Literature DB >> 7730632

IL-2 enhances the function of recombinant poxvirus-based vaccines in the treatment of established pulmonary metastases.

V Bronte1, K Tsung, J B Rao, P W Chen, M Wang, S A Rosenberg, N P Restifo.   

Abstract

Neoplastic cells are generally poor immunogens. Transfection of the murine tumor CT-26 with beta-galactosidase (beta-gal), a protein from Escherichia coli, did not alter its growth rate in vivo, or its lethality, and did not elicit a measurable anti-beta-gal immune response. Immunization with beta-gal-expressing recombinant vaccinia viruses (rVV) elicited specific anti-beta-gal cytolytic T lymphocytes, but rVV-beta-gal was only marginally therapeutic when given to tumor-bearing mice. With the aim of expanding the immune response against beta-gal, used here as a model tumor Ag, we gave mice exogenous IL-2 starting 12 h after the poxvirus. The therapeutic effectiveness of the combination of poxvirus and IL-2 was far greater than either of these treatments alone. When the cDNA for IL-2 was inserted into the viral genome of the rVV construct to make a double recombinant (drVV), antitumor activity was further augmented. One mechanism of action may be the enhanced activation or expansion of cytotoxic T cells, because a marked increase in primary cytotoxic responses against vaccinia determinants was observed. Interestingly, other cytokines (mGM-CSF, mTNF-alpha, and mIFN-gamma) inserted into the rVV genome did not modify the efficacy of the rVV constructs. The increase in specific CTL responses against beta-gal by drVV expressing the tumor-associated Ags (TAA) and IL-2 was more pronounced in mice bearing the lacZ-transduced tumor than in those bearing the parental cell line, suggesting that the TAA presented by growing tumor cells can either pre-activate or otherwise amplify the immune response induced by the rVV. Unfortunately, in several long-term surviving mice, tumor recurred that no longer expressed beta-gal. These results indicate that treatment of disseminated tumors by using recombinant viruses expressing TAA can be enhanced by IL-2 provided exogenously, or encoded within the recombinant virus.

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Year:  1995        PMID: 7730632      PMCID: PMC2041892     

Source DB:  PubMed          Journal:  J Immunol        ISSN: 0022-1767            Impact factor:   5.422


  52 in total

1.  Bacterial lacZ gene as a highly sensitive marker to detect micrometastasis formation during tumor progression.

Authors:  W C Lin; T P Pretlow; T G Pretlow; L A Culp
Journal:  Cancer Res       Date:  1990-05-01       Impact factor: 12.701

2.  Attenuation and immunogenicity in primates of vaccinia virus recombinants expressing human interleukin-2.

Authors:  C Flexner; B Moss; W T London; B R Murphy
Journal:  Vaccine       Date:  1990-02       Impact factor: 3.641

3.  Interleukin-2 production by tumor cells bypasses T helper function in the generation of an antitumor response.

Authors:  E R Fearon; D M Pardoll; T Itaya; P Golumbek; H I Levitsky; J W Simons; H Karasuyama; B Vogelstein; P Frost
Journal:  Cell       Date:  1990-02-09       Impact factor: 41.582

4.  Vaccinia recombinants expressing early bovine papilloma virus (BPV1) proteins: retardation of BPV1 tumour development.

Authors:  G Meneguzzi; M P Kieny; J P Lecocq; P Chambon; F Cuzin; R Lathe
Journal:  Vaccine       Date:  1990-06       Impact factor: 3.641

5.  Use of tumor-infiltrating lymphocytes and interleukin-2 in the immunotherapy of patients with metastatic melanoma. A preliminary report.

Authors:  S A Rosenberg; B S Packard; P M Aebersold; D Solomon; S L Topalian; S T Toy; P Simon; M T Lotze; J C Yang; C A Seipp
Journal:  N Engl J Med       Date:  1988-12-22       Impact factor: 91.245

6.  Recombinant vaccinia virus vaccine against the human melanoma antigen p97 for use in immunotherapy.

Authors:  C D Estin; U S Stevenson; G D Plowman; S L Hu; P Sridhar; I Hellström; J P Brown; K E Hellström
Journal:  Proc Natl Acad Sci U S A       Date:  1988-02       Impact factor: 11.205

7.  Vaccinia-interleukin 2 recombinant virus or exogenous interleukin 2 does not alter the magnitude or immune response gene defects of the cytotoxic T-cell response to vaccinia virus in vivo.

