The heterogeneity of B-chromosome DNA: no evidence for a B-chromosome specific repetitive DNA correlated with B-chromosome effects on meiotic pairing in the triticinae

The compositional heterogeneity of DNAs of A (normal) and B (supernumerary) chromosomes of Aegilops speltoides, Ae. mutica and Triticum aestivum has been compared in order to elucidate the mechanism of B-chromosome disruption of meiotic pairing in interspecific hybrids. Comparisons of % heterologous association after DNA/DNA hybridation at C₀t 10^?2 (highly repetitious DNA) and C₀t 100 (moderately repetitious DNA), and comparisons of nucleotide base divergence (ΔT_ms) and thermal elution profiles of homologous and heterologous duplexes, show that genotypes of Aegilops spp., having large numbers of Bs, do not carry additional families of repetitious DNA exclusive to B-chromosomes. Neither the presence of Bs nor the direction of DNA/DNA hybridisation affect the above parameters. No cryptic DNA satellites were revealed in A- and B-chromosome DNA after sedimentation in actinomycin D-CsCl gradients; and there were no significant differences in buoyant densities of main-band DNA. Mean melting temperatures (T_m); transition temperatures (ΔT) and numbers and positions of peaks of dissociating DNA fractions in profiles of differentiated melting curves of native DNAs were similar in strictly comparable denaturation conditions. One small AT-rich (< 5%) DNA fraction correlated with speltoides Bs was revealed; however, no corresponding fraction is associated with mutica Bs. The overall similarity in numbers and base composition of families of DNA (repetitious and unique) of As and Bs is discussed in relation to the origin of Bs and the origin of the meiotic diploidising system in haploid T. aestivum.     

Primate repetitive DNAs: evidence for new satellite DNAs and similarities in non-satellite repetitive DNA sequence properties

Repetitious DNA sequences have been isolated from a number of the primates in both Suborders Anthropoidea and Prosimii by hydroxyapatite chromatography at a C₀t of 10. In addition to finding previously unreported possible AT-rich satellite DNAs in Orangutan, Gibbon, Rhesus and Slow Loris a clear similarity to human DNA was found in the non-satellite repetitious DNA sequence properties of the primates in the Suborder Anthropoidea. This is based on the presence of the hydroxyapatite isolated 1.703 and 1.714 g/cm³ DNA families in CsCl gradients in the analytical ultracentrifuge following renaturation and extensive DNA hyperpolymer network formation. Within the superfamily Hominoidea the amount of the 1.714 g/cm³ DNA family was greater than that of the 1.703 g/cm³ DNA family while the reverse situation was true within the Superfamily Cercopithecoidea. The orangutan 1.703 and 1.714 g/cm³ DNA families were shown to exhibit the same differential reassociation behavior demonstrated previously in human DNA (Marx et al., 1976a). These data are interpreted as preliminary evidence for a similar sequence organization in the Order Primates Suborder Anthropoidea.     

Chromosomal localisation of DNA sequences in condensed and dispersed human chromatin.

The DNAs purified from condensed and dispersed human chromatin were used as templates for the in vitro synthesis of ³H-labelled complementary RNAs (cRNAs). These cRNAs were hybridised in situ to preparations of fixed human metaphase chromosomes which had previously been stained with quinacrine and photographed with fluorescent (UV) light. Autoradiographs of the hybridised chromosomes were stained and photographed and the results analysed by comparison of the fluorescence photographs with the autoradiographs. This method allowed positive identification of every chromosomal site of hybridisation and quantitative analysis of grain distribution over a number of metaphase spreads. The cRNA transcribed from condensed chromatin DNA (cRNA_C) hybridised mainly to a limited number of sites close to or including centromeric heterochromatin (C-bands) and also to the brightly fluorescent regions of the Y chromosome. Many of these C-band regions are known to contain satellite DNAs, indicating that the repeated DNA in the condensed chromatin fraction consists largely, if not entirely, of satellite sequences. The cRNA transcribed from dispersed chromatin DNA (cRNA_D) does not contain satellite DNAs and hybridised more generally over the chromosome arms. However, the main sites of hybridisation with cRNA_D included the C-bands in the Y chromosome and autosomes, i.e. those regions which bound cRNA_C. This suggests that nonsatellite repeated DNA sequences may be associated with satellite DNAs in the chromosomes. No general correlation between the distribution of either kind of cRNA and the overall level of quinacrine fluorescence in chromosomes or chromosome arms was detectable, nor could the dispersed fraction be equated with cytological euchromatin, since it hybridised in many sites which appear heterochromatic. However, there was a suggestion that some non-fluorescing Q-bands bound cRNA_D preferentially. The differences which were found between the distribution of the cRNAs from the two chromatin fractions may be associated with differences in genetic activity.     

Characterisation of DNA from condensed and dispersed human chromatin

Condensed and dispersed chromatin fractions were isolated from human placental nuclei. The DNA of each fraction was purified and characterised by isopycnic centrifugation, thermal fractionation on hydroxylapatite (HAP) and sequence complexity studies. The DNAs had identical buoyant densities in neutral CsCl (1.698 g/cm³) and similar melting profiles on HAP. Analytical ultracentrifugation in Ag⁺-Cs₂SO₄, however, showed that satellite DNAs were present in the condensed fraction DNA (DNA_C) but were not visible in the dispersed fraction DNA (DNA_D). In addition, DNA_C was found to be enriched in highly reiterated sequences (20% reassociated by C₀t 10^?3) which can be correlated with the presence of satellite DNAs, whereas DNA_D contained only 3% of these fast reassociating sequences. In contrast DNA_D contained 30% intermediate sequences (reassociating between C₀t 10^?3 and C₀t 100) which represent only 10% of DNA_C. The reassociated highly repeated sequences of DNA_C showed the presence of two components in both CsCl density gradients and HAP thermal elution studies. This suggests that either there are sequence relationships resulting in partial mismatching between the different highly repeated DNA sequences in this fraction, or that highly repeated sequences are associated with less repetitious DNA. The results are discussed in terms of possible differences in genetic activity between the chromatin fractions.     

Conservation of repeated DNA base sequences in theCrustacea: A molecular approach to decapod phylogeny

Summary Analysis of data obtained from molecular hybridization of³H-labeled repetitious DNA has been utilized to reconstruct the broad outlines of phylogenetic relationships among decapod Crustacea. This molecular reconstruction agrees reasonably well with the paleontological record, and with other schemes obtained by comparative morphological and serological approaches. Preliminary evidence is in line with the hypothesis that continuous addition of new repeated sequence families to the genome over long periods of time may in part account for the correlation observed between percent repetitious DNA hybridized and divergence time. It is tentatively concluded that a core of DNA base sequence homology has been highly conserved throughout the evolution of theCrustacea. Demonstration of inter-species sequence homology has important implications to models which relegate a genetic regulatory function to repeated DNAs.     

Repeated sequences in the DNA of Drosophila and their localization in giant chromosomes

It is shown by isopycnic density gradient centrifugation that the DNAs of the sibling species Drosophila hydei, Drosophila neohydei and Drosophila pseudoneohydei differ regarding the numbers and proportions of satellite DNA bands. An overwhelming proportion of all repetitive nucleotide sequences of the DNA is contained in these satellite fractions. The majority of the satellites are species specific despite the close phylogenetic and cytological relationship between the three species studied. — By in situ hybridization experiments it is demonstrated that the various satellite sequences occupy different positions within the chromosomes. All types of localization patterns, from a wide spread occurrence in all chromosomes to an apparent restriction to kinetochore regions of single chromosomes, have been observed. Main band DNA, on the other hand, in its hybridization behavior reflects the DNA distribution according to the banding pattern in giant chromosomes. Generally satellite sequences seem to be included in -heterochromatic chromosome regions but no relation to the heterochromatin of the Y-chromosome was found. — Renaturation studies support various evidence that satellite sequences occur in tandemly repetitious units. At least some of this repetitious material seems to be linked to non-satellite DNA sequences or to DNA of other satellites.     

Differences in DNA composition along mammalian metaphase chromosomes

Denaturation of chromosomal DNA in situ can be achieved without disruption of chromosomal morphology by heating slides at 25–90° C in 10–95% formamide in SSC. The extent of denaturation is proportional to formamide concentration and temperature. Reassociation of denatured DNA is prevented with formaldehyde. — The DNA in the paracentromeric constrictions in human chromosomes 1, 9 and 16 denatures earlier than in any other regions, as shown by the red colour with acridine orange. When the temperature or formamide concentration is raised a red and green banding pattern emerges in which regions known to stain brightly with quinacrine mustard are red whereas other regions are green. The last regions to turn red are the short arms of some acrocentric chromosomes. Since A+T-rich DNA denatures before G+C-rich DNA, it is inferred that QM-bright areas are rich in A+T. Similar results are obtained with mouse and Microtus agrestis cells. — Reassociation of chromosomal DNA denatured by heat and formamide occurs if no formaldehyde is used. In human cells, kinetic studies on reassociation indicate that the highest degree of repetition is in the DNA of the distal half of the Y chromosome. Next in degree of repetition are the paracentromeric constrictions, the short arm regions of some of the acrocentric chromosomes, and all the centromeric regions. Highly repetitious DNA is found in all mouse centromeric regions except that of the Y chromosome. Constitutively heterochromatic segments of X and Y and the autosomal centromeric regions of Microtus agrestis also contain repetitious DNA. — It is proposed that differential base content and susceptibility to denaturation of DNA contribute to or at least accompany Q-, G- and R-banding. The degree of C-banding is related to repetitious DNA. The human Y chromosomal DNA is probably A+T-rich and exceptionally repetitious, exhibiting spontaneous reassociation under many experimental conditions.     

In situ localization and characterization of different classes of chromosomal DNA: acridine orange and quinacrine mustard fluorescence

In situ denaturation of metaphase chromosomes with alkali results in a shift from green to yellow, orange, brown and red fluorescence with acridine orange, indicating increasing denaturation of chromosomal DNA. The kinetics and characteristics of denaturation are described. Mouse and Microtus agrestis chromosomes denature uniformly but human cells show sequential denaturation. With increasing concentrations of alkali, the secondary constrictions in chromosomes 1, 9 and 16 are the first, and the distal half of the Y chromosome the last, to become denatured. — Reassociation of chromosomal DNA occurs within seconds after the start of incubation in salt solution. Areas containing repetitious DNA, e.g. mouse centromeres, fluoresce much more strongly than other regions with acridine orange after prolonged reassociation. Since human and Microtus centromeric regions behave similarly, it is proposed that they, too, contain repetitious DNA. — Reassociation treatment leads to enhancement of bright quinacrine mustard fluorescence in regions already bright before treatment. Furthermore, regions containing repetitious DNA, e.g. the secondary constrictions in human chromosomes 1, 9 and 16, whose fluorescence is dull before treatment, turn bright after reassociation. — The methods of fluorescence analysis of mammalian chromosomes with acridine orange and quinacrine mustard permit the localization and study of different classes of chromosomal DNA.     

Direction of DNA replication in mammalian cells

We have re-examined the direction of DNA synthesis in mammalian cells by means of pulse-labeling with [³H]thymidine and DNA autoradiography. Our results show that, whether or not the cells are treated with 5-fluoro-deoxyuridine, and whether they are labeled first with high specific activity [³H]thymidine and then with low, or vice versa, most (? 90%) of the unambiguous autoradiographic patterns can be explained by bidirectional replication but not by unidirectional replication.We also find that in autoradiographic experiments using two different specific activities of [³H]thymidine, obvious differences in grain density are obtained only when the difference in specific activity is threefold or more. Thus, the apparently contradictory findings of Lark et al. (1971) can be explained by the low difference in specific activity used by those authors.     

