A cloned repeated DNA sequence in human chromosome heteromorphisms

A sequence derived by ECoRI restriction of human satellite DNA III has been cloned in lambda gt WES. The cloned DNA was used as a template for in vitro synthesis of cRNA, which was hybridized in situ to preparations of human metaphase chromosomes with a range of heterochromatic polymorphisms. Most of the hybridization was found on chromosome 1, and the amount of hybridization was related to the size of the C-band on this chromosome. Hybridization to other chromosomes was not related to the C-band size, although hybridization of total satellite DNA is proportional to C-band size. Total satellite DNAs contain a mixture of sequences, some of which are predominantly located on only one pair of chromosomes. Hybridization in situ is able to discriminate between such chromosome-specific sequences and the bulk of satellite DNA. Further analysis of satellite DNAs may identify sequences specific for every chromosome pair.     

The DNA-based human karyotype

Image cytometry and computer analysis are used to determine the relative DNA content and the DNA-based centromeric index of the 24 chromosomes of the human karyotype. A two-step procedure is used. Chromosomes of cells in metaphase first are stained with quinacrine and identified visually by their fluorescent Q-band patterns. They then are stained for DNA using gallocyanin-chrome alum. The chromosome images are scanned and recorded as digital values of optical density by an CYDAC image cytometric microscope system, CYDAC. The digital images are processed by computer to measure for each chromosome the relative DNA stain contents of the whole chromosome and of the p and q arms and the DNA-based centromeric index. About ten cells are analyzed for each of the donors, who are phenotypically normal men and women. The chromosome measurements are pooled by chromosome type for each donor and are compared among donors. The means of the chromosome measurements give the DNA-based human karyotype. Analysis of the DNA-based data shows that some chromosomes or portions of chromosomes vary significantly among donors. These variants do not correlate with detectable morphologic polymorphisms, such as Q- or C-band variants; thus they represent new and otherwise undetectable chromosome polymorphisms whose genetic basis and clinical significance are yet to be determined.     

C-band polymorphisms of chromosome 9: quantification by Ce-bands

Summary C-band polymorphisms of chromosome 1 can be quantified by C_e bands visualized using oblique epi-illumination. In this paper the polymorphic region of chromosome 9, including variants such as 9qh+, inversions, and translocations, was analyzed in a total of 1860 chromosomes from 20 individuals and 8 fetuses. In this sample we found between zero and five C_e bands on 9q and between zero and four C_e bands on 9p with a maximum of five C_e bands per chromosome. On the basis of these observations at least 19 different polymorphic patterns can be expected theoretically, 15 of which were observed in our sample. Among these, five polymorphic C_e-band classes were distinguishable by the method presented. Considering both homologues, 5²=25 quantitatively discernible chromosome 9 pairs may exist.     

Quantitative analysis of C bands in chromosomes 1, 9, and 16 of Brazilian Indians and Caucasoids

Summary Densitometric C-band measurements in chromosomes 1, 9, and 16 of 394 Indians and 40 Caucasoids living in Brazil are reported. No significant intratribal variability in the average length of these regions was observed, and the intertribal variation showed no consistent patterns. But the Caucasoids always presented lower means. The relative C-band sizes of these three chromosomes, however, were very similar in Indians and Caucasoids. The indices of heteromorphism displayed analogous results; only in chromosome 16 are they dissimilar in these two ethnic groups. An unexpected sex difference was observed in the C-band sizes of this chromosome, females uniformly presenting higher averages than males. Centromeric heterochromatin appeared in 6% and 9% respectively of the short arms of chromosomes 1 and 9 among the Caucasoids, while among the Indians its prevalence was 2% in both chromosomes.     

Some factors affecting the action of restriction endonucleases on human metaphase chromosomes

We have investigated whether restriction endonucleases produce bands on human chromosomes by extracting DNA, using staining methods which are stoichiometric for DNA. Restriction enzymes that produce C-band patterns appear to remove DNA extensively from chromosome arms. In general, however, those restriction enzymes that produce G-bands do not extract DNA from chromosomes, and their effects are believed to be due to conformational change in the chromosomal DNA; in these cases, the chromosomal regions affected appear to be determined by the chromosome structure and not by the specificity of the enzyme. DNA loss from chromosomes due to digestion by restriction enzymes may in some cases be uniform, although a G-banding pattern is visible after Giemsa staining.     

