Heterochromatin as a factor influencing X-chromosome inactivation in hybrids of the common vole (Microtinae, Rodentia)]

Expression of X-linked genes for G6PD and alpha-GAL was studied in female interspecific hybrids of Microtus. The G6PD and alpha-GAL isozymes of Microtus arvalis were found to predominate in all cases when a species carrying a heterochromatin block on the X-chromosome served as one partner of hybridization and M. arvalis containing no heterochromatin block served as another. The proportions of G6PD and alpha-GAL parental forms were approx. equal in hybrid females when both species participating in hybridization contained heterochromatin blocks on X-chromosomes. Cytological analysis for revealing active and nonactive X-chromosomes on metaphase spreads of hybrid females supports the biochemical data. Non-random inactivation of X-chromosomes carrying the heterochromatin blocks in the interspecific hybrids with M. arvalis and a random one, when both parents contain heterochromatin blocks on the X-chromosomes are supposed to be the cause for the phenomenon observed. The study provided data supporting our previous hypothesis that heterochromatin affects the X-chromosome inactivation process in interspecific hybrid voles.     

The Role of Heterochromatin in the Expression of a Heterochromatic Gene, the Rolled Locus of Drosophila Melanogaster

Constitutive heterochromatic regions of chromosomes are those that remain condensed through most or all of the cell cycle. In Drosophila melanogaster, the constitutive heterochromatic regions, located around the centromere, contain a number of gene loci, but at a much lower density than euchromatin. In the autosomal heterochromatin, the gene loci appear to be unique sequence genes interspersed among blocks of highly repeated sequences. Euchromatic genes do not function well when brought into the vicinity of heterochromatin (position-effect variegation). We test the possibility that the blocks of centromeric heterochromatin provide an environment essential for heterochromatic gene function. To assay directly the functional requirement of autosomal heterochromatic genes to reside in heterochromatin, the rolled (rl) gene, which is normally located deep in chromosome 2R heterochromatin, was relocated within small blocks of heterochromatin to a variety of euchromatic positions by successive series of chromosomal rearrangements. The function of the rl gene is severely affected in rearrangements in which the rl gene is isolated in a small block of heterochromatin, and these position effects can be reverted by rearrangements which bring the rl gene closer to any large block of autosomal or X chromosome heterochromatin. There is some evidence that five other 2R heterochromatic genes are also affected among these rearrangements. These findings demonstrate that the heterochromatic genes, in contrast to euchromatic genes whose function is inhibited by relocation to heterochromatin, require proximity to heterochromatin to function properly, and they argue strongly that a major function of the highly repeated satellite DNA, which comprises most of the heterochromatin, is to provide this heterochromatic environment.     

Distorted heterochromatin replication in <Emphasis Type="Italic">Drosophila melanogaster</Emphasis> polytene chromosomes as a result of euchromatin-heterochromatin rearrangements

Studies of the position effect resulting from chromosome rearrangements in Drosophila melanogaster have shown that replication distortions in polytene chromosomes correlate with heritable gene silencing in mitotic cells. Earlier studies mostly focused on the effects of euchromatin-heterochromatin rearrangements on replication and silencing of euchromatic regions adjacent to the heterochromatin breakpoint. This review is based on published original data and considers the effect of rearrangements on heterochromatin: heterochromatin blocks that are normally underrepresented or underreplicated in polytene chromosomes are restored. Euchromatin proved to affect heterochromatin, preventing its underreplication. The effect is opposite to the known inactivation effect, which extends from heterochromatin to euchromatin. The trans-action of heterochromatin blocks on replication of heterochromatin placed within euchromatin is discussed. Distortions of heterochromatin replication in polytene chromosomes are considered to be an important characteristic associated with the functional role of the corresponding genome regions.     

