REZOLVE (ANZGOG-1101): A Phase 2 Trial of Intraperitoneal Bevacizumab to Treat Symptomatic Ascites in Patients With Chemotherapy-Resistant, Epithelial Ovarian Cancer

For cancer patients, including those with recurrent ovarian cancer, an important cause of morbidity is malignant ascites. Researchers here evaluated the activity of intraperitoneal injections of low-dose bevacizumab in delaying re-accumulation of malignant ascites in women with chemotherapy-resistant epithelial ovarian cancer (CR-EOC) who have ceased chemotherapy.

IP-bev 5 mg/kg was administered to 24 women with CR-EOC and malignant ascites that reaccumulated within 28 days of their last paracentesis (P-1), after their first therapeutic paracentesis on study (P0). At each subsequent paracentesis (P1, P2, etc), they allowed additional doses of IP-bev provided the interval from the last dose was 42 days or greater (median time from first to second therapeutic ascitic drainage). Based on outcomes, they suggest intraperitoneal bevacizumab as safe and active, and support its further evaluation as a palliative intervention for recurrent ascites in CR-EOC patients receiving best supportive care.

This article was published by MDLinx.

Phase 3 OVAL Trial of VB-111 in Platinum-Resistant Ovarian Cancer Gets Green Light to Continue

An independent data safety monitoring committee has not observed any safety issues with the phase 3 OVAL trial examining VB-111 in patients with platinum-resistant ovarian cancer, and as such, has recommended that the trial continue as planned.

By Courtney Marabella

An independent data safety monitoring committee (DSMC) has not observed any safety issues with the phase 3 OVAL trial (NCT03398655) examining VB-111 (ofranergene obadenovec) in patients with platinum-resistant ovarian cancer, and as such, has recommended that the trial continue as planned, according to an announcement from VBL Therapeutics.¹

This recommendation followed a pre-planned review of the international, registration-enabling, phase 3 trial that is examining the combination of VB-111 and paclitaxel to placebo plus paclitaxel in patients with platinum-resistant ovarian cancer.

“This review continues the trend of encouraging reviews that have taken place since the clinical trial began,” Dror Harats, MD, chief executive officer of VBL Therapeutics, stated in a press release. “The trial continues to enroll on track in the United States, Europe and Israel. We look forward to the next DSMC review during the third quarter of 2021, followed by completion of enrollment at the end of 2021 or in early 2022.”

In March 2020, VB-111 met the prespecified efficacy criterion of the phase 3 trial. Specifically, VB-111 plus paclitaxel reached the predetermined benchmark of an absolute percentage advantage of 10% or higher in CA-125 response compared with paclitaxel alone.²

The combination elicited a CA-125 response rate of 53% in the first 60 evaluable participants across both treatment arms. The response rate in the experimental arm, assuming a balanced randomization, was 58% or higher. Additionally, in patients with post-dosing fever, the response rate reported with the regimen was 69%.

In August 2020, the DMSC evaluated the unblinded overall survival (OS) data collected on the first 100 participants who underwent randomization and had follow up for at least 3 months. Based on these data, the DMSC unanimously recommended that the trial to continue.

As of November 16, 2020, a high response rate of over 50% in the total evaluable patient population was maintained with approximately 200 patients enrolled, according to the press release.

To be eligible for enrollment to OVAL, patients had to be 18 years of age or older with histologically-confirmed epithelial ovarian cancer and platinum resistance. Additionally, patients had to have an ECOG performance status of 0 or 1 and measurable disease according to RECIST v1.1 criteria that requires chemotherapy treatment.³

Patients who had non-epithelial tumors, ovarian tumors with low malignant potential clear cell carcinomas, grade 1 serous tumors, or mucinous cancer, were not permitted. Moreover, patients who previously received over 5 regimens for their disease or and prior radiotherapy to the pelvis or abdomen, were also excluded from the trial.