DNA replication,3H-cRNA in situ hybridization and C-band patterns in the polycentric chromosomes ofLuzula purpurea Link

DNA late-replication,³H-cRNA in situ hybridization, and C-band distribution patterns were studied inLuzula purpurea Link chromosomes (2n=6). With each technique it was possible to identify homologous chromosomes. DNA late-replicating regions were present at the ends and in the middle of one chromosome pair (pair 1), on both ends of another chromosome pair with one end having more late-replicating regions than the other end (pair 2), and all along the length of the final pair (pair 3). The distribution of label following in situ hybridization of³H-cRNA complementary to Cot 1-reassociated DNA was similar to the DNA late-replication patterns. One chromosome pair had grains concentrated at the ends and in the middle of the chromosomes; another pair had grains at both ends with a greater grain concentration at one end; the final chromosome pair had grains distributed all along the length. C-band distribution patterns were also similar to the DNA late-replication and³H-cRNA in situ-hybridized ones. The results demonstrate that the constitutive heterochromatin ofL. purpurea polycentric chromosomes is similar to the constitutive heterochromatin of monocentric animal chromosomes in that it consists of highly repeated DNA sequences which are replicated late in the S stage of interphase.     

Chromosome markers in Mus musculus: Differences in C-banding between the subspecies M. m. musculus and M. m. molossinus

Quinacrine (Q-band) and centromeric heterochromatin (C-band) patterns of metaphase chromosomes of two subspecies of Mus musculus were compared. M. m. musculus (the laboratory mouse) and M. m. molossinus (a subspecies from Southeast Asia) had similar Q-band patterns along the length of the chromosomes, but differences were observed in the centromeric region of some chromosomes. The two subspecies had very different distributions of C-band material. Antibodies to 5-methylcytosine were bound to regions of the chromosome corresponding to the C-bands in each animal. These findings support the idea that satellite DNA, which is concentrated in the C-band region, changes more quickly than bulk DNA. The interfertility of these two subspecies permits the development of a musculus strain carrying normal marker chromosomes for genetic studies.     

Evidence for a highly differentiated sex chromosome heteromorphism in the salamander Necturus maculosus (Rafinesque)

The mitotic chromosomes of the neotenic (sensu Gould, 1977, and Alberch et al., 1979) salamander Necturus maculosus (Rafinesque) have been examined using a C-band technique to demonstrate the distribution of heterochromatin. The C-banded mitotic chromosomes provide evidence of a highly differentiated XY male/XX female sex chromosome heteromorphism, in which the X and Y chromosomes differ greatly in size and morphology, and in the amount and distribution of C-band heterochromatin. The X chromosome represents one of the largest biarmed chromosomes in the karyotype and is indistinguishable from similar sized autosomes on the basis of C-band heterochromatin. The Y chromosome, on the other hand, is diminutive, morphologically distinct from all other chromosomes of the karyotype, and is composed almost entirely of C-band heterochromatin. The discovery of an X/Y chromosome heteromorphism in this species is consistent with the observation by King (1912) of a heteromorphic spermatogenic bivalent. Karyological and phylogenetic implications are discussed.     

Patterns of exchange induced by mitomycin C in C-bands of human chromosomes. I. Relationship to C-band size in chromosomes 1, 9, and 16

Summary Frequencies of exchange were determined in C-bands of chromosomes 1, 9 and 16 in six normal males, and related to relative C-band area. Comparing these different chromosomes, more exchanges occurred on average in 9 than in 1 although their mean C-band sizes were similar. Chromosome 16 exchanges were fewer, both overall and relative to C-band area. Comparing the same chromosome between individuals, there was a positive correlation between relative frequency and band size in both 1-1 and 9-9 exchanges. No clear trend was observed for other exchange events.If homology is required for interchange, if cannot be dependent solely on overall C-band size. Perhaps certain DNA sequences, sensitive to mitomycin C damage, are located in part of each C-band, with less per unit area in chromosome 1 than in 9 and still less in chromosome 16.X- and U-type exchanges between chromosome 9s occurred in near equal frequencies in all individuals. If synapsis of specific, affected sequences is a pre-requisite for interchange, this observation suggests that the affected sequence in chromosome 9 is arranged in both orientations relative to the centromere.     

