PURPOSE: The identification of tumor antigens recognized by cytotoxic and T helper lymphocytes has led to the development of specific cancer vaccines. Immunization with tumor antigen-pulsed dendritic cells has proved effective at eliciting elevated levels of tumor antigen-specific T cells in patient blood, but objective clinical responses remain rare, suggesting that vaccine-induced T cells are not trafficking optimally to site(s) of tumor burden. Accumulating evidence from animal models suggests that route of immunization can have a substantial influence on the subsequent migration of primed, activated T cells in vivo. EXPERIMENTAL DESIGN: In a clinical trial designed to elicit more effective cytotoxic T-cell mediated antitumor responses, metastatic melanoma patients were immunized directly via a peripheral intralymphatic route with autologous dendritic cells pulsed with HLA-A*0201-restricted melanoma-associated peptide antigens derived from MART-1 and gp100. RESULTS: Within 10 days of intralymphatic dendritic cell vaccination, four of six patients developed dramatic and diffuse erythematous rashes in sun-exposed areas of skin that showed extensive T-cell infiltration. CTLs grown from rash biopsies were strongly enriched for tumor antigen-specific T cells that had elevated expression of cutaneous lymphocyte antigen and chemokine receptor-6, consistent with a skin-homing phenotype. Of note, the only patient in the study with cutaneously localized disease showed a significant regression of metastatic lesions following the development of a surrounding rash. CONCLUSIONS: The evidence presented here is consistent with immunization studies in animal models and supports the concept that T cells are "imprinted" in peripheral lymph node sites to express specific ligands and chemokine receptors that allow them to migrate to skin. Furthermore, the preferential migration of the T cells to sun-exposed cutaneous sites suggests that inflammation plays a critical role in this migration. These observations suggest that further study of the effects of immunization route and inflammation on T-cell migration in humans is warranted, and could lead to vaccination approaches that would more reliably direct trafficking of activated T cells to diverse sites of metastatic disease.
PURPOSE: The identification of tumor antigens recognized by cytotoxic and T helper lymphocytes has led to the development of specific cancer vaccines. Immunization with tumor antigen-pulsed dendritic cells has proved effective at eliciting elevated levels of tumor antigen-specific T cells in patient blood, but objective clinical responses remain rare, suggesting that vaccine-induced T cells are not trafficking optimally to site(s) of tumor burden. Accumulating evidence from animal models suggests that route of immunization can have a substantial influence on the subsequent migration of primed, activated T cells in vivo. EXPERIMENTAL DESIGN: In a clinical trial designed to elicit more effective cytotoxic T-cell mediated antitumor responses, metastatic melanomapatients were immunized directly via a peripheral intralymphatic route with autologous dendritic cells pulsed with HLA-A*0201-restricted melanoma-associated peptide antigens derived from MART-1 and gp100. RESULTS: Within 10 days of intralymphatic dendritic cell vaccination, four of six patients developed dramatic and diffuse erythematous rashes in sun-exposed areas of skin that showed extensive T-cell infiltration. CTLs grown from rash biopsies were strongly enriched for tumor antigen-specific T cells that had elevated expression of cutaneous lymphocyte antigen and chemokine receptor-6, consistent with a skin-homing phenotype. Of note, the only patient in the study with cutaneously localized disease showed a significant regression of metastatic lesions following the development of a surrounding rash. CONCLUSIONS: The evidence presented here is consistent with immunization studies in animal models and supports the concept that T cells are "imprinted" in peripheral lymph node sites to express specific ligands and chemokine receptors that allow them to migrate to skin. Furthermore, the preferential migration of the T cells to sun-exposed cutaneous sites suggests that inflammation plays a critical role in this migration. These observations suggest that further study of the effects of immunization route and inflammation on T-cell migration in humans is warranted, and could lead to vaccination approaches that would more reliably direct trafficking of activated T cells to diverse sites of metastatic disease.
Authors: J J Campbell; G Haraldsen; J Pan; J Rottman; S Qin; P Ponath; D P Andrew; R Warnke; N Ruffing; N Kassam; L Wu; E C Butcher Journal: Nature Date: 1999-08-19 Impact factor: 49.962
Authors: P Johansen; A C Häffner; F Koch; K Zepter; I Erdmann; K Maloy; J J Simard; T Storni; G Senti; A Bot; B Wüthrich; T M Kündig Journal: Eur J Immunol Date: 2005-02 Impact factor: 5.532
Authors: D Yang; O Chertov; S N Bykovskaia; Q Chen; M J Buffo; J Shogan; M Anderson; J M Schröder; J M Wang; O M Howard; J J Oppenheim Journal: Science Date: 1999-10-15 Impact factor: 47.728
Authors: A Mackensen; T Krause; U Blum; P Uhrmeister; R Mertelsmann; A Lindemann Journal: Cancer Immunol Immunother Date: 1999 May-Jun Impact factor: 6.968
Authors: B A Zabel; W W Agace; J J Campbell; H M Heath; D Parent; A I Roberts; E C Ebert; N Kassam; S Qin; M Zovko; G J LaRosa; L L Yang; D Soler; E C Butcher; P D Ponath; C M Parker; D P Andrew Journal: J Exp Med Date: 1999-11-01 Impact factor: 14.307
Authors: E J Kunkel; J J Campbell; G Haraldsen; J Pan; J Boisvert; A I Roberts; E C Ebert; M A Vierra; S B Goodman; M C Genovese; A J Wardlaw; H B Greenberg; C M Parker; E C Butcher; D P Andrew; W W Agace Journal: J Exp Med Date: 2000-09-04 Impact factor: 14.307
Authors: Pawel Kalinski; Howard Edington; Herbert J Zeh; Hideho Okada; Lisa H Butterfield; John M Kirkwood; David L Bartlett Journal: Immunol Res Date: 2011-08 Impact factor: 2.829
Authors: Fanny Edele; Jan C Dudda; Eva Bachtanian; Thilo Jakob; Hanspeter Pircher; Stefan F Martin Journal: PLoS One Date: 2014-08-14 Impact factor: 3.240