Confocal pictures were taken with a 20x plan apo objective. Nuclear staining (DAPI) is
Confocal pictures were taken with a 20x plan apo objective. Nuclear staining (DAPI) is
-
shown in blue and the mCAT-1-mCherry in red. <a href=https://2014.igem.org/Team:Freiburg/Notebook/Labjournal#MirjaHarms_Specificity_pictures">Labjournal</a>
+
shown in blue and the mCAT-1-mCherry in red.<a href="https://2014.igem.org/Team:Freiburg/Notebook/Labjournal#MirjaHarms_Localization">Labjournal</a></p>
</p>
</p>
</figcaption>
</figcaption>
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</section>
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is based on the murine CAT-1 receptor, which serves
-
as the viral entry site of our viral vector into the target cells. We demonstrate
-
that the virus can be used to stably integrate genes into the genome of murine cells.
-
We also targeted other cell lines by expressing the gene for the murine CAT-1 receptor
-
in these cells before viral transduction. Since mCAT-1 is naturally only present in murine
-
cell lines, we use human cell lines for transfection of the receptor. Expression of
-
a reporter suggests that only the cells expressing the mCAT-1 receptor are being
-
infected by the viral particles, thus making particular gene transfer possible.
-
</p>
-
-
<h2 id="Results-Receptor-LocalisationReceptor">Subcellular Localization of the Receptor</h2>
-
-
<p>
-
Since the mCAT-1 receptor serves as the entry site of our viral vector, it is essential
-
that it is expressed on the surface of target cells. In order to determine the localization
-
of the mCAT-1 receptor, we labeled the C-terminus of the mCAT-1 with the fluorescent protein
-
mCherry and transfected it into human embryonic kidney (HEK-293T) cells. After distinct
-
time points cells were imaged with a confocal scanning laser microscope. The mCAT1-mCherry
-
construct was found predominantly at the surface of the cells (Figs. 1, 2).
shown in blue and the mCAT-1-mCherry in red. <a href="<a href=https://2014.igem.org/Team:Freiburg/Notebook/Labjournal#Specificity_pictures">Labjournal</a>
Figure 3: HEK-293T cells transfected with different receptor constructs
-
and infected with MuLV-EGFP afterwards.
-
</p>
-
<p class="desc">
-
Cells transfected with (A) mCAT-1, (B) mCAT-1-HA and (C) mCAT-1-HA-mCherry (red).
-
Cells were transduced with MuLV-EGFP after 24 h. Pictures were taken after 48 h.
-
EGFP fluorescence is shown in green. <a href="https://2014.igem.org/Team:Freiburg/Notebook/Labjournal#MirjaHarms_differnt_kinds_of_receptors">Labjournal</a>
-
</p>
-
</figcaption>
-
</figure>
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-
-
<div class="row category-row">
-
<div class="col-sm-6">
-
<p>
-
Owing to the limited resolution and sensitivity of the cell culture microscope used
-
for the images in Fig. 3, it was not clear whether the cells expressing the receptor
-
were the same cells that were transduced by the virus and expressed EGFP (Fig. 3C).
-
Therefore we obtained higher qualtiy images with a confocal microscope (Fig. 4). The
-
cells were transfected with the mCAT-1-mCherry construct, 24h later infected by
-
the virus containing EGFP, and imaged 48h later. We found many cells that expressed
-
EGFP in the cytoplasm and the mCAT-1 receptor on the plasma membrane, whereas we did not
-
find cells that expressed EGFP but not the receptor, suggesting that
-
mCAT-1 expression is required for infection of the cells by the MuLV.
-
</p>
-
<p>
-
We also noticed that mCAT-1-mCherry was less present after transduction with
-
the viral particles. Possible explanations are that the receptor is internalized
-
after infection by a mechanism initiated by the virus, or that the expression
-
rate of the receptor decreases after infection. Since the particles can only
-
transfer their cargo into dividing cells, we often found pairs of cells that were
-
infected by the viral vector or observed high expression of the receptor in
-
cells next to targeted cells.
