Chromosomal evolution inCallithrix emiliae

We studied the karyotype of specimens ofCallithrix emiliae (Callithricidae, Primates) from Rondonia, Brazil. Comparison with the karyotype ofCallithrix jacchus showed that, even though these two species show many karyotypic similarities, they differ by a Robertsonian translocation, a paracentric inversion and large-scale addition of heterochromatin. TheC. emiliae species appears to be in an active phase of chromosome evolution by the addition of constitutive heterochromatin.     

Intraspecific polymorphism of sex chromosome heterochromatin in two species of the Anopheles gambiae complex

The Hoechst 33258 banding pattern of the mitotic chromosomes of several laboratory and natural populations of the sibling species A. gambiae and A. arabiensis has been analyzed. A clear intraspecific polymorphism of sex chromosome heterochromatin has been observed. Nevertheless in each species heterochromatic variations fall within a characteristic species-specific pattern. Moreover, while laboratory populations tend to be monomorphic for a given heterochromatic variant, natural populations exhibit a high degree of intrapopulation polymorphism. The possible role of sex chromosome heterochromatin in controlling fertility and mating behaviour of Anopheles mosquitoes is discussed.     

Chromosome plasticity in Ctenomys (Rodentia Octodontidae): chromosome 1 evolution and heterochromatin variation

A chromosome 1 (Cr1) pericentric inversion is described in six of seven species in the genus Ctenomys (tuco-tucos) from Uruguay. The inversion was inferred from G-band analyses of subtelocentric Cr1 hypothesised to be derived from the ancestral metacentric condition. Cr1 varies across species in heterochromatin amount and localisation including a metacentric chromosome without positive C-bands in C. torquatus, a subtelocentric chromosome with heterochromatic short arms in C. rionegrensis, and a subtelocentric chromosome negative after C-banding in five of the species analysed here. Pachytene chromosomes from C. rionegrensis, a species with the highest heterochromatin content, and C. torquatus, one of the species with the lowest heterochromatin content, were analysed in order to assess possible mechanisms of heterochromatin evolution. This analysis revealed the presence of three heterochromatic chromocenters in C. rionegrensis where bivalents converge, while in C. torquatus only one chromocenter was observed. In both species, highly repetitive DNA was observed, localised in chromocenters after “in situ” hybridisation. Heterochromatin associated protein M31 was localised in chromocenters of both species after immuno-detection. The spread of heterochromatin in Ctenomys chromosomes could be produced by chromatin exchanges at the chromocenter level. We propose the exchange of this DNA associated proteins between non-homologous chromosomes in pachytene to be the responsible for the spread of heterochromatin through the karyotypes of species like C. rionegrensis     

Studies of He-T DNA sequences in the pericentric regions of Drosophila chromosomes

He-T DNA is a complex set of repeated DNA sequences with sharply defined locations in the polytene chromosomes of Drosophila melanogaster. He-T sequences are found only in the chromocenter and in the terminal (telomere) band on each chromosome arm. Both of these regions appear to be heterochromatic and He-T sequences are never detected in the euchromatic arms of the chromosomes (Young et al. 1983). In the study reported here, in situ hybridization to metaphase chromosomes was used to study the association of He-T DNA with heterochromatic regions that are under-replicated in polytene chromosomes. Although the metaphase Y chromosome appears to be uniformly heterochromatic, He-T DNA hybridization is concentrated in the pericentric region of both normal and deleted Y chromosomes. He-T DNA hybridization is also concentrated in the pericentric regions of the autosomes. Much lower levels of He-T sequences were found in pericentric regions of normal X chromosomes; however compound X chromosomes, constructed by exchanges involving Y chromosomes, had large amounts of He-T DNA, presumably residual Y sequences. The apparent co-localization of He-T sequences with satellite DNAs in pericentric heterochromatin of metaphase chromosomes contrasts with the segregation of satellite DNA to alpha heterochromatin while He-T sequences hybridize to beta heterochromatin in polytene nuclei. This comparison suggests that satellite sequences do not exist as a single block within each chromosome but have interspersed regions of other sequences, including He-T DNA. If this is so, we assume that the satellite DNA blocks must associate during polytenization, leaving the interspersed sequences looped out to form beta heterochromatin. DNA from D. melanogaster has many restriction fragments with homology to He-T sequences. Some of these fragments are found only on the Y. Two of the repeated He-T family restriction fragments are found entirely on the short arm of the Y, predominantly in the pericentric region. Under conditions of moderate stringency, a subset of He-T DNA sequences cross-hybridizes with DNA from D. simulans and D. miranda. In each species, a large fraction of the cross-hybridizing sequences is on the Y chromosome.     

Cold-sensitive chromosome regions and heterochromatin inCestrum (Solanaceae):C. strigillatum,C. fasciculatum,andC. elegans

Cold-induced mitotic under-condensation of certain chromosome segments is a rare phenomenon in plants. There are about 11 genera of monocotyledons and only 3 of dicotyledons, where species are known to have such cold-sensitive regions (CSRs). The molecular causes of cold-induced undercondensation are not clear, and no consistent cytochemical characteristics of CSRs are known. Recently we have presented a chromosome banding analysis on CSRs and their relation to constitutive heterochromatin inCestrum parqui (Solanaceae), a species of sect.Cestrum. The present study is concerned with a similar analysis inC. strigillatum of sect.Cestrum, and inC. fasciculatum andC. elegans of sect.Habrothamnus. Chromomycin/DAPI fluorescent double staining, sequential C-banding, and sequential silver impregnation were applied. The species differ in detail but are similar qualitatively. Four classes of heterochromatin can be discriminated. (1) CSRs, with banding properties indicating AT-rich constitutive heterochromatin. After cold-treatment CSR heterochromatin can be silver-impregnated from interphase, as chromocentres, to metaphase, as undercondensed segments. CSRs are subject to frequent heteromorphy. (2) Nucleolar organizers. Two pairs were identified in the karyotypes. Banding properties indicate GC-rich heterochromatin. The nucleolar organizing regions are less evident and their silver-reducing capability reduces during metaphase. (3) Non-nucleolar CMA-positively fluorescing bands. These are minute, polymorphic, positively C-stained, and restricted to one or a few sites in the karyotypes. (4) Indifferently fluorescing, positively C-stained bands. They occur on centromeres, some chromosome ends, and clustered over the chromosome arms. They are mostly very delicate and do not resist harsh banding treatments. — The species investigated here andC. parqui resemble each other qualitatively in heterochromatin classes (1), (2), and (3), but differ much in banding properties of class (4). Therefore, heterochromatin characteristics in the genus are not so uniform as the present results inC. strigillatum, C. fasciculatum, andC. elegans appear to show.     

Relative DNA content of somatic nuclei and chromosomal studies in three genera,Tilapia, Sarotherodon,andOreochromis of the tribe Tilapiini (Pisces,Cichlidae)

Seven Tilapiine species from three generaTilapia, Sarotherodon, andOreochromis were cytogenetically studied for chromosome number, chromosome morphology, and DNA content. The chromosome number 2n=44 was the same in all seven species. Arm number (NF) differences indicate the possible role of pericentric invasions in the karyotypic evolution of these species. C-banding of metaphase chromosomes shows that heterochromatin is localised around the centromere in all species ofOreochromis and Sarotherodon butT. zillii has more heterochromatin with six chromosomes having completely C-positive short arms. DNA values vary between 0.84 pq forO. macrochir and 1.21 pq forO. aureus. No heteromorphic sex chromosome pair could be found in any species. These findings suggest that karyotypic evolution has occurred but does not appear to be associated with speciation in this group.     