Study participants were randomized to receive either VB-111 plus paclitaxel, or placebo plus paclitaxel. Patients in the experimental arm received intravenous (IV) VB-111 at a dose of 1 x 1013 viral particles every 2 months and IV paclitaxel at a weekly dose of 80 mg/m².

The primary end point of the study is OS, while secondary end points include progression free survival, combined CA-125 and RECIST v1.1 response, CA-125 response, and objective response rate per RECIST v1.1 criteria.

Prior data from a prospective, open-label, dose-escalating phase 1/2 trial (NCT01711970) evaluating VB-111 with paclitaxel in patients with platinum-resistant ovarian cancer showed that the regimen induced a CA-125 response in 58% of evaluable patients.⁴ Half of study participants had received previous antiangiogenic therapy and half had platinum-refractory disease. Notably, efficacy with the combination was observed, despite these poor prognostic characteristics.

Of the participants who experienced a decrease in CA-125 of greater than 50%, investigators observed a favorable trend for OS. Post treatment fever was associated with improve survival, at 808 days in patients who had a fever compared with 479 days in those who did not (P = .27). The agent was found to be well tolerated.

This article was published by OncLive.

Bevacizumab Beyond Disease Progression Plus Carboplatin-Based Doublet in Platinum-Sensitive Ovarian Cancer

By Matthew Stenger

In the phase III MITO16b/MANGO–OV2/ENGOT–ov17 trial, investigators found that treatment with a carboplatin-based doublet plus bevacizumab beyond disease progression significantly improved progression-free survival vs a carboplatin-based doublet alone in women with platinum-sensitive ovarian cancer who experienced disease recurrence after first-line treatment with a platinum-based therapy plus bevacizumab. The study was reported in The Lancet Oncology by Sandro Pignata, MD, and colleagues.

As stated by the investigators, “Bevacizumab is approved in combination with chemotherapy for the treatment of ovarian cancer, either in first-line therapy or for patients with recurrent disease not previously treated with the same drug. We aimed to test the value of continuing bevacizumab beyond progression after first-line treatment with the same drug.”

Study Details

The open-label trial included 406 women from sites in Italy, France, Switzerland, and Greece who had previously received first-line platinum-based therapy including bevacizumab and had recurrent (≥ 6 months since last platinum dose) stage IIIB to IV disease. Patients were randomly assigned between December 2013 and November 2016 to receive a carboplatin-based doublet plus continued bevacizumab (bevacizumab group, n = 203) or a carboplatin-based doublet alone (control group, n = 203).

Chemotherapy consisted of investigator’s choice, selected prior to random assignment, of:

• Carboplatin at area under the curve (AUC) = 5 on day 1 plus paclitaxel at 175 mg/m² on day 1 every 21 days
• Carboplatin AUC = 4 on day 1 plus gemcitabine at 1,000 mg/m² on days 1 and 8 every 21 days
• Carboplatin AUC = 5 on day 1 plus pegylated liposomal doxorubicin at 30 mg/m² on day 1 every 28 days.

Bevacizumab was given at 10 mg/kg every 14 days when combined with pegylated liposomal doxorubicin/carboplatin or at 15 mg/kg every 21 days when combined with gemcitabine/carboplatin or paclitaxel/carboplatin. The primary endpoint was investigator-assessed progression-free survival in the intention-to-treat population.

Progression-Free Survival

Median follow-up was 20.1 months (interquartile range = 12.9–27.8 months). Median progression-free survival was 11.8 months (95% confidence interval [CI] = 10.8–12.9 months) in the bevacizumab group vs 8.8 months (95% CI = 8.4–9.3 months) in the control group (hazard ratio [HR] = 0.51, 95% CI = 0.41–0.65, P < .0001). Hazard ratios favored the bevacizumab group in all subgroups examined except for the subgroup of 53 patients with BRCA1 or BRCA2 mutations: hazard ratios were 0.36 (95% CI =0.25–0.50) among 203 patients with wild-type BRCA and 1.58 (95% CI = 0.667–3.71) among those with mutations (P = .0004 for interaction).

