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

Hawaiian Drosophila genomes: size variation and evolutionary expansions

This paper reports genome sizes of one Hawaiian Scaptomyza and 16 endemic Hawaiian Drosophila species that include five members of the antopocerus species group, one member of the modified mouthpart group, and ten members of the picture wing clade. Genome size expansions have occurred independently multiple times among Hawaiian Drosophila lineages, and have resulted in an over 2.3-fold range of genome sizes among species, with the largest observed in Drosophila cyrtoloma (1C = 0.41 pg). We find evidence that these repeated genome size expansions were likely driven by the addition of significant amounts of heterochromatin and satellite DNA. For example, our data reveal that the addition of seven heterochromatic chromosome arms to the ancestral haploid karyotype, and a remarkable proportion of ~70 % satellite DNA, account for the greatly expanded size of the D. cyrtoloma genome. Moreover, the genomes of 13/17 Hawaiian picture wing species are composed of substantial proportions (22-70 %) of detectable satellites (all but one of which are AT-rich). Our results suggest that in this tightly knit group of recently evolved species, genomes have expanded, in large part, via evolutionary amplifications of satellite DNA sequences in centric and pericentric domains (especially of the X and dot chromosomes), which have resulted in longer acrocentric chromosomes or metacentrics with an added heterochromatic chromosome arm. We discuss possible evolutionary mechanisms that may have shaped these patterns, including rapid fixation of novel expanded genomes during founder-effect speciation.

Structure analysis of two Toxoplasma gondii and Neospora caninum satellite DNA families and evolution of their common monomeric sequence

A family of repetitive DNA elements of approximately 350 bp-Sat350-that are members of Toxoplasma gondii satellite DNA was further analyzed. Sequence analysis identified at least three distinct repeat types within this family, called types A, B, and C. B repeats were divided into the subtypes B1 and B2. A search for internal repetitions within this family permitted the identification of conserved regions and the design of PCR primers that amplify almost all these repetitive elements. These primers amplified the expected 350-bp repeats and a novel 680-bp repetitive element (Sat680) related to this family. Two additional tandemly repeated high-order structures corresponding to this satellite DNA family were found by searching the Toxoplasma genome database with these sequences. These studies were confirmed by sequence analysis and identified: (1). an arrangement of AB1CB2 350-bp repeats and (2). an arrangement of two 350-bp-like repeats, resulting in a 680-bp monomer. Sequence comparison and phylogenetic analysis indicated that both high-order structures may have originated from the same ancestral 350-bp repeat. PCR amplification, sequence analysis and Southern blot showed that similar high-order structures were also found in the Toxoplasma-sister taxon Neospora caninum. The Toxoplasma genome database (http://ToxoDB.org ) permitted the assembly of a contig harboring Sat350 elements at one end and a long nonrepetitive DNA sequence flanking this satellite DNA. The region bordering the Sat350 repeats contained two differentially expressed sequence-related regions and interstitial telomeric sequences.

Germ line-restricted, highly repeated DNA sequences and their chromosomal localization in a Japanese hagfish (Eptatretus okinoseanus)

The various species of Japanese hagfish, namely, Eptatretus okinoseanus (types A and B), Eptatretus burgeri and Myxine garmani, are known to eliminate a fraction of their chromosomes during early embryogenesis. High molecular weight DNA from germ line cells and somatic cells of these hagfish species was isolated and digested with different restriction enzymes. The DNA fragments were separated by agarose gel electrophoresis. Digestion with BamHI and DraI generated two weak bands and one weak band, respectively, that were estimated to be about 90, and 180 bp and about 90 bp long and were limited to the germ line DNA in both types of E. okinoseanus. DNA filter hybridization experiments showed that the two BamHI fragments and the one DraI fragment were present almost exclusively in the germ line DNA of E. okinoseanus. Thus, these DNA fragments appear to be eliminated during embryogenesis. Moreover, evidence was obtained that these fragments are highly and tandemly repeated. Molecular cloning and sequence analysis revealed that the BamHI fragments are mainly composed of a family of closely related sequences that are 95 bp long (EEEo1, for Eliminated Element of E. okinoseanus 1), and the DraI fragment is composed of another family of closely related sequences that are 85 bp long (EEEo2). The two DNA families account for about 19% of the total eliminated DNA in E. okinoseanus type A. Fluorescence in situ hybridization experiments demonstrated that the two families of DNA are located on several C-band-positive, small chromosomes that are limited to germ cells in both types of E. okinoseanus.