Hoechst 33258 banding of Drosophila nasutoides metaphase chromosomes

Hoechst 33258 banding of D. nasutoides metaphase chromosomes is described and compared with Q and C bands. The C band positive regions of the euchromatic autosomes, the X and the Y fluoresce brightly, as is typical of Drosophila and other species. The fluorescence pattern of the large heterochromatic chromosome is atypical, however. Contrary to the observations on other species, the C negative bands of the large heterochromatic chromosome are brightly fluorescent with both Hoechst 33258 and quinacrine. Based on differences in the various banding patterns, four classes of heterochromatin are described in the large heterochromatic chromosome and it is suggested that each class may correspond to an AT-rich DNA satellite.     

Chromosome evolution in Australian rodents

The chromosome complements of 188 specimens of 29 species of Australian murid rodents belonging to the subfamilies Pseudomyinae and Hydromyinae and the Uromys/Melomys group have been compared. At least one specimen of 18 different species was successfully C-banded. — The autosomal complements of many (9) diverse Pseudomyinae, one species of Melomys and one Hydromyinae proved to be identical, comprising 48 elements in the diploid set, the two smallest autosomal pairs of which are metacentric. No other karyotype is common to more than one species. From this we conclude that these three groups have been derived from a common ancestor which also possessed such a karyotype. The genus Zyzomys is exceptional since it possesses only 44 elements and lacks the two smallest metacentrics. — Karyotypic evolution within this apparently single phyletic line has been remarkably conservative, only three rearrangements being required to derive the most divergent karyotype. Moreover most of the observed rearrangements involve pericentric inversions and only one example of a fusion was found. Considerable differences in heterochromatin content, as determined by C-banding, occur between species however. Two species proved exceptional in this respect, namely Notomys cervinus and Uromys caudimaculatus. N. cervinus possesses numerous heterochromatic short arms. In U. caudimaculatus, there is a striking difference between northern and southern populations; in the former heterochromatin is present principally in the telomeric areas of the conventional A-chromosomes whereas in the latter it is found as separate supernumerary chromosomes. — In contrast to the autosomes, the X and Y chromosomes show high inter- and intra-specific variability in both size and morphology. All of this variability can be explained in terms of variation in heterochromatin content. Moreover the amount of heterochromatin in the X and Y chromosomes is highly correlated both within and between species. The Y chromosome of Uromys caudimaculatus is, however, distinctive in that it lacks C-banding.     

Heterochromatin and chromosome variation in cultivated species ofTulipa subg.Leiostemones (Liliaceae)

The chromosomes of several cultivatedTulipa species of subg.Leiostemones were examined in conventionally stained and C-banded preparations. The heterochromatin content varied from almost none to 45%. Several chromosome types were recognized with respect to chromosome morphology and heterochromatin distribution, and groups of species with common chromosome characteristics could be identified. These karyological relationships are discussed with respect to the groups formed on the basis of floral and bulb charateristics.     

A Novel MS7 Repeat Specific for Heterochromatin of Sex Chromosomes in Voles of Genus Microtus, Group arvalis: Genomic Organization and Chromosomal Localization

The tandemly arranged MS4 repeat with monomeric units of 4.1 kb is species-specifically distributed in heterochromatin of sex chromosomes of four common vole species of genus Microtus, group arvalis. In this work, we studied the genomic organization of the MS4 homolog in euchromatin of the X chromosome of M. arvalis. It has been shown by analyzing the phage genomic clones that one MS4 copy makes a part of a monomeric unit exceeding 8.5 kb that also includes a new MS7 repeat and, possibly, LINE fragments. MS7 is located together with MS4 in heterochromatin of common vole sex chromosomes, but in a substantially lesser amount. Probably, as a result of an evolutionary transition of an original repeat from euchromatin of the X chromosome to heterochromatin of the Y chromosome, MS4 underwent multiple amplification, and MS7 spread throughout heterochromatin, being surrounded by the MS4 tandem arrays.     

