope</h3>
 +
By binding of ligands to a receptor at the cell surface the cell reacts
 +
amongst others with a efflux of calcium ions from the ER into the
 +
cytoplasm. To measure the intensity of activation one way is to
 +
quantify the concentration or rather the increase of calcium ions in the
 +
cytoplasm. Fura-2 is a fluorescent dye which change the quality
 +
dependent on the Ca<sup>2+</sup> concentration. Fura-2AM (Fura-2-acetoxymethyl
 +
ester) is a membrane-permeable derivative of Fura-2 but after crossing
 +
the membrane the acetoxymethyl groups are removed by cellular esterases
 +
so it remains as Fura-2 in the cytoplasm. Fura-2 is excited at 340 nm
 +
and 380 nm of light, and the ratio of the emissions at those
 +
wavelengths is directly correlated to the amount of intracellular
 +
calcium. Without Ca<sup>2+</sup> the maximum emission results from excitation at
 +
365nm. With Ca<sup>2+</sup> the maximum emission change to excitation at 340 nm and
 +
the emission decrease by extinction at 380 nm.<br>
 +
So to measure properly it is necessary to alternate quickly between the
 +
two excitation wavelengths. Excitation was measured with a high-end
 +
inverted fluorescenc microscope (Zeiss Axiovert 100). <br>
 +
&nbsp; &nbsp;&nbsp;&nbsp; &nbsp;<br>
 +
&nbsp; &nbsp;<br>
 +
[[Image:TeamFreiburg2008_FURA_PRINZIP.jpg]]<br>
 +
<small>Fig. 1: Fura-2 Emission with (blue) and without free
 +
calciumions (red)</small><br><br>
 +
'''Fura-2 Loading'''<br>
 +
<u>Procedure:</u><br><br>
 +
1. 1 ml T-cell cellsuspension (in Ringer-Solution)<br>
 +
2. + 0.5 µl Pluronic F 127<br>
 +
3. + 0.5 µl Fura-Solution (2mM) and vortex<br>
 +
4. incubation at 37°C and 8% CO2 for 20 min <br>
 +
5. centrifuge at 1000 rpm (206 rcf) and 4°C for 5 min<br>
 +
6. discard the supernatant<br>
 +
7. + 100 µl Ringer-Solution for resuspension<br>
 +
<br>
 +
<h3>Ca<sup>2+</sup> measurement with FACS</h3>
 +
Cells resuspended in medium with 1% serum were incubated with 5 μg/ml
 +
of Indo-1, which is the Ca<sup>2+</sup> complexing dye,&nbsp; and 0.5 μg/ml of
 +
pluronic F-127, which fasilitates dye uptake (both Molecular Probes) 45
 +
min at 37°C. After incubation, cells were distributed into to 1.5 ml
 +
eppendorf tubes and the washed with the medium we wanted to measure
 +
them. After washing, cells were resuspended in the according medium and
 +
kept on ice. Ca<sup>2+</sup> response was induced by addition of the indicated
 +
stimulus 1 min after starting to record the ratio of Ca<sup>2+</sup>-bound Indo-1
 +
versus unbound Indo-1 with a LSRII fluorescence spectrometer (Becton
 +
Dickinson). Cells were measured for approximately 2min before putting
 +
the stimuli on it. Data were analyzed with the FloJo 6.1 software.<br>
 +
<br>
 +
<h1>Results and discussion</h1>
 +
<h2>Cell stability in the presence of Mg<sup>2+</sup> measured by MTT-Assay</h2>
 +
'''T-cells:'''<br>
 +
[[Image:Freiburg08tabellet-cellstability.JPG‎|Freiburg08tabellet-cellstability.JPG‎]]<br>
 +
<small>Table 1: Absorbance of reduced MTT of T-cells with various Mg<sup>2+</sup> concentration</small><br>
 +
<br>
 +
[[Image:TeamFreiburg2008-t-cellstability1.png]]<br>
 +
<small>Fig. 2: graphic illustration of the results from Table 1.</small><br>
 +
<br>
 +
'''B-cells:'''<br>
 +
Counting stained and unstained B-cells brought following result: <br>
 +
Dead cells : 1<br>
 +
Living cells: 44<br>
 +
Total cell number: 45<br>
 +
<br>
 +
'''293T-cells:'''<br>
 +
[[Image:TeamFreiburg2008_TABELLE-t-cellstability3.jpg‎ ]]<br>
 +
<small>Table 2: Absorbance of reduced MTT of 293T-cells with various Mg<sup>2+</sup> concentration and TA treatment</small><br>
 +
<br>
 +
The MTT assays and the trypan blue staining proofed the tolerance of
 +
the used cells towards a concentration up to 12.5 mM Mg<sup>2+</sup>. This is the
 +
exact concentration in which the origami are produced and stored. The
 +
lower absorbance in the tests with TA could possibly come from the
 +
removal of the TA-buffer because it seemed that the TA buffer disturbs
 +
the adhesion of the 293T cells to the ground of the well so that some
 +
cells might be sucked off with the TA.<br>
 +
<br>
 +
<h2>Calcium<sup>2+</sup> measurement</h2>
 +
<h3>Ca<sup>2+</sup> measurement with FACS</h3>
 +
In this measurement we tried to activate T-Cells by clustering.
 +
Therefore we tested two different buffers, Krebs-Ringer-Hepes with
 +
12.5 mM Mg<sup>2+</sup> buffer and TA with 12.5 mM Mg<sup>2+</sup>. As positive control we used
 +
UCHT1 (=anti-CD3), which can stimulate T-cells (Susana Minguet, Vol.
 +
26, Page 43-54).<br>
 +
<br>
 +
&nbsp;<br>
 +
