Sergei A. Kuznetsov

MT1-MMP-Deficient Mice Develop Dwarfism, Osteopenia, Arthritis, and Connective Tissue Disease due to Inadequate Collagen Turnover

MT1-MMP is a membrane-bound matrix metalloproteinase (MT-MMP) capable of mediating pericellular proteolysis of extracellular matrix components. MT1-MMP is therefore thought to be an important molecular tool for cellular remodeling of the surrounding matrix. To establish the biological role of this membrane proteinase we generated MT1-MMP-deficient mice by gene targeting. MT1-MMP deficiency causes craniofacial dysmorphism, arthritis, osteopenia, dwarfism, and fibrosis of soft tissues due to ablation of a collagenolytic activity that is essential for modeling of skeletal and extraskeletal connective tissues. Our findings demonstrate the pivotal function of MT1-MMP in connective tissue metabolism, and illustrate that modeling of the soft connective tissue matrix by resident cells is essential for the development and maintenance of the hard tissues of the skeleton.

Single‐Colony Derived Strains of Human Marrow Stromal Fibroblasts Form Bone After Transplantation In Vivo

Populations of marrow stromal fibroblasts (MSFs) can differentiate into functional osteoblasts and form bone in vivo. It is not known, however, what proportion of MSF precursor cells, colony forming units‐fibroblast (CFU‐Fs), have osteogenic potential. In the present study, analysis of bone formation in vivo by single‐colony derived strains of human marrow stromal fibroblasts (HMSFs) has been performed for the first time. Each strain originated from an individual CFU‐F and underwent four passages in vitro prior to subcutaneous implantation into immunodeficient mice within vehicles containing hydroxyapatite‐tricalcium phosphate ceramic. Multicolony derived HMSF strains were also transplanted to serve as positive controls. After 8 weeks, abundant bone formation was found in the transplants of all multicolony derived HMSF strains, whereas 20 out of 34 (58.8%) single‐colony derived strains from four donors formed bone. Immunostaining with antibody directed against human osteonectin and in situ hybridization for human‐specific alu sequences demonstrated that cells forming new bone were of human origin and were vital for at least 45 weeks post‐transplantation. Both the incidence of bone‐forming colonies and the extent of bone formation by single‐colony derived HMSF strains were increased by cultivation with dexamethasone and ascorbic acid phosphate. Other factors, including type of transplantation vehicle, morphology, size, and structure of the original HMSF colonies showed no obvious correlation with the incidence or extent of bone formation. Hematopoietic tissue within the newly formed bone was developed in the transplants exhibiting exuberant bone formation. These results provide evidence that individual human CFU‐Fs have osteogenic potential and yet differ from each other with respect to their osteogenic capacity.

A Mosaic Activating Mutation in AKT1 Associated with the Proteus Syndrome

BACKGROUND The Proteus syndrome is characterized by the overgrowth of skin, connective tissue, brain, and other tissues. It has been hypothesized that the syndrome is caused by somatic mosaicism for a mutation that is lethal in the nonmosaic state. METHODS We performed exome sequencing of DNA from biopsy samples obtained from patients with the Proteus syndrome and compared the resultant DNA sequences with those of unaffected tissues obtained from the same patients. We confirmed and extended an observed association, using a custom restriction-enzyme assay to analyze the DNA in 158 samples from 29 patients with the Proteus syndrome. We then assayed activation of the AKT protein in affected tissues, using phosphorylation-specific antibodies on Western blots. RESULTS Of 29 patients with the Proteus syndrome, 26 had a somatic activating mutation (c.49G→A, p.Glu17Lys) in the oncogene AKT1, encoding the AKT1 kinase, an enzyme known to mediate processes such as cell proliferation and apoptosis. Tissues and cell lines from patients with the Proteus syndrome harbored admixtures of mutant alleles that ranged from 1% to approximately 50%. Mutant cell lines showed greater AKT phosphorylation than did control cell lines. A pair of single-cell clones that were established from the same starting culture and differed with respect to their mutation status had different levels of AKT phosphorylation. CONCLUSIONS The Proteus syndrome is caused by a somatic activating mutation in AKT1, proving the hypothesis of somatic mosaicism and implicating activation of the PI3K-AKT pathway in the characteristic clinical findings of overgrowth and tumor susceptibility in this disorder. (Funded by the Intramural Research Program of the National Human Genome Research Institute.).

