Dallas C. Jones

Pharmacologic targeting of a stem/progenitor population in vivo is associated with enhanced bone regeneration in mice.

Drug targeting of adult stem cells has been proposed as a strategy for regenerative medicine, but very few drugs are known to target stem cell populations in vivo. Mesenchymal stem/progenitor cells (MSCs) are a multipotent population of cells that can differentiate into muscle, bone, fat, and other cell types in context-specific manners. Bortezomib (Bzb) is a clinically available proteasome inhibitor used in the treatment of multiple myeloma. Here, we show that Bzb induces MSCs to preferentially undergo osteoblastic differentiation, in part by modulation of the bone-specifying transcription factor runt-related transcription factor 2 (Runx-2) in mice. Mice implanted with MSCs showed increased ectopic ossicle and bone formation when recipients received low doses of Bzb. Furthermore, this treatment increased bone formation and rescued bone loss in a mouse model of osteoporosis. Thus, we show that a tissue-resident adult stem cell population in vivo can be pharmacologically modified to promote a regenerative function in adult animals.

Regulation of Adult Bone Mass by the Zinc Finger Adapter Protein Schnurri-3

Genetic mutations that disrupt osteoblast function can result in skeletal dysmorphogenesis or, more rarely, in increased postnatal bone formation. Here we show that Schnurri-3 (Shn3), a mammalian homolog of the Drosophila zinc finger adapter protein Shn, is an essential regulator of adult bone formation. Mice lacking Shn3 display adult-onset osteosclerosis with increased bone mass due to augmented osteoblast activity. Shn3 was found to control protein levels of Runx2, the principal transcriptional regulator of osteoblast differentiation, by promoting its degradation through recruitment of the E3 ubiquitin ligase WWP1 to Runx2. By this means, Runx2-mediated extracellular matrix mineralization was antagonized, revealing an essential role for Shn3 as a central regulator of postnatal bone mass.

The E3 ubiquitin ligase Wwp2 regulates craniofacial development through mono-ubiquitylation of Goosecoid

Craniofacial anomalies (CFAs) are the most frequently occurring human congenital disease, and a major cause of infant mortality and childhood morbidity. Although CFAs seems to arise from a combination of genetic factors and environmental influences, the underlying gene defects and pathophysiological mechanisms for most CFAs are currently unknown. Here we reveal a role for the E3 ubiquitin ligase Wwp2 in regulating craniofacial patterning. Mice deficient in Wwp2 develop malformations of the craniofacial region. Wwp2 is present in cartilage where its expression is controlled by Sox9. Our studies demonstrate that Wwp2 influences craniofacial patterning through its interactions with Goosecoid (Gsc), a paired-like homeobox transcription factor that has an important role in craniofacial development. We show that Wwp2-associated Gsc is a transcriptional activator of the key cartilage regulatory protein Sox6. Wwp2 interacts with Gsc to facilitate its mono-ubiquitylation, a post-translational modification required for optimal transcriptional activation of Gsc. Our results identify for the first time a physiological pathway regulated by Wwp2 in vivo, and also a unique non-proteolytic mechanism through which Wwp2 controls craniofacial development.

MLK3 regulates bone development downstream of the faciogenital dysplasia protein FGD1 in mice

Mutations in human FYVE, RhoGEF, and PH domain-containing 1 (FGD1) cause faciogenital dysplasia (FGDY; also known as Aarskog syndrome), an X-linked disorder that affects multiple skeletal structures. FGD1 encodes a guanine nucleotide exchange factor (GEF) that specifically activates the Rho GTPase CDC42. However, the mechanisms by which mutations in FGD1 affect skeletal development are unknown. Here, we describe what we believe to be a novel signaling pathway in osteoblasts initiated by FGD1 that involves the MAP3K mixed-lineage kinase 3 (MLK3). We observed that MLK3 functions downstream of FGD1 to regulate ERK and p38 MAPK, which in turn phosphorylate and activate the master regulator of osteoblast differentiation, Runx2. Mutations in FGD1 found in individuals with FGDY ablated its ability to activate MLK3. Consistent with our description of this pathway and the phenotype of patients with FGD1 mutations, mice with a targeted deletion of Mlk3 displayed multiple skeletal defects, including dental abnormalities, deficient calvarial mineralization, and reduced bone mass. Furthermore, mice with knockin of a mutant Mlk3 allele that is resistant to activation by FGD1/CDC42 displayed similar skeletal defects, demonstrating that activation of MLK3 specifically by FGD1/CDC42 is important for skeletal mineralization. Thus, our results provide a putative biochemical mechanism for the skeletal defects in human FGDY and suggest that modulating MAPK signaling may benefit these patients.

