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Role of SerpinB2 in tumour cellsLee Major Unknown Date (has links)
SerpinB2 (aka plasminogen activator type 2) is well described as an extracellular inhibitor of urokinase-type plasminogen activator (uPA). However, the majority of SerpinB2 is retained intracellularly, and many uPA-independent activities have been reported for SerpinB2 suggesting an alternate function. This thesis explores the role of SerpinB2 in epithelial tumour cell lines, highlights the problems associated with various expression systems and argues that SerpinB2 has no role in growth or apoptosis of tumour cells. A potential role for immune modulation and angiogenesis is suggested in in vivo models. Previous research using SerpinB2 transfected, clonally selected tumour cell lines suggested that SerpinB2 regulates the retinoblastoma tumour suppressor protein (Rb) by binding and protecting Rb from degradation. Despite the use of two techniques under numerous conditions and positive controls, no significant interaction between SerpinB2 and Rb was found. SerpinB2 was reported to bind Rb through a PENF homology motif located within the SerpinB2 C-D interhelical loop region. The PENF homology motif was postulated to represent the motif responsible for binding to the C-pocket of Rb. Epstein Barr Virus nuclear antigen 6 (EBNA6) is a known Rb binding protein, which contains two predicted PENF homology motifs. However, mutation of the two PENF homology motifs within EBNA6 did not reduce Rb binding. Furthermore, the SerpinB2 PENF homology motif is actually not well conserved between SerpinB2 proteins from multiple species, whereas other regions of the SerpinB2 C-D loop show a high level of conservation. These data do not support a role for SerpinB2 and the PENF homology motif in Rb binding. SerpinB2 has been proposed to have a role in regulating growth and apoptosis. To further investigate this proposed phenotype of SerpinB2, SerpinB2 was expressed in a range of epithelial tumour lines using transient transfection. No change in growth, apoptosis or Rb levels were found. After ≈2-3 month antibiotic selection for the SerpinB2-expressing plasmid, SerpinB2 protein was lost without the loss of the transgene, indicating selective pressure against long-term SerpinB2 protein expression. To further investigate long-term SerpinB2 expression adenovirus and lentivirus vectors were used. Infection of tumour cell lines with adenovirus vectors expressing SerpinB2 resulted in reduced cell growth, characterised by increased p53 (but not Rb) levels and G2 arrest or apoptosis. When SerpinB2 expressing lentivirus vectors were used to transduce the same tumour cell lines, high levels of long-term expression of functional SerpinB2 was achieved. However, SerpinB2-expressing cell lines showed no differences in growth, proliferation, Rb levels, or apoptosis induced by a range of agents. Growth and apoptosis observed with adenovirus SerpinB2 had all the characteristics of adenovirus-associated toxicity, which has been reported previously for specific proteins. These experiments highlighted the problems associated with SerpinB2 expression systems and suggest that SerpinB2 expression per se is not toxic nor has a role in regulating Rb, growth and apoptosis. Screening of a number of tumour cell lines identified the HPV16 transformed cervical cancer line as expressing high levels of SerpinB2. SerpinB2 was located both extracellularly and intracellularly with a cytoplasmic and nuclear distribution. A high molecular weight SerpinB2 species was identified in CaSki cells and was shown to be the N-linked glycosylated species. Sequencing showed the protein to be Type A SerpinB2 and the protein was shown to form an inhibitory complex with uPA. An abundant low molecular weight SerpinB2 species was also identified in CaSki cell supernatants and appeared to be a proteolytic fragment of SerpinB2. Treatment of CaSki with PMA, TNFα and IFNγ increased SerpinB2 levels. Lentiviral based shRNA failed to significantly down regulate SerpinB2 expression and increasing SerpinB2 levels with lentiviral expression did not change growth, apoptosis, Rb levels or E7 transcription. Lentiviral expression of SerpinB2 in (normally SerpinB2 negative) HPV16 transformed SiHa cells, also failed to show changes in Rb levels or E7 transcription. CaSki thus express wild-type and functional SerpinB2, but no evidence could found that SerpinB2 effects HPV16 E7 transcription or Rb levels. The data presented identifies CaSki as valuable source of biologically functional SerpinB2. SerpinB2 expression in breast cancer cells has been associated with positive prognosis. Tubo, a SerpinB2-negative murine breast carcinoma cell line, was transduced with lentivirus expressing SerpinB2 and grown subcutaneously in BALB/c mice. SerpinB2 expressing tumours appeared red and were larger than control tumours. Furthermore, SerpinB2 expressing tumours had a ≈2 fold higher density of blood vessels when compared to Tubo and Tubo expressing EGFP. Mice carrying tumours expressing SerpinB2 also showed reduced anti-tumour IgG2 responses. These data suggest that a role for SerpinB2 in regulating angiogenesis and antitumour immunity. In conclusion, this thesis challenges the notion that SerpinB2 regulates Rb, cell cycle, and apoptosis and suggests a potential role for SerpinB2 in tumour angiogenesis and immunity.