Bone formation in vivo: comparison of osteogenesis by transplanted mouse and human marrow stromal fibroblasts.

BACKGROUND Marrow stromal fibroblasts (MSFs) are known to contain bone precursor cells. However, the osteogenic potential of human MSFs has been poorly characterized. The aim of this study was to compare the osteogenic capacity of mouse and human MSFs after implantation in vivo. METHODS After in vitro expansion, MSFs were loaded into a number of different vehicles and transplanted subcutaneously into immunodeficient mice. RESULTS Mouse MSFs transplanted within gelatin, polyvinyl sponges, and collagen matrices all formed a capsule of cortical-like bone surrounding a cavity with active hematopoiesis. In transplants of MSFs from transgenic mice harboring type I procollagen-chloramphenicol acetyltransferase constructs, chloramphenicol acetyltransferase activity was maintained for up to 14 weeks, indicating prolonged bone formation by transplanted MSFs. New bone formation by human MSFs was more dependent on both the in vitro expansion conditions and transplantation vehicles. Within gelatin, woven bone was observed sporadically and only after culture in the presence of dexamethasone and L-ascorbic acid phosphate magnesium salt n-hydrate. Consistent bone formation by human MSFs was achieved only within vehicles containing hydroxyapatite/tricalcium phosphate ceramics (HA/TCP) in the form of blocks, powder, and HA/TCP powder-type I bovine fibrillar collagen strips, and bone was maintained for at least 19 weeks. Cells of the new bone were positive for human osteonectin showing their donor origin. HA/TCP powder, the HA/TCP powder-type I bovine fibrillar collagen strips, and HA/TCP powder held together with fibrin were easier to load and supported more extensive osteogenesis than HA/TCP blocks and thus may be more applicable for therapeutic use. CONCLUSIONS In this article, we describe the differences in the requirements for mouse and human MSFs to form bone, and report the development of a methodology for the consistent in vivo generation of extensive bone from human MSFs.

Factors required for bone marrow stromal fibroblast colony formation in vitro

Marrow stromal fibroblasts (MSFs) are essential for the formation of the haemopoietic microenvironment and bone; however, regulation of MSF proliferation is poorly understood. MSF colony formation was studied in primary mouse and human marrow cell cultures. After a brief exposure to serum, MSF colony formation occurred in the absence of both serum and non‐adherent marrow cells, if medium conditioned by marrow cells was present (serum‐free conditioned medium, SF‐CM). In mouse and human cultures stimulated to proliferate by SF‐CM, neutralizing antibodies against PDGF, TGF‐β, bFGF and EGF specifically suppressed MSF colony formation. The degree of supression was species‐dependent, with the most profound inhibition achieved in mouse cultures by anti‐PDGF, anti‐bFGF and anti‐EGF, and in human cultures by anti‐PDGF and anti‐TGF‐β. Serum‐free medium not conditioned by marrow cells (SFM) did not support MSF colony formation. In mouse cultures in SFM, human recombinant bFGF and bovine natural bFGF were able to partially substitute for the stimulating effect of SF‐CM. Other growth factors, including TGF‐β1, TGF‐β2, PDGF, EGF, IL‐6, IGF‐I and IGF‐II, showed no activity when tested alone. In human cultures in SFM, none of the growth factors, alone or in combination, stimulated MSF colony formation. Mouse and human MSFs grown in SF‐CM formed bone and a haemopoietic microenvironment when transplantated into immunodeficient mice in vivo, and therefore were functionally equivalent to MSFs generated in the presence of serum. These data indicate that stimulation of the initial proliferation of an MSF precursor cell is complex, and requires participation of at least four growth factors: PDGF, bFGF, TGF‐β and EGF. In addition, mouse and human MSF precursor cells have different requirements for each of the growth factors.

