Premiers stades de l'oogenèse de Rhabdophaga saliciperda (Cecidomyiidae,Diptera)

The females of Rhabdophaga saliciperda have in their somatic cells 8 chromosomes and the males 6. The type of sex determination is therefore: X₁X₁X₂X₂—♀; X₁X₂—♂. The cells of the germinal line have 46 chromosomes, but a variation of their number was observed. In the oogonia and spermatogonia the number of heterochromatic chromosomes may exceed the number of E chromosomes, i.e. 8. In the beginning of the growth stage of the oocytes an incorporation of somatic cells was observed. The nuclei of these somatic cells persist in the cytoplasm of the oocytes until the maturation divisions. The possibility of their participation in the reconstruction of the nucleus of the mature egg is envisaged. The metaphase of the I segmentation division has a complex character. During prophase of the first meiotic division the E chromosomes form 4 bunches of 6–8 chromosomes each. Some univalents may also be present. The 8 S chromosomes form 4 regular bivalents. The 4 groups of E chromosomes persist until metaphase I. During metaphase I a phenomenon of expulsion of the majority of E chromosomes from the metaphase spindle was observed. The 4 bivalents remain in the equatorial plain of the spindle with some E Chromosomes. After this expulsion 2 groups of chromosomes are formed. In connection with them 2 spindles develop. An irregular distribution of E chromosomes follows without their division. The bivalents are probably separated in regular manner. These 2 spindles correspond to the I maturation division. The II maturation division was not observed because of lack of respective stages.     

Nuclear structure and behaviour in the vegetative hyphae of Pythium aphanidermatum

Nuclear divisions taking place in the hyphae ofPythium aphanidermatum have been described. Typical prophase type of nuclei with elongate chromatin fibres have been observed. Achromatic structures resembling spindle fibres with well defined poles during anaphase configuration have been noticed. A mild pretreatment with acenaphthene vapours proved instrumental in arresting the progress of nuclear division. Stages similar to early and late anaphase and telophase with deeply staining chromosomal masses have been observed. A high concentration of acenaphthene treatment resulted in the formation of giant nuclei.This work is based on a thesis submitted byK. Seshadri in partial fulfilment of the requirements for the M. Sc. degree of the Indian Agricultural Research Institute, New Delhi. His present address is: University Botany Laboratory, Chepauk, Madras-5, India.     

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).     

On the sex chromosome trivalent in some Lepidoptera females

In four of the moth species investigated, viz. Witlesia murana, Scoparia arundinata (Pyraloidea), Bactra furfurana and B. lacteana (Tortricoidea) the metaphase plates of the first meiotic division of their oocytes show a trivalent in addition to the normal bivalents. It evidently has its rise in a transverse break in one of the conjugated chromosomes. Two sex chromatin bodies can be seen in the female somatic cells of three of these species, whereas other species with a normal XY bivalent have only one. These two sex chromatin bodies are unequal in size, and their sizes bear approximately the same relation to each other as do those of the two smaller chromosomes of the trivalent. The broken chromosome is evidently the Y chromosome. The sex chromosome designation for the four above-mentioned species is thus XY₁Y₂ for the females and XX for the males. The sex chromosomes of the four species are among the biggest of the respective complements. This supports the view that the big chromosome to be found in several Lepidoptera species is the sex chromosome. It seems that in animals with holokinetic chromosomes an excessive fragmentation is hindered, at least in the case of the sex chromosomes, by its deleterious effect on the balance of sex-determining genes.Dedicated to Doctor Sally Hughes-Schrader on the occasion of her seventy-fifth birthday.     

Die Cytologie der Parthenogenese bei dem Tardigraden Hypsibius dujardini

Hypsibius dujardini Doy. (Articulata, Tardigrada) shows obligatory parthenogenesis under given cultivating conditions. Males were never found. The first meiotic division reduces the number of chromosomes; the (2n=10) chromosomes are divided between a small polar body and the egg nucleus. Prior to the second division the dyads divide, thus restoring the diploid number. A diploid polar body is formed subsequent to the second division. After the egg nucleus has moved toward the center of the egg, the cleavage divisions begin. — During meiosis II and the first cleavage divisions the chromosomes can develop into “large chromosomes” which presumably consist mostly of RNA. No “large chromosomes” are found after the seventh cleavage division. Sometimes a plate of coloured material (“elimination chromatin”) can be observed between the anaphase daughter plates of the first cleavage divisions. In this case the chromosomes are always small.     

