The mechanism and pattern of banding induced by restriction endonucleases in human chromosomes

Protamine composition of koala and wombat spermatozoa provides new insights into DNA stability following cryopreservation

To investigate differences in the post-thaw DNA stability of koala and wombat spermatozoa, protamine amino acid sequences were compared and it was found that there were three more arginine residues for the wombat. Koala and wombat spermatozoa, cryopreserved using identical protocols, were examined for changes in sperm DNA fragmentation (SDF) dynamics over 24h of post-thaw incubation. Following validation of a wombat sperm chromatin dispersion test, wombat DNA showed a rate of SDF that was 6-fold higher than for koala spermatozoa (P=0.038). Finally, we examined whether expected differences in chromatin compactness, associated with protamine sequence, had an effect on restriction site accessibility of sperm DNA. Thawed spermatozoa were exposed to Alu I and EcoR1 endonuclease restriction enzymes and the SDF dynamics were observed. Koala spermatozoa exposed to Alu I showed a greater rate of SDF (P=0.01), whereas wombat spermatozoa exposed to EcoR1 showed a greater rate of SDF (P=0.032). We conclude that restriction sites in these species are differentially present or exposed and potentially account for differences in SDF dynamics. Although differences in the arginine composition of protamine may explain relative differences in SDF following cryopreservation, they do not support the hypothesis that increased arginine composition increases DNA stability; rather, increased arginine composition in the wombat may reduce post-thaw chromatin swelling.

Heterochromatin heterogeneity in Hypostomus prope unae (Steindachner, 1878) (Siluriformes, Loricariidae)from Northeastern Brazil

Cytogenetic analyses using C-banding and chromosomal digestion by several restriction enzymes were carried out in four populations (named A, B, C and D) of Hypostomus prope unae (Loricariidae, Hypostominae) from Contas river basin, northeastern Brazil. These populations share 2n=76 and single NORs on the second metacentric pair but exclusive karyotype forms for each locality. Populations A and B presented conspicuous terminal and interstitial heterochromatic blocks on most of acrocentric chromosomes and equivalent to NORs with differences in both position and bearing pair. Population D showed evident marks at interstitial regions and interspersed with nucleolar region while population C presented interstitial and terminal heterochromatin segments, non-coincident with NORs. The banding pattern after digestion with the endonucleases Alu I, Bam HI, Hae III and Dde I revealed a remarkable heterogeneity within heterochromatin, allowing the identification of distinctive clusters of repeated DNA in the studied populations, besides specific patterns along euchromatic regions. The analysis using restriction enzymes has proved to be highly informative, characterizing population differences and peculiarities in the genome organization of Hypostomus prope unae.

Unfixed and fixed human chromosomes show different staining patterns after restriction endonuclease digestion

Restriction endonucleases (REs) have been widely used to produce banding patterns on chromosomes, but it remains uncertain to what extent the patterns are due to the sequence specificity of the enzymes, and to what extent chromatin structure influences the pattern of digestion. To throw light on this question, we have digested with restriction endonucleases unfixed chromosomes prepared in two different ways (isolated, and whole metaphase cells spread with a cytocentrifuge) and compared the results with those obtained on conventionally fixed chromosomes. Unfixed isolated chromosomes are easily destroyed by REs; after fixation with cold methanol, which produced minimal alteration to the chromatin structure, the chromosomes are resistant to the action of REs, and conventional methanol-acetic acid fixation is required to permit the induction of banding patterns by REs. Unfixed cytocentrifuge preparations, in which the chromosomes are still surrounded by cytoplasm, are much more resistant to the action of REs, and again banding patterns were only induced after methanol-acetic acid fixation. We conclude that the action of restriction endonucleases on chromosomes is strongly influenced by chromatin organisation, and that methanol-acetic acid fixation is required to permit the induction of conventional banding patterns on chromosomes.

Characterization of restriction enzyme banding polymorphisms in human chromosomes

C and Re-banding chromosome heteromorphisms were analysed in blood cultures from 43 normal individuals. Restriction enzymes used were AluI, DdeI, HaeIII, and MboI. Chromosome pairs exhibiting heteromorphisms were: 1, 3, 4, 6, 9, 10, 12-16, and 18-22. Each individual showed a specific combination of C- and Re-banding heteromorphisms not shared by any other individual in the series. Some polymorphisms could be detected by all the banding methods used. Others could be detected by some of the banding methods, and in some cases by only one of the banding methods used. The efficiency of each banding method to detect chromosomal polymorphisms depended on the type of polymorphism and the chromosomal pair analysed. Our results indicate that Re-banding polymorphisms occur due to changes in base composition of different fractions of heterochromatin or due to the presence or absence of different heterochromatic subsets. C- and Re-banding are complementary methods that expand the identification of chromosomal markers and which can be used to identify the parental origin of individual chromosomes.

Heterochromatin heterogeneity revealed by restriction endonuclease digestion and subsequent C-banding on bovine metaphase chromosomes

Conventional alkaline C-banding was found to be an effective additional step in restriction endonuclease banding to improve staining contrast and to reveal hidden changes in the heterochromatic blocks. Examples of these cases are demonstrated on the bovine chromosome set using Hinf I and Taq I endonucleases in the digestion experiments.

Karyotype and genome characterization in four cartilaginous fishes

Different approaches can be used to elucidate the unsolved questions concerning taxonomic evolution in cartilaginous fish. The study of the karyological characteristics of these vertebrates by combining molecular and traditional techniques of chromosome preparation and banding has been demonstrated to be a very effective method. In this paper we studied the localization and the composition of the constitutive heterochromatin by using C- and restriction endonuclease-banding in four selachian species, belonging to two of the four superorders. We also characterized two different types of repetitive genomic sequences in these species: satellite DNA and (TTAGGG)(n) telomeric sequences. Finally, we analysed the nuclear ribosomal gene to determine the number of the nucleolar organizers and their position on chromosomes by using silver staining, chromomycin A(3), and FISH (fluorescent in situ hybridization). The results showed a prevailingly telomeric localization of constitutive heterochromatin in the Galeomorphii, the presence of additional nucleolar organizer sites in Raja asterias, an exclusively telomeric localization of the (TTAGGG)(n) sequences in Scyliorhinus stellaris and both telomeric and interstitial in Taeniura lymma. These data, together with those concerning the conservation of the satellite DNA, seem to support the hypothesis that Chondrichthyes have an evolutionary history leading them to the acquisition of large genomes rich in highly repeated sequences and subjected to some selective pressures favoring the conservation of this DNA fraction.

Sau3A in situ digestion of human chromosome 3 pericentromeric heterochromatin. I. Differential digestion of α-satellite and satellite 1 DNA sequences

In situ digestion with the restriction endonuclease (RE) Sau3A (Sau3A REISD) uncovers a polymorphism for the pericentromeric heterochromatin of human chromosome 3, which can be positively stained (3+) or not (3–), and has proven useful to differentiate donor and recipient cells after sex-matched bone marrow transplantation and to analyze the so-called hemopoietic chimerism. The aim of the present investigation was to obtain insight into the molecular basis of such polymorphism to optimize its use for chimerism quantification using methodological approaches other than REISD. To this end, fluorescence in situ hybridization (FISH) assays using probes for the satellite DNA sequences that mainly constitute chromosome 3 pericentromeric heterochromatin (α-satellite and satellite 1 DNA) were performed on control and Sau3A-digested chromosomes. The results obtained suggest that chromosome 3 α-satellite DNA is digested in all individuals studied, irrespective of the karyotype obtained by Sau3A REISD (3++, 3+–, 3--), and thus it does not seem to be involved in the polymorphism uncovered by Sau3A on this chromosome. Satellite 1 DNA is not digested in any case, and shows a polymorphism for its domain size, which correlates with the polymorphism uncovered by Sau3A in such a way that 3+ chromosomes show a large domain (3L) and 3– chromosomes show a small domain (3S). It seems, therefore, that the cause of the polymorphism uncovered by Sau3A on the pericentromeric region of chromosome 3 is a difference in the size of the satellite 1 DNA domain. Small satellite 1 DNA domains fall under the resolution level of REISD technique and are identified as 3–.Key words: heterochromatin, α-satellite DNA, classical satellite DNA, satellite 1 DNA, restriction endonucleases, FISH.

Molecular cytogenetic analysis of heterochromatin in the chromosomes of tilapia, Oreochromis niloticus (Teleostei: Cichlidae)

The structure of the heterochromatic bands in mitotic chromosomes of the important tropical aquaculture species of tilapia, Oreochromis niloticus, was investigated by the combination of the C-banding technique, chromosomal digestion with two restriction endonucleases and fluorescence in situ hybridization (FISH) of two satellite DNAs (SATA and SATB). The tilapia chromosomes presented heterochromatic bands in the centromeres and in the short arms of almost all chromosomes that were differentially digested by the restriction endonucleases HaeIII and EcoRI. FISH of SATA showed that this satellite sequence is distributed in the centromeric region of all chromosomes of tilapia. FISH also revealed an intense hybridization signal for SATB in only one chromosome pair, but less intense signals were also present in several other pairs. The digestion of tilapia chromosomes by HaeIII and EcoRI was positively correlated with the position of SATA and SATB in chromosomes as revealed by FISH. The results obtained may be useful in future molecular and genetic studies of tilapias.

Characterization of the heterochromatic chromosome regions in sheep

In order to elucidate the structural chromosome organization of the heterochromatic regions in sheep, we have used C-banding, silver-staining, sequential CDD technique and restriction endonuclease banding. By these banding techniques we obtained four fractions of repetitive DNA, the autosomal fractions A and B, the C fraction in the X chromosome, and the D fraction in the Y chromosome. Silver staining revealed active nucleolus organizer regions (NOR's) on the telomeric GC-rich areas of chromosomes 1, 2, 3, 4, and 25 which were digested with HaeIII restriction endonuclease.

Cycling-PRINS. A method to improve the accuracy of telomeric sequence detection in mammalian chromosomes

The presence of (TTAGGG)n telomeric sequence was investigated in a Chinese hamster tumor-derived cell line, using single primed in situ labelling (single-PRINS) and multiple cycles of amplification (cycling-PRINS). The telomeric sequence hybridized the centromere of most chromosomes, using both techniques. However, signals visible at the telomeric regions of some chromosomes and an enhancement of the frequency signals at the centromere of chromosome 1 were obtained using cycling-PRINS. These results indicate that cycling-PRINS represents a promising improvement for detection of telomeric sequence in cell lines where the conventional methods failed to demonstrate their presence.

Localization of chromosome breakpoints induced by AluI and BamHI in Chinese hamster ovary cells treated in the G1 phase of the cell cycle

Intact Chinese hamster ovary cells were exposed to the restriction endonucleases (REs) AluI or BamHI. In metaphase spreads from these cells, 300 breakpoints per RE were localized in G-banded chromosome type aberrations (dicentrics, translocations, rings, terminal and interstitial deletions). The majority of breakpoints induced by both REs were localized in G-light bands and showed a similar distribution of breakpoint clusters. RE digestion of metaphase spreads with AluI induced C-banding, and with BamHI G-banding. The data indicate that nuclease sensitive sites associated with active genes are mainly responsible for the distribution of breakpoints.

Differential digestion of the centromeric heterochromatic regions of the 5-azacytidine-decondensed human chromosomes 1, 9, 15, and 16 by NdeII and Sau3AI restriction endonucleases

A study on the factors involved in chromosome digestion by restriction endonuclease was carried out on 5-azacytidine treated and untreated human chromosomes 1, 9, 15 and 16 by using NdeII and Sau3AI isoschizomers. After treatment with 5-azacytidine, chromosomes 1, 9, 15, and 16 showed two differentiated areas at the centromeric regions: the centromere, fully condensed, and the pericentromeric heterochromatin, decondensed. Chromosomes not treated with 5-azacytidine after digestion with Sau3AI and NdeII showed all the centromeric regions undigested, except pair number 1, digested at the pericentromeric area. Digestion of the 5-azacytidine decondensed chromosomes with Sau3AI and NdeII showed the centromeres undigested in the four chromosome pairs while the pericentromeric heterochromatin appeared largely digested. Other factors, different to target distribution, are necessary to explain the pattern of restriction endonuclease digestion observed in this communication.