Among 130 vs 143 patients eligible for objective response rate analysis, objective response was observed in 69.2% vs 49.7% of patients (P = .001). Median overall survival was 26.7 months (95% CI = 22.7–30.5 months) vs 27.1 months (95% CI = 22.0 months–not reached; HR = 0.99, 95% CI = 0.73–1.39, P < .98).

Adverse Events

Grade ≥ 3 adverse events occurred in 79% of patients in the bevacizumab group vs 69% in the control group, with the most common in the bevacizumab group being decreased neutrophil count (40% vs 41% in control group), decreased platelet count (30% vs 22%), and hypertension (29% vs 10%). Grade 3 to 4 proteinuria occurred in 4% vs 0%. Serious adverse events occurred in 26% vs 20% of patients. Death considered related to treatment occurred in one patient in the bevacizumab group and two patients in the control group.

The investigators concluded, “Continuing bevacizumab beyond progression combined with chemotherapy in patients with platinum-sensitive recurrent ovarian cancer improves progression-free survival compared with standard chemotherapy alone and might be considered in clinical practice.”

Dr. Pignata, of the Istituto Nazionale per lo Studio e la Cura dei Tumori IRCCS Fondazione Pascale, Naples, is the corresponding author for The Lancet Oncology article.

This article was published by The ASCO Post.

Pap Test/Cervical Swab Samples Can Reveal Ovarian Cancer Biomarkers

By Sharon Worcester

Residual fixatives from liquid-based Pap tests and cervical swabs contain tumor-specific biomarkers for ovarian cancer, according to an analysis of proteins found in matched biospecimens from a woman with high grade serous ovarian cancer.

The findings suggest that Pap test fluid or cervical swabs could be used to detect ovarian cancer biomarker proteins to allow for earlier detection of ovarian cancer, reported Kristin L. M. Boylan, PhD, assistant director of the Ovarian Cancer Early Detection Program at the University of Minnesota, Minneapolis, and colleagues.

The investigators examined the biospecimens from a 72-year-old woman diagnosed with metastatic high-grade serous adenocarcinoma that did not encompass the cervix. The Pap test, obtained prior to surgery, was negative for malignancy, but nearly 5,000 proteins were detected in the three matched biospecimens, including more than 2,000 that were expressed in each of them.

These proteins included several known ovarian cancer biomarkers, such as CA125, HE4, and mesothelin, the investigators noted.

The findings were published online Feb. 9 in Clinical Proteomics.

“Our data demonstrate that ovarian cancer biomarkers can be detected in Pap test fluid or a cervical swab by MS-based proteomics,” they wrote. “In addition to identifying multiple known biomarkers, over 2,000 proteins were detected in all three biospecimens, suggesting a potential role for novel biomarker discovery.”

Proteins from the cell-free supernatant of the patient’s liquid-based Pap test fixative were concentrated by acetone precipitation or eluted from the cervical swab, and protein was also extracted from the patient’s tumor. Analyses showed similarities in the Pap test fluid and cervical swab proteins, as well as the tumor extract, they said.

The findings are notable, because while early detection of ovarian cancer increases survival, an adequately sensitive and specific screening tool for use in the general population is lacking, they explained.

Pap test screening is widely accepted, suggesting that developing it as a screening tool for both cervical and ovarian cancers could improve testing for this “lethal but elusive disease,” they added, concluding that “[W]hile our samples were from a single patient, the results are proof of concept: that Pap test fluid or cervical swabs could be used for detection of ovarian cancer biomarker proteins, and this approach warrants further investigation.”

Senior author Amy Skubitz, PhD, professor and director of the Ovarian Cancer Early Detection Program, stated in a press release that she “sees an opportunity for this method to be translated into a self-administered, at-home test, where swabs could be collected by women at home and sent to a central laboratory for analysis of proteins that would diagnose ovarian cancer.”

However, next steps include using quantitative mass spectrometry to determine if the proteins or peptides identified in this analysis are detected at higher levels in ovarian cancer Pap tests or swabs compared to controls.

