@phdthesis{Dagvadorj2016,
  author    = {Dagvadorj, Nergui},
  title     = {Improvement of T-cell response against WT1-overexpressing leukemia by newly developed anti-hDEC205-WT1 antibody fusion proteins},
  url       = {http://nbn-resolving.de/urn:nbn:de:bvb:20-opus-149098},
  school      = {Universit{\"a}t W{\"u}rzburg},
  year      = {2016},
  abstract  = {Wilms tumor protein 1 (WT1) is a suitable target to develop an immunotherapeutic approach against high risk acute myeloid leukemia (AML), particularly their relapse after allogeneic hematopoietic stem cell transplantation (HSCT). As an intracellular protein traversing between nucleus and cytoplasm, recombinant expression of WT1 is difficult. Therefore, an induction of WT1-specific T-cell responses is mostly based on peptide vaccination as well as dendritic cell (DC) electroporation with mRNA encoding full-length protein to mount WT1-derived peptide variations presented to T cells. Alternatively, the WT1 peptide presentation could be broadened by forcing receptor-mediated endocytosis of DCs. In this study, antibody fusion proteins consisting of an antibody specific to the human DEC205 endocytic receptor and various fragments of WT1 (anti-hDEC205-WT1) were generated for a potential DC-targeted recombinant WT1 vaccine. Anti-hDEC205-WT1 antibody fusion proteins containing full-length or major parts of WT1 were not efficiently expressed and secreted due to their poor solubility and secretory capacity. However, small fragment-containing variants: anti-hDEC205-WT110-35, anti-hDEC205-WT191-138, anti-hDEC205-WT1223-273, and anti-hDEC205-WT1324-371 were obtained in good yields. Since three of these fusion proteins contain the most of the known immunogenic epitopes in their sequences, the anti-hDEC205-WT191-138, anti-hDEC205-WT1223-273, and anti-hDEC205-WT1324-371 were tested for their T-cell stimulatory capacities. Mature monocyte-derived DCs loaded with anti-hDEC205-WT191-138 could induce ex vivo T-cell responses in 12 of 16 blood samples collected from either healthy or HSC transplanted individuals compared to included controls (P < 0.01). Furthermore, these T cells could kill WT1-overexpressing THP-1 leukemia cells in vitro after expansion. In conclusion, alongside proving the difficulty in expression and purification of intracellular WT1 as a vaccine protein, our results from this work introduce an alternative therapeutic vaccine approach to improve an anti-leukemia immune response in the context of allogeneic HSCT and potentially beyond.},
  subject      = {Akute myeloische Leuk{\"a}mie},
  language  = {en}
}
@phdthesis{Pramanik2006,
  author    = {Pramanik, Kallal},
  title     = {Stroma-leukaemic cell interactions : Analysis of stroma environment-induced effect on human acute myeloid leukaemic cells},
  url       = {http://nbn-resolving.de/urn:nbn:de:bvb:20-opus-21893},
  school      = {Universit{\"a}t W{\"u}rzburg},
  year      = {2006},
  abstract  = {In spite of the progress made in deciphering regulatory networks of cancer cells on the molecular level, the interaction of tumour cells with their stroma has not been adequately analyzed. Earlier, we have addressed the hypothesis that the murine embryonic microenvironment can induce the differentiation of human tumour cells. To examine such interactions, human leukaemic AML cells were injected into pre-implantation murine blastocysts at embryonic day 3.5 of gestation. Analysis of developing mice revealed the presence of human AML cells in chimaeric embryos and adults and the appearance of haematopoietic differentiation markers on progeny of injected human AML cells. This finding strengthens the notion that the embryonic microenvironment is capable of regulating the proliferation and differentiation of leukaemic AML cells. Based on these results, I embarked to analyse the consequences of stromal environment-induced changes in human AML cells upon in vitro coculture with selected haematopoietic stromal cell lines in terms of changes in differentiation and proliferation properties of AML cells. For this purpose, established human AML cell lines were cocultured on a variety of mitotically inactivated stromal cell lines derived from different murine embryonic/foetal haematopoietic sites such as yolk sac, aorta-gonad-mesonephros (AGM) region and foetal liver. To score for coculture-induced changes, I compared the morphology, histo-chemical properties, immunophenotype, proliferation rate, and gene expression profile in cocultured and non-cocultured AML cells. Results show that, upon coculture of Kasumi-1 cells- a cell line established from a FAB class M2 patient - with AGM-derived DAS 104-4, but not with other stromal cell lines, Kasumi-1 AML cells exibit decreased proliferation and colony formation capabilities and acquire differentiated morphologies. Along this line, coculturing of Kasumi-1 cells resulted in the up-regulation of the myelo-monocytic lineage cell surface markers CD11b and CD14. Coculture also resulted in increase in lysosomal marker CD68, a hallmark of myeloid differentiation. Interestingly, apart from cell lines, coculture on DAS 104-4 stroma was also efficient in inducing myeloid differentiation of patient derived primary M2-AML cells. Moreover, cocultivation of KG-1 cell line on DAS 104-4 showed activation of \&\#61538;-globin transcription and up-regulation of Glycophorin A on its surface, which indicate DAS 104-4 coculture-induced erythroid differentiation of KG-1 cells. Analysis of the proliferation rate of Kasumi-1 cells using the CFSE retention assay revealed that upon cocultivation on DAS 104-4, but not on NIH 3T3 cells, there is a decrease both in the proliferation rate and in the frequency of colony forming cells in clonogenic methyl cellulose cultures. Cell cycle analysis revealed the coculture-induced accumulation of G1-G0 stage cells. Gene-expression analysis by quantitative RT-PCR revealed a substantial decrease in the amount of AML1 and AML1-ETO fusion transcripts in parallel with an increase in p16, p21, C/EBP\&\#61537; and PU.1 transcription levels. Interestingly, AML1-ETO transcription down-regulation of AML cells needs direct contact with DAS 104-4 cells. Knocking down AML1-ETO expression by siRNA strategy led to reduction in proliferation and depletion of colony forming cells in Kasumi1 cell population. siRNA-mediated AML1-ETO knock-down Kasumi-1 cells showed increased susceptibility to stroma-induced myeloid differentiation. However, on its own, AML1-ETO down-regulation was not sufficient to induce myeloid differentiation. This indicates that AML1-ETO down-regulation may have an active role on the coculture-induced effect but in addition to AML1-ETO down-regulation, further stimuli are required for the coculture-induced myeloid differentiation in the AML cells. In summary, in the present study I established and characterised a coculture-based in vitro system, which is capable of reducing the proliferation while inducing differentiation of human AML cells. The concept emerging from the studies indicates that the stroma environment can affect leukaemic cell proliferation and differentiation in contact-dependent and CD44 activation-independent manner. Furthermore, this study emphasizes the role of AML1-ETO in AML and indicates that AML1-ETO down-regulation is involved in the stroma-induced differentiation of Kasumi-1 cells. The result described here encourages further investigation into the mechanistic details of molecular and cellular interactions between the leukaemic cells and their stroma, which in turn may lead to the identification of new paradigms for a knowledge-based control and reprogramming of leukaemic cells.},
  subject      = {Akute myeloische Leuk{\"a}mie},
  language  = {en}
}