The transformation of the synaptonemal complex into the “elimination chromatin” in Bombyx mori oocytes

In Bombyx mori oocytes the synaptonemal complexes are retained in modified form from pachytene to metaphase I. At the end of pachytene the length and width of the lateral components of the complex increase, whereafter the complexes become compacted during later stages of the meiotic prophase. Ultimately, at metaphase I the modified synaptonemal complexes of individual bivalents fuse to form a more or less continuous sheet between the homologous chromosomes. This sheet corresponds to the structure historically known as the elimination chromatin. It is concluded that in the absence of crossing over and chiasma formation in Bombyx mori females the retainment and subsequent modification of the synaptonemal complex has evolved as a substitute mechanism to ensure regular disjunction of the bivalents.     

The meiotic prophase in Bombyx mori females analyzed by three-dimensional reconstructions of synaptonemal complexes

Serial sectioning followed by three dimensional reconstruction of lateral components of the synaptonemal complex have been used to follow chromosome pairing during the prophase of the achiasmatic meiotic division in the silkworm, Bombyx mori. During leptotene and early zygotene, the lateral components become attached to the nuclear envelope at a specific region, thus forming a chromosome bouquet. The attachment of lateral components to the nuclear envelope precedes the completion of the components between their attachment points. Synapsis and synaptonemal complex formation start during the period of lateral component organization in the individual nucleus. Telomeric movements on the nuclear envelope occur at two stages of the prophase: the chromosome pairing appears to be initiated by an association of unpaired ends of homologous chromosomes, the nature of this primary attraction and recognition being unknown. Secondly, the paired chromosomes become dispersed in the nucleus by shifting of attachment sites of completed synaptonemal complexes at the end of zygotene. This movement is possibly related to a membrane flow occurring during this stage. Membrane material is synthesized at the region of synaptonemal complex attachment. Later, the excess membrane material is shifted to the opposite pole where it protrudes into the lumen of the nuclei thus forming vacuoles. — Two previously undescribed features of chromosome pairing were revealed. In late zygotene, chromosome pairing and synaptonemal complex formation were frequently observed to be delayed or even prevented over a short distance by interlocking of two bivalents, both being attached to the nuclear envelope. Such interlocking of bivalents was not found in pachytene. Secondly, one nucleus was found in which two homologous chromosomes were totally unpaired while the remaining 27 bivalents were completed or in a progressed state of pairing. The lateral components of the two unpaired chromosomes had the same length and were located several microns apart, thus eliminating the possibility of a permanent association of homologous chromosomes before the onset of meiosis in Bombyx mori females. — During pachytene, one of the 8 cells belonging to the syncytial cell cluster characteristic of oogenesis continues the meiotic prophase whereas the remaining 7 cells, the nurse cells, enter a different developmental sequence, finally resulting in their degeneration. The synaptonemal complex of the oocyte develops into a sausage-like structure after pachytene by a deposition of dense material onto the lateral components, thus filling out most of the central region. The diameter of this modified synaptonemal complex reaches at least 300 nm, as compaired to a pachytene width of approximately 130 nm. Also, the length of synaptonemal complexes increases from 212 at zygotene/pachytene to at least 300 at the modified pachytene stage. In nurse cells, synaptonemal complexes are shed from the bivalents shortly after pachytene simultaneously with a condensation of the chromatin. These free synaptonemal complex fragments associate and form various aggregates, either more or less normal looking polycomplexes or various complex figures formed by reorganized synaptonemal complex subunits. Later stages have not been included in the present investigation.     

The Drosophila meiotic kleisin C(2)M functions before the meiotic divisions

Stepwise and regionally controlled resolution of sister chromatid cohesion is thought to be crucial for faithful chromosome segregation during meiotic divisions. In yeast, the meiosis-specific -kleisin subunit of the cohesin complex, Rec8, is protected from cleavage by separase but only during meiosis I and specifically within the pericentromeric region. While the Drosophila genome does not contain an obvious Rec8 orthologue, as other animal and plant genomes, it includes c(2)M, which encodes a distant -kleisin family member involved in female meiosis. C(2)M associates in vivo with the Smc3 cohesin subunit, as previously shown for yeast Rec8. In contrast to Rec8, however, C(2)M accumulates predominantly after the pre-meiotic S-phase. Moreover, after association with the synaptonemal complex, it disappears again and cannot be detected on meiotic chromosomes by metaphase I. C(2)M cleavage fragments are not observed during completion of the meiotic divisions, and mutations within putative separase cleavage sites do not interfere with meiotic chromosome segregation. Therefore, C(2)M appears to function within the synaptonemal complex during prophase I but possibly not thereafter. This suggests that C(2)M may not confer sister chromatid cohesion needed for meiosis I and II chromosome segregation.     