“Their presence alone is not sufficient for diagnosis,” she stated.

This study was supported by the Minnesota Ovarian Cancer Alliance, the Cancurables Foundation, Charlene’s Light: A Foundation for Ovarian Cancer, and the Department of Defense Ovarian Cancer Research Program Pilot Award. The authors reported having no disclosures.

This article was published by MDEdge.

How Biomarker Testing May Help Women Battling Ovarian Cancer

Receiving a cancer diagnosis can be overwhelming. But the more you know about your specific situation, the better.

By Alice Oglethorpe

Every year, more than 21,000 women in the United States are diagnosed with ovarian cancer. In about half of these cases, women have tumors with homologous recombination deficiency (HRD). HRD describes a tumor that has an impaired ability to repair DNA damage via a specific pathway. Ovarian cancers with HRD harbor a BRCA mutation and may display other irregularities that result in genomic instability and are particularly sensitive to certain therapies. HRD may be caused by mutations in the BRCA, ATM, and CHEK1/2 genes. These mutations can be inherited or acquired later in life.

Regardless of the cause, the prognosis for ovarian cancer is disheartening: the five-year relative combined survival rate for ovarian cancer at all stages is 47%. However, when it comes to ovarian cancer treatment, knowledge is power. That’s where genetic and biomarker testing come in.

In 2012, when Rozzie* consulted her doctor about some pain she had experienced, she didn’t know much about ovarian cancer or gene mutations that can impact a cancer diagnosis—but that was about to change. Her doctor ordered two CT scans in the area of her pain and the first came back fine, but the second brought bad news. The CT scan results were confirmed after the doctor performed a biopsy on some masses in her neck: Rozzie had advanced ovarian cancer.

The role of genetics and tumor biology in ovarian cancer

Finding out as much as possible about ovarian cancer is a crucial first step after diagnosis. Certain genes can help inform the specific type of cancer as well as treatment options, which is why genetic testing can be key. These tests, done through a blood draw, saliva, or a sample from a tumor, identify inherited mutations and cancer risks. The results can help confirm a diagnosis, predict disease progression, calculate the risk of recurrence, and identify how a patient may respond to specific therapies.

In Rozzie’s case, her doctor recommended genetic testing after her diagnosis. It was important to her to find a doctor who made her feel comfortable and would help her fight this disease.

“Don’t be afraid of what you might find out from a genetic test. Be more afraid of what you don’t know.”

“Every year on the anniversary of my ovarian cancer diagnosis I send all of my doctors a thank you letter,” Rozzie says, “If it wasn’t for them persevering to determine why I had been in pain all those years ago, I wouldn’t be here today.”

Rozzie worked with her genetic counselor to complete her testing and she found out within a few weeks that she had an inherited BRCA mutation, which can fall under the HRD family. With this new information, Rozzie and her doctor were able to develop a treatment plan customized to her tumor biology.

“Although I was initially afraid, my doctor assured me that having ovarian cancer with a gene mutation, like BRCA, gives my treatment team more data to make informed decisions to manage and treat my disease,” says Rozzie. “I learned not to be afraid of what you might find out—be more afraid of what you don’t know.”

The importance of biomarker testing

Biomarker testing for HRD is becoming an important step after a cancer diagnosis to help oncologists make informed decisions about treatment. For example, the results can help determine if targeted therapies such as PARP inhibitors should be used.

PARP inhibitors work to fight cancer with mutated genes by blocking PARP pathways, which makes it difficult for tumor cells with abnormal genes (such as a BRCA gene) to continue to thrive. Understanding your gene mutation status can help your doctor understand if you may be eligible for treatment with a PARP inhibitor. If eligible, patients take these treatments daily by mouth, as pills or capsules.

“Testing for gene mutations allowed me to learn more about my cancer and create a plan for my treatment journey,” Rozzie says. “I didn’t decide to get cancer, but I did decide to get genetic testing, which made me feel more in control. Knowledge is power.”

