Radiobiological effects of alpha-particles from Astatine-211: From DNA damage to cell death
Abstract
ABSTRACT
In recent years, the use of high linear energy transfer (LET) radiation for radiotherapeutic
applications has gained increased interest. Astatine-211 (211At) is an -particle emitting
radionuclide, promising for targeted radioimmunotherapy of isolated tumor cells and
microscopic clusters. To improve development of safe radiotherapy using 211At it is important
to increase our knowledge of the radiobiological effects in cells. During radiotherapy, both
tumors and adjacent normal tissue will be irradiated and therefore, it is of importance to
understand differences in the radioresponse between proliferating and resting cells. The aim
of this thesis was to investigate effects in fibroblasts with different proliferation status after
irradiation with -particles from 211At or X-rays, from inflicted DNA damage, to cellular
responses and biological consequences.
Throughout this work, irradiation was performed with -particles from 211A or X-rays. The
induction and repair of double-strand breaks (DSBs) in human normal fibroblasts were
investigated using pulsed-field gel electrophoresis and fragment analysis. The relative
biological effectiveness (RBE) of 211At for DSB induction varied between 1.4 and 3.1. A
small increase of DSBs was observed in cycling cells compared to stationary cells. The repair
kinetics was slower after 211At and more residual damage was found after 24 h. Comparison
between cells with different proliferation status showed that the repair was inefficient in
cycling cells with more residual damage, regardless of radiation quality. Activation of cell
cycle arrests was investigated using immunofluorescent labeling of the checkpoint kinase
Chk2 and by measuring cell cycle distributions with flow cytometry analysis. After -particle
irradiation, the average number of Chk2-foci was larger and the cells had a more affected cell
cycle progression for several weeks compared with X-irradiated cells, indicating a more
powerful arrest after 211At. Flow cytometry showed that cycling cells were arrested in G2/M
while stationary cells underwent a delayed entry into S phase after release of contact
inhibition. Radiation-induced chromosomal damage was studied by investigating the
formation of micronuclei after first mitosis post-irradiation. Alpha-particles induced 2.7 and
4.1 times more micronuclei in cycling and stationary cells, respectively, compared with Xrays.
Induction of DSBs and cell survival after irradiation were also investigated in synchronized
Chinese hamster fibroblasts. The cells were synchronized with mimosine in G1, early, mid
and late S phase and in mitosis and cell survival was determined using the clonogenic assay.
The radioresponse between cell cycle phases varied after both 211At and X-rays, resulting in
variations of RBE for 211At between 1.8 and 3.9 for DSB induction and between 3.1 and 7.9
for 37% survival. The lowest RBE was observed in mitotic cells for both DSB induction and
clonogenic survival.
In summary, for all endpoints studied -particles from 211At were more detrimental compared
with X-rays. Further, the radioresponse was dependent upon the proliferation status of the
cells at the time of irradiation, after both low- and high-LET radiation, resulting in variations
of the relative biological effects.
Parts of work
I Claesson K, Stenerlöw B, Jacobsson L and Elmroth K. Relative Biological Effectiveness of the
3-Particle Emitter 211At for Double-Strand Break Induction in Human Fibroblasts. Radiation
Research 2007; 167, 312-318.
::PMID::17316073 II Claesson K, Magnander K, Kahu K, Lindegren S, Hultborn R and Elmroth K. RBE of 3-
Particles from 211At for Complex DNA Damage and Cell Survival in Relation to Cell Cycle
Position. International Journal of Radiation Biology 2011; 87, 372-384.
::PMID::21171940 III Claesson K, Nordén Lyckesvärd M, Magnander K, Lindegren S and Elmroth K. Double-Strand
Break Repair and Cell Cycle Arrest Activation in Stationary and Cycling Diploid Cells
Irradiated with High- and Low-LET Radiation. Manuscript. IV Claesson K, Nordén Lyckesvärd M, Magnander K, Delle U and Elmroth K. Effects on
Micronuclei Formation and Growth Kinetics in Normal Fibroblasts after Irradiation with Alpha
Particles and X rays: Differential Response in Stationary and Cycling Cell Cultures. Manuscript
Degree
Doctor of Philosophy
University
University of Gothenburg. Sahlgrenska Academy
Institution
Institute of Clincial Sciences. Department of Oncology
Disputation
Fredagen den 27 Maj 2011, kl. 13.00, Hörsal Förmaket, Vita stråket 12
Date of defence
2011-05-27
kristina.claesson@oncology.gu.se
Date
2011-05-26Author
Claesson, Kristina
Publication type
Doctoral thesis
ISBN
978-91-628-8270-9
Language
eng