Authors:  A Müllbacher; I A Ramshaw; B E Coupar
Journal:  Scand J Immunol       Date:  1989-01       Impact factor: 3.487

8.  Recombinant fowlpox virus inducing protective immunity in non-avian species.

Authors:  J Taylor; R Weinberg; B Languet; P Desmettre; E Paoletti
Journal:  Vaccine       Date:  1988-12       Impact factor: 3.641

9.  Immunization with a vaccinia virus recombinant expressing herpes simplex virus type 1 glycoprotein D: long-term protection and effect of revaccination.

Authors:  J F Rooney; C Wohlenberg; K J Cremer; B Moss; A L Notkins
Journal:  J Virol       Date:  1988-05       Impact factor: 5.103

10.  Immunogenic (tum-) variants of mouse tumor P815: cloning of the gene of tum- antigen P91A and identification of the tum- mutation.

Authors:  E De Plaen; C Lurquin; A Van Pel; B Mariamé; J P Szikora; T Wölfel; C Sibille; P Chomez; T Boon
Journal:  Proc Natl Acad Sci U S A       Date:  1988-04       Impact factor: 11.205
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  40 in total

Review 1.  Nucleic acid vaccines: tasks and tactics.

Authors:  B S McKenzie; A J Corbett; J L Brady; C M Dyer; R A Strugnell; S J Kent; D R Kramer; J S Boyle; A M Lew
Journal:  Immunol Res       Date:  2001       Impact factor: 2.829

2.  Dendritic cells infected with poxviruses encoding MART-1/Melan A sensitize T lymphocytes in vitro.

Authors:  C J Kim; T Prevette; J Cormier; W Overwijk; M Roden; N P Restifo; S A Rosenberg; F M Marincola
Journal:  J Immunother       Date:  1997-07       Impact factor: 4.456

3.  Unopposed production of granulocyte-macrophage colony-stimulating factor by tumors inhibits CD8+ T cell responses by dysregulating antigen-presenting cell maturation.

Authors:  V Bronte; D B Chappell; E Apolloni; A Cabrelle; M Wang; P Hwu; N P Restifo
Journal:  J Immunol       Date:  1999-05-15       Impact factor: 5.422

4.  Identification of a CD11b(+)/Gr-1(+)/CD31(+) myeloid progenitor capable of activating or suppressing CD8(+) T cells.

Authors:  V Bronte; E Apolloni; A Cabrelle; R Ronca; P Serafini; P Zamboni; N P Restifo; P Zanovello
Journal:  Blood       Date:  2000-12-01       Impact factor: 22.113

5.  Chloride secretion in the trachea of null cystic fibrosis mice: the effects of transfection with pTrial10-CFTR2.

Authors:  L J MacVinish; D R Gill; S C Hyde; K A Mofford; M J Evans; C F Higgins; W H Colledge; L Huang; F Sorgi; R Ratcliff; A W Cuthbert
Journal:  J Physiol       Date:  1997-03-15       Impact factor: 5.182

Review 6.  The next wave of recombinant and synthetic anticancer vaccines.

Authors:  K R Irvine; N P Restifo
Journal:  Semin Cancer Biol       Date:  1995-12       Impact factor: 15.707

Review 7.  T-cell recognition of self peptides as tumor rejection antigens.

Authors:  Y Kawakami; S A Rosenberg
Journal:  Immunol Res       Date:  1996       Impact factor: 2.829

Review 8.  The new vaccines: building viruses that elicit antitumor immunity.

Authors:  N P Restifo
Journal:  Curr Opin Immunol       Date:  1996-10       Impact factor: 7.486

9.  Construction and characterization of a triple-recombinant vaccinia virus encoding B7-1, interleukin 12, and a model tumor antigen.

Authors:  M W Carroll; W W Overwijk; D R Surman; K Tsung; B Moss; N P Restifo
Journal:  J Natl Cancer Inst       Date:  1998-12-16       Impact factor: 13.506

10.  Immunizing patients with metastatic melanoma using recombinant adenoviruses encoding MART-1 or gp100 melanoma antigens.

Authors:  S A Rosenberg; Y Zhai; J C Yang; D J Schwartzentruber; P Hwu; F M Marincola; S L Topalian; N P Restifo; C A Seipp; J H Einhorn; B Roberts; D E White
Journal:  J Natl Cancer Inst       Date:  1998-12-16       Impact factor: 13.506
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