A genome-screen of a large twin cohort reveals linkage for quantitative ultrasound of the calcaneus to 2q33-37 and 4q12-21.

UNLABELLED: A genome-wide screen was performed on a large cohort of dizygous twin pairs to identify regions of the genome that contain QTL for QUS of bone. Suggestive linkage of QUS parameters to 2q33-37 and 4q12-21 highlighted these regions as potentially important for studies of genes that regulate bone. INTRODUCTION: The genetics of osteoporotic fracture is only partly explained by bone mineral density (BMD). Quantitative ultrasound (QUS) of the calcaneus can also be used for independent clinical assessment of osteoporotic fracture risk. Two specific indices are derived from this assessment: broadband ultrasound attenuation (BUA) and velocity of sound (VOS). Both parameters provide information on fracture risk; however, BUA has been studied more extensively and may be favored because it is thought to have a stronger predictive value for osteoporotic fracture and incorporates aspects of trabecular structure and bone quality as well as BMD. Studies of QUS in twins have shown that both derived parameters are under substantial genetic control, independent of BMD. MATERIALS AND METHODS: To identify regions of the genome that contain quantitative trait loci (QTL) for QUS of bone, we performed a genome-wide screen on a large cohort of dizygous twin pairs. Unselected female dizygous twins from 1067 pedigrees from the St Thomas' UK Adult Twin Registry were genome scanned (737 highly polymorphic microsatellite markers). Multipoint linkage analyses provided maximum evidence of linkage for BUA (LOD 2.1-5.1) to 2q33-37. Linkage for VOS (LOD 2.2-3.4) was maximal at 4q12-21. Potential evidence of linkage in the cohort indicated five other possible locations of QTL (LOD > 2.0) relevant to bone density or structure on chromosomes 1, 2, 13, 14, and X. RESULTS AND CONCLUSIONS: This study has identified eight genomic locations with linkage of LOD > 2.0. This data should be of value in assisting researchers to localize genes that regulate bone mass and microstructure. These results should complement genome screens of BMD and bone structure and serve to enable further targeted positional candidate and positional cloning studies to advance our understanding of genetic control of bone quality and risk of fracture.

Comparison of genome screens for two independent cohorts provides replication of suggestive linkage of bone mineral density to 3p21 and 1p36.

Low bone mineral density (BMD) is a major risk factor for osteoporotic fracture. Studies of BMD in families and twins have shown that this trait is under strong genetic control. To identify regions of the genome that contain quantitative trait loci (QTL) for BMD, we performed independent genomewide screens, using two complementary study designs. We analyzed unselected nonidentical twin pairs (1,094 pedigrees) and highly selected, extremely discordant or concordant (EDAC) sib pairs (254 pedigrees). Nonparametric multipoint linkage (NPL) analyses were undertaken for lumbar spine and total-hip BMD in both cohorts and for whole-body BMD in the unselected twin pairs. The maximum evidence of linkage in the unselected twins (spine BMD, LOD 2.7) and the EDAC pedigrees (spine BMD, LOD 2.1) was observed at chromosome 3p21 (76 cM and 69 cM, respectively). These combined data indicate the presence, in this region, of a gene that regulates BMD. Furthermore, evidence of linkage in the twin cohort (whole-body BMD; LOD 2.4) at chromosome 1p36 (17 cM) supports previous findings of suggestive linkage to BMD in the region. Weaker evidence of linkage (LOD 1.0-2.3) in either cohort, but not both, indicates the locality of additional QTLs. These studies validate the use, in linkage analysis, of large cohorts of unselected twins phenotyped for multiple traits, and they highlight the importance of conducting genome scans in replicate populations as a prelude to positional cloning and gene discovery.

Targeted deletion of the tub mouse obesity gene reveals that tubby is a loss-of-function mutation.