Identical satellite DNA sequences in sibling species of Drosophila

The evolution of simple satellite DNAs was examined by DNA-DNA hybridization of ten Drosophila melanogaster satellite sequences to DNAs of the sibling species, Drosophila simulans and Drosophila erecta. Seven of these repeat types are present in tandem arrays in D. simulans and each of the ten sequences is repeated in D. erecta. In thermal melts, six of the seven satellite sequences in D. simulans and seven of the ten sequences in D. erecta melted within 1 deg.C of the corresponding values in D. melanogaster. The remaining sequences melted within 3 deg.C of the homologous hybrids. Therefore, there is little or no alteration in those satellite sequences held in common, despite a period of about ten million years since the divergence of D. melanogaster and D. simulans from a common ancestor. Simple satellite sequences appear to be more highly conserved than coding regions of the genome, on a per nucleotide basis. Since multiple copies of three satellite sequences could not be detected in D. simulans yet are present in D. erecta, a species more distantly related to D. melanogaster than is D. simulans, these sequences show discontinuities in evolution. There were major quantitative variations between species, showing that satellite DNAs are prone to massive amplification or diminution events over timespans as short as those separating sibling species. In D. melanogaster, these sequences amount to 21% of the genome but only 5% in D. simulans and 0.4% in D. erecta. There was a general trend of lower abundance with evolutionary distance for most satellites, suggesting that the amounts of different satellite sequences do not vary independently during evolution.

Centromeric satellite DNA in the newt Triturus cristatus karelinii and related species: its distribution and transcription on lampbrush chromosomes

Two abundant satellite DNA sequences have been identified in and cloned from the DNA of Triturus cristatus karelinii. The smaller of these with a repeat unit of 33 base pairs (bp) is designated TkS1, the larger with 68 bp is designated TkS2. These satellites are also present in DNA from T.c. cristatus, T.c. carnifex and T. marmoratus but in substantially lower copy number. In situ hybridisations to lampbrush chromosomes of T.c. karelinii and T.c. cristatus have shown that the satellites are concentrated in the heterochromatic centromere bars of T.c. karelinii and in a region around the centromere granule in T.c. cristatus. The satellites also bind specifically to the centromere regions of mitotic metaphase chromosomes. They do not bind to the heteromorphic arms of chromosome 1, which have previously been shown to be rich in highly repeated DNA. DNA/RNA-transcript in situ hybrids to lampbrush chromosomes with TkS1 suggest that this sequence is occasionally transcribed on lampbrush loops near the centromeres.

Y chromosomal DNA of Drosophila hydei

Six recombinant DNA clones are described, which are derived from the Y chromosome of Drosophila hydei. They reveal characteristic features of Y chromosomal DNA sequences. Three of the cloned inserts are Y-specific and are members of the same family of repeated sequences associated with the lampbrush loop-forming fertility gene "nooses" in the short arm of the Y chromosome. The other three cloned sequences are members of three different families of repeated sequences, but display a small amount of homology to one another and to the family of the nooses sequences. These three cloned sequences are found preferentially in the Y chromosome, but also in other chromosomal positions. The Y chromosomal copies are located in the short arm of the Y chromosome. The other copies are found in autosomal kinetochore-associated heterochromatin or, for one of the cloned sequences, in one band of the giant chromosome 4, in addition to the kinetochore heterochromatin.

Satellite DNA of Drosophila nasuta nasuta and D. n. albomicana: localization in polytene and metaphase chromosomes

The DNA from the two Drosophila nasuta races, D. n. nasuta and D. n. albomicana was investigated by CsCl density gradient centrifugation. D. n. nasuta has one major AT-rich satellite DNA sequence with a density of 1.664 g/cm3, while D. n. albomicana has at least three satellites with densities of 1.674 g/cm3, 1.665 g/cm3 and 1.661 g/cm3. The isolated satellite sequences hybridize in situ to all heterochromatic regions of all metaphase chromosomes of both races. In polytene chromosomes the satellite sequences hybridize exclusively to the chromocenter. All chromosomal regions hybridizing with the satellites show also bright quinacrine fluorescence.

Reiteration frequency of procollagen genes in the guinea pig genome. Collagen genes are not amplified during granuloma fibroblasts differentiation

Procollagen mRNA was purified from collagen synthesizing polysomes obtained from an experimental guinea pig granuloma, and iodinated in vitro. The procollagen 125I-labelled mRNA was hibridized with granuloma and liver guinea pig DNA in vast DNA excess conditions. A Cot 1/2 800-900 mol . s . 1-1 for both tissues was obtained from the hybridization curves. With these results, we could suggest the existence of 11-13 procollagen genes per haploid genome. By the analysis of the hybridization data it was possible to infer that there is no genomic amplification in tissues highly specialized in the synthesis of collagen such as granuloma.

The satellite DNAs of Drosophila simulans

The resolution of antibiotic-CsCl gradients enabled an examination of the satellite DNAs in the nuclear DNA of Drosophila simulans. Of the eight distinct satellite DNAs which were detected, four band at almost the same buoyant density in CsCl but can be resolved in netropsin sulphate-CsCl gradients. Each consists of a repeated sequence which, in five of the satellites, is shown to be arranged in tandem for long regions of the chromosomal DNA. One satellite (1·697 g/ml in CsCl) contains repeated sequences interspersed with other sequences. The satellite DNAs were compared with the satellite DNAs known to be present in the sibling species, D. melanogaster. The two species have different overall complements of satellite DNAs, but one satellite (1·672 g/ml) may be identical.

Cytological dissection of sex chromosome heterochromatin of Drosophila hydei

Prophase chromosomes of Drosophila hydei were stained with 0.5 microgram/ml Hoechst 33258 and examined under a fluorescence microscope. While autosomal and X chromosome heterochromatin are homogeneously fluorescent, the entirely heterochromatic Y chromosome exhibits an extremely fine longitudinal differentiation, being subdivided into 18 different regions defined by the degree of fluorescence and the presence of constrictions. Thus high resolution Hoechst banding of prophase chromosomes provides a tool comparable to polytene chromosomes for the cytogenetic analysis of the Y chromosome of D. hydei. - D. hydei heterochromatin was further characterized by Hoechst staining of chromosomes exposed to 5-bromodeoxyuridine for one round of DNA replication. After this treatment the pericentromeric autosomal heterochromatin, the X heterochromatin and the Y chromosome exhibit numerous regions of lateral asymmetry. Moreover, while the heterochromatic short arms of the major autosomes show simple lateral asymmetry, the X and the Y heterochromatin exhibit complex patterns of contralateral asymmetry. These observations, coupled with the data on the molecular content of D. hydei heterochromatin, give some insight into the chromosomal organization of highly and moderately repetitive heterochromatic DNA.

Non-random position of the A-T rich DNA sequences in early embryos of Drosophila virilis

Examination of early embryos of Drosophila virilis by light and electron microscopy has shown that the A-T rich satellite DNA sequences have a non-random distribution within the nuclei. As observed by 33258 Hoechst staining and fluorescent microscopy, these sequences are consistently found to be located on the sides of the nuclei nearest to the vitelline membrane. This arrangement of the A-T rich sequences has been observed from the syncytial balstoderm stage into the gastrula stage where, in each nucleus, the satellite DNA sequences remain at a point nearest the topological outside of the organism.

Spermatogenesis in Sciara coprophila. I. Chromosome orientation on the monopolar spindle of meiosis I

Meiosis I of spermatogenesis in the fungus fly, Sciara coprophila, has a monopolar spindle which collects the maternal and supernumerary L chromosome sets, while the paternal chromosomes migrate away from the single pole to be excluded in a bud. By inspection, the metacentric paternal chromosome IV moves with its centromere lagging rather than leading the direction of motion. Therefore, we wondered if all paternal homologues move in such a reverse orientation. To determine the orientation of the other homologues which are acrocentrics (chromosomes II, III, X), their centromeres were localized by use of the DAPI C-bonding technique. In addition, we characterized centromeric heterochromatin on polytene chromosomes by C-banding and in situ hybridization of satellite DNA isolated by Ag+-Cs2SO4 (rho CsC1 satellite I=1.698 g/ml; rho CsC1 satellite II=1.705 g/ml). The two satellite fractions were localized to the centromeric heterochromatin of all the chromosomes, and to a varying degree to all chromosome telomeres. By DAPI C-banding we could precisely locate each centromere band on polytene chromosomes, and these results agreed with those of satellite cRNA in situ hybridization. We then applied the DAPI C-banding technique to primary spermatocyte preparations, and determined that all paternal chromosomes migrate at anaphase I with their centromeres lagging rather than leading movement to the cell periphery. Since in polytene chromosomes the X chromosome contains a moderately fluorescent band on its noncentromeric end as well, in order to clarify its DAPI C-banding result in primary spermatocytes, we did in situ hybridization of (3)H nick-translated cloned rDNA, since rDNA is a convenient marker for the centromeric heterochromatin of the X. These data and the DAPI C-banding results indicate that the X as well as all th other paternal homologues display a reverse orientation (centromeres lag) as they migrate away from the single spindle pole to the cell periphery. - One model explaining this unusual paternal chromosome orientation is that there may be unique neocentromeric-like attachments to the non-centromeric free ends of these chromosomes. These attachments could serve to pull the paternal chromosomes to the cellular periphery as anaphase I progresses. In order to test this model, we analyzed anaphase I spermatocytes after a terminal block of heterochromatin had been removed from metacentric paternal chromosome IV by X-irradiation. We observed that when metacentric paternal chromosome IV is broken, it maintains its inverted "V" orientation rather than assuming a rod-like configuration. These data imply that there are no unique, terminal neocentromeric attachments to paternal chromosome IV as it progresses to the cellular periphery.

Localization of nucleoli in Drosophila melanogaster polytene chromosomes

The majority of D. melanogaster salivary gland nuclei contains many nucleoli which vary in size and number. All nucleoli hybridize in situ with a cloned Drosophila DNA fragment containing 26S ribosomal gene. Autoradiographic analysis of preparations after pulse H3-uridine or H3-thymidine labelling of the salivary gland indicates an intensive transcription and replication of DNA within nucleoli. The nucleoli are bound to different sites of polytene chromosomes by chromatin fibers similar to strands of ectopic pairing and they are most often bound to regions which may be defined as intercalary heterochromatin.

Absorption spectrum of Feulgen-stained polytene chromosomes of Drosophila melanogaster

Hetero- and euchromatic polytene chromosome regions of early and fully grown larvae of Drosophila melanogaster had their Feulgen absorption curves determined cytophotometrically. Hydrolysis conditions adequate to induce maximal DNA depurination were used. No differences in curve shapes specially concerning the absorption shoulder at the 520 less than or equal to lambda less than or equal to 550 nm spectral range were detected with advancing polytenization or when comparing the absorption patterns for the hetero- and euchromatic regions to each other. It is considered that prominence of the Feulgen absorption shoulder could be related to the amount of Schiff molecules di-substituted with apurinic acid aldehydes and to the relatively larger resistance of these apurinic acid fragments towards solubilization with acid hydrolysis due to their binding to nuclear proteins. It is therefore assumed that no significant differences owing to the above-cited factors exist for the chromosome regions analyzed at 2 phases of the polytenization process. Consequently, the replication of reiterated sequences from the main band DNA which occurs in polytene chromosome regions of Drosophila melanogaster appears not to affect the Feulgen absorption spectrum of this material.

Fluorescence patterns of heterochromatin in mitotic and polytene chromosomes in seven members of three sub-groups of the melanogaster species group of Drosophila

A comparative study of fluorescence patterns of heterochromatin in mitotic and polytene chromosomes of seven species belonging to 3 subgroups (melanogaster sub-group: D. melanogaster and D. simulans; montium sub-group: D. kikkawai and D. jambulina; ananassae sub-group: D. ananassae. D. malerkotliana and D. bipectinata) of the melanogaster species group of Drosophila (Sophophora) has been made. Hoechst 33258 (H) fluorescence patterns of mitotic chromosomes reveal differences correlated to the taxonomic groupings of these species. The melanogaster sub-group species have H-bright regions on heterochromatin of all chromosomes; the montium subgroup species have H-bright regions mainly on the 4th and Y-chromosomes; in the ananassae sub-group, while D. ananassae chromosomes do not show any H-bright regions. D. malerkotliana and D. bipectinata have small H-bright segments only on their 4th chromosomes. The H- and quinacrine mustard (QM) fluorescence patterns of larval salivary gland polytene chromocentre in these species, however, do not show the same taxonomic correlation. While D. ananassae and D. kikkawai polytene nuclei lack any H- or QM-bright region in the chromocentre, the remaining species have prominent H- and/or QM-bright region(s). In D. jambulina, the QM-bright regions are generally bigger than H-bright regions, while in D. malerkotliana and D. bipectinata the situation is reversed. Actinomycin D counterstaining prior to H-staining of polytene preparations of each species confirms that the H-bright region/s in the chromocentre are composed of A-T rich sequences. In vivo labelling of salivary gland polytene nuclei with 5-bromo-deoxyuridine for 24 to 48 h and subsequent H-staining reveals that in all the species, the H-bright regions do not replicate in 3rd instar stage and presumably represent the non-replicating alpha heterochromatin. Significantly, in all the species (excepting D. kikkawai and D. ananassae), the size, location and the number of H- and/or QM-bright regions were seen to vary in different polytene nuclei in the same gland. It seems that the organization and the extent of under-replication of alpha heterochromatin varies in different polytene nuclei. Present studies also show that even closely related species differ in the content and organization of H-bright heterochromatin. The 81F band at the base of 3R in D. melanogaster, but not in D. simulans, appears to contain non-replicating H-bright sequences in addition to replicating chromatin.

Contrasting response of euchromatin and heterochromatin to translocation in polytene chromosomes of Drosophila melanogaster

Studies on Feulgen-DNA content in the polytene chromosomes of D. melanogaster T(1:4)wm258-21 heterozygotes showed that when the euchromatic region 3D1-E2 is located next to the heterochromatic breakpoint it contains less DNA than in the non-translocated homologue (Hartmann-Goldstein and Cowell, 1976). In contrast to the region adjacent to the breakpoint, region 3C1-10, which contains intercalary heterochromatin, shows more DNA in the translocated than in the non-translocated chromosome. Transposition may induce morphologically euchromatic regions containing putatively underreplicated sequences to undergo additional replication cycles. Region 2E1-3A4, distal to 3C1 and at some distance from the heterochromatic breakpoint is apparently unaffected. Extended replication and reduced DNA content in regions which have undergone chromosomal rearrangement could be accounted for by varying degrees of blockage of replication in individual strands of the polytene chromosome.

Localization of satellite DNAs in the chromosomes of the guinea pig

The in situ hybridization method has been used to investigate the localization of each of the three satellite DNAs present in the genome of the guinea pig. Purified fractions of the satellite DNAs were utilized as templates for synthesis of 3H-labeled complementary RNA (cRNA) by E. coli RNA polymerase, then each cRNA was hybridized to metaphase spreads of embryonic guinea pig cells. The cRNAs of all three satellite DNAs hybridized predominantly to the centromeric region of the chromosomes. The cRNAs of satellite DNAs II and III hybridized to all chromosomes except the Y chromosome. The cRNA of satellite DNA I did not hybridize to the Y chromosome nor to two pairs of small acrocentric chromosomes. Satellite II cRNA hybridized to the telomeric region of chromosomes 3 and 4.

Detection and location of three simple sequence DNAs in polytene chromosomes from virilis group species of Drosophila

In vitro synthesized RNAs complementary to the three satellite DNAs of Drosophila virilis have been used in a series of in situ hybridization experiments with polytene chromosomes from virilis group species. Gall and Atherton (1974) demonstrated that each of the satellites of D. virilis is comprised of many repeats of a distinct, seven base pair long, simple sequence. With few exceptions, copies of each of these simple sequences are detected in the chromocenters of all virilis group species. This is true even in species which do not possess satellite DNAs at buoyant densities corresponding to those of the satellite DNAs of D. virilis. Small quantities of the three simple sequences are also detected in euchromatic arms of several different species. The same euchromatic location may contain detectable copies of one, two, or all three simple sequence DNAs. The amounts of simple sequences at each location in the euchromatin may vary between species, between different stocks of the same species, and even between individuals of the same stock. The simple sequences located in the euchromatin appear to undergo DNA replication during formation of polytene chromosomes unlike those in heterochromatin. The locations of the euchromatic sequences are not the results of single chromosomal inversion events involving heterochromatic and euchromatic breakpoints.

Distribution of repetitive DNA sequences in the polytene chromosomes of Rhynchosciara americana

The distribution of fast, intermediate and slow renaturing fractions of Rhynchosciara americana DNA was examined in the polytene salivary gland chromosomes by in situ hybridization. Heterochromatic areas readily hybridized but hybrid formation in the euchromatin depended more on the repetitiveness of the RNA probe.