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Role of SerpinB2 in tumour cellsLee Major Unknown Date (has links)
SerpinB2 (aka plasminogen activator type 2) is well described as an extracellular inhibitor of urokinase-type plasminogen activator (uPA). However, the majority of SerpinB2 is retained intracellularly, and many uPA-independent activities have been reported for SerpinB2 suggesting an alternate function. This thesis explores the role of SerpinB2 in epithelial tumour cell lines, highlights the problems associated with various expression systems and argues that SerpinB2 has no role in growth or apoptosis of tumour cells. A potential role for immune modulation and angiogenesis is suggested in in vivo models. Previous research using SerpinB2 transfected, clonally selected tumour cell lines suggested that SerpinB2 regulates the retinoblastoma tumour suppressor protein (Rb) by binding and protecting Rb from degradation. Despite the use of two techniques under numerous conditions and positive controls, no significant interaction between SerpinB2 and Rb was found. SerpinB2 was reported to bind Rb through a PENF homology motif located within the SerpinB2 C-D interhelical loop region. The PENF homology motif was postulated to represent the motif responsible for binding to the C-pocket of Rb. Epstein Barr Virus nuclear antigen 6 (EBNA6) is a known Rb binding protein, which contains two predicted PENF homology motifs. However, mutation of the two PENF homology motifs within EBNA6 did not reduce Rb binding. Furthermore, the SerpinB2 PENF homology motif is actually not well conserved between SerpinB2 proteins from multiple species, whereas other regions of the SerpinB2 C-D loop show a high level of conservation. These data do not support a role for SerpinB2 and the PENF homology motif in Rb binding. SerpinB2 has been proposed to have a role in regulating growth and apoptosis. To further investigate this proposed phenotype of SerpinB2, SerpinB2 was expressed in a range of epithelial tumour lines using transient transfection. No change in growth, apoptosis or Rb levels were found. After ≈2-3 month antibiotic selection for the SerpinB2-expressing plasmid, SerpinB2 protein was lost without the loss of the transgene, indicating selective pressure against long-term SerpinB2 protein expression. To further investigate long-term SerpinB2 expression adenovirus and lentivirus vectors were used. Infection of tumour cell lines with adenovirus vectors expressing SerpinB2 resulted in reduced cell growth, characterised by increased p53 (but not Rb) levels and G2 arrest or apoptosis. When SerpinB2 expressing lentivirus vectors were used to transduce the same tumour cell lines, high levels of long-term expression of functional SerpinB2 was achieved. However, SerpinB2-expressing cell lines showed no differences in growth, proliferation, Rb levels, or apoptosis induced by a range of agents. Growth and apoptosis observed with adenovirus SerpinB2 had all the characteristics of adenovirus-associated toxicity, which has been reported previously for specific proteins. These experiments highlighted the problems associated with SerpinB2 expression systems and suggest that SerpinB2 expression per se is not toxic nor has a role in regulating Rb, growth and apoptosis. Screening of a number of tumour cell lines identified the HPV16 transformed cervical cancer line as expressing high levels of SerpinB2. SerpinB2 was located both extracellularly and intracellularly with a cytoplasmic and nuclear distribution. A high molecular weight SerpinB2 species was identified in CaSki cells and was shown to be the N-linked glycosylated species. Sequencing showed the protein to be Type A SerpinB2 and the protein was shown to form an inhibitory complex with uPA. An abundant low molecular weight SerpinB2 species was also identified in CaSki cell supernatants and appeared to be a proteolytic fragment of SerpinB2. Treatment of CaSki with PMA, TNFα and IFNγ increased SerpinB2 levels. Lentiviral based shRNA failed to significantly down regulate