The mouse tubby phenotype is characterized by maturity-onset obesity accompanied by retinal and cochlear degeneration. A positional cloning effort to find the gene responsible for this phenotype led to the identification of tub, a member of a novel gene family of unknown function. A splice defect mutation in the 3' end of the tub gene, predicted to disrupt the C terminus of the Tub protein, has been implicated in the genesis of the tubby phenotype. It is not clear, however, whether the Tub mutant protein retains any biological activity, or perhaps has some dominant function, nor is it established that the tubby mutation is itself responsible for all of the observed tubby phenotypes. To address these questions, we generated tub-deficient mice and compared their phenotype to that of tubby mice. Our results demonstrate that tubby is a loss-of-function mutation of the tub gene and that loss of the tub gene is sufficient to give rise to the full spectrum of tubby phenotypes. We also demonstrate that loss of photoreceptors in the retina of tubby and tub-deficient mice occurs by apoptosis. In addition, we show that Tub protein expression is not significantly altered in the ob, db, or melanocortin 4 receptor-deficient mouse model of obesity.

Identification and functional analysis of novel human melanocortin-4 receptor variants.

Inactivation of the melanocortin-4 receptor (MC4-R) by gene-targeting results in mice that develop maturity-onset obesity, hyperinsulinemia, and hyperglycemia. These phenotypes resemble common forms of human obesity, which are late-onset and frequently accompanied by NIDDM. It is not clear whether sequence variation of the MC4-R gene contributes to obesity in humans. Therefore, we examined the human MC4-R gene polymorphism in 190 individuals ascertained on obesity status. Three allelic variants were identified, including two novel ones, Thr112Met and Ile137Thr. To analyze possible functional alterations, the variants were cloned and expressed in vitro and compared with the wild-type receptor. One of the novel variants, Ile137Thr, identified in an extremely obese proband (BMI 57), was found to be severely impaired in ligand binding and signaling, raising the possibility that it may contribute to development of obesity. Furthermore, our results also suggest that sequence polymorphism in the MC4-R coding region is unlikely to be a common cause of obesity in the population studied, given the low frequency of functionally significant mutations.

Homozygosity and physical mapping of the autosomal recessive retinitis pigmentosa locus (RP14) on chromosome 6p21.3.

Retinitis pigmentosa (RP) is a heterogeneous genetic disorder with autosomal dominant, autosomal recessive, and X-linked forms. We previously mapped an additional arRP locus to chromosome 6p21 (RP14) in a single extended kinship from the Dominican Republic. Aided by a second linked RP pedigree from the same region of the Dominican Republic, we have refined the disease locus to a 2-cM region that is homozygous-by-descent in both pedigrees. A complete YAC, and a partial BAC, contig of the RP14 locus was constructed between the markers D6S1560 and D6S291, encompassing approximately 2.1 Mb. The contig contains 12 YACs and 31 BACs and is characterized by 45 markers including 8 microsatellite markers, 6 gene-derived sequences/ESTs obtained from the databases, and 28 new STSs and 4 new ESTs obtained by BLAST search using DNA sequence from the ends of the BAC and YAC inserts. With a STS density of approximately 1 every 20 kilobases, this contig significantly enhances available maps of the region.

TULP1 mutation in two extended Dominican kindreds with autosomal recessive retinitis pigmentosa.

The RP14 autosomal recessive Retinitis pigmentosa (arRP) locus has been mapped to a 2cM region of chromosome 6p21.3. TULP1 (the gene encoding tubby-like protein 1) is a candidate target for the disease mutation because it maps to the RP14 minimum genetic region and because a mutation in the highly homologous mouse tub gene leads to obesity, deafness and early progressive retinal degeneration. Here we report a splice-site mutation (IVS14+1, G-->A) that is homozygous in all affected individuals (N=33) and heterozygous in all obligate carriers (N=50) from two RP14-linked kindreds. The mutation was not observed in 210 unrelated controls. The data indicate that impairment of TULP1 protein function is a rare cause of arRP and that the normal protein plays an essential role in the physiology of the retina.