Identification of a mutation in chloroplast DNA correlated with formation of defective chloroplasts in a variegated mutant of Nicotiana tabacum

Summary As in wild-type Nicotiana tabacum L., two satellite DNAs having densities of 1.700 and 1.705 g cm^–3 in CsCl were identified in the organelle fraction of homogenates made from variegated leaves of a cytoplasmic mutant of N. tabacum. As the proportion of white to green tissue increased a great reduction in the 1.700 chloroplast DNA occurred correlated with a concomitant reduction in the total number of defective and normal chloroplasts per cell. At the same time, there was an absolute increase in the 1.705 satellite DNA. Separation of the two satellite DNAs was achieved by one cycle of purification on NaI gradients. When the 1.700 chloroplast DNAs from white and from green tissue of variegated leaves were compared, identical properties were found by the conventional buoyant density, T _m and renaturation kinetics measurements. However, using a specially constructed difference melting system, the 1.700 DNA from defective chloroplasts was shown to have an approximately 1% higher GC composition than the DNA from normal chloroplasts. Also, by renaturation of a mixture of alkali denatured normal and defective chloroplast DNAs and subsequent spreading in formamide for electron microscopy, internal regions of mismatching were observed. The nonhomologous region corresponded to about 500–1000 base pairs. No differences in composition of the 1.705 satellite DNA derived from white or green tissues were detected either by difference melting or formation of heteroduplexes.     

High affinity DNA-microtubule interactions: evidence for a conserved DNA-MAP interaction involving unusual high CsCl density repetitious DNA families

We have examined high affinity interactions of chick brain microtubule proteins with ³⁵S labelled tracer DNAs from chick, mouse and D. melanogaster under equilibrium conditions by the nitrocellulose filter binding technique. Ternary reaction mixtures of the above two components and a third component, an excess of unlabelled competitor DNA from either E. coli., mouse, D. melanogaster or chick, were used to measure small fractions of DNA in each case (1–4%) bound to microtubule protein under high stringency- large competitor DNA concentration and 0.5 M NaCl. As seen in part previously (Marx, K.A. and Denial, T. (1985) in The Molecular Basis of Cancer, 172B, 65–75 (Rein, ed), A. Liss, N.Y.) the measured order of competitor DNA strengths was identical for all three tracer DNAs. That is: chick > mouse > D. melanogaster > E. coli competitor DNA. Since the homologous interaction, chick competitor DNA with chick brain microtubule protein, is always the strongest interaction measured, we interpret this as evidence for a conserved protein-DNA sequence interaction. ³⁵S chick DNA tracer sequences, isolated from nitrocellulose filters following the stringent binding in the presence of 0.9 mM^–1 E. coli. competitor DNA, was used in driven reassociation reactions with total chick driver DNA. This fraction was found to be significantly enriched in repetitive chick DNA sequences. Since we have observed a similar phenomenon in mouse, we then compared the stringent binding mouse sequences and showed that the bulk of these sequences did not cross-hybridize with total chick DNA. Finally, all three ³⁵S tracer DNAs binding to nitrocellulose were isolated and sedimented to equilibrium on CsCl density gradients. The CsCl density distributions from all three DNAs showed significant (100-fold) enrichment in classical satellite DNAs as well as higher enrichment in two very unusual high CsCl density families of DNA (1.720–1.740 g/cm³; 1.750–1.765 g/cm³). These families are never observed as distinct bands in total DNA CsCl gradients, nor could we isolate them in purified tubulin control binding experiments. This apparently general phenomena may be identifying some of the sequence families involved in the high affinity microtubule interaction, which appears to be conserved in evolution.     