SerpinB2 expression and increasing SerpinB2 levels with lentiviral expression did not change growth, apoptosis, Rb levels or E7 transcription. Lentiviral expression of SerpinB2 in (normally SerpinB2 negative) HPV16 transformed SiHa cells, also failed to show changes in Rb levels or E7 transcription. CaSki thus express wild-type and functional SerpinB2, but no evidence could found that SerpinB2 effects HPV16 E7 transcription or Rb levels. The data presented identifies CaSki as valuable source of biologically functional SerpinB2. SerpinB2 expression in breast cancer cells has been associated with positive prognosis. Tubo, a SerpinB2-negative murine breast carcinoma cell line, was transduced with lentivirus expressing SerpinB2 and grown subcutaneously in BALB/c mice. SerpinB2 expressing tumours appeared red and were larger than control tumours. Furthermore, SerpinB2 expressing tumours had a ≈2 fold higher density of blood vessels when compared to Tubo and Tubo expressing EGFP. Mice carrying tumours expressing SerpinB2 also showed reduced anti-tumour IgG2 responses. These data suggest that a role for SerpinB2 in regulating angiogenesis and antitumour immunity. In conclusion, this thesis challenges the notion that SerpinB2 regulates Rb, cell cycle, and apoptosis and suggests a potential role for SerpinB2 in tumour angiogenesis and immunity.
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Role of SerpinB2 in tumour cellsLee Major Unknown Date (has links)
SerpinB2 (aka plasminogen activator type 2) is well described as an extracellular inhibitor of urokinase-type plasminogen activator (uPA). However, the majority of SerpinB2 is retained intracellularly, and many uPA-independent activities have been reported for SerpinB2 suggesting an alternate function. This thesis explores the role of SerpinB2 in epithelial tumour cell lines, highlights the problems associated with various expression systems and argues that SerpinB2 has no role in growth or apoptosis of tumour cells. A potential role for immune modulation and angiogenesis is suggested in in vivo models. Previous research using SerpinB2 transfected, clonally selected tumour cell lines suggested that SerpinB2 regulates the retinoblastoma tumour suppressor protein (Rb) by binding and protecting Rb from degradation. Despite the use of two techniques under numerous conditions and positive controls, no significant interaction between SerpinB2 and Rb was found. SerpinB2 was reported to bind Rb through a PENF homology motif located within the SerpinB2 C-D interhelical loop region. The PENF homology motif was postulated to represent the motif responsible for binding to the C-pocket of Rb. Epstein Barr Virus nuclear antigen 6 (EBNA6) is a known Rb binding protein, which contains two predicted PENF homology motifs. However, mutation of the two PENF homology motifs within EBNA6 did not reduce Rb binding. Furthermore, the SerpinB2 PENF homology motif is actually not well conserved between SerpinB2 proteins from multiple species, whereas other regions of the SerpinB2 C-D loop show a high level of conservation. These data do not support a role for SerpinB2 and the PENF homology motif in Rb binding. SerpinB2 has been proposed to have a role in regulating growth and apoptosis. To further investigate this proposed phenotype of SerpinB2, SerpinB2 was expressed in a range of epithelial tumour lines using transient transfection. No change in growth, apoptosis or Rb levels were found. After ≈2-3 month antibiotic selection for the SerpinB2-expressing plasmid, SerpinB2 protein was lost without the loss of the transgene, indicating selective pressure against long-term SerpinB2 protein expression. To further investigate long-term SerpinB2 expression adenovirus and lentivirus vectors were used. Infection of tumour cell lines with adenovirus vectors expressing SerpinB2 resulted in reduced cell growth, characterised by increased p53 (but not Rb) levels and G2 arrest or apoptosis. When SerpinB2 expressing lentivirus vectors were used to transduce the same tumour cell lines, high