Studies of specific viruses from Guthrie cards and prognostic markers in bone marrow samples from children diagnosed with leukemia
Aims: The aim of this thesis was to increase understanding of how molecular processes influence the development and risk assessment of childhood leukemia. Studies I and II investigates whether a specific virus infection in utero could be involved in a “first hit” in leukemogenesis. Studies III and IV examine whether alterations in protein expression from cell cycle regulating genes may predict a relapse in children with myeloid malignancies undergoing hematopoietic stem cell transplantation (HSCT).
Background: Genetic alterations, analyzed at time of diagnosis in children who develop leukemia, have been traced back to neonatal dried blood spots (DBS). This suggests that the majority of chromosome translocations occur in utero during fetal hematopoiesis, generating a “first hit”. A “second hit” is then required to generate a leukemic clone. Today, experiments in vitro, animal models, and clinical observations have revealed that several viruses are oncogenic and capable of initiating a genetic alteration. Smith M postulated the theory that an in utero infection might be the “first hit”, causing genetic aberrations that could later lead to the development of the leukemic clone, which is supported by the early age of onset and space-time clustering data, based on time, place of birth, and diagnosis. Leukemia develops as a result of hematopoietic or lymphoid tissue with uncontrolled cell division. Normally cell division is controlled by the cell cycle, the network of which is complex with numerous regulating proteins both up and down stream, but also containing several feedback loops. The important regulators of this process are tumor suppressor genes, essential for normal cell proliferation and differentiation as well as for controlling DNA integrity. Errors in these genes or their protein expression affect the ability of the cell to check for DNA damage, thus tumors may occur. Proteins from these genes could serve as prognostic markers and predict relapse.
Methods: In studies I and II we investigated neonatal DBS by PCR for the presence of adenovirus DNA (243 samples) and the three newly discovered polyomaviruses (50 samples) from children who later developed leukemia but also from controls (486 and 100 samples respectively). In studies III and IV we explored the expression of one (p53) respectively four (p53, p21, p16 and PTEN) cell cycle regulating proteins in bone marrow at diagnosis as well as pre and post HSCT in myeloid malignancies in children. We retrospectively collected clinical data and bone marrow samples from 33 children diagnosed with chronic myeloid malignancies (MDS, JMML and CML), 34 children diagnosed with AML as well as 55 controls. The samples were prepared by tissue micro array (TMA) as well as immunohistochemistry and examined for protein expression in a light microscope.
Results: In study I we detected adenovirus DNA in only two patients who later developed leukemia, but in none of the controls. In study II all the samples were negative for KIPyV, WUPyV and MCPyV DNA in both patients and controls. In study III we found an overexpression of p53 protein at diagnosis that significantly predicted relapse after HSCT in children with rare chronic myeloid malignancies. In study IV a significantly higher p53 expression was found in the relapse compared to the non-relapse group at six months post HSCT in children with AML, suggesting that p53 may be used as prognostic markers for predicting a relapse. In addition, the calculated cut off level for p53 at diagnosis (study III) and at six months (study IV) post HSCT was approximately 20%, which indicates that a p53 expression over 20% may predict relapse in children with myeloid malignancies.
Conclusion: Although we did not find an association between adenoviruses or the three newly discovered polyomaviruses and the development of childhood leukemia, a virus could still be involved in this process; the virus may have escaped detection, other new viruses could be involved or a virus could precipitate the “second hit”. We suggest that evaluation of p53 protein expression may be used as a supplement to regular prognostic markers both pre and post HSCT. To further evaluate this, a prospective multicenter study has been started.
List of scientific papers
I. Honkaniemi E, Talekar G, Huang W, Bogdanovic B, Forestier E, von Doblen E, Engvall M, Ornelles DA, Gooding L and Gustafsson B. Adenovirus DNA in Guthrie cards from children who develop acute lymphoblastic leukaemia (ALL). Br J Cancer, 2010 Mar 2;102(5):796-8
https://doi.org/10.1038/sj.bjc.6605581
II. Gustafsson B, Honkaniemi E, Goh S, Giraud G, Forestier E, von Döbeln U, Allander T, Dalianis T, Bogdanovic G. KI, WU and Merkel Cell polyomavirus DNA was not detected in Guthrie cards of children, who later developed acute lymphoblastic leukemia (ALL). Journal of Pediatric Hematology-Oncology. 2012 Jul;34(5):364-7.
https://doi.org/10.1097/MPH.0b013e318241fb52
III. Emma Honkaniemi, MD, Kristin Mattsson, Gisela Barbany MD, PhD, Birgitta M. Sander MD, PhD, Britt M. Gustafsson MD, PhD. Elevated p53 protein expression; a predictor of relapse in rare chronic myeloid malignancies in children? Pediatric Hematology-Oncology, 2014 May;31(4):327-39.
https://doi.org/10.3109/08880018.2014.898723
IV. Kristin Mattson, Emma Honkaniemi, MD, Gisela Barbany MD, PhD, Britt M. Gustafsson MD, PhD. Increased p53 protein expression as a potential predictor of early relapse after hematopoietic stem cell transplantation in children with acute myelogenous leukemia. [Submitted]
History
Defence date
2014-11-28Department
- Department of Clinical Science, Intervention and Technology
Publisher/Institution
Karolinska InstitutetMain supervisor
Britt, GustafssonPublication year
2014Thesis type
- Doctoral thesis
ISBN
978-91-7549-697-9Number of supporting papers
4Language
- eng