The inter-relationship between heterochromatin distribution and chiasma distribution

The distribution of chiasmata and their relationship to the presence of fixed and polymorphic heterochromatic segments is described in seven grasshopper species. In six of these, Cryptobothrus chrysophorus, Trimerotropis bilobata, Calliptamus wattenwylianus, Arcyptera fusca, Pezotettix giorni and Acrotylus insubricus, the presence of terminally located polymorphic heterochromatic segments leads to a radical redistribution of chiasmata away from the segments to more proximal sites. Polymorphisms for proximal heterochromatic segments exist in the first three of these species and they lead to a predominance of terminally associated homologues at male meiosis. In Oxya japonica where both polymorphic and fixed blocks are present, the polymorphic blocks have a similar pronounced effect on chiasma distribution, whereas the fixed blocks have no such effect.     

Chromosome banding in Amphibia

The karyotypes of 14 species of Anura from 9 genera of the suborders Amphicoela, Aglossa, Opisthocoela and Anomocoela were analysed with various banding techniques and conventional cytogenetic methods. The 18S + 28S and 5S ribosomal RNA genes were localized by means of in situ hybridization. No Q-, R- and G-banding patterns in the euchromatic segments of the metaphase chromosomes could be demonstrated in any of the species; this does not seem to be caused by a higher degree of spiralization of the amphibian chromosomes, but by the special DNA organization in these organisms. In most karyotypes, constitutive heterochromatin is present at centromeres, telomeres and nucleolus organizer regions (NORs), but rarely in interstitial positions. The heterochromatic regions are either quinacrine positive and mithramycin negative or vice versa. All species examined possess only one homologous pair of NORs; these display the brightest mithramycin fluorescence in the karyotypes. Many specimens exhibited unequal labelling of the two NORs both after silver and mithramycin staining as well as after in situ hybridization with ³H-18S + 28S rRNA. In four species, between one and six chromosome pairs with homologous 5S rRNA sites could be identified. The 5S rRNA genes and the 18S + 28S rRNA genes are closely linked in two species. In the male meiosis of the Amphicoela and Opisthocoela, there are intersitial, subterminal and terminal chiasmata in the bivalents, whereas only terminal chiasmata are observed in the bivalents of the Aglossa and Anomocoela. No heteromorphic sex-specific chromosomes could be demonstrated in any of the species. The differential staining techniques revealed that the chromosomal structure in these four suborders is largely the same as in the highly evolved anuran suborders Procoela and Diplasiocoela.     

Cytogenetics of two species of Euceraphis (Homoptera,Aphididae)

Somatic cell divisions, spermatogenesis, and the prophase stages of primary oocytes, are described for two species of birch aphid, Euceraphis betulae (Koch) and E. punctipennis (Zetterstedt). Females of E. betulae have two autosome pairs, two pairs of X-chromosomes of different lengths, and two B-chromosomes. Females of E. punctipennis have the same number of X-chromosomes and B-chromosomes as E. betulae, but only a single pair of autosomes. The sex determination system is X₁X₂0. E. punctipennis males sometimes have only one B-chromosome. In the spermatogenesis of E. betulae, pairing of homologous autosomes occurs in early prophase I, but no evidence was found of chiasmata or end-to-end alignment of homologues. Instead, homologues remain closely aligned in parallel as they condense into metaphase, and anaphase I separates the products of pairing in a strictly reductional manner. The two unpaired X-chromosomes and both B-chromosomes are stretched on the anaphase I spindle and all four pass into the larger secondary spermatocyte. The second division is equational. The B-chromosomes thus show accumulation in spermatogenesis, which must be compensated in some way by an elimination mechanism in oogenesis. Meiosis of E. punctipennis is highly anomalous. The two autosomes pair but separate again in early prophase I, then one homologue becomes heterochromatic and is apparently rejected from the late prophase nucleus. A single, equational maturation division follows. In female meiosis I, both species show highly characteristic diplotene figures with multiple chiasmata, the B-chromosomes remaining unpaired. These results are discussed in relation to previous work on aphid cytogenetics.     

Karyotype,DNA replication and origin of sex chromosomes in Anopheles atroparvus

Anopheles atroparvus has two pairs of autosomes similar in length and morphology and two sex chromosomes with equal, heterochromatic, late replicating long arms with homologous C-, G-, and Q-bands. The short arm of the Y is shorter than that of the X and both are euchromatic. The mean number of chiasmata per cell in the male is 3.2. During mitosis there is a high grade of somatic pairing but X and Y, which form a heteropycnotic mass in the interphase nucleus, have a differential behaviour. The chronology of DNA replication was studied in spermatogonia and brain cells by autoradiography. It is hypothesized that the present sex chromosomes of A. atroparvus evolved by accumulation of sex determining factors and gene deterioration resulting in heterochromatinization of the long arms, followed by structural rearrangements.—The homology of the two sex chromosomes requires limited dosage compensation which is achieved either as in Drosophila by modifier genes or by accumulation on the short arm of the X, only of female determining factors which do not require dosage compensation.     

C-banding and non-homologous associations

A chromosome complement formed by 16 autosomes and an Xy_p sex chromosome system was found in Epilachna paenulata Germar (Coleoptera: Coccinellidae). All autosomes were metacentric except pair 1 which was submetacentric. The X and the Y chromosomes were also submetacentric but the Y was minute. The whole chromosome set carried large paracentric heterochromatic C-segments representing about 15% of the haploid complement length. Heterochromatic segments associated progressively during early meiotic stages forming a large single chromocenter. After C-banding, chromocenters revealed an inner networklike filamentous structure. Starlike chromosome configurations resulted from the attachment of bivalents to the chromocenters. These associations were followed until early diakinesis. Thin remnant filaments were also observed connecting metaphase I chromosomes. Evidence is presented that, in this species, the Xy_p bivalent resulted from an end-to-end association of the long arms of the sex chromosomes. The parachute Xy_p bivalent appeared to be composed of three distinct segments: two intensely heterochromatic C-banded corpuscles formed the canopy and a V-shaped euchromatic filament connecting them represented the parachutist component. The triple constitution of the sex bivalent was interpreted as follows: each heterochromatic corpuscle corresponded to the paracentric C-segment of the X and Y chromosomes; the euchromatic filament represented mainly the long arm of the X chromosome terminally associated with the long arm of the Y chromosome. The complete sequence of the formation of the Xy_p bivalent starting from nonassociated sex chromosomes in early meiotic stages, and progressing through pairing of heterochromatic segments, coiling of the euchromatic filament, and movement of the heterochromatic corpuscles to opposite poles is described. These findings suggest that in E. paenulata the Xy_p sex bivalent formation is different than in other coleopteran species and that constitutive heterochromatic segments play an important role not only in chromosome associations but also in the Xy_p formation.     

Characterisation of a very complex constitutive heterochromatin in two Gerbillus species (Rodentia)

A large amount of heterochromatin is observed in two species of the genus Gerbillus, G. nigeriae and G. hesperinus. The C-band material represents about one-half of the total karyotype length in the former species, and about one-third in the latter. Several banding techniques and various 5-bromodeoxyuridine (BrdU) treatments were used to characterise these heterochromatic segments. After applying the R-banding technique, three different staining responses of the heterochromatin can be distinguished. In G. nigeriae, strongly stained segments (R-band positive) appear in most chromosomes and, in particular, constitute the short arms of all the larger chromosomes. Palely staining heterochromatic segments (R-band negative) are less abundant in G. nigeriae but predominate in G. hesperinus. In addition, in both species an intermediate staining of heterochromatin is observed near the centromere or in the heterochromatic short arms of some acrocentric and small submetacentric chromosomes. Very short BrdU treatment during the end of the last cell cycle results in asymmetrical staining of chromatids in heterochromatic segments after applying the acridine orange or FPG (fluorescence plus Giemsa) technique. The alternating location of strongly staining segments in one or the other chromatid simulates sister chromatid exchanges (pseudo-SCE). This pattern persists after longer BrdU treatment during different stages of the last cell cycle and is independent of the R-staining properties of the heterochromatin. The lateral asymmetric appearance of the large heterochromatic segments in Gerbillus is interpreted as reflecting an uneven distribution of adenine and thymidine between the two strands of DNA.     

Heterochromatin content and chiasma distribution in the megameric chromosomes of Stethophyma gracile and S. lineatum (Orthoptera: Acrididae)

Single populations of Stethophyma gracile and S. lineatum from Eastern Canada show substantial differences in the relative amount of heterochromatic and euchromatic material in the extensively heterochromatic (megameric) M₉ autosome. No differences in chromosome phenotype between these two species have been previously reported. A new polymorphism with respect to an interstitial, supernumerary H-block was also found in the S. lineatum population, and it appears to have some interchromosomal influence upon chiasma condition. These findings suggest that the North American Stethophyma forms may parallel the extensive and deme-specific heterochromatin variation found in the European populations of the Palaearctic S. grossum. Special attention was focused upon the structural organization of the proximal and distal H-segments on the M₉ during the early prophase of the first meiotic division in the male sex. These conspicuous, hetregions, prior to diplotene, are clearly interrupted and contain short, euchromatic sequences. This condition can readily account for the absence of chiasma localization and the distribution of chiasmata along the H-blocks at diplotene-diakinesis in the megameric element. This is the only member of the complement showing no evidence of pronounced proximal or proximal/distal chiasma localization at diplotene. Possible explanations for this interesting phenomenon are suggested.     

The supernumerary segment system of Stethophyma

Three species of the genus Stethophyma have been cytologically examined and all three show variation both for supernumerary heterochromatic segments and for the distribution of standard heterochromatin among the autosomes. The European species, S. grossum, for example, shows considerable interpopulation variation for standard heterochromatin while two of the populations, from Spain and Austria, show supernumerary segment polymorphism. The segments are located interstitially on the S₁₁ chromosome but occupy different positions in the different populations. — In all species, the presence of the extra heterochromatic segments increases the mean chiasma frequency. Moreover, the influence of the segments upon mean chiasma frequency is different in different populations and in different species. In the Spanish population, the increase is both intra- and interchromosomal whereas in Austria the influence of the segment is completely interchromosomal. — In the American species, S. gracile and S. lineatum, where supernumerary heterochromatic segments are carried on both S₁₀ and S₁₁ chromosomes, the effect on chiasma frequency shows a dosage relationship, an increase in the number of segments per individual being correlated with an increase in mean chiasma frequency. It is suggested that the interstitial segments found in all species have originated by direct duplication of chromosome material. By contrast the terminal segments in S. lineatum and S. gracile may be derived by translocation from a B-chromosome since such a chromosome has been found in one individual of the former species. — The variation in segment structure and the distribution of standard heterochromatin, among the European species of S. grossum suggests that these systems have evolved independently in different populations.On educational leave from the Forest Research Laboratory, Fredericton, N. B. Canada.     

NORs and counterstain-enhanced fluorescence studies in Cyprinidae of different ploidy level

The ribosomal RNA gene expression in the genomes of evolutionary diploid (Scardinius erythrophthalmus, Leucaspius delineatus, Tinca tinca) and polyploid species (Cyprinus carpio, Carassius carassius, Carassius auratus gibelio, Carassius auratus auratus) of Cyprinidae has been investigated by means of a silver nitrate technique. The diploid species investigated exhibited only one pair of chromosomes with nucleolus organizers (NOR). Higher numbers of rRNA-expressing chromosomal sites in several evolutionary polyploid species (Carassins) gave evidence against a complete functional diploidization, at least with regard to the NOR bearing chromosomes in these species. The NORs displayed a heterochromatic brilliant chromomycin A₃ fluorescence. No distamycin-A/DAPI-bright heterochromatic blocks were detected in the genomes of the Cyprinidae.     

The Location of the nucleolus organizer regions in Drosophila hydei

The positions of the nucleolus organizer regions in metaphase chromosomes of Drosophila hydei were detected by in situ hybridization experiments. In agreement with earlier conclusions the nucleolus of the X chromosome was found to originate in a terminal region of the heterochromatic arm. The Y chromosome contains two nucleolus organizers, one in a terminal position of the long arm, and the other in the short arm. The implications with respect to the evolution of the Y chromosome are discussed.     

C-Banding studies on australian hylid frogs: secondary constriction structure and the concept of euchromatin transformation

A C-banding and silver staining analysis of 12 species of Australian frogs of the genus Litoria, has shown that 6 morphologically distinct classes of secondary constrictions are present. These constrictions are distinguished by the distribution and type of C-banding chromatin and the distribution of silver staining material. Not all of these constrictions are nucleolus organizers. Groups of closely related species often share particular constrictions, although previously unencountered constrictions do occur in some species. It is argued that changes in position of nucleolar organizing constrictions is most easily explained by the amplification of latent nucleolus organizing sites. One of the more unusual features of this group of species is the shared similarity in gross chromosome morphology, contrasted to the extensive C-banding variation at secondary constriction sites. While in some of these cases chromosomal evolution has undoubtedly proceeded by the addition of heterochromatic segments, the predominant mechanism of change appears to involve the large scale transformation of euchromatin to heterochromatin.     

Heterochromatin distribution and chiasma localization in the grasshopper Bryodema tuberculata (fabr.) (Acrididae)

The problem of extreme localisation of chiasmata in the grasshopper species Bryodema tuberculata has been reinvestigated, using C-banding, Q-banding and benzimidazol techniques. These techniques reveal the precise localisation of heterochromatin in different chromosomes. Single or double heterochromatic blocks are present near the centromeric regions, except in chromosomes 5 and 11, which have larger blocks. These two chromosomes possess a distal chiasma while the other autosomes have a proximal chiasma. The results with regard to the distribution of chiasmata, in relation to the localisation of heterochromatin, as well as the existence of a short arm, are compared with the earlier observations of White, and discussed briefly.     

Comparison of the karyotypes ofPsathyrostachys juncea andP. huashanica (Poaceae) studied by banding techniques

The karyotypes ofP. juncea (Elymus junceus) andP. huashanica (both outbreeders) were investigated by Feulgen-staining and by C-, N-, and Agbanding, based on a single plant in cach case. Both species have 2n=2x=14 and large chromosomes, possibly a generic character. The karyotype ofP. juncea has 8 metacentrics and 6 SAT-chromosomes with minute, heterochromatic satellites while that ofP. huashanica has 9 metacentrics and 5 SAT-chromosomes only, 2 of which with small, heterochromatic satellites. The C-banding patterns ofP. juncea chromosomes comprise from one to five, mostly small, bands at distal, and terminal positions, while those ofP. huashanica chromosomes are characterized by large telomeric bands in most arms. Banding patterns and chromosome morphology allow identification of the homologues of the seven chromosome pairs inP. juncea, but of two pairs inP. huashanica only. The patterns of both taxa are polymorphic, supporting that both taxa are outbreeders. The karyotypic characters suggest thatP. juncea is more closely related toP. fragilis than either is toP. huashanica. N-banding stains weakly. Silver nitrate staining demonstrates that nucleolus organizers of both species have different nucleolus forming capacities. The presence of micronucleoli suggests that both species have an extra unidentified chromosome with nucleolus forming capacity.     

Cytogenetic studies of the Australian rodent,Uromys caudimaculatus,a species showing extensive heterochromatin variation

The Australian rodent, Uromys caudimaculatus, consists of two chromosome races, a) The Southern Race is characterized by the possession of two to twelve B-chromosomes. These vary considerably in size, morphology, and C- and G-banding characteristics, they behave as univalent at meiosis and are inherited in a random manner, b) The Northern Race lacks Bchromosomes, but possesses large blocks of distal C-positive heterochromatin on between 18 and 28 of the 46 chromosomes. The C-blocks may be entirely G-positive, entirely G-negative, or G-banded, suggesting heterogeneity within the C-blocks. There is extensive variation both between and within populations of the northern race in the number and size of the distal heterochromatic blocks. There is no apparent difference between the races in chiasma frequency. The northern race does have a much higher proportion of interstitial versus distal chiasmata, although it is probable that this is merely a reflection of lack of crossing over in the heterochromatic blocks rather than an actual shift of chiasma localisation within the euchromatin. Despite the extensive differences between the races in the amount and organization of constitutive heterochromatin, hybrids show no abnormalities at meiosis and they are fully fertile.     

Color differential staining of NOR-associated heterochromatic segments using acridine orange

A new staining technique has been evaluated for detecting heterochromatic segments accompanying nucleolus organizing regions (NORs). This technique essentially consists of C-banding followed by acridine orange staining. When the technique was applied to five species of plants, the NOR-associated heterochromatic segments (NOR H-segments) were differentiated from other segments of the chromosomes as regions emitting yellowish green fluorescence. An incubation of at least 30 min in hot 2 x SSC was required to make the NOR H-segments emit yellowish green fluorescence in Nothoscordum fragrans. Fluorescence on other heterochromatic segments varied from reddish orange to bright yellow; euchromatic segments emitted orange or yellowish orange fluorescence. The technique permits identification of NOR H-segments throughout mitosis based on the characteristic fluorescent color.     