Limatin (LIMAB1), an actin-binding LIM protein, maps to mouse chromosome 19 and human chromosome 10q25, a region frequently deleted in human cancers.

LIM domains, found in over 60 proteins, play key roles in the regulation of developmental pathways. They were first identified as cysteine-rich motifs found in the three proteins Lin-11, Isl-1, and Mec-3. LIM proteins frequently contain DNA-binding homeodomains, allowing these proteins to activate transcription. LIM domains also function as protein-binding interfaces, mediating specific protein-protein interactions. Limatin is a novel LIM protein that binds to actin filaments via a domain that is homologous to erythrocyte dematin. Here we report the murine and human chromosomal localizations of limatin (LIMAB1). Limatin was mapped to mouse Chromosome 19 by restriction fragment length polymorphism analysis and to human chromosome region 10q25 by fluorescence in situ hybridization. Radiation hybrid mapping placed LIMAB1 in a 37-cR interval between markers D10S554 and D10S2390. Interestingly, 10q25 is a region of frequent loss of heterozygosity in human tumors, thus identifying limatin as a candidate tumor suppressor gene.

Identification and characterization of the mouse obesity gene tubby: a member of a novel gene family.

The mutated gene responsible for the tubby obesity phenotype has been identified by positional cloning. A single base change within a splice donor site results in the incorrect retention of a single intron in the mature tub mRNA transcript. The consequence of this mutation is the substitution of the carboxy-terminal 44 amino acids with 24 intron-encoded amino acids. The normal transcript appears to be abundantly expressed in the hypothalamus, a region of the brain involved in body weight regulation. Variation in the relative abundance of alternative splice products is observed between inbred mouse strains and appears to correlate with an intron length polymorphism. This allele of tub is a candidate for a previously reported diet-induced obesity quantitative trait locus on mouse chromosome 7.

Autosomal dominant distal spinal muscular atrophy in four generations.

Distal spinal muscular atrophy is a rare lower motor neuron disorder that may be difficult to distinguish clinically from type II Charcot-Marie-Tooth disease. We report on clinical and pathologic findings in 13 members of a four-generation extended family with autosomal dominant distal spinal muscular atrophy. The patients developed a slowly progressive lower motor neuron disorder involving mainly the distal lower extremities; onset was from the second to fourth decades. Electromyography and muscle biopsy findings were indicative of motor denervation. Combined silver/cholinesterase/immunocytochemical staining of intramuscular nerve revealed abundant collateral axonal branching in mild disease but marked loss of terminal motor endplate innervation in the more severe state, suggesting decreased growth of motor axon collaterals with disease progression. Multipoint DNA linkage analysis showed that this family's disorder is not linked to the chromosome 5q11.2-13.3 spinal muscular atrophy locus.

Linkage disequilibrium and haplotype analysis among Polish families with spinal muscular atrophy.

Spinal Muscular Atrophy (SMA) is an inherited degenerative disorder of anterior horn cells that results in progressive muscle weakness and atrophy. The autosomal recessive forms of childhood-onset SMA have been mapped to chromosome 5q11.2-13.3, in a number of studies examining different populations. A total of 9 simple sequence repeat markers were genotyped against 32 Polish families with SMA. The markers span an approximately 0.7 cM region defined by the SMA flanking markers D5S435 and MAP1B. Significant linkage disequilibrium (corrected P < .05) was detected at four of these markers, with D/Dmax values of < or = .89. Extended haplotype analysis revealed a predominant haplotype associated with SMA. The apparently high mutation rate of some of the markers has resulted in a number of haplotypes that vary slightly from this predominant haplotype. The predominant haplotype and these closely related patterns represent 25% of the disease chromosomes and none of the nontransmitted parental chromosomes. This predominant haplotype is present both in patients with acute (type I) and in chronic (types II and III) forms of SMA and occurs twice in a homozygous state, both times in children with chronic SMA.

Refinement of the spinal muscular atrophy locus by genetic and physical mapping.