This article was published by Women’s Health.

Proton Therapy Induces Biologic Response to Attack Treatment-Resistant Cancers

Mayo Clinic researchers have developed a novel proton therapy technique to more specifically target cancer cells that resist other forms of treatment. The technique is called LEAP, an acronym for “biologically enhanced particle therapy.” The findings are published today in Cancer Research, the journal of the American Association for Cancer Research.

“The human body receives tens of thousands of DNA lesions per day from a variety of internal and external sources,” says Robert Mutter, M.D., a radiation oncologist at Mayo Clinic and co-principal investigator of the study.” Therefore, cells have evolved complex repair pathways to efficiently repair damaged DNA. Defects in these repair pathways can lead to the development of diseases, including cancer, says Dr. Mutter.

“Defects in the ATM-BRCA1-BRCA2 DNA repair pathway are commonly observed in cancer,” says Dr. Mutter. “And breast and ovarian cancer mutations in BRCA1 and BRCA2 repair genes are the most common cause.”

Dr. Mutter; Zhenkun Lou, Ph.D., co-principal investigator of the study; and their colleagues studied a novel method of delivering proton therapy to target tumors with inherent defects in the ATM-BRCA1-BRCA2 DNA repair pathway.

“We compared the effects of delivering the same amount of energy or dose into cancer cells using a dense energy deposition pattern with LEAP versus spreading out the same energy more diffusely, which is typical of conventional photon and proton therapy,” says Dr. Mutter. “Surprisingly, we discovered that cancers with inherent defects in the ATM-BRCA1-BRCA2 pathway are exquisitely sensitive to a new concentrated proton technique.”

Dr. Lou says surrounding normal tissues were spared, and their full complement of DNA repair elements remained intact. “We also found that we could rewire the DNA repair machinery pharmacologically by co-administration of an ATM inhibitor, a regulator of the body’s response to DNA damage, to make repair-proficient cells exquisitely sensitive to LEAP,” says Dr. Lou.

Dr. Mutter says the distinct physical characteristics of protons allow radiation oncologists to spare nearby normal tissues with superior accuracy, compared to conventional photon-based radiation therapy. “LEAP is a paradigm shift in treatment, whereby newly discovered biologic responses, induced when proton energy deposition is concentrated in cancer cells using novel radiation planning techniques, may enable the personalization of radiotherapy based on a patient’s tumor biology,” says Dr. Mutter.

Drs. Mutter and Lou say their findings are the product of several years of preclinical development through collaboration with experts in physics, radiation biology and mechanisms of DNA repair. Dr. Mutter and the radiation oncology team at Mayo Clinic are developing clinical trials to test the safety and efficacy of LEAP in multiple tumor types.

This article was published by NewsWise.

Improving Cancer Immunotherapy by Blocking Glucose Supply

All cells use sugar as a vital source of energy and building blocks. Unfortunately, that means even cancer cells use sugar. Researchers at Memorial Sloan Kettering (MSK) Cancer Center wondered what happens when tumor cells and immune cells battle for the same sugar supply. Using mouse models and data from human patients, the researchers found a direct relationship between the amount of sugar that a tumor consumes and the effectiveness of immunotherapy. The more sugar the tumor consumed, the less effective the immunotherapy.

Their findings, “CTLA-4 blockade drives loss of T_reg stability in glycolysis-low tumors,” were published in Nature and suggest that blocking cancer cells’ use of sugar could tip the scales in favor of immune cells, especially when they are activated by immunotherapy drugs.

“Limiting the metabolic competition in the tumor microenvironment (TME) may increase the effectiveness of immunotherapy,” the researchers wrote. “Because of its critical role in glucose metabolism of activated T cells, CD28 signaling has been proposed as a T-cell metabolic biosensor. Conversely, CTLA-4 engagement has been shown to down-regulate T-cell glycolysis. Here, we investigated the impact of CTLA-4 blockade on the metabolic fitness of intra-tumor T cells in relationship to the tumor glycolytic capacity. We found that CTLA-4 blockade promotes immune cell infiltration and metabolic fitness especially in glycolysis-low tumors.”