Meiotic cytology of Saccharomyces cerevisiae in protoplast lysates

Summary This report describes cytological features of meiosis in Saccharomyces cerevisiae prepared for electron microscopy by lysis of protoplasts or nuclei on an aqueous surface. Whereas the chromatin of cells lysed before or after meiotic prophase was widely dispersed, pachytene bivalents appeared as discrete, elongate masses of compact chromatin. These bivalents were of nearly uniform thickness; they ranged in length from about 0.6 m to 4.0 m, with a median of 1.6–1.8 m. Enzymatic digestion of chromosomal DNA removed the chromatin to reveal the underlying synaptonemal complex. The lysis of partially purified nuclei was less disruptive and thereby revealed the regular association of the telomeres with fragments of the nuclear envelope. In tetraploid cells, pachytene lysates contained quadrivalents characterized by the close apposition of chromatin masses of similar length. One or more points of intimate association appear to represent sites of exchange between pairing partners. The departure of the diploid cells from pachytene was accompanied by the renewed association of spindle microtubules with the chromosomes shortly before the diplotene chromosomes decondensed. Later, the successive meiotic divisions were identified by the appearance of a single spindle for meiosis I and of two spindles for meiosis II.     

Chromosome behavior in the primary nucleus ofAcetabularia calyculus as revealed by epifluorescent microscopy

Summary Chromosome behavior preceding secondary nuclei formation within a giant primary nucleus (50–100 m in diameter) inAcetabularia calyculus was observed by the fluorescence emitted from 4-6-diamidino-2-phenylindole (DAPI)-stained DNA.Throughout the period when the large nucleolus was present in the primary nucleus, thin chromonemata were observed twining around the nucleolus. Nuclear division was initiated by degeneration of the sausage-shaped nucleolus into a number of spherical subunits soon after the initiation of cap formation. On the fourth day of cap development, the chromonemata became thicker and chromomeres appeared. They accumulated adjacent to the single spherical nucleolus. The lump of chromosomes became loosened and thick chromosomes were scattered in the nucleus. The peculiar shapes of chromosomes which suggest the existence of chiasmata were frequently observed until the chromosome segregation started. This sequence of chromosome behavior seems to be the prophase of meiotic division. Chromosome segregation, the first meiotic division, occurred on the seventh day of cap development, probably being accompanied by the second meiotic division. Immediately after nuclear division of the primary nucleus, secondary nuclei were formed and cyst formation started 24 hours after repeated mitoses of the secondary nuclei.     

Pachytene synaptonemal complexes and meiotic achiasmatic chromosomes

Microsporocytes sometimes undergo an achiasmatic meiosis when placed into culture early in the season at a time after premeiotic S but prior to leptonema. Trillium meiocytes were examined by light and electron microscopy to analyze the frequency of cells in various stages of meiotic prophase and the occurrence of the synaptonemal complex at different times of culture. On the basis of the results, a hypothesis is proposed that suggests there is a tripartite sensitive period that occurs between S phase and leptonema. Where the cells are in this sensitive period at the time of transplantation into culture determines whether the cells do not enter meiotic prophase, enter but produce achiasmatic division figures, or enter and develop normally.This work was supported in part by grants from the National Science Foundation (GB 5173X and GB 6476) and the National Institute of Health (GM 16882)     

Ultrastructural characterization of the sex chromosomes during spermatogenesis of spiders having holocentric chromosomes and a long diffuse stage