18p− Syndrome: an unusual case and diagnosis by in situ hybridization with chromosome 18-specific alphoid DNA sequence

Summary A patient with an atypical clinical picture of 18p^– syndrome is described. By the in situ hybridization technique we localized the chromosome 18-specific cloned repetitive sequence to metaphase chromosomes of the patient. The predominant hybridization of the probe was found in pericentromeric regions of homologous chromosomes 18. The amount of pericentromeric DNA measured by in situ hybridization differed between homologous chromosomes; and the number of radioactive grains was statistically greater in the normal chromosome 18 than in the aberrant chromosome 18p^–. The results indicate that this probe may be useful in clinical cytogenetics for identification of aberrant chromosomes, localization of breakpoints, and studies of C-band DNA polymorphism of chromosome 18.     

Pericentromeric location of the telomeric DNA sequences on the European grayling chromosomes

The chromosomal characteristics, locations and variations of the C-band positive heterochromatin and telomeric DNA sequences were studied in the European grayling karyotype (Thymallus thymallus, Salmonidae) using conventional C-banding, endonucleases digestion banding, silver nitrate (AgNO₃), chromomycin A₃ and 4′,6-diamidino-2-phenylindole staining techniques as well as fluorescence in situ hybridization (FISH) and primed in situ labelling. Original data on the chromosomal distribution of segments resistant to AluI restriction endonuclease and identification of the C-banded heterochromatin presented here have been used to characterize the grayling karyotype polymorphism. Structural and length polymorphism of the chromosome 21 showing a conspicuous heterochromatin block adjacent to the centromere seems to be the result of the deletion and inversion. Two pairs of nuclear organizer regions (NOR)-bearing chromosomes were found to be polymorphic in size and displaying several distinct forms. FISH with telomeric peptide nucleic acid probe enabled recognition of the conservative telomeric DNA sequences. The karyotype of the thymallid fish is thought to experienced numerous pericentric inversions and internal telomeric sites (ITSs) observed at the pericentromeric regions of the six European grayling metacentric chromosomes are likely relics of the these rearrangements. None of the ITS sites matched either chromosome 21 or NOR bearing chromosomes.     

Chromosome polymorphism in a human newborn population. II. Potentials of polymorphic chromosome variants for characterizing the idiogram of an individual.

Replicate chromosome preparations of umbilical-cord-blood leukocytes from 376 neonates born at the Albert Einstein College Hospital, Bronx, New York, were stained with C-, Q-, and G-banding methods to determine the frequencies and distributions of the variable chromosome bands. The C-band variants of primarily chromosomes 1, 9, and 16, as well as those of the remaining C, E, and F-group chromosomes, and the brightly fluorescing Q-band variants of chromosomes 3 and 4 and all of the acrocentrics, including the Y, were similarly analyzed. Polymorphism of these chromosome regions was so extensive that the idiogram of each of the 376 newborns of this study had a unique variant pattern, even when only the C- or only the Q-band patterns were compared. The distribution of polymorphic Q-bands in the population sampled was consistent with the expectations of the Hardy-Weinberg law, with the exception of chromosomes 3 and 22, where some deficiency of individuals with "homozygous" Q-band patterns was found. The baseline data presented here reinforce the view that polymorphic chromosome characteristics are very useful markers for characterizing the karyotype of an individual, for pedigree studies, for prenatal chromosome analyses, for population studies, for attempts at gene localizations, and for identifying specific cells or their chromosomes in somatic cell genetic studies.     

