Patch size of gall-forming aphids: deme formation revisited

Plants of the genus Pistacia (Anacardiaceae) serve as obligate hosts for a group of specialized gall-forming aphids (Homoptera: Fordinae). The aphids regularly migrate between the Pistacia (primary) host plants and the roots of non-specific grasses and cereals (secondary hosts). Gall density varies considerably between trees and sites. The intimate relationships between the aphids and their primary host, the natural variation of host susceptibility, and the heterogeneous geographical environment may promote local adaptation and deme formation in the aphid populations. Indeed, previous analyses of the genetic structure of the aphid Baizongia pistaciae, which forms large galls on the deciduous P. palaestina trees, suggested deme formation (Martinez et al. 2005). In this study, we analyzed the genetic structure of the B. pistaciae population at eight sites and 78 trees throughout Israel and a single population in Turkey, using two molecular markers (AFLP fingerprints and COI sequencing). The genetic distance between the Israeli populations was found to be low (D = 0.01–0.02), and there was no genetic differentiation found between any population pairs. In five of the Israeli populations, we also compared the genetic identity between aphids forming galls on the same tree and between galls on neighboring trees. The analysis indicated that the genetic identity of different galls within a tree resembles the correspondence between trees within a population. Our results showed no indication of deme formation or any hierarchical genetic substructuring within B. pistaciae populations in Israel. The extensive gene flow between aphid colonies may be explained by their dispersal abilities and the potential bridging role of the secondary hosts.     

Karyotype and chromosomal banding pattern in Heteropeza pygmaea

The chromosomes of somatic and germ line cells of female embryos produced by paedogenesis were studied. The haploid set in somatic cells consists of one long submetacentric chromosome, one large acrocentric, one medium metacentric and two small acrocentrics. The length vs arm index karyogram makes it possible to distinguish all but the two pairs of small acrocentric chromosomes. — Attempts were made to develope a method for banding pattern visualization. The best result was obtained using trypsin which induced banding in the chromosomes of the somatic cells and occasionally also of the germ line cells. The resulting banding patterns were frequently not identical in members of a chromosome pair. There was also a variation between metaphases within an embryo as well as from different embryos. Some tentative explanations for these results are discussed.     

Distinct chromatin organization in the germ line founder cell of the Caenorhabditis elegans embryo

Cells belonging to the germ lineage segregate physically and molecularly from their somatic neighbors during embryogenesis. While germ line‐specific chromatin modifications have been identified at later stages in the Caenorhabditis elegans nematode, none have been found in the single P₄ germ line founder cell that arises at the beginning of gastrulation. Using light and electron microscopy, we now report that the chromatin organization in the germ line founder cell of the early C. elegans embryo is distinct from that in the neighboring somatic cells. This unique organization is characterized by a greater chromatin compaction and an expansion of the interchromatin compartment. The ultrastructure of individual chromatin domains does not differ between germ line and somatic cells, pointing to a specific organization mainly at the level of the whole nucleus. We show that this higher order reorganization of chromatin is not a consequence of the P₄ nucleus being smaller than somatic nuclei or having initiated mitosis. Imaging of living embryos expressing fluorescent markers for both chromatin and P granules revealed that the appearance of a distinct chromatin organization in the P₄ cell occurs approximately 10 min after its birth and coincides with the aggregation of P granules around the nucleus, suggesting a possible link between these two events. The higher order reorganization of chromatin that is reported here occurs during the establishment of definitive germ cell identity. The changes we have observed could therefore be a prerequisite for the programming of chromatin totipotency.     

Maternal effects of general and regional specificity on embryos of Drosophila melanogaster caused by dunce and rutabaga mutant combinations

Summary The developmental patterns of embryos produced by female germ line cells homozygous for null-enzyme mutations of dunce and for dunce in combination with each of three different rutabaga mutations are compared with the normal pattern. At least three discrete developmental defects at progressive stages following fertilization can be identified and correlated with the loss of adenylate cyclase activity caused by rutabaga mutations, suggesting that the defects are caused by elevated cyclic AMP levels in female germ line cells. The earliest defect occurs soon after fertilization and affects DNA replication and mitosis, prevents nuclear migration, and leads to large polyploid nuclei. A later defect prevents cleavage nuclei from migrating into, or dividing in, the posterior region of the egg. The last affects the developmental behavior or fate of blastoderm cells. Some of these defects mimic those produced by previously described maternal-effect mutations.     

