Scientists provide explanation for how cancer spreads

Their work was Published in the May issue of Nature Reviews Cancer. The studies, spanning 15 years, have revealed that the newly formed hybrid of the cancer cell and white blood cell adapts the white blood cell’s natural ability to migrate around the body, while going through the uncontrolled cell division of the original cancer cell. This causes a metastatic cell to emerge, which like a white blood cell, can migrate through tissue, enter the circulatory system and travel to other organs.

“This is a unifying explanation for metastasis,” said John Pawelek, a researcher in the Department of Dermatology at Yale School of Medicine and at Yale Cancer Center, who conducted the studies with colleague Ashok K. Chakraborty and several other Yale scientists. “Although we know a vast amount about cancer, how a cancer cell becomes metastatic still remains a mystery.”

The fusion theory was first proposed in the early 1900s and has attracted a lot of scientific interest over the years. Pawelek and his colleagues began their research several years ago by fusing white blood cells with tumor cells. These experimental hybrids the researchers observed, were remarkably metastatic and lethal when implanted into mice. In addition, the scientists noted, some of the molecules the hybrids used to metastasize originated from white blood cells, and these molecules were the same as those used by metastatic cells in human cancers. Pawelek and his team then validated previous findings that hybridization occurs naturally in mice, and results in metastatic cancer.

“Viewing the fusion of a cancer cell and a white blood cell as the initiating event for metastasis suggests that metastasis is virtually another disease imposed on the pre-existing cancer cell,” said Pawelek. “We expect this to open new areas for therapy based on the fusion process itself.”

The research team recently began studying cancers from individuals who had received a bone marrow transplant—a new source of white blood cells for the patient. Genes from the transplanted white blood cells were found in the patient tumor cells, indicating that fusion with white blood cells had occurred. But Pawelek said these studies must be greatly expanded before his team can say with certainty that white blood cell fusion accounts for cancer metastasis in humans.

“To date, the fusion theory and the considerable evidence supporting it have largely been overlooked by the cancer research community,” said Pawelek. “The motivation for our article is to encourage other laboratories to join in.”

Source: Yale University

Researchers find new genetic target for sickle cell disease therapy
Researchers have identified a gene that directly affects the production of a form of hemoglobin that is instrumental in modifying the severity of the inherited blood disorders sickle cell disease and thalassemia. The discovery could lead to breakthrough therapies for sickle cell disease and thalassemia, which could potentially eliminate the devastating and life-threatening complications of these diseases, such as severe pain, damage to the eyes and other organs, infections, and stroke.
Bone marrow-derived stem cells may offer novel therapeutic option for skin disorder
Stem cells derived from bone marrow may serve as a novel therapeutic option to treat a disease called epidermolysis bullosa (EB), a disorder characterized by extraordinarily fragile skin, according to a study prepublished online in Blood, the official journal of the American Society of Hematology.
Dormant stem cells for emergencies
Many specialized cells, such as in the skin, intestinal mucosa or blood, have a lifespan of only a few days. For these tissues to function, a steady replenishment of specialized cells is indispensable. This is the task of so-called "adult" stem cells also known as tissue stem cells.
Researchers discover new enzyme in cancer growth
While studying the mechanics of blood clots, researchers at the University of Oklahoma Health Sciences Center discovered a new enzyme that not only affects the blood, but seems to play a primary role in how cancer tumors expand and spread throughout the body. The research appeared in recent issues of the journal Blood and the Journal of Thrombosis and Haemostasis.
Researchers identify cell group key to Lyme disease arthritis
A research team led by the La Jolla Institute for Allergy & Immunology and Albany Medical College has illuminated the important role of natural killer (NK) T cells in Lyme disease, demonstrating that the once little understood white blood cells are central to clearing the bacterial infection and reducing the intensity and duration of arthritis associated with Lyme disease.
Researchers provide definitive proof of where, how blood stem cells are created
Stem cell researchers at UCLA have proven definitively that blood stem cells are made during mid-gestational embryonic development by endothelial cells, the cells that line the inside of blood vessels.
Genetic breakdown in Fanconi anemia may have link to HPV-associated cancer
A genetic malfunction that causes DNA instability in people with the blood disorder Fanconi anemia may put them at high risk for squamous cell carcinomas linked to human papillomavirus (HPV), according to a study posted online ahead of print by Oncogene.
Magnetic nanotags allow sensitive detection of cancer biomarkers
(PhysOrg.com) -- The detection of cancer-associated proteins, or biomarkers, in blood samples is a potentially powerful tool for early diagnosis of cancer and monitoring of cancer treatment. A team led by researchers at Stanford University and the University of California, Santa Cruz, has developed a compact prototype detector that uses magnetic nanotechnology to spot cancer-associated proteins in a human blood serum sample with much higher sensitivity than current detectors.

Scientists provide explanation for how cancer spreads

Related stories:

News discussion: