Wnt/beta-catenin signaling in mesenchymal progenitors controls osteoblast and chondrocyte differentiation during vertebrate skeletogenesis.

Chondrocytes and osteoblasts are two primary cell types in the skeletal system that are differentiated from common mesenchymal progenitors. It is believed that osteoblast differentiation is controlled by distinct mechanisms in intramembranous and endochondral ossification. We have found that ectopic canonical Wnt signaling leads to enhanced ossification and suppression of chondrocyte formation. Conversely, genetic inactivation of beta-catenin, an essential component transducing the canonical Wnt signaling, causes ectopic formation of chondrocytes at the expense of osteoblast differentiation during both intramembranous and endochondral ossification. Moreover, inactivation of beta-catenin in mesenchymal progenitor cells in vitro causes chondrocyte differentiation under conditions allowing only osteoblasts to form. Our results demonstrate that beta-catenin is essential in determining whether mesenchymal progenitors will become osteoblasts or chondrocytes regardless of regional locations or ossification mechanisms. Controlling Wnt/beta-catenin signaling is a common molecular mechanism underlying chondrocyte and osteoblast differentiation and specification of intramembranous and endochondral ossification.

Wnt-5a inhibits the canonical Wnt pathway by promoting GSK-3-independent beta-catenin degradation.

Wnts are secreted signaling molecules that can transduce their signals through several different pathways. Wnt-5a is considered a noncanonical Wnt as it does not signal by stabilizing beta-catenin in many biological systems. We have uncovered a new noncanonical pathway through which Wnt-5a antagonizes the canonical Wnt pathway by promoting the degradation of beta-catenin. This pathway is Siah2 and APC dependent, but GSK-3 and beta-TrCP independent. Furthermore, we provide evidence that Wnt-5a also acts in vivo to promote beta-catenin degradation in regulating mammalian limb development and possibly in suppressing tumor formation.

Complete loss of Ndel1 results in neuronal migration defects and early embryonic lethality.

Regulation of cytoplasmic dynein and microtubule dynamics is crucial for both mitotic cell division and neuronal migration. NDEL1 was identified as a protein interacting with LIS1, the protein product of a gene mutated in the lissencephaly. To elucidate NDEL1 function in vivo, we generated null and hypomorphic alleles of Ndel1 in mice by targeted gene disruption. Ndel1(-/-) mice were embryonic lethal at the peri-implantation stage like null mutants of Lis1 and cytoplasmic dynein heavy chain. In addition, Ndel1(-/-) blastocysts failed to grow in culture and exhibited a cell proliferation defect in inner cell mass. Although Ndel1(+/-) mice displayed no obvious phenotypes, further reduction of NDEL1 by making null/hypomorph compound heterozygotes (Ndel1(cko/-)) resulted in histological defects consistent with mild neuronal migration defects. Double Lis1(cko/+)-Ndel1(+/-) mice or Lis1(+/-)-Ndel1(+/-) mice displayed more severe neuronal migration defects than Lis1(cko/+)-Ndel1(+/)(+) mice or Lis1(+/-)-Ndel1(+/+) mice, respectively. We demonstrated distinct abnormalities in microtubule organization and similar defects in the distribution of beta-COP-positive vesicles (to assess dynein function) between Ndel1 or Lis1-null MEFs, as well as similar neuronal migration defects in Ndel1- or Lis1-null granule cells. Rescue of these defects in mouse embryonic fibroblasts and granule cells by overexpressing LIS1, NDEL1, or NDE1 suggest that NDEL1, LIS1, and NDE1 act in a common pathway to regulate dynein but each has distinct roles in the regulation of microtubule organization and neuronal migration.

Of mice and MEN1: Insulinomas in a conditional mouse knockout.