Reiterated genes with varying location in intercalary heterochromatin regions of Drosophila melanogaster polytene chromosomes

The localization of two cloned D. melanogaster DNA fragments in polytene chromosomes was determined by means of in situ hybridization. These different fragments (Dm 225 and Dm 234B) are present in the genome in hundreds copies and contain genes whose transcription yields two different classes in abundant mRNA (Ilyin et al., 1976, 1977; Tchurikov et al., 1978). About 20--30 sites of these genes are demonstrable in the polytene chromosomes of a given stock. There are small but significant variations in the number and localization of these sites among individuals of the same stock. On the other hand, different stocks of D. melanogaster have an utterly different distribution of revealed hybridization sites in the polytene chromosomes. The location of both fragments (Dm 225 and Dm 234) was found to be virtually identical within any given stock of D. melanogaster. 69 sites for localization of Dm 225 or Dm 234 genes were detected in the chromosomes of 11 individuals studied. At least 50 (and up to 62) of them coincide with intercalary heterochromatin regions which are known to be characterized by ectopic pairing, late replication and the presence of "weak spots" in the chromosome. The ability of Dm225 and Dm 234 to code for the "abundant" classes of messenger RNA (Ilyin et al., 1976) and the fact that their location may coincide with the histone and ribosomal genes suggest that intercalary heterochromatin regions are "nests" containing various types of actively transcribable tandem-repeated genes coding for common "household" cell functions.

Localization of Drosophila nasutoides satellite DNAs in metaphase chromosomes

Metaphase chromosomes of D. nasutoides were hybridized in situ with 3H-cRNA synthesized from the four satellites which make up 50--60% of the total DNA of this species. All four satellites were localized in the large, metacentric, heterochromatic chromosome four. They did not, however, appear to hybridize to centromeric or other constitutive heterochromatin, nor did they, with the exception of satellite I, seem to hybridize in the specific regions of chromosome four which, on the basis of C, Q, and H banding and AT contents, were predicted to contain some of these satellites.--Comparison of grain patterns with the results of fluorescent staining indicated that satellite-bearing heterochromatin was not always associated with other fractions of constitutive heterochromatin in interphase nuclei and was, at least partially, decondensed in some larger nuclei.

Heat-shock DNA homology in distantly related species of Drosophila

Polytene chromosomes of D. melanogaster and D. virilis were hybridized in situ with 125I labeled mRNA isolated from polysomes of D. melanogaster tissue culture cells incubated at 37 degrees C. 125I mRNA hybridized preferentially with subdivisions 87A and 87Cl of the D. melanogaster 3R chromosome; grains were also observed at regions 93D, 95D and over the chromocenter. A considerable cross hybridization of this mRNA with D. virilis polytene chromosomes was observed. The 29C region of the D. virilis second chromosome was the main site of hybridization. Significant grain numbers also appeared in region 20F of the same chromosome. The two regions mentioned belong to heat shock loci in the latter species. Based on label intensity we conclude that region 29C of D. virilis contains DNA sequences retaining molecular homology with those at subdivisions 87A and 87Cl of D. melanogaster. SDS-polyacrylamide gel electrophoresis revealed similar distributions of heat shock proteins in the two species studied.

Genetic studies on heterochromatin in Drosophila melanogaster and their implications for the functions of satellite DNA

In Drosophila melanogaster the centromeric heterochromatin of all chromosomes consists almost entirely of several different satellite DNA sequences. In view of this we have examined by genetic means the meiotic consequences of X chromosomes with partial deletions of their heterochromatin, and have found that the amount and position of recombination on each heterochromatically deleted X is substantially different from that of a normal X. It appears that the amount of heterochromatin is important in modifying the "centromere effect" on recombination.--In all the deleted Xs tested, chromosome segregation is not appreciably altered from that of a nondeleted control chromosome. Thus satellite DNA does not appear to be an important factor in determining the regular segregation of sex chromosomes in Drosophila. Additionally, since X chromosomes with massive satellite DNA deficiencies are able to participate in a chromocenter within salivary gland nuclei, a major role of satellite DNA in chromocenter formation in this tissue is also quite unlikely.--In order to examine the mechanisms by which the amount of satellite DNA is increased or decreased in vivo, we have measured cytologically the frequency of spontaneous sister chromatid exchanges in a ring Y chromosome which is entirely heterochromatic and consists almost exclusively of satellite DNA. In larval neuroblast cells the frequency of spontaneous SCE in this Y is approximately 0.3% per cell division. Since there is no meiotic recombination in D. melanogaster males and since meiotic recombination in the female does not occur in heterochromatin, our results provide a minimum estimate of the in vivo frequency of SCE in C-banded heterochromatin (which is predominantly simple sequence DNA), without the usual complications of substituted base analogs, incorporated radioactive label or substantial genetic content.--We emphasise that: (a) satellite DNA is not implicated in any major way in recognition processes such as meiotic homologue recognition or chromocenter formation in salivaries, (b) there is likely to be continuous variation in the amount of satellite DNA between individuals of a species; and (c) the amount of satellite DNA can have a crucial functional role in the meiotic recombination system.