Molecular analysis of chromosomal polymorphism in the South American cricetid, Graomys griseoflavus

Graomys griseoflavus is a South American phyllotine rodent widespread in Argentina that shows a high frequency of Robertsonian fusions (RFs). DNA restriction with EcoRI produced a 250-bp repeated family (EG250) specific for the genus. Southern hybridization and sequencing analysis indicate that the EG250 family is heterogeneous, comprising at least two subfamilies. In situ hybridized EG250 probe showed a centromere location in almost all chromosomes. In all karyomorphs C-banding was negative, but restriction enzyme banding (Re-banding) with Alul and Mbol showed centromeric blocks in the autosomes that will generate Robertsonian fusions. Thus, we found three groups of chromosomes: (a) EG250 and Re-banding negative; (b) EG250 positive and Re-banding negative; and (c) EG250 and Re-banding positive. We consider that group (b) is more the result of chromatin condensation state than that of the frequency of recognition sites for the enzymes used. Restriction enzyme blocks would appear in regions with heterochromatic EG250 subfamilies, while lack of banding would be due to decondensed EG250 subfamilies becoming an easier target for chromosomal restriction. It is suggested that heterochromatic EG250 DNA provides a favourable molecular environment for Robertsonian fusion occurrence.

Restriction endonuclease/nick translation procedure on fixed chromosomes of the Atlantic salmon fish cell line

We have used a restriction endonuclease/nick translation (RE/NT) procedure to study the ability of restriction enzymes to cleave DNA in fixed chromosomes of a fish cell line. This technique has proved to be very useful in revealing the chromatin heterogeneity underlying the chromosome structure that remains cryptic to other techniques also able to induce longitudinal differentiation on fish chromosomes. The differences observed in the banding patterns after nick translation procedure seem to be due, at least in part, to differences in activity among the enzymes assayed. The results obtained also reveal some evidence about the origin and evolution of the marker chromosomes of the Atlantic salmon cell line.

Heritability and heteromorphic distributions of AluI chromosome banding variants in twins

The heritability and heteromorphic appearance of chromosomal banding patterns induced through in situ digestion with the restriction enzyme AluI were studied by analyzing the chromosomes of 25 monozygotic and 25 dizygotic twin pairs selected at random from a juvenile twin registry. A total of 19 AluI banding variants were found to be heteromorphic, with the pericentromeric region of chromosome 3 and the satellites of chromosome 22 being most and least heteromorphic, respectively. As expected, the correlations of the semi-quantitative scores for each of the chromosomal variants were significantly higher between MZ twin pairs (ranging from 0.48 to 0.95) than DZ twin pairs (ranging from -0.02 to 0.69), suggesting that genetic factors play an important role in their appearance. This finding was confirmed in a model fitting analysis in which the heritabilities of the AluI-induced chromosome variants were found to range from 70 to 96% for 12/13 heteromorphisms studied. These consistent findings are significant in that these variants may be useful for family studies in clinical genetics.

The DNA fragments produced by AluI and BstNI digestion of fixed mouse chromosomes

AluI and BstNI restriction endonucleases were used to study cytological and biochemical effects on centromere DNA in fixed mouse chromosomes. These enzymes were employed, as it is known that AluI is incapable of attacking major satellite DNA, contrary to BstNI that is known to cut this DNA fraction into monomers of 234 bp. After digestion in situ, electrophoretic analysis was carried out to characterize the DNA purified (1) from the material remaining on the chromosomes and (2) from the material solubilized from chromosomes. The DNA was then transferred to a nylon filter and 32P-labelled major satellite DNA was used as a probe for hybridization experiments. Other preparations were simply stained with Giemsa after digestion in situ with AluI and BstNI. Our results show that although restriction endonuclease cleavage primarily depends on DNA base sequence, this factor is not always sufficient to explain nuclease-induced cytological effects. In fact, the structural organization of peculiar regions such as the centromeres of mouse chromosomes might affect cleavage efficiency when restriction enzyme digestion is performed in situ.

Detection of the heteromorphic spectrum of heterochromatin in the human genome by in situ digestion using restriction endonuclease AluI

A battery of selective banding techniques has been utilized to identify the heteromorphic markers in the human genome. The recent addition of the AluI/Giemsa (G)-technique has helped not only in identifying the variable sites, but in characterizing their heteromorphic spectra. In the present investigation, we classified the pericentromeric heterochromatin by the AluI/G-technique by its size and position using 50 normal individuals and suggested the potential uses of this banding technique over earlier methods.

Restriction endonuclease digestion patterns of harvest mice (Reithrodontomys) chromosomes: a comparison to G-bands, C-bands, and in situ hybridization

Constitutive heterochromatin of a karyotypically conserved species of harvest mouse was compared to that of three karyotypically derived species of harvest mice by examining banding patterns produced on metaphase patterns produced by two of these restriction endonucleases (EcoRI and MboI) were compared to published G- and C-banded karyotypes and in situ hybridization of a satellite DNA repeat for these taxa. The third restriction endonuclease (PstI) did not produce a detectable pattern of digestion. For the most part, patterns produced by EcoRI and MboI can be related to C-banded chromosomes and in situ hybridization of satellite DNA sequences. Moreover, digestion with EcoRI reveals bands not apparent with these other techniques, suggesting that restriction endonuclease digestion of metaphase chromosomes may provide additional insight into the structure and organization of metaphase chromosomes. The patterns produced by restriction endonuclease digestion are compatible with the chromosomal evolution of these taxa, documenting that in the highly derived taxa not only are the chromosomes rearranged but the abundance of certain sequences is highly variable. However, technical variation and difficulty in producing consistent results even on a single slide with some restriction endonucleases documents the problems associated with this method.

Cryptic variants of acrocentric human chromosomes as analysed by restriction endonucleases

Ten phenotypically normal human individuals have been analysed by in situ treatments with restriction endonucleases in order to obtain a better characterization of some cryptic variants of acrocentric chromosomes. Treatments with AluI, NdeII and Sau3AI confirm the existence of two cryptic amplified regions on the short arms of both one chromosome 15 and one chromosome 22, in one female. These amplifications seem to be of different origin involving the nucleolar organizer region of chromosome 15 and the satellite of chromosome 22.

Restriction endonuclease/nick translation of fixed mouse chromosomes: a study of factors affecting digestion of chromosomal DNA in situ

We used a restriction endonuclease/nick translation procedure to study the ability of certain enzymes, known to cleave mouse satellite DNA in solution, to attack satellite DNA in fixed mouse chromosomes. Although AvaII and Sau96I readily attack the mouse major satellite in fixed chromosomes, BstNI and EcoRII do not normally do so, although if the heterochromatin is uncondensed as a result of culture in the presence of 5-azacytidine, BstNI can attack it. No clear evidence was obtained for digestion in situ of the minor satellite of mouse chromosomes by MspI, the only enzyme reported to cleave this satellite. Our results show that the DNA of mouse heterochromatin is not merely not extracted by certain restriction enzymes, but is actually not cleaved by them. Chromatin conformation is therefore shown to be an important factor in determining patterns of digestion of chromosomes by restriction endonucleases.

Time-dependent AluI action on human chromosomes

We have analyzed the pattern of AluI digestion over time on human chromosomes in order to monitor the evolution of the in situ enzyme action. Short treatments followed by Giemsa staining produce a G-like banding effect, whereas longer treatments produce a C-like banding pattern. However, when Propidium iodide staining is used, it reveals a uniform bright fluorescence after short AluI digestions and C bands when longer treatments are developed. We propose that C banding is the result of a uniform DNA removal in non centromeric regions taking place after a critical time point, the initial G like banding being produced by changes in the DNA-proteins interactions.

Patterns of digestion of human chromosomes by restriction endonucleases demonstrated by in situ nick translation

A restriction enzyme-nick translation procedure has been developed for localizing sites of restriction endonuclease action on chromosomes. This method involves digestion of fixed chromosome preparations with a restriction enzyme, nick translation with DNA polymerase I in the presence of biotinylated-dUTP, detection of the incorporated biotin label with streptavidinalkaline phosphatase, and finally staining for alkaline phosphatase. Results obtained obtained on human chromosomes using a wide variety of restriction enzymes are described, and compared with results of Giemsa and Feulgen staining after restriction enzyme digestion. Results of nick translation are not in general the opposite of those obtained with Giemsa staining, as might have been expected. Although the nick translation procedure is believed to give a more accurate picture of the distribution of restriction enzyme recognition sites on chromosomes than Giemsa staining, it is clear that the results of the nick translation experiments are affected by accessibility to the enzymes of the chromosomal DNA, as well as by the extractability of the DNA.