Germ line specific DNA and chromosomes of the ciliate Stylonychia lemnae

The variation in DNA content of the micronucleus (germinal nucleus) of Stylonychia lemnae and its relation to the number of chromosomes was examined. Different populations possess similar amounts of micronuclear DNA but there are differences of ±30% between clones of the same population. However, the DNA content varies by about 100% in the micronuclei during the lifetime of a clone. The haploid micronucleus contains 35 or 36 chromosomes which persist in the developing macronucleus anlagen and grow to giant chromosomes. Besides this remaining subset, the micronucleus contains a variable number of germ line restricted chromosomes (mean about 140; range between 100 and 180). The somatic macronucleus eliminates these elements early in its development. The varying number of the germ line restricted chromosomes is responsible for the variation in the micronuclear DNA content.     

Die Zytologie der bisexuellen und parthenogenetischen Fortpflanzung von Heteropeza pygmaea Winnertz,einer Gallmücke mit pädogenetischer Vermehrung

Heteropeza pygmaea (syn. Oligarces paradoxus) can reproduce as larvae by paedogenesis or as imagines (Fig. 1). The eggs of imagines may develop after fertilization or parthenogenetically. The fertilized eggs give rise to female larvae, which develop into mother-larvae with female offspring (Weibchenmütter). Only a few of the larvae which hatch from unfertilized eggs become motherlarvae with female offspring; the others die. Spermatogenesis is aberrant, as it is in all gall midges studied to date. The primary spermatocyte contains 53 or 63 chromosomes. The meiotic divisions give rise to two sperms each of which contains only 7 chromosomes (Figs. 5–11). The eggs of the imago are composed of the oocyte and the nurse-cell chamber. In addition to the oocyte nucleus and the nurse-cell nuclei there are three other nuclei in the eggs (Figs. 15–17). They are called small nuclei (kleine Kerne). In prometaphase stages of the first cleavage division it could be seen that these nuclei contain about 10 chromosomes. Therefore it is assumed that these nuclei originate from the soma of the mother-larva. The chromosome number of the primary oocyte is approximately 66. The oocyte completes two meiotic divisions. The reduced egg nucleus contains approximately 33 chromosomes. The polar body-nuclei degenerate during the first cleavage divisions. The fertilized egg contains 2–3 sperms. The primary cleavage nucleus is formed by the egg nucleus and usually all of the sperm nuclei and the small nuclei (Figs. 21–29). The most frequent chromosome numbers in the primary cleavage nuclei are about 77 and 67. The first and the second cleavage divisions are normal. A first elimination occurs in the 3rd, 4th, and 5th cleavage division (Fig. 30). All except 6 chromosomes are eliminated from the future somatic nuclei. Following a second elimination (Figs. 33, 34), the future somatic nuclei contain 5 chromosomes. No elimination occurs in the divisions of the germ line nucleus. In eggs which develop parthenogenetically the primary cleavage nucleus is formed by the egg nucleus and 2–3 small nuclei. It's chromosome number is therefore about 53 or 63. After two eliminations, which are similar to the ones which occur in fertilized eggs, the soma contains 5 chromosomes. The somatic nuclei of male larvae which arrise by paedogenesis contain 5 chromosomes; while the somatic nuclei of female larvae of paedogenetic origin contain 10 chromosomes. It was therefore assumed earlier that sex was determined by haploidy or diploidy. But the above results show that larvae from fertilized as well as from unfertilized eggs of imagines have 5 chromosomes in the soma, but are females, and the female paedogenetic offspring of larvae from unfertilized eggs have either 5 or 10 chromosomes in their somatic cells. Therefore sex determination is not by haploidy-diploidy but by some other, unknown, mechanism. The cytological events associated with paedogenetic, bisexual, and parthenogenetic reproduction in Heteropeza pygmaea are compared (Fig. 37). The occurrence and meaning of the small nuclei which are found in the eggs of most gall midges are discussed. It has been shown here that these nuclei function to restore the chromosome number in fertilized eggs; it is suggested that they function similarity in certain other gall midges. Consideration of the mode of restoration of the germ-line chromosome number leads to the conclusion that in Heteropeza few, if any, of the chromosomes are limited to the germ-line, i.e. can never occur in somatic cells (p. 124).     

Chromatin diminution and early cleavage in Parascaris univalens (Nematoda)

Summary In Parascaris developmental commitment to the germ line and somatic lineages is indicated by the orientation of the mitotic spindle in blastomeres, the topology of cells in the embryo, and chromatin diminution in presomatic blastomeres. Using three different experimental techniques: transient pressure treatment, application of cytochalasin B, and isolation of blastomeres, we have succeeded in uncoupling several developmental processes during cleavage of P. univalens. The following results were obtained: (1) Following mitotic nondisjunction we observed identical behavior of all chromatids in each blastomere. Thus chromosome differentiation by differential replication does not occur. (2) Chromosome fragments obtained by pressure treatment of egg cells underwent chromatin diminution. Thus this process does not require an intact germ-line chromosome. However, chromosomes immobilized on a monopolar spindle did not undergo chromatin diminution. Thus diminution appears to require segregation of chromatids. (3) Blastomeres that completely lacked chromosomes as a result of mitotic nondisjunction underwent normal early cleavage divisions. (4) Pressure treatment or prolonged treatment with cytochalasin B caused egg cells or germ line blastomeres to lose their germ line quality, as deduced from the coincident occurrence of symmetrical (presomatic-like) cleavage and chromatin diminution. (5) Isolated blastomeres from 2-cell embryos, i.e. 1/2 blastomeres, usually cleaved according to their prospective fates in the whole embryo. However, in some partial embryos derived from such blastomeres, chromatin diminution was delayed for either one or two cleavage mitoses. An activation model as an alternative to a prelocalization model is presented, which can account for early blastomere topogenesis and chromatin diminution.     

The cytology of paedogenesis in the gall midgeMycophila speyeri

In paedogenetically developing female eggs of the gall midgeMycophila speyeri only one equational meiotic division occurs. The primary cleavage nucleus contains 29 chromosomes. In the fourth cleavage division 23 chromosomes are eliminated from the future somatic nuclei while the primordial germ-line nucleus keeps the high chromosome number.—The paedogenetic development of male eggs begins with two meiotic divisions. The egg nucleus with 14 or 15 chromosomes fuses with two, sometimes only one, somatic nuclei (2n=6) of maternal origin (regulation). Thus the primary cleavage nucleus contains 26 or 27 chromosomes, sometimes only 20 or 21. Elimination in cleavage divisions V and VI leeds to somatic nuclei with 3 chromosomes while the primordial germ-line nucleus keeps the high chromosome number.—Differences between male and female eggs and the evolution of regulation in gall midges are discussed.     

A high degree of aneuploidy in frozen-thawed human preimplantation embryos

We have studied the chromosomal content in 68 normally fertilised freeze-thawed human embryos of good morphology from 34 patients with an average maternal age of 32,6 years. Forty embryos showed post-thaw cellular division and twenty-eight post-thaw cleavage arrest. After spreading of the embryos on microscope slides, analysis of chromosomes X, Y, 15, 16, 17 and 18 was performed using two rounds of fluorescent in situ hybridisation (FISH). According to the results, the embryos were divided into four groups: (I) normal, all nuclei uniformly diploid, (II) diploid mosaics, normal diploid blastomeres in combination with abnormal blastomeres, (III) abnormal, all nuclei abnormal, (IV) chaotic, the chromosome constitution varies randomly from cell to cell. Approximately 25% of the embryos had normal number of the chromosomes tested, while the majority of the embryos were abnormal. Most of the abnormal embryos were diploid mosaics (57%). This was true for the embryos showing cleavage division as well as the embryos showing cleavage arrest. Our data show a slightly higher incidence of abnormal embryos compared to those obtained with FISH in non-cryopreserved embryos and confirm that the majority of preimplantation embryos fertilised in vitro contain abnormal blastomeres. The results, mechanisms, significance and implications are discussed. Received: 19 November 1998 / Accepted: 4 March 1999     

Nuclear division and migration during early embryogenesis of Bradysia tritici coquillet (syn. Sciara ocellaris) (diptera : Sciaridae)

Nuclear division and migration of cleavage nuclei in the embryos of Bradysia tritici (Diptera : Sciaridae) have been studied by light microscopy and nuclear staining. There are 8 cleavage cycles up to the syncytial blastoderm stage (4.5 hr), and during the 11th cycle cellularization begins (6.5 hr). The first 3 divisions take about 30 min each. During the 5th and 6th cycles, the maximum rate of division is reached (12 min/cycle at 22°C). After pole cell formation, the duration of the following mitotic cycles increases progressively. During nuclear migration, the presumptive germ line nuclei reach the egg cortex first, followed by anterior somatic nuclei and finally, posterior somatic nuclei reach the egg cortex. Possibly as a result of this region-specific nuclear migration, nuclear divisions become parasynchronous after 3 hr of embryogenesis (4th cycle). Several mitotic cycles later, between the 8th and 10th cycle in different embryos, X-chromosome elimination in somatic nuclei begins at the anterior egg pole and progresses in anteroposterior direction. Our observations suggest that the observed region-specific differences may be due to the activity of localized factors in the egg that control migration and nuclear cycle of the somatic nuclei.     

Photoreversible inhibition by ultraviolet light of germ line development in Smittia sp. (Chironomidae, Diptera)

Pole cell formation in embryos of the parthenogenetic midge, Smittia sp., can be delayed or inhibited by irradiation of the posterior egg pole with ultraviolet light (uv). This leaves the schedule of nuclear divisions and chromosome eliminations virtually unaffected. However, uv irradition delays the precocious migration to the posterior pole of one nucleus, which normally becomes included in the first pole cell. This effect is photoreversible, i.e., mitigated by application of blue light after uv. Photoreversibility indicates that a nucleic acid component is involved as an effective target. During normal development of Smittia a number of chromosomes are eliminated during mitosis V, not only from somatic nuclei but also in the germ line. In the latter, this mitosis takes place during the first gonial division in the larva. After uv irradiation, the first pole cell nucleus has undergone supernumerary mitoses before pole cell formation and, as a result, is driven into mitosis V precociously as the pole cell divides. This is frequently associated with chromosome elimination from pole cells, which in turn is correlated with subsequent disappearance of already formed pole cells. Adults derived from embryos without pole cells do not form ovaries. Pole cell formation, pole cell preservation, and ovary development are separately inhibited by uv, and inhibition of each step is photoreversible. The results are discussed in the context of germ cell determination, protection against chromosome elimination, and the role of chromosomes limited to the germ line.     

The diminution of heterochromatic chromosomal segments in Cyclops (Crustacea,Copepoda)

The chromosomes of Cyclops divulsus, C. furcifer, and C. strenuus, like those of several other Copepods, undergo a striking diminution of chromatin early in embryogenesis. The process is restricted to the presumptive soma cells and occurs at the 5th cleavage in C. divulsus, at the 6th and 7th in C. furcifer, and at the 4th in C. strenuus. The eliminated chromatin derives from the excision of heterochromatic chromosome segments (H-segments). Their chromosomal location is different in the three investigated species: Whereas in C. divulsus and C. furcifer the H-segments form large blocks — exclusively terminal in the former and terminal as well as kinetochoric in the latter — the germ line heterochromatin in C. strenuus is scattered all along the chromosomes. Extensive polymorphism exists with respect to the length of the terminal H-segments in C. furcifer, and with respect to the overall content of heterochromatin in the chromosomes of C. strenuus. In a local race of C. strenuus an extreme form of dimorphism has been found which is sex limited: females as a rule are heterozygous for an entire set of large (heterochromatin-rich), and a second set of small chromosomes in their germ line. Males are homozygous for the large set. In the first three cleavage divisions the H-polymorphism is solely expressed through differences of chromosome length. Following diminution the differences between homologous have disappeared. Feulgen cytophotometry demonstrates that in the three species the 1C DNA value for the germ line, as measured in sperm, is about twice that measured in somatic mitoses (germ line/soma C-values in picograms of DNA: C. strenuus 2.2/0.9, C. furcifer 2.9/1.44, C. divulsus 3.1/1.8). — The data imply that chromatin diminution is based on a mechanism which allows specific DNA segments, regardless of their location and size, to be cut out from the chromosomes without affecting the structural continuity of the remaining DNA. This mechanism may be analogous to that of prokaryotic DNA excision.     

Immunocytological and FISH analysis of pole cell formation and soma elimination of germ line-limited chromosomes in the chironomid Acricotopus lucidus

In the chironomid Acricotopus lucidus, germ line-soma differentiation becomes evident with the formation of the pole cells and the elimination of the germ line-limited chromosomes (Ks) from the future somatic nuclei of the embryo. Unlike in Drosophila, the early nuclear divisions do not proceed synchronously in A. lucidus. Usually, only one nucleus, the future pole nucleus, penetrates into the pole plasm, always at a telophase stage in the course of a regular mitosis. This happens by chance, depending on the orientation of the mitotic spindles of the early syncytial nuclei. Consequently, the time and the cell cycle at which a nucleus reaches the pole plasm, and pole cells arise, vary between embryos of the same oviposition. When entering the first germ line mitosis, while polar plasm and syncytial plasm are still not separated, some future somatic nuclei begin to eliminate their Ks. While the soma chromosomes (Ss) undergo normal anaphasic migration to the opposite poles, the K chromatids do not separate and remain in the equatorial plane, as demonstrated by fluorescence in situ hybridization using germ line-specific DNA probes. The elimination of the Ks does not occur at the same time in all future somatic nuclei. Nondisjunction of Ks was observed in the first mitosis of the pole nucleus, leading to primordial germ cells with different compositions of their K complements. The pattern and timing of elimination mitoses in the embryos indicate that each of the future somatic nuclei seems to regulate the elimination of the Ks autonomously.     