[[Image:FACS-Auswertung_fuer_final_report.jpg|600 px]]<br>
 +
<small>Fig. 3: Results of the FACS measurement. Cells were stained with
 +
Indo-1. Different stimuli were used. Stimuli were given after 1min.
 +
Time is given in seconds.<br>
 +
Green line: cells buffered in
 +
Krebs-Ringer-Hepes buffer. The both other lines show the positive
 +
controls of cells buffered in TA (blue) and Krebs-Ringer-Hepes (red).</small><br>
 +
<br>
 +
Figure 3 shows the change in intra cellular calcium concentration after
 +
adding the DNA-Origami (green) compared to the positive controls (blue
 +
and red). The cells in Krebs-Ringer-Hepes buffer, which were stimulated
 +
with UCHT 1 show a very high activation, while the cells buffered in TA
 +
and the Origami treaded cell show only a slowly signal. When we put the
 +
cells buffered in TA in the LSRII fluorescence spectrometer and
 +
rechecked all the settings we saw, that most of the cells were already
 +
dead. This could be the reason for the low signal of the TA buffered
 +
cells (blue line). The cells treaded with Origami didn´t show any
 +
calcium change at all. After the FACS measurement we tested some of
 +
those Origami on the AFM. None of the Origami which we used were
 +
stable, so probably that is the reason why we couldn´t see any signal
 +
by adding NIP-Origami. To confirm this conclusion this measurement would
 +
have to be carried out again.<br>
 +
<br>
 +
<h3>Ca<sup>2+</sup> measurement with microscope</h3>
 +
This measurement was also used to activate the T-cell receptors (TCR)
 +
by clustering. The TCR's were modified with a anti-NIP antibodies and
 +
the NIP-molecules were coupled to DNA origamis. As a negative control
 +
we used a DNA-Origami without NIP. The positive control was Pervanadat.<br>
 +
By adding the origamis to the cells we could see a small signal for
 +
both with and without NIP. The amount of fluorescent cells increase
 +
slowly but there was no significant difference between the negative
 +
control and the sample (7 NIP's per origami).<br>
 +
By contrast the Pervanadat produced a strong signal that differs from
 +
the origami reactions.<br>
 +
<br>
 +
[[Image:CalciumImaging_teamfreiburg2008.jpg|750px]]<br>
 +
<small>Fig. 4: T-cells stimulated with Pervanadat: A) 1 sec before addition B) 100 sec after addition C) 200 sec after addition</small><br>
 +
<br><br>
 +
In contrast to the positive control (Pervanadat) which was working quit
 +
well, our sample (DNA-origami with NIP) and the negative control
 +
(DNA-origami without NIP) did not show a significant Ca<sup>2+</sup> efflux. There
 +
are two reasons which could be responsible that the cell answer to
 +
origamis with and without NIP’s almost looks the same.<br>
 +
1. Spatial avoidance: Because of the rough surface of T-cells big
 +
molecules could have problems to trigger two or more TCR’s. Also huge
 +
extracellular proteins could avoid that the nanoplates reach the small
 +
TCR’s.<br>
 +
2. Non-specific binding:<br>
 +
Also the negative control produced a weak signal which could result
 +
from non-specific binding to the cell surface, because the cells were
 +
not blocked.<br>
 +
<br>
 +
In both cases the slow Ca<sup>2+</sup> efflux could result from the mechanical
 +
touch between the cells by adding the liquid with the probes.<br>
 +
<h2>Binding measurement</h2><br>
 +
To check, that the DNA-Origami really bind specifically to the T-cells and B-cells, both genetically fused to a NIP Fab-fragment, Alexa 488 linked origamis with and without NIP were given to the cells and the fluorescence was visualized with a LSM. The results are shown in Figure 4 and 5.<br>
 +
<br>
 +
[[Image:TeamFreiburg2008_Bindungsmessung_1.jpg|600 px]]<br>
 +
<small>Fig. 5: B-cells with NIP linked Origami (left) and without NIP (right) in 50% TA (Tris-Acetat) and 50% Krebs-Ringer-Hepes buffer, </small><br>
 +
<small>both buffers contain 12.5 mM Mg<sup>2+</sup> </small>
 +
<br>
 +
<br>
 +
[[Image:Freiburg2008_Bindungsmessung2.PNG| 600px]]<br>
 +
<small>Fig. 6: B-cells with NIP linked Origami (left) and without NIP (right) in TA (Tris-Acetat)</small><br>
 +
<br>
 +
Figure 5 and 6 show that the Origami with NIP as well as the Origami without NIP bound to both cell types. During the binding measurements it seemed that the origamis were
 +
absorbed by the cells or that they bind unspecifically. Later tests at
 +
the AFM, with the same Origami showed no functional origami which could be an explanation to
 +
the behaviour of the cells. The expanded form of the B-cells in
 +
TA-buffer showed that sole TA-buffer is osmotically disadvantageous for
 +
the cells.<br>
}}
}}