The relationship between repetitive DNA and chromosomal bands in man

The relationship between chromosomal bands and repetitious DNA has been investigated by means of the quinacrine fluorescence technique and in situ hybridization with c-RNA to different fractions of repetitive DNA. A comparison of the Q bands with the labelling patterns obtained showed a preferential distribution of repetitive DNA's at Cot's ranging from 0 to 5 in those regions that are Q band positive. A distinct labelling was also observed in the pericentromeric regions and in some telomeres. It is suggested that the distribution of repetitive DNA along the chromosomes plays an important role in band formation.     

Chromosomal Mapping of Repetitive DNAs in the Grasshopper Abracris flavolineata Reveal Possible Ancestry of the B Chromosome and H3 Histone Spreading

Supernumerary chromosomes (B chromosomes) occur in approximately 15% of eukaryote species. Although these chromosomes have been extensively studied, knowledge concerning their specific molecular composition is lacking in most cases. The accumulation of repetitive DNAs is one remarkable characteristic of B chromosomes, and the occurrence of distinct types of multigene families, satellite DNAs and some transposable elements have been reported. Here, we describe the organization of repetitive DNAs in the A complement and B chromosome system in the grasshopper species Abracris flavolineata using classical cytogenetic techniques and FISH analysis using probes for five multigene families, telomeric repeats and repetitive C₀t-1 DNA fractions. The 18S rRNA and H3 histone multigene families are highly variable and well distributed in A. flavolineata chromosomes, which contrasts with the conservation of U snRNA genes and less variable distribution of 5S rDNA sequences. The H3 histone gene was an extensively distributed with clusters occurring in all chromosomes. Repetitive DNAs were concentrated in C-positive regions, including the pericentromeric region and small chromosomal arms, with some occurrence in C-negative regions, but abundance was low in the B chromosome. Finally, the first demonstration of the U2 snRNA gene in B chromosomes in A. flavolineata may shed light on its possible origin. These results provide new information regarding chromosomal variability for repetitive DNAs in grasshoppers and the specific molecular composition of B chromosomes.     

Satellite DNA associated with heterochromatin in Rhynchosciara

The DNA of Rhynchosciara hollaenderi was examined using isopycnic centrifugation in neutral CsCl. Two low density minor bands (collectively termed satellite DNA) were detected in addition to the main band DNA. Main band DNA has a buoyant density of 1.695 g/cm³. The larger of the two minor bands has a buoyant density of 1.680 g/cm³ while the smaller of the two minor bands has a buoyant density of about 1.675 g/cm³. Thermal denaturation studies have confirmed the presence of the two minor classes of DNA.—The satellite and main band DNAs were isolated in relatively pure form and were transcribed in vitro using DNA-dependent RNA polymerase from Escherichia coli. Annealing of the two complementary RNAs (cRNAs) with main band and satellite DNA was examined using filter hybridization techniques.—The chromosomal distribution of the satellite DNA was determined by in situ molecular hybridization of satellite-cRNA with Rhynchosciara salivary gland chromosomes. Satellite-cRNA hybridized with the centromeric heterochromatin of each of the four chromosomes (A, B, C, and X) and with certain densely staining bands in the telomere regions of the A and C chromosomes. Main band-cRNA annealed with many loci scattered throughout the chromosomes including areas containing satellite DNA.     

