2SNP: scalable phasing based on 2-SNP haplotypes

2SNP software package implements a new very fast scalable algorithm for haplotype inference based on genotype statistics collected only for pairs of SNPs. This software can be used for comparatively accurate phasing of large number of long genome sequences, e.g. obtained from DNA arrays. As an input 2SNP takes genotype matrix and outputs the corresponding haplotype matrix. On datasets across 79 regions from HapMap 2SNP is several orders of magnitude faster than GERBIL and PHASE while matching them in quality measured by the number of correctly phased genotypes, single-site and switching errors. For example, 2SNP requires 41 s on Pentium 4 2 Ghz processor to phase 30 genotypes with 1381 SNPs (ENm010.7p15:2 data from HapMap) versus GERBIL and PHASE requiring more than a week and admitting no less errors than 2SNP.     

Chromosomal localizations by in situ hybridization of the repetitious human DNA families and evidence of their satellite DNA equivalents

Four of the five major repetitious human DNA families, have been mapped by the in situ hybridization technique at their T_OPT values. Two of the lighter density DNA families have autoradiographic grain patterns over heterochromatic chromosomal regions that resemble those of known satellite DNAs. The two heaviest density DNA families have autoradiographic grain patterns of middle repetitious DNAs, with all chromosomes showing labelling. Some evidence suggests that one of these DNA families is concentrated in certain chromosomal regions. Both DNA families exhibit biphasic T_OPT curves. The presence of two thermal stability classes of hybrids suggests sequence interspersion. By co-enrichment studies in Ag⁺-Cs₂SO₄ gradients, evidence suggests the origin of the three lightest density renaturated human DNA families to be satellites I, II and III.     

Chromosomal localization of several families of repetitive sequences by in situ hybridization.

Four recombinant DNA clones (H1, H7, H12, and H15) carrying low-repetitive human DNA were previously isolated from a human genomic library based on their specificity for chromosome 21 and were studied for their distribution as determined by in situ hybridization. Clone H7 hybridized to the satellite regions of chromosomes 13, 14, 15, 21, and 22 as well as to the centromere region of chromosome 1. Clone H12 hybridized strongly to chromosomes 11 and 17 and the centromere of the X. Clones H1 and H15 had a very widespread distribution throughout the genome. Clone H15 hybridized significantly more to the short arm of chromosome 18 than to any other chromosomal segment. Clone H1 hybridized strongly to the centromere of chromosome 19 and also showed random distribution on all the other human chromosomes. We conclude that these probes appear to represent four repetitive families that demonstrate in situ hybridization patterns that do not correspond with those of any other repetitive family. Further, the in situ hybridization patterns do not show the strong chromosome 21 specificity originally defined by Southern blot analysis. The nature and chromosomal localization of these repetitive families should be useful in regional mapping and evolutionary studies and give additional insight into chromosomal organization.     

Chromosomal localization of GABAA receptor subunit genes: relationship to human genetic disease

Hybridization of GABAA receptor probes to human chromosomes in situ and to DNA from sorted human chromosomes has localized the genes encoding a beta subunit and three isoforms of the alpha subunit. The alpha 2 and beta genes are both located on chromosome 4 in bands p12-p13 and may be adjacent. The alpha 1 gene is on chromosome 5 (bands q34-q35) and the alpha 3 gene is on the X chromosome. The alpha 3 locus was mapped also on the mouse X chromosome using genetic break-point analysis in an interspecies pedigree. The combined results locate the human alpha 3 gene within band Xq28, in a location that makes it a candidate gene for the X-linked form of manic depression.     