“If we reduce a tumor’s use of glucose, then we free up more of it for immune cells to use, which benefits the immune response,” said Taha Merghoub, PhD, assistant attending lab member at MSK Cancer Center, who co-led the research effort.

“What we think we’ve identified is a new means to improve checkpoint blockade immunotherapy,” added Jedd D. Wolchok, MD, PhD, medical oncologist at MSK. Wolchok also serves as chief of the immuno-oncology service in the human oncology and pathogenesis program, directs the Parker Institute for Cancer Immunotherapy, and co-directs the Ludwig Center for Cancer Immunotherapy at MSK.

The researchers used a mouse model of breast cancer that is highly glycolytic to observe the relationship between tumor cells’ use of glucose and response to immunotherapy. In the first set of tumors, the researchers genetically knocked down key enzyme cells required to rapidly consume glucose in a process called glycolysis. In the second set, the enzyme was left alone. Each set of tumors was grown in mice and then the mice were treated with checkpoint inhibitors targeting CTLA-4 before having surgery to remove the tumor.

The researchers found that the mice whose tumors consumed less sugar survived longer and had a far lower rate of metastasis than the mice with tumors that used more glucose.

The researchers also noted that the improved immune response exhibited memory. When researchers re-implanted tumors in the mice exposed to the less-glycolytic tumors, tumor growth remained suppressed.

By mimicking the highly and poorly glycolytic TME in vitro, the researchers showed that the effect of CTLA-4 blockade to promote Treg destabilization is dependent on T_reg glycolysis and CD28 signaling. These findings indicated that decreasing tumor competition for glucose may facilitate the therapeutic activity of CTLA-4 blockade, thus supporting its combination with inhibitors of tumor glycolysis.

“It was surprising and exciting to see that CTLA-4 blockade induces T_regs to use glucose and that this in turn reduces the suppression activity of these cells,” noted Roberta Zappasodi, PhD, a former Parker Institute Bridge scholar in the Merghoub-Wolchok lab and now a faculty member at Weill Cornell Medicine.

“The implication is that for tumors that are highly glycolytic and don’t respond to immune checkpoint blockade, one way of overcoming this resistance is to target tumor glycolysis with drugs,” Merghoub added.

These findings reveal that there is a need for drugs that can prevent tumor cells from using glucose while allowing immune cells to use it freely.

This article was published by GEN News.

Common Genetic Test Often Wrong When Identifying Rare Disease-Causing Variants Such as BRCA1 and BRCA2, Study Says

By Sandee LaMotte, CNN

A genetic test used to detect common traits many people share is not reliable in identifying rare disease-causing variations, such as those that can predict breast and ovarian cancer, a new study has found.

The SNP test, which stands for “single nucleotide polymorphism,” is used by direct-to-consumer DNA and ancestry companies to identify common traits such as eye color, height and proclivity toward cheek dimples and dandruff, to name a few.

But when SNP tests are applied to identifying rare mutations that contribute to disease, the study found only 16% of nearly 5,000 rare mutations could be confirmed bymore stringent DNA sequencing tools.

When applied to mutations in BRCA1 and BRCA2 genes, which can predict a high risk for breast and ovarian cancer, the SNP test only had a positive predictive value of 4.2%, according to the study published Monday in the journal BMJ Open Access.

“It seems that a very rare, disease-causing variant detected using a SNP chip is more likely to be wrong than right,” said study co-author Caroline Wright, a professor of genomic medicine at the University of Exeter in the United Kingdom, and co-author Michael Weedon, an associate professor in bioinformatics and human genetics at the University of Exeter, in an accompanying commentary to the study.

“The implications of our findings are very simple: SNP chips perform poorly for detecting very rare genetic variants and the results should never be used to guide a patient’s medical care, unless they have been validated,” added co-author Leigh Jackson, a lecturer in genomic medicine at Exeter, in a separate press statement.

