Barcoding microbial ribosomal RNA creates a recording of gene transfer events without requiring translation.

Genome sequencing of cancer and normal tissues, alongside single-cell transcriptomics, continues to produce findings that challenge the idea that cancer is a ‘genetic disease’, as posited by the somatic mutation theory (SMT). In this prevailing paradigm, tumorigenesis is caused by cancer-driving somatic mutations and clonal expansion. However, results from tumor sequencing, motivated by the genetic paradigm itself, create apparent ‘paradoxes’ that are not conducive to a pure SMT. But beyond genetic causation, the new results lend credence to old ideas from organismal biology. To resolve inconsistencies between the genetic paradigm of cancer and biological reality, we must complement deep sequencing with deep thinking: embrace formal theory and historicity of biological entities, and (re)consider non-genetic plasticity of cells and tissues. In this Essay, we discuss the concepts of cell state dynamics and tissue fields that emerge from the collective action of genes and of cells in their morphogenetic context, respectively, and how they help explain inconsistencies in the data in the context of SMT.

Citation: Huang S, Soto AM, Sonnenschein C (2025) The end of the genetic paradigm of cancer. PLoS Biol 23: e3003052. https://doi.org/10.1371/journal.pbio.

Copyright: © 2025 Huang et al. This is an open access distributed under the terms of the Creative Commons Attribution License, which permits unrestricted use, distribution, and reproduction in any medium, provided the original author and source are credited.

Like people, bacteria get invaded by viruses. In bacteria, the viral invaders are called bacteriophages, derived from the Greek word for bacteria-eaters, or in shortened form, “phages.” Scientists have sought to learn how the single-cell organisms survive phage infection in a bid to further understand human immunity and develop ways to combat diseases.

Now, Johns Hopkins Medicine scientists say they have shed new light on how bacteria protect themselves from certain phage invaders—by seizing genetic material from weakened, dormant phages and using it to “vaccinate” themselves to elicit an immune response.

In their experiments, the scientists say Streptococcus pyogenes bacteria (which cause strep throat) take advantage of a class of phages known as temperate phages, which can either kill cells or become dormant. The bacteria steal genetic material from temperate phages during this dormant period and form a biological “memory” of the invader that their offspring inherit as the bacteria multiply. Equipped with these memories, the new population can recognize these viruses and fight them off.