A genetic linkage map of 27 markers on human chromosome 21

Down syndrome and the enteric nervous system

Down syndrome (DS) is the most common chromosomal abnormality occurring in humans. Up to 77% of DS children have associated gastrointestinal (GI) abnormalities, which may be structural or functional in nature. Functional disturbances may, in turn, affect the outcome of corrective surgical procedures, prompting to caution. It is becoming clear that the processes affecting the enteric nervous system (ENS) in DS not only affect the micro-anatomy but also nerve function, and there is some histological evidence of ENS variations in both human and DS animal models. This suggests that developmental disorders of the ENS are probably fundamental to the functional GI disturbances encountered in patients with DS. The anomalous brain development, function and resulting intellectual impairment associated with DS appears to result from the genetic imbalance created by the trisomy of chromosome 21. The possible links between the brain, GI and ENS involvement are not as yet entirely clear. Neurotropic factors affecting brain development during embryogenesis are probably interlinked with ENS development, but the precise mechanism of how this occurs has yet to be established. This study explores what is known about the ENS dysfunction in DS and reviews the possible importance of chromosome 21 located and other genes in its etiology. Functional motor disturbances of the esophagus and colon are not uncommon and may be congenital or acquired in nature. The most prominent of these include esophageal dysmotility syndromes (e.g. achalasia, gastroesophageal reflux, dysphagia) as well as a higher incidence of chronic constipation and Hirschsprung's disease (HSCR) (2-15%) occurring in association with DS. Chromosome 21 itself is thought to be the site of a modifier gene for HSCR. Recently identified candidate genetic mechanisms provide unique insights into the genetic background of the neurological and cognitive disorders associated with DS. Although the role of the triplicated chromosome 21 and genetic dosage remain important, the additional role of other chromosome 21 genes in the etiology of ENS developmental anomalies remains undetermined and requires ongoing research.

Margareta Mikkelsen

Margareta Mikkelsen, a well-known Danish cytogeneticist, started to research autosome aberrations in 1959 and built the first chromosome laboratory at the University of Copenhagen with Anders Frøland. In 1968, she developed a fully functional chromosome laboratory from scratch at the John F. Kennedy Institute (JFKI). Not only the laboratory performed diagnoses all over Denmark, but also it is a sole place among all the departments of human genetics to train Danes to be clinical geneticists. A generation of Danish geneticists grew up under Dr. Mikkelsen's wing. Dr. Mikkelsen played a pioneering role in research on Down syndrome (DS) and exploring the source of the extra chromosome 21 remains her main interest. She performed the first case of prenatal diagnosis by amniocentesis in Denmark and since then, she was active in this field. The JFKI also committed to research on the fragile X syndrome. Dr. Mikkelsen took on many public responsibilities in Denmark and in Europe. She was on the board of many Danish scientific organizations and an active member of the European Society of Human Genetics (ESHG). She was efficient in public education with communication in lay language. After her retirement, she was more dynamic in medical ethics. Born as Irmtraud Wieser in Munich, Dr. Mikkelsen walked through the hardship of pre-war Germany, the inferno of the World War II, the trauma brought by her two husbands' alienation, the obstacles in work, and physical ailment to fulfill her unwavering commitment to human genetics.

Patterns of meiotic recombination on the long arm of human chromosome 21

In this study we quantify the features of meiotic recombination on the long arm of human chromosome 21. We constructed a 67. 3-centimorgan (cM) high-resolution, comprehensive, and accurate genetic linkage map of chromosome 21q using 187 highly polymorphic markers covering almost the entire long arm; 46 loci, consisting of mutually recombining marker sets, were ordered with greater than 1000:1 odds and with average interlocus distance of 1.46 cM. These markers were used to accurately identify all exchanges in 186 female and 160 male meioses and to show (1) significant excess of recombination in female versus male meioses, (2) an overall decline in female:male recombination between the centromere and the telomere, (3) greater positive chiasma interference in male than in female meioses, and (4) lack of correlation between exchange frequency and parental age. By comparing the genetic map with the 21q sequence map, we show a general trend of increasing male, but near-constant female, recombination versus physical distance across 21q, explaining the gender-specific recombination effect. The recombination rate varies considerably between genders across 21q but is the greatest (eightfold) in the pericentromeric region, with a rate of approximately 250 kb/cM in females and approximately 2125 kb/cM in males. We used information on the locations of all exchanges to construct an empirical map function that confirms the statistical findings of positive interference. These analyses reveal that occurrence of recombination on 21q is not only gender-specific but also region-specific and that recombination suppression at the centromere is not universal. We also find evidence that male exchange location is highly correlated with gene density.

