Lactoferrin: An adjuvant to enhance the efficacy of the BCG vaccine

Tuberculosis (TB), caused by Mycobacterium tuberculosis (MTB), is a disease with world wide consequences, affecting nearly a third of the world's population. The established vaccine for TB; an attenuated strain of Mycobacterium bovis Calmette Guerin (BCG), has existed virtually unchanged since 1921. Intensive research is focused on developing a TB vaccine that can surpass and improve the existing BCG vaccine. Lactoferrin, an iron binding protein found in mucosal secretions and granules of neutrophils was hypothesized to be an ideal adjuvant to enhance the efficacy of the BCG vaccine. Specifically, Lactoferrin enhanced the ratio of IL-12:IL-10 production from macrophages stimulated with LFS or infected with BCG, indicating the potential to affect T-cell development in vivo. Five different vaccination protocols were investigated for generation of host protective responses against MTB infection using Lactoferrin admixed to the BCG vaccine. Mice immunized and boosted at 2 weeks with BCG/Lactofefrin increased host protection against MTB infection by decreasing organ bacterial load and reducing lung histopathology. The observed postchallenge results paralleled with increasing production of IFN-γ, IL-2, TNF-α, and IL-12 from BCG stimulated splenocytes. In vitro studies examined possible mechanisms of Lactoferrin action on BCG infected macrophages and dendritic cells. Addition of Lactoferrin to BCG infected macrophages and dendritic cells increased stimulation of presensitized CD3+ and CD4+ T-cells. Analysis by fluorescent activated cell sorting (FACS) revealed an increase in surface expression of MHC I and decreased ratio of CD80/86 from BCG infected macrophages cultured with Lactoferrin. In contrast, Lactoferrin decreased surface expression of MHC I, MHC II, CD80, CD86, and CD40, but increased CD 11c, from BCG infected dendritic cells, indicating involvement of adhesion molecules. Overall, these studies indicate that Lactoferrin is a useful and effective adjuvant to improve efficacy of the BCG vaccine by enhancing generation of mycobacterial antigen specific T-cell responses through promotion of antigen presentation and T-cell stimulation.^

The structural and functional relationship of the p53 tumor suppressor protein

The tumor-suppressing function of p53 can be affected in a variety of manners. Here, we describe a novel mechanism of transformation by mutant p53. Previously, it had been believed that mutant p53 molecules transform cells by oligomerizing with wild-type p53 and inactivating it. However, we demonstrated that there exists an additional mechanism of inactivation of p53 available to p53 mutants. It involves sequestration of cofactors necessary to p53, and subsequent interruption of its transactivation and tumor suppression functions. The p53 amino or carboxyl termini, known to interact with a large number of cellular factors, can affect wild-type p53 in this manner. Although they are unable to oligomerize with wild-type p53, they transform cells containing p53, and inhibit its transactivation ability. In addition, they interrupt growth suppression by p53, but not RB, confirming that they specifically affect p53 function, rather than having a general growth-stimulatory phenomenon. Also, we have cloned a p53 tumor mutation which results in expression of the amino terminus of p53. This provides a means to study the factor-sequestration transforming mechanism in vivo. Additionally, we found that the published sequence of the mdm2 gene is in error. mdm2 is a gene intimately involved with p53, blocking its ability to transform cells. Finally, previous data had established the influence of cell-cycle status on p53 function. In growth-arrested cells, wild-type p53 expressed by a transgene cannot activate transcription, but if these cells are forced to cycle by addition of cyclin E, p53 once again becomes functional. In this study, we extend these findings by examining only those cells successfully transfected, using fluorescence-activated cell sorting. Our results support the previous data, that cyclin E pushes growth-arrested cells back into the cell cycle. In summary, we have demonstrated the potential importance of cofactor association and protein modification to the abilities of p53 to cause transcription activation and repression, inhibition of DNA replication and induction of DNA repair, and initiation of cell-cycle arrest and apoptosis. Further elucidation of these processes and their roles in tumor suppression will prove fascinating indeed. ^

Characterization and optimization of antigen-specific T cell responses during ex vivo expansion of melanoma tumor-infiltrating lymphocytes

Treatment of metastatic melanoma with tumor reactive T cells (adoptive T cell therapy, ACT) is a promising approach associated with a high clinical response rate. However, further optimization of this treatment modality is required to increase the clinical response after this therapy. ACT in melanoma involves an initial phase (pre-REP) of tumor-infiltrating lymphocyte (TIL) expansion ex vivo from tumor isolates followed by a second phase, “rapid expansion protocol” (REP) generating the billions of cells used as the TIL infusion product. The main question addressed in this thesis was how the currently used REP affected the responsiveness of the CD8+ T cells to defined melanoma antigens. We hypothesized that the REP drives the TIL to further differentiate and become hyporesponsive to antigen restimulation, therefore, proper cytokine treatment or other ways to expand TIL is required to improve upon this outcome. We evaluated the response of CD8+ TIL to melanoma antigen restimulation using MART-1 peptide-pulsed mature DC in vitro. Post-REP TILs were mostly hypo-responsive with poor proliferation and higher apoptosis. Phenotypic analysis revealed that the expression of CD28 was significantly reduced in post-REP TILs. By sorting experiment and microarray analysis, we confirmed that the few CD28+ post-REP TILs had superior survival capacity and proliferated after restimulation. We then went on to investigate methods to maintain CD28 expression during the REP and improve TIL responsiveness. Firstly, IL-15 and IL-21 were found to synergize in maintaining TIL CD28 expression and antigenic responsiveness during REP. Secondly, we found IL-15 was superior as compared to IL-2 in supporting the long-term expansion of antigen-specific CD8+ TIL after restimulation. These results suggest that current expansion protocols used for adoptive T-cell therapy in melanoma yield largely hyporesponsive products containing CD8+ T cells unable to respond in vivo to re-stimulation with antigen. A modification of our current approaches by using IL-15+IL-21 as supporting cytokines in the REP, or/and administration of IL-15 instead of IL-2 after TIL infusion, may enhance the anti-tumor efficacy and long-term persistence of infused T cells in vivo.