Application of DNA fingerprints for cell-line individualization.

DNA fingerprints of 46 human cell lines were derived using minisatellite probes for hypervariable genetic loci. The incidence of 121 HaeIII DNA fragments among 33 cell lines derived from unrelated individuals was used to estimate allelic and genotypic frequencies for each fragment and for composite individual DNA fingerprints. We present a quantitative estimate of the extent of genetic difference between individuals, an estimate based on the percentage of restriction fragments at which they differ. The average percent difference (APD) among pairwise combinations from the population of 33 unrelated cell lines was 76.9%, compared with the APD in band sharing among cell lines derived from the same individual (less than or equal to 1.2%). Included in this survey were nine additional cell lines previously implicated as HeLa cell derivatives, and these lines were clearly confirmed as such by DNA fingerprints (APD less than or equal to 0.6%). On the basis of fragment frequencies in the tested cell line population, a simple genetic model was developed to estimate the frequencies of each DNA fingerprint in the population. The median incidence was 2.9 X 10(-17), and the range was 2.4 X 10(-21) to 6.6 X 10(-15). This value approximates the probability that a second cell line selected at random from unrelated individuals will match a given DNA fingerprint. Related calculations address the chance that any two DNA fingerprints would be identical among a large group of cell lines. This estimate is still very slight; for example, the chance of two or more common DNA fingerprints among 1 million distinct individuals is less than .001. The procedure provides a straightforward, easily interpreted, and statistically robust method for identification and individualization of human cells.     

Use of fragment–sharing estimates from DNA fingerprinting to determine relatedness in a tropical wren

We assessed the usefulness of DNA fragment–sharing scores from DNA fingerprints for assigning relatedness to unknown pairs of individuals in a population of stripe–backed wrens (Campylorhynchus nuchalis). Preliminary investigation of scoring biases revealed consistency both within and between scorers in relative band–sharing scores, but a tendency for scores to be inflated and for inter–scorer agreement to decline as distance between lanes on an autoradiograph increased. Distributions of band–sharing values matched expected distributions well, which suggests that variability in scores is mostly inherent and not a result of errors in scoring. Confidence intervals based on band–sharing scores or means of scores across enzymes, probes and scorers revealed that unrelated (r= 0) and first–order dyads (r=Vi) could be distinguished on the basis of single band–sharing scores from the best combination of enzyme and probe (HaeIII/33.15) and that first– and second–order dyads could be distinguished when confidence intervals were based on means of band–sharing scores across two enzymes, two probes and two scorers.     

Variation in the size of human apolipoprotein(a) is due to a hypervariable region in the gene

Summary We have investigated whether the size heterogeneity of the human apolipoprotein (a) [apo(a)] is due to differences in the number of plasminogen kringle 4-like repeat units present in the different alleles. Using the Southern blot hybridization technique and a DNA probe for the kringle 4 domain of plasminogen, we have observed that in 31 different individuals a 5.8-kb PvuII restriction fragment band varies widely in intensity relative to other bands. A strong correlation (r=0.76, P<0.001) was found between apo(a) protein size and the variation in intensity of the detected restriction fragment band. We confirmed this correlation in a large family where the parents are heterozygous for the apo(a) protein size isoforms. The specificity of the 5.8-kb band was established by using an apo(a)-specific oligonucleotide. These correlations strongly suggest that the observed size heterogeneity in apo(a) protein is due to different numbers of copies of the kringle 4 sequence in the apo(a) glycoprotein gene.     

DNA fingerprinting in cattle using the probe pV47

The multilocus probe pV47 detected an average of nine bands in cattle between 23 kb and 4 kb. Band sharing was estimated for three groups of unrelated animals. The first group comprised 20 individuals of 12 different breeds, the second group 10 individuals of the Swiss Simmental population and the third group 11 individuals of the Swiss Brown Swiss population. The band sharing probabilities were 33%, 42% and 58% respectively. The DNA fingerprints of 38 offspring with a total of 277 bands revealed no bands that could not be traced to the parents.     