Microtubule- and motor-dependent fusion in vitro between apical and basolateral endocytic vesicles from MDCK cells

The pathways of endocytosis from the apical and the basolateral domains of epithelial MDCK cells are known to converge at the level of late endosomes in vivo. We have now reconstituted the meeting process in a cell-free assay that measures the fusion of apically and basolaterally derived endocytic vesicles with late endosomes. Our results show that this in vitro process requires the presence of polymerized microtubules, as does the convergence of the two pathways in vivo, and also depends on the presence of microtubule binding proteins, in particular the mechanochemical motors kinesin and cytoplasmic dynein.

Repair of craniotomy defects using bone marrow stromal cells.

BACKGROUND Techniques used to repair craniofacial skeletal defects parallel the accepted surgical therapies for bone loss elsewhere in the skeleton and include the use of autogenous bone and alloplastic materials. Transplantation of a bone marrow stromal cell population that contains osteogenic progenitor cells may be an additional modality for the generation of new bone. METHODS Full thickness osseous defects (5 mm) were prepared in the cranium of immunocompromised mice and were treated with gelatin sponges containing murine alloplastic bone marrow stromal cells derived from transgenic mice carrying a type I collagen-chloramphenicol acetyltransferase reporter gene to follow the fate of the transplanted cells. Control surgical sites were treated with spleen stromal cells or gelatin sponges alone, or were left untreated. The surgical defects were analyzed histologically for percent closure of the defect at 2, 3, 4, 6, and 12 weeks. RESULTS Cultured bone marrow stromal cells transplanted within gelatin sponges resulted in osteogenesis that repaired greater than 99.0+/-2.20% of the original surgical defect within 2 weeks. In contrast, cranial defects treated with splenic fibroblasts, vehicle alone, or sham-operated controls resulted in minimal repair that was limited to the surgical margins. Bone marrow stromal cells carrying the collagen transgene were immunodetected only in the newly formed bone and thus confirmed the donor origin of the transplanted cells. CONCLUSIONS These studies demonstrate that mitotically expanded bone marrow cells can serve as an abundant source of osteoprogenitor cells that are capable of repairing craniofacial skeletal defects in mice without the addition of growth or morphogenetic factors.

Bone Marrow Stromal Cells: Characterization and Clinical Application:

The bone marrow stroma consists of a heterogeneous population of cells that provide the structural and physiological support for hematopoietic cells. Additionally, the bone marrow stroma contains cells with a stem-cell-like character that allows them to differentiate into bone, cartilage, adipocytes, and hematopoietic supporting tissues. Several experimental approaches have been used to characterize the development and functional nature of these cells in vivo and their differentiating potential in vitro. In vivo, presumptive osteogenic precursors have been identified by morphologic and immunohistochemical methods. In culture, the stromal cells can be separated from hematopoietic cells by their differential adhesion to tissue culture plastic and their prolonged proliferative potential. In cultures generated from single-cell suspensions of marrow, bone marrow stromal cells grow in colonies, each derived from a single precursor cell termed the colony-forming unit-fibroblast. Culture methods have been developed to expand marrow stromal cells derived from human, mouse, and other species. Under appropriate conditions, these cells are capable of forming new bone after in vivo transplantation. Various methods of cultivation and transplantation conditions have been studied and found to have substantial influence on the transplantation outcome. The finding that bone marrow stromal cells can be manipulated in vitro and subsequently form bone in vivo provides a powerful new model system for studying the basic biology of bone and for generating models for therapeutic strategies aimed at regenerating skeletal elements.

