J Berzofsky

Publications (2)8.32 Total impact

• Article: High-avidity CTL exploit two complementary mechanisms to provide better protection against viral infection than low-avidity CTL.

  M Derby, M Alexander-Miller, R Tse, J Berzofsky
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  ABSTRACT: Previously, we observed that high-avidity CTL are much more effective in vivo than low-avidity CTL in elimination of infected cells, but the mechanisms behind their superior activity remained unclear. In this study, we identify two complementary mechanisms: 1) high-avidity CTL lyse infected cells earlier in the course of a viral infection by recognizing lower Ag densities than those distinguished by low-avidity CTL and 2) they initiate lysis of target cells more rapidly at any given Ag density. Alternative mechanisms were excluded, including: 1) the possibility that low-avidity CTL might control virus given more time (virus levels remained as high at 6 days following transfer as at 3 days) and 2) that differences in efficacy might be correlated with homing ability. Furthermore, adoptive transfer of high- and low-avidity CTL into SCID mice demonstrated that transfer of a 10-fold greater amount of low-avidity CTL could only partially compensate for their decreased ability to eliminate infected cells. Thus, we conclude that high-avidity CTL exploit two complementary mechanisms that combine to prevent the spread of virus within the animal: earlier recognition of infected cells when little viral protein has been made and more rapid lysis of infected cells.
  The Journal of Immunology 03/2001; 166(3):1690-7. · 5.79 Impact Factor
• Article: Targeting tumor specific translocations in sarcomas in pediatric patients for immunotherapy.

  C Mackall, J Berzofsky, L J Helman
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  ABSTRACT: In an effort to develop more effective therapies for various sarcomas in pediatric patients, the authors have focused on using recurrent tumor-specific translocations as potential novel tumor antigens. In general, these translocations generate fusion transcription factors. Because cytotoxic T cell lymphocyte receptors recognize peptide fragments bound to major histocompatibility complex Class 1 molecules, it is possible that unique peptides spanning the translocation breakpoint region may be processed, bound to major histocompatibility complex Class I molecules and displayed on the tumor cell surface where they could be susceptible to cytotoxic T cell lymphocyte killing. The authors have investigated the PAX-3-FKHR fusion product seen in alveolar rhabdomyosarcoma, and the EWS-FLI-1 fusion product seen in Ewing's sarcoma. Peptides spanning these fusion regions contain potential major histocompatibility complex Class 1 and Class II binding motifs suggesting they may serve as novel T cell antigens. Preliminary mouse experiments suggest that cytotoxic T cell lymphocytes specific for the PAX-3-FKHR fusion peptide can be generated and can recognize and kill tumor cells bearing the PAX-3-FKHR fusion protein. Clinical trials are ongoing to determine whether this approach will be useful.
  Clinical Orthopaedics and Related Research 05/2000; · 2.53 Impact Factor