Polymorphic class II sequences linked to the rat major histocompatibility complex (RT1) homologous to human DR and DQ sequences

Until recently, the analysis of Class II genes linked to the rat major histocompatibility complex, RT1, has been confined to serologic and electrophoretic analysis of their gene products. To obtain a more definitive estimate of the number and relative polymorphism of RT1 Class II sequences, we performed Southern blot analysis of rat genomic DNA employing human cDNA probes specific for Class II heavy and light chain genes. Southern blots of EcoRI and BamHI digests of genomic DNA from ten inbred strains, expressing eight RT1 haplotypes, were hybridized with the human DQ beta or DR beta cDNA that are homologous to Class II light chain sequences. Four to eight bands were observed to hybridize with the light chain cDNA: band sizes ranged from 2.5 to 28 kb. Restriction fragment patterns were polymorphic; the only identical patterns observed were those associated with RT1 haplotypes with identical RT1.B regions. The number and size of bands hybridizing with DQ beta and DR beta suggested a minimum of four light chain sequences in each haplotype. Southern blots of BamHI and EcoRI digests of genomic DNA from the same strains were hybridized with a DR alpha cDNA that is homologous to Class II heavy chain sequences. All RT1 haplotypes expressed either a 10.0-kb or 13.0-kb band when digested with BamHI, and either a 17-kb or 3.7-kb band when digested with EcoRI. Considerably less polymorphism was detected with the DR alpha probe; this observation is consistent with previously reported limited protein polymorphism of the rat equivalent of the I-E alpha subunit. The size and number of bands hybridizing with the DR alpha probe suggests a minimum of two heavy chain sequences. These observations suggest that the RT1 complex includes more Class II sequences than have been observed in serologic and electrophoretic analyses of Class II gene products. Furthermore, the level of polymorphism of RT1 Class II sequences appears to be comparable with mouse and human Class II sequences.     

Genetic similarity, breeding distribution range and sexual selection

Large populations with extensive breeding distributions may sustain greater genetic variability, thus producing a positive relationship between genetic variation and population size. Levels of genetic variability may also be affected by sexual selection, which could either reduce levels because a small fraction of males contribute to the following generation, or augment them by generating genetic variability through elevated rates of mutations. We investigated to what extent genetic variability, as estimated from band sharing coefficients for minisatellite markers, could be predicted by breeding distribution range, population size and intensity of sexual selection (as reflected by degree of polygyny and extra-pair paternity). Across a sample of 62 species of birds in the Western Palearctic, we found extensive interspecific variation in band sharing coefficients. High band sharing coefficients (implying low local genetic variability among individuals) were associated with restricted breeding distributions, a conclusion confirmed by analysis of statistically independent linear contrasts. Independently, species with large population sizes had small band sharing coefficients. Furthermore, bird species with a high richness of subspecies for their breeding distribution range had higher band sharing coefficients. Finally, bird species with high levels of polygyny and extra-pair paternity had small band sharing coefficients. These results suggest that breeding distribution range, population size and intensity of sexual selection are important predictors of levels of genetic variability in extant populations.     

GENETIC FINGERPRINT-INFERRED POPULATION SUBDIVISION AND SPATIAL GENETIC TESTS FOR ISOLATION BY DISTANCE AND ADAPTATION IN THE COASTAL PLANT LIMONIUM CAROLINIANUM

This paper examines two wild populations of Limonium carolinianum for population genetic subdivision and spatial patterns of genetic variation in an attempt to simultaneously test for both the action of local adaptation to tidal gradients and isolation by distance (IBD). A VNTR (variable number of tandem repeats) genetic “fingerprinting” marker was used to infer relatedness among mapped plants in two populations. Band sharing within and between populations estimated F'_ST, an approximate measure of F_ST. Regression models were used to analyze the relationship between band sharing and spatial separation in tidal elevation and horizontal distance, as well as the relationship of fecundity differences with band sharing and spatial distance. Populations differed in band size frequency distributions and mean number of bands per profile and, therefore, likely differed in effective population size. F'_ST was estimated at 0.0678 and was significantly greater than F'_ST among randomly constructed subpopulations. Band sharing decreased 0.13% per meter in one population but showed no significant relation to distance in the other. In the population with significant IBD band sharing increased with increasingly different tidal elevation, contrary to an adaptive hypothesis, possibly due to directional gene flow or drift. Deme sizes were approximately 25 meters and greater than 100 meters, spanning larger areas than the entire environmental gradient. Fecundity differences were not associated with spatial parameters or band sharing. Unequal potential maternal fecundity measured as variance in number of seeds per maternal family was a significant source of genetic sampling variance. The VNTR marker employed is capable of detecting adaptation as identity by descent in ecological time and is an appropriate method for estimating the net evolutionary fate of polygenic traits. The results show that the net balance between selection along an environmental gradient and the effects of IBD and unequal maternal fecundity favor genetic differentiation by random processes in populations of Limonium.     

