Molecular Determinants and Consequences of Specificity in Histone 2A Ubiquitination

Specific ubiquitination of histones H2A is a crucial decision making point in the response to DNA damage. This thesis analysis the role of three distinct groups of lysines on H2A that are specifically ubiquitinated by three different E3 ligases, RING1b/BMI1, BRCA1/BARD1 and RNF168. The mechanistic basics underlying this specificity are discussed. The work describes how specific ubiquitination is employed to guide repair pathway choice between homologous recombination and non-homologous end joining. It shows that USP48, a deubiquitinating enzyme specific for the BRCA1 ubiquitination site, guides repair pathway choice by determining the extent of DNA end resection. Analysis of the E3 ligase RNF168 shows how specific interaction of the E3 with the nucleosomal acidic patch defines site-specificity. Furthermore, a general framework for structural analysis of E3-E2-Substrate complexes is presented

USP48 restrains resection by site-specific cleavage of the BRCA1 ubiquitin mark from H2A

BRCA1 ligase activity is tightly regulated to maintain genome stability and confer DNA double strand repair. Here the authors identify USP48 as a H2A deubiquitinating enzyme that acts as a BRCA1 E3 ligase antagonist and characterize its role during DNA repair

Inflammation-induced emergency megakaryopoiesis driven by hematopoietic stem cell-like megakaryocyte progenitors

Infections are associated with extensive platelet consumption, representing a high risk for health. However, the mechanism coordinating the rapid regeneration of the platelet pool during such stress conditions remains unclear. Here, we report that the phenotypic hematopoietic stem cell (HSC) compartment contains stem-like megakaryocyte-committed progenitors (SL-MkPs), a cell population that shares many features with multipotent HSCs and serves as a lineage-restricted emergency pool for inflammatory insults. During homeostasis, SL-MkPs are maintained in a primed but quiescent state, thus contributing little to steady-state megakaryopoiesis. Even though lineage-specific megakaryocyte transcripts are expressed, protein synthesis is suppressed. In response to acute inflammation, SL-MkPs become activated, resulting in megakaryocyte protein production from pre-existing transcripts and a maturation of SL-MkPs and other megakaryocyte progenitors. This results in an efficient replenishment of platelets that are lost during inflammatory insult. Thus, our study reveals an emergency machinery that counteracts life-threatening platelet depletions during acute inflammation