TY - JOUR
T1 - Cells under pressure - Treatment of eukaryotic cells with high hydrostatic pressure, from physiologic aspects to pressure induced cell death
AU - Frey, Benjamin
AU - Janko, Christina
AU - Ebel, Nina
AU - Meister, Silke
AU - Schlücker, Eberhard
AU - Meyer-Pittroff, Roland
AU - Fietkau, Rainer
AU - Herrmann, Martin
AU - Gaipl, Udo S.
PY - 2008
Y1 - 2008
N2 - The research on high hydrostatic pressure in medicine and life sciences is multifaceted. According to the used pressure head the research has to be divided into two different parts. To study physiological aspects of pressure on eukaryotic cells physiological pressure (pHHP; < 100 MPa) is used. pHHP induces morphological alterations in the cellular organelles and evokes a reversible stress response similar to the well known heat shock response. pHHP induces highly reversible alterations and normally does not affect cellular viability. The treatment of eukaryotic cells with nonphysiological pressure (HHP; ≥ 100 MPa) reveals different outcomes. Treatment with HHP < 150 MPa does not markedly affect viability of human cells, but induces apoptosis in murine cells. In human cells apoptosis is observed after treatment with ≥ 200 MPa. Moreover, HHP treatment with > 300 MPa leads to necrosis. Therefore, HHP plays a role for the sterilisation of human transplants, of food stuff, and pharmaceuticals. Human tumour cells subjected to HHP > 300 MPa display a necrotic phenotype along with a gelificated cytoplasm, preserve their shape, and retain their immunogenicity. These observations favour the use of HHP to produce whole cell based tumour vaccines. Further experiments revealed that the increment of pressure as well as the pressure holding time influences the cell death of tumour cells. We conclude that high hydrostatic pressure offers both, an economic, easy to apply, clean, and fast technique for the generation of vaccines, and a promising tool to study physiological aspects.
AB - The research on high hydrostatic pressure in medicine and life sciences is multifaceted. According to the used pressure head the research has to be divided into two different parts. To study physiological aspects of pressure on eukaryotic cells physiological pressure (pHHP; < 100 MPa) is used. pHHP induces morphological alterations in the cellular organelles and evokes a reversible stress response similar to the well known heat shock response. pHHP induces highly reversible alterations and normally does not affect cellular viability. The treatment of eukaryotic cells with nonphysiological pressure (HHP; ≥ 100 MPa) reveals different outcomes. Treatment with HHP < 150 MPa does not markedly affect viability of human cells, but induces apoptosis in murine cells. In human cells apoptosis is observed after treatment with ≥ 200 MPa. Moreover, HHP treatment with > 300 MPa leads to necrosis. Therefore, HHP plays a role for the sterilisation of human transplants, of food stuff, and pharmaceuticals. Human tumour cells subjected to HHP > 300 MPa display a necrotic phenotype along with a gelificated cytoplasm, preserve their shape, and retain their immunogenicity. These observations favour the use of HHP to produce whole cell based tumour vaccines. Further experiments revealed that the increment of pressure as well as the pressure holding time influences the cell death of tumour cells. We conclude that high hydrostatic pressure offers both, an economic, easy to apply, clean, and fast technique for the generation of vaccines, and a promising tool to study physiological aspects.
KW - Apoptosis
KW - Cell death
KW - High hydrostatic pressure
KW - Immunogenicity
KW - Necrosis
KW - Stress response
KW - Transplants
KW - Tumour vaccine
UR - http://www.scopus.com/inward/record.url?scp=55249091823&partnerID=8YFLogxK
U2 - 10.2174/092986708785909166
DO - 10.2174/092986708785909166
M3 - Review article
C2 - 18855663
AN - SCOPUS:55249091823
SN - 0929-8673
VL - 15
SP - 2329
EP - 2336
JO - Current Medicinal Chemistry
JF - Current Medicinal Chemistry
IS - 23
ER -