Most often we think about cancer as developing from cells that acquire cancer-driving mutations, but there’s a subset of cancers driven by another culprit: viruses. To date, “seven human viruses have been identified that cause cancer,” explains Dr. Nicholas Salisbury, a postdoctoral fellow in Dr. Denise Galloway’s lab. Epstein-Barr virus (EBV) was the first of these to be discovered, whereas human papillomavirus (HPV), perhaps the most well-known of the cancer-causing viruses, was discovered a decade later, in the 1970s. The most recent virus to join this family, Merkel cell polyomavirus (MCV), was only discovered in 2008 and causes about 80% of Merkel cell carcinoma (MCC) cases. MCC is a rare, aggressive skin cancer that, unlike other skin cancers, is predominantly driven by viral infection rather than UV rays. After Merkel cell polyomavirus infects its host cell, it highjacks the cellular machinery to replicate its own genome and causes no evident disease. In a small subset of cases, Merkel cell viral DNA becomes integrated into the host genome and pushes the cell towards becoming cancerous. Dr. Salisbury shares that most people will “get infected with Merkel cell polyomavirus at some point during childhood through skin-to-skin contact, but only about 1 in 100,000 will develop cancer.” Unlike HPV, there is no vaccine available for Merkel cell polyomavirus. And as the newest cancer-causing virus on the block, we still have so much to learn about Merkel cell polyomavirus and what leads it to cause cancer so that more effective treatment options can be developed.
Merkel cell carcinoma is caused by expression of two viral genes: small and large tumor antigens, often referred to as small T and large T. However, it wasn’t until about 5 years after Merkel cell polyomavirus was first discovered that the Galloway lab found another gene encoded within Large T in an alternate reading frame, which they named the Alternate Large T Open reading frame, or ALTO for short. Comparing the genomes of different polyomaviruses, the Galloway lab found that the ALTO sequence was fairly similar to a gene in the mouse polyomavirus (Middle T) that can cause tumors in mice. Dr. Salisbury reasoned that “since Middle T and ALTO are evolutionarily related, we initially believed that ALTO might have the same function,” predicting ALTO was also an oncogene. In a recent PNAS article led by Salisbury, he set off to test this hypothesis. Ultimately in this study, Dr. Salisbury found that his initial hypothesis was incorrect—but what he uncovered could lead to the development of a new and much needed therapy for Merkel cell carcinoma.
This research started off as “a basic biology question: what is the function of this gene?” shares Dr. Salisbury. As he explains, “this virus has two distinct biologies. First, it can infect and replicate in human cells, but without causing symptoms or overt clinical disease. Second, it integrates into the human genome and no longer replicates but causes cancer.” From previous work knocking out ALTO in Merkel cell polyomavirus and infecting cells with this mutant virus, the Galloway lab knew it wasn’t essential for viral replication. Given its similarity to oncogenic mouse Middle T, it seemed likely that ALTO might play an essential role in causing cancer. For Dr. Salisbury, the first hint that this story might not be so straightforward was when he started to look at ALTO protein expression in MCC cells using an antibody the lab developed. “When the virus infected cells in culture, ALTO could be detected as little speckles throughout the cell. However, when looking at patient-derived MCC cells, ALTO could never be detected,” Dr. Salisbury notes. While he admits some people questioned why he wanted to study an oncovirus protein that didn’t appear to be expressed in the cancer, Dr. Salisbury continued his work anyway. “To me, the fact that the ALTO DNA sequence was present in these cancer cells, but they were not producing the protein, suggested something interesting was going on. There was likely a reason why ALTO expression had been shut down.” To get at why these cancer cells didn’t express ALTO, but did express small T and large T, Dr. Salisbury transfected various MCC cell lines with an ALTO expression construct to force expression of this mysterious viral gene. Restoring ALTO expression in MCC cells caused growth arrest, revealing that ALTO is in fact a tumor suppressor, not an oncogene.