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_Cell Stability, Ca2+ Signaling and DNA-Origami Binding to Cells


Contents

Introduction

To test receptor activation in a natural context, it was also tried to activate T-cells (B12.7.5) with the NIP-linked DNA-origami. Those T-cells have a NIP Fab-fragment genetically fused to their receptor. During these tests many problems were faced which could emerge as obstacles in the main project, the artificial receptor, which is expressed by 293T-cells.
One problem was to find a medium in which the T-cells survive, the DNA-Origami structures are stable and which is also suitable for the fluorescent measurement on the microsope). Normally, the cells were kept in RPMI (10% FCS), but the phenol red itself is an electron acceptor and would disturb the measurement. Another complication was, that the Origami need a high Mg2+ concentration (12.5 mM), which stabilizes the DNA backbone, but low concentration of other bivalent cations, which could disrupt the Origami. None of the common cell culture medium does achieve these conditions. In order to solve the cell culture problem the stability of the Origami in different media were tested (see DNA-Origami). On the other hand we also had to test if our cells survive 12.5 mM Mg2+, which we tested with an MTT-Assay.
As explained before, we also wanted to use the Origami to activate T-cell receptors (TCR) by clustering. For this experiment we measured the calcium influx with a FACS, as described earlier (Susana Minguet, Immunity Vol. 26, Page 43-54). But in this publication much higher concentration of the stimulus were used than we were able to produce. Therefore we were looking for another method to measure the calcium influx. One very commonly used method is to stain the cells with Fura-2AM and measure the changes in calcium concentration with a confocal laser scanning microscope. Usually this measurement is only suitable for adherent cells, because by giving the stimulus to the cells the cells would move. To avoid this problem we used Poly-L-Lysin coated µ-Slides(ibidi).
To check, that the DNA-Origami really bind specifically to the cells(T-cells and B-cells), Alexa 488 linked Origamis with and without NIP were given to the cells and the fluorescence was visualized with a LSM.


