This will become a novel protocol for super charging an individual's immune system while also targeting a specific problem if necessary. Obviously a huge advance and a wonderful tool.
The cycle requires nine days of culturing, but then it can be injected without ado.
It is actually amazing what we are now seeing in the biological sciences..
The cycle requires nine days of culturing, but then it can be injected without ado.
It is actually amazing what we are now seeing in the biological sciences..
A code for reprogramming immune sentinels
For the first time, a research team at Lund University in Sweden has
successfully reprogrammed mouse and human skin cells into immune cells
called dendritic cells. The process is quick and effective, representing
a pioneering contribution for applying direct reprogramming for
inducing immunity. Importantly, the finding opens up the possibility of
developing novel dendritic cell-based immunotherapies against cancer.
Our so-called dendritic cells function as the immune system's
sentinels. Their task is to scan our tissues for foreign particles, such
as bacteria, viruses or cancer cells, and to devour them. They
subsequently break down the particles into smaller pieces, known as
antigens, and present them on the surface to the immune system's killer
cells (T-cells). In this way, the killer cells learn which infectious
agents and cancer cells they are to search for and kill.
Due to these key features, dendritic cell-based strategies have been
tested to treat cancer patients. However, cancer can affect the
dendritic cells in such a way that they get lost or become
dysfunctional. We therefore need to find new ways of generating
dendritic cells for every patient. Now, for the first time, a research
team in Lund has succeeded in obtaining dendritic cells by a process
called direct reprogramming. They have identified three essential
proteins (PU.1, IRF8 and BATF3) that are required and sufficient to
change the identity of mouse cells to make them become dendritic cells
instead. They have also confirmed that the same protein cocktail
reprograms human skin-derived cells to dendritic cells. This study is
now published and highlighted in the cover of the journal Science Immunology.
"From a tissue section taken from the skin, we can cultivate
millions of cells and reprogram them to dendritic cells in a process
that takes only nine days", says Filipe Pereira, the leader of the
research team that conducted the study.
"Our study has shown that reprogrammed cells have the ability to
effectively capture and present antigens to killer cells in the same way
as 'natural' dendritic cells." The researchers can even direct the
induced dendritic cells towards a particular target by presenting the
right antigen to them in a test tube, before introducing the cells into
the organism. This finding opens up future possibilities to develop new
strategies for immunotherapy against solid tumours and blood cancers,
beyond the treatments currently available.
"This represents an excellent opportunity to merge the fields of
cellular reprogramming and cancer immunotherapy. Generating dendritic
cells employing direct cell reprogramming is very attractive from a
therapeutic perspective: our studies may be useful in the clinic for
generation of patient-specific dendritic cells", according to Filipe
Pereira.
Cancer immunotherapy employs the cellular components of a persons'
immune system to fight cancer and it was awarded with the Nobel Prize in
Physiology or Medicine this year. By using reprogrammed dendritic cells
the probability of rejection by the organism is lower as these cells
can be generated from the skin of each individual patient.
"Tumours often undergo a number of mutations, developing into a
heterogeneous entity, which makes it more difficult for the immune
system to identify them as a threat. In a more creative perspective, we
now want to explore the process of dendritic cell reprogramming to
develop a cancer gene therapy. We are aiming at injecting the three
reprogramming proteins straight into the tumour forcing it to present
their own tumour-specific antigens. This allows the activation of the
killer cells against tumour cells and may lead to their elimination. We
have named this concept TrojanDC in an analogy with Homero's Trojan
horse. The great potential of this technology for cancer treatment lead
us to start a new company together with Lund University for the
development of this concept into a product that hopefully will reach
cancer patients one day", says Filipe Pereira.
"Additionally, our studies open up the possibility of reprogramming
other dendritic cell sub-types taking advantage of their distinct
functional features. A better understanding of the mechanisms that
determine the identity of immune sentinels and of how to use this
knowledge to reprogram other cell types into dendritic cells could make
these patient-specific cells useful in the clinic", concludes Filipe
Pereira.
For the first time, a research team at Lund University in Sweden has
successfully reprogrammed mouse and human skin cells into immune cells
called dendritic cells. The process is quick and effective, representing
a pioneering contribution for applying direct reprogramming for
inducing immunity. Importantly, the finding opens up the possibility of
developing novel dendritic cell-based immunotherapies against cancer.
Our so-called dendritic cells function as the immune system's
sentinels. Their task is to scan our tissues for foreign particles, such
as bacteria, viruses or cancer cells, and to devour them. They
subsequently break down the particles into smaller pieces, known as
antigens, and present them on the surface to the immune system's killer
cells (T-cells). In this way, the killer cells learn which infectious
agents and cancer cells they are to search for and kill.
Due to these key features, dendritic cell-based strategies have been
tested to treat cancer patients. However, cancer can affect the
dendritic cells in such a way that they get lost or become
dysfunctional. We therefore need to find new ways of generating
dendritic cells for every patient. Now, for the first time, a research
team in Lund has succeeded in obtaining dendritic cells by a process
called direct reprogramming. They have identified three essential
proteins (PU.1, IRF8 and BATF3) that are required and sufficient to
change the identity of mouse cells to make them become dendritic cells
instead. They have also confirmed that the same protein cocktail
reprograms human skin-derived cells to dendritic cells. This study is
now published and highlighted in the cover of the journal Science Immunology.
"From a tissue section taken from the skin, we can cultivate
millions of cells and reprogram them to dendritic cells in a process
that takes only nine days", says Filipe Pereira, the leader of the
research team that conducted the study.
"Our study has shown that reprogrammed cells have the ability to
effectively capture and present antigens to killer cells in the same way
as 'natural' dendritic cells." The researchers can even direct the
induced dendritic cells towards a particular target by presenting the
right antigen to them in a test tube, before introducing the cells into
the organism. This finding opens up future possibilities to develop new
strategies for immunotherapy against solid tumours and blood cancers,
beyond the treatments currently available.
"This represents an excellent opportunity to merge the fields of
cellular reprogramming and cancer immunotherapy. Generating dendritic
cells employing direct cell reprogramming is very attractive from a
therapeutic perspective: our studies may be useful in the clinic for
generation of patient-specific dendritic cells", according to Filipe
Pereira.
Cancer immunotherapy employs the cellular components of a persons'
immune system to fight cancer and it was awarded with the Nobel Prize in
Physiology or Medicine this year. By using reprogrammed dendritic cells
the probability of rejection by the organism is lower as these cells
can be generated from the skin of each individual patient.
"Tumours often undergo a number of mutations, developing into a
heterogeneous entity, which makes it more difficult for the immune
system to identify them as a threat. In a more creative perspective, we
now want to explore the process of dendritic cell reprogramming to
develop a cancer gene therapy. We are aiming at injecting the three
reprogramming proteins straight into the tumour forcing it to present
their own tumour-specific antigens. This allows the activation of the
killer cells against tumour cells and may lead to their elimination. We
have named this concept TrojanDC in an analogy with Homero's Trojan
horse. The great potential of this technology for cancer treatment lead
us to start a new company together with Lund University for the
development of this concept into a product that hopefully will reach
cancer patients one day", says Filipe Pereira.
"Additionally, our studies open up the possibility of reprogramming
other dendritic cell sub-types taking advantage of their distinct
functional features. A better understanding of the mechanisms that
determine the identity of immune sentinels and of how to use this
knowledge to reprogram other cell types into dendritic cells could make
these patient-specific cells useful in the clinic", concludes Filipe
Pereira.
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