An ultrastructural study has been made of spermatogenesis in two species of primitive spiders having holocentric chromosomes (Dysdera crocata, XO and Segestria florentia X₁X₂O). Analysis of the meiotic prophase shows a scarcity or absence of typical leptotene to pachytene stages. Only in D. crocata have synaptonemal complex (SC) remnants been seen, and these occurred in nuclei with an extreme chromatin decondensation. In both species typical early prophase stages have been replaced by nuclei lacking SC and with their chromatin almost completely decondensed, constituting a long and well-defined diffuse stage. Only nucleoli and the condensed sex chromosomes can be identified. — In S. florentina paired non-homologous sex chromosomes lack a junction lamina and thus clearly differ from the sex chromosomes of more evolved spiders with an X₁X₂O male sex determination mechanism. In the same species, sex chromosomes can be recognized during metaphase I due to their special structural details, while in D. crocata the X chromosome is not distinguishable from the autosomes at this stage. — The diffuse stage and particularly the structural characteristics of the sex chromosomes during meiotic prophase are reviewed and discussed in relation to the meiotic process in other arachnid groups.     

Demonstration of kinetochores and centrioles in spermatocytes of two species of cockroaches by silver staining

Light microscopy following silver staining of spermatocytes of German and Madagascar hissing cockroaches demonstrated: (1) the localization of a kinetochore in each autosomal synaptonemal complex during pachytene, and (2) visualization of centrioles in different stages of meiotic prophase. The presence of a hairpin-like twist and the nucleolus organizer region in the X-chromosome was observed only in the German cockroach.On leave from the Kunming Institute of Zoology, The Chinese Academy of Sciences, Peoples Republic of China     

DNA reduplication during meiotic prophase in the oocytes of Carausius morosus Br. (Insecta,Cheleutoptera)

Cytological investigations combined with cytophotometric DNA determinations on Feulgen stained squash preparations of ovarioles from third and fourth instar nymphs of Carausius morosus revealed that during meiotic prophase a largely despiralized stage follows pachytene and that in this stage an extra reduplication of the nuclear DNA takes place (pachyreduplication phase). Meiotic prophase then proceeds with tetrapachytene, a pachytene-like stage with twice the amount of DNA as compared to oocyte nuclei in earlier meiotic stages, and with more than half the somatic number of elements, being probably autobivalents.Supported by Deutsche Forschungsgemeinschaft.     

Fine structure of chromosome pairing in ten Ascomycetes: meiotic and premeiotic (mitotic) synaptonemal complexes

The meiotic prophase of ten Ascomycetes was studied by both light and electron microscopy. All ten species show a Neurospora type of meiosis. Two Podospora have no distinct synaptonemal complexes but synaptic structures in their nucleolus. The synaptonemal complexes of the eight other species are well differenciated and have uniform dimensions. The banded pattern of the lateral components seems to be a characteristic of Ascomycetes. The most striking observation is the specificity of this banding which can be used as a marker in interspecific crosses. Ascophanus carneus shows two kinds of synaptonemal complexes: normally between the pachytene bivalents and unusually in the ascogenous hyphae mitoses before meiosis and even before caryogamy.     

Subnuclear redistribution of DNA species in confluent and growing mammalian cells

About 20 to 25 percent of the nuclear DNA from cultured cells of the African green monkey, Cercopithecus aethiops, consists of a homogeneous, highly repetitive fraction designated C. aethiops component DNA. Use of in situ hybridization techniques reveals component at the centromeres of chromosomes from both diploid and heteroploid African green monkey kidney (AGMK) tissue culture cells. — Component DNA comprises 47 percent of the nucleolar DNA in actively growing primary AGMK cells, but only 31 percent of the nucleolar DNA in confluent cells which show density-dependent growth inhibition. Further, there is a pronounced shift of both main band and component DNA from euchromatin to heterochromatin when growing cells attain confluency. Thus, the relative subnuclear distributions of component and main band DNA's are different in growing and confluent cells. — In situ hybridization techniques indicate that component sequences aggregate in clumps in nuclei of growing cells and show a diffuse distribution in nuclei of confluent cells. This suggests that centromeric regions of the various chromosomes or groups of chromosomes aggregate and disaggregate reversibly as the culture changes from density-dependent growth inhibition to active cell division. — Hypotonic citrate treatment of primary AGMK cells causes nucleoli of confluent cells to disperse: this dispersion following citrate treatment was not seen in growing AGMK cells or in confluent or growing heteroploid cells. Similarly, this nucleolar dispersion was seen in confluent diploid mouse and human cells but not in growing diploid cells or in confluent or growing heteroploid cells.     