Patients with multiple endocrine neoplasia type 1 (MEN1) develop multiple endocrine tumors, primarily affecting the parathyroid, pituitary, and endocrine pancreas, due to the inactivation of the MEN1 gene. A conditional mouse model was developed to evaluate the loss of the mouse homolog, Men1, in the pancreatic beta cell. Men1 in these mice contains exons 3 to 8 flanked by loxP sites, such that, when the mice are crossed to transgenic mice expressing cre from the rat insulin promoter (RIP-cre), exons 3 to 8 are deleted in beta cells. By 60 weeks of age, >80% of mice homozygous for the floxed Men1 gene and expressing RIP-cre develop multiple pancreatic islet adenomas. The formation of adenomas results in elevated serum insulin levels and decreased blood glucose levels. The delay in tumor appearance, even with early loss of both copies of Men1, implies that additional somatic events are required for adenoma formation in beta cells. Comparative genomic hybridization of beta cell tumor DNA from these mice reveals duplication of chromosome 11, potentially revealing regions of interest with respect to tumorigenesis.

Molecular pathology of the MEN1 gene.

Multiple endocrine neoplasia type 1 (MEN1), among all syndromes, causes tumors in the highest number of tissue types. Most of the tumors are hormone producing (e.g., parathyroid, enteropancreatic endocrine, anterior pituitary) but some are not (e.g., angiofibroma). MEN1 tumors are multiple for organ type, for regions of a discontinuous organ, and for subregions of a continuous organ. Cancer contributes to late mortality; there is no effective prevention or cure for MEN1 cancers. Morbidities are more frequent from benign than malignant tumor, and both are indicators for screening. Onset age is usually earlier in a tumor type of MEN1 than of nonhereditary cases. Broad trends contrast with those in nonneoplastic excess of hormones (e.g., persistent hyperinsulinemic hypoglycemia of infancy). Most germline or somatic mutations in the MEN1 gene predict truncation or absence of encoded menin. Similarly, 11q13 loss of heterozygosity in tumors predicts inactivation of the other MEN1 copy. MEN1 somatic mutation is prevalent in nonhereditary, MEN1-like tumor types. Compiled germline and somatic mutations show almost no genotype/phenotype relation. Normal menin is 67 kDa, widespread, and mainly nuclear. It may partner with junD, NF-kB, PEM, SMAD3, RPA2, FANCD2, NM23beta, nonmuscle myosin heavy chain II-A, GFAP, and/or vimentin. These partners have not clarified menin's pathways in normal or tumor tissues. Animal models have opened approaches to menin pathways. Local overexpression of menin in Drosophila reveals its interaction with the jun-kinase pathway. The Men1+/- mouse has robust MEN1; its most important difference from human MEN1 is marked hyperplasia of pancreatic islets, a tumor precursor stage.

Managing a mouse mutant resource center...this is not your father's transgenic core.

Genetically engineered mice are making an increasingly valuable contribution to biomedical research, and many institutions have begun to assemble dedicated facilities for the development of transgenic animals. The authors describe the structure, function, and management of the transgenic core at NHGRI.

An 11-amino acid beta-hairpin loop in the cytoplasmic domain of band 3 is responsible for ankyrin binding in mouse erythrocytes.

The best-studied cytoskeletal system is the inner surface of the erythrocyte membrane, which provides an erythrocyte with the structural support needed to be stable yet flexible as it passes through the circulation. Current structural models predict that the spectrin-actin-based cytoskeletal network is attached to the plasma membrane through interactions of the protein ankyrin, which binds to both spectrin and the cytoplasmic domain of the transmembrane protein band 3. The crystal structure of the cytoplasmic domain of band 3 predicted that the ankyrin binding site was located on a beta-hairpin loop in the cytoplasmic domain. In vitro, deletion of this loop eliminated ankyrin affinity for band 3 without affecting any other protein-band 3 interaction. To evaluate the importance of the ankyrin-band 3 linkage to membrane properties in vivo, we generated mice with the nucleotides encoding the 11-aa beta-hairpin loop in the mouse Slc4a1 gene replaced with sequence encoding a diglycine bridge. Mice homozygous for the loop deletion were viable with mildly spherocytic and osmotically fragile erythrocytes. In vitro, homozygous ld/ld erythrocytes were incapable of binding ankyrin, but contrary to all previous predictions, abolishing the ankyrin-band 3 linkage destabilized the erythrocyte membrane to a lesser degree than complete deficiencies of either band 3 or ankyrin. Our data indicate that as yet uncharacterized interactions between other membrane proteins must significantly contribute to linkage of the spectrin-actin-based membrane cytoskeleton to the plasma membrane.

