Vitamin K antagonism impairs the bone marrow microenvironment and hematopoiesis.

Vitamin K antagonists (VKAs) have been used in 1% of the world's population for prophylaxis or treatment of thromboembolic events for 64 years. Impairment of osteoblast function and osteoporosis has been described in patients receiving VKAs. Given the involvement of cells of the bone marrow microenvironment (BMM), such as mesenchymal stem cells (MSCs) and macrophages, as well as other factors such as the extracellular matrix for the maintenance of normal hematopoietic stem cells (HSCs), we investigated a possible effect of VKAs on hematopoiesis via the BMM. Using various transplantation and in vitro assays, we show here that VKAs alter parameters of bone physiology and reduce functional HSCs 8-fold. We implicate impairment of the functional, secreted, vitamin K-dependent, γ-carboxylated form of periostin by macrophages and, to a lesser extent, MSCs of the BMM and integrin ß3-AKT signaling in HSCs as at least partly causative of this effect, with VKAs not being directly toxic to HSCs. In patients, VKA use associates with modestly reduced leukocyte and monocyte counts, albeit within the normal reference range. VKAs decrease human HSC engraftment in immunosuppressed mice. Following published examples that alteration of the BMM can lead to hematological malignancies in mice, we describe, without providing a causal link, that the odds of VKA use are higher in patients with vs without a diagnosis of myelodysplastic syndrome (MDS). These results demonstrate that VKA treatment impairs HSC function via impairment of the BMM and the periostin/integrin ß3 axis, possibly associating with increased MDS risk.

SUMO-specific proteases and isopeptidases of the SENP family at a glance.

The ubiquitin-related SUMO system controls many cellular signaling networks. In mammalian cells, three SUMO forms (SUMO1, SUMO2 and SUMO3) act as covalent modifiers of up to thousands of cellular proteins. SUMO conjugation affects cell function mainly by regulating the plasticity of protein networks. Importantly, the modification is reversible and highly dynamic. Cysteine proteases of the sentrin-specific protease (SENP) family reverse SUMO conjugation in mammalian cells. In this Cell Science at a Glance article and the accompanying poster, we will summarize how the six members of the mammalian SENP family orchestrate multifaceted deconjugation events to coordinate cell processes, such as gene expression, the DNA damage response and inflammation.

Acetylation of SUMO2 at lysine 11 favors the formation of non-canonical SUMO chains.

Post-translational modifications by ubiquitin-related SUMO modifiers regulate cellular signaling networks and protein homeostasis. While SUMO1 is mainly conjugated to proteins as a monomer, SUMO2/3 can form polymeric chains. Poly-SUMOylation is best understood in the SUMO-targeted ubiquitin ligase (StUbL) pathway, where chains prime proteins for subsequent ubiquitylation by StUbLs. SUMO chains typically form in response to genotoxic or proteotoxic stress and are preferentially linked via lysine 11 of SUMO2/3. Here, we report that K11 of SUMO2/3 undergoes reversible acetylation with SIRT1 being the K11 deacetylase. In a purified in vitro system, acetylation of SUMO2/3 impairs chain formation and restricts chain length. In a cellular context, however, K11 acetyl-mimicking SUMO2 does not affect the StUbL pathway, indicating that in cells non-canonical chains are more prevalent. MS-based SUMO proteomics indeed identified non-canonical chain types under basal and stress conditions. Importantly, mimicking K11 acetylation alters chain architecture by favoring K5- and K35-linked chains, while inhibiting K7 and K21 linkages. These data provide insight into SUMO chain signaling and point to a role of K11 acetylation as a modulator of SUMO2/3 chains.

Assays of SUMO protease/isopeptidase activity and function in mammalian cells and tissues.

Covalent conjugation of the ubiquitin-related SUMO modifier to lysine residues of cellular proteins (SUMOylation) is a prevalent posttranslational modification. SUMOs are synthesized as precursor proteins that require carboxy-terminal processing prior to conjugation. Subsequently, a multistep enzymatic pathway is used for conjugation to target proteins. SUMOylation generally impacts protein-protein interactions and the assembly of multiprotein complexes. Cellular processes regulated by SUMOylation include DNA damage responses, cell cycle progression, or the control of gene expression. SUMOylation is reversible and commonly only a small fraction of a particular SUMO target is modified at a given time. Deconjugation of SUMO is catalyzed by a group of cysteine proteases termed SUMO proteases or SUMO isopeptidases. In human cells nine SUMO proteases, belonging to three separate families of cysteine proteases have been identified so far. The regulation and target specificity of individual SUMO proteases have not been dissected in detail, but the current view is that each protease controls the modification of subsets of proteins that are functionally and/or physically linked. Importantly, some SUMO proteases/isopeptidases not only function in deconjugation of SUMO from proteins, but also act in C-terminal processing of the SUMO precursors. Here we describe general methods for monitoring SUMO protease/isopeptidase activities in cell or tissue extracts.

The SUMO Isopeptidase SENP6 Functions as a Rheostat of Chromatin Residency in Genome Maintenance and Chromosome Dynamics.

Signaling by the ubiquitin-related SUMO pathway relies on coordinated conjugation and deconjugation events. SUMO-specific deconjugating enzymes counterbalance SUMOylation, but comprehensive insight into their substrate specificity and regulation is missing. By characterizing SENP6, we define an N-terminal multi-SIM domain as a critical determinant in targeting SENP6 to SUMO chains. Proteomic profiling reveals a network of SENP6 functions at the crossroads of chromatin organization and DNA damage response (DDR). SENP6 acts as a SUMO eraser at telomeric and centromeric chromatin domains and determines the SUMOylation status and chromatin association of the cohesin complex. Importantly, SENP6 is part of the hPSO4/PRP19 complex that drives ATR-Chk1 activation. SENP6 deficiency impairs chromatin association of the ATR cofactor ATRIP, thereby compromising the activation of Chk1 signaling in response to aphidicolin-induced replicative stress and sensitizing cells to DNA damage. We propose a general role of SENP6 in orchestrating chromatin dynamics and genome stability networks by balancing chromatin residency of protein complexes.

SUMO Signaling by Hypoxic Inactivation of SUMO-Specific Isopeptidases.

Post-translational modification of proteins with ubiquitin-like SUMO modifiers is a tightly regulated and highly dynamic process. The SENP family of SUMO-specific isopeptidases comprises six cysteine proteases. They are instrumental in counterbalancing SUMO conjugation, but their regulation is not well understood. We demonstrate that in hypoxic cell extracts, the catalytic activity of SENP family members, in particular SENP1 and SENP3, is inhibited in a rapid and fully reversible process. Comparative mass spectrometry from normoxic and hypoxic cells defines a subset of hypoxia-induced SUMO1 targets, including SUMO ligases RanBP2 and PIAS2, glucose transporter 1, and transcriptional regulators. Among the most strongly induced targets, we identified the transcriptional co-repressor BHLHE40, which controls hypoxic gene expression programs. We provide evidence that SUMOylation of BHLHE40 is reversed by SENP1 and contributes to transcriptional repression of the metabolic master regulator gene PGC-1α. We propose a pathway that connects oxygen-controlled SENP activity to hypoxic reprogramming of metabolism.