Isolation, characterization, and mapping of the mouse and human WDR8 genes, members of a novel WD-repeat gene family

The Trp-Asp (WD) motif has been shown to exist in a number of proteins. Genes containing repeats of the WD motif compose a large gene family associated with a variety of cellular functions and can be divided into a number of functional subfamilies. By means of the differential display method using ttw, a mouse model for the early stage of ectopic ossification, we have identified a novel mouse gene, Wdr8 (WD repeat domain 8), which contains two WD repeats, together with its human orthologue. The human and mouse WDR8 genes encode 460 and 462 amino acids, respectively, with 89% identity, and are expressed in almost all tissues, including bone and cartilage, and in bone-forming cells, including osteoblasts and chondrocytes. Wdr8 expression in cartilage was differentially displayed by stimuli for ectopic ossification in ttw and was observed strongly only at a transition period from hypertrophic to mineralizing stages in ATDC5, a chondrogenic cell line that exhibits endochondral ossification, suggesting a potential role for Wdr8 in the process of ossification. The WDR8 protein is highly conserved among a variety of species, but is distinctly different from other WD-repeat proteins, indicating that it represents a novel subfamily of the WD-repeat gene family.

Isolation, characterization and mapping of the mouse and human PRG4 (proteoglycan 4) genes

PRG4 (proteoglycan 4) has been identified as megakaryocyte stimulating factor and articular superficial zone protein. PRG4 has characteristic motifs including somatomedin B and hemopexin domains, a chondroitin sulfate-attachment site and mucin-like repeats. During a screen of genes implicated in ectopic ossification, we found a novel mouse gene highly homologous to human and bovine PRG4 genes. Here, we report isolation, characterization and mapping of the gene, Prg4 together with characterization of its human orthologue. Prg4 cDNA was 3,320 bp long, encoding a 1,054 amino-acid protein. Human and mouse PRG4 genes each consisting of 12 exons spanned 18 and 16 kb, respectively. Characteristic motifs were conserved across species; however, the mucin-like repeat regions were highly diverse in length between species with a tendency that larger animals had longer repeats. Expression of human and mouse PRG4 genes was similar and found not only in cartilage, but also in liver, heart, lung, and bone. Expression of the mouse gene increased with progression of ectopic ossification. Multiple tissue-specific splicing variants lacking some of the motifs were found in both human and mouse. Although a specific role in the articular joint has previously been reported, the presence of multi-functional motifs as well as unique expression and alternative splicing patterns suggest that PRG4 functions in several distinctive biological process including regulation of ossification.

Mutation frequencies of EXT1 and EXT2 in 43 Japanese families with hereditary multiple exostoses

Hereditary multiple exostoses (EXT) is an autosomal dominant bone disease characterized by the formation of cartilage-capped prominences. EXT is genetically heterogeneous with at least four chromosomal loci. Among the four loci, the exostosis type 1 gene (EXT1) and type 2 gene (EXT2) have been cloned. Previous studies have shown that disease-type-specific frequency of mutations is different among various ethnic populations. To determine those frequencies in the Japanese, we conducted a large-scale mutation screening on both genes. In 23 of 43 Japanese families examined, we found 21 different mutations, of which 18 are novel. Seventeen (40%) of the 23 families had a mutation in EXT1 and six (14%) had a mutation in EXT2, suggesting that the former mutations are more frequent than the latter in Japanese EXT families. Of the 17 families with EXT1 mutations, 13 had those causing premature termination of the EXT1 protein and four showed missense mutations, whereas five of the six families with EXT2 mutations had those causing premature termination and one showed missense mutation. Interestingly, all four EXT1 missense mutations occurred in an arginine residue at codon 340 (R340) that is known as a critical site for expression of heparan sulfate glycosaminoglycans, suggesting that the region encompassing the arginine residue may play an important role in the function of the EXT1 protein. These results expand our knowledge of the ethnic difference of EXT and the structure-function relationship of the EXT genes.

Spondylar dysplasia in type X collagenopathy

BACKGROUND

The type X collagen gene (COL10A1) is currently known as the disease-causing gene of metaphyseal dysplasia type Schmid (MDS), whereas a mutation of COL10A1 has been reported to cosegregate with a disease phenotype of mild spondylometaphyseal dysplasia (SMD) in a Japanese family.