A molecular marker that segregates with sorghum leaf blight resistance in one cross is maternally inherited in another

Leaf blight-resistant sorghum accession SC326-6 was crossed to the susceptible cultivar BTx623 to analyze the genetic basis for resistance. Field scoring of inoculated F₂ progeny revealed that resistance was transmitted as a dominant single-gene trait. By combining the random amplified polymorphic DNA (RAPD) technique with bulked-segregant analysis, it was possible to identify PCR amplification products that␣segregated with disease response. Primer OPD12 amplified a 323-bp band (D12R) that segregated with resistance. Creation of longer primers, or SCARs (sequence characterized amplified regions) for D12R resulted in the amplification of a single major band of the predicted size from all the resistant F₂ progeny and the resistant parent SC326-6, but not from BTx623 or 24 of 29 susceptible F₂ progeny. The SCAR primers also amplified a single band with DNA from IS3620C, the female parent in a cross with BTx623 that has been used to produce a recombinant inbred population for RFLP mapping. An equivalent band was amplified from all 137 recombinant inbred progeny, indicating that organelle DNA is the amplification target in this cross. Received: 31 July 1998 / Accepted: 23 November 1998     

The immunoglobulin lambda variable light-chain region in primates has been shaped by multiple, independent, small-scale and large-scale insertion/deletion events

We analyzed genomes of nonhuman primates to determine the ancestral state of a 9.1-kb insertion/deletion polymorphism, located on human chromosome 22. The 9.1-kb+ allele was found in 16 chimpanzees, 3 bonobos, and 2 Bornean orangutans; however, 9 chimpanzees and 6 Sumatran orangutans showed neither the 9.1-kb+ nor the 9.1-kb- allele, but a novel allele, termed 9.1-kbnull. A clone from a chimpanzee BAC library carrying the 9.1-kbnull allele was sequenced: the BAC DNA aligns with the human chromosome 22 reference sequence except for a 75-kb region, suggesting that the 9.1-kbnull allele originated from a deletion. Furthermore, the 9.1-kb+ chromosomes of chimpanzees and bonobos contain a 1030-nucleotide sequence, absent in humans, that may result from a retro-transposition insertion in their common ancestor. Our results provide additional evidence that human chromosome 22 has undergone multiple small-scale and large-scale insertions and deletions since sharing a common ancestor with other primates.     

Dispersal, philopatry, and genetic relatedness in a social carnivore: comparing males and females

A balance must be maintained between the proportion of individuals dispersing and the proportion remaining philopatric such that inbreeding and resource competition are minimized. Yet the relative importance of dispersal and philopatric behaviour is uncertain, especially for species with complex social systems. We examine the influence of dispersal on genetic relationships of a white-nosed coati ( Nasua narica : Procyonidae) population from Panama. Field studies of the coati indicate a social system in which all females are highly philopatric and live in bands while all adult males become solitary at maturity, but do not disperse from the home range of their natal band. Based on analyses of multilocus DNA fingerprints, we confirm that female philopatry is the rule, long-distance dispersal is rare, and that relatedness between most bands is low. However, some new bands result from fission events and these bands retain relatively high relatedness to one another for several years. Adult males inhabiting the home range of a band are closely related to band members. In contrast, males and band members whose ranges do not overlap are unrelated or only slightly related. Adult males are also more closely related to other males whose home ranges they overlap extensively than to males whose home ranges they overlap only slightly. These results indicate that males initially disperse from their natal bands to reduce resource competition and not to avoid inbreeding. Inbreeding avoidance, if it occurs, results from more extensive range movements by males during the mating season.     

