Gene Expression Profiling Not Quite Perfected In Predicting Lung Cancer Prognosis
Main Category: Lung CancerAlso Included In: Genetics
Article Date: 23 Nov 2006 - 2:00 PDT
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While there have been significant advances in the use of gene expression profiling to assess a cancer prognosis, a Mayo Clinic review and analysis of existing lung cancer studies shows that this technology has not yet surpassed the accuracy of conventional methods used to assess survival in lung cancer patients.
The interest in and the knowledge of gene expression profiling in medical science has exploded since the completion of the human genome project in 2003. Researchers caution that the science of gene expression profiling, in which scientists examine the genetic signature of a cell, is in its infancy, particularly in lung cancer.
"Growing evidence suggests that gene-based prediction is not stable and little is known about the prediction power of a gene expression profile as compared to well-known clinical and pathologic predictors," according to Ping Yang, M.D., Ph.D., the corresponding author of the study that appears in the November issue of Cancer Epidemiology, Biomarkers and Prevention (CEBP). The study's first author is Zhifu Sun, M.D., a research associate with the Department of Health Sciences Research at Mayo Clinic.
Dr. Yang, a researcher with Mayo Clinic's Department of Health Sciences, said that while gene expression profiling has been successfully used to classify various tumors and assess tumor stage, metastasis and patient survival rates, the evidence suggests that gene-based prediction for lung cancer is not yet entirely dependable. However, some results have been promising: gene profiling has reliably predicted patient survival for lung adenocarcinoma almost as well as established predictors.
The results of conventional methods that factor in age, gender, stage, cell type and tumor grade outweigh the predictive advantage of a gene expression profile. "Any new technique that does not significantly outperform less expensive and easily conducted approaches is less likely to be useful in clinical practice," the authors wrote.
Few studies have compared conventional methods of lung cancer prediction with gene profiling. It remains to be seen whether gene expression profiling of lung cancer cases can replace or augment the existing assessment tools and, furthermore, whether it can lead to improved patient care.
In terms of problems associated with gene expression profiling in lung cancer research, the authors found:
* The accuracy of gene expression-based outcome prediction varies greatly among studies. * Most studies lacked independent validation.
* Clinical outcome prediction between gene expression profiles and pathological features overlap significantly.
* Current analytical algorithms favor genes at high expression or genes highly differentially expressed, most of which are related to tumor differentiation and may not correlate with clinical outcomes; conversely, genes expressed at low levels or in a subtle difference are often overlooked, which may be quite relevant biologically to clinical questions.
The authors of the study recommend that medical scientists engaged in gene expression profiling should:
* Clearly define a study aim. The main focus in microarray studies should explore the molecular explanations for varied clinical outcomes given a group of patients with similar clinical and pathological characteristics.
* Lay out and compare alternative study designs
* Carefully select samples in terms of size, quality and unambiguous clinical outcomes
* Understand the limitations of DNA microarray
* Provide clinically relevant interpretation from the study results and address the value added in practice
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Cancer Epidemiology, Biomarkers and Prevention
The study was funded by the National Institutes of Health, National Cancer Institute and Mayo Clinic.
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Gene Expression Profiling
posted by Gregory D. Pawelski on 11 Dec 2006 at 11:42 pmWhile some types of cancer remain localized for many years and never spread to other organs, others are systemic disease at the time the patient first became aware of the primary tumor. Localized tumors can be dealt with by surgeons with successful (curative) results. However, tumors which have spread (metastasized) to other organs are virtually impossible to remove and will eventually kill the patient unless they respond to systemic treatment (chemotherapy), which is designed to kill tumor cells.
Cancer occurs when cells lose the molecular mechanisms that control their growth and death, resulting in uncontolled cell proliferation and form tumors. These molecular mechanisms are contolled by genes encoded in the DNA of the cell, and acquired mutations or other changes in these genes lead to loss of control. Therefore, cancers are genetic diseases. But, each individual tumor, even those of the same general type will have different mutations, the consequences of which may be altered by the tissue environment, which can in turn be influenced by the external environment. The result is that cancers are even more different from each other than the individuals affected.
This heterogeneity means that a particular drug will rarely be effective against all tumors of a particular type, and the degree of efficacy will vary between patients. Also, as a result of their original mutations, many tumor cells acquire the ability to adapt rapidly to changes in their environment, sometimes by further mutation, often by molecular changes which induce resistance to the drugs used to treat them. Further courses of chemotherapy then select for resistant cells, and the treatment eventually fails to control the tumor.
To overcome the problems of heterogeneity and prevent rapid cellular adaptation, oncologists are able to tailor chemotherapy to individual patients. This is done by testing the tumor cells to see if they are susceptible to particular drugs, before giving them to the patient.
Many hope that molecular tests may hold the key to success, particularly as more specific drugs are designed to hit the molecular changes that are responsible for the uncontrolled growth of cancer cells. Like testing breast cancer for the presence of hormone receptors and over-expression of growth factor receptors. However, most drugs cannot be looked at in this way and tests that are now in use have limited predictive accuracy.
So how about exposing cancer cells to the drug and testing their effect? You need to expose the cancer cells to the drugs without altering their behavior from the original tumor. It is not possible to remove the non-cancer cells from the tumor without doing this. But certain assay culture methods can get rid of the non-cancer cells before the end of the culture period. These cell culture assays have contributed to the molecular understanding of chemosensitivity and resistance.
An international study published in the August 5, 2004 issue of the New England Journal of Medicine reported that cell culture assay tests with a cell-death endpoint are effective in identifying gene expression patterns that correlate with clinical drug resistance. The study, titled "Gene Expression Patterns in Drug Resistant Acute Lymphoblastic Leukemia Cells and Response to Treatment" employed the cell-death assay to examine drug resistance at the molecular level.
The investigators exposed cells to drugs and cultured in a 96 hour suspension cell culture drug resistance assay (MTT) to define sensitivity and resistance. They used the data to define gene expression patterns associated with sensitivity and resistance to each of 4 drugs commonly used in the treatment of childhood leukemia. They were able to show that the gene expression definitions of sensitivity and resistance were significantly and independently associated with treatment outcome.
This work could not have been done without prior work in more than a thousand cell culture drug resistance test assays from children with leukemia to define sensitivity and resistance for each of the four drugs. Cell culture assays are the Rosetta Stone which allows for identification of clinically relevant gene expression patterns which correlate with clinical drug resistance for different drugs in specific diseases.
In an accompanying editorial, a review of the study findings indicated that the observed gene expression profiles represent fundamental biochemical features and suggests that gene expression profiles could be used to alter therapy instead of in vitro sensitivity testing. They go on to state that there is no single gene whose expression accurately predicts therapy outcome, emphasizing that cancer is a complex disease and needs to be attacked on many fronts.
A number of cell culture assay labs across the country have data from tens of thousands of fresh human tumor specimens, representing virtually all types of human solid and hematologic neoplasms, in which were tested a median of 17 drugs and/or drug combinations under very similar conditions to that of this acute lymphoblastic leukemia study. Cells were exposed to drugs and cultured in suspension for 96 hours and tested simultaneously with two different assays (MTT and DISC). What this means is that these cell culture assay labs have the Rosetta Stone database necessary to define sensitivity and resistance for virtually all of the currently available drugs in virtually all types of human solid and hematologic neoplasms.
Improving cancer patient diagnosis and treatment through a combination of cellular and gene-based testing will offer predictive insight into the nature of an individual's particular cancer and enable oncologists to prescribe treatment more in keeping with the heterogeneity of the disease. The biologies are very different and the response to given drugs is very different.
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