Chromosomal constitution of nucleolus-associated chromatin in man

Summary Use of specific stains permits analysis of the frequency of nucleolus-associated heterochromatin in chromosomes 1 and 9 from human fibroblasts. In 81% of interphase nuclei the heterochromatic segment of both No. 1 chromosomes is associated with the nucleolus, while in 19% only one heterochromatic segment shows such an association with the other occupying a random position in the nucleoplasm. The nucleolar association of chromosome 9 heterochromatin is less constant: in 42.3% of the nuclei both segments are associated with the nucleolus, in 39% of the nuclei only one heterochromatic segment presents such an association, and in 18.7% neither of the two heterochromatic segments is in nucleolar association. In 6% of the cells, one or two chromosome 9 heterochromatic segments are in contact with the nuclear membrane.In situ hybridization using tritium-labeled 28S and 18S RNA shows that in the interphase nucleus the acrocentric short arms, carriers of ribosomal cistrons, are associated with the nucleolus.These observations demonstrate the complexity of the nucleolus-associated chromatin which, in addition to segments of chromosomes 1, 9, 13, 14, 15, 21 and 22, may include the Y chromosome. They also confirm that the nucleolus constitutes one of the orientation points determining the relative localization of chromosomes in the interphase nucleus.     

Pseudomultiple production in Ageneotettix deorum deorum

Meiosis in Ageneotettix deorum deorum is characterised by extensive pseudomultiple formation during prophase. The association of non-homologous chromosomes takes place prior to pairing and chiasma formation and occurs to a varying degree in all prophase cells. These pseudomultiples originate during interphase as a consequence of the association of heterochromatin. All autosomes carry procentric heterochromatic segments of variable size and the L₁, L₃ and M₅ chromosomes also possess terminal heterochromatic regions. The association of non-homologous chromosomes during zygotene and pachytene does not appear to impede pairing or the frequency and distribution of chiasmata. — A majority of the pseudomultiples dissociate after diakinesis, during orientation and congression on the spindle. However in 4% of the cells examined, associations, mainly quadrivalents, persist through metaphase. — Heterochromatic associations of non-homologous chromosomes are again evident during second prophase, though here they involve only the centric heterochromatic regions; 9% of these associations persist through second metaphase. — The nature and behaviour of the pseudomultiples in Ageneotettix are pertinent to the interpretation of terminal associations in other Orthoptera and provide evidence that persistent associations can arise following a non-chiasmate association.On educational leave from the Forest Research Laboratory, Fredericton, N.B. Canada.     

Meiotic behavior of an unequal bivalent in the grasshopper Calliptamus palaestinensis Bdhr.

Summary Unequal bivalents were found in two of four populations of the short horned grasshopper, Calliptamus palaestinensis bdhr. sampled in Israel.The inequality of the homologues was due to an extra segment which was heterochromatic and apparently terminal. Pairing configurations at pachytene and position of chiasmata at later stages revealed however that the extra segment was interstitial, and the long member terminated in a minute segment homologous to the terminal part of its normal partner. The percentage of reductional divisions at anaphase I corresponded well with the percentage of terminal chiasmata (i.e. distal to the extra segment) observed at diakinesis.The assumption of an interstitial position of the extra segment would explain the previously puzzling examples of unequal bivalents in Orthoptera whose reductional divisions have not been readily accounted for otherwise.     

Supernumerary segments in five species of grasshoppers (Orthoptera: Acridoidea)

Supernumerary segments have been observed in five species of grasshoppers: Calliptamus barbarus, Oedipoda fuscocincta, Acrotylus insubricus, Omocestus raymondi and Chorthippus ariasi. In four cases they are located in the S-chromosomes, but in A. insubricus they are carried by the megameric pair (M₉). In C. barbarus and O. fuscocincta we have observed non-homologous association during diplotene between the extra segments and the X-chromosome. The supernumerary segments of these two species are distally located. However, in anaphase-I the unequal bivalents divide reductionally in 30% and 20% of the cells, respectively. Finally, the supernumerary segments of C. barbarus do not produce any effect on mean chiasma frequency, but they decrease significantly the between-cell variance of chiasmata in males carrying them.