Spawning patterns in the three-spined stickleback (Gasterosteus aculeatus L.): an evaluation by DNA fingerprinting

We analysed a random sample of 10 three-spined stickleback nests by DNA fingerprinting. DNA from the guardian male and a random subsample of LO fry per nest were probed with pYNZ 132, a human single-locus probe for VNTR-loci (variable number of tandem repeats). On average this probe produced DNA fingerprints of 12 scoreable bands. By comparing the bands present in each individual, we calculated band sharing indices (BSIs) between the guardian male and its fry. The BSls varied between 0.40 and 0.77 with an average (± S.D.) of 0.59 ± 0.09. We therefore conclude that the guardian male was the true father of the fry in all these nests. Once the paternal bands in each fry were determined, we compared the maternal bands among the fry of each nest. Based on the BSIs obtained with these comparisons, we found that one guardian male enticed three females to spawn in its nest, six enticed two females and three enticed one female.     

Base sequence studies of 300 nucleotide renatured repeated human DNA clones

A band of 300 nucleotide long duplex DNA is released by treating renatured repeated human DNA with the single strand-specific endonuclease S₁. Since many of the interspersed repeated sequences in human DNA are 300 nucleotides long, this band should be enriched in such repeats. We have determined the nucleotide sequences of 15 clones constructed from these 300 nucleotide S₁-resistant repeats. Ten of these cloned sequences are members of the Alu family of interspersed repeats. These ten sequences share a recognizable consensus sequence from which individual clones have an average divergence of 12.8%. The 300 nucleotide Alu family consensus sequence has a dimeric structure and was evidently formed from a head to tail duplication of an ancestral monomeric sequence. Three of the remaining clones are variations on a simple pentanucleotide sequence previously reported for human satellite III DNA. Two of the 15 clones have distinct and complex sequences and may represent other families of interspersed repeated sequences.     

DNA fingerprinting of red clover (Trifolium pratense L.) with Jeffrey's probes: detection of somaclonal variation and other applications

Summary DNA fingerprints generated by the Jeffreys' probes, 33.6 and 33.15, indicated the presence of minisatellite-like sequences in the red clover genome. The fingerprints generated by probe 33.6 gave less background and fewer but better defined bands than those obtained with probe 33.15. Assay of a regenerative somaclonal variant (F49R) by DNA fingerprinting with probe 33.6 detected mutation that was unlinked to the regenerative trait. The fingerprints obtained under the applied conditions also demonstrated genetic stability of consecutive generations of the regenerants in tissue culture. DNA fingerprints of F₁ plants revealed that each polymorphic band was inherited from either one or the other parent. Both probes distinguished individual-specific genotypes in seven cultivars of red clover. Greater variability in DNA fingerprints was detected between (V=0.899) than within (0.417≤V≤0.548) cultivars.     

X chromosome restriction fragment length polymorphisms in five racial groups: rare variant detected with the RC8 (DXS9) probe in the Marathi population, India

Restriction fragment length polymorphisms were investigated in five racial groups using the X chromosome probes DXS9 and DXS7. The allele frequencies of these polymorphisms showed significant differences and both DNA fragments were found to be highly polymorphic in the populations of south and southeast Asia. In the Marathi population of India, a rare allele B*3 (3 kilobases; kb) and an altered 7-kb fragment instead of the 6.6-kb constant band were found with DXS9. This is the first time that the rare B*3 allele is found in a non-European population.     

Mapping and characterization of a novel human myc-like (MYCLK1) sequence.

The myc family of proto-oncogenes consists of several members that possess regions of sequence homology and some have known similarities in structure and function. We have isolated an 8.8-kb EcoRI fragment from a human genomic library by hybridization to a 28-base oligonucleotide probe derived from a region of the second exon of MYC, which is highly conserved in the myc gene family. Sequence analysis of this myc-like (MYCLK1) DNA fragment has revealed the existence of a region with 85% homology to the 28-base oligonucleotide probe. An open reading frame of 207 nucleotides containing the region of homology was found. We have mapped MYCLK1 to human chromosome 7 at band p15 by chromosome in situ hybridization; this site is distinct from the map location of previously characterized myc genes. Whether MYCLK1 represents a new functional member of the myc family of proto-oncogenes remains to be determined.     

Analysis of three restriction fragment length polymorphisms in the human type II procollagen gene.