Dampening of death pathways by schnurri-2 is essential for T-cell development

Generation of a diverse and self-tolerant T-cell repertoire requires appropriate interpretation of T-cell antigen receptor (TCR) signals by CD4+ CD8+ double-positive thymocytes. Thymocyte cell fate is dictated by the nature of TCR–major-histocompatibility-complex (MHC)–peptide interactions, with signals of higher strength leading to death (negative selection) and signals of intermediate strength leading to differentiation (positive selection). Molecules that regulate T-cell development by modulating TCR signal strength have been described but components that specifically define the boundaries between positive and negative selection remain unknown. Here we show in mice that repression of TCR-induced death pathways is critical for proper interpretation of positive selecting signals in vivo, and identify schnurri-2 (Shn2; also known as Hivep2) as a crucial death dampener. Our results indicate that Shn2−/− double-positive thymocytes inappropriately undergo negative selection in response to positive selecting signals, thus leading to disrupted T-cell development. Shn2−/− double-positive thymocytes are more sensitive to TCR-induced death in vitro and die in response to positive selection interactions in vivo. However, Shn2-deficient thymocytes can be positively selected when TCR-induced death is genetically ablated. Shn2 levels increase after TCR stimulation, indicating that integration of multiple TCR–MHC–peptide interactions may fine-tune the death threshold. Mechanistically, Shn2 functions downstream of TCR proximal signalling compenents to dampen Bax activation and the mitochondrial death pathway. Our findings uncover a critical regulator of T-cell development that controls the balance between death and differentiation.

Schnurri-3 regulates ERK downstream of WNT signaling in osteoblasts

Mice deficient in Schnurri-3 (SHN3; also known as HIVEP3) display increased bone formation, but harnessing this observation for therapeutic benefit requires an improved understanding of how SHN3 functions in osteoblasts. Here we identified SHN3 as a dampener of ERK activity that functions in part downstream of WNT signaling in osteoblasts. A D-domain motif within SHN3 mediated the interaction with and inhibition of ERK activity and osteoblast differentiation, and knockin of a mutation in Shn3 that abolishes this interaction resulted in aberrant ERK activation and consequent osteoblast hyperactivity in vivo. Additionally, in vivo genetic interaction studies demonstrated that crossing to Lrp5(-/-) mice partially rescued the osteosclerotic phenotype of Shn3(-/-) mice; mechanistically, this corresponded to the ability of SHN3 to inhibit ERK-mediated suppression of GSK3β. Inducible knockdown of Shn3 in adult mice resulted in a high-bone mass phenotype, providing evidence that transient blockade of these pathways in adults holds promise as a therapy for osteoporosis.

Control of bone resorption in mice by Schnurri-3

Mice lacking the large zinc finger protein Schnurri-3 (Shn3) display increased bone mass, in part, attributable to augmented osteoblastic bone formation. Here, we show that in addition to regulating bone formation, Shn3 indirectly controls bone resorption by osteoclasts in vivo. Although Shn3 plays no cell-intrinsic role in osteoclasts, Shn3-deficient animals show decreased serum markers of bone turnover. Mesenchymal cells lacking Shn3 are defective in promoting osteoclastogenesis in response to selective stimuli, likely attributable to reduced expression of the key osteoclastogenic factor receptor activator of nuclear factor-κB ligand. The bone phenotype of Shn3-deficient mice becomes more pronounced with age, and mice lacking Shn3 are completely resistant to disuse osteopenia, a process that requires functional osteoclasts. Finally, selective deletion of Shn3 in the mesenchymal lineage recapitulates the high bone mass phenotype of global Shn3 KO mice, including reduced osteoclastic bone catabolism in vivo, indicating that Shn3 expression in mesenchymal cells directly controls osteoblastic bone formation and indirectly regulates osteoclastic bone resorption.