Hmgb3 deficiency deregulates proliferation and differentiation of common lymphoid and myeloid progenitors.

Hmgb3 is an X-linked member of a family of chromatin-binding proteins that is expressed in primitive hematopoietic cells capable of long-term hematopoietic repopulation. To examine the role of Hmgb3 in adult hematopoiesis, we generated Hmgb3-deficient (Hmgb3(-/Y)) mice, which are viable but erythrocythemic. Hmgb3(-/Y) mice contain normal numbers of hematopoietic stem cells (HSCs), which generate fewer than normal numbers of common lymphoid progenitors (CLPs) and common myeloid progenitors (CMPs) and greater than normal numbers of more mature progenitors. Although fewer Hmgb3(-/Y) primitive progenitor cells are in the G2/M cell cycle phase, bromodeoxyuridine (BrdU) incorporation demonstrated enhanced proliferation compared with their wild-type counterparts. Hmgb3(-/Y) HSCs have increased levels of Gata-2 and c-myb mRNA. We propose that Hmgb3 deficiency leads to a failure of HSCs to expand into normal numbers of CLPs and CMPs. This defect is compensated for by the ability of Hmgb3(-/Y) progenitors to expand rapidly and differentiate into normal numbers of hematopoietic cells.

A dinucleotide deletion in the ankyrin promoter alters gene expression, transcription initiation and TFIID complex formation in hereditary spherocytosis.

Ankyrin defects are the most common cause of hereditary spherocytosis (HS). In some HS patients, mutations in the ankyrin promoter have been hypothesized to lead to decreased ankyrin mRNA synthesis. The ankyrin erythroid promoter is a member of the most common class of mammalian promoters which lack conserved TATA, initiator or other promoter cis elements and have high G+C content, functional Sp1 binding sites and multiple transcription initiation sites. We identified a novel ankyrin gene promoter mutation, a TG deletion adjacent to a transcription initiation site, in a patient with ankyrin-linked HS and analyzed its effects on ankyrin expression. In vitro, the mutant promoter directed decreased levels of gene expression, altered transcription initiation site utilization and exhibited defective binding of TATA-binding protein (TBP) and TFIID complex formation. In a transgenic mouse model, the mutant ankyrin promoter led to abnormalities in gene expression, including decreased expression of a reporter gene and altered transcription initiation site utilization. These data indicate that the mutation alters ankyrin gene transcription and contributes to the HS phenotype by decreasing ankyrin gene synthesis via disruption of TFIID complex interactions with the ankyrin core promoter. These studies support the model that in promoters that lack conserved cis elements, the TFIID complex directs preinitiation complex formation at specific sites in core promoter DNA and provide the first evidence that disruption of TBP binding and TFIID complex formation in this type of promoter leads to alterations in start site utilization, decreased gene expression and a disease phenotype in vivo.

Runx1 deficiency predisposes mice to T-lymphoblastic lymphoma.