levels of long-term expression of functional SerpinB2 was achieved. However, SerpinB2-expressing cell lines showed no differences in growth, proliferation, Rb levels, or apoptosis induced by a range of agents. Growth and apoptosis observed with adenovirus SerpinB2 had all the characteristics of adenovirus-associated toxicity, which has been reported previously for specific proteins. These experiments highlighted the problems associated with SerpinB2 expression systems and suggest that SerpinB2 expression per se is not toxic nor has a role in regulating Rb, growth and apoptosis. Screening of a number of tumour cell lines identified the HPV16 transformed cervical cancer line as expressing high levels of SerpinB2. SerpinB2 was located both extracellularly and intracellularly with a cytoplasmic and nuclear distribution. A high molecular weight SerpinB2 species was identified in CaSki cells and was shown to be the N-linked glycosylated species. Sequencing showed the protein to be Type A SerpinB2 and the protein was shown to form an inhibitory complex with uPA. An abundant low molecular weight SerpinB2 species was also identified in CaSki cell supernatants and appeared to be a proteolytic fragment of SerpinB2. Treatment of CaSki with PMA, TNFα and IFNγ increased SerpinB2 levels. Lentiviral based shRNA failed to significantly down regulate SerpinB2 expression and increasing SerpinB2 levels with lentiviral expression did not change growth, apoptosis, Rb levels or E7 transcription. Lentiviral expression of SerpinB2 in (normally SerpinB2 negative) HPV16 transformed SiHa cells, also failed to show changes in Rb levels or E7 transcription. CaSki thus express wild-type and functional SerpinB2, but no evidence could found that SerpinB2 effects HPV16 E7 transcription or Rb levels. The data presented identifies CaSki as valuable source of biologically functional SerpinB2. SerpinB2 expression in breast cancer cells has been associated with positive prognosis. Tubo, a SerpinB2-negative murine breast carcinoma cell line, was transduced with lentivirus expressing SerpinB2 and grown subcutaneously in BALB/c mice. SerpinB2 expressing tumours appeared red and were larger than control tumours. Furthermore, SerpinB2 expressing tumours had a ≈2 fold higher density of blood vessels when compared to Tubo and Tubo expressing EGFP. Mice carrying tumours expressing SerpinB2 also showed reduced anti-tumour IgG2 responses. These data suggest that a role for SerpinB2 in regulating angiogenesis and antitumour immunity. In conclusion, this thesis challenges the notion that SerpinB2 regulates Rb, cell cycle, and apoptosis and suggests a potential role for SerpinB2 in tumour angiogenesis and immunity.
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Role of SerpinB2 in tumour cellsLee Major Unknown Date (has links)
SerpinB2 (aka plasminogen activator type 2) is well described as an extracellular inhibitor of urokinase-type plasminogen activator (uPA). However, the majority of SerpinB2 is retained intracellularly, and many uPA-independent activities have been reported for SerpinB2 suggesting an alternate function. This thesis explores the role of SerpinB2 in epithelial tumour cell lines, highlights the problems associated with various expression systems and argues that SerpinB2 has no role in growth or apoptosis of tumour cells. A potential role for immune modulation and angiogenesis is suggested in in vivo models. Previous research using SerpinB2 transfected, clonally selected tumour cell lines suggested that SerpinB2 regulates the retinoblastoma tumour suppressor protein (Rb) by binding and protecting Rb from degradation. Despite the use of two techniques under numerous conditions and positive controls, no significant interaction between SerpinB2 and Rb was found. SerpinB2 was reported to bind Rb through a PENF homology motif located within the SerpinB2 C-D interhelical loop region. The PENF homology motif was postulated to represent the motif responsible for binding to the C-pocket of Rb. Epstein Barr Virus nuclear antigen 6 (EBNA6) is a known Rb binding protein, which contains two predicted PENF homology motifs. However, mutation of the two PENF homology motifs within EBNA6 did not reduce Rb binding. Furthermore, the SerpinB2 PENF homology motif is actually not well conserved between SerpinB2 proteins from multiple species, whereas other regions of the SerpinB2 C-D loop show a high level of conservation. These data do not support a role for SerpinB2 and the PENF homology motif in Rb binding. SerpinB2 has been proposed to have a role in regulating growth and apoptosis. To further investigate this proposed phenotype of SerpinB2, SerpinB2 was expressed in a range of epithelial tumour lines using transient transfection. No change in growth, apoptosis or Rb levels were found. After ≈2-3 month antibiotic selection for the SerpinB2-expressing plasmid, SerpinB2 protein was lost without the loss of the transgene, indicating selective pressure against long-term SerpinB2 protein expression. To further investigate long-term SerpinB2 expression adenovirus and lentivirus vectors were used. Infection of tumour cell lines with adenovirus vectors expressing SerpinB2 resulted in reduced cell growth, characterised by increased p53 (but not Rb) levels and G2 arrest or apoptosis. When SerpinB2 expressing lentivirus vectors were used to transduce the same tumour cell lines, high levels of long-term expression of functional SerpinB2 was achieved. However, SerpinB2-expressing cell lines showed no differences in growth, proliferation, Rb levels, or apoptosis induced by a range of agents. Growth and apoptosis observed with adenovirus SerpinB2 had all the characteristics of adenovirus-associated toxicity, which has been reported previously for specific proteins. These experiments highlighted the problems associated with SerpinB2 expression systems and suggest that SerpinB2 expression per se is not toxic nor has a role in regulating Rb, growth and apoptosis. Screening of a number of tumour cell lines identified the HPV16 transformed cervical cancer line as expressing high levels of SerpinB2. SerpinB2 was located both extracellularly and intracellularly with a cytoplasmic and nuclear distribution. A high molecular weight SerpinB2 species was identified in CaSki cells and was shown to be the N-linked glycosylated species. Sequencing showed the protein to be Type A SerpinB2 and the protein was shown to form an inhibitory complex with uPA. An abundant low molecular weight SerpinB2 species was also identified in CaSki cell supernatants and appeared to be a proteolytic fragment of SerpinB2. Treatment of CaSki with PMA, TNFα and IFNγ increased SerpinB2 levels. Lentiviral based shRNA failed to significantly down regulate SerpinB2 expression and increasing SerpinB2 levels with lentiviral expression did not change growth, apoptosis, Rb levels or E7 transcription. Lentiviral expression of SerpinB2 in (normally SerpinB2 negative) HPV16 transformed SiHa cells, also failed to show changes in Rb levels or E7 transcription. CaSki thus express wild-type and functional SerpinB2, but no evidence could found that SerpinB2 effects HPV16 E7 transcription or Rb levels. The data presented identifies CaSki as valuable source of biologically functional SerpinB2. SerpinB2 expression in breast cancer cells has been associated with positive prognosis. Tubo, a SerpinB2-negative murine breast carcinoma cell line, was transduced with lentivirus expressing SerpinB2 and grown subcutaneously in BALB/c mice. SerpinB2 expressing tumours appeared red and were larger than control tumours. Furthermore, SerpinB2 expressing tumours had a ≈2 fold higher density of blood vessels when compared to Tubo and Tubo expressing EGFP. Mice carrying tumours expressing SerpinB2 also showed reduced anti-tumour IgG2 responses. These data suggest that a role for SerpinB2 in regulating angiogenesis and antitumour immunity. In conclusion, this thesis challenges the notion that SerpinB2 regulates Rb, cell cycle, and apoptosis and suggests a potential role for SerpinB2 in tumour angiogenesis and immunity.