Geographical distribution of haplotypes in Swedish families with Huntington's disease

This study was planned to determine the number of origins of the mutation underlying Huntington's disease (HD) in Sweden. Haplotypes were constructed for 23 different HD families, using six different polymorphisms [(CCG) _n , GT70, 674, BS1, E2 and 4.2], including two within the gene. In addition, extensive genealogical investigations were performed, and the geographical origin of the haplotypes was studied. Ten different haplotypes were observed suggesting multiple origins for the HD mutation in Sweden. Analysis of the two polymorphic markers within the HD gene (the CCG repeat and GT70) indicates that there are at least three origins for the HD mutation in Sweden. One of these haplotypes (7/A) accounts for 89% of the families, suggesting that the majority of the Swedish HD families are related through a single HD mutation of ancient origin. Furthermore, three of the families that were previously considered to be unrelated could be traced to a common ancestor in the 15th century, a finding that is consistent with this hypothesis.     

Crystal structure of dimeric human ciliary neurotrophic factor determined by MAD phasing.

Ciliary neurotrophic factor (CNTF) promotes the survival and differentiation of developing motor neurons and is a potential therapeutic for treating neurodegeneration and nerve injury. The crystal structure of human CNTF has been determined at 2.4 A resolution using multi-wavelength anomalous diffraction (MAD) phasing from a single Yb3+ ions. The structure reveals that CNTF is dimeric, with a novel anti-parallel arrangement of the subunits, not previously observed for other cytokines. Each subunit adopts a double crossover four-helix bundle fold, in which two helices contribute to the dimer interface, whilst two different helices show pronounced kinks. Analysis of the electrostatic surface of CNTF identified residues within these kinked helices that may contact the CNTF receptor-alpha. Solution experiments show that CNTF dimerizes at concentrations > 40 microM. Such dimers are likely to be relevant to the storage of CNTF in the peripheral nerve given the high concentrations present in this tissue. However, it is unlikely that they play a role in engaging the three distinct receptor subunits that comprise the CNTF receptor, given the low concentration of extracellular CNTF and its high potency.     

Assessment of genetic diversity of accessions in Brassicaceae genetic resources by frequency distribution analysis of S haplotypes

Plant genetic resources are important sources of genetic variation for improving crop varieties as breeding materials. Conservation of such resources of allogamous species requires maintenance of the genetic diversity within each accession to avoid inbreeding depression and loss of rare alleles. For assessment of genetic diversity in the self-incompatibility locus (S locus), which is critically involved in the chance of mating, we developed a dot-blot genotyping method for self-incompatibility (S) haplotypes and applied it to indigenous, miscellaneous landraces of Brassica rapa, provided by the IPK Gene Bank (Gatersleben, Germany) and the Tohoku University Brassica Seed Bank (Sendai, Japan), in which landraces are maintained using different population sizes. This method effectively determined S genotypes of more than 500 individuals from the focal landraces. Although our results suggest that these landraces might possess sufficient numbers of S haplotypes, the strong reduction of frequencies of recessive S haplotypes occurred, probably owing to genetic drift. Based on these results, we herein discuss an appropriate way to conserve genetic diversity of allogamous plant resources in a gene bank.     

Chromosomal damage induced by caprolactam in human lymphocytes

Caprolactam was tested in the in vitro human lymphocyte cytogenetic assay both in the presence and absence of S9 mix at dose levels up to 5500 micrograms/ml using lymphocytes obtained from a male donor and in the presence of S9 mix using lymphocytes obtained from a female donor. Statistically significant increases in chromosomal damage were observed at 5500 micrograms/ml dose level in cells from both donors. This positive response was enhanced by the inclusion of chromosomal gaps in the calculations. It was concluded that caprolactam induces chromosomal damage in human lymphocytes in vitro albeit at comparatively high dose levels.     

The Southwest of Scotland Structural Chromosomal Abnormalities Database: an assessment of its contribution to genetic counselling in affected families

AIM: To assess the effect of establishing a genetic database on the provision of genetic counselling to individuals and families with structural chromosomal abnormalities. METHOD: For the four year period 1997-2000, we compared all cytogenetics laboratory records with entries on the database to determine its completeness. We assessed the extent to which families had been followed up, compared these findings with a previous four year period (1977-1980) and sought to discover why some families were not followed up. RESULTS: Of 215 probands identified during 1997-2000, 19 (9%) were not recorded on the register. Approximately one third of families were followed up completely, one third were partially followed up and one third had had no follow-up, for a variety of reasons. In this last group, there was evidence that some had received inadequate or incorrect genetic advice. There was no evidence that the database improved follow-up in families with structural chromosome abnormalities. Over 20 years, there has been a downward trend in the proportion of cases referred to the genetic clinic. CONCLUSIONS: Our register can be used to monitor trends in clinical practice but has had no direct effect on the service provided to patients and their families.     