Satellite DNA sequences flank amplified DHFR domains in marker chromosomes of mouse fibrosarcoma cells

This study centers on marker chromosomes carrying expanded chromosomal regions which were observed in two independent derivatives of the AA12 murine fibrosarcoma line, the 10^–3 M MTX-res H2 and the 5×10^–7 M MTX-res E. Previous characterization of the marker chromosomes of MTX-res variants showed their common derivation from a marker chromosome (m) of the parental line, endowed with two interstitial C-bands. Cytogenetic evidence pointed to one C-band ofm as the site involved in the chromosomal rearrangements leading to the HSR/ASR chromosomes. ISH of a³H-labeled satellite DNA probe allowed satellite sequences flanking the HSR/ASR in the marker chromosomes, where the C-band was no longer visible, to be detected. FISH experiments using biotinylated DHFR and satellite DNA probes showed that the respective target sequences are contiguous in new marker chromosomes. They also allowed inter- and intrachromosomal rearrangements to be seen at DHFR amplicons and satellite sequences. Double-color FISH using digoxygenated satellite DNA and biotinylated pDHFR7 showed that in a marker chromosome from the H2 cell line the two target sequences are not only adjacent, but closer than 3 Mb, as indicated by overlapping of the different fluorescence signals given by the two probes. Another marker chromosome in the E variant was shown to display a mixed ladder structure consisting of a head-to-head tandem of irregularly-sized satellite DNA blocks, with two symmetrical interspersed DHFR clusters.Abbreviations DHFR dihydrofolate reductase - MTX Methotrexate - HSR Homogeneously Staining Region - ASR Abnormally Staining Region - DM Double Minute - ISH In Situ Hybridization - FISH FluorescenceIn Situ Hybridization     

Genetic linkage between C-bands and storage protein genes in chromosome 1B of tetraploid wheat

Summary Genetic mapping of polymorphic C-bands allows direct comparisons between genetic and physical maps. Eleven C-bands and two seed storage protein genes on chromosome 1B, polymorphic between Langdon durum and four accessions of T. dicoccoides, were used to study the distribution of recombination along the entire length of the chromosome. Recombination in the short arm was almost completely restricted to the satellite, two-thirds of the arm's length from the centromere; the Gli-B1 gene was found to be tightly linked to the telomeric C-band. In the long arm, the distal 51.4% of the arm accounted for 88% of recombination; the proximal half of the arm accounted for the remaining 12%. While the amount of crossing-over differed significantly between the four T. dicoccoides 1B chromosomes, there were no significant differences in the relative distributions of crossing-over along the chromosome. Consequently, the genetic maps obtained from the four individual T. dicoccoides chromosomes were combined to yield a consensus map of 14 markers (including the centromere) for the chromosome.     

Classification of Y chromosome polymorphisms by DNA content and C-banding

A system has been developed using a microscope photometer to measure the DNA content of individual chromosomes. After correcting for the systematic and statistical errors the measured values are highly reproducible. Data are presented of measurements of human Y chromosomes from a cytogenetically normal population. When compared with the C-banding pattern from the same specimens the DNA content is found to change in discrete steps of 1.36×10^–14 g or 13.26×10⁶ bp for each of the Y chromosome polymorphic types.     

A cytogenetic survey of an institution for the mentally retarded

Summary Heteromorphisms of chromosomes 1,9, and 16 were studied by C-banding in a population of 403 mentally retarded individuals from diverse ethinic groups. A significant difference in the distribution of heteromorphisms was found among the different racial groups. The Orientals had a larger C-band on chromosome 1 and a smaller C-band on chromosome 9 than the other racial groups while the Caucasians had a larger C-band on chromosome 9. The Oriental group also had a significantly greater proportion of inverted C-band. No differences were found in the distribution of C-band heteromorphisms among different etiologic categories of mental retardation.     

C-band length variability and reproductive wastage

Summary The possible influence of total Y chromosome length and the C-band size variability of chromosomes 1, 9, 16, and Y, on reproductive wastage was investigated. One hundred couples with recurrent reproductive wastage and 106 control couples with at least two healthy children and no miscarriages were cytogenetically studied. Total Y chromosome length was evaluated as the Y/F index and the C-band size was analyzed quantitatively according to the linear measurement method of Baliek et al. (1977). The different degrees of mitotic contraction were corrected on the basis of the linear correlation found between heterochromatin and euchromatin length. Statistical comparison between results of Y chromosome from both samples demonstrated, in the test group, an increase in the mean value of the Y/F index, but the increase of Y C-band length did not reach significance. In addition mean values of C-band length on chromosomes 1, 9, and 16 in couples from the test group and especially those who had had two or more abortions, were lower than those in the controls. Among the latter the frequency of chromosomes included in the category of very large heterochromatin size is higher. However these length differences have been demonstrated only in specific subgroups, and in each one for a different chromosome. Our results indicated that Y chromosome length as well as C-band size variabilities are not directly related to reproductive wastage.     