OBJECTIVE

To elucidate whether or not spondylar dysplasia is common in patients with mutations of COL10A1.

MATERIALS AND METHODS

We re-evaluated the radiological manifestations in six patients with mutations of COL10A1, who had been previously reported as having MDS.

RESULTS

Two of six patients showed mild platyspondyly in infancy and early childhood. In both patients, the spondylar dysplasia tended to normalize with age, but mild alterations of the vertebral bodies persisted, even into late childhood. The other radiological manifestations of both patients were identical to those of MDS.

CONCLUSION

Our observation suggests that mild spondylar dysplasia may not be uncommon in MDS.

Bile acid acyl adenylate: a possible intermediate to produce a protein-bound bile acid

The non-enzymatic production of a protein-bound adduct by the action of the acyl adenylate of bile acids is described. On incubation of deoxycholyl adenylate with substance P in phosphate buffer, peptides covalently bound with one or two molecules of the bile acid were detected. The modified peptides were structurally characterized by time-of-flight mass spectrometry with matrix-assisted laser desorption/ionization (MALDI-TOFMS) in the post-source decay mode, and by liquid chromatography/electrospray ionization MS/MS. The deoxycholic acid was bound on substance P through the amino group at Arg-1 and/or Lys-3. The adenylate of cholic acid also produced the protein-bound bile acid on incubation with lysozyme, and the binding sites of the cholic acid appeared to be the lysine residues at 1, 33, 97 and 116. The results clearly suggest that bile acid adenylates in vivo may act as active intermediates to produce covalently bound bile acid adducts with peptides and proteins by nucleophilic displacement of the 5'-adenylic acid through the free amino groups.

Novel and recurrent EBP mutations in X-linked dominant chondrodysplasia punctata

Chondrodysplasia punctata (CDP) is a heterogeneous group of skeletal dysplasias characterized by stippled epiphyses. A subtype of CDP, X-linked dominant chondrodysplasia punctata (CDPX2), known also as Conradi-Hünermann-Happle syndrome, is a rare skeletal dysplasia characterized by short stature, craniofacial defects, cataracts, ichthyosis, coarse hair, and alopecia. The cause of CDPX2 was unknown until recent identification of mutations in the gene encoding Delta(8),Delta(7) sterol isomerase emopamil-binding protein (EBP). Twelve different EBP mutations have been reported in 14 patients with CDPX2 or unclassified CDP, but with no evidence of correlation between phenotype and nature of the mutation. To characterize additional mutations and investigate possible phenotype-genotype correlation, we sequenced the entire EBP gene in 8 Japanese individuals with CDP; 5 of them presented with a CDPX2 phenotypes. We found EBP mutations in all 5 CDPX2 individuals, but none in non-CDPX2 individuals. Three of these CDPX2 individuals carried novel nonsense mutations in EBPand the other two, separate missense mutations that had been reported also in different ethnic groups. Our results, combined with previous information, suggest all EBP mutations that produce truncated proteins result in typical CDPX2, whereas the phenotypes resulted from missense mutations are not always typical for CDPX2. Patients with nonsense mutations showed abnormal sterol profiles consistent with a defect in Delta(8), Delta(7) sterol isomerase. X-inactivation patterns of the patients showed no skewing, an observation that supports the assumption that inactivation of the EBP gene occurs at random in affected individuals.

Domain-specific mutations in TGFB1 result in Camurati-Engelmann disease

Camurati-Engelmann disease (CED, MIM 131300) is an autosomal dominant, progressive diaphyseal dysplasia characterized by hyperosteosis and sclerosis of the diaphyses of long bones. We recently assigned the CED locus to an interval between D19S422 and D19S606 at chromosome 19q13.1-q13.3, which two other groups confirmed. As the human transforming growth factor-1 gene (TGFB1) is located within this interval, we considered it a candidate gene for CED.