Using chromosomal data in the phylogenetic and molecular dating framework: karyotype evolution and diversification in Nierembergia (Solanaceae) influenced by historical changes in sea level

Karyotype data within a phylogenetic framework and molecular dating were used to examine chromosome evolution in Nierembergia and to infer how geological or climatic processes have influenced in the diversification of this solanaceous genus native to South America and Mexico. Despite the numerous studies comparing karyotype features across species, including the use of molecular phylogenies, to date relatively few studies have used formal comparative methods to elucidate chromosomal evolution, especially to reconstruct the whole ancestral karyotypes. Here, we mapped on the Nierembergia phylogeny one complete set of chromosomal data obtained by conventional staining, AgNOR‐, C‐ and fluorescent chromosome banding, and fluorescent in situ hybridisation. In addition, we used a Bayesian molecular relaxed clock to estimate divergence times between species. Nierembergia showed two major divergent clades: a mountainous species group with symmetrical karyotypes, large chromosomes, only one nucleolar organising region (NOR) and without centromeric heterochromatin, and a lowland species group with asymmetrical karyotypes, small chromosomes, two chromosomes pairs with NORs and centromeric heterochromatin bands. Molecular dating on the DNA phylogeny revealed that both groups diverged during Late Miocene, when Atlantic marine ingressions, called the ‘Paranense Sea’, probably forced the ancestors of these species to find refuge in unflooded areas for about 2 Myr. This split agrees with an increased asymmetry and heterochromatin amount, and decrease in karyotype length and chromosome size. Thus, when the two Nierembergia ancestral lineages were isolated, major divergences occurred in chromosomal evolution, and then each lineage underwent speciation separately, with relatively minor changes in chromosomal characteristics.     

Accumulation of Transposable Elements in the Heterochromatin and on the Y Chromosome of Drosophila simulans and Drosophila melanogaster

The elements of the transposon families G, copia, mdg 1, 412, and gypsy that are located in the heterochromatin and on the Y chromosome have been identified by the Southern blotting technique in Drosophila simulans and D. melanogaster populations. Within species, the abundance of such elements differs between transposon families. Between species, the abundance in the heterochromatin and on the Y chromosome of the elements of the same family can differ greatly suggesting that differences within a species are unrelated to structural features of elements. By shedding some new light on the mechanism of accumulation of transposable elements in the heterochromatin, these data appear relevant to the understanding of the long-term interaction between transposable elements and the host genome. Received: 8 August 1997 / Accepted: 11 December 1997     

Characterization of different types of condensed chromatin inCostus (Zingiberaceae)

The chromatin structure of six diploids species ofCostus was analysed using conventional Giemsa staining, C-banding and DAPI/CMA fluorochromes. The interphase nuclei in all the species show an areticulate structure and the prophase chromosomes show large blocks of proximal condensed chromatin. After banding procedures, each chromosome exhibits only centromeric dot-like DAPI⁺/CMA^– C-bands whereas the satellites (one pair at each karyotype) are weakly stained after C-banding and show a DAPI^–/CMA⁺ fluorescence. Two chromocentres show bright fluorescence with CMA and weak staining after C-banding whereas the others chromocentres show only a small fraction of DAPI⁺ heterochromatin. These results were interpreted to mean that the greater part of the condensed chromatin has an euchromatic nature whereas two types of well localized heterochromatin occur in a small proportion. The Z-stage analysis suggests that heterochromatin and condensed euchromatin decondense at different times. The chromosome number and morphology of all species are given and the implications of the condensed euchromatin are discussed.Dedicated to Prof.Elisabeth Tschermak-Woess on the occasion of her 70th birthday.     

Heterochromatin and chromosome aberrations

The chromosome breaking effect of mitomycin C, methyl methanesulfonate, maleic hydrazide, 8-ethoxycaffeine and gamma rays on the primary root meristematic cells of Nigella damascena was studied. All the agents tested except 8-ethoxycaffeine, produced relatively fewer aberrations, when compared to Vicia faba cells, though both the species have nearly similar total chromosomal length. Test for the presence of heterochromatin in Nigella gave negative results and it is interpreted that the observed differences between Vicia and Nigella are due to the presence and absence of heterochromatin in their chromosome complements respectively. The role of heterochromatin in the production of chromosome aberrations and its significance in evolution are briefly discussed.     

Habit differentiation and chromosome evolution inPleione (Orchidaceae)

Karyotypic and heterochromatin studies suggest a basic division of the orchid genusPleione into two groups, one represented by the clearly epiphytic species and the other including both species with terrestrial trends as well as those that are truly terrestrial. The epiphytic group possesses only (sub) metacentric chromosomes and is characterised by a considerable amount of terminal heterochromatin while the terrestrial group has some subtelocentric chromosomes and only small amounts of centromeric heterochromatin. It is concluded that a major phyletic split in the mode of chromosome change occurred during the transition from the epiphytic to the terrestrial habitat.     

Observations on centromeric heterochromatin and satellite DNA in salamanders of the genus Plethodon

DNA from Plethodon cinereus cinereus separates into two fractions on centrifugation to equilibrium in neutral CsCl. The smaller of these fractions has been described as a high-density satellite. It represents about 2% of nuclear DNA from this species, and it has a density of 1.728 g/cm³. It is cytologically localized near the centromeres of all 14 chromosomes of the haploid set. In P. c. cinereus the heavy satellite DNA constitutes about 1/4 of the DNA in centromeric heterochromatin. The nature of the rest of the DNA in centromeric heterochromatin is unknown. The number of heavy satellite sequences clustered around the centromeres in a chromosome from P. c. cinereus is roughly proportional to the size of the chromosome, as determined by in situ hybridization with satellite-complementary RNA, and autoradiography. Likewise the amount of contromeric heterochromatin, as identified by its differential stainability with Giemsa, shows a clear relationship to chromosome size. — The heavy satellite sequences identified in DNA from P. c. cinereus are also present in smaller amounts in other closely related forms of Plethodon. Plethodon cinereus polycentratus and P. richmondi have approximately half as many of these sequences per haploid genome as P. c. cinereus. P. hoffmani and P. nettingi shenandoah have about 1/3 as many of these sequences as P. c. cinereus. P. c. cinereus, P. c. polycentratus, and P. richmondii all have detectable heavy satellites with densities of 1.728 g/cm³. Among these forms, satellite size as determined by optical density measurements, and number of satellite sequences as determined from hybridization studies, vary co-ordinately. P. c. cinereus heavy satellite sequences are not detectable in P. nettingi, P. n. hubrichti, or P. dorsalis. The latter species has a heavy satellite with a density of 1.718 g/cm³, representing about 8% of the genomic DNA, and two light satellites whose properties have not been investigated. The heavy satellite of P. dorsalis is cytologically localized in the centromeric heterochromatin of this species. — These observations are discussed in relation to the function and evolution of highly repetitive DNA sequences in the centromeric heterochromatin of salamanders and other organisms.     

The karyotypes of the thorny catfishes <Emphasis Type="Italic">Wertheimeria maculata</Emphasis> Steindachner, 1877 and <Emphasis Type="Italic">Hassar wilderi</Emphasis> Kindle, 1895 (Siluriformes: Doradidae) and their relevance in doradids chromosomal evolution

We studied the karyotypes of two doradids, the rare and endangered Wertheimeria maculata and a derived Amazonian species, Hassar wilderi. Cytogenetic characterization was assessed using conventional staining (Giemsa), C-banding, and NOR banding. Both species had 2n = 58 chromosomes but differed in their chromosome formulae, 24 m + 14sm + 8st + 12a for W. maculata and 32 m + 16sm + 10st for H. wilderi. In W. maculata heterochromatin was mainly telomeric, and three chromosomes had a fully heterochromatic arm; in H. wilderi heterochromatin was also predominantly telomeric and evident in many more chromosomes. Hassar wilderi also presented one pair of homologues with a fully heterochromatic arm. In both species, nucleolar organizer regions were restricted to one pair of subtelocentric chromosomes. Assuming a basal position for W. maculata, we hypothesized that underlying conserved diploid and NOR-bearing chromosome numbers, chromosomal evolution in doradids has involved pericentric inversions and an increase of heterochromatic blocks.     