Patients were scheduling unneeded surgeries

Wright told CNN the idea for the study came from anecdotal reports from fellow clinicians, who knew patients scheduled for “invasive medical procedures that were both unnecessary and unwarranted” based on what turned out to be false-positive SNP results.

In what they consider to be the first large-scale study of its kind, the team decided to use the UK Biobank to test the accuracy of the SNP tests in identifying rare disease-causing genes. The Biobank is a research repository of in-depth genetic and health information from 500,000 people who live in the UK.

The genes of nearly 50,000 people in the UK Biobank had undergone both SNP testing and next generation sequencing, a DNA test with high “accuracy for these rare variants,” Wright said.

“This large dataset allowed us to systematically investigate the performance of SNP chips across millions of genetic variants with a wide range of frequencies, down to those present in fewer than 1 in 100,000 individuals,” wrote Wright and Weedon in the commentary.

Those results were then compared to data from a small group of people in the Personal Genome Project, a non-profit global effort designed to encourage people to share their consumer genetic data for research.

In that small group, the study “found that nearly every individual had at least one rare disease-causing variant that was falsely detected by the SNP chip,” Wright and Weedon wrote.

DNA tests called SNP’s aren’t sensitive enough to correct identify rare disease-causing genes, the study said.

“SNP’s are just the wrong tool for the job when it comes to rare variants,” Wright told CNN. “They’re excellent for the common variants that are present in lots of people, but the rarer the variant is, the less likely they are to be able to correctly detect it.”

Quality control

Does this mean that consumers should toss out the health data they’ve gotten from a consumer-based DNA test? No, Wright says, because she believes credible genetic testing companies would send out any such data for more detailed sequencing before reporting the results to their customers.

“I’m not as concerned about the variants companies specifically report to their consumers, because they will have done additional quality control on those specific variants.” Wright said.

CNN reached out to two of the largest DNA testing consumer sites, Ancestry and 23andMe.

Although the AncestryHealth product was discontinued in mid-January, Ancestry spokesperson Gina Spatafore told CNN they would continue to support existing customers. Spatafore confirmed that AncestryHealth did indeed confirm any rare disease findings via a lab certified by the Center for Medicare and Medicaid Services as part of the Clinical Laboratory Improvement Amendments (CLIA) regulations.

“It is true that SNP chips do not detect very rare, single-point mutations as well as sequencing can — this has been a well-known and validated fact for many years,” Spatafore said.

“That’s why health results provided through our AncestryHealth product are fully validated in CLIA laboratories before they are reported to our customers,” she said. “Ancestry has never reported any health finding that was not shown by a CLIA lab to be both clinically and analytically valid.”

Andy Kill, communications manager for 23andMe, told CNN that the company only reported rare disease data on “three of the most well-studied” BRCA genes which “carry clear, documented risk for breast and ovarian cancer.”

“About 1 in 40 individuals of Ashkenazi Jewish descent has one of these three variants,” Kill told CNN.

In addition, 23andMe requires users to take “a tutorial that very clearly spells out we are only testing for three of 1,000+ genetic variants, and if you do not have one of these variants to not forgo other screenings,” Kill said.

Breast cancer tops lung cancer as most diagnosed cancer in the world, new report says “If an individual has a family history of a medical condition or other indications for clinical testing, we always recommend consulting a health care provider first,” he said.

Careful with raw data

Wright said her biggest concern is that studies show people often upload their raw data to third party websites that offer to further analyze their genetic makeup. When they do that, consumers may well be uploading “hundreds of thousands of other variants that haven’t necessarily gone through such strict quality control.”

“This raw data still contain these erroneous results,” Wright said. “Some of those will be very wrong, and yet might be linked to disease.”

Both Ancestry and 23andMe spokespeople told CNN they echo those concerns.

“We caution all of our customers who wish to use their unvalidated raw genotypic data to not do so for any health purposes,” Spatafore said.