Variability and familial transmission of constitutive heterochromatin of human chromosomes evaluated by the method of linear measurement

Summary Using the method of linear measurement, the lengths of constitutive heterochromatin of chromosomes 1, 9, 16, and Y were determined in 125 unrelated individuals, and in 30 members of ten families. The method used eliminates the variations in the C-band length due to different degrees of contraction of chromosomes in different mitoses, and enables the size of heterochromatin blocks to be expressed. It was found that the distribution of C-band lengths in the group of 125 individuals was normal, i.e., Gaussian, for all four classes of chromosomes measured. On the basis of length distribution and by computing the P₁, P₁₀, P₉₀ and P₉₉ percentiles, the actual numerical limits could be proposed for the five-step evaluation of heterochromatin length according to the Paris Conference (1971), Supplement (1975), for chromosomes 1, 9, 16, and in a preliminary way also for Y. When applying the proposed limits to data obtained in the present study, 165 C-band variants could be identified among the 125 individuals.In ten families, C-block lengths of the chromosomes transmitted from parents to progeny could be determined in 63 cases. The mean difference in C-band length of transmitted chromosomes, as measured in parents and in children, was 0.46×10^-7 m. An analysis was carried out to detect the factors upon which the magnitude of this difference depends, and to define what differences are attributable to methodological errors. The results revealed that the difference rises slightly with the increasing length of the measured C block. Three degrees, defined by concrete ranges of difference in C-block length, were proposed for expressing the probability that the compared chromosomes had been transmitted.The study further attests to the effectiveness of the method of constitutive heterochromatin measurement for paternity testing. In our set of ten families, the comparison of C-band lengths of chromosomes 1, 9, 16, and Y led to rejection of paternity in 64% of unrelated individuals; excluding the Y chromosome, the percentage decreased to 61. As many as 47% of the individuals were rejected by a difference higher than two units (i.e., transmission of the compared chromosome highly improbable).     

Aspects of evaluation,significance, and evolution of human C-band heteromorphism

Summary The C-band heteromorphism may be evaluated in different forms. The results obtained from classification are easily influenced by subjective factors, and the conclusions of such types of data are acceptable only if they are well matched with a control. The length measurements is simple to obtain, and a quantitative presentation of the data, with correction for the contraction stage of the chromosomes, is considered the most effecient method to evaluate the C-band size heteromorphism. Excluding the acrocentrics, whose short arms present a complex heteromorphism, and the chromosome Y, whose variable C band is terminal, all others present C-band location heteromorphism except pair 16. It is possible to multiply the detectable heteromorphisms in some bands by using diverse staining methods. The present state of knowledge about the role of heterochromatin in the cell is analyzed, as is the effect of C-band variability on the phenotype, the reproductive fitness, and the individual viability. Although a great amount of data is available, no result can be considered definitive as yet. Aspects in which the use of C-band heteromorphisms are profitable are considered.     

Preferential segregation of marker chromosomes 14 and 18 in mouse recombinant inbred strains derived from the KE and CBA/Kw strains

The segregation pattern of chromosomes 14 and 18 were analyzed in recombinant inbred strains of mice developed from KE and CBA/Kw strains. The analysis was possible owing to the fact that the C-band on chromosomes 14 of the CBA/Kw strain and that of chromosome 18 of the KE strain show size polymorphism: while the CBA/Kw mice have a small sized C-band on chromosome 14, the KE mice show small C-bands on chromosome 18. Chromosomes were identified by G-banding and FISH. The results show that the chromosomes with small centromeric chromatin segregate preferentially.