The relation of radiation sensitivity to pronuclear chromosome structure

After treatment of spermatozoa of Phryne cincta from a Berlin population (bs) with low crossing-over and from an Alpine population (as) with high crossing-over frequency, egg mortality was ascertained and chromosomal mutation rate determined by examination of the polytene chromosomes of the F₁ progeny. — The as stock exhibits a 1.33 times greater radiation sensitivity than the bs stock, both in chromosomal mutation and in egg mortality rates. There is no evidence that factors other than structural ones account for the differences in radiation sensitivity. From inversion length measurements, it was proposed that a reduction of the spiral diameter of the paternal pronucleus chromosomes is responsible for a higher site number and thereby for a greater radiation sensitivity.Dedicated to Prof. Dr. B.E. Wolf, initiator of this work, in honour of his 70th birthday on September 27, 1978     

PREMATURE CHROMOSOME CONDENSATION OF THE KARYOGAMY-BLOCKED SPERM PRONUCLEUS IN THE FERTILIZATION OF FUCUS DISTICHUS (FUCALES,PHAEOPHYCEAE)1

Mitosis of egg and sperm pronuclei of Fucus distichus subsp. evanescens (C. Agardh)Powell was examined by fluorescence and electron microscopy when migration of the sperm pronucleus and, as a result, karyogamy were blocked by colchicine treatment after plasmogamy. Chromosome condensation was obsewed in both pronuclei Microspectrophotometric studies after staining the nuclei with mithramycin A clearly showed that DNA synthesis ocurred in the egg pronucleus but not in the sperm pronucleus. This means that chromosomes condensed prematurely in the sperm pronucleus (premature chromosome condensation). In some cases, the egg chromosomes became arranged on a metaphase plate, whereas the sperm chromosomes lay scattered near the egg pronucleus. Immuno fluorescence microscopy using anti-β-tubulin antibody confirmed that a normal spindle was formed at the egg pronucleus. A pair of centrioles existed at the two poles of this spindle. The sperm nuclear membrane disappeared, and microtubules radiated to the sperm chromosomes from one pole of the egg spindle.     

Modification du caryotype par une inversion péricentrique à l'état homozygote chez l'Amphibien Urodèle Pleurodeles waltlii Michahelles

A cytogenetic study on four generations of the newt Pleurodeles waltlii has resulted in a stock homozygous for a pericentric inversion in chromosomes no. 6.-The chromosomal rearrangement has first been detected at the heterozygous state in a female resulting from a cross between a normal female and a male treated with X rays. — The rearranged chromosome is very easily recognizable under direct microscopic investigation. The heterozygotes and the homozygotes for the aberration grow normally; thus, the inversion constitutes a nuclear marker which can be readily used.     

Structure and organization of rhodophyte and chromophyte plastid genomes: implications for the ancestry of plastids

Summary Recombinational repair is the means by which DNA double-strand breaks (DSBs) are repaired in yeast. DNA divergence between chromosomes was shown previously to inhibit repair in diploid G1 cells, resulting in chromosome loss at low nonlethal doses of ionizing radiation. Furthermore, 15–20% divergence prevents meiotic recombination between individual pairs of Saccharomyces cerevisiae and S. carlsbergensis chromosomes in an otherwise S. cerevisiae background. Based on analysis of the efficiency of DSB-induced chromosome loss and direct genetic detection of intragenic recombination, we conclude that limited DSB recombinational repair can occur between homoeologous chromosomes. There is no difference in loss between a repair-proficient Pms⁺ strain and a mismatch repair mutant, pms1. Since DSB recombinational repair is tolerant of diverged DNAs, this type of repair could lead to novel genes and altered chromosomes. The sensitivity to DSB-induced loss of 11 individual yeast artificial chromosomes (YACs) containing mouse or human (chromosome 21 or HeLa) DNA was determined. Recombinational repair between a pair of homologous HeLa YACs appears as efficient as that between homologous yeast chromosomes in that there is no loss at low radiation doses. Single YACs exhibited considerable variation in response, although the response for individual YACs was highly reproducible. Based on the results with the yeast homoeologous chromosomes, we propose that the potential exists for intra- YAC recombinational repair between diverged repeat DNA and that the extent of repair is dependent upon the amount of repeat DNA and the degree of divergence. The sensitivity of YACs containing mammalian DNA to ionizing radiation-induced loss may thus be an indicator of the extent of repeat DNA.     