Chromosomal instability in incontinentia pigmenti: study of four families

Cytogenetic studies in four patients affected by Incontinentia pigmenti and in their relatives did not show a significant increase of chromatid and chromosome gaps and breaks. This seems to negate a correlation between these findings and the disease. We propose that the responsibility for the chromosomal breakages sometimes observed in this syndrome can be due to external factors that disturb the basal percentage of the lesions.     

A worldwide population study of the Ag-system haplotypes, a genetic polymorphism of human low-density lipoprotein.

The aim of this investigation is to examine the distribution of the Ag immunological polymorphism in human populations on a worldwide scale and to look for possible explanations of this distribution in the field of modern human peopling history and Ag-system evolution. Extensive Ag-antigene typings were carried out on 13 human population samples, including sub-Saharan African, European, west and east Asiatic, Melanesian, Australian aborigine, and Amerindian groups. Complete Ag-haplotype frequencies were estimated by maximum-likelihood-score procedures, and the data were analyzed by genetic distance computations and principal coordinate projections. With the exception of the Amerindian sample, the Ag polymorphism is shown to be highly polymorphic in all the populations tested. Their genetic relationships appear to be closely correlated to their geographical distribution. This suggests that the Ag system has evolved as a neutral or nearly neutral polymorphism and that it is highly informative for modern human peopling history studies. From the worldwide Ag haplotypic distributions, a model for the Ag molecular structure is derived. According to this model and to the most recent results obtained from molecular data, the establishment of the Ag polymorphism could be explained by several mutations and recombination events between the haplotypes most frequently found in human populations today. As a conclusion, genetic and paleontological data suggest that the genetic structure of caucasoid populations (located from North Africa to India) may be the least differentiated from an ancestral genetic stock. Worldwide genetic differentiations are properly explained as the results of westward and eastward human migrations from a Near East-centered but undefined geographical area where modern humans may have originated. The importance of Ag polymorphism analyses for the reconstruction of human settlement history and origins is discussed in the light of the main conclusions of the most recent genetic polymorphism studies.     

Intra- and extragenic marker haplotypes of CFTR mutations in cystic fibrosis families

Summary In order to facilitate the screening for the less common mutations in the cystic fibrosis (CF) gene viz., the CF transmembrane conductance regulator gene (CFTR), marker haplotypes were determined for German nonCF (N) and CF chromosomes by polymerase chain reaction analysis of four polymorphisms upstream of the CF gene (XV-2c, KM.19, MP6-D9, J44) and six intragenic polymorphisms (GATT, TUB9, M470V, T854T, TUB18, TUB20) that span the CFTR gene from exon 6 through exon 21. Novel informative sequence variants of CFTR were detected in front of exons 10 (1525-61 A or G), 19 (3601-65 C or A), and 21 (4006-200 A or G). The CF locus exhibits strong long-range marker-marker linkage disequilibrium with breakpoints of recombination between XV-2c and KM.19, and between exons 10 and 19 of CFTR. Marker alleles of GATT-TUB9 and TUB18-TUB20 were found to be in absolute linkage disequilibrium. Four major haplotypes encompass more than 90% of German N and CF chromosomes. Fifteen CFTR mutations detected on 421 out of 500 CF chromosomes were each identified on one of these four predominant 7-marker haplotypes. Whereas all analysed F508 chromosomes carried the same KM.19-D9-J44-GATT-TUB9-M470V-T854T haplotype, another frequent mutation in Germany, R553X, was identified on two different major haplotypes. Hence, a priori haplotyping cannot exclude a particular CF mutation, but in combination with population genetic data, enables mutations to be ranked by decreasing probability.     