Hirschsprung's disease: genetic and functional associations of Down's and Waardenburg syndromes

Despite significant advances in understanding the genetic background in Hirschsprung's disease (HD), the majority of cases are believed to be multigenic and multifactorial. Conditions associated with an increased risk of HD suggest some common inherited factor and include Down's syndrome, Waardenburg syndrome (WS), dominant sensorineural deafness, neurofibromatosis, neuroblastoma, phaechromocytoma, the MEN type 2B syndrome, and other abnormalities. The reported incidence of Down's syndrome in HD is approximately 2%, but the range varies from 2% to 15%. WS, on the other hand, is one of a number of uncommon human conditions in which pigmentary disturbances are associated with sensorineural deafness. HD mutations have been mapped to a number of genes, i.e., RET proto-oncogene, at 10q11.2; the recessive EDNRB gene, located at 13q22; its ligand endothelin 3 (EDN3); and the glial cell line-derived neurotrophic factor (GDNF) in humans. Mutations of known genes appear to account for only a relatively small number of HD cases (20% in the case of RET). GDNF may modulate the disease phenotype by interacting with other susceptibility loci (e.g., RET). The genetic aspects of HD occurring in association with trisomy 21 and WS are reviewed. Clinical presentation, diagnosis, treatment and long-term outcome in this patient group are evaluated. Additional data are presented on 12 children with Down's syndrome out of 408 surgically treated HD patients. The role of associated anomalies is evaluated, and an increased susceptibility to severe enterocolitis associated with a high mortality rate is reported. Surgical correction can be achieved, but patients may require some form of ongoing help to facilitate acceptable bowel function. The decision as to the nature and timing of the surgical correction must be individualized.

Allelic heterogeneity of Mediterranean myoclonus and the cystatin B gene

Mediterranean myoclonus is a progressive myoclonus epilepsy with autosomal recessive inheritance. Another form has been described in Finland, the so-called Baltic myoclonus. Mediterranean myoclonus and Baltic myoclonus are also known as Unverricht-Lundborg disease. Linkage analyses have shown that the genes for both these forms of myoclonus are closely linked to 21q22.3 DNA markers, suggesting that they are caused by mutations at the same locus (EPM1). Recently, two heterozygous mutations were found in the cystatin B gene in patients with Unverricht-Lundborg disease. We report recombinational and linkage disequilibrium mapping of EPM1, and cystatin B gene sequencing, in 14 consanguineous pedigrees with Mediterranean myoclonus. Linkage to 21q22.3 DNA markers was observed in all these families. Haplotype analysis suggests that a common mutation segregates within these pedigrees, and that this mutation is different from the common one responsible for the Finnish form of Unverricht-Lundborg disease. No mutation was found in the exons or splice junctions of the cystatin B gene in the 14 pedigrees.

Random-breakage mapping method applied to human DNA sequences

The random-breakage mapping method [Game et al. (1990) Nucleic Acids Res., 18, 4453-4461] was applied to DNA sequences in human fibroblasts. The methodology involves NotI restriction endonuclease digestion of DNA from irradiated calls, followed by pulsed-field gel electrophoresis, Southern blotting and hybridization with DNA probes recognizing the single copy sequences of interest. The Southern blots show a band for the unbroken restriction fragments and a smear below this band due to radiation induced random breaks. This smear pattern contains two discontinuities in intensity at positions that correspond to the distance of the hybridization site to each end of the restriction fragment. By analyzing the positions of those discontinuities we confirmed the previously mapped position of the probe DXS1327 within a NotI fragment on the X chromosome, thus demonstrating the validity of the technique. We were also able to position the probes D21S1 and D21S15 with respect to the ends of their corresponding NotI fragments on chromosome 21. A third chromosome 21 probe, D21S11, has previously been reported to be close to D21S1, although an uncertainty about a second possible location existed. Since both probes D21S1 and D21S11 hybridized to a single NotI fragment and yielded a similar smear pattern, this uncertainty is removed by the random-breakage mapping method.

Leukocyte adhesion deficiency mimicking Hirschsprung disease

An infant had clinical signs suggestive of Hirschsprung disease as the initial manifestation of leukocyte adhesion deficiency. Chromosome studies showed a deletion of the distal third of the long arm of one chromosome 21, and flow cytometric studies confirmed the defective expression of CD18.