-
</p>
-
<p>
-
We were wondering whether receptor expression is indeed required for virus entry into the cell.
-
Although we observed by confocal microscopy that many cells that expressed EGFP
-
also expressed the receptor, we set out to correlate the expression levels of receptor and
-
EGFP, i.e. the cargo of the virus. Therefore we used FACS analysis to quantify
-
the levels of mCherry and EGFP fluorescence in all cells (Fig. 5). Although many cells that expressed
-
the receptor were not transduced with EGFP, we found that all cells that expressed EGFP
-
also expressed the receptor (Fig. 5, top right quadrant). Only a negligible number
-
of cells showed EGFP expression but low mCherry fluorescence (Fig. 5, top left quadrant).
-
This requirement for the presence of the receptor to allow efficient virus entry indicated
-
that the MuLV is indeed highly specific for the mCAT-1 receptor.
Figure 4: HEK-293T cells expressing mCAT-1-mCherry transduced with MuLV-GFP.
-
</p>
-
<p class="desc">
-
(A) Overlay of all three channels, (B) DAPI, (C) EGFP and (D) mCAT-1-mCherry.
-
Objective plan apo 60x, NA 1.40. <a href="https://2014.igem.org/Team:Freiburg/Notebook/Labjournal#MirjaHarms_Localization_receptor_Virus">Labjournal</a>
Figure 5: FACS data of HEK-293T cells tranfected with the receptor and
-
infected with MuLV-EGFP.
-
</p>
-
<p class="desc">
-
HEK-293T cells were transfected with the mCAT-1-mCherry and infected with MuLV-EGFP.
-
Cells were analyzed by flow cytometry 48 h after infection. <a href="https://2014.igem.org/Team:Freiburg/Notebook/Labjournal#MirjaHarms_differnt_kinds_of_receptors">Labjournal</a>
To enable efficient infection of cells with the virus, the time point for viral infection should match the time the receptor needs for expression in target cells. In order to determine the expression time of mCAT-1 in HEK-293T cells, we transfected the cells with the HA-tagged mCAT-1. Cells transfected with receptor DNA were analyzed after different incubation times. We found that the expression of the receptor peaked at 24 h after transfection (Fig. 6). In later experiments we used this time point for viral infections.
-
</p>
-
<p>
-
Since the presence of mCAT-1 on the cell surface is a main factor for viral tranduction efficiency, we quantified the expression of the receptor after transfection of HEK-293T cells with different concentrations of receptor DNA by Western blotting. We found that the expression of the receptor in the cell increases with higher amounts of transfected DNA (Fig. 7). However, we did not use such high DNA concentrations for our later experiments because we found that non-murine cells transfected with high amounts of transfected DNA died, probably due to overexpression of the mCAT-1 receptor.
Figure 6: Expression time of the receptor that was transfected into HEK-293T cells.
-
</p>
-
<p class="desc">
-
After transfection with mCAT-1-HA cells were lysed with RIPA buffer
-
at distinct time points. A Western blot was performed using an anti-HA antibody. <a href="https://2014.igem.org/Team:Freiburg/Notebook/Labjournal#MirjaHarms_Expression_time_receptor">Labjournal</a>
The specificity of our system is based on the murine CAT-1 receptor, which serves
as the viral entry site of our viral vector into the target cells. We demonstrate
that the virus can be used to stably integrate genes into the genome of murine cells.
We also targeted other cell lines by expressing the gene for the murine CAT-1 receptor
in these cells before viral transduction. Since mCAT-1 is naturally only present in murine
cell lines, we use human cell lines for transfection of the receptor. Expression of
a reporter suggests that only the cells expressing the mCAT-1 receptor are being
infected by the viral particles, thus making particular gene transfer possible.
Subcellular Localization of the Receptor
Since the mCAT-1 receptor serves as the entry site of our viral vector, it is essential
that it is expressed on the surface of target cells. In order to determine the localization
of the mCAT-1 receptor, we labeled the C-terminus of the mCAT-1 with the fluorescent protein
mCherry and transfected it into human embryonic kidney (HEK-293T) cells. After distinct
time points cells were imaged with a confocal scanning laser microscope. The mCAT1-mCherry
construct was found predominantly at the surface of the cells (Figs. 1, 2).