Electron microscopy and biochemical analysis of mouse metaphase chromosomes after digestion with restriction endonucleases

Electron microscopy (EM) of whole mounted mouse chromosomes, light microscopy (LM), and agarose gel electrophoresis of DNA were used to investigate the cytological effect on chromosomes of digestion with the restriction endonucleases (REs) AluI, HinfI, HaeIII and HpaII. Treatment with AluI produces C-banding as seen by LM, cuts DNA into small fragments, and reduces the density of centromeres and disperses the chromatin of the arms as determined by EM. Treatment with HinfI produces C-banding, cuts DNA into slightly larger fragments than does AluI and increases the density of centromeres and disperses the fibres in the chromosomal arms. Exposure to HaeIII produces G- + C-banding, cuts the DNA into large fragments, and results in greater density of centromeres and reduced density of arms. Finally HpaII digestion produces G-like bands, cuts the DNA into the largest fragments found and results in greater density of centromeres and the best preservation of chromosomal arms detected by EM. These results provide evidence for: (1) REs producing identical effects in the LM (AluI and HinfI) produce different effects in the EM. (2) All enzymes appear to affect C-bands but while REs such as AluI reduce the density of these regions, other enzymes such as HpaII, HaeIII or HinfI increase their density. Conformational changes in the chromatin could explain this phenomenon. (3) The appearance of chromosomes in the EM is related to the action of REs on isolated DNA. The more the DNA is cut by the enzyme, the greater the alteration of the chromosomal ultrastructure.

Characterization of the heterochromatin in moose (Alces alces) chromosomes

The karyotype of moose (2n = 68) is characterized by very large C-bands close to the centromeres of most chromosomes. The C-banded material represents 40% of the genome. For further characterization of the heterochromatin chromosome spreads were treated with restriction endonucleases and the restriction enzyme (Re) banding pattern was analyzed. HaeIII, AluI, MboI, RsaI and HinfI produced informative Re-bands. DdeI induced an even digestion with no banding. Staining with chromomycin A3 produced bright fluorescence in regions corresponding to C-bands. Labeling with BrdUrd during late S phase differentiates four regions in the C banded area. The sequence of these regions from centromere to telomere are: late, early, late and early replicating. The authors propose the existence of five satellite DNA families with distinctive characteristics of G-C and A-Trichness and different replication timing, and point out the different clusters for the endonucleases detailed above and their varying location in the chromosomes examined.

Differential decondensation of mitotic chromosomes during hypotonic treatment of living cells as a possible cause of G-banding: an ultrastructural study

The chromosomal ultrastructure of Chinese hamster cells treated with 0.075 M KCl - a solution ordinarily used for making preparations of spread chromosomes - was studied. The hypotonic treatment was shown to result in differential decondensation of chromosomes which consists in the uneven distribution of deoxyribonucleoprotein (DNP) fibrils along chromatids. Fixation of cells with methanol acetic acid causes an abrupt restructuring of chromosomes. However, the DNP preserves its uneven distribution along chromatids. As seen on ultra-thin sections of marker nucleolus organizer chromosomes, the densely packed regions may correspond to G-bands detected in the selfsame chromosomes by standard methods of differential staining. The results suggest that the capacity of chromosomes for differential staining is based on the different resistance of G- and R-bands to the decondensing action of hypotonic solutions on living cells.

Evolution of chromosome bands: molecular ecology of noncoding DNA

Giemsa dark bands, G-bands, are a derived chromatin character that evolved along the chromosomes of early chordates. They are facultative heterochromatin reflecting acquisition of a late replication mechanism to repress tissue-specific genes. Subsequently, R-bands, the primitive chromatin state, became directionally GC rich as evidenced by Q-banding of mammalian and avian chromosomes. Contrary to predictions from the neutral mutation theory, noncoding DNA is positionally constrained along the banding pattern with short interspersed repeats in R-bands and long interspersed repeats in G-bands. Chromosomes seem dynamically stable: the banding pattern and gene arrangement along several human and murine autosomes has remained constant for 100 million years, whereas much of the noncoding DNA, especially retroposons, has changed. Several coding sequence attributes and probably mutation rates are determined more by where a gene lives than by what it does. R-band exons in homeotherms but not G-band exons have directionally acquired GC-rich wobble bases and the corresponding codon usage: CpG islands in mammals are specific to R-band exons, exons not facultatively heterochromatinized, and are independent of the tissue expression pattern of the gene. The dynamic organization of noncoding DNA suggests a feedback loop that could influence codon usage and stabilize the chromosome's chromatin pattern: DNA sequences determine affinities of----proteins that together form----a chromatin that modulates----rate constants for DNA modification that determine----DNA sequences. Theories of hierarchical selection and molecular ecology show how selection can act on Darwinian units of noncoding DNA at the genome level thus creating positionally constrained DNA and contributing minimal genetic load at the individual level.