Directed integration of the physical and genetic linkage maps of swine chromosome 7 reveals that the SLA spans the centromere

The first integrated physical and genetic linkage map encompassing the entire swine chromosome 7 (SSC7) reveals that the porcine MHC (SLA) spans the centromere. A SLA class II antigen gene lies on the q arm, whereas class I and III genes lie on the p arm, suggesting that the presence of a centromere within the SLA does not preclude a functional complex. The SLA appears smaller than other mammalian MHC, as the genetic distance across two class I, three class II, and three class III SLA gene markers is only 1.1 cM. There are significant variations in recombination rates as a function of position along the chromosome, and the SLA lies in the region with the lowest rate. Furthermore, the directed integration approach used in this study was more efficient than previous efforts that emphasized the screening of large insert libraries for random microsatellites.

Clinical features of early onset, familial Alzheimer's disease linked to chromosome 14

Early onset familial Alzheimer's disease (AD) has an autosomal dominant mode of inheritance. Two genes are responsible for the majority of cases of this subtype of AD. Mutations in the beta-amyloid precursor protein (beta APP) gene on chromosome 21 have been shown to completely cosegregate with the disease. We and others have previously described the clinical features of families with beta APP mutations at the codon 717 locus in an attempt to define the phenotype associated with a valine to isoleucine (Val-->Ile) or a valine to glycine (Val-->Gly) change. More recently, a second locus for very early onset disease has been localized to chromosome 14. The results of linkage studies in some families suggesting linkage to both chromosomes have been explained by the suggestion of a second (centromeric) locus on chromosome 21. Here we report the clinical features and genetic analysis of a British pedigree (F74) with early onset AD in which neither the beta APP locus nor any other chromosome 21 locus segregates with the disease, but in which good evidence is seen for linkage on the long arm of chromosome 14. In particular we report marker data suggesting that the chromosome 14 disease locus is close to D14S43 and D14S77. Given the likelihood that F74 represents a chromosome 14 linked family, we describe the clinical features and make a limited clinical comparison with the beta APP717 Val-->Ile and beta APP717 Val-->Gly encoded families that have been previously described.(ABSTRACT TRUNCATED AT 250 WORDS)

Physical structure of human chromosome 21: an analysis of YACs spanning 21q

We have resolved the sizes of the yeast artificial chromosomes (YACs) from an ordered library spanning the entire long arm of Chromosome (Chr) 21 to examine the proximity of sequence-tagged sites (STS) originally used to position these clones. The average insert length was 540 kilobases, and some 18% of the 765 clones have either lost or generated multiple YACs during cultivation. Comparing the sizes of YACs that share common sites allowed the identification of an additional 8% of the clones with large scale additions or deletions. Maximum physical distances between chromosome markers, as established by the co-occurrence of STS on a single YAC, generally agreed with those estimated by other procedures, except for a large region in 21q21. In addition to providing insights into the structure, mapping and organization of this chromosome, knowledge of the sizes and contents of these clones will greatly facilitate the acquisition of any sequence present in this library.

Cu/Zn superoxide dismutase in patients with non-familial Alzheimer's disease

Chromosome 21 contains genes whose altered expression has long been associated with Down's syndrome and whose altered structure with some cases of Alzheimer's disease (AD). The gene for the Cu/Zn superoxide dismutase enzyme (SOD-1), a key enzyme in the metabolism of oxygen free radicals, is located on the distal portion of chromosome 21. Due to the triplication of the SOD-1 gene, patients with Down's syndrome have an almost 50% increase in their SOD activity. On the other hand, almost 25% of the patients with Down's syndrome over 40 years of age develop progressive dementia, with clinical symptoms of AD. Therefore, we decided to evaluate whether abnormalities in the production of free radicals could be detected in blood cells from AD patients, and whether they correlated with molecular variations in the Cu/Zn SOD-1 gene. Superoxide anion production was evaluated spectrophotometrically in suspensions of monocytes from 9 sporadic AD patients, and from 9 aged-matched apparently normal controls. After stimulation with increasing concentrations of n-formyl-methionyl-leucyl-phenylalanine (fMLP) or Ca ionophore A23187, monocyte free radical generation was quantitatively and qualitatively normal. Furthermore, restriction fragment length polymorphism (RFLP) analysis of leukocyte DNA digested with a variety of enzymes, gave comparable results in patients and controls. Our data support the possibility that in addition to the generation of free radicals, other directions should be explored to elucidate the mechanisms of dementia in AD.

Development of a microsatellite genetic map spanning 5q31-q33 and subsequent placement of the LGMD1A locus between D5S178 and IL9

Limb-girdle muscular dystrophy (LGMD) is a genetically and clinically heterogeneous group of disorders. We previously localized an autosomal dominant form of the disorder (LGMD1A) to chromosome 5q22-31 by linkage analysis in a single large pedigree. After developing a microsatellite genetic map incorporating six loci in q31-33 of chromosome 5 and spanning 35 cM, we have refined the original localization. Using multipoint analysis, LGMD1A is localised to a 7 cM region between the markers IL9 and D5S178 with odds > 1000:1.