Maternal expression of the checkpoint protein BubR1 is required for synchrony of syncytial nuclear divisions and polar body arrest in Drosophila melanogaster

The spindle checkpoint is a surveillance mechanism that regulates the metaphase-anaphase transition during somatic cell division through inhibition of the APC/C ensuring proper chromosome segregation. We show that the conserved spindle checkpoint protein BubR1 is required during early embryonic development. BubR1 is maternally provided and localises to kinetochores from prophase to metaphase during syncytial divisions similarly to somatic cells. To determine BubR1 function during embryogenesis, we generated a new hypomorphic semi-viable female sterile allele. Mutant females lay eggs containing undetectable levels of BubR1 show early developmental arrest, abnormal syncytial nuclear divisions, defects in chromosome congression, premature sister chromatids separation, irregular chromosome distribution and asynchronous divisions. Nuclei in BubR1 mutant embryos do not arrest in response to spindle damage suggesting that BubR1 performs a checkpoint function during syncytial divisions. Furthermore, we find that in wild-type embryos BubR1 localises to the kinetochores of condensed polar body chromosomes. This localisation is functional because in mutant embryos, polar body chromatin undergoes cycles of condensation-decondensation with additional rounds of DNA replication. Our results suggest that BubR1 is required for normal synchrony and progression of syncytial nuclei through mitosis and to maintain the mitotic arrest of the polar body chromosomes after completion of meiosis.     

Chromatin diminution in early embryogenesis of Ascaris lumbricoides L. var. suum

The occurrence of chromatin diminution in early Ascaris lumbricoides L. embryos has been studied in detail, and it is shown that it is possible to preselect three characteristic types of mitoses: pre-diminution, diminution, and post-diminution mitosis. The first three embryonic mitotic divisions are of the pre-diminution type. Chromatin diminution occurs after the third mitosis, but there is a variation from embryo to embryo as to whether or not chromosomal diminution occurs during the fourth, fifth, and six divisions. However, the seventh embryonic division, which gives rise to an eight-cell embryo, always exhibits chromatin diminution. Subsequent mitoses of somatic cells already in the diminished state are of the post-diminution type of mitosis.     

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.     

Interphase chromosome arrangement in Anopheles atroparvus

The arrangement of chromosomes in interphase nuclei of Anopheles atroparvus has been inferred from an analysis of: 1. The early stages of mitosis as seen following Quinacrine staining, and 2. The reversible effects on the chromatin pattern obtained following the treatment of living cells with various NaCl solutions, and the following conclusions have been reached: (a) The chromatin is connected to the nuclear membrane, (b) Homologous chromosomes show close side-by-side somatic pairing, (c) The long arms of the sex chromosomes form a fluorescent peripheral body, (d) The autosomes are strongly reflexed at the centromeres, (e) The autosomal centromeric regions are polarized towards the peripheral body, (f) The telomeric regions of all the autosomes are closely apposed.--A ring-shaped pattern of interphase chromatin is constantly and reversibly induced by NaCl 0.15 to 0.18 M solutions.--These relationships indicate a peripheral arrangement of the interphase somatic complement.--The distribution of the chromosomes in polytene nuclei and at the beginning of meiosis resembles that suggested above for somatic interphase cells. This distribution may apply more widely in the Diptera.     

Some observations on the mode of division of somatic nuclei of Mucor and Allomyces

Summary A series of successive photographs of the division of the living nucleus in a germinating sporangiospore of Mucor fragilis has been obtained. In this sequence the nucleus is seen to divide directly by elongation and constriction. The nucleolus divides at the same time and in the same way. These observations agree with the finding, first made by Léger (1896) and several times confirmed since then, that the nuclei of Mucorales apparently divide without first arranging their chromosomes in a metaphase plate and without the help of a spindle apparatus.In stained preparations of Mucor chromosomes are not normally visible as separate entities but they can be clearly seen in Feulgen preparations of dividing somatic nuclei of Allomyces arbuscula. In contrast to Mucor the nucleolus of Allomyces is dissolved during division. The chromosomes seem to sort themselves out on their own and form new nucleoli. Metaphase plates and spindles have not been encountered.To Professor Dr. E. G. Pringsheim, teacher and friend, on his 80th bithday.     