A model for the production of chromosome damage by Mitomycin C

A model is presented, which is based on the idea that the chromosome damage induced by Mitomycin C results directly from repair or misrepair of DNA molecules responsible for the linear continuity of the chromosomes. Testing the model with human cells confirms the prediction that exchanges with complete joining occur between chromosome regions containing homologous, repetitive DNA. Most probably incomplete exchanges involve homologous, but unique DNA sequences. — Prerequisites determining the MC-induced aberration patterns are the distribution of the chemical due to compartmentalization, the somatic pairing of chromosomes, and the occurrence of repeated or unique DNA sequences. — The scoring of different classes of MC-induced chromatid aberrations (attenuation, constriction, gap, break) in alcohol/acetic acid-fixed chromosome has a limited value.     

Gueriniella and the cytotaxonomy of iceryine coccids (Coccoidea:Margarodidae)

The chromosome complement of Gueriniella serratulae (F.) Fernald, Tribe Iceryini, Subfamily Monophlebinae of the primitive coccid Family Margarodidae, is 2 n =6; males are unknown. Reproduction is by thelytokous parthenogenesis. Meiosis is normal; polar bodies do not contribute to the formation of a zygote-substitute nucleus; and development is initiated by a haploid cleavage of the female pronucleus. Diploidy is restored by the fusion of the 2 nuclei resulting from this division. With the exception of Gueriniella, all cytologically known Iceryini are haplo-diploids, with a chromosome complement of n=2. The hypothesis is proposed that Gueriniella is a persistent primitive stemming from the ancestral iceryine stock prior to the loss of the sex chromosomes and the evolution of haplo-diploidy within the tribe. A review of the available evidence from cytology, taxonomy, endosymbiosis, behavior and distribution shows good agreement with this interpretation.Dedicated to Professor Jakob Seiler on the occasion of his 80th birthday.Supported in part by National Science Foundation Grant GB-1922 to S. Hughes-Schrader; we also gratefully acknowledge the support of Professor G. Russo, Director of the Entomological Laboratory, Portici.     

The action of N-methyl-N-nitrosourea on non-established human cell lines in vitro. II. Non-random distribution of chromatid aberrations in diploid and Down's cells.

Chromatid gaps, breaks and aberrations involved in interchanges induced by N-methyl-N-nitrosourea (MNU) were found non-randomly distributed on individual chromosomes and chromosome segments (G bands) both in human diploid fibroblasts with trisomy 21 cultured in vitro. Aberration events were located exclusively in pale G bands. Considering cells in the first post-treatment mitosis, the pattern of aberration distribution, as revealed by the position of hot spots, varied with recovery time and was different in diploid and Down's cells. In comparison with diploid cells, the X chromosomes of Down's cells were not involved in aberrations. Despite the higher aberration frequencies of Down's cells, the number of hot spots and the proportion of aberrations located in hot spots were not increased in this cell type. Therefore, the increased chromosomal sensitivity to MNU of Down's cells does not reflect an increased sensitivity of special chromosomes or chromosome sites.     

Cytogenetic studies on <Emphasis Type="Italic">Metasequoia glyptostroboides</Emphasis>, a living fossil species

The chromosome morphology and meiotic pairing behavior in the pollen mother cells (PMCs) of Metasequoia glyptostroboides were investigated. The results showed that: (1) The chromosome number of the PMCs was 2n=22. (2) The PMCs developed in the successive manner, and the nucleoids in the dynamic development were similar to those of the other gymnosperms. (3) At prophase, most of the chromosomes were unable to be identified distinctively because the chromosomes were long and tangled together. The chromosome segments were paired non-synchronously. At pachytene, the interstitial or terminal regions of some bivalents did not form synapsis and the paired chromosomes showed difference in sizes, indicating that there were structure differences between the homologous chromosomes. (4) At diakinesis, the ring bivalents showed complicated configurations due to the differences in location and number of chiasmata. In addition, there were cross-linked bivalents. (5) At metaphase I, the chromosome configuration of each cell was 8.2II ⁰ + 1.1II + 1.3II ⁺ + 0.8I. Most of the chromosomes were ring bivalents, but some were cross-linked bivalents, rod bivalents, or univalents. (6) 15\% PMCs at anaphase I and 22\% PMCs at anaphase II presented chromosome bridges, chromosome fragments, micronuclei, and lagging chromosomes. Twenty seven percent microspores finally moved into one to three micronuclei. Twenty five percent pollens were abortive. The results indicated that the observed individual of M. glyptostroboideswas probably a parpcentric inversion heterozygote, and there were structural and behavioral differences between the homologous chromosomes. The chromosomal aberration of M. glyptostroboidesmay play an important role in the evolution of this relict species, which is known as a living fossil. Further evidence is needed to test whether the differences between homologous chromosomes were due to hybridization.     

Trends in chromosome evolution in the genus Hypostomus Lacépède, 1803 (Osteichthyes, Loricariidae): a new perspective about the correlation between diploid number and chromosomes types

Phylogenetic relationships and identification of species of the genus Hypostomus is still unclear. Considering this, cytogenetics may prove itself as an important tool in understanding the systematic of this genus. Reviews in Hypostomus indicate that the diploid number ranges from 54 to 84 chromosomes, and the increase in diploid number has been associated to higher percentages of subtelocentric and acrocentric chromosomes. Although there is a high number of species in the genus, there are relatively few papers concerning Hypostomus cytogenetics, and most of the data is published as grey literature. With the aim to understand the chromosomal evolution in the genus (correlation between diploid number x chromosomes types), H. ancistroides and H. topavae from the Piquiri River, Upper Paraná River basin, were cytogenetically analyzed, and the diploid number observed was 68 and 80 chromosomes, respectively. Additional data on the diploid number and chromosome formulae was compiled from papers (27 analyses) and abstracts from grey literature (77 analyses). Our analysis shows no correlation between chromosome numbers and percentages of subtelocentric and acrocentric chromosomes for most of the species, since there is considerable variation between these percentages even between species with the same diploid number, indicating that the proportion of chromosome types is not always associated to diploid numbers.     

Differences between genetic and physical centromere distances in the case of two genes for male sterility in barley

Summary Linkage studies with thirty translocations (one of the two chromosomes involved being number 4) in relation to msg24 (chromosome 4) and thirteen translocations (one of the two chromosomes involved being number 6) in relation to msg6 (chromosome 6) show without exception close linkage for all combinations tested. The results indicate that both genes are located genetically in or close to the centromere regions of their chromosomes.Cytological analysis of two BTT stocks (balanced tertiary trisomics) ascertained the respective chromosome arms (both msg24 and msg6 on the short arms) and revealed marked differences between genetic and physical centromere distances. The reason is obviously the high content of centromeric heterochromatin occupying both the chromosome arms involved.     

Contributions to the cytology of endosperm in angiosperms-XII.Pisum sativum L.

A study of the cytology of endosperm ofPisum sativum, pea, fixed at different stages of development reveals that it remains free nuclear throughout its entire life. The nuclei are extremely polymorphic and differ in size from each other. The nuclei increase proportionately in size with the advancement in endosperm age.The haploid chromosome number of the taxon was verified asn=7. The endosperm nuclei were normally triploid with 3n=21 chromosomes, but higher polyploidy (6n and 12n) and aneuploidy were also recorded in small proportions. Nuclear fusions and aberrations such as irregular separation of chromosomes, sticky bridges and laggards are believed to be responsible for the origin of polyploid nuclei.Accumulation of mitotic aberrations including bridges and laggards are considered to result in reduced divisional activity thereby leading to endosperm breakdown with the consequent low seed set in some cases.     