Proximal deletion of chromosome 21 confirmed by in situ hybridization and molecular studies

Foetal blood sampling was performed at 35 weeks of gestation due to abnormal foetal ultrasound findings. There was apparent monosomy 21 (45,XX,-21) in all mitoses analyzed. The infant died at 37 weeks during delivery. Examination disclosed facial anomalies, clubfeet, hypoplasia of the left urogenital tract, agenesis of corpus callosum, ventricular dilatation, and heterotopias. Reevaluation of the karyotype showed an unbalanced translocation t(1;21) (q44;q22.11) which resulted from a maternal balanced translocation. These findings were confirmed by fluorescence in situ hybridization and molecular studies with chromosome 21 specific markers. The latter showed a proximal deletion of the maternally derived chromosome 21 including all loci from centromere down to the D21S210 locus. This case illustrates the need for complementary cytogenetic and molecular investigations in cases of apparent monosomy 21.

Identification of flanking markers for the familial amyotrophic lateral sclerosis gene ALS1 on chromosome 21

Amyotrophic lateral sclerosis (ALS) is a progressive, adult-onset, neurodegenerative disorder characterized by the death of large motor neurons from the cerebral cortex, brainstem, and spinal cord. The etiology of ALS remains unknown; however, approximately 10% of the cases are familial in nature. In the majority of these families, the mode of transmission is autosomal dominant. Recently, linkage of an autosomal dominant familial ALS (FALS) gene to the locus ALS1 on chromosome 21q was established. In addition, evidence was provided for genetic heterogeneity, with approximately 55% of families most likely linked to chromosome 21. The development of a number of highly informative simple sequence repeat polymorphisms in the region of linkage-21q21 through 21q22.1-has permitted us to confirm both the assignment of ALS1 to 21q and the genetic heterogeneity of FALS. In addition, we have been able to refine the mapping of ALS1, based on recombination events in two of the linked families. Flanking markers for the FALS gene are D21S213 on the centromeric side and D21S219 on the telomeric side. The candidate region is approximately 4 Mb and contains the genes copper/zinc superoxide dismutase (CuZnSOD); the fourth member of the class II cytokine receptor family (CRF2-4); and the interferon-alpha receptor (IFNAR).

A genetic linkage map of the bovine genome

A cattle genetic linkage map was constructed which marks about 90% of the expected length of the cattle genome. Over 200 DNA polymorphisms were genotyped in cattle families which comprise 295 individuals in full sibling pedigrees. One hundred and seventy-one loci were found linked to one other locus. Twenty nine of the 30 chromosome pairs are represented by at least one of the 36 linkage groups. Less than a 50 cM difference was found in the male and female genetic maps. The conserved loci on this map show as many differences in gene order compared to humans as is found between humans and mice. The conservation is consistent with the patterns of karyotypic evolution found in the rodents, primates and artiodactyls. This map will be important for localizing quantitative trait loci and provides a basis for further mapping.

Mapping of the Down syndrome phenotype on chromosome 21 at the molecular level

Phenotypic and molecular analysis of individuals with partial trisomy 21 can be used to determine which regions of chromosome 21 are involved in the pathogenesis of specific features of Down's Syndrome. Using dosage analysis of 27 sequences we defined, at the molecular level, the extent of the chromosome 21 duplication in ten individuals with partial trisomy 21. Phenotype-genotype correlations led to the definition of minimal regions, the duplications of which are linked to the expression of 23 clinical features of Down's Syndrome. The D21S55 region or Down's Syndrome Chromosome Region 1 (DCR1) (1/20 of the long arm), on 21q22.2-21q22.3 proximal, is involved in four cardinal features of the disease: mental retardation, growth retardation, muscular hypotonia and joint hyperlaxity, and in eight of the 18 more common morphological anomalies of the face, hands and feet. Overlapping the DCR1, the D21S55-MX1 region or DCR2 (1/10 of the long arm), spanning 21q21.2 down to the 1/4th proximal part of 21q22.3, is involved in the features defined by the DCR1 plus congenital heart defect and five additional morphological anomalies. Thus, our results indicate that duplication of a relatively small region of chromosome 21 plays a critical role in the pathogenesis of the Down's phenotype.