Chromosomal rearrangements affecting RUNX1 and CBFB are common in acute leukemias. These mutations result in the expression of fusion proteins that act dominant-negatively to suppress the normal function of the Runt-related transcription factor 1 (RUNX)/core binding factor beta (CBFbeta) complexes. In addition, loss-of-function mutations in Runt-related transcription factor 1 (RUNX1) have been identified in sporadic cases of acute myeloid leukemia (AML) and in association with the familial platelet disorder with propensity to develop AML (FPD/AML). In order to examine the hypothesis that decreased gene dosage of RUNX1 may be a critical event in the development of leukemia, we treated chimeric mice generated from Runx1(lacZ/lacZ) embryonic stem (ES) cells that have homozygous disruption of the Runx1 gene with N-ethyl-N-nitrosourea (ENU). We observed an increased incidence of T-lymphoblastic lymphoma in Runx1(lacZ/lacZ) compared with wild-type chimeras and confirmed that the tumors were of ES-cell origin. Our results therefore suggest that deficiency of Runx1 can indeed predispose mice to hematopoietic malignancies.

Wnt/beta-catenin signaling is sufficient and necessary for synovial joint formation.

A critical step in skeletal morphogenesis is the formation of synovial joints, which define the relative size of discrete skeletal elements and are required for the mobility of vertebrates. We have found that several Wnt genes, including Wnt4, Wnt14, and Wnt16, were expressed in overlapping and complementary patterns in the developing synovial joints, where beta-catenin protein levels and transcription activity were up-regulated. Removal of beta-catenin early in mesenchymal progenitor cells promoted chondrocyte differentiation and blocked the activity of Wnt14 in joint formation. Ectopic expression of an activated form of beta-catenin or Wnt14 in early differentiating chondrocytes induced ectopic joint formation both morphologically and molecularly. In contrast, genetic removal of beta-catenin in chondrocytes led to joint fusion. These results demonstrate that the Wnt/beta-catenin signaling pathway is necessary and sufficient to induce early steps of synovial joint formation. Wnt4, Wnt14, and Wnt16 may play redundant roles in synovial joint induction by signaling through the beta-catenin-mediated canonical Wnt pathway.

Improved generation of C57BL/6J mouse embryonic stem cells in a defined serum-free media.

C57BL/6 is a well-characterized mouse strain that is used extensively for immunological and neurological research. The establishment of C57BL/6 ES cell lines has facilitated the study of gene-altered mice in a pure genetic background-however, relatively few such lines exist. Using a defined media supplement, knockout serum replacement (KSR) with knockout DMEM (KSR-KDMEM), we find that we can readily establish ES cell lines from blastocysts of C57BL/6J mice. Six lines were established, all of which were karyotypically normal and could be maintained in the undifferentiated state on mouse embryonic fibroblast (MEF) feeders. One line was further tested and found to be karyotypically stable and germline competent, both prior to manipulation and after gene targeting. For this cell line, efficiencies of cell cloning and chimera generation were greater when maintained in KSR-KDMEM. Our work suggests that the use of defined serum-free media may facilitate the generation of ES cells from inbred mouse strains.

Hmgb3: an HMG-box family member expressed in primitive hematopoietic cells that inhibits myeloid and B-cell differentiation.

Hmgb3 is a member of a family of chromatin-binding proteins that can alter DNA structure to facilitate transcription factor binding. We identified the Hmgb3 cDNA in a subtractive hybridization screen for transcripts that are preferentially expressed in hematopoietic stem cells. We inserted an internal ribosomal entry site-green fluorescence protein cassette into the 3' untranslated region of the X-linked Hmgb3 locus to identify Hmgb3-expressing cells. In adult mice, Hmgb3 mRNA is detected in bone marrow cells, primitive Lin-, c-kit+, Sca-1+, IL-7Ralpha- cells, and Ter119+ erythroid cells. We observed that long-term repopulating ability is entirely contained in the subpopulation of Lin-, c-kitHI cells that express Hmgb3. Most common lymphoid and myeloid progenitors express Hmgb3. Introduction of a retrovirus containing the Hmgb3 cDNA into mouse bone marrow stem cells demonstrated that enforced expression of Hmgb3 inhibited B-cell and myeloid differentiation. We conclude that down-regulation of Hmgb3 protein levels is an important step for myeloid and B-cell differentiation.