The distribution of sequences complementary to human satellite DNAs I, II and IV in the chromosomes of chimpanzee (Pan troglodytes), gorilla (Gorilla gorilla) and orang utan (Pongo pygmaeus)

Human satellite DNAs I, II and IV were transcribed to yield radioactive complementary RNAs (cRNAs). These cRNAs were hybridised to metaphase chromosomes of man, chimpanzee (Pan troglodytes), gorilla (Gorilla gorilla) and orang utan (Pongo pygmaeus). The results of this in situ hybridisation were analysed quantitatively and compared with accepted chromosome homologies based on Giemsa banding patterns. The cRNA to satellite II (cRNAII) did not hybridise to chimpanzee chromosomes, although its hybridisation to chromosomes of gorilla and orang utan yielded more autoradiograph grains than hybridisation to human chromosomes, and cRNAIV hybridised to many chromosomes of gorilla and chimpanzee but was almost entirely restricted to the Y chromosome in orang utan. Most sites of hybridisation were located on homologous chromosomes in all four species, but there were a number of sites which showed no correspondence between satellite DNA location and chromosome banding patterns, and others where a given chromosomal location hybridised with different cRNAs in each species. These results are in contrast to those found for many transcribed DNA sequences, where the same sequence is usually located at homologous chromosome sites in different species, and appear to cast doubt on many proposed models of satellite DNA function.

Evolution of Drosophila mitochondrial DNAs. Comparison of denaturation maps

In an approach to the functional anatomy of the mitochondrial genome and its evolution, we have compared buoyant densities, contour lengths, and denaturation maps in circular mitochondrial DNAs of the genus Drosophila. Mitochondrial DNAs from three representatives of the subgenus Drosophila (D. virilis, D. hydei, D. funebris) are similar in size (approx. 5 mum or 1 - 10(7) daltons) and buoyant density (approx. 1.685 g/ml), while in two members of the subgenus Sophophora (D. melanogaster, D. simulans), mitochondrial DNAs are longer (approx. 6 mum or 12.4 - 10(6) daltons) and have a lower buoyant density (approx. 1.681 g/ml). The latter mitochondrial DNAs also share one distinctly large early melting region, which in D. melanogaster is equivalent to 1.54 mum of native DNA. The corresponding (A + T)-rich region in D. virilis or D. hydei mitochondrial DNA is 1 mum shorter. Except for this region, denaturation maps of D. melanogaster and D. virilis mitochondrial DNAs are indistinguishable. The addition or deletion of a single block of (A + T)-rich sequences can fully account for the differences in buoyant density and size between the mitochondrial DNAs we have examined. In an appendix, we show that there is an equivalent discrepancy between the extent of strand separation determined by electron by electron microscopy and the actual extent of DNA denaturation, whether this is determined from absorbance changes or inferred from the reduction in contour lengths of individual circular molecules. The reduction in contour length appears to result exclusively from the uniform foreshortening of single-stranded DNA, not only in regions of visible strand separation but also in denatured regions hidden within putatively native segments of molecules. For molecules showing 15--45% strand separation, we estimate that putatively native segments are approximately 50% denatured.

Characterization of Drosophila heterochromatin. I. Staining and decondensation with Hoechst 33258 and quinacrine