A genetic map of DNA loci on bovine chromosome 1

We constructed a genetic map of most of the length of bovine chromosome 1 using the CSIRO and the Texas A&M University cattle reference families. Twelve loci are in a single linkage group, 9 of which are highly polymorphic loci. Four loci are of known biochemical function, alpha-1 crystallin (CRYA1), gamma-s crystallin (CRYG8), superoxide dismutase 1 (SOD1), and uridine monophosphate synthase (UMPS), and these have also been previously mapped in humans. The loci CRYA 1, CSRD 1613, GMBT 7, RM 95, SOD1, and UMPS had been previously assigned to bovine syntenic group U10, while CSRD 1613 and UMPS had also been assigned to chromosome 1 by in situ hybridization. All of the loci show statistically significant linkage to at least one other locus. The conserved loci indicate that there have been major rearrangements during the evolution of bovine chromosome 1 compared to other mammalian chromosomes. The estimate of the total length of the linkage group is 168 cM, which accords well with the predicted length based on chiasmata frequencies for the bovine genome and the relative size of chromosome 1 in the bovine genome.

Failure to find linkage between schizophrenia and genetic markers on chromosome 21

We sought evidence for the involvement of mutations in the amyloid precursor protein gene (APP) in the pathogenesis of schizophrenia in two ways. First, linkage analysis was performed in a sample of 24 families multiply affected with schizophrenia. The genotypes were studied for GT12 (D21S210), a highly polymorphic microsatellite marker at the APP locus. Second, we used single strand conformation analysis (SSCA) to screen for mutations in exon 17 of APP in one affected member from each family and in a sample of 44 unrelated patients. In addition, we looked for linkage between schizophrenia and a series of highly polymorphic markers situated at approximately 20cM intervals along the long arm of chromosome 21. We were unable to find evidence for linkage to GT12 or the other markers studied. SSCA did not reveal any mutations in exon 17 of AP. We conclude that mutations within APP are an unlikely cause of schizophrenia. Moreover, this study provides no evidence for a major gene for schizophrenia on chromosome 21, and linkage can be excluded from much of this region under some genetic models.

Isolation and characterization of a DNA fragment containing various kinds of repetitive sequences located on human chromosome 21

In order to investigate the repetitive sequences located on human chromosome 21, we have isolated DNA fragments containing Alu sequences. One of the clones, p1, was chosen for further study, because it contained repetitive sequences different from the Alu sequence. Nucleotide sequence analysis of p1 indicates that p1 contains L1 and O-family sequences. Interestingly, when the L1 sequence was used as a probe, a discrete band of 5 kb was seen in HindIII-digested DNA from somatic cell hybrids containing human chromosome 21 as the sole human chromosome. The L1 sequence was rearranged and was interrupted by O-family sequence, which was flanked by 6 bp target site duplications. Since all three repetitive sequences are known to act as retroposons, these results imply that there is an integration hot spot on human chromosome 21. The sequence was mapped within 21q11-21.

A NotI restriction map of the entire long arm of human chromosome 21

A variety of maps of the human genome have been constructed, including cloned DNA maps. We have isolated 40 of the 42 NotI sites that exist on the long arm of human chromosome 21, as NotI linking clones and constructed a complete NotI restriction map spanning the entire region. This map, which provides the most reliable ordering and distance estimation in the region from a pericentromeric locus to the terminus, demonstrates the usefulness of linking clone mapping for analysing human chromosomes.

Unbalanced translocation, t(18;21), detected by fluorescence in situ hybridization (FISH) in a child with 18q- syndrome and a ring chromosome 21

We report on an 8-year-old girl with minor anomalies consistent with 18q- syndrome and mild developmental delay. Initially cytogenetics showed a terminal deletion of chromosome 21 with mosaicism for a small ring chromosome 21 as the only apparent karyotypic abnormality: mos 45,XX,-21/46,XX,+r(21) (48%/52%). Further studies including FISH and DNA analysis demonstrated a de novo unbalanced translocation of chromosomes 18 and 21 with the likely breakpoints in 18q23 and 21q21.1. Most of 21q was translocated to the distal long arm of one chromosome 18, and this derivative 18 appeared to lack 18q23-qter. The small ring chromosome 21 [r(21)], present in only 52% of the patient's blood lymphocytes, did not appear to be associated with the abnormal phenotype since all 13 chromosome 21 markers that were examined in genomic DNA were present in 2 copies, and the phenotype of the patient was consistent with the 18q- syndrome. The karyotype was reinterpreted as mos 45,XX,-18,-21,+der(18) t(18;21) (q23;q21.1)/46,XX,-18,-21,+der(18) t(18;21) (q23;q21.1), +r(21) (p13q21.1) (48%/52%). These results demonstrate the power of FISH in conjunction with DNA analysis for examination of chromosome rearrangements that may be misclassified by traditional cytogenetic studies alone.