An autosomal dominant posterior polar cataract locus maps to human chromosome 20p12-q12

We assigned the locus for a previously reported new type of autosomal dominant posterior polar cataract (CPP3) to 20p12-q12 by a genome-wide two-point linkage analysis with microsatellite markers. CPP3 is characterized by progressive, disc-shaped, posterior subcapsular opacity. The disease was seen in 10 members of a Japanese family and transmitted in an autosomal dominant fashion through four generations. We obtained a maximum lod score (Zmax) of 3.61 with a recombination fraction (theta) of 0.00 for markers D20S917, D20S885 and D20S874. Haplotype analysis gave the disease gene localization at a 15.7-cM interval between D20S851 and D20S96 loci on chromosome 20p12-q12. Since the BFSP1 that encodes the lens-specific beaded filament structural protein 1 (filensin) has been mapped around the CPP3 region, we performed sequence analysis on its entire coding region. However, no base substitution or deletion was detected in the CPP3 patients. The mapping of the CPP3 locus to 20p12-q12 not only expands our understanding of the genetic heterogeneity in autosomal dominant posterior polar cataracts but also is a clue for the positional cloning of the disease gene.

Mutations in the N-terminal globular domain of the type X collagen gene (COL10A1) in patients with Schmid metaphyseal chondrodysplasia

Schmid metaphyseal chondrodysplasia (SMCD) is a relatively common, heritable osteochondrodysplasia characterized by short-limbed short stature with normal facies, and generalized metaphyseal dysplasias of the long and short tubular bones. Several mutations of the type X collagen gene (COL10A1) have been reported in patients with SMCD, all in the C-terminal globular domain. To address whether mutations in other domains can cause SMCD, we examined the coding region of the COL10A1 gene in DNA samples from six Japanese families affected with SMCD, by direct sequencing. We detected novel mutations in three unrelated SMCD patients; one was a one-base deletion in the C-terminal globular domain and others were de novo missense mutations in the N-terminal globular domain. All three cases revealed a typical clinical phenotype for SMCD. Thus, we have demonstrated that mutations of COL10A1 in regions other than the C-terminal globular domain can cause SMCD, and the results suggest that the N-terminal globular domain also plays an important role in formation of type X collagen.

Fatigue responses of human triceps surae muscles during repetitive maximal isometric contractions

Nine healthy men (22-45 yr) completed 100 repetitive maximal isometric contractions of the ankle plantar flexor muscles in two knee positions of full extension (K0) and flexion at 90 degrees (K90), positions that varied the contribution of the gastrocnemii. Electromyographic activity was recorded from the medial and lateral gastrocnemii and soleus muscles by using surface electrodes. Plantar flexion torque in K0 was greater and decreased more rapidly than in K90. The electromyographic amplitude decreased over time, and there were no significant differences between muscles and knee joint positions. The level of voluntary effort, assessed by a supramaximal electrical stimulation during every 10th contraction, decreased from 96 to 70% (P < 0.05) with no difference between K0 and K90. It was suggested that a decrease in plantar flexion torque was attributable to both central and peripheral fatigue and that greater fatigability in K0 than in K90 would result from a greater contribution and hence more pronounced fatigue of the gastrocnemius muscle. Further support for this possibility was provided from changes in twitch torque.

Nonlinear time-course of lumbar muscle fatigue using recurrence quantifications

Isometric skeletal muscle fatigue is usually assumed to be a linear process based upon the monotonic decrease in spectral frequency of the EMG. Since spectral analysis by fast Fourier transform (FFT) constitutes a linear transformation of the data, the present study was designed to reevaluate the time-course of muscle fatigue with a nonlinear tool, recurrence quantification analysis (RQA). Surface EMG recordings were obtained from the multifidus muscle of 17 human subjects during isometric posture-holding of the upper torso. The process of muscle fatigue was found to be linear for 59% of the subjects by FFT criteria, but nonlinear for 76% by RQA criteria. As a demonstrative control, both slow and fast transients occurring within a nonlinear mathematical process could be accurately depicted by RQA, but not by FFT. It is concluded that assessment of EMG patterns by nonlinear techniques can give insight into the time-course of fatiguing muscles attributed to the summation of several nonlinear and competing processes.

