The genetic control of nucleolus formation in wheat

The wheat variety Chinese Spring has four pairs of nucleolus organisers of known rDNA content. The genetic control of these has been investigated in root tip cells by cytologically scoring the number of nucleoli per cell in (a) aneuploid derivatives each having a different dosage of a particular chromosome or chromosome arm and (b) in substitution lines where nucleolus organiser chromosomes have been replaced by homologues possessing different amounts of rDNA. It has been assumed that nucleolus organiser activity is correlated with nucleolus size and thus with the presence of a cytologically visible nucleolus. Those nucleolus organisers on chromosomes 1A and 5D, which together possess only 10% of the rDNA form a visible nucleolus only infrequently in the presence of the larger nucleolus organisers on chromosomes 1B and 6B. When a major pair of organisers on chromosomes 1B or 6B is deleted, the smaller nucleolus organisers form a visible nucleolus more frequently. Similarly, when the major nucleolus organisers are replaced by organisers with less rDNA, the smaller nucleolus organisers form visible nucleoli more frequently. When a small nucleolus organiser is replaced by one with much more rDNA, a larger nucleolus is formed. These and other findings lead to the general conclusions that there is a frequently, but not invariably, seen correlation between rRNA gene number and nucleolus size. However the relative size of the nucleolus formed depends principally upon the proportion of the total active rRNA genes in the cell which are localised at the nucleolus organiser in question. Varying the dosage of at least 13 non nucleolus organiser chromosomes also resulted in changes in the number of visible nucleoli per cell. This implies the genetic control of individual nucleolus organisers is complex. Inclusion in the wheat genome of the nucleolus organiser chromosome from Aegilops umbellulata, causes suppression of the wheat nucleolus organisers, the Aegilops umbellulata organiser remaining active. This suppression is similar to that observed in many interspecific plant and animal hybrids.     

Nucleolus organizer competition in Triticum aestivum — Aegilops umbellulata chromosome addition lines

Summary The nucleolar organizer activity of wheat (Triticum aestivum, AABBDD) and Aegilops umbellulata (UU) chromosomes have been analyzed in the complete set of the chromosome addition lines by using a highly reproducible silver-staining procedure. Chromosomes 1U and 5U produce the partial inactivation of wheat nucleolar organizer chromosomes 6B, 1B and 5D. The chromosomes D and G from Ae. umbellulata, which are not SAT-chromosomes, seem to specifically influence the activity of wheat NORs. The predominant status of the U genome with respect to nucleolar competition in the Triticeae is confirmed.     

Relationships between the chromosomes of Aegilops umbellulata and wheat

 A comparative genetic map of Aegilops umbellulata with wheat was constructed using RFLP probes that detect homoeoloci previously mapped in hexaploid bread wheat. All seven Ae. umbellulata chromosomes display one or more rearrangements relative to wheat. These structural changes are consistent with the sub-terminal morphology of chromosomes 2 U, 3 U, 6 U and 7 U. Comparison of the chromosomal locations assigned by mapping and those obtained by hybridization to wheat/Ae. umbellulata single chromosome addition lines verified the composition of the added Ae. umbellulata chromosomes and indicated that no further cytological rearrangements had taken place during the production of the alien-wheat aneuploid lines. Relationships between Ae. umbellulata and wheat chromosomes were confirmed, based on homoeology of the centromeric regions, for 1 U, 2 U, 3 U, 5 U and 7 U. However, homoeology of the centromeric regions of 4 U with wheat group-6 chromosomes and of 6 U with wheat group-4 chromosomes was also confirmed, suggesting that a re-naming of these chromosomes may be pertinent. The consequences of the rearrangements of the Ae. umbellulata genome relative to wheat for gene introgression are discussed. Received: 10 July 1997 / Accepted: 19 September 1997     

The nucleolus organizers of diploid wheats revealed by in situ hybridization

Summary Labelled RNA, transcribed in vitro from wheat ribosomal DNA cloned in a bacterial plasmid, has been hybridised to metaphase chromosomes of five diploid wheats. Autoradiography of the chromosomes has provided unequivocal evidence that these genotypes possess two pairs of nucleolus organizer chromosomes. The diploid wheat accessions used possess widely differing numbers of ribosomal RNA genes.     