Partial physical map of human chromosome 21 from fibroblast and lymphocyte DNA

A partial physical map of the human chromosome 21 including 26 genes and anonymous sequences was established by pulsed-field gel electrophoresis analysis of restriction fragments obtained from lymphocyte and fibroblast DNAs. The sizes of the restriction fragments obtained by total digestion with eight different enzymes were compared in these two tissues. Differences resulting from the variations in the methylation state of the restriction sites were frequently observed. These differences and partial digestions were used to estimate the order and the distances between genes and sequences. Six linkage groups were defined: D21S13-D21S16, D21S1-D21S11, D21S65-D21S17, (D21S55,ERG)-ETS2, BCEI-D21S19-D21S42-D21S113-CBS-CRYA1, and COL6A2-S100B. For six intergenic distances the resolution of previous maps was significantly increased.

Absence of linkage between chromosome 21 loci and familial amyotrophic lateral sclerosis

Familial amyotrophic lateral sclerosis (FALS) has recently been shown to be linked to chromosome 21 markers in a subset of families. However, we were unable to show linkage between FALS and chromosome 21 markers which flank the putative FALS locus in UK families.

Mitotic errors in somatic cells cause trisomy 21 in about 4.5% of cases and are not associated with advanced maternal age

The study of DNA polymorphisms has permitted the determination of the parental and meiotic origin of the supernumerary chromosome 21 in families with free trisomy 21. Chromosomal segregation errors in somatic cells during mitosis were recognized after analysis of DNA markers in the pericentromeric region and (in order to identify recombination events) along the long arm of chromosome 21. Mitotic errors accounted for about 4.5% (11 of 238) of free trisomy 21 cases examined. The mean maternal age of mitotic errors was 28.5 years and there was no association with advanced maternal age. There was no preference in the parental origin of the duplicated chromosome 21. The 43 maternal meiosis II errors in this study had a mean maternal age of 34.1 years-the highest mean maternal age of all categories of chromosomal segregation errors.

Closure of a genetic linkage map of human chromosome 7q with centromere and telomere polymorphisms

We have constructed a 2.4-cM resolution genetic linkage map for chromosome 7q that is bounded by centromere and telomere polymorphisms and contains 66 loci (88 polymorphic systems), 38 of which are uniquely placed with odds for order of at least 1000:1. Ten genes are included in the map and 11 markers have heterozygosities of at least 70%. This map is the first to incorporate several highly informative markers derived from a telomere YAC clone HTY146 (locus D7S427), including HTY146c3 (HET 92%). The telomere locus markers span at least 200 kb of the 7q terminus and no crossovers within the physical confines of the locus were observed in approximately 240 jointly informative meioses. The sex-equal map length is 158 cM and the largest genetic interval between uniquely localized markers in this map is 11 cM. The female and male map lengths are 181 and 133 cM, respectively. The map is based on the CEPH reference pedigrees and includes over 4000 new genotypes, our previously reported data plus 29 allele systems from the published CEPH version 5 database, and was constructed using the program package CRI-MAP. This genetic linkage map can be considered a baseline map for 7q, and will be useful for defining the extent of chromosome deletions previously reported for breast and prostate cancers, for developing additional genetic maps such as index marker and 1-cM maps, and ultimately for developing a fully integrated genetic and physical map for this chromosome.

Cloning and linkage mapping of three polymorphic tetranucleotide (TAAA)n repeats on human chromosome 21

We report the cloning, sequencing, and mapping of three short sequence repeat polymorphisms due to tetranucleotide (TAAA)n repeats from human chromosome 21. These DNA markers (D21S221, D21S225, D21S226) have been cloned from the chromosome 21-specific plasmid library of J. C. Fuscoe, C. C. Collins, D. Pinkel, and J. W. Gray (1989, Genomics 5: 100-109) and were shown to be polymorphic by polymerase chain reaction amplification and polyacrylamide gel electrophoresis. Genotypes were determined in informative CEPH pedigrees and used in linkage analysis relative to other mapped markers on human chromosome 21. One of these markers, D21S221, is closely linked to the amyloid precursor protein gene (APP), which has been implicated in the etiology of familial Alzheimer disease in some families.

Dinucleotide repeat (GT)n markers on chromosome 21

To further develop the linkage map of human chromosome 21 (HC21), we have concentrated on identifying highly polymorphic markers based on dinucleotide repeat sequences such as (GT)n, as these are often highly polymorphic, are widespread throughout the human genome, and can be rapidly analyzed by the polymerase chain reaction. We report here nine (GT)n polymorphic markers from HC21.