A method for the determination of the hepatic enzyme activity catalyzing bile acid acyl glucuronide formation by high-performance liquid chromatography with pulsed amperometric detection

A method for the determination of the activity of hepatic glucuronyltransferase catalyzing formation of bile acid 24-glucuronides using high-performance liquid chromatography (HPLC) with pulsed amperometric detection (PAD) has been developed. Bile acid 24-glucuronides were simultaneously separated on a semimicrobore column, Capcell Pak C18UG120, using 20 mM ammonium phosphate (pH 6.0)-acetonitrile (27:10 and 16:10) as the mobile phase in the stepwise gradient elution mode. A 1 M potassium hydroxide solution for the hydrolysis of the 24-glucuronides, which liberates the corresponding bile acids and glucuronic acid, was mixed with the mobile phase in a post-column mode, and the resulting eluant was heated at 90 degrees C, the 24-glucuronides being monitored using a pulsed amperometric detector; the limit of detection was 10 ng. The proposed method was applied to the determination of the hepatic enzyme activity catalyzing bile acid 24-glucuronide formation and the result exhibited the efficient 24-glucuronide formation of the monohydroxylated bile acid, lithocholic acid.

A case of Satoyoshi's syndrome

Satoyoshi's syndrome is a rare neurologic disorder characterized by progressive muscle spasms, alopecia, diarrhea, and skeletal abnormalities. We describe a 21-year-old woman with Satoyoshi's syndrome whose skeletal changes were followed for 15 years until after she had reached skeletal maturity. The patient developed slipping of the epiphyses in the proximal humeri and femurs and metaphyseal lesions mimicking metaphyseal chondrodysplasia. These lesions were a consequence of physeal injuries caused by the recurrent muscle spasms.

Intrafamilial phenotypic variability in Engelmann disease (ED): are ED and Ribbing disease the same entity?

We report on clinical and radiologic manifestations in a 3-generation Japanese family with Engelmann disease (ED) or progressive diaphyseal dysplasia. A large variation of phenotype was remarkable among 12 affected family members. Of the 12 patients, 7 had full manifestations of ED, such as bilateral, symmetrical diaphyseal sclerosis of long bones with myopathy and limb pain, whereas the other 5 exhibited only segmental (rhizomelic and/or mesomelic) involvement and asymmetric diaphyseal sclerosis without any clinical symptoms. The phenotype of the latter group of patients resembled Ribbing disease (RD). We propose that ED and RD represent phenotypic variation of the same disorder.

Genetic mapping of the Camurati-Engelmann disease locus to chromosome 19q13.1-q13.3

Camurati-Engelmann disease (CED [MIM 131300]), or progressive diaphyseal dysplasia, is an autosomal dominant sclerosing bone dysplasia characterized by progressive bone formation along the periosteal and endosteal surfaces at the diaphyseal and metaphyseal regions of long bones and cranial hyperostosis, particularly at the skull base. The gene for CED, or its chromosomal localization, has not yet been identified. We performed a genomewide linkage analysis of two unrelated Japanese families with CED, in which a total of 27 members were available for this study; 16 of them were affected with the disease. Two-point linkage analysis revealed a maximum LOD score of 7.41 (recombination fraction.00; penetrance 1.00) for the D19S918 microsatellite marker locus. Haplotype analysis revealed that all the affected individuals shared a common haplotype observed, in each family, between D19S881 and D19S606, at chromosome 19q13.1-q13.3. These findings, together with a genetic distance among the marker loci, indicate that the CED locus can be assigned to a 15.1-cM segment between D19S881 and D19S606.

Sequence analysis of a total of three megabases of DNA in two regions of chromosome 8p

Large-scale sequencing of genomic regions and in silico gene trapping together represent a highly efficient and powerful approach for identifying novel genes. We performed megabase-level sequence analyses of two genomic regions on human chromosome 8p (8p11.2 and 8p22-->p21.3), after covering those segments with sequence-ready contigs composed of 74 cosmids, 14 BACs, and three PAC clones. We determined continuous nucleotide sequences of 1,856,753 bases on 8p11.2 and 1,210,381 bases on 8p22-->p21.3 by combining the shotgun and primer-walking methods. In silico gene trapping identified four novel genes in the 8p11.2 region and, in the 8p22-->p21.3 region, six known genes (PRLTS, PCM1, MTAMR7, HCAT2, HFREP-1 and PHP) and three novel genes. The distribution of Alu and LINE1 repetitive elements and the densities of predicted exons were different in each region, and Alu-rich portions contained more exonic sequences than LINE1-rich areas.