Length of human constitutive heterochromatin in relation to chromosomal contraction

Summary Linear measurement of blocks of constitutive heterochromatin and the euchromatin portion 1q-h in three members of a family was used to study the dependence of the size of C blocks on the degree of chromosomal contraction. The results demonstrate that the size of heterochromatin portions decrease regularly with an increases of the degree of euchromatin contraction. The dependence was found to be linear, except for mitoses with an extremely high or low degree of contraction. The finding was used for the development of a new method of evaluation of constitutive heterochromatin.     

Distorted heterochromatin replication in Drosophila melanogaster polytene chromosomes as a result of euchromatin-heterochromatin rearrangements

Studies of the position effect resulting from chromosome rearrangements in Drosophila melanogaster have shown that replication distortions in polytene chromosomes correlate with heritable gene silencing in mitotic cells. Earlier studies mostly focused on the effects of euchromatin--heterochromatin rearrangements on replication and silencing of euchromatic regions adjacent to the heterochromatin breakpoint. This review is based on published original data and considers the effect of rearrangements on heterochromatin: heterochromatin blocks that are normally underrepresented or underreplicated in polytene chromosomes are restored. Euchromatin proved to affect heterochromatin, preventing its underreplication. The effect is opposite to the known inactivation effect, which extends from heterochromatin to euchromatin. The trans-action of heterochromatin blocks on replication of heterochromatin placed within euchromatin is discussed. Distortions of heterochromatin replication in polytene chromosomes are considered to be an important characteristic associated with the functional role of the corresponding genome regions.     

C- and Q-chromatin of the experimentally condensed human interphase chromosomes]

Condensed interphase chromosomes of the cultured human lymphocytes obtained by the fusion of interphase and metaphase cells were studied using C- and Q-bands techniques. The appearance and localization of the constitutive heterochromatin blocks on condensed chromosomes at G1-period were the same as on the metaphase ones. These characters were used for a group and individual identification of some chromosomes condensed at G1-period and for a study of the association of the constitutive heterochromatin blocks in the interphase nuclei. The fluorescent analysis of the chromosomes condensed at G1-period detected some bright fluorescent blocks of the constitutive heterochromatin.     

Decondensation of pericentric heterochromatin alters the sequence of centromere separation in mouse cells

The centromeres of a genome separate in a sequential, nonrandom manner that is apparently dependent upon the quantity and quality of pericentric heterochromatin. It is becoming increasingly clear that the biological properties of a centromere depend upon its physicochemical makeup, such as its tertiary structure, and not necessarily on its particular nucleotide sequence. To test this idea we altered the physical state of the AT-rich pericentric heterochromatin of mouse with Hoechst 33258 (bis-benzimidazole) and studied a biological parameter, viz., sequence of separation. We report that an alteration in the physical state of heterochromatin, i.e., decondensation, is accompanied by aberrations in the pattern of centromere separation. The most dramatic effect seems to be on chromosomes with large blocks of heterochromatin. Many chromosomes with large blocks of heterochromatin that, in untreated cells, separate late tend to separate early. Decondensation with Hoechst 33258 does not seem to alter the sequence of separation of inactive centromeres relative to that of active centromeres. These data indicate that alteration in the physical parameters of the pericentric heterochromatin might dispose the centromeres to errors. It is likely that this aberration results from early replication of the pericentric heterochromatin associated with active centromeres. Received: 24 August 1998; in revised form: 24 August 1998 / Accepted: 28 August 1998     

The size and internal structure of a heterochromatic block determine its ability to induce position effect variegation in Drosophila melanogaster