Physical mapping of rDNA genes establishes the karyotype of almond

The localisation of ribosomal RNA genes on chromosomes of almond (Prunus amygdalus, 2n = 16) was studied by fluorescence in situ hybridisation. Simultaneous double-colour hybridisation with both 18S–5.8S–25S and 5S rDNA probes demonstrated that all chromosomes can be identified. In spite of the small size, differences in length between chromosomes that hybridised with the same rDNA probe as well as between chromosomes without hybridisation signal are apparent. Chromosomes were ordered in the karyotype according to their length. The 18S-5.8S-25S rDNA genes were detected in subdistal positions of chromosomes 2, 3, and 8. Sites located on chromosomes 2 and 3 carry a higher number of repeats than the site of chromosome 8. The 5S rDNA genes were found proximally located on chromosomes 5 and 7, the signal on chromosome 5 showing higher intensity than the signal on chromosome 7. Chromosomes 1, 4, and 6 show no hybridisation signal.     

Inheritance of Arabidopsis DNA in offspring from Brassica napus and A. thaliana somatic hybrids

 Chromosome counts and RFLP markers mapped to Arabidopsis thaliana were used to determine the proportion of eliminated chromosomes and retained A. thaliana DNA in the back-crossed (BC) progeny derived from symmetric and asymmetric somatic hybrids between Brassica napus and A. thaliana. All plants were analysed for the presence of two RFLP markers per chromosome, preferably with one located on each chromosome arm. A reduction in both A. thaliana RFLP markers and chromosome numbers was found in the BC₁ and BC₂ generations of the symmetric hybrids as well as in the BC₁ generation of the asymmetric hybrids. In the symmetric hybrids, two back-crosses to B. napus were required to reduce the frequency of retained A. thaliana loci to 42.4% and mean chromosome number to 39.4. In comparison, the BC₁ progeny of the asymmetric hybrids had 16% of the analysed A. thaliana loci present and an average of 38.4 chromosomes maintained. When the frequency of A. thaliana chromosomes with both analysed loci maintained was compared with the frequency of chromosomes with one locus lost and one kept, a reduction in the number of complete chromosomes between BC₁ and BC₂ derived from the symmetric hybrids was observed. Among the BC₁ plants in the asymmetric group the situation was different, with higher amounts of incomplete donor chromosomes compared to whole chromosomes. The results indicate that A. thaliana chromosome fragments are more often found in the progeny of irradiated hybrids, while back-crossed symmetric hybrids have more complete chromosomes. Received: 2 April 1998 / Accepted: 14 July 1998     

Chromosome differentiation in diploid species of Lotus (Leguminosae)

Summary Meiotic chromosome behavior was studied in seven diploid species of Lotus (L. alpinus Schleich., L. japonicus (Regel) Larsen, L. filicaulis Dur., L. schoelleri Schweinf., L. krylovii Schischk. and Serg., L. tenuis Waldst. et Kit., L. corniculatus var. minor Baker) and in 51 interspecific hybrids from 16 different crosses. Meiosis in the diploid species was quite regular. In a high proportion of the PMC's of the hybrids there was close chromosome homology with a normal association of 6 II's. However, meiotic irregularities including bridges, lagging chromosomes, univalents, and quadrivalents, occurred in a small percentage of the cells. The late separation of bivalents, the presence of quadrivalents, and inversion bridges with fragments, would indicate for some hybrids that certain chromosomes were structurally differentiated. The large number of rod bivalents observed at diakinesis was also highly suggestive that genetic nonhomology in one chromosome arm could contribute to the frequency of this type of bivalent. Therefore, the maximum number of 6 II's which occurred in a high percentage of cells may be misleading in that cryptic structural differences between chromosome arms, or segments, are not revealed. Pollen fertility in the species and hybrids was not correlated with meiotic irregularities suggesting that pollen fertility is genotypically controlled.     