Three cases of pustulotic arthro-osteitis associated with episcleritis

Three cases of pustulotic arthro-osteitis (PAO) associated with episcleritis were described. In each patient, the episcleritis developed more than 10 years after the onset of PAO. These episcleritis were treated with topical corticosteroids. PAO is classified as a member of the seronegative spondylarthritis group of diseases. Though complications of seronegative spondylarthritis include uveitis and episcleritis. PAO associated with episcleritis was not reported. Episcleritis should be considered as a complication of PAO.

Cloning and characterization of human and mouse PROSC (proline synthetase co-transcribed) genes

Large-scale DNA sequencing, coupled with in silico gene trapping, is a robust approach to identifying unknown genes in selected genomic regions. Using this approach we have isolated a novel human gene, PROSC (for proline synthetase co-transcribed [bacterial homolog]), from human chromosome 8p11.2, and its mouse counterpart. The human PROSC gene spanned 17 kb of genomic DNA; its cDNA was 2530 bp long, with 8 exons that included an open reading frame of 825 bp (275 amino acids). The mouse cDNA (Prosc), 1995 bp long, was predicted to encode 274 amino acids. PROSC is ubiquitously expressed in human tissues and has been highly conserved among divergent species from bacteria to mammals, suggesting its important cellular function. The gene product is likely to be a soluble cytoplasmic protein, but its function remains to be determined.

Cloning and characterization of a novel gene (C8orf2), a human representative of a novel gene family with homology to C. elegans C42.C1.9

Large-scale sequencing of selected genomic regions, coupled with in silico gene trapping, is a robust approach to identifying previously unknown genes. In this way we have found a gene (C8orf2) that is highly homologous to C. elegans C42C1.9. C8orf2 was situated on 8p11. 2 between STS markers NIB1979 (proximal) and AFMA295ZD5 (distal), oriented toward the centromere. C8orf2 consisted of 16 exons spanning more than 16.5 kb of genomic DNA, and was expressed ubiquitously in human tissues. The gene encoded 339-and 152-amino acid polypeptides by alternative splicing; the larger variant contained a region extremely rich in charged amino acids, in particular lysine and glutamic acid. C8orf2 also bore sequence homology to the human KE04p gene. Its conservation among highly divergent species suggests that C8orf2 belongs to a novel gene family.

Cloning and characterization of ASH2L and Ash2l, human and mouse homologs of the Drosophila ash2 gene

Drosophila ash2 belongs to the trithorax (trx) gene family. The ash2 product positively regulates expression of homeotic selector genes, and is implicated in early development and formation of various disc patterns in the fruit fly. Through large-scale sequencing of human genomic DNA coupled with in silico gene trapping, we identified a gene (ASH2L) on chromosome 8p11.2 whose predicted product was highly homologous to ash2, characterized it, and identified its mouse counterpart. The human ash2 cDNA is 2368 bp long, encoding 628 amino acids. The 16-exon gene spans more than 34 kb of genomic DNA between STS markers WI-9207 (centromere) and AFMA295ZD5 (telomere) on chromosome 8, with transcription oriented telomere to centromere. The ash2 genes are highly conserved among different species, including C. elegans and yeast. The presence of a conserved bipartite nuclear localization signal and a PHD finger motif in the human ash2 gene suggests that the gene product would function as a transcriptional regulator in humans, as its homologue does in Drosophila.

Spondylo-epi-metaphyseal dysplasia with normal stature: a case followed from infancy to skeletal maturity

Spondylo-epi-metaphyseal dysplasia is a rare skeletal dysplasia showing radiographic abnormalities in the epiphyses and metaphyses of the long and short tubular bones, and in the spine. There are very few reports of a case followed throughout the entire growth period. Here we report the case of a Japanese girl followed from 1 month old to skeletal maturity at 16 years old. She developed progressive kyphoscoliosis at 7 years old, and underwent a surgical correction of the spine at 14 years old. The diagnosis of spondylo-epi-metaphyseal dysplasia was made from examining all the follow-up radiographs showing abnormalities in the spine, long bones and hands involving epiphyses and metaphyses. She had normal stature--a rare finding in this condition.