Cloned genomic DNA sequences corresponding to various regions of the human type II procollagen gene were used to analyze the DNA from 78 normal volunteers. Southern hybridization experiments detected polymorphic HindIII, BamHI, and EcoRI sites. The presence of the polymorphic HindIII site results in a 7.0-kilobase (kb) band, and the absence of this site results in a 14.0-kb band. When present, the BamH1 polymorphic site yields a 4.8-kb band, and when absent, yields a 7.2-kb band. The presence of the EcoRI polymorphic site results in a 3.7-kb band, and its absence results in a 7.0-kb band. Each polymorphic site was mapped. Analyses of the data demonstrated that the sites are present in overall gene frequencies of .39 for HindIII, .04 for BamHI, and .02 for EcoRI. Gene frequencies of the polymorphic sites were also studied with respect to race. The polymorphic sites are present in a Hardy-Weinberg distribution in the study population. Study of an extended family demonstrated that the segregation of the HindIII polymorphic site is consistent with Mendelian inheritance.     

Individualization and estimation of relatedness in crocodilians by DNA fingerprinting with a Bkm-derived probe

Individual-specific DNA fingerprints of crocodilians were obtained by the use of Bkm-2(8) probe. Pedigree analyses of Crocodylus palustris, C. porosus and Caiman crocodilus revealed that the multiple bands (22–23 bands with Aludigest) thus obtained were inherited stably in a Mendelian fashion. Unique fingerprints permitted us to identify individuals, assign parentage, and reconstruct the DNA profile of a missing parent. Average band sharing between unrelated crocodiles was found to be 0.37. Band sharing between animals of known pedigrees increased predictably with relatedness and provided a basis for distinguishing relatives from non-relatives. Similar results obtained in other species/genera, using the same probe, suggest that this approach may be applicable to all species of crocodilians, and could facilitate genetic studies of wild and captive populations.     

Linkage studies of polymorphic, repeated DNA sequences in centromeric regions of human chromosomes.

The DNA at human centromeric regions was characterized by using a repetitive sequence, 308, which localizes in situ exclusively to centromeres of all chromosomes. We previously noted that this sequence is enriched on chromosome 6 and has chromosome-specific organization on 6, 3, 7, 14, X, and Y. In addition to this basic organization, sequences homologous to 308 are polymorphic among normal individuals. The variants are transmitted in a Mendelian manner within a family. To determine the chromosome origin of the variants, we studied their linkage to markers of various chromosomes. Linkage analysis of one pedigree segregating two polymorphisms shows that the 2.6-kilobase (kb) BamHI and 2.6-kb TaqI fragments are linked to each other and to the HLA loci on chromosome 6. Data from another family shows that 2.8-kb TaqI, 4.0-kb TaqI, and 1.3-kb BamHI polymorphic fragments are linked and are probably near the Fy locus on chromosome 1. By dot blot analysis, we determined that the relative amount of these sequences in the genome is not measurably different between unrelated individuals. Thus, the polymorphisms represent changes in homologous 308 sequences on specific chromosomes and can be used as chromosome-specific markers. Linkage studies using polymorphisms of repeated sequences will be most useful within a kindred, especially from an inbred population, because polymorphic repeats of the same restriction size may be heterogeneous in origin.     

Amelogenin gene similarity in vertebrates: DNA sequences encoding amelogenin seem to be conserved during evolution

Summary Mouse amelogenin cDNA was used in hybridization assays with genomic DNA, cut with the restriction enzyme Eco RI, from the edentulous chicken (Gallus domesticus), the monophyodont mouse (as control), diphyodont man, and the polyphyodont fishes Atlantic salmon (Salmo salar) and seawolf (Anarrhichas lupus). The hybridization assay was performed under stringent conditions with non-radioactive probes. Hybridization was obtained with mouse (6.4-kb band), man (9-kb and 13-kb bands), and seawolf (18-kb band) genomic DNA. This demonstrates DNA sequence similarities between these species, and supports the theory that DNA sequences encoding enamel proteins appear to be highly conserved during the evolution of vertebrates. Lack of hybridization in salmon and chicken may be due to sequence divergencies or structural differences in an amelogenin gene analog, or it may be that no amelogenin gene is present in these animals.