Evolution of DNA in Heterochromatin: the Drosophila Melanogaster Sibling Species Subgroup as a Resource

The Drosophila melanogasterspecies subgroup is a closely-knit collection of eight sibling species whose relationships are well defined. These species are too close for most evolutionary studies of euchromatic genes but are ideal to investigate the major changes that occur to DNA in heterochromatin over short periods during evolution. For example, it is not known whether the locations of genes in heterochromatin are conserved over this time. The 18S and 28S ribosomal RNA genes can be considered as genuine heterochromatic genes. In D. melanogasterthe rRNA genes are located at two sites, one each on the X and Y chromosome. In the other seven sibling species, rRNA genes are also located on the sex chromosomes but the positions often vary significantly, particularly on the Y. Furthermore, rDNA has been lost from the Y chromosome of both D. simulansand D. sechellia, presumably after separation of the line leading to present-day D. mauritiana.We conclude that changes to chromosomal position and copy number of rDNA arrays occur over much shorter evolutionary timespans than previously thought. In these respects the rDNA behaves more like the tandemly repeated satellite DNAs than euchromatic genes. This revised version was published online in July 2006 with corrections to the Cover Date.     

Comparative cytogenetics between the species Passiflora edulis and Passiflora cacaoensis

Passiflora edulis Sims is the most economically important species of the genus Passiflora. A new species was described recently, Passiflora cacaoensis Bernacci & Souza, which displayed morphologic characteristics very similar to P. edulis. Due to the need for delimitation of the two species, karyomorphological and banding analyses were carried out. Both species have 2n = 18, with the same karyotype formula 16 m + 2sm. There was variation between the species regarding the location of satellites and the width of chromosome pairs 2, 4 and 8. C banding revealed the presence of constitutive heterochromatin in the centromeric and telomeric regions of all chromosomes in both species. However, only in P. cacaoensis did chromosomes 3 and 9 have a large quantity of heterochromatin. Fluorochrome banding revealed CMA⁺ bands only in the satellites, but no DAPI⁺ bands. Fluorescence in situ hybridisation (FISH) showed that in P. cacaoensis the rDNA 5S probe is located in a single site in the subterminal position of the long arm of chromosome 5. However, for the rDNA 45S probe, two sites were detected in terminal positions of the long arms of chromosome 7, with a bigger and stronger signal, and of chromosome 9. According to the asymmetry index and the quantity of heterochromatin, P. cacaoensis is a more basal species than P. edulis. The cytogenetic data indicate that P. cacaoensis is closely related to P. edulis, but is a different species.     

Genomic divergence of allopatric sibling species studied by molecular cytogenetics of their F1 hybrids

Despite their similar karyotype morphology and close taxonomic affinity, the genomes of allopatric sibling species, Gibasis karwinskyana and Gibasis consobrina, are clearly distinguished in metaphases of their F₁ hybrids by genomic in-situ hybridization (GISH). The reduced ability of chromosomes from one species to bind labelled total DNA from the other involves almost the whole chromosome complement, and is equally pronounced in euchromatin and heterochromatin. The only region strongly conserved in the two species is an AT-rich band proximal to each nucleolus organizer. Molecular differentiation is accompanied by chromosome pairing failure in the F₁ interspecific hybrids, although the reason remains open to question. The two species also differ in their numbers of detectable sites for rRNA genes. The greater number of such sites in G. consobrina may be linked with a propensity for interchange heterozygosity. The ability to discriminate rapidly and reliably between the chromosomes of close relatives with almost identical karyotypes makes GISH invaluable in preliminary studies of phytogeny. Detection of even small conserved chromosome bands using GISH confirms the sensitivity of the technique and demonstrates its potential use in evolutionary cytogenetics. This will allow rapid re-evaluation of many important genetic systems exposed by classical cytogenetics in previous decades.