Cloning of translocation breakpoints associated with Shwachman syndrome and identification of a candidate gene

Shwachman syndrome is an autosomal-recessive disorder characterized by exocrine pancreatic insufficiency, bone-marrow dysfunction, and metaphyseal chondrodysplasia. A de novo balanced translocation was recently documented in a patient with this disease. Toward isolating the gene(s) responsible for Shwachman syndrome, we cloned and sequenced the translocation breakpoints in the DNA of this patient. The nucleotide sequences around the breakpoints contained neither repetitive elements nor motifs reported to be implicated in recombination events, although we did detect gains or losses of oligonucleotides at the translocation junctions. By large-scale genomic sequencing and in silico gene trapping, we identified two novel transcripts in the vicinity of the breakpoints that might represent candidate genes for Shwachman syndrome, one on chromosome 6 and the other on chromosome 12. The gene on chromosome 12 was actually disrupted by the translocation.

Association of the human NPPS gene with ossification of the posterior longitudinal ligament of the spine (OPLL)

OPLL (ossification of the posterior longitudinal ligament of the spine) is a common form of human myelopathy with a prevalence of as much as 4% in a variety of ethnic groups. To clarify the genetic factors that predispose to OPLL, we have studied ttw (tiptoe walking), a mouse model that presents ectopic ossification of the spinal ligaments similar to OPLL and have found that the ttw phenotype is caused by the nonsense mutation of the gene encoding nucleotide pyrophosphatase (NPPS), a membrane-bound glycoprotein thought to produce inorganic pyrophosphate, a major inhibitor of calcification and mineralization. To investigate a possible role of NPPS in the etiology of OPLL, we have examined its genetic variations in OPLL patients. A total of 323 OPLL patients was screened by means of polymerase chain reaction/single-strand conformation polymorphism analysis covering all the exons and their surrounding introns, plus about 1.5-kb of the promoter region. We identified ten nucleotide variations in the NPPS gene; five of the alterations caused amino-acid substitutions, and two of them were found specifically in OPLL patients. Subsequently, we performed an association study using these variations and found a significant association of an allele, viz., a deletion of T at a position 11 nucleotides upstream from the splice acceptor site of intron 20 (IVS20-11delT), with OPLL; the proportion of the individuals having this deletion was significantly higher (P = 0.0029) in OPLL patients than in controls, indicating that those who have this variation may be more susceptible to the abnormal ossification of the spinal ligaments. Thus, our study suggests that NPPS plays an important role in the etiology of human OPLL.

Genomic organization, mapping, and polymorphisms of the gene encoding human cartilage intermediate layer protein (CILP)

The CILP gene encodes a proform of two polypeptides. One of them, cartilage intermediate layer protein (CILP), is a non-collagenous protein recently isolated from human articular cartilage. The other is homologous to a porcine nucleotide pyrophosphohydrolase (NTPPHase) whose enzymatic activity is highest in articular tissue. The investigation reported here revealed that the CILP gene consists of nine exons spanning approximately 15 kb of genomic DNA on chromosome 15q22. We also report six single nucleotide variations in this gene; five of them cause amino acid changes and the most common of them substitutes isoleucine for threonine at codon 395.

Metaphyseal anadysplasia: evidence of genetic heterogeneity

We report on two unrelated children, a girl and a boy, with regressive metaphyseal dysplasia. Both children had bow legs and a transient growth decline in early childhood. Metaphyseal modifications of the long bones in the children were most conspicuous at an early age and then subsided by age 2 to 3 years. The father of the boy may have had the same disorder, because he was shorter than his sibs and showed mild modifications of the vertebral end plates with mild narrowing of the interpediculate distance of the lumbar spine. The evolution of the metaphyseal dysplasia in the children closely resembled that of metaphyseal anadysplasia (MAD), which is X-linked recessive in inheritance. By contrast, the occurrence of an isolated, affected girl and possible father-to-son transmission reported here were consistent with autosomal dominant transmission, suggesting heterogeneity of MAD. Molecular studies of the type X collagen gene in the boy did not demonstrate any disease-causing mutation.