New Genetic Model Improves Breast Cancer Screening

Researchers using the OncoVue® (InterGenetics Inc,655 Research Parkway, Suite 300, Oklahoma City, OK 73104) clinical breast cancer model for assessing genetic risk had much higher accuracy when compared with the more commonly used Gail model, according to data presented at the 31st Annual CTRC-AACR San Antonio Breast Cancer Symposium (SABCS, December 10 - 14, 2008).

By using a combination of a questionnaire and a saliva test, the OncoVue® model takes into account genetic variation in single nucleotide polymorphisms, or SNPs, that the traditional Gail model, which bases risk calculation primarily on traditional risk factors like woman's own personal medical history (number of previous breast biopsies and the presence of atypical hyperplasia in any previous breast biopsy specimen), her own reproductive history (age at the start of menstruation and age at the first live birth of a child), and the history of breast cancer among her first-degree relatives (mother, sisters, daughters) to estimate her risk of developing invasive breast cancer over specific periods of time, does not.

The single nucleotide polymorphisms or SNPs used by the OncoVue model, are small genetic changes within DNA that underlie individuality, including disease risk.

The initial research considered 117 common SNPs as candidates, but during test development the list was ultimately narrowed to 22 SNPs in 19 genes that proved to be most informative in estimating a woman’s individualized risk of developing breast cancer.

‘Women are clamoring for genetic tests like this one. The traditional Gail model looks at personal and clinical risk factors, but not at the inherited genetic variation in SNPs,’ explained lead investigator Kathie Dalessandri, M.D., a physician scientist who led the research team along with colleagues at the University of California, San Francisco, and the Buck Institute for Age Research.

Buccal cell DNA had been collected from 177 women without breast cancer who comprised the control group and 169 women diagnosed with breast cancer between 1997 and 1999 in Marin County, California. This region has been recognized for many years as having higher than average breast cancer incidence and mortality rates. Despite their elevated risk, Marin women who develop breast cancer have similar risk factors as Marin women who do not develop breast cancer when assessed by the classical Gail model characteristics. The researchers theorized that the OncoVue model which integrates the influence of genetic variation along with personal and clinical information would be able to more accurately estimate risk for these Marin women.

DNA was genotyped for 22 SNP variants, and the researchers assessed the fraction of case and control patients who were assigned an OncoVue risk score greater than 1.5 times average likelihood of developing breast cancer between ages 30 and 69. In this blinded analysis, the OncoVue® score proved 2.4 times (p=0.036) more accurate than the Gail model characteristics in accurately identifying the Marin cases with their increased risk from Marin controls with their reduced risk.

In this blinded validation study OncoVue exhibited significantly improved performance, compared to the Gail model alone, in estimating individual risk among Marin County, California women. The improved performance of OncoVue was similar to that observed in two previous independent validation sets, thus, supporting the clinical utility of OncoVue for more accurate individualized breast cancer risk estimation.

Additionally, OncoVue exhibited a 51 percent improvement over the Gail model in assigning an elevated risk score to cases. The improvement in risk estimation is significant and Dalessandri believes the OncoVue model will soon become standard clinical practice for evaluating breast cancer risk. ‘Within the next few years there is going to be a definite paradigm shift toward prevention by analysis of genetic material rather than traditional risk factors,’ Dalessandri noted. ‘As these tests become more commonplace we will be able to more effectively target prevention and early intervention to those at highest risk.’

For more information, read:

• Dalessandri KM, Miike R, Wrensch MR, et al. Validation of OncoVue®, a new individualized breast cancer risk estimator in the Marin County, California adolescent risk study. SABCS Poster Discussion Session (5): Risk and Prevention (5:00 PM-7:00 PM) Friday, December 12, 2008 Abstract 502.

Also read PubMed abstracts:

• Saccone SF, Rice JP, Saccone NL, Power-based, phase-informed selection of single nucleotide polymorphisms for disease association screens. Genet Epidemiol. 2006 Sep;30(6):459-70.
• Tempfer CB, Hefler LA, Schneeberger C, Huber JC. How valid is single nucleotide polymorphism (SNP) diagnosis for the individual risk assessment of breast cancer? Gynecol Endocrinol. 2006 Mar;22(3):155-9.
• Stram DO, Tag SNP selection for association studies. Genet Epidemiol. 2004 Dec;27(4):365-74.

More information:

• NCI– National Cancer Institute: Breast Cancer Risk Assessment Tool, based on a statistical model known as the ‘Gail model,’ named after Dr. Mitchell Gail, Senior Investigator in the Biostatistics Branch of NCI's Division of Cancer Epidemiology and Genetics.
• Decarli A, Calza S, Masala S, et al. Gail Model for Prediction of Absolute Risk of Invasive Breast Cancer: Independent Evaluation in the Florence–European Prospective Investigation Into Cancer and Nutrition Cohort. JNCI Journal of the National Cancer Institute 2006 98(23):1686-1693.
• Human Genome Project: What are SNPs?