In the In(1LR)pn2a rearrangement, the 1A-2E euchromatic segment is transposed to the vicinity of X heterochromatin (Xh), resulting in position effect variegation (PEV) of the genes in the 2BE region. Practically the whole X-linked heterochromatin is situated adjacent to variegated euchromatic genes. Secondary rearrangements showing weakening or reversion of PEV were obtained by irradiation of the In(1LR)pn2a. These rearrangements demonstrate a positive correlation between the strength of PEV of the wapl locus and the sizes of the adjacent heterochromatic blocks carrying the centromere. The smallest PEV-inducing fragment consists of a block corresponding to approximately 10% of Xh and containing the entire XR, the centromere, and a very proximal portion of XL heterochromatin. Heterochromatic blocks retaining the entire XR near the 2E region, but lacking the centromere, show no PEV. Reversion of PEV was also observed as a result of an internal rearrangement of the Xh blocks where the centromere is moved away from the eu-heterochromatin boundary but the amount of X heterochromatin remaining adjacent to 2E is unchanged. We propose a primary role of the X pericentromeric region in PEV induction and an enhancing effect of the other blocks, positively correlated with their size.     

Location,structure and behaviour of C-heterochromatin during meiosis in Dichroplus silveiraguidoi (Acrididae-Orthoptera)

The constitutive heterochromatin of Dichroplus silveiraguidoi, a species which shows an exceptionally low chromosome number (2n=8), was studied at meiosis with a staining technique on normal and hypotonically treated specimens. The results showed: 1) an unusual behaviour of the heterochromatic blocks located in the so-called synaptic region of the sex bivalent (Neo Y-Neo X), which remains paired from early prophase through metaphase I; 2) in normal or in hypotonically treated cells a heterogeneous configuration of the C-heterochromatic blocks was observed. This configuration is characterized by the existence of small positive granules interconnected by euchromatic filaments and is enhanced by treatment with a low ionic strength solution; 3) A weakly positive stained (intermediate) material was demonstrated in the Neo X chromosome; 4) A large amount of heterochromatin is distributed in the form of granular material along the length of the autosomes and as telomeric and centromeric blocks in all chromosomes. The possible evolutionary mechanisms involved and the significance of the C-band heterochromatin demonstrated in this species are discussed.     

Meiotic effects of supernumerary heterochromatin in Heteropternis obscurella

The endemic Australian grasshopper Heteropternis obscurella shows considerable variation in respect of both chromosome structure and chromosome behaviour. The structural differences depend upon different patterns of heterochromatin distribution as revealed by C-banding. These involve differences between populations in respect of polytypic variation in the size of paracentromeric C-bands and differences within populations in respect of polymorphisms both for terminal blocks of heterochromatin in autosomes 3 to 8 and a large proximal block of heterochromatin in autosome 7. The behavioural differences stem in part from genotypically determined variation in the chiasma distribution pattern which is markedly localised in a majority of populations but more randomly distributed in populations from the south of Western Australia. Behavioural differences also arise as secondary consequences of the presence of those heterochromatic blocks which occur as polymorphisms. The distal blocks on autosomes 5, 6, 7 and 8 lead to a redistribution of chiasmata to more proximal sites while the proximal block on 7 leads to the virtual abolition of chiasma formation in that bivalent and its replacement by a non-chiasmate mechanism of segregation. This depends upon a persistent proximal heterochromatic association between the pairing partners. The presence of distal C-blocks on bivalents 3 to 8 gives rise to persistent pseudomultiples, formed as a result of heterochromatic associations between these blocks. Such pseudomultiples involve any two or three of these six bivalents, provided they carry distal blocks, and their frequency rises dramatically in the presence of the proximal heterochromatic block on chromosome 7.     

C-bands and chiasma distribution inScilla amoena,S. ingridae,andS. mischtschenkoana (Hyacinthaceae)

An effect of C-band pattern and polymorphism on chiasma distribution in pollen meiosis was recently demonstrated inScilla siberica. A further meiotic banding study has been performed in the alliesS. amoena, S. ingridae, andS. mischtschenkoana in order to analyze the effect, if any, of their specific C-band patterns and cytochemically different heterochromatin types on recombination. No clear evidence for a preferential formation of chiasmata adjacent to homozygous intercalary heterochromatin and no consistent reduction of chiasma frequency near strongly heterozygous intercalary heterochromatin blocks, as observed inS. siberica, could be found. Terminal C-band heteromorphism is suspected to cause distal chiasma defaults. The results suggest once more that there is no uniform effect of heterochromatin on crossover distribution.     