Distribution of mobile dispersed genes (mdg-1 and mdg-3) in the chromosomes of Drosophila melanogaster

The localization of mobile dispersed genes (mdg-1 and mdg-3) was studied by in situ hybridization with the polytene chromosomes of 20 laboratory stocks of Drosophila melanogaster. The average number of sites was 20 for mdg-1 and 12 for mdg-3, but the actual number varied from stock to stock (14–27 for mdg-1 and 5–18 for mdg-3). A total of 182 possible sites have been detected for mdg-1 and 123 sites for mdg-3. In spite of the individual and interstock variation, the distribution over chromosomes was found to be nonrandom for mdg-3 and especially for mdg-1. Frequently occurring sites of mdg-1 hybridization were revealed, most of which coincided with regions of intercalary heterochromatin, especially in chromosome 2.     

Examination of DNA sequences undergoing chromatin conformation changes at a variegating breakpoint in Drosophila melanogaster

Position effect variegation in Drosophila melanogaster is associated with the inability of certain genes to be correctly expressed in a proportion of cells, giving a mosaic phenotype. The lack of expression is thought to be due to alterations in the gene's chromatin structure due to its proximity to a region of heterochromatin. Because of the difficulties involved, there is little biochemical data to support the intuitively appealing model of heterochromatin spreading used to explain this phenomenon.Differences in restriction fragment length were used to distinguish DNA regions from either normal (non-position affected) or rearranged (position affected) chromosomes so as to examine possible changes in gene copy number and the effects of endogenous nucleases. DNA sequences at the breakpoint of In (1)w ^m4, which variegates for the white gene, were assayed under conditions where the chromatin conformation was altered using second site modifier mutations (Su(var) or En(var)). No change in the DNA sequerice copy number was observed at either chromosome breakpoint, relative to wild type, when either suppressor or enhancer mutations were present. Therefore copy number change, through differential polyploidization or somatic gene loss, is not affected by Su(var) or En(var) induced changes in the chromatin conformation.Initial experiments showed a gross difference in the sensitivity of DNA to endogenous nucleases that appeared associated with Su(var) and En(var) mutations. En(var) mutation bearing samples appeared delayed in the digestion, relative to Su(var). This differential sensitivity seemed to be genome-wide as there was no detectable difference between either breakpoint of In(1)w ^m4 or the sequences on the homologous w ^- chromosome. However, after isogenizing the genetic background, the previously noted difference between the Su(var) and En(var) mutations was eliminated. In studies dealing with nuclease digestion of chromatin, the isogenization of genetic background is essential before meaningful comparisons can be made.     

Observations on the effect of X-ray alone and in combination with ultrasound on human chromosomes

Summary Human peripheral blood was treated with ultrasound either before or after irradiation, and chromosome aberrations in lymphocytes of peripheral blood cultures compared to those resulting from an equivalent dose of irradiation given alone.When peripheral blood is sonicated at a high intensity (3 W/cm²) for 10 min after irradiation, there is an increase in aberration frequency as compared to control samples receiving the equivalent radiation dose alone. However, should the blood be sonicated at the same frequency and for the same time period before radiation there is no significant increase in total chromosome aberrations over the irradiated controls. On the contrary a significant decreases occurs in certain classes of aberration.When sonification with a lower intensity (20 mW/cm²) was used in combination with irradiation the reverse effect was noted. Ultrasound administered for 10 min after radiation caused no significant increase in aberrations. On the contrary increasing the period of sonification to one hour resulted in a lowering of all types of aberration, significant in the case of dicentrics and total chromosome aberrations, when compared to irradiation alone. Reversing the order of treatment again resulted in the opposite effect to that achieved with comparable experiments at high intensities of sonification. Ultrasound before radiation did not produce lower breakage rates. Instead, when the period of sonification was increased to one hour, the number of aberrant cells, fragments, and total aberrations rose significantly over controls.It is suggested that sonification produces chemical changes affecting cellular repair systems, which when combined with ionising radiation, results in an increased or decreased repair effect depending on the dose, duration, and order of treatment.Dedicated to Prof. Dr. Felix Mainx on the occasion of his 80th birthday     