Morphological and biochemical effects of endonucleases on isolated mammalian chromosomes in vitro

Endonuclease digestion of isolated and unfixed mammalian metaphase chromosomes in vitro was examined as a means to study the higher-order regional organization of chromosomes related to banding patterns and the mechanisms of endonuclease-induced banding. Isolated mouse LM cell chromosomes, digested with the restriction enzymes AluI, HaeIII, EcoRI, BstNI, AvaII, or Sau96I, demonstrated reproducible G- and/or C-banding at the cytological level depending on the enzyme and digestion conditions. At the molecular level, specific DNA alterations were induced that correlated with the banding patterns produced. The results indicate that: (1) chromatin extraction is intimately involved in the mechanism of endonuclease-induced chromosome banding. (2) The extracted DNA fragments are variable in size, ranging from 200 bp to more than 4 kb in length. (3) For HaeIII, there appears to be variation in the rate of restriction site cleavage in G- and R-bands; HaeIII sites appear to be more rapidly cleaved in R-bands than in G-bands. (4) AluI and HaeIII ultimately produce banding patterns that reflect regional differences in the distribution of restriction sites along the chromosome. (5) BstNI restriction sites in the satellite DNA of constitutive heterochromatin are not cleaved intrachromosomally, probably reflecting an inaccessibility of the BstNI sites to enzyme due to the condensed nature of this chromatin or specific DNA-protein interactions. This implies that some enzymes may induce banding related to regional differences in the accessibility of restriction sites along the chromosome. (6) Several specific nonhistone protein differences were noted in the extracted and residual chromatin following an AluI digestion.(ABSTRACT TRUNCATED AT 250 WORDS)

Chromosome banding in Amphibia. XII. Restriction endonuclease banding

Fixed metaphase chromosomes of several species of Amphibia were treated with various restriction endonucleases and subsequently stained with Giemsa. Metaphases of man and chicken were examined in parallel under the same experimental conditions for comparison. The restriction enzymes always induce subsets of the C-banding patterns present in the amphibian karyotypes. The heterochromatic regions can be either resistant or sensitive to the restriction enzyme. The modified C-banding patterns revealed by different restriction endonucleases in the karyotype of the same species can be either extremely dissimilar or almost completely congruent. Correspondingly, the action of the same restriction enzyme on the karyotypes of different species may vary greatly. There is only rarely a correlation between the type of C-banding patterns produced by different restriction endonucleases and their specific base pair recognition sequences. In contrast to mammalian and avian chromosomes, restriction enzymes induce no multiple G-banding patterns in amphibian chromosomes. This is attributed to the difference in organization of the DNA in the genomes of poikilothermic vertebrates. The possible mechanisms of restriction endonuclease banding and the various uses of this technique for amphibian chromosomes are discussed.

Restriction endonuclease digestion and chromosome banding in the mosquito, Culiseta longiareolata (Diptera: Culicidae)

Fixed chromosomes of the mosquito, Culiseta longiareolata (2n = 6) were treated in situ with nine restriction endonucleases and stained with ethidium bromide or Giemsa. All the heterochromatic regions were apparently protected from digestion by all enzymes except Mbo I. This enzyme selectively digested one of the three types of heterochromatin present in the species. Staining with the fluorochrome quinacrine after enzyme treatment produced a standard Q-banding pattern or a Hoechst 33258-like pattern, depending on the enzyme. These results confirmed: (a) the presence of three types of heterochromatic containing different DNA fractions in the chromosomes of this species, (b) restriction enzymes accessibility to the DNA of heterochromatin regions, and (c) the selective cleavage of particular DNA fractions without DNA removal. Moreover, quinacrine staining after enzyme digestion proved useful in detecting differential activity among enzymes which produced the same banding pattern with standard dyes.

Restriction endonuclease resistant chromatin in human chromosomes

The recent addition of restriction endonucleases in obtaining selective bands in the human genome has added a new dimension to molecular genetics. However, a considerable discrepancy exists in banding patterns produced by AluI in chromosomes 19 and 20, by MboI in chromosomes 4, 5, 8, 21 and 22 and by RsaI in chromosomes 12, 21 and 22. The principal causes of these differences are highlighted.