Induction of paternal genome loss by the paternal-sex-ratio chromosome and cytoplasmic incompatibility bacteria (Wolbachia): A comparative study of early embryonic events

Paternal genome loss (PGL) during early embryogenesis is caused by two different genetic elements in the parasitoid wasp, Nasonia vitripennis. Paternal sex ratio (PSR) is a paternally inherited supernumerary chromosome that disrupts condensation of the paternal chromosomes by the first mitotic division of fertilized eggs. Bacteria belonging to the genus Wolbachia are present in Nasonia eggs and also disrupt paternal chromosome condensation in crosses between cytoplasmically incompatible strains. Cytoplasmic incompatibility Wolbachia are widespread in insects, whereas PSR is specific to this wasp. PGL results in production of male progeny in Nasonia due to haplodiploid sex determination. The cytological events associated with PGL induced by the PSR chromosome and by Wolbachia were compared by fluorescent light microscopy using the fluorochrome Hoescht 33258. Cytological examination of eggs fertilized with PSR-bearing sperm revealed that a dense paternal chromatin mass forms prior to the first metaphase. Quantification of chromatin by epifluorescence indicates that this mass does undergo replication along with the maternal chromatin prior to the first mitotic division but does not replicate during later mitotic cycles. Contrary to previous reports using other staining methods, the paternal chromatin mass remains condensed during interphase and persists over subsequent mitotic cycles, at least until formation of the syncytial blastoderm and cellularization, at which time it remains near the center of the egg with the yolk nuclei. Wolbachia-induced PGL shows several marked differences. Most notable is that the paternal chromatin mass is more diffuse and tends to be fragmented during the first mitotic division, with portions becoming associated with the daughter nuclei. Nuclei containing portions of the paternal chromatin mass appear to be delayed in subsequent mitotic divisions relative to nuclei free of paternal chromatin. Crosses combining incompatibility with PSR were cytologically similar to Wolbachia-induced PGL, although shearing of the paternal chromatin mass was reduced. Wolbachia may, therefore, block an earlier stage of paternal chromatin processing in the fertilized eggs than does PSR. © 1995 Wiley-Liss, Inc.     

Meiotic pairing constraints and the activity of sex chromosomes

The state of activity and condensation of the sex chromosomes in gametocytes is frequently different from that found in somatic cells. For example, whereas the X chromosomes of XY males are euchromatic and active in somatic cells, they are usually condensed and inactive at the onset of meiosis; in the somatic cells of female mammals, one X chromosome is heterochromatic and inactive, but both X chromosomes are euchromatic and active early in meiosis. In species in which the female is the heterogametic sex (ZZ males and ZW females), the W chromosome, which is often seen as a condensed chromatin body in somatic cells, becomes euchromatic in early oocytes. We describe an hypothesis which can explain these changes in the activity and condensation of sex chromosomes in gametocytes. It is based on the fact that normal chromosome pairing seems to be essential for the survival of sex cells; chromosomal anomalies resulting in incomplete pairing during meiosis usually result in gametogenic loss. We argue that the changes seen in the sex chromosomes reflect the need to avoid pairing failure during meiosis. Pairing normally requires structural and conformational homology of the two chromosomes, but when the regions is avoided when these regions become heterochromatinized. This hypothesis provides an explanation for the changes found in gametocytes both in species with male heterogamety and those with female heterogamety. It also suggests possible reasons for the frequent origin of large supernumerary chromosomes from sex chromosomes, and for the reported lack of dosage compensation in species with female heterogamety.     

The mitotic configuration of Chaetomium globosum

The somatic nuclear division ofChaetomium globosum was studied utilizing acetocarmin and aceto-orcein techniques. Nuclear division in hyphae of this species was found to be mitotic, but diversity in morphology and division configuration was noted. Identifiable chromosomes, the metaphase plate, and the chromosome bridge were commonly seen.A combination of extremely small nuclei, difficulties in staining, multinucleate conditions, and protoplasmic streaming in hyphae presented difficulties for these studies. Contradictory views are held on the structure of the nucleus, presence of the centriolar body, and other karyological features as described byFinley (1970)Rabinow &Bakerspigel (1965). Nuclear division structural details in a few other fungal species such as the centriolar body, spindle apparatus, and nuclear membrane disassociation have been examined by electron microscopy (Motta, 1969;Ichida &Fuller, 1968;Namboodiri &Lowry, 1967).The present study and the previous report onC. globosum (Hsu, Yu &Volz, 1972) presents comparative data for a NASA Appollo 16 MEED Mycology investigation now in progress.     