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Role of SerpinB2 in tumour cellsLee Major Unknown Date (has links)
SerpinB2 (aka plasminogen activator type 2) is well described as an extracellular inhibitor of urokinase-type plasminogen activator (uPA). However, the majority of SerpinB2 is retained intracellularly, and many uPA-independent activities have been reported for SerpinB2 suggesting an alternate function. This thesis explores the role of SerpinB2 in epithelial tumour cell lines, highlights the problems associated with various expression systems and argues that SerpinB2 has no role in growth or apoptosis of tumour cells. A potential role for immune modulation and angiogenesis is suggested in in vivo models. Previous research using SerpinB2 transfected, clonally selected tumour cell lines suggested that SerpinB2 regulates the retinoblastoma tumour suppressor protein (Rb) by binding and protecting Rb from degradation. Despite the use of two techniques under numerous conditions and positive controls, no significant interaction between SerpinB2 and Rb was found. SerpinB2 was reported to bind Rb through a PENF homology motif located within the SerpinB2 C-D interhelical loop region. The PENF homology motif was postulated to represent the motif responsible for binding to the C-pocket of Rb. Epstein Barr Virus nuclear antigen 6 (EBNA6) is a known Rb binding protein, which contains two predicted PENF homology motifs. However, mutation of the two PENF homology motifs within EBNA6 did not reduce Rb binding. Furthermore, the SerpinB2 PENF homology motif is actually not well conserved between SerpinB2 proteins from multiple species, whereas other regions of the SerpinB2 C-D loop show a high level of conservation. These data do not support a role for SerpinB2 and the PENF homology motif in Rb binding. SerpinB2 has been proposed to have a role in regulating growth and apoptosis. To further investigate this proposed phenotype of SerpinB2, SerpinB2 was expressed in a range of epithelial tumour lines using transient transfection. No change in growth, apoptosis or Rb levels were found. After ≈2-3 month antibiotic selection for the SerpinB2-expressing plasmid, SerpinB2 protein was lost without the loss of the transgene, indicating selective pressure against long-term SerpinB2 protein expression. To further investigate long-term SerpinB2 expression adenovirus and lentivirus vectors were used. Infection of tumour cell lines with adenovirus vectors expressing SerpinB2 resulted in reduced cell growth, characterised by increased p53 (but not Rb) levels and G2 arrest or apoptosis. When SerpinB2 expressing lentivirus vectors were used to transduce the same tumour cell lines, high levels of long-term expression of functional SerpinB2 was achieved. However, SerpinB2-expressing cell lines showed no differences in growth, proliferation, Rb levels, or apoptosis induced by a range of agents. Growth and apoptosis observed with adenovirus SerpinB2 had all the characteristics of adenovirus-associated toxicity, which has been reported previously for specific proteins. These experiments highlighted the problems associated with SerpinB2 expression systems and suggest that SerpinB2 expression per se is not toxic nor has a role in regulating Rb, growth and apoptosis. Screening of a number of tumour cell lines identified the HPV16 transformed cervical cancer line as expressing high levels of SerpinB2. SerpinB2 was located both extracellularly and intracellularly with a cytoplasmic and nuclear distribution. A high molecular weight SerpinB2 species was identified in CaSki cells and was shown to be the N-linked glycosylated species. Sequencing showed the protein to be Type A SerpinB2 and the protein was shown to form an inhibitory complex with uPA. An abundant low molecular weight SerpinB2 species was also identified in CaSki cell supernatants and appeared to be a proteolytic fragment of SerpinB2. Treatment of CaSki with PMA, TNFα and IFNγ increased SerpinB2 levels. Lentiviral based shRNA failed to significantly down regulate SerpinB2 expression and increasing SerpinB2 levels with lentiviral expression did not change growth, apoptosis, Rb levels or E7 transcription. Lentiviral expression of SerpinB2 in (normally SerpinB2 negative) HPV16 transformed SiHa cells, also failed to show changes in Rb levels or E7 transcription. CaSki thus express wild-type and functional SerpinB2, but no evidence could found that SerpinB2 effects HPV16 E7 transcription or Rb levels. The data presented identifies CaSki as valuable source of biologically functional SerpinB2. SerpinB2 expression in breast cancer cells has been associated with positive prognosis. Tubo, a SerpinB2-negative murine breast carcinoma cell line, was transduced with lentivirus expressing SerpinB2 and grown subcutaneously in BALB/c mice. SerpinB2 expressing tumours appeared red and were larger than control tumours. Furthermore, SerpinB2 expressing tumours had a ≈2 fold higher density of blood vessels when compared to Tubo and Tubo expressing EGFP. Mice carrying tumours expressing SerpinB2 also showed reduced anti-tumour IgG2 responses. These data suggest that a role for SerpinB2 in regulating angiogenesis and antitumour immunity. In conclusion, this thesis challenges the notion that SerpinB2 regulates Rb, cell cycle, and apoptosis and suggests a potential role for SerpinB2 in tumour angiogenesis and immunity.
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