Synaptonemal complex formation in hybrids of Lolium temulentum × Lolium perenne (L.)

The chromosomes of Lolium temulentum are longer and contain on average 50% more nuclear DNA than the chromosomes of L. perenne. In the hybrid, despite the difference in length and DNA content, pairing between the homoeologous chromosomes at pachytene is effective and the chiasma frequency at first metaphase in pollen mother cells is high, about 1.6 per bivalent, comparable to that in the L. perenne parent. Electron microscopic observations from reconstructed nuclei at pachytene show that synaptonemal complex (SC) formation in 40% of bivalents is perfect, complete and continuous from telomere to telomere. In others, SCs extend from telomere to telomere but incorporate lateral component loops in interstitial chromosome segments. Even in these bivalents, however, pairing is effective in the sense of chiasma formation. The capacity to form perfect SCs is achieved by an adjustment of chromosome length differences both before and during synapsis. Perfect pairing and SC formation is commoner within the larger bivalents of the complement. At zygotene, in contrast to pachytene, pairing is not confined to homoeologous chromosomes. On the contrary there is illegitimate pairing between non-homologous chromsomes resulting in multivalent formation. There must, therefore, be a mechanism operative between zygotene and pachytene that corrects and modifies associations in such a way as to restrict the pairing to bivalents comprised of strictly homoeologous chromosomes. Such a correction bears comparison with that known to apply in allopolyploids. In the hybrid and in the L. perenne parent also, certain specific nucleolar organisers are inactivated at meiosis.     

The influence of hypotonic treatment on the morphology of meiotic stages I. Prophase of the first meiotic division of male mice,man and Locusta migratoria

Male mice were treated with hydroxyurea (HU) to obtain a restricted germ cell population and a sequential analysis of the first meiotic prophase was performed. The results from HU-treated mice were compared with those from untreated mice, human and grasshopper material with and without hypotonic treatment.In hypotonically treated material the three subclasses of diffuse stages were obvious in all species investigated. In material not treated hypotonically the different classes of prophase stages showed a more gradual course, there was a tendency towards less spreading of the bivalents and no pronounced diffuse substages could be found. The first desynaptic stage in this material could be recognized in most cases as wellspread classical pachytene like bivalents with a pronounced double-threaded structure. The more advanced desynaptic stage in untreated material resembled the diffuse stage as found in plant meiosis.     

Modulation of formation of tumor metastases by peritoneal macrophages elicited by various agents

Summary We have studied the formation of experimental B16 melanoma metastases in the lungs of mice inoculated IV with tumoricidal or nontumoricidal peritoneal macrophages elicited by various agents. IV inoculation of peritoneal M elicited by Brewer's thioglycollate medium (TG-M) 1 day before the injection of B16 melanoma cells dramatically increased the number of metastatic foci in the lungs. NIH thioglycollate broth and proteose peptone each elicited a relatively low number of M, which were morphologically distinguishable from TG-M and did not influence the yield of B16 melanoma colonies in the lungs. Resident or C. pravum-elicited M also did not augment metastatis formation. TG-M became highly tumoricidal after IP stimulation with poly I: C. However, tumoricidal TG-M inoculated IV 1 day before IV inoculation of B16 melanoma cells did not have an antimetastatic effect. On the contrary, both tumoricidal and nontumoricidal TG-M augmented metastasis formation. Poly I: C treatment had a substantial antimetastatic effect in the normal mice, but not in mice with adoptively transferred TG-M. Histological analysis revealed that IV-inoculated TG-M (tumoricidal or nontumoricidal, either viable or disrupted) induced severe intravascular reaction in the lungs, but not in the liver or kidney. This reaction manifested in the aggregation of the various blood cells, preferentially neutrophils. These reactions were not observed after IV inoculation of PM or NIH TG-M.Intravascular inflammatory reactions induced by TG-M may be responsible for the augmentation of metastasis formation, partly by suppression of NK reactivity and mostly by the acceleration of the processes of tumor cell extravasation. These data may provide some insight into the failure to achieve systemic adoptive immunotherapy using activated peritoneal TG-M. Abbreviations used in this paper are: TG-M, thioglycollate-elicited macrophages; PM, proteose-peptone-elicited macrophages; NIH TG-M, macrophages elicited with NIH thioglycollate broth; CP-M, macrophages; elicited with C. parvum; poly I: C, polyinosinic: polycytidylic acid; TGM, thioglycollate medium; NIHTGB, NIH thioglycollate broth     

