Gene expression in relapsed childhood ALL [ 2003 - 2005 ]

Research Grant

Researchers: Prof Ursula Kees (Principal investigator) ,  Dr David Baker ,  Prof Nicholas De Klerk

Brief description Resistant forms of childhood acute lymphoblastic leukaemia (ALL) constitute a leading cause of cancer-related deaths in children. Despite tremendous improvements in therapy, 25-30% of patients still experience a relapse and many of them occur in patients stratified as low risk. Further treatment is often toxic, frequently unsuccessful and carries the risk of significant long-term morbidity. For the design of more appropriate therapy, information on the biology of relapsed ALL is urgently required. The sequencing of the human genome and advanced screening technology (microarrays) allow the detailed analysis of expression patterns in large numbers of specimens. We propose to study the genetic features of this disease by investigating 28 childhood ALL patients from whom we have stored specimens received at two time points, one at diagnosis and one at relapse. The hypothesis of this study is that relapsed leukaemias display genetic features which are correlated to their resistance to therapy. The specific questions we will be asking are: (1) Which genes are expressed at high levels in leukaemia specimens at the time of relapse while not expressed (or expressed at lower levels) at the time of diagnosis and vice versa? (2) What is the function of differentially expressed genes? (3) Is the pattern of gene expression correlated with resistance to the particular drug therapy used? (4) Is the leukaemia clone at relapse related or unrelated to the clone present at diagnosis, as determined by receptor rearrangement? The expression levels of identified discriminator genes will be confirmed by real-time quantitative polymerase chain reaction (PCR). The quality of this set of specimens makes them particularly suited to achieve the stated goals, providing a unique opportunity to investigate drug resistance in childhood ALL. The data generated will provide the basis for the examination of genes suitable as new therapeutic targets.

Funding Amount $AUD 455,250.00

Funding Scheme NHMRC Project Grants

Notes Standard Project Grant