Uncoupling of growth plate maturation and bone formation in mice lacking both Schnurri-2 and Schnurri-3

Formation and remodeling of the skeleton relies on precise temporal and spatial regulation of genes expressed in cartilage and bone cells. Debilitating diseases of the skeletal system occur when mutations arise that disrupt these intricate genetic regulatory programs. Here, we report that mice bearing parallel null mutations in the adapter proteins Schnurri2 (Shn2) and Schnurri3 (Shn3) exhibit defects in patterning of the axial skeleton during embryogenesis. Postnatally, these compound mutant mice develop a unique osteochondrodysplasia. The deletion of Shn2 and Shn3 impairs growth plate maturation during endochondral ossification but simultaneously results in massively elevated trabecular bone formation. Hence, growth plate maturation and bone formation can be uncoupled under certain circumstances. These unexpected findings demonstrate that both unique and redundant functions reside in the Schnurri protein family that are required for proper skeletal patterning and remodeling.

Control of Postnatal Bone Mass by the Zinc Finger Adapter Protein Schnurri-3

Abstract:  The completed skeleton undergoes continuous remodeling for the duration of adult life. Rates of bone formation by osteoblasts and bone resorption by osteoclasts determine adult bone mass. Abnormalities in either the osteoblast or osteoclast compartment affect bone mass and result in skeletal disorders, the most common of which is osteoporosis, a state of low bone mass. Much is known about the molecular control of bone formation and resorption from rare single gene disorders resulting in elevated or reduced bone mass. Such genetic disorders can be attributed either to osteoclast deficiencies, collectively termed “osteopetrosis,” or to intrinsically elevated osteoblast activity, termed “osteosclerosis.” However, an increasing need for anabolic therapies to prevent age‐induced bone loss has stimulated a search for additional genes that act at the level of the osteoblast to regulate matrix synthesis. Recently, we have discovered a zinc finger adaptor protein called Schnurri‐3 (Shn3) that potently regulates adult bone mass. Mice that lack Shn3 have normal skeletal morphogenesis but display profoundly elevated bone mass that increases with age. The molecular mechanism was revealed to be the recruitment of WWP1, a Nedd4 family E3 ubiquitin ligase, by Shn3 to the major transcriptional regulator of the osteoblast, Runx2. In the absence of Shn3, Runx2 degradation by WWP1 is inhibited resulting in increased levels of Runx2 protein and enhanced expression of Runx2 target genes leading to increased osteoblast synthetic activity. Small molecules that inhibit Shn3 or WWP1 may be attractive candidates for the treatment of diseases of low bone mass.

Schnurri-3: A Key Regulator of Postnatal Skeletal Remodeling

Schnurri-3, a large zinc finger protein distantly related to Drosophila Shn, is a potent and essential regulator of adult bone formation. Mice lacking Shn3 display an osteosclerotic phenotype with profoundly increased bone mass due to augmented osteoblast activity. Shn3 controls protein levels of Runx2, the principal regulator of osteoblast differentiation, by promoting its degradation. In osteoblasts, Shn3 functions as a component of a trimeric complex between Runx2 and the E3 ubiquitin ligase WWP1. This complex inhibits Runx2 function and expression of genes involved in extracellular matrix mineralization due to the ability of WWP1 to promote Runx2 polyubiquitination and proteasome-dependent degradation. Our study reveals an essential role for Shn3 as a regulator of postnatal bone mass. Compounds designed to block Shn3/WWP1 function may be possible therapeutic agents for the treatment of osteoporosis.