Cytochemical studies on the chromatin elimination in solenobia (Lepidoptera)

Summary The chemical nature of the elimination chromatin in the first maturation division ofSolenobia was investigated with the Feulgen reaction, by staining with methyl green-pyronin. with toluidine blue before and after treatment with ribonuclease and cold perchloric acid, with the Hotchkiss periodic acid-Schiff test, and the Millon reaction.The Feulgen reaction and Hotchkiss test for polysaccharides turned out, to be negative while the tests for ribonucleic acid and protein were positive. The elimination chromatin is therefore essentially ribonucleoprotein.The elimination process is considered to be one way by which chromosomes rich in ribonucleoprotein typically present in metabolically active cells, are stripping themselves from material that may have become superfluous. Such visible shedding of material from chromosomes, though less spectacular than in the maturation division of eggs in Lepidoptera and few other insects, may be more common than is generally thought and it is suggested that the interzonal fibers found in many mitoses fall into this category.     

Reproduction and the mechanism of meiotic restitution in the parthenogenetic lizard Cnemidophorus uniparens

Gross details of the reproductive cycle and the cytology of oogenesis were studied in 155 egg clutches produced by 69 captive individuals of the triploid parthenogenetic lizard Cnemidophorus uniparens. The mean clutch cycle lasted 23 days. The mean number of ova per clutch was 3.3, and the mean number of oocytes per right and left ovaries was 1.65 and 1.70, respectively. Comparison of the size of the oocytes at ovulation (9–10 mm) with the estimated mean duration of vitellogenesis (8.8 days) gave an average of approximately 1 mm yolk deposition per day. The mean time for the retention of eggs in the oviducts was 9.3 days. The germinal disc of the oocyte consists of a series of layers formed by the arrangement of various cytoplasmic and yolk particles in the polar region. In a mature oocyte the germinal vesicle is located immediately below the vitelline membrane and lies at the center of the germinal disc. The germinal vesicle is characterized by a dense disc-like cluster of diplotene chromosomes. Diplonema extends until near ovulation when the oocytes have attained a size of about 9 mm. Diakinesis and metaphase I occur rapidly and immediately prior to ovulation. Counts of approximately as many bivalents as there are somatic chromosomes were obtained from oocytes at diakinesis and metaphase I. The second division occurs almost immediately before or at the precise moment of ovulation. The chromosomes of the first polar body consist of dyads, of which there are as many as the triploid number of 69. A metaphase II plate obtained in polar view also revealed dyad chromosomes, of which there were approximately as many as the triploid somatic number. The second telophase is normal as evidenced by formation of the second polar body. Chromosomes from the opposing telophase plates show a monad structure. The presence of as many bivalents in the first division as the triploid somatic number of 69 indicates that the 3N condition of C. uniparens was doubled prior to meiosis. This is further supported by the occurrence of two maturation divisions each giving rise to a polar body, by the dyad structure of the chromosomes in the first polar body and the second metaphase, and by the presence of monochromosomes at telophase II. Thus, parthenogenesis in these lizards is of the meiotic type. The somatic number of chromosomes is doubled early in oogenesis presumably by a premeiotic endoduplication, and the 3N level is restored by two subsequent maturation divisions.     

Electron microscopic identification of sex chromatin bodies of tissue culture cells

Summary A method is described for the unequivocal identification of sex chromatin bodies in electron micrographs of thin sections of tissue culture cells derived from human skin. Fibers, rodlets, and circular profiles having a similar diameter of about 200 Å appear to be the only components of the sex chromatin bodies. The fibers and rodlets are sometimes resolvable into two similar subunits and the circular profiles often have a less electron dense center. The overall density of sex chromatin bodies is found to be considerably less than that of metaphase chromosomes. The fibers of the sex chromatin bodies found lying away from the nuclear periphery appear to be organized more compactly than the fibers of the sex chromatin bodies found lying at the nuclear periphery.This paper is based on investigations supported by a research grant No. GM-04738 from the National Institutes of Health, Public Health Service, to Dr. H. Ris, Department of Zoology, University of Wisconsin.     

Nuclear division in the red algae Chondria nidifica and Chondria tenuissima

Cytological investigations are reported for two Chondria species, the Pacific species Chondria nidifica Harvey and Chondria tenuissima (Goodenough et Woodward) C. A. Agardh from the shore of the Marmara Sea in Istanbul. Nuclear division during mitosis and meiosis has been followed in somatic cells and in tetrasporangial mother cells respectively of diploid tetrasporic plants. The spherical interphase nucleus stains densely, showing many chromatin granules. Mitotic nuclei in the apical groove show a large number of chromosomes at metaphase; the chromosome number has been estimated at diakinesis to be 40 in both C. nidifica and C. tenuissima. The meiotic nuclei of tetraspore mother cells in prophase contain several relatively large nucleolar-derivatives in both species. The nucleolar derivatives disappear completely before the chromosomes begin to differentiate. In meiotic prophase the tetraspore mother cell enlarges from its original diameter. The period of the second meiotic anaphase seems to be extremely short in comparison with other nuclear phases. When the chromosomes reach the poles, they spread and subsequently form a relatively compact mass at telophase. The spindle has not been observed in C. tenuissima. Photographs are presented of nucleoli and nucleolar-derivatives in mitotic and meiotic divisions.     