Physical mapping of translocation breakpoints in a set of wheat-Aegilops umbellulata recombinant lines using in situ hybridization

Aegilops umbellulata Zhuk. carries genes at Glu-U1 loci that code for a pair of high-molecular-weight glutenin subunits not found in common wheat, Triticum aestivum. Wheat-Ae. umbellulata recombinant lines were produced with the aim of transferring genes coding for glutenin subunits from Ae. umbellulata into wheat with minimal flanking material. We used fluorescent genomic in situ hybridization to evaluate the extent of recombination and to map physically the translocation breakpoints on 11 wheat-Ae. umbellulata recombinant lines. In situ hybridization was able to identify alien material in wheat and showed breakpoints not only near the centromeres but also along chromosome arms. To characterize and identify chromosomes further, including deletions along the 1U chromosome, we used simultaneous multiple target in situ hybridization to localize a tandemly repeated DNA sequence (pSc119.2) and the 18S–25S and 5S rRNA genes. One line contained an Ae. umbellulata telocentric chromosome and another two had different terminal deletions, mostly with some wheat chromosome rearrangements. Although from six independent original crosses, the other eight lines included only two types of intercalary wheat-Ae. umbellulata recombination events. Five occurred at the 5S rRNA genes on the short arm of the Ae. umbellulata chromosome with a distal wheat-origin segment, and three breakpoints were proximal to the centromere in the long arm, so most of the long arm was of Ae. umbellulata origin. The results allow characterization of recombination events in the context of the karyotype. They also facilitate the design of crossing programmes to generate lines where smaller Ae. umbellulata chromosome segments are transferred to wheat with the potential to improve bread-making quality by incorporating novel glutenin subunits without undesirable linked genes.     

Location of genes coding isozyme markers on Aegilops umbellulata chromosomes adds data on homoeology among Triticeae chromosomes

Summary Zymogram analysis was used to identify the Aegilops umbellulata chromosomes that carry the structural genes for particular isozymes. Wheat, Aegilops and wheat-Aegilops hybrid derivative lines (which contained identified Aegilops chromosomes) were tested by gel electrophoresis for isozymes of particular enzymes. It was found that Aegilops chromosome A (nomenclature according to G. Kimber 1967) carries a structural gene for 6-phosphogluconate dehydrogenase, Aegilops chromosome B carries structural genes for glucose phosphate isomerase and phosphoglucose mutase, Aegilops chromosome D carries genes for leaf peroxidases, Aegilops chromosome E carries structural genes for endosperm peroxidases, acid phosphatases and leaf esterases, Aegilops chromosome F carries a gene for embryo plus scutellum peroxidases and Aegilops chromosome G carries structural genes for endosperm alkaline phosphatases, leaf alkaline phosphatases and leaf esterases. The results obtained indicate that chromosome B is partially homoeologous of the wheat chromosomes of group 1 and 4, and chromosome E is partially homoeologous of wheat chromosomes of groups 7 and 4. Circumstantial evidence is also provided about the possible association between chromosomes C, D and A of A. umbellulata respectively with chromosomes 5, 2 and 1 of wheat.     

Chromosomal location of genes controlling seed proteins in species related to wheat

Summary The seed proteins of Chinese Spring wheat stocks which possess single chromosomes from other plant species related to wheat have been separated by gel electrophoresis in the presence of sodium dodecyl sulphate. Marker protein bands have been detected for both arms of barley chromosome 5, chromosome E (= 1R) and B (= 2R) of rye, chromosomes A,B (= 1C^u) and C (= 5C^u) of Aegilops umbellulata and chromosomes I and III of Agropyron elongatum. These studies, and previous findings, indicate that chromosome 5 of barley, chromosome 1R of rye, chromosome I of Ag. elongatum and possibly chromosome 1C^u of Ae. umbellulata are similar to chromosomes 1A, 1B and 1D in hexaploid wheat in that they carry genes controlling prolamins on their short arms and genes controlling high-molecular-weight (apparent molecular weight greater than 86,000) seed protein species on their long arms. These findings support the idea that all these chromosomes are derived from a common ancestral chromosome and that they have maintained their integrity since their derivation from that ancestral chromosome.     