Mutations of the GNAS1 Gene, Stromal Cell Dysfunction, and Osteomalacic Changes in Non–McCune–Albright Fibrous Dysplasia of Bone

Activating missense mutations of the GNAS1 gene, encoding the α subunit of the stimulatory G protein (Gs), have been identified in patients with the McCune–Albright syndrome (MAS; characterized by polyostotic fibrous dysplasia, café au lait skin pigmentation, and endocrine disorders). Because fibrous dysplasia (FD) of bone also commonly occurs outside of the context of typical MAS, we asked whether the same mutations could be identified routinely in non‐MAS FD lesions. We analyzed a series of 8 randomly obtained, consecutive cases of non‐MAS FD and identified R201 mutations in the GNAS1 gene in all of them by sequencing cDNA generated by amplification of genomic DNA using a standard primer set and by using a novel, highly sensitive method that uses a protein nucleic acid (PNA) primer to block amplification of the normal allele. Histologic findings were not distinguishable from those observed in MAS‐related FD and included subtle changes in cell shape and collagen texture putatively ascribed to excess endogenous cyclic adenosine monophosphate (cAMP). Osteomalacic changes (unmineralized osteoid) were prominent in lesional FD bone. In an in vivo transplantation assay, stromal cells isolated from FD failed to recapitulate a normal ossicle; instead, they generated a miniature replica of fibrous dysplasia. These data provide evidence that occurrence of GNAS1 mutations, previously noted in individual cases of FD, is a common and perhaps constant finding in non‐MAS FD. These findings support the view that FD, MAS, and nonskeletal isolated endocrine lesions associated with GNAS1 mutations represent a spectrum of phenotypic expressions (likely reflecting different patterns of somatic mosaicism) of the same basic disorder. We conclude that mechanisms underlying the development of the FD lesions, and hopefully mechanism‐targeted therapeutic approaches to be developed, must also be the same in MAS and non‐MAS FD.

In vivo bone formation by human bone marrow stromal cells: Effect of carrier particle size and shape

Successful closure of bone defects in patients remains an active area of basic and clinical research. A novel and promising approach is the transplantation of human bone marrow stromal cells (BMSCs), which have been shown to possess a significant osteogenic potential. The extent and quality of bone formation by transplanted human BMSCs strongly depends on the carrier matrix with which cells are transplanted; to date, hydroxyapatite/tricalcium phosphate (HA/TCP) supports far more osteogenesis than any other matrix tested. In order to further improve the technique of BMSC transplantation, we studied whether commercially available HA/TCP particles, clinically approved as an osteoconductive material and commercially available as particles measuring 0.5-1.0 mm diameter, is an optimum matrix for promoting bone development by BMSCs. HA/TCP and HA particles of varying size were sieved into a variety of size ranges, from <0.044 mm to 1.0-2.0 mm. Transplants were formed by mixing 40 mg aliquots of particles with cultured passaged human BMSCs. They were placed in subcutaneous pockets in immunocompromised Bg-Nu-XID mice and harvested 4 or 10 weeks later. The transplants were examined histologically; the presence of bone within each transplant was evaluated using histomorphometry or blindly scored on a semiquantitative scale. Transplant morphology and the amount of new bone varied in a consistent fashion based on particle size and shape. Transplants incorporating HA/TCP particles of 0.1-0.25 mm size demonstrated the greatest bone formation at both 4 and 10 weeks; larger or smaller particles were associated with less extensive bone formation, while a size of 0.044 mm represented a threshold below which no bone formation could be observed. Flat-sided HA particles measuring 0.1-0.25 mm formed no bone. The differences in bone formation were not attributable to the differences in cell attachment among the groups. Instead, the size and spatial and structural organization of the particles within BMSC transplants appear to determine the extent of bone formation. These findings provide necessary information for the successful clinical application of BMSC transplantation techniques.