Continuum of overlapping clones spanning the entire human chromosome 21q

A continuous array of overlapping clones covering the entire human chromosome 21q was constructed from human yeast artificial chromosome libraries using sequence-tagged sites as landmarks specifically detected by polymerase chain reaction. The yeast artificial chromosome contiguous unit starts with pericentromeric and ends with subtelomeric loci of 21q. The resulting order of sequence-tagged sites is consistent with other physical and genetic mapping data. This set of overlapping clones will promote our knowledge of the structure of this chromosome and the function of its genes.

Sequence-tagged sites (STSs) for a set of mapped markers on chromosome 21

Sequence tagged sites (STSs) have been proposed as a "common language" for comparing physical and genetic maps of the human genome produced by a variety of techniques. We have produced 44 STSs from 38 mapped loci on human chromosome 21. The STSs represent most of the loci designated as genetic reference or ordered physical framework markers, along with a number of others chosen to span all regions of 21q. Of the STSs, 12 are from gene segments, including 4 from exons of the APP gene encoding the amyloid beta protein precursor, and 32 mark anonymous DNA loci. These STSs make each of the corresponding loci readily accessible to the research community without the need for exchange of clones. These sites also represent multiple start points for the isolation of YAC clones that should permit overlapping the entire chromosome 21 long arm as cloned DNA.

Linkage mapping of the AML1 gene on human chromosome 21 using a DNA polymorphism in the 3' untranslated region

We have detected a polymorphism in the 3' untranslated region of the AML1 gene, which is located at the breakpoint on chromosome 21 in the t(8;21)(q22;q22.3) translocation often associated with patients with acute myeloid leukemia. Informative CEPH families were genotyped for this polymorphism and used to localize the gene on the linkage map of human chromosome 21. The AML1 gene is located between the markers D21S216 and D21S211, in chromosomal band 21q22.3.

Generation of 19 STS markers that can be anchored at specific sites on human chromosome 21

Sequence-tagged sites (STSs) are short stretches of DNA that can be specifically detected by the polymerase chain reaction (PCR) and can be used to construct long-range physical maps of chromosomal DNA. These STSs can be detected by PCR assays developed by reference to data obtained from the sequencing of restriction fragment length polymorphism-DNA markers for chromosome 21, which were derived from recombinant lamba-phage and plasmid clones made from DNA of a human-hamster hybrid cell line. In this report, we describe the generation of 19 new STSs that are specific for human chromosome 21.

D21S215 is a (GT)n polymorphic marker close to centromeric alphoid sequences on chromosome 21

A plasmid, AWZ1, that contained a dinucleotide (GT)n repeat was identified from a chromosome 21-specific genomic library. When amplified by PCR from human genomic DNA, the repeat length was highly polymorphic between individuals; its location, D21S215, was mapped in the CEPH pedigrees by linkage analysis to the pericentromeric region of chromosome 21. It is the closest polymorphic marker to alphoid sequences on this chromosome.

Uniparental isodisomy due to duplication of chromosome 21 occurring in somatic cells monosomic for chromosome 21

Uniparental disomy has been recently recognized as an important phenomenon in non-Mendelian inheritance of human genetic disorders. Several mechanisms for uniparental disomy, i.e., the presence of two homologous chromosomes derived from one parent, have been proposed. We studied two independent cases of abnormalities of chromosome 21 in which there were abnormal karyotypes at birth but blood cells with normal karyotype predominated later in life, and the cells with abnormalities disappeared. Uniparental isodisomy was observed in the normal cells in these individuals. The uniparental disomy in these families was the result of duplication of a chromosome in mitosis after the loss of the homologous abnormal chromosome. The duplication can be seen as mechanism for cell survival and is called here "compensatory" isodisomy, which provided a selective advantage for the cell population with the normal number of chromosomes 21.

Gene-dosage mapping of 30 DNA markers on chromosome 21

Using a slot-blot method for the dosage of single-copy sequences, the copy numbers of 30 chromosome 21 markers were assessed in the blood DNA of 11 patients with partial trisomy or monosomy 21 and in the DNA of a patient-derived human-hamster hybrid cell line carrying a microduplication of chromosome 21. The physical order of these markers on chromosome 21 was thereby determined.

CEPH maps

There are CEPH genetic maps on each homologous human chromosome pair. Genotypes for these maps have been generated in 88 laboratories that receive DNA from a reference panel of large nuclear pedigrees/families supplied by the Centre d'Etude du Polymorphisme Humain. These maps serve as useful tools for the localization of both disease genes and other genes of interest.

Integrating maps of chromosome 21

The past year has seen major progress in the construction of various types of maps of human chromosome 21. Perhaps more significantly, the chromosome 21 research community is making very significant progress on integration of these maps through the use of common resources and increased collaboration and communication.