Genetic control of a novel series of trypsin inhibitors in wheat and its relatives

The aneuploids of Chinese Spring wheat have been used to locate the genes(Ti-2) coding for a novel series of trypsin inhibitors to the long arms of the homoeologous group 5 chromosomes. Three allelic variants at the 5D locus were detected in a limited survey among wheat varieties, but no variation at the loci on either chromosome 5A or chromosome 5B was detected. Homoeoloci were found in a number of alien relatives, and in the majority of cases, these were present on the group 5 homoeologue. However, inAegilops umbellulata, theTi-U2 locus was located on a chromosome presumed to belong to homoeologous group 1. NoHordeum vulgare orH. chilense Ti-2 gene was expressed in a wheat background. This new marker will be especially useful as a screening mechanism for nullisomy of chromosome 5B in work aimed at introgression of alien chromatin into wheat.The Agricultural Genetics Company is thanked for financial support.     

Physical mapping of the 18S.26S rRNA multigene family in common wheat: Identification of a new locus

In situ hybridization in conjunction with deletion mapping was used to map physically the 18S.26S multigene rRNA family in Triticum aestivum L. cv. Chinese Spring. Using in situ hybridization, we report a new locus in the 7DL arm of Chinese Spring and Aegilops squarrosa, and also confirm the nucleolus organizing region (Nor) locus in the short arm of chromosome 1A at the telomeric end in Chinese Spring. Based on in situ hybridization labeling patterns, we show that rDNA exists as condensed rDNA (heterochromatic) at each end and diffused rDNA within the secondary constriction region of the Nor-B1 (1B), Nor-B2 (6B) and Nor-D3 (5D) loci. In Nor-B1, 80% of the condensed rDNA domain lies in the proximal end and 20% in the distal end joined by diffuse rDNA threads. In Nor-B2, condensed rDNA is distributed evenly at each end joined by diffuse rDNA in the middle. In Nor-D3, the base of the satellite contains a greater concentration of condensed rDNA than the tip of the short arm. On the basis of these observations, we support the model that the usual state of rDNA is inactive (facultatively heterochromatic; Hilliker and Appels 1989). A small fraction of rDNA at a specific location (usually in the middle in wheat) exists as a diffuse region (active) in condensed chromosomes.by R. Appels     

Control of Endosperm Proteins in TRITICUM AESTIVUM (Var. Chinese Spring) and AEGILOPS UMBELLULATA by Homoeologous Group 1 Chromosomes

The genetic control of major wheat endosperm proteins by homoeologous group 1 chromosomes has been studied by two-dimensional polyacrylamide gel electrophoresis. The control of at least 15 distinct protein subunits or groups of protein subunits has been allocated to chromosomes 1A, 1B and 1D of Chinese Spring wheat from the analysis of grains of aneuploid genotypes. In addition, six protein subunits have been shown to be controlled by chromosome 1C^u of the related species, Aegilops umbellulata, from studies of wheat lines carrying disomic substitutions of 1C^u chromosomes. On the basis of protein subunit patterns, chromosome 1C^u is more closely related to chromosome 1D of wheat than to chromosomes 1A or 1B.     

Variation in nucleolar organiser rRNA gene multiplicity in wheat and rye

In hexaploid wheat and diploid rye, different varieties have different numbers of ribosomal RNA genes as indicated by rRNA/DNA hybridisation. Wheat has four different chromosomes which carry nucleolar organisers. Analyses of DNA isolated from substitution lines in which each of these nucleolar organiser chromosomes of several varieties has been substituted one at a time into a common genetic background, have indicated that none of the four organiser chromosomes possess an invariant number of ribosomal RNA genes. The ribosomal RNA gene complement of the varieties investigated can be approximately accounted for by the sum of the ribosomal RNA genes on each of the four nucleolar organiser chromosomes.     