Contextualizing Images in Dreams and Daydreams

A contextualizing image (CI) is a powerful central image of a dream which appears to contextualize (provide a picture-context for) the dreamer's emotion. For instance, dreamers who have experienced any serious traumatic event sometimes dream, I was overwhelmed by a tidal wave. This appears to picture their feeling of terror and/or vulnerability.A scoring system for CIs is examined here and is applied to dreams and daydreams supplied by 40 students. Two raters scoring dreams on a blind basis showed good inter-rater reliability. Recent dreams were shown to have more as well as more intense CIs than recent daydreams; likewise, dreams that stand out had more intense CIs than daydreams that stand out. Students with thin boundaries had more and more intense CIs than students with thick boundaries in their recent dreams and nightmare, but not so clearly in dreams and nightmares that stand out. The emotions judged as contextualized by the powerful images tended towards fear/terror and helplessness/vulnerability in dreams (especially in dreams that stand out) whereas emotions contextualized by images in daydreams showed a wide range with no clusters.     

Organization of heterologous DNA inserts on the mouse meiotic chromosome core

With simultaneous immunofluorescence and fluorescent in situ hybridization, we have determined the organization of native and heterologous DNA sequences relative to the cores of meiotic prophase chromosomes. The normal chromatin organization is demonstrated with probes of mouse sequences: a cosmid probe that identities unique sequences and a 720 kb yeast artificial chromosome (YAC) probe that recognizes a specific region of the chromatin domain. The heterologous DNA consists of a 1.8 Mb insertion of 40 tandem head-to-tail phage LIZ vectors and of 11.4 Mb of bacterial/mouse DNA repeats. The lengthy insert is unusual in that it is not contained in the chromatin domain of chromosome 4 and in that it fails to form direct attachments to the chromosome core. The ends are attached indirectly, probably by means of the flanking mouse sequences. At late stages of meiotic prophase, while the terminal attachments remain the same, the DNA becomes highly compacted. Apparently, higher order condensation and core attachment are independent processes. The condensed inserts relax precociously at metaphase I. In the mouse heterozygous for the insert, the two sister inserts are usually merged, as are all four inserts in the homozygous mouse. Evidently chromatin loops with identical sequences can become associated during meiotic prophase. Mouse sequences within a heterologous DNA insert (repeats of bacterial plasmid pBR322 with a mouse -globin insert) were observed to restore some degree of core attachment.     

Meiosis readiness in Lilium longiflorum “Croft”

It is proposed that anthers of Lilium longiflorum Croft approaching the end of premeiotic mitosis reach a state described as meiosis readiness after which cells in premeiotic prophase are unable to complete a mitotic division but despiralize to interphase and enter a meiotic division. Many of the laggard premeiotic cells begin despiralization before reaching an extremely contracted state of late prophase. Premeiotic despiralization is not, therefore, attributed to a deficiency in metaphase but to an inability of these cells to complete prophase. Premeiotic despiralization appears to be preceded by a slowing-down of prophase development. There is variation among anthers and anther regions in the onset of prophase retardation and meiosis readiness. It is suggested that meiosis readiness depends upon a gradual accumulation of meiosis-inducing substances in the cytoplasm of the premeiotic cells. It has not been determined whether the cells that undergo premeiotic despiralization give rise to the giant microsporocytes with shattered chromosomes observed at late prophase of meiosis.     