Two AT-rich satellite DNAs in the chironomid Glyptotendipes barbipes (Staeger)

Two AT-rich satellite DNAs are present in the genome of Glyptotendipes barbipes. The two satellites have densities of 1.680 g/cm³ (=21% GC) and of 1.673 g/cm³ (=13% GC) in neutral CsCl-density gradients. The main band DNA has a density of 1.691 g/cm³ (=32% GC). This value is in agreement with the 33% GC-content of G. barbipes DNA calculated from thermal denaturation (T_M=83° C). — In brain DNA as well as in salivary gland DNA the two satellite sequences together comprise 12–15% of the total G. barbipes DNA. Comparisons of the density profiles of DNA extracted from polytene and non-polytene larval tissue gave no hints for underreplication of the satellite DNAs during polytenization. — The two satellite DNAs have been isolated from total DNA by Hoechst 33258-CsCl density centrifugation and then localized in the polytene salivary gland chromosomes by in situ hybridization. Both satellite sequences hybridize to all heterochromatic centromere bands of all four chromosomes of G. barbipes. Satellite I (1.673 g/cm³) hybridizes mainly with the middle of the heterochromatin, satellite II (1.680 g/cm³) hybridizes with two bands at the margin of the heterochromatin. In situ hybridization with polytene chromosomes of Chironomus thummi revealed the presence of G. barbipes satellite sequences also in the Ch. thummi genome at various locations, mainly the centromere regions.     

Chromosomal location by in situ hybridization of the human Sau3A family of DNA repeats

Summary The Sau3A family is a human, clustered, highly repetitive, GC-rich DNA family. In situ hybridization studies with a plasmid carrying a Sau3A monomer as a probe have shown that Sau3A sequences are preferentially concentrated in the heterochromatic regions of human acrocentric chromosomes (D and G groups, both in pericentromeric regions and in cytological satellites) and in pericentromeric heterochromatin of chromosome 1. The same chromosomal locations were observed by using as probes two recombinant phages which carry Sau3A-positive genomic sectors. The two sectors differfor the relative proportions of monomer and multiples of Sau3A repeats, which show different extents of homology to the cloned monomer, and for the presence, in one of the two, of a samll amount of an unrelated repeat (alphoid DNA). The similarity of the results obtained with the three probes suggests that heterogeneous Sau3A repeats share the same chromosomal localizations and that the two analyzed genomic sectors may not contain significant amounts of repetitive DNAs other than the Sau3A family. A comparison between the chromosomal locations of Sau3A and EcoRI families of repeats has confirmed that each family is characterized by specific chromosomal locations and that single heterochromatic regions may contain both.     

A Possible Role of Repetitious DNA in Recombinatory Joining during Chromosome Rearrangement in DROSOPHILA MELANOGASTER

It is postulated that certain repetitious DNA components play a role in the recombination processes during chromosome rearrangements. When the distribution of silver grain densities after the in situ hybridization of repetitious DNA (Rudkin and Tartof 1973) and the distribution of chromosome breaks due to X-irradiation (Kaufmann 1946) are compared, a strong correlation is found for the euchromatic portion of the D. melanogaster salivary X chromosome. These observations justify the postulate above that certain repetitious DNA provides homologous regions in the DNA of broken chromosome ends necessary for proper recombinatory joining.     

DNA with damage in both strands as affinity probes and nucleotide excision repair substrates

Nucleotide excision repair (NER) is a multistep process of recognition and elimination of a wide spectrum of damages that cause significant distortions in DNA structure, such as UV-induced damage and bulky chemical adducts. A series of model DNAs containing new bulky fluoro-azidobenzoyl photoactive lesion dC^FAB and well-recognized nonnucleoside lesions nFlu and nAnt have been designed and their interaction with repair proteins investigated. We demonstrate that modified DNA duplexes dC^FAB/dG (probe I), dC^FAB/nFlu₊₄ (probe II), and dC^FAB/nFlu_?3 (probe III) have increased (as compared to unmodified DNA, umDNA) structure-dependent affinity for XPC—HR23B (Kd_um > Kd_I > Kd_II ≈ Kd_III) and differentially crosslink to XPC and proteins of NER-competent extracts. The presence of dC^FAB results in (i) decreased melting temperature (ΔT_m = ?3°C) and (ii) 12° DNA bending. The extended dC^FAB/dG-DNA (137 bp) was demonstrated to be an effective NER substrate. Lack of correlation between the affinity to XPC—HR23B and substrate properties of the model DNA suggests a high impact of the verification stage on the overall NER process. In addition, DNAs containing closely positioned, well-recognized lesions in the complementary strands represent hardly repairable (dC^FAB/nFlu₊₄, dC^FAB/nFlu_?3) or irreparable (nFlu/nFlu₊₄, nFlu/nFlu_?3, nAnt/nFlu₊₄, nAnt/nFlu_?3) structures. Our data provide evidence that the NER system of higher eukaryotes recognizes and eliminates damaged DNA fragments on a multi-criterion basis.     