Genetic Analysis of the Heterochromatin of Chromosome 3 in Drosophila Melanogaster. II. Vital Loci Identified through Ems Mutagenesis

Chromosome 3 of Drosophila melanogaster contains the last major blocks of heterochromatin in this species to be genetically analyzed. Deficiencies of heterochromatin generated through the detachment of compound-3 chromosomes revealed the presence of vital loci in the heterochromatin of chromosome 3, but an extensive complementation analysis with various combinations of lethal and nonlethal detachment products gave no evidence of tandemly repeated vital genes in this region. These findings indicate that the heterochromatin of chromosome 3 is genetically similar to that of chromosome 2. A more thorough genetic analysis of the heterochromatic regions has been carried out using the chemical mutagen ethyl methanesulfonate (EMS). Seventy-five EMS-induced lethals allelic to loci uncovered by detachment-product deficiencies were recovered and tested for complementation. In total, 12 complementation groups were identified, ten in the heterochromatin to the left of the centromere and two to the right. All but two complementation groups in the left heterochromatic block could be identified as separate loci through deficiency mapping. The interallelic complementation observed between some EMS-induced lethals, as well as the recovery of a temperature-sensitive allele for each of the two loci, provided further evidence that single-copy, transcribed vital genes reside in the heterochromatin of chromosome 3. Cytological analysis of three detachment-product deficiencies provided evidence that at least some of the genes uncovered in this study are located in the most distal segments of the heterochromatin in both arms. This study provides a detailed genetic analysis of chromosome 3 heterochromatin and offers further information on the genetic nature and heterogeneity of Drosophila heterochromatin.     

The interphase distribution of satellite DNA-containing heterochromatin in mouse nuclei

The distribution of sites capable of binding mouse satellite-complementary RNA in the cytological hybridization reaction has been examined in mouse liver and testis interphase nuclei. The approach taken has been to combine hybridization with semi-thin sectioning and autoradiography in order to obtain a clear picture of the relationship of satellite DNA-containing structures to the rest of the interphase nucleus. In liver nuclei, hybridization occurs primarily with blocks of heterochromatin associated with the nuclear envelope. The most prominent of these, in terms both of size and intensity of hybridization, is the nucleolar stalk and the rest of the nucleolus-associated heterochromatin. The nucleolar body itself is not labeled, nor is much of the peripheral condensed chromatin ; in fact, a polarized distribution of satellite DNA is evident. In Sertoli and spematid nuclei, satellite DNA is found in a small number of large heterochromatin blocks with which the nucleolus is associated; some of this material bears a relationship to the nuclear envelope in these cells also.     

Heterochromatic self-association, a determinant of nuclear organization, does not require sequence homology in Drosophila

Chromosomes of higher eukaryotes contain blocks of heterochromatin that can associate with each other in the interphase nucleus. A well-studied example of heterochromatic interaction is the brown(Dominant) (bwD) chromosome of D. melanogaster, which contains an approximately 1.6-Mbp insertion of AAGAG repeats near the distal tip of chromosome 2. This insertion causes association of the tip with the centric heterochromatin of chromosome 2 (2h), which contains megabases of AAGAG repeats. Here we describe an example, other than bwD, in which distally translocated heterochromatin associates with centric heterochromatin. Additionally, we show that when a translocation places bwD on a different chromosome, bwD tends to associate with the centric heterochromatin of this chromosome, even when the chromosome contains a small fraction of the sequence homology present elsewhere. To further test the importance of sequence homology in these interactions, we used interspecific mating to introgress the bwD allele from D. melanogaster into D. simulans, which lacks the AAGAG on the autosomes. We find that D. simulans bwD associates with 2h, which lacks the AAGAG sequence, while it does not associate with the AAGAG containing X chromosome heterochromatin. Our results show that intranuclear association of separate heterochromatic blocks does not require that they contain the same sequence.     