Material and Methods


Cell stability in the presence of Mg2+ measured by MTT-Assay

To test the Mg2+ tolerance of the T-cells (cell line B.12.7.5), 100 µl cellsuspension was mixed with 800 µl RPMI medium  and 100 µl  MgCl2 or MgAc, respectively containing various concentrations of Mg2+ in a 24-well plate. 3 days later cells of each well were spun down, the supernatant was discarded and the cells were resuspended in 200 µl new RPMI medium. 50 µl 3-(4,5-Dimethylthiazol-2-yl)-2,5-diphenyltetrazoliumbromid (MTT) was added to each sample. After 4 h of incubation at 37°C the cells were spun down again and after discarding the medium the pellet was resolved in 400 µl DMSO and 50 µl Soerensens’ reagent. The reduced blue MTT was detected in a photometer at 570nm.

B-cells (cell line j558lδmmb1nfleck)  from 10 ml dishes were spun down and resuspended in 9ml Krebs-Ringer-Hepes (12.5mM MgAc). After incubation for 45 min the cells were spun down again and resolved in 1 ml PBS. 5 µl of the suspension was mixed with 45 µl Trypan blue and the cells were counted in a “Neubauer cell chamber”.

293T cells were scraped off an 10 ml dish, spun down and resolved in 10 ml new DMEM medium. 500 µl of this suspension was given in each plate of a 6-well plate containing 4500 µl DMEM medium with different concentrations of Mg2+. 3 days later the media of 3 wells was sucked off and the cells were washed in PBS, then TA-buffer (Tris-Acetat buffer) was given to these wells. After 1h the TA-buffer was removed, the cells of all dishes were washed in PBS and 2ml new DMEM medium plus 500 µl MTT was added. After incubation for 3.5h at 37°C the cells were scraped off the wells and spun down at 13000 rpm for 5min. Then the pellet was resolved in 4 ml DMSO and 500 µl Soerensens’ reagent. Detection took place at 570 nm.

Media


Medium for B- and T-cell :

  • RPMI
  • 10% FCS 
  • HEPES (10mM) 
  • β-mercaptoethanol (50µM) 
  • L-Glutamine (2 mM)
  • 1% Pen-Strep


Medium for 293T:

  • DMEM
  • 10% FCS 
  • 5% PenStrep 
  • L-Glutamine (1.5 mM)


Krebs-Ringer-Hepes (12.5 mM Mg2+):

  • NaCl (155 mM)
  • KCl (4.5 mM)
  • CaCl2 (2 mM)
  • MgCl2 (1 mM)
  • MgAcetat (11.5 mM)
  • D-glucose (10 mM)
  • Hepes (5 mM)

->  pH 7.4 with NaOH

Soerensens’ reagent:

  • 10 ml glycine (0.1 M)
  • 10 ml NaCl (0.1 M)
  • 80 ml Aqua dest.