A quantitative study of histones of meiocytes

The existence of a meiocyte-specific histone fraction (FM) (Sheridan and Stern, 1967) is confirmed. FM appears during premeiotic interphase and prophase I in Lilium candidum in addition to a set of standard somatic fractions. Several pieces of evidence were obtained showing that FM can not be an aggregate of non-histone protein with some histone fraction. If the amount of somatic fractions in the total histone is taken as 100% then the relative content of any somatic fraction remains constant (with insignificant fluctuations around the constant level) during the whole period of the rise and fall of FM. Thus, FM appears not at the expence but in excess of somatic fractions, i.e. FM is an extra histone and the resulting histone content of the meiocytes in pachytene is higher than that of somatic and sporogenous cells during mitosis. — The relative amount of FM increase during prophase I reaches a maximum of about 14% over the sum of somatic histone fractions at zygotene-pachytene, and falls to 7% at meiotic divisions. These events coincide with the rise and fall of the synaptonemal complex, and it is therefore the suggested that FM is one of the molecular components of a synaptonemal complex.Dedicated to Professor A. A. Prokofieva-Belgovskaia on the occasion of the seventieth anniversary of her birthday.     

Loss of microtubular orientation and impaired development of prophase bands upon inhibition of RNA synthesis in root meristem cells

Synchronous cells in Allium cepa L. root meristems were treated with 3deoxyadenosine (cordycepin, an inhibitor of RNA synthesis) when roughly half of the population had reached G₂ phase (fast cells) while the other half was still in late S (slow cells). Since this drug also blocks DNA replication, slow cells remained in S while the treatment was continued.Indirect immunodetection of tubulin showed that a band typical of prophase formed in some cells with a portion of their nuclear DNA unreplicated. Most of the cells arrested in late S which had not developed a prophase band had a diminished number of cortical microtubules. Changes in their orientation (from transversal to oblique or longitudinal) occurred in roughly a cycle time (28 h).In the presence of 3deoxyadenosine, fast cells which had reached G₂ at the start of the treatment proceeded to prophase and remained there. Mature prophase bands were also formed in these cells but eventually they disoriented and, finally, disappeared. The data suggest that microtubular orientation in the meristematic cells depends on long-lived RNA species.Abbreviations 3AdR 3deoxyadenosine - MT microtubule - PB tubulin band typical of prophase     

The regulation of total creatine content in a myoblast cell line

Total cellular creatine content is an important bioenergetic parameter in skeletal muscle. To understand its regulation we investigated creatine transport and accumulation in the G8 cultured skeletal myoblast line. Like other cell types, these contain a creatine transporter, whose activity, measured using a radiolabelling technique, was saturable (Km = 110 ± 25 M) and largely dependent on extracellular [Na⁺]. To study sustained influences on steady state creatine concentration we measured total cellular creatine content using a fluorimetric method in 48 h incubations. We found that the total cellular creatine content was relatively independent of extracellular creatine concentration, consistent with high affinity sodium-dependent uptake balanced by slow passive efflux. Accordingly, in creatine-free incubations net creatine efflux was slow ( 5 ± 1 % of basal creatine content per day over 6 days), while creatine content in 48 h incubations was reduced by 28 ± 13% of control by the Na⁺,K⁺-ATPase inhibitor ouabain. Creatine accumulation after 48 h was stimulated by treatment with the mixed - and -adrenergic agonist noradrenaline, the -adrenergic agonist isoproterenol, the ₂-agonist clenbuterol and the cAMP analogue N⁶,2-O-dibutyryladenosine 3,5-cyclic monophosphate, but was unaffected by the ₁ adrenergic agonist methoxamine. The noradrenaline enhancement of creatine accumulation at 48 h was inhibited by the mixed - and -antagonist labetalol and by the -antagonist propranolol, but was unaffected by the ₂ antagonist phentolamine; greater inhibition was caused by the ₂ antagonist butoxamine than the ₁ antagonist atenolol. Creatine accumulation at 48 h was increased to 230 ± 6% of control by insulin and by 140 ± 13% by IGF-I (both at 3 nM). Creatine accumulation at 48 h was also increased to 280 ± 40% of control by 3,3,5-triiodothyronine (at 70 M) and to 220 ± 35% of control by amylin (60 nM). As 3,3,5-triiodothyronine, amylin and isoproterenol all stimulate the Na⁺,K⁺-ATPase, we suggest that they stimulate Na⁺-creatine cotransport indirectly by increasing the transmembrane [Na⁺] concentration gradient and membrane potential.Abbreviations IGF-I insulin-like growth factor I - IGF-II insulin-like growth factor II - T₃ 3,3,5-triiodothyronine - CGRP calcitonin gene-related peptide