Polyploidy and reproductive patterns in the root-knot nematode Meloidogyne hapla

A total of 32 populations and egg mass isolates of Meloidogyne hapla obtained from various geographical areas were studied cytologically and with respect to their mode of reproduction. In 29, maturation of oocytes is by regular meiosis. The reduced chromosome number at metaphase I is 17 in 18 populations, 16 in 8, and 15 in 3 populations. Reproduction in all these populations is by cross-fertilization, although nonfertilized eggs can develop by parthenogenesis. In the latter case, the two groups of telophase chromosomes of the second maturation division become enclosed in the same pronucleus, thus reestablishing the somatic chromosome number. Maturation of spermatocytes in three populations studied is by regular meiosis and the reduced chromosome number appears to be equal to that of the oocytes. In the remaining three populations, no synapsis takes place and the somatic number of 45 chromosomes is observed at metaphase of the single maturation division of both oocytes and spermatocytes. Reproduction is by obligatory mitotic parthenogensis. It is postulated that the basic chromosome number for the genus is nine and that the facultatively parthenogenetic populations are tetraploid, whereas, the obligatorily parthenogenetic populations are pentaploid. A preliminary scheme of the phylogeny in the family Heteroderidae is given.     

Genetic and cytological characterisation of fusion chromosomes of Dictyostelium discoideum

Abnormally large chromosomes which appear to result from the fusion of 2 chromosomes of the normal karyotype have been found in diploids of Dictyostelium discoideum formed by parasexual fusion of haploid strains HU483 (n=7) and HU245 (n=7). These fusion chromosomes appear to be the products of the tandem translocation of most, if not all, of one acrocentric chromosome to the telomere of a second acrocentric. Thus the chromosome number of the diploids is reduced from the normal 2n=14 to 2n=13 with the formation of an abnormally large acrocentric fusion chromosome. Experimental haploidisation of such diploids results in two types of products, those with a normal 7 chromosome karyotype and those with an abnormal 6 chromosome karyotype which contains the fusion chromosome. Genetic analysis of haploid segregants indicates that linkage groups II and VII are involved in this fusion. Phenotypes of recombinant diploids obtained following mitotic crossing-over establishes that linkage group II is proximal to linkage group VII. Cytological examination of the karyotypes of haploid strains bearing the fusion chromosome suggest that chromosome 2 may correspond to linkage group II and chromosome 3 to linkage group VII. Haploid strains bearing the fusion chromosome grow and develop normally so little or no genetic information can have been lost in the fusion event. While the nature of this event is unknown it may have involved aberrant recombinational DNA repair since the parental haploid strain HU483 bears the radB13 DNA repair mutation.     

Development of <Emphasis Type="Italic">Triticum aestivum-Leymus racemosus</Emphasis> translocation lines using gametocidal chromosomes

Specific chromosomes of certain Aegilops species introduced into wheat genome background may often facilitate chromosome breakage and refusion, and finally result in a variety of chromosome restructuring. Such a phenomenon is commonly called gametocidal effect of the chromosomes. The chromosome 2C of Ae. cylindrica is one of such chromosomes. In the present study, scab resistant wheat-L. racemosus addition lines involving chromosomes Lr.2 and Lr.7 were crossed to wheat-Ae. cylindrica disomic addition line Add2C. Then F₁ hybrids were subsequently backcrossed with wheat cv “Chinese Spring”. BC₁ plants with chromosome structural aberration were identified by C-banding. In the self-pollinated progenies of these plants, three translocation lines were developed and characterized by mitotic and meiotic analysis combined with C-banding and fluorescent in situ hybridization (FISH) using biotin-labeled genomic DNA of L. racemosus as probe. Some other putative translocation lines to be further characterized were also found. The practicability and efficiency of the translocation between wheat and alien chromosomes induced by gametocidal chromosomes, as well as the potential use of the developed alien translocation lines were also discussed.