Linkage mapping of the carbonyl reductase (CBR) gene on human chromosome 21 using a DNA polymorphism in the 3' untranslated region

A DNA polymorphism has been found in the 3' untranslated region of the carbonyl reductase gene (CBR). Genotypes of the members of the CEPH pedigrees have been obtained and used in linkage analysis to map the CBR gene in the linkage map of human chromosome 21. The gene maps between the interferon-alpha receptor (IFNAR) and the D21S55 loci.

Isolation of chromosome 21-specific yeast artificial chromosomes from a total human genome library

A new approach for the isolation of chromosome-specific subsets from a human genomic yeast artificial chromosome (YAC) library is described. It is based on the hybridization with an Alu polymerase chain reaction (PCR) probe. We screened a 1.5 genome equivalent YAC library of megabase insert size with Alu PCR products amplified from hybrid cell lines containing human chromosome 21, and identified a subset of 63 clones representative of this chromosome. The majority of clones were assigned to chromosome 21 by the presence of specific STSs and in situ hybridization. Twenty-nine of 36 STSs that we tested were detected in the subset, and a contig spanning 20 centimorgans in the genetic map and containing 8 STSs in 4 YACs was identified. The proposed approach can greatly speed efforts to construct physical maps of the human genome.

A contiguous Not I restriction map of band q22.3 of human chromosome 21

A contiguous high-resolution NotI restriction map of the distal region of the long arm of human chromosome 21 was constructed by three strategies: linking clones to identify adjacent pieces of DNA, partial digestion to identify neighboring fragments, and cell line polymorphisms to prove identity or adjacency of DNA fragments. Twenty-nine single-copy DNA probes and five linking clone probes were used to determine the order of 30 Not I fragments, covering 10 megabases of DNA in band q22.3. Smaller Not I fragments occur preferentially in this region, suggesting that band q22.3 is unusually rich in genes, since Not I sites occur almost exclusively in CpG islands. Comparison of the physical map and genetic maps in this region reveals a 10-fold higher than average recombination frequency.

Walking, cloning, and mapping with yeast artificial chromosomes: a contig encompassing D21S13 and D21S16

Chromosome 21 has often been used as a model system for the development of genome mapping and cloning strategies in humans. In this report methods for systematic chromosome walking, cloning, and mapping are exemplified in the construction of a 1.5-Mb yeast artificial chromosome (YAC) contig encompassing and extending 400 kb beyond each of the genetic loci D21S13 and D21S16. Isolation of insert-terminal sequences from YACs in this contig provides a set of closely spaced physical markers. These have been used to generate a long-range genomic restriction map.

A genetic linkage map of 41 restriction fragment length polymorphism markers for human chromosome 3

A genetic linkage map for human chromosome 3 has been constructed using 41 polymorphic DNA markers genotyped in 40 CEPH reference families. The map spans a genetic distance of 261 cM in males and 413 cM in females; the ratio of these distances (approximately 1.6 in favor of female meioses) was fairly constant across the map. Frequency of recombination was relatively uniform throughout much of the chromosome, except that in both telomeric regions recombination was more frequent than the physical distances would predict. The genetic map was basically in agreement with physical localization of 24 loci that were mapped by fluorescent in situ hybridization. This map can be used for linkage studies for genetic diseases, and it will serve as a step toward a high-resolution map for human chromosome 3.

Linkage mapping of highly informative DNA polymorphisms within the human interferon-alpha receptor gene on chromosome 21

Two polymorphic loci within the interferon-alpha receptor (IFNAR) gene on human chromosome 21 have been identified and mapped by linkage analysis in 40 CEPH families. These markers are (1) a multiallelic RFLP with an observed heterozygosity of 0.72 and (2) a variable (AT3)n short sequence repeat at the poly(A) tail of an Alu sequence (AluVpA) with an observed heterozygosity of 0.83. This locus is close to D21S58 (theta = 0.02, zeta = 36.76) and D21S17 (theta = 0.02, Zeta = 21.76) with chromosomal band 21q22.1. Multipoint linkage analysis suggests the most likely locus order to be 21cen-D21S58-IFNAR-D21S17-21qter. Given its high heterozygosity, the IFNAR gene can be used as an index marker on human chromosome 21.

Polymorphisms in the transcribed 3' untranslated region of eukaryotic genes

In this review we present preliminary evidence for a new class of polymorphism that may be used in a systematic way to map cDNAs efficiently and to expedite the construction of a high-resolution genetic map of the human genome. Ultimately, transcribed 3' untranslated polymorphisms will warrant further study because they should be widely distributed throughout the genome within transcribed sequences, and they can be readily identified as a result of cDNA cloning and sequencing. Furthermore, these markers should be universally available on the basis of the sequence data and highly useful in linkage analyses.