We report the mapping and characterization of 12 microsatellite markers including 11 novel markers. All markers were generated from overlapping YAC clones that span the spinal muscular atrophy (SMA) locus. PCR amplification of 32 overlapping YAC clones shows that 9 of the new markers (those set in italics) map to the interval between the two previous closest flanking markers (D5S629 and D5S557): cen-D5S6-D5S125-D5S435-D5S1407- D5S629-D5S1410-D5S1411/D5S1412-D5S1413- D5S1414-D5Z8-D5Z9-CATT1-D5Z10/D5Z6- D5S557-D5S1408-D5S1409-D5S637-D5S351-MA P1B-tel. Four of these new markers detect multiple loci in and out of the SMA gene region. Genetic analysis of recombinant SMA families indicates that D5S1413 is a new proximal flanking locus for the SMA gene. Interestingly, among the 40 physically mapped loci, the 14 multilocus markers map contiguously to a genomic region that overlaps, and perhaps helps define, the minimum genetic region encompassing the SMA gene(s).

Assessment of nonallelic genetic heterogeneity of chronic (type II and III) spinal muscular atrophy.

We have previously reported the mapping of the chronic (type II/intermediate and type III/mild/Kugelberg-Welander) form of the childhood-onset spinal muscular atrophies (SMA) to chromosome 5q11.2-13.3, with evidence for nonallelic genetic heterogeneity within a small sample of seven families [Brzustowicz et al., Nature 1990;344:540-541]. We now report the results of linkage analysis and heterogeneity testing on a set of 38 families with chronic SMA. Significant evidence for nonallelic heterogeneity was detected among these families, with the predominant locus for chronic SMA mapping to a 0.51-cM region on 5q, between the loci D5S6 and MAP1B. The estimated proportion of linked families, alpha, was 0.91, with a 2.3-unit support interval of 0.75 to 0.98. The indication that some families diagnosed with chronic SMA are not linked to chromosome 5q must be considered in strategies to map the SMA locus. The relevance of these findings to acute SMA (SMA type I, severe, Werdnig-Hoffmann disease) is still unknown.

High resolution physical map of the region surrounding the spinal muscular atrophy gene.

Spinal muscular atrophy (SMA) is the second most common lethal, autosomal recessive disease in Caucasians, second only to cystic fibrosis. In an effort to identify the causative gene in SMA, we have used radiation hybrid (RH) mapping to prepare a high resolution physical map of the proximal region of chromosome 5 (5q11-13) which contains the SMA gene. The map of the SMA region, which spans approximately 4 Mb, contains 19 loci including 9 polymorphic DNA markers, 8 monomorphic sequence tagged sites (STS) and two genes. Based upon the RH map the two polymorphic loci which most closely flank the SMA locus were estimated to be separated by approximately 750 kb. Using two different directional cloning schemes, several new clones between the genetic markers which most closely flank SMA were isolated. These new clones within the SMA candidate region, together with cosmid clones prepared from one RH hybrid which retains an approximately 1 Mb segment spanning the SMA region as its only human DNA, will greatly facilitate efforts to identify the gene for SMA. In addition, analysis of cloned DNA segments from within the SMA candidate region has identified the presence of a novel, chromosome 5-specific, low copy repeated sequence which is distributed throughout the region containing the SMA gene as well as in at least four other regions of chromosome 5. Whether or not these novel repeated sequences throughout the SMA region are involved in the disease remains to be determined.

Construction of a yeast artificial chromosome contig spanning the spinal muscular atrophy disease gene region.