Receptor Functionality and Virus Specificity
Transduction of genes into murine cell lines that naturally express the mCAT-1
receptor occurred with an efficiency of over 80%. For our system we needed functional
expression of the receptor in non-murine cell lines, i.e. the receptor has to serve
as an entry site for the virus, and the virus has to efficiently deliver its cargo
into the target cell. We tested the functionality of the mCAT-1 receptor by expressing
it in HEK-293T cells and subsequent infection with the virus containing EGFP as a cargo.
The presence of green fluorescent cells in the infected cultures of different non-murine
cell lines indicated that the receptor was not only expressed but can also be used
as an entry site by the virus.
During our project we generated receptor constructs which were labeled with fluorescent
protein (for microscopy) or the HA tag (for Western blotting). Since we didn't know
whether the tags have an impact on viral infection capabilities, we tested them for
their functionality, confirming that all receptor constructs lead to viral infection
when expressed in non-murine cell lines (Fig. 3). For making the receptor visible for
fluorescent microscopy and analysis by flow cytometry, we used the mCherry tag
(constructs p14rz_005 and p14rz_006).
Owing to the limited resolution and sensitivity of the cell culture microscope used
for the images in Fig. 3, it was not clear whether the cells expressing the receptor
were the same cells that were transduced by the virus and expressed EGFP (Fig. 3C).
Therefore we obtained higher qualtiy images with a confocal microscope (Fig. 4). The
cells were transfected with the mCAT-1-mCherry construct, 24h later infected by
the virus containing EGFP, and imaged 48h later. We found many cells that expressed
EGFP in the cytoplasm and the mCAT-1 receptor on the plasma membrane, whereas we did not
find cells that expressed EGFP but not the receptor, suggesting that
mCAT-1 expression is required for infection of the cells by the MuLV.
We also noticed that mCAT-1-mCherry was less present after transduction with
the viral particles. Possible explanations are that the receptor is internalized
after infection by a mechanism initiated by the virus, or that the expression
rate of the receptor decreases after infection. Since the particles can only
transfer their cargo into dividing cells, we often found pairs of cells that were
infected by the viral vector or observed high expression of the receptor in
cells next to targeted cells.
We were wondering whether receptor expression is indeed required for virus entry into the cell.
Although we observed by confocal microscopy that many cells that expressed EGFP
also expressed the receptor, we set out to correlate the expression levels of receptor and
EGFP, i.e. the cargo of the virus. Therefore we used FACS analysis to quantify
the levels of mCherry and EGFP fluorescence in all cells (Fig. 5). Although many cells that expressed
the receptor were not transduced with EGFP, we found that all cells that expressed EGFP
also expressed the receptor (Fig. 5, top right quadrant). Only a negligible number
of cells showed EGFP expression but low mCherry fluorescence (Fig. 5, top left quadrant).
This requirement for the presence of the receptor to allow efficient virus entry indicated
that the MuLV is indeed highly specific for the mCAT-1 receptor.
Receptor Expression
To enable efficient infection of cells with the virus, the time point for viral infection should match the time the receptor needs for expression in target cells. In order to determine the expression time of mCAT-1 in HEK-293T cells, we transfected the cells with the HA-tagged mCAT-1. Cells transfected with receptor DNA were analyzed after different incubation times. We found that the expression of the receptor peaked at 24 h after transfection (Fig. 6). In later experiments we used this time point for viral infections.
Since the presence of mCAT-1 on the cell surface is a main factor for viral tranduction efficiency, we quantified the expression of the receptor after transfection of HEK-293T cells with different concentrations of receptor DNA by Western blotting. We found that the expression of the receptor in the cell increases with higher amounts of transfected DNA (Fig. 7). However, we did not use such high DNA concentrations for our later experiments because we found that non-murine cells transfected with high amounts of transfected DNA died, probably due to overexpression of the mCAT-1 receptor.