Satellite DNA properties of the germ line limited DNA and the organization of the somatic genomes in the nematodesAscaris suum andParascaris equorum

During the early cleavage divisions in some Ascarids, parts of the chromosomes are eliminated from the somatic blastomeres (chromatin diminution, Boveri, 1887) while the chromosomes in the germ line cells maintain their integrity. To characterize the germ line and soma genome, DNA was isolated from gametes and embryonic somatic cells of two Ascarid species,Parascaris equorum var. univalens andAscaris suum. It was shown that the germ line limited DNAs of these species have the same density and almost identical reassociation kinetics: in CsCl the predominant component of the germ line limited DNA ofP. equorum andA. suum has the buoyant density of 1.697g/cm³, while soma DNA of both species bands at 1.700 g/cm³. InP. equorum there is a small additional germ line limited satellite DNA component with the density of 1.690 g/cm³, identical to that of mitochondrial DNA of both organisms. Comparison of the reassociation kinetics of germ line and soma DNA demonstrates for both species that the eliminated DNA sequences are highly repetitive. In contrast to these similarities between the germ line limited DNAs ofP. equorum andA. suum the analysis of their base composition revealed differences (40% guanine plus cytosine inP. equorum and 36% inA. suum). The only very fast reassociating DNA sequences which we could isolate from soma DNA was demonstrated to be foldback DNA. The reassociation kinetics of totalA. suum soma DNA was investigated by hydroxylapatite chromatography. Least squares analysis of the data revealed about 10% of intermediate repetitive DNA sequences. Their interspersion between single copy DNA sequences was analyzed by comparing the reassociation kinetics of DNA fragments 0.35 and 7.2 kilobases long. Thus the DNA sequence arrangement ofAscaris does not follow the short period interspersion pattern observed in most organism.     

Highly repetitive DNA sequences that are restricted to the germ line in the hagfish Eptatretus cirrhatus: a mosaic of eliminated elements

The New Zealand hagfish, Eptatretus cirrhatus, is known to eliminate parts of its chromosomes during embryogenesis from presumptive somatic cells. Electrophoresis of germ line and somatic DNAs of this species, after treatment with the restriction endonucleases DraI and EcoRI, revealed three fragments of DNA that were restricted to the germ line. DNA filter hybridization experiments demonstrated that these fragments were present almost exclusively in the germ line DNA of E. cirrhatus and that they were highly and tandemly repeated. Thus, these DNA fragments appeared to be eliminated during embryogenesis. Moreover, one fragment (a DraI fragment) cross-hybridized with the germ line DNA from other species of hagfish, namely, Eptatretus okinoseanus and Paramyxine atami. Molecular cloning and sequence analysis revealed that the DraI fragment was composed mainly of closely related sequences of 85 bp in length and that this sequence was about 75% homologous to the sequence of EEEo2 (eliminated element of E. okinoseanus 2) which is a germ line-restricted and highly repetitive sequence that was isolated previously from E. okinoseanus. The other two fragments were composed of three families of closely related sequences that were 172 bp long (designated EEEc1), 61 bp long (EEEc2) and 54 bp long (EEEc3). Fluorescence in situ hybridization experiments revealed that each eliminated element was distributed on several chromosomes that are limited to germ cells. EEEo2 was dispersed on 12 C-band-positive chromosomes. EEEc1 and EEEc3 were dispersed on all C-band-positive and several C-band-negative chromosomes. By contrast, EEEc2 was located to terminal regions of several C-band-negative chromosomes. These results suggest that the eliminated chromosomes in hagfish are mosaics of highly repeated, germ line-restricted families of DNA sequences. Received: ██; in revised form: 25 October 1997 / Accepted: ██     

Q-, C-, and G-banding patterns in the germ-line and somatic chromosomes of Miastor sp. (Diptera: cecidomyidae)