On their website, 23andMe tells its users that if they decide to download their raw data, they should “take caution in uploading your data to any third party applications or any service outside of your 23andMe account.

“Raw data should not be used for medical purposes and we do not recommend the use of third party services that claim to interpret raw data to provide health information.”

When it comes to disease risk from BRCA genes, the US Centers for Disease Control and Prevention advises that “a direct-to-consumer genetic test may not give you a complete understanding of your breast cancer risk, especially if breast cancer runs in your family.

“If you think you may be at higher risk for breast cancer, it is best to work with a doctor or genetic counselor who can assess your risk, interpret your results, and build an action plan.”

This article was published by CNN Health.

Moffitt Researchers Discover Mechanism that Regulates Anti-Tumor Activity of Immune Cells

The study finally paves the way for the use of antibodies different from IgG as immunotherapeutic agents for at least tumors currently resistant to conventional immune checkpoint blockade.

The prognosis of ovarian cancer is poor, with an estimated five-year survival of only 40% for advanced disease, the stage at which most ovarian carcinomas are diagnosed. These poor outcomes are partly due to the lack of effective therapies for advanced disease and recurrence. Immunotherapies hold promise for many types of cancer; however, studies have shown that patients with ovarian cancer do not have strong responses to existing drugs. In a new article published in Nature, Moffitt Cancer Center researchers demonstrate why some ovarian cancer patients evolve better than others and suggest possible approaches to improve patient outcomes.

Immunotherapeutic drugs activate T cells, a type of immune cell, to put up a defense against tumor cells. Immunotherapies are approved to treat several different types of cancer and have greatly changed the standard of care and improved patient outcomes. However, in ovarian cancer, clinical studies using immunotherapies aimed at stimulating T cells resulted in modest response rates. Studies have suggested that cancer patients who have a higher presence of other immune cells, such as plasma and memory B cells, could respond better to immunotherapies, but how these cell types promote better outcomes is unclear. Moffitt researchers wanted to confirm whether antibodies produced by these cells are associated with better outcomes and assess how these cells contribute to the spontaneous anti-tumor immune response against ovarian cancer.

The researchers analyzed a panel of 534 samples from ovarian cancer patients and found that patients who had a higher infiltration of B cells or B cell-derived plasma cells had better outcomes. B cells are a type of immune cell that produce antibodies and express one of five types of B cell receptors on their surface: IgM, IgD, IgG, IgE or IgA. These isotypes regulate different B cell signaling pathways and control B cell processes.

The surprise came when, upon further analysis of the samples, the Moffitt team discovered that the antibodies produced by B and plasma cells were predominantly of the IgA subtype, followed by IgG.

“We found that the presence of IgA regulated downstream signaling pathways of the ovarian cancer cells. Specifically, IgA resulted in inhibition of the RAS signaling pathway, which is known to contribute to ovarian cancer development,” said Jose Conejo-Garcia, M.D., Ph.D., chair of Moffitt’s Immunology Department.

This inhibition of RAS sensitized the tumor cells to T cell mediated cell killing, produced by both novel CAR T cells and tumor-infiltrating lymphocytes. The team also assessed that IgA and IgG secreted by the B cells recognized specific ovarian tumor cell surface markers and stimulated other immune cells called myeloid cells to target ovarian cancer cells for destruction.

These data provide new insights into how components of the immune system regulate ovarian cancer progression and offer new opportunities to develop improved targeted agents. This includes a repertoire of tumor-derived antibodies that can be effectively used as novel immunotherapeutic agents. In addition, the study provides a mechanistic rationale for integrated antibody responses in the development of novel immunotherapies, which until now have been based on T cell-centric approaches.

“The findings indicate that immunotherapies that boost both coordinated B and T cell responses against ovarian cancer, an immunogenic disease currently resistant to checkpoint inhibitors, are likely to show superior therapeutic benefit,” said Subir Biswas, Ph.D., first author and postdoctoral fellow in the Conejo-Garcia lab.

This article was published by EurekaAlert!.