A number of preliminary experiments have shown that the fluorescence pattern of Hoechst 33258, as opposed to that of quinacrine, varies with the concentration of dye. The metaphase chromosomes of D. melanogaster, D. simulans, D. virilis, D. texana, D. hydei and D. ezoana have therefore been stained with two concentrations of H 33258 (0.05 and 0.5 mug/ml in phosphate buffer at pH 7) and with a single concentration of quinacrine (0.5% in absolute alcohol). The three fluorescence patterns so obtained were shown to be somewhat different in some of the species and the coincide in others. All three stainings gave an excellent longitudinal differentiation of heterochromatin while euchromatin fluoresced homogeneously. Living ganglion cells of the six species mentioned above were treated with quinacrine and H 33258. Quinacrine induced a generalized lengthening and swelling of the chromosomes and H 33258 the decondensation of specific heterochromatic regions. A correlation of the base composition of the satellite DNAs contained in the heterochromatin of the species studied with the relative fluorescence and decondensation patterns showed that: 1) the extremely fluorochrome bright areas and those decondensed are present only in species containing AT rich satellite DNA; 2) the opposite is not true since some AT-rich satellite DNAs are neither fluorochrome bright nor decondensed; 3) there is no good correspondence between Hoechst bright areas and the decondensed ones. AT richness therefore appears to be a necessary but not sufficient condition both for bright fluorescence and decondensation. Some cytological evidence suggests that similarly AT rich satellite DNAs respond differently in fluorescence and decondensation because they are bound to different chromosomal proteins. A combination of the results of fluorescence and decondensation revealed at least 14 types of heterochromatin; 4-7 of which are simultaneously present in the same species. Since closely related species (i.e. D. melanogaster and D. simulans; D. virilis and D. texana) show marked differences in the heterochromatic types they contain, it can be suggested that within the genus Drosophila qualitative variations of heterochromatin have played an important role in speciation.

Satellite DNA in the kangaroo Macropus rufogriseus

Two distinct satellite DNAs, amounting to 25% of the total DNA, were isolated from the nuclei of the red-necked wallaby, Macropus rufogriseus. The physical properties of native, single-stranded and reassociated molecules were studied in buoyant-density gradient centrifugation. The homogeneity of each satellite fraction was examined using melting characteristics of native and reassociated DNA, and renaturation kinetics. These data suggest that sequence heterogeneity exists in both fractions. Each satellite fraction was found by in situ hybridization to be localized in heterochromatin of interphase nuclei and in the centromeric regions of metaphase chromosomes. The chromosomal distributions of the two satellite DNAs differentiate the sex chromosomes, which have sequences of only one satellite, from the autosomes which have sequences of both satellites in the centromeric heterochromatin. Giemsa C-banding techniques also showed a differentiation of the centromeric regions of sex chromosomes from those of the autosomes.

Ectopic pairing and evolution of 5S ribosomal RNA genes in the chromosomes of Drosophila funebris

5S ribosomal RNA from Drosophila melanogaster labeled with 125I was used to locate the 5S rRNA genes in chromosomes of D. funebris by means of in situ hybridization. Silver grains were observed at three distinct sites, one of which was a recognized reverse repeat. Only one half of the reverse repeat, however, hybridizes with 5S rRNA and the significance of this phenomenon is discussed. A case of ectopic pairing between two different 5S sites in the genome is reported, and the significance of ectopic pairing is considered.

The appearance of new structures and functions in proteins during evolution

The likelihood of a de novo generation of classes of efficient proteins through neoformation of DNA, through modification of expressed DNA, and through modification of nonexpressed DNA is examined. So is the likelihood that newly formed inefficient enzymes be turned into efficient enzymes. The conclusions are that neither gene duplicates nor dormant genes represent promising materials for a de novo generation of protein classes, that (with exceptions) such generation is unlikely to have taken place in recent evolution, that new structural genes must nearly consistently derive from preexisting structural genes, and that new functions can be evolved only on the basis of old proteins. Conditions of protein evolution in prokaryotes suggest that the saltatory formation of protein classes is as unlikely in prokaryotes as in eukaryotes. Data on the history of a few protein classes are reviewed to illustrate the preceding inferences. The analysis leads to the hypothesis that most protein classes originated before the major elements of the translation apparatus of modern cells were fully evolved. If simple sequence DNA is turned into structural genes by evolution, this process (again with exceptions) is considered to have taken place only at that very remote period. A polyphyletic origin of proteins is thought to date back to the same era. It is proposed that the development of genic multiplicity and of marked structural and functional diversity of proteins may have come about in the earliest cells primarily through the independent generation of structurally different polymerases in different protocells, followed by cell conjugation and the subsequent use by enriched cells of supernumerary types of polymerase for evolving further functions. Functional growth, as it took place at early times, is briefly discussed as well as functional change. The foundations for new functional developments in old proteins are analyzed. In considering the evolutionary recovery of lost functions, aspects of cell differentiation and gene regulation are linked with the evolutionary picture. The distinction between eurygenic and stemogenic control of gene activity is used. Next to gene deletion, cell and tissue deletion is held to be an event of general evolutionary significance, through cell and tissue origination that presumably accompanies the restoration of a lost molecular function.