Heteropolarity in unicellular cyanobacteria: structure and development ofCyanocystis violacea

Cyanocystis violacea isolated from a marine rock sample conforms with the diagnosis ofDermocarpa violacea Crouan in all significant characteristics. The distinct heteropolarity of the cells and simultaneous cell divisions, are stable characters in culture. Development and growth of cells, simultaneous cell division and nanocyte formation have been documented by single-cell slide cultures and fine structural studies. The reddish violet color of the cytoplasm is due to the abundance of phycoerythrin.This paper is dedicated to Prof. DrLothar Geitler, whose monumental contribution to the knowledge of blue-green algae will remain the basis for future studies on these organisms for many years to come. One of us (EIF) was fortunate enough to have had Prof.Geitler as his major professor. All of us consider Prof.Geitler our teacher.     

A Brief Report on the Chromosome Number of Neodiplogaster pinicola and Panagrellus redivivoides (Nematoda: Rhabditida)

Both Neodiplogaster pinicola and Panagrellus redivivoides reproduce amphimictically, with XO type of sex determination. In N. pinicola, primary spermatocytes have six bivalent chromosomes and one univalent; after two meiotic divisions, sperm are produced with either six or seven chromosomes. In primary oocytes, with seven bivalents, meiosis is initiated by entrance of a sperm. After two meiotic divisions, three polar nuclei are produced, and egg and sperm pronuclei fuse. Cleavage begins after the egg is laid. Males have a 2n number of 13 chromosomes; females, 14. In P. redivivoides, primary spermatocytes have four bivalents and one univalent. After two meiotic divisions, spermatids are produced with either four or five well separated chromosomes. In primary oocytes, the first maturation division is initiated after penetration of a sperm; after two meiotic divisions, each egg has five chromosomes. Cleavage begins immediately after fusion of egg and sperm pronuclei, and embryonic development and hatching occur within the uterus. Males have a 2n chromosome number of 9; females, 10.     

The internal order of the interphase nucleus

Summary This paper has two parts. The first one is theoretical, whereas in the second, some experimenteal results are reported. Part 1: Theoretical Considerations. Comings' considerations on an ordered arrangement of chromatin in the interphase nucleus are used as a basis for further investigations and calculations in order to establish a preliminary model of the interphase nucleus. Information on the amount of DNA of a diploid human nucleus, on the degree of spiralization of chromatin threads found in electron microscopy, and measurements of salivary gland chromosomes was used to estimate the lengths of the entire interphase chromosomes. The number of fixing points-pores—was indirectly calculated proposing a model of an internal order of the chromatin threads. This number was found in concord with a direct calculation of the number of pores in the nuclear membrane based on results from electron microscopy. Part 2: Experimental Results and Discussion. In the second part of this study, an approach was made as to how to arrange chromosomes and chromosome segments in their proximity to each other. Results of cytogenetic studies of newborn babies and abortions, of cells from patients with Bloom's syndrome and Fanconi's anemia and normal cells treated with Mitomycin C and Trenimon, are thought to be informative under certain suppositions for the problem, which chromosome or chromosome parts are situated in proximity to each other. The symmetrical and equal interchanges seen, for example, in Bloom's syndrome are an indication of somatic pairing during the time of reunion. Therefore, the unequal interchanges in the same syndrome in which different chromosomes are involved should give evidence for proximity of nonhomologous chromosomes. Arguments for and against a temporal and spacial hypothesis for somatic pairing are discussed. The differing frequencies of chromosomes involved in Robertsonian translocations in man are informative for proximities of satellite regions at the nucleolus. Nucleolus and sex chromatin could be used as fixed points in a model of the interphase nucleus in which finally the absolute localization of the chromosomes will be discovered. The discussion points out promising methods for further investigations on the subject and mentions problems which could be attacked if the approach described here leads to a model of internal order in the interphase nucleus.This work was supported by the Deutsche Forschungsgemeinschaft within the Sonderforschungsbereich 35, Klinische Genetik.