Pairing-dependent mislocalization of a Drosophila brown gene reporter to a heterochromatic environment.

We describe the precise positioning of a reporter gene within heterochromatin where it may be silenced. A transposition of the 59E-60A region into pericentric heterochromatin ensnares distal 59E-60A via somatic pairing. The frequency with which a brown (bw) reporter gene in 59E is silenced is influenced by chromosomal configurations. Silencing occurs only when the bw+ reporter is unpaired due to heterozygosity with a deficiency, where the frequency of bw+ reporter expression is correlated with the extent of bw gene and flanking sequence present. Surprisingly, the frequency of pairing between the transposition in heterochromatin and distal 59E observed cytologically is indistinguishable from the frequency of pairing of homologous chromosomes at 59E in wild-type larval brains, regardless of configuration. Therefore, bringing a susceptible reporter gene into close proximity with heterochromatin does not necessarily affect its expression, but local pairing changes resulting from altered chromosomal configurations can lead to silencing. We also find that an ensnared distal copy of bw that is interrupted by a heterochromatic insertion enhances silencing. This demonstrates that bw can be simultaneously acted upon by pericentric and distal blocks of heterochromatin.     

Spermatogenesis and chromatin condensation in male germ cells of sea cucumber Holothuria leucospilota (Clark, 1920)

Male germ cells in the testis of Holothuria leucospilota can be divided into 12 stages based on ultrastructure and patterns of chromatin condensation. The spermatogonium (Sg) is a spherical-shaped cell with a diameter of about 6.5-7microm. Its nucleus mostly contains euchromatin and small blocks of heterochromatin scattered throughout the nucleus. The nucleolus is prominent. Primary spermatocytes are divided into six stages, i.e., leptotene (LSc), zygotene (ZSc), pachytene (PSc), diplotene (DSc), diakinesis (DiSc) and metaphase (MSc). The early cells are round while in DiSc and in MSc cells are oval in shape. From LSc to MSc, the sizes of cells range from 3.5 to 4microm. LSc contains large blocks of heterochromatin as a result of increasingly condensed 17nm fibers. In ZSc, the nucleus contains prominent synaptonemal complexes but a nucleolus is absent. In PSc, heterochromatin blocks are tightly packed together by 26nm fibers and appeared as large patches in DSc. Heterochromatin patches were enlarged to form chromosomes in DiSc and MSc and then the chromosome are moved to be aligned along equatorial region. The secondary spermatocyte (SSc) is an oval cell about 4.5-5.5microm. Their nuclei contain large clumps of heterochromatin along the nuclear envelope and in the center nuclear region. Spermatids are divided into two stages, i.e., early spermatid (ESt) and late spermatid (LSt). The nuclei decrease in size by a half and become spherical; thus the chromatin fibers condensed into 20nm and are closely packed together leaving only small spaces in LSt. The spermatozoa (Sz), with chromatin tightly packed in the spherical nucleus with a diameter of 2microm and a small acrosome situated at the anterior of the nucleus. The tail consists of a pair of centrioles lying perpendicular to each other and surrounded by a mitochondrial ring, and an axonemal complex, surrounded by a plasma membrane.     

The biological significance of variation in satellite DNA and heterochromatin in newts of the genus Triturus: an evolutionary perspective

The functional and evolutionary significance of highly repetitive, simple sequence (satellite) DNA is analysed by examining available information on the patterns of variation of heterochromatin and cloned satellites among newts (family Salamandridae), and particularly species of the European genus Triturus. This information is used to develop a model linking evolutionary changes in satellite DNAs and chromosome structure. In this model, satellites accumulate initially in large tandem blocks around centromeres of some or all of the chromosomes, mainly by repeated chromosomal exchanges in these regions. Centromeric blocks later become broken up and dispersed by small, random chromosome rearrangements in these regions. They are dispersed first to pericentric locations and then gradually more distally into the chromosome arms and telomeres. Dispersal of a particular satellite is accompanied by changes in sequence structure (for example, base substitutions, deletions, etc.) and a corresponding decrease in its detectability at either the molecular or cytological level. On the basis of this model, observed satellites in newt species may be classified as 'old', 'young', or of 'intermediate' phylogenetic age. The functions and effects of satellite DNA and heterochromatin at the cellular and organismal levels are also discussed. It is suggested that satellite DNA may have an impact on cell proliferation through the effect of late-replicating satellite-rich heterochromatin on the duration of S-phase of the cell cycle. It is argued that even small alterations in cell cycle time due to changes in heterochromatin amount may have magnified effects on organismal growth that may be of adaptive significance.     