Chromosomal features revealed by comparison of genetic maps of Glycine max and Glycine soja

Recombination is a crucial component of evolution and breeding. New combinations of variation on chromosomes are shaped by recombination. Recombination is also involved in chromosomal rearrangements. However, recombination rates vary tremendously among chromosome segments. Genome-wide genetic maps are one of the best tools to study variation of recombination. Here, we describe high density genetic maps of Glycine max and Glycine soja constructed from four segregating populations. The maps were used to identify chromosomal rearrangements and find the highly predictable pattern of cross-overs on the broad scale in soybean. Markers on these genetic maps were used to evaluate assembly quality of the current soybean reference genome sequence. We find a strong inversion candidate larger than 3 Mb based on patterns of cross-overs. We also identify quantitative trait loci (QTL) that control number of cross-overs. This study provides fundamental insights relevant to practical strategy for breeding programs and for pan-genome researches.     

Identification of risk-related haplotypes with the use of multiple SNPs from nuclear families

Family-based association studies offer robustness to population stratification and can provide insight into maternally mediated and parent-of-origin effects. Usually, such studies investigate multiple markers covering a gene or chromosomal region of interest. We propose a simple and general method to test the association of a disease trait with multiple, possibly linked SNP markers and, subsequently, to nominate a set of “risk-haplotype-tagging alleles.” Our test, the max_Z² test, uses only the genotypes of affected individuals and their parents without requiring the user to either know or assign haplotypes and their phases. It also accommodates sporadically missing SNP data. In the spirit of the pedigree disequilibrium test, our procedure requires only a vector of differences with expected value 0 under the null hypothesis. To enhance power against a range of alternatives when genotype data are complete, we also consider a method for combining multiple tests; here, we combine max_Z² and Hotelling’s T². To facilitate discovery of risk-related haplotypes, we develop a simple procedure for nominating risk-haplotype-tagging alleles. Our procedures can also be used to study maternally mediated genetic effects and to explore imprinting. We compare the statistical power of several competing testing procedures through simulation studies of case-parents triads, whose diplotypes are simulated on the basis of draws from the HapMap-based known haplotypes of four genes. In our simulations, the max_Z² test and the max_TDT (transmission/disequilibrium test) proposed by McIntyre et al. perform almost identically, but max_Z², unlike max_TDT, extends directly to the investigation of maternal effects. As an illustration, we reanalyze data from a previously reported orofacial cleft study, to now investigate both fetal and maternal effects of the IRF6 gene.     

Chromosomal instability and human hepatocarcinogenesis

Recently, many studies have identified losses and gains of several chromosomal loci in human hepatocellular carcinoma (HCC) with fine microsatellite analysis and comparative genomic hybridization. Although distribution of aberrant chromosomal arms differs among HCCs, loss of 1p, 4q, 6q, 8p, 9p, 10q, 13q, 16q and 17p, and gain of 1q, 6p, 8q, 17q and 20q have been recurrently reported, and loss of 4q and 16q seems to occur preferentially in hepatitis B virus-related HCCs. Accumulation of these aberrant chromosomal regions is associated with tumor progression, and some chromosomal aberrations, such as loss of 1p, are frequently identified in well-differentiated HCCs and also detected even in dysplastic nodule and cirrhotic nodule. This evidence suggests that chromosomal instability (CIN) emerges at an early stage during hepatocarcinogenesis and is successively inherent to tumor cells, resulting in acquisition of malignant phenotype. The molecular basis of CIN is beginning to be explored; however, several mechanisms may be involved for CIN of HCC.     

Chromosomal instability and human cancer

Genetic instability is a defining feature of human cancer. The main type of genetic instability, chromosomal instability (CIN), enhances the rate of gross chromosomal changes during cell division. CIN is brought about by mutations of CIN genes, i.e. genes that are involved in maintaining the genomic integrity of the cell. A major question in cancer genetics is whether genetic instability is a cause and hence a driving force of tumorigenesis. A mathematical framework for studying the somatic evolution of cancer sheds light onto the causal relations between CIN and human cancer.