Microscopy deep learning predicts viral infections

When viruses infect a cell, changes in the cell nucleus occur, and these can be observed through fluorescence microscopy. Using fluorescence images made in live cells, researchers at the University of Zurich have trained an artificial neural network to reliably recognize cells that are infected by adenoviruses or herpes viruses. The procedure also identifies severe acute infections at an early stage.

In humans, adenoviruses can infect the cells of the respiratory tract, while herpes viruses can infect those of the skin and nervous system. In most cases, this does not lead to the production of new virus particles, as the viruses are suppressed by the immune system. However, adenoviruses and herpes viruses can cause persistent infections that the immune system is unable to keep completely in check and that produce viral particles for years. These same viruses can also cause sudden, violent infections where affected cells release large amounts of viruses, such that the infection spreads rapidly. This can lead to serious acute diseases of the lungs or nervous system.

The research group of Urs Greber, Professor at the Institute of Molecular Life Sciences at the University of Zurich (UZH), has now shown for the first time that a machine-learning algorithm can recognize the cells infected with herpes or adenoviruses based solely on the fluorescence of the cell nucleus.

Greber said, our method not only reliably identifies virus-infected cells but also accurately detects virulent infections in advance. The study authors believe that their development has many applications including predicting how human cells react to other viruses or microorganisms. The method opens up new ways to better understand infections and to discover new active agents against pathogens such as viruses or bacteria.

The analysis method is based on combining fluorescence microscopy in living cells with deep-learning processes. Herpes and adenoviruses formed inside an infected cell change the organization of the nucleus, and these changes can be observed under a microscope. The group trained a deep-learning algorithm an artificial neural network to automatically detect these changes. The network is trained with a large set of microscopy images through which it learns to identify patterns that are characteristic of infected or uninfected cells. After training and validation are complete, the neural network automatically detects virus-infected cells.

The research team has also demonstrated that the algorithm is capable of identifying acute and severe infections with 95 percent accuracy and up to 24 hours in advance. Images of living cells from lytic infections, in which the virus particles multiply rapidly and the cells dissolve, as well as images of persistent infections, in which viruses are produced continuously but only in small quantities, served as training material. Despite the great precision of the method, it is not yet clear which features of infected cell nuclei the artificial neural network actually recognizes to distinguish the two phases of infection. However, even without this knowledge, the researchers are now able to study the biology of infected cells in greater detail.

The group has already discovered some differences: The internal pressure of the nucleus is greater during virulent infections than during persistent phases. In addition, in a cell with lytic infection, viral proteins accumulate more rapidly in the nucleus.

Greber said, we suspect that distinct cellular processes determine whether or not a cell disintegrates after it is infected. We can now investigate these and other questions.