Giant sex chromosomes retained within the Portuguese lineage of the field vole (<Emphasis Type="Italic">Microtus agrestis</Emphasis>)

The field vole (Microtus agrestis) is characterised by extremely large blocks of heterochromatin on both the X and Y chromosome. Some other Microtus also have blocks of heterochromatin on their sex chromosomes but not as extensive and always of independent origin from the heterochromatic expansion found in M. agrestis. Coupled with evidence of geographic variation in large heterochromatic blocks within other species (e.g. in the western hedgehog Erinaceus europaeus), it might be expected that field voles would show substantial variation in size and disposition of the sex chromosome heterochromatin. In fact, only minor variation has been described up to now. Those studies conducted previously were largely on field voles from central and northern Europe. Here, we describe the karyotype of field voles from Portugal, of interest because recent molecular studies have shown field voles from western Iberia to be a separate evolutionary unit that might be considered a cryptic species, distinct from populations further to the east. The two Portuguese field voles (one female, one male) that we examined also had essentially the same karyotype as seen in other field voles, including the giant sex chromosomes, but with small differences in the structure of the Y chromosome from that described previously. The finding that field voles throughout Europe show relatively little variation in their giant sex chromosomes is consistent with molecular data which suggest a recent origin for this complex of species/near-species.     

Nature and distribution of constitutive heterochromatin and NOR location in the grasshopper Phaeoparia megacephala (Romaleidae: Orthoptera)

The constitutive heterochromatin (CH) of Phaeoparia megacephala was studied using C-banding and fluorochrome staining (CMA3, DAPI and acridine orange). The nucleolar organizer regions (NOR) were identified with silver staining. The chromosome complement of this species was 2n = 23, XO in males, and 2n = 24, XX in females. The CH was pericentromeric in all chromosomes. L1, L2, L3 and X chromosomes showed large blocks of CH, while the medium and small chromosomes had small blocks. The staining procedure with acridine orange revealed the same pattern. All the pericentromeric regions showed small blocks of CMA3-positive constitutive heterochromatin (GC-rich regions), while only part of the large C-band positive chromosome segments (L1, L2, L3 and X) were CMA3 positive. This character demonstrates an uncommon heterogeneity of constitutive heterochromatin in P. megacephala. The fluorochrome DAPI did not reveal DAPI-positive regions (AT-rich regions). Silver staining revealed only one pair of medium chromosomes with NOR.     

Location and variation of the constitutive heterochromatin in Petunia hybrida

The location of heterochromatin in the chromosomes of Petunia hybrida (2n=14) is presented. C-banded mitotic metaphase chromosomes and carmine-stained pachytene bivalents have been studied. It is shown that the heterochromatin is predominantly located near the centromeres and at the secondary constrictions of the satellite chromosomes. The distribution of chromomeres in pachytene bivalents also reveals that heterochromatin is not restricted to distinct blocks, as is the case in tomato, but occurs in smaller chromomeres which gradually decrease in size towards the ends. Conspicuous telomeres have not been observed. Both C-banding technique and pachytene analysis demonstrate large variation of heterochromatin between different lines of Petunia. The study of pachytene morphology has been hampered by a high degree of non-specific stickiness of the bivalents. Both techniques prove to be unsuitable tools for large-scale chromosome identification of Petunia lines.