New Drug for Cancer Treatment Could Bolster Immune System

Arizona based Translational Genomics Research Institute (TGen), a non-profit organization dedicated to conducting groundbreaking medical research, together with Scottsdale Healthcare, a primary clinical research facility housed in the Virginia G. Piper Cancer Center in Scottsdale and Mayo Clinic, one of only 39 U.S. medical centres that have been named as a National Cancer Institute (NCI) Comprehensive Cancer Center, started testing VTX-2334, a novel Toll-Like Receptor 8 (TLR8) agonists for the treatment of cancer, respiratory and autoimmune diseases in early December 2008. The new drug is developed by VentiRx Pharmaceuticals, Inc., a biopharmaceutical company based in San Diego, and could help cancer patients by stimulating their immune system.

During the initial Phase I trial, a yearlong first-in-humans test, researchers will study the drug's safety and pharmacology of multiple doses of VTX-2337 in patients with late-stage cancer. If successful, a Phase II trial will test the drug's effectiveness on tumours.

Dr. Ramesh Ramanathan, Medical Director of TGen Clincal Research Services at Scottsdale Healthcare, said the new drug appears to be quite promising. ‘VTX-2337 is a new, novel, small molecule aimed at stimulating the immune cells in the blood, lymph nodes, and in and around the tumour. It represents an exciting new class of agents for cancer therapy with good preclinical evidence of activity.’

VentiRx Pharmaceuticals, founded in June 2006 by Michael Kamdar and Robert Hershberg, M.D., Ph.D, is committed to the development of novel medicines for the treatment of cancer, infectious, respiratory, and autoimmune diseases. The medical research team of experienced biotechnology professionals, is excited to be working on this new drug. Michael Kamdar, Executive Vice President and Chief Business Officer at VentiRx : ‘Entering Phase I clinical trials represents a significant milestone for VentiRx and our TLR efforts in that we have rapidly advanced into a clinical development company with a novel molecule that may play an important role and have broad application in the treatment of cancer.’

Role of the immune system
A weakened immune system is often the result of advanced cancer. 'We hope that this new drug will actually help enable the immune system to slow down the growth of tumours, and perhaps even shrink them,' Ramanathan explained.

Toll-like receptors (TLRs) play an important role in stimulating innate and adaptive immunity and TLR ligands have become interesting targets to use as stand-alone immunotherapeutics or vaccine adjuvants for cancer treatment.

VTX-2337 is a small molecule TLR8 agonist that is expected to be used in combination with standard of care for the treatment of patients with cancer. Preclinical evaluation of VTX-2337 suggests that it may play a key role in augmenting the innate arm of the immune system.
There are two broad components of the immune system, the innate arm, and the adaptive arm. Both generally aim to eliminate viruses and bacteria.

• The innate arm senses infectious agents as they infect the body by recognizing structures they have in common, such as lipids, proteins, sugars, and nucleic acids (DNA and RNA). This is an initial rapid response, which is not precise but potent.
• The adaptive arm of the immune system is instructed by the innate arm to devise more specific responses to unique components of the invading pathogens. This is a more precise response and takes longer, especially when an infectious agent is encountered for the first time.

‘VTX-2337 is the first selective TLR8 compound to reach the clinic, and we are hopeful that modulation of the innate immune response will provide a benefit to patients in a number of oncology indications,’ said Dr. Robert Hershberg, Executive Vice President and Chief Medical Officer at VentiRx.

Also read PubMed abstracts:

• Smits EL, Ponsaerts P, Berneman ZN, Van Tendeloo VF. The use of TLR7 and TLR8 ligands for the enhancement of cancer immunotherapy. Oncologist 2008 Aug;13(8):859-75. Epub 2008 Aug 13
• Zhang SY, Jouanguy E, Sancho-Shimizu V, von Bernuth H, et al
  Human Toll-like receptor-dependent induction of interferons in protective immunity to viruses.
  Immunol Rev 2007 Dec;220:225-36
• Uematsu S, Akira S
  Toll-like receptors and Type I interferons
  J Biol Chem 2007 May 25;282(21):15319-23. Epub 2007 Mar 29
• Ghosh TK, Mickelson DJ, Fink J, Solberg JC, et al
  Toll-like receptor (TLR) 2-9 agonists-induced cytokines and chemokines: I. Comparison with T cell receptor-induced responses.
  Cell Immunol 2006 Sep;243(1):48-57. Epub 2007 Jan 23