A cell-based Dkk1 binding assay reveals roles for extracellular domains of LRP5 in Dkk1 interaction and highlights differences between wild-type and the high bone mass mutant LRP5(G171V).

Dkk1 is a secreted antagonist of the LRP5-mediated Wnt signaling pathway that plays a pivotal role in bone biology. Because there are no well-documented LRP5-based assays of Dkk1 binding, we developed a cell-based assay of Dkk1/LRP5 binding using radioactive (125)I-Dkk1. In contrast to LRP6, transfection of LRP5 alone into 293A cells resulted in a low level of specific binding that was unsuitable for routine assay. However, co-transfection of LRP5 with the chaperone protein MesD (which itself does not bind Dkk1) or Kremen-2 (a known Dkk1 receptor), or both, resulted in a marked enhancement of specific binding that was sufficient for evaluation of Dkk1 antagonists. LRP5 fragments comprising the third and fourth beta-propellers plus the ligand binding domain, or the first beta-propeller, each inhibited Dkk1 binding, with mean IC(50)s of 10 and 196 nM, respectively. The extracellular domain of Kremen-2 ("soluble Kremen") was a weaker antagonist (mean IC(50) 806 nM). We also found that cells transfected with a high bone mass mutation LRP5(G171V) had a subtly reduced level of Dkk1 binding, compared to wild type LRP5-transfected cells, and no enhancement of binding by MesD. We conclude that (1) LRP5-transfected cells do not offer a suitable cell-based Dkk1 binding assay, unless co-transfected with either MesD, Kremen-2, or both; (2) soluble fragments of LRP5 containing either the third and fourth beta-propellers plus the ligand binding domain, or the first beta-propeller, antagonize Dkk1 binding; and (3) a high bone mass mutant LRP5(G171V), has subtly reduced Dkk1 binding, and, in contrast to LRP5, no enhancement of binding with MesD.

Structure-based mutation analysis shows the importance of LRP5 beta-propeller 1 in modulating Dkk1-mediated inhibition of Wnt signaling.

A single point mutation (G to T) in the low-density lipoprotein receptor related protein 5 (LRP5) gene results in a glycine to valine amino acid change (G171V) and is responsible for an autosomal dominant high bone mass trait (HBM) in two independent kindreds. LRP5 acts as a co-receptor to Wnts with Frizzled family members and transduces Wnt-canonical signals which can be antagonized by LRP5 ligand, Dickkopf 1 (Dkk1). In the presence of Wnt1, LRP5 or the HBM variant (LRP5-G171V) induces beta-catenin nuclear translocation and activates T cell factor (TCF)-luciferase reporter activity. HBM variant suppresses Dkk1 function and this results in reduced inhibition of TCF activity as compared to that with LRP5. Structural analysis of LRP5 revealed that the HBM mutation lies in the 4th blade of the first beta-propeller domain. To elucidate the functional significance and consequence of the LRP5-G171V mutation in vitro, we took a structure-based approach to design 15 specific LRP5 point mutations. These included (a) substitutions at the G171 in blade 4, (b) mutations in blades 2-6 of beta-propeller 1, and (c) mutations in beta-propellers 2, 3 and 4. Here we show that substitutions of glycine at 171 to K, F, I and Q also resulted in HBM-like activity in the presence of Wnt1 and Dkk1. This indicates the importance of the G171 site rather than the effect of specific amino acid modification to LRP5 receptor function. Interestingly, G171 equivalent residue mutations in other blades of beta-propeller 1 (A65V, S127V, L200V, A214V and M282V) resulted in LRP5-G171V-like block of Dkk1 function. However G171V type mutations in other beta-propellers of LRP5 did not result in resistance to Dkk1 function. These results indicate the importance of LRP5 beta-propeller 1 for Dkk1 function and Wnt signaling. These data and additional comparative structural analysis of the LRP5 family member LDLR suggest a potential functional role of the first beta-propeller domain through intramolecular interaction with other domains of LRP5 wherein Dkk1 can bind. Such studies may also lead to a better understanding of the mechanisms underlying the reduced function of Dkk1-like inhibitory ligands of LRP5 with HBM-like mutations and its relationship to increased bone density phenotypes.