Analysis of DNA from related and diverse species of Barley

DNAs of three closely related diploid species Hordeum vulgare, H. agriocrithon and H. spontaneum were compared among themselves and with a group of three species related to each other H. californicum (2x), H. jubatum (4x), and H. arizonicum (6x) having one genome in common.Buoyant densities of the DNAs from these species fall within a narrow range (1.700–1.701 g cm⁻³). Melting temperatures (T_m) of the DNAs are also similar (85.2–86.2°C). None of the DNAs showed any satellite band in neutral Cesium chloride gradients. In silver-cesium sulphate gradients, however, DNAs of all the species formed satellites on both the light and heavy sides of the main. band The diploid series have similar but not identical satellite patterns. The members of the polyploid series showed similar satellite patterns among themselves but distinct from those of the diploid series. In the polyploid group the amount of satellite showed a progressive decrease with the increase in the ploidy.The amount of repeated DNA (reassociating up to Cot 100) in H. vulgare was 69% and in H. arizonicum 65% of the total. The two species differed in their Cot curves. The low Cot fractions of H. arizonicum contained components of low buoyant densities which were absent in the corresponding Cot fractions of H. vulgare DNA.     

Scaffold attachment regions in centromere-associated DNA

Due to indications that kinetochore proteins are an integral part of the protein scaffold component of the chromosome (Earnshaw et al. 1984), we chose to map the distribution of scaffold attachment regions (SARs) at centromeres. Using the SAR mapping assay of Mirkovitch et al., Southern blots were prepared and probed with ³²P-labeled fragments from the human 1.9 kb centromeric α-satellite repeat unit of chromosome 1 or the 1.7 kb centromeric α-satellite repeat unit of chromosome 16. Our results demonstrated the presence of one SAR site per 1.9 kb repeat unit in chromosome 1, and every 1.7 kb repeat unit in chromosome 16, separated by regions of small DNA loops over the length of the α-satellite regions. We also identified several in vitro vertebrate topoisomerase II and cenP-B consensus sequences throughout the chromosome 1 α-satellite region using computer and base ratio analysis, to address the question as to why some α-satellite regions are SAR related and others are not. To provide in situ indications of SAR localization in the human genome, SAR DNA and non-SAR DNA were prepared following lithium 3,5-di-iodosalicylate extraction. Sequences protected from DNAse I digestion by SAR proteins, as compared with unprotected DNA that was digested by the enzyme, was labeled with biotin-UTP, hybridized to chromosomal DNA in situ, and then detected with fluorescein-avidin-DCS. Both SAR and non-SAR DNA selectively labeled virtually all centromeric regions of the human metaphase karyotype. Chromosomal arms were less strongly bound by SAR DNA, with a pattern that followed the chromosomal axis. In the more condensed chromosomes an R-banding pattern was evident. In general, labeling patterns produced by both SAR and non-SAR fractions were similar, as expected from the indications that SAR DNAs are heterogenous in sequence and do not form a specific class of sequences. We conclude that centromeric regions of several, possibly all, human metaphase chromosomes are also regions where the chromosomal axis contains loops, smaller in size than in the arms and where attachment sites are concentrated. This clustering of SARs may be responsible in part for the tight chromatin packing associated with the primary constriction of the centromeric region. Received: 10 October 1995; in revised form: 10 May 1996 / Accepted: 13 May 1996