->  pH 10.5 with NaOH

Binding measurement

To test the binding between origamis and T-cells/B-cells 15 µl cell suspension in Ringer (12.5 mM Mg2+) or TA-buffer (12.5 mM Mg2+) was mixed with 15 µl of origamis on a µ-Slide (ibidi, µ-Slides 18 well-flat, Cat. No: 81824). Those slides are coated with Poly-L-Lysine, which fixes the cells on the bottom of the slide. So the suspensions cells could be measured on a microscope.


Calcium2+ measurement


Ca2+ measurement with microscope

By binding of ligands to a receptor at the cell surface the cell reacts amongst others with a efflux of calcium ions from the ER into the cytoplasm. To measure the intensity of activation one way is to quantify the concentration or rather the increase of calcium ions in the cytoplasm. Fura-2 is a fluorescent dye which change the quality dependent on the Ca2+ concentration. Fura-2AM (Fura-2-acetoxymethyl ester) is a membrane-permeable derivative of Fura-2 but after crossing the membrane the acetoxymethyl groups are removed by cellular esterases so it remains as Fura-2 in the cytoplasm. Fura-2 is excited at 340 nm and 380 nm of light, and the ratio of the emissions at those wavelengths is directly correlated to the amount of intracellular calcium. Without Ca2+ the maximum emission results from excitation at 365nm. With Ca2+ the maximum emission change to excitation at 340 nm and the emission decrease by extinction at 380 nm.
So to measure properly it is necessary to alternate quickly between the two excitation wavelengths. Excitation was measured with a high-end inverted fluorescenc microscope (Zeiss Axiovert 100).
       
   
TeamFreiburg2008 FURA PRINZIP.jpg
Fig. 1: Fura-2 Emission with (blue) and without free calciumions (red)

Fura-2 Loading
Procedure:

1. 1 ml T-cell cellsuspension (in Ringer-Solution)
2. + 0.5 µl Pluronic F 127
3. + 0.5 µl Fura-Solution (2mM) and vortex
4. incubation at 37°C and 8% CO2 for 20 min
5. centrifuge at 1000 rpm (206 rcf) and 4°C for 5 min
6. discard the supernatant
7. + 100 µl Ringer-Solution for resuspension

Ca2+ measurement with FACS

Cells resuspended in medium with 1% serum were incubated with 5 μg/ml of Indo-1, which is the Ca2+ complexing dye,  and 0.5 μg/ml of pluronic F-127, which fasilitates dye uptake (both Molecular Probes) 45 min at 37°C. After incubation, cells were distributed into to 1.5 ml eppendorf tubes and the washed with the medium we wanted to measure them. After washing, cells were resuspended in the according medium and kept on ice. Ca2+ response was induced by addition of the indicated stimulus 1 min after starting to record the ratio of Ca2+-bound Indo-1 versus unbound Indo-1 with a LSRII fluorescence spectrometer (Becton Dickinson). Cells were measured for approximately 2min before putting the stimuli on it. Data were analyzed with the FloJo 6.1 software.

Results and discussion

Cell stability in the presence of Mg2+ measured by MTT-Assay

T-cells:
Freiburg08tabellet-cellstability.JPG‎
Table 1: Absorbance of reduced MTT of T-cells with various Mg2+ concentration

TeamFreiburg2008-t-cellstability1.png
Fig. 2: graphic illustration of the results from Table 1.

B-cells:
Counting stained and unstained B-cells brought following result:
Dead cells : 1
Living cells: 44
Total cell number: 45

293T-cells:
TeamFreiburg2008 TABELLE-t-cellstability3.jpg
Table 2: Absorbance of reduced MTT of 293T-cells with various Mg2+ concentration and TA treatment

The MTT assays and the trypan blue staining proofed the tolerance of the used cells towards a concentration up to 12.5 mM Mg2+. This is the exact concentration in which the origami are produced and stored. The lower absorbance in the tests with TA could possibly come from the removal of the TA-buffer because it seemed that the TA buffer disturbs the adhesion of the 293T cells to the ground of the well so that some cells might be sucked off with the TA.