Q-, C-, and G-banding patterns are described for the germ-line and somatic chromosomes of Miastor sp. The chromosome number in the germ line is 36, which is 3 less than that previously reported for the same cultured line 18 years ago. There are 8 chromosome groups: 8 large acrocentrics, 11 large and medium submetacentrics, 4 medium metacentrics, 4 medium subtelocentrics, 6 medium telocentrics, one medium acrocentric, one small submetacentric, and one small telocentric. All 8 large acrocentrics have a Q-band and an interstitial C-band in the short arm, suggesting that these chromosomes are at least partially homologous (or homeologous) and that the germ line originally was polyploid. Only one other germ-line chromosome, the small submetacentric, has a Q-band and an interstitial C-band. In somatic cells there are 8 chromosomes, 28 chromosomes having been eliminated during early cleavage. Three of the four pairs of somatic chromosomes are heteromorphic, despite the indications of a polyploid origin of the germ-line chromosomes and despite the presence of somatic pairing. Furthermore, there is a great deal of restriction on which chromosomes are retained in somatic cells, and it may be that the same 8 chromosomes are retained by all embryos. The G-banding pattern is not as clear as the other two banding patterns. The findings are discussed in relation to observations in other cecidomyids, and a model for the evolution of the chromosome system of Miastor is presented.     

Lebendbeobachtungen der Chromosomen-Aufregulation bei der Gallmücke Heteropeza pygmaea (Cecidomyiidae,Diptera)

In male-determined, paedogenetically developing eggs of Heteropeza pygmaea a restitutive fertilization takes place after meiosis. Two small nuclei of maternal origin (somatic nuclei) and the egg nucleus migrate to the center of the egg chamber. Their chromosomes then form the metaphase plate of the primary cleavage nucleus. The in vitro observations and the analysis of photomicrographs and time lapse films revealed that the metaphase stage can be reached in three different ways: 1. The egg nucleus and the two somatic nuclei form one common spindle. 2. The egg nucleus forms a spindle and the two somatic nuclei together form another one. The two spindles then fuse in late prometaphase and form a single spindle. 3. The egg nucleus alone forms a spindle. The chromosomes of the somatic nuclei migrate to the equator of this spindle. This variation in the restitutive fertilization is explained by an increasing asynchrony between the development of the egg nucleus and the slower somatic nuclei from the first to the third type.     

Analysis of localization and reorganization of germ plasm in Xenopus transgenic line with fluorescence‐labeled mitochondria

Germ plasm is found in germ‐line cells of Xenopus and thought to include the determinant of primordial germ cells (PGCs). As mitochondria is abundant in germ plasm, vital staining of mitochondria was used to analyze the movement and function of germ plasm; however, its application was limited in early cleavage embryos. We made transgenic Xenopus, harboring enhanced green fluorescent protein (EGFP) fused to the mitochondria transport signal (Dria‐line). Germ plasm with EGFP‐labeled mitochondria was clearly distinguishable from the other cytoplasm, and retained mostly during one generation of germ‐line cells in Dria‐line females. Using the Dria‐line, we show that germ plasm is reorganized from near the cell membrane to the perinuclear space at St. 9, dependent on the microtubule system.     

Isolation and chromosomal localization of a germ line-specific highly repetitive DNA family in Acricotopus lucidus (Diptera, Chironomidae)

. In the chironomid Acricotopus lucidus, parts of the genome, the germ line-limited chromosomes, are eliminated from the future soma cells during early cleavage divisions. A highly repetitive, germ line-specific DNA sequence family was isolated, cloned and sequenced. The monomers of the tandemly repeated sequences range in size from 175 to 184 bp. Analysis of sequence variation allowed the further classification of the germ line-restricted repetitive DNA into two related subfamilies, A and B. Fluorescence in situ hybridization to gonial metaphases demonstrated that the sequence family is highly specific for the paracentromeric heterochromatin of the germ line-limited chromosomes. Restriction analysis of genomic soma DNA of A. lucidus revealed another tandem repetitive DNA sequence family with monomers of about 175 bp in length. These DNA elements are found only in the centromeric regions of all soma chromosomes and one exceptional germ line-limited chromosome by in situ hybridization to polytene soma chromosomes and gonial metaphase chromosomes. The sequences described here may be involved in recognition, distinction and behavior of soma and germ line-limited chromosomes during the complex chromosome cycle in A. lucidus and may be useful for the genetic and cytological analysis of the processes of elimination of the germ line-limited chromosomes in the soma and germ line. Received: 12 April 1997; in revised form 26 June 1997 / Accepted: 29 June 1997