Association of the ADAM33 gene with asthma and bronchial hyperresponsiveness.

Asthma is a common respiratory disorder characterized by recurrent episodes of coughing, wheezing and breathlessness. Although environmental factors such as allergen exposure are risk factors in the development of asthma, both twin and family studies point to a strong genetic component. To date, linkage studies have identified more than a dozen genomic regions linked to asthma. In this study, we performed a genome-wide scan on 460 Caucasian families and identified a locus on chromosome 20p13 that was linked to asthma (log(10) of the likelihood ratio (LOD), 2.94) and bronchial hyperresponsiveness (LOD, 3.93). A survey of 135 polymorphisms in 23 genes identified the ADAM33 gene as being significantly associated with asthma using case-control, transmission disequilibrium and haplotype analyses (P = 0.04 0.000003). ADAM proteins are membrane-anchored metalloproteases with diverse functions, which include the shedding of cell-surface proteins such as cytokines and cytokine receptors. The identification and characterization of ADAM33, a putative asthma susceptibility gene identified by positional cloning in an outbred population, should provide insights into the pathogenesis and natural history of this common disease.

Mapping of the mouse hyh gene to a YAC/BAC contig on proximal Chromosome 7.

Mice that are homozygous for the autosomal recessive hydrocephaly with hop gait (hyh) mutation on Chromosome (Chr) 7 have congenital hydrocephalus characterized by an interhemispheric cyst arising from the third ventricle and agenesis of the corpus callosum. Analysis of more than 500 backcross and intercross progeny maps the hyh locus to proximal Chr 7, approximately 13 cM centromeric to its originally reported map position. Analysis of recombinants at several MIT microsatellite markers localized the hyh locus between D7Mit75 and D7Mit56. Development of several new SSLP markers allowed us to refine the hyh candidate interval to a region defined by the cone-rod homeobox ( Crx) gene proximally and D7Mit56 distally. A contig of yeast artificial chromosome (YAC) clones and bacterial artificial chromosome (BAC) clones spanning this entire region has been developed, and a number of potential candidate genes for hyh within this interval have been identified. Gene content is conserved between this region of mouse Chr 7 and human Chr 19q13.3. Physical mapping of the regions around D7Mit75 and D7Mit56 has also determined the order of a number of MIT markers that remain unresolved on the Mouse Genome Database (MGD) map. Our physical map and transcript map may be useful for positional cloning of genes in this unusually gene-rich region of the genome.

A mutation in the LDL receptor-related protein 5 gene results in the autosomal dominant high-bone-mass trait.

Osteoporosis is a complex disease that affects >10 million people in the United States and results in 1.5 million fractures annually. In addition, the high prevalence of osteopenia (low bone mass) in the general population places a large number of people at risk for developing the disease. In an effort to identify genetic factors influencing bone density, we characterized a family that includes individuals who possess exceptionally dense bones but are otherwise phenotypically normal. This high-bone-mass trait (HBM) was originally localized by linkage analysis to chromosome 11q12-13. We refined the interval by extending the pedigree and genotyping additional markers. A systematic search for mutations that segregated with the HBM phenotype uncovered an amino acid change, in a predicted beta-propeller module of the low-density lipoprotein receptor-related protein 5 (LRP5), that results in the HBM phenotype. During analysis of >1,000 individuals, this mutation was observed only in affected individuals from the HBM kindred. By use of in situ hybridization to rat tibia, expression of LRP5 was detected in areas of bone involved in remodeling. Our findings suggest that the HBM mutation confers a unique osteogenic activity in bone remodeling, and this understanding may facilitate the development of novel therapies for the treatment of osteoporosis.