The childhood spinal muscular atrophies (SMAs) are the most common, serious neuromuscular disorders of childhood second to Duchenne muscular dystrophy. A single locus for these disorders has been mapped by recombination events to a region of 0.7 centimorgan (range, 0.1-2.1 centimorgans) between loci D5S435 and MAP1B on chromosome 5q11.2-13.3. By using PCR amplification to screen yeast artificial chromosome (YAC) DNA pools and the PCR-vectorette method to amplify YAC ends, a YAC contig was constructed across the disease gene region. Nine walk steps identified 32 YACs, including a minimum of seven overlapping YAC clones (average size, 460 kb) that span the SMA region. The contig is characterized by a collection of 30 YAC-end sequence tag sites together with seven genetic markers. The entire YAC contig spans a minimum of 3.2 Mb; the SMA locus is confined to roughly half of this region. Microsatellite markers generated along the YAC contig segregate with the SMA locus in all families where the flanking markers (D5S435 and MAP1B) recombine. Construction of a YAC contig across the disease gene region is an essential step in isolation of the SMA-encoding gene.

Refinement of the spinal muscular atrophy locus to the interval between D5S435 and MAP1B.

The childhood-onset SMA locus has been mapped to chromosome 5q13, in a region bounded by the proximal locus, D5S6, and the closely linked distal loci, D5S112 and MAP1B. We now describe a highly polymorphic, tightly linked microsatellite marker (D5S435) that is very likely the closest proximal marker to the SMA locus. Multipoint linkage analysis firmly establishes the following order of markers at 5q13: centromere-D5S76-D5S6-D5S435-MAP1B/D5S112- D5S39-telomere. The data indicate that SMA resides in an approximately 0.7-cM (range 0.1-2.1) region between D5S435 and MAP1B. This finding reduces by approximately fourfold the genetic region that most likely harbors the SMA locus and will facilitate the physical mapping and cloning of the disease gene region.

Fine-mapping of the spinal muscular atrophy locus to a region flanked by MAP1B and D5S6.

The microtubule-associated protein 1B (MAP1B) locus has been mapped in close proximity to spinal muscular atrophy (SMA) on chromosome 5q13. We have identified a second microsatellite within a MAP1B intron, which increases the heterozygosity of this locus to 94%. Two unambiguous recombination events establish MAP1B as a closely linked, distal flanking marker for the disease locus, while a third recombinant establishes D5S6 as the proximal flanking marker. The combination of key recombinants and linkage analysis place the SMA gene in an approximately 2-cM interval between loci D5S6 and MAP1B. Physical mapping and cloning locate MAP1B within 250 kb of locus D5S112. The identification and characterization of a highly polymorphic gene locus tightly linked to SMA will facilitate isolation of the disease gene, evaluation of heterogeneity, and development of a prenatal test for SMA.

Spinal muscular atrophy is not the result of mutations at the beta-hexosaminidase or GM2-activator locus.

The disease locus for the clinically heterogeneous childhood spinal muscular atrophies (SMA) maps to the chromosome 5 subregion, 5q11.2-13.3. The beta-subunit of beta-D-N-acetylhexosaminidase (hexosaminidase) (EC 3.2.1.52) (Hex B) maps to the same region, and the protein required for substrate recognition by this enzyme, GM2-activator protein, likewise maps to chromosome 5. We have investigated the possibility of allelic variation among some forms of SMA and hexosaminidase deficiency. Recombination between the Hex B and SMA loci eliminates this enzyme as a candidate site for defects causing the illness. Furthermore, we show that, despite previous evidence to the contrary, the GM2-activator locus does not map to chromosome 5, thereby eliminating it as a candidate gene for SMA.

Mapping of human microtubule-associated protein 1B in proximity to the spinal muscular atrophy locus at 5q13.

A polyclonal antiserum directed against the C-terminal domain of dystrophin was used to isolate a cDNA clone encoding an antigenically cross-reactive protein, microtubule-associated protein 1B (MAP-1B). Physical mapping of the human MAP-1B locus places its chromosomal location at 5q13, in proximity to the spinal muscular atrophy (SMA) locus. SMA is a degenerative disorder primarily affecting motor neurons. Genetic linkage analysis of SMA families using a human dinucleotide repeat polymorphism just 3' of the MAP-1B gene has shown tight linkage to SMA mutations. These mapping data together with the postulated role of MAP-1B in neuronal morphogenesis and its localization in anterior horn motor neurons suggest a possible association with SMA.