Calcium2+ measurement

Ca2+ measurement with FACS

In this measurement we tried to activate T-Cells by clustering. Therefore we tested two different buffers, Krebs-Ringer-Hepes with 12.5 mM Mg2+ buffer and TA with 12.5 mM Mg2+. As positive control we used UCHT1 (=anti-CD3), which can stimulate T-cells (Susana Minguet, Vol. 26, Page 43-54).

 
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Fig. 3: Results of the FACS measurement. Cells were stained with Indo-1. Different stimuli were used. Stimuli were given after 1min. Time is given in seconds.
Green line: cells buffered in Krebs-Ringer-Hepes buffer. The both other lines show the positive controls of cells buffered in TA (blue) and Krebs-Ringer-Hepes (red).


Figure 3 shows the change in intra cellular calcium concentration after adding the DNA-Origami (green) compared to the positive controls (blue and red). The cells in Krebs-Ringer-Hepes buffer, which were stimulated with UCHT 1 show a very high activation, while the cells buffered in TA and the Origami treaded cell show only a slowly signal. When we put the cells buffered in TA in the LSRII fluorescence spectrometer and rechecked all the settings we saw, that most of the cells were already dead. This could be the reason for the low signal of the TA buffered cells (blue line). The cells treaded with Origami didn´t show any calcium change at all. After the FACS measurement we tested some of those Origami on the AFM. None of the Origami which we used were stable, so probably that is the reason why we couldn´t see any signal by adding NIP-Origami. To confirm this conclusion this measurement would have to be carried out again.

Ca2+ measurement with microscope

This measurement was also used to activate the T-cell receptors (TCR) by clustering. The TCR's were modified with a anti-NIP antibodies and the NIP-molecules were coupled to DNA origamis. As a negative control we used a DNA-Origami without NIP. The positive control was Pervanadat.
By adding the origamis to the cells we could see a small signal for both with and without NIP. The amount of fluorescent cells increase slowly but there was no significant difference between the negative control and the sample (7 NIP's per origami).
By contrast the Pervanadat produced a strong signal that differs from the origami reactions.

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Fig. 4: T-cells stimulated with Pervanadat: A) 1 sec before addition B) 100 sec after addition C) 200 sec after addition


In contrast to the positive control (Pervanadat) which was working quit well, our sample (DNA-origami with NIP) and the negative control (DNA-origami without NIP) did not show a significant Ca2+ efflux. There are two reasons which could be responsible that the cell answer to origamis with and without NIP’s almost looks the same.
1. Spatial avoidance: Because of the rough surface of T-cells big molecules could have problems to trigger two or more TCR’s. Also huge extracellular proteins could avoid that the nanoplates reach the small TCR’s.
2. Non-specific binding:
Also the negative control produced a weak signal which could result from non-specific binding to the cell surface, because the cells were not blocked.

In both cases the slow Ca2+ efflux could result from the mechanical touch between the cells by adding the liquid with the probes.

Binding measurement


To check, that the DNA-Origami really bind specifically to the T-cells and B-cells, both genetically fused to a NIP Fab-fragment, Alexa 488 linked origamis with and without NIP were given to the cells and the fluorescence was visualized with a LSM. The results are shown in Figure 4 and 5.

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Fig. 5: B-cells with NIP linked Origami (left) and without NIP (right) in 50% TA (Tris-Acetat) and 50% Krebs-Ringer-Hepes buffer,
both buffers contain 12.5 mM Mg2+

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Fig. 6: B-cells with NIP linked Origami (left) and without NIP (right) in TA (Tris-Acetat)

Figure 5 and 6 show that the Origami with NIP as well as the Origami without NIP bound to both cell types. During the binding measurements it seemed that the origamis were absorbed by the cells or that they bind unspecifically. Later tests at the AFM, with the same Origami showed no functional origami which could be an explanation to the behaviour of the cells. The expanded form of the B-cells in TA-buffer showed that sole TA-buffer is osmotically disadvantageous for the cells.

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