A knockout-first model of H3f3a gene targeting leads to developmental lethality.

Histone variant H3.3 is encoded by two genes, H3f3a and H3f3b, which can be expressed differentially depending on tissue type. Previous work in our lab has shown that knockout of H3f3b causes some neonatal lethality and infertility in mice, and chromosomal defects in mouse embryonic fibroblasts (MEFs). Studies of H3f3a and H3f3b null mice by others have produced generally similar phenotypes to what we found in our H3f3b nulls, but the relative impacts of the loss of either H3f3a or H3f3b have varied depending on the approach and genetic background. Here we used a knockout-first approach to target the H3f3a gene for inactivation in C57BL6 mice. Homozygous H3f3a targeting produced a lethal phenotype at or before birth. E13.5 null embryos had some potential morphological differences from WT littermates including smaller size and reduced head size. An E18.5 null embryo was smaller than its control littermates with several potential defects including small head and brain size as well as small lungs, which would be consistent with a late gestation lethal phenotype. Despite a reduction in H3.3 and total H3 protein levels, the only histone H3 post-translational modification in the small panel assessed that was significantly altered was the unique H3.3 mark phospho-Serine31, which was consistently increased in null neurospheres. H3f3a null neurospheres also exhibited consistent gene expression changes including in protocadherins. Overall, our findings are consistent with the model that there are differential, cell-type-specific contributions of H3f3a and H3f3b to H3.3 functions in epigenetic and developmental processes.

Knockout tales: the versatile roles of histone H3.3 in development and disease.

Histone variant H3.3 plays novel roles in development as compared to canonical H3 proteins and is the most commonly mutated histone protein of any kind in human disease. Here we discuss how gene targeting studies of the two H3.3-coding genes H3f3a and H3f3b have provided important insights into H3.3 functions including in gametes as well as brain and lung development. Knockouts have also provided insights into the important roles of H3.3 in maintaining genomic stability and chromatin organization, processes that are also affected when H3.3 is mutated in human diseases such as pediatric tumors and neurodevelopmental syndromes. Overall, H3.3 is a unique histone linking development and disease via epigenomic machinery.

Stem cell models help crack regional oncohistone codes driving childhood gliomas.

In this issue of Cell Stem Cell, Funato et al. (2021) and Bressan et al. (2021) use stem cells as models to define functions of the histone H3.3 G34R mutation in childhood gliomas. Both studies find strong regional specificity to oncohistone activity and implicate specific elements of an aberrantly locked-in neural progenitor transcriptional circuitry.

A GRHL3-regulated repair pathway suppresses immune-mediated epidermal hyperplasia.

Dermal infiltration of T cells is an important step in the onset and progression of immune-mediated skin diseases such as psoriasis; however, it is not known whether epidermal factors play a primary role in the development of these diseases. Here, we determined that the prodifferentiation transcription factor grainyhead-like 3 (GRHL3), which is essential during epidermal development, is dispensable for adult skin homeostasis, but required for barrier repair after adult epidermal injury. Consistent with activation of a GRHL3-regulated repair pathway in psoriasis, we found that GRHL3 is upregulated in lesional skin and binds known epidermal differentiation gene targets. Using an imiquimod-induced model of immune-mediated epidermal hyperplasia, we found that mice lacking GRHL3 have an exacerbated epidermal damage response, greater sensitivity to disease induction, delayed resolution of epidermal lesions, and resistance to anti-IL-22 therapy compared with WT animals. ChIP-Seq and gene expression profiling of murine skin revealed that while GRHL3 regulates differentiation pathways both during development and during repair from immune-mediated damage, it targets distinct sets of genes in the 2 processes. In particular, GRHL3 suppressed a number of alarmin and other proinflammatory genes after immune injury. This study identifies a GRHL3-regulated epidermal barrier repair pathway that suppresses disease initiation and helps resolve existing lesions in immune-mediated epidermal hyperplasia.