Development of the large nucleolus in the oocytes of the copepod Acanthocyclops vernalis: an electron microscope study

A central feature of oogenesis in the copepod crustacean, Acanthocyclops vernalis, is the development of a very large nucleolus in the oocytes. This nucleolus appears to be the only source of rRNA for the oocyte, as no helper cells are present. Previous work has suggested that ribosomal DNA sequences other than those found at the morphological nucleolar organizers are participating in the elaboration of this nucleolus. It has been hypothesized that chromatin diminution, which occurs during early embryonic development, may involve the loss of these rDNA sequences, which are needed only for the production of ribosomes during oogenesis. The present study examines the development of the large oocyte nucleolus at the electron microscopic level. Nucleologenesis in A. vernalis was found to proceed through 5 stages. During the first 3 stages nucleolar morphology resembled that described in other organisms. In the last 2, however, nucleolar morphology changed radically and the nucleolus was seen to increase greatly in size while breaking up into multiple subunits. The subunits initially resemble active nucleoli, although in the last stage, synthesis appears to stop, as the nucleolus was found to consist only of dense areas containing ribosome-like particles. These observations are consistent with the hypothesis that diminuted DNA contains ribosomal RNA genes.     

Physical mapping of 5S and 18S-25S rDNA and repetitive DNA sequences in Aegilops umbellulata.

An accurate physical map of the location of the 5S and the 18S-5.8S-25S rRNA genes and a repetitive DNA sequence has been produced on Aegilops umbellulata Zhuk., (2n = 2x = 14) chromosomes by in situ hybridization. Chromosome morphology together with the hybridization pattern of pSc119.2, a DNA sequence from rye, allowed identification and discrimination of different chromosomes; pSc119.2 hybridizes with all Ae. umbellulata chromosomes at the telomeres, except for the short arm of chromosome 6U, and shows intercalary sites on the long arms of chromosomes 6U and 7U. The 5S and 18S-25S rDNA have been mapped physically only on the short arms of chromosomes 1U and 5U. On chromosome 1U the order of the genes is 5S rDNA subterminal and 18S-25S rDNA more proximal, while on chromosome 5U the position of the genes is reversed. The relative order of the genes, together with the hybridization pattern of the pSc119.2, is useful in identifying whole chromosomes or chromosome segments from Ae. umbellulata in recombinant or addition lines with wheat. The data help link the physical organization of chromosomes to the genetic map. Other members of the Triticeae vary in the presence and order of the 5S and 18S-25S rDNA sequences on groups 1 and 5, indicating multiple and complex evolutionary rearrangements of the chromosome arms.     

Mapping of the nucleolus organizer region on chromosome 4 inArabidopsis thaliana

InArabidopsis thaliana the ribosomal RNA genes (rRNA genes or rDNA) are clustered in tandemly repeated blocks in two nucleolus organizer regions (NORs). Cytogenetic analysis has shown that the NORs are localized on chromosome 2 (NOR 2) and 4 (NOR 4). Recently the map position of NOR 2 was determined using a RFLP which was larger than 100 kb. In the course of a fingerprint analysis of differentArabidopsis ecotypes we have detected four rDNA polymorphisms between the ecotypes Landsberg (La) and Niederzenz (Nd). Mapping of these polymorphisms using established segregating F₂ populations reveals that all polymorphisms detected are dominant. Three of them map to the locus on the second chromosome that has been shown to harbour the NOR 2. The fourth polymorphism can be unambigously assigned to the upper arm of the fourth chromosome. This is the first polymorphism found which originates in the second rDNA cluster ofArabidopsis thaliana. It enables localization of NOR 4 and thus completes the mapping of rDNA genes in the NORs ofArabidopsis.     

Chromosome location of the ribosomal RNA genes in Triturus vulgaris meridionalis (Amphibia,Urodela)

Ribosomal genes have been localized on mitotic and lampbrush chromosomes of 20 specimens of Triturus vulgaris meridionalis by in situ hybridization with ³H 18S+28S rRNA. The results may be summarized as follows: 1) each individual shows positive in situ hybridization at the nucleolus organizing region (NOR) on chromosome XI; 2) in addition, many specimens exhibit a positive reaction in chromosomal sites other than the NOR (additional ribosomal sites); 3) the chromosomal distribution of the additional sites appears to be identical in different tissues from the same specimen and to follow a specific individual pattern; 4) the additional ribosomal sites are preferentially found at the telomeric, centromeric or C-band regions of the chromosomes involved.Abbreviations rRNA ribosomal RNA - NOR nucleolus organizer region - rDNA the DNA sequences coding for 18S+28S rRNA plus the intervening spacer sequences - SSC 0.15 M sodium chloride, 0.015 sodium citrate, pH 7     

Drosophila melanogaster has different ribosomal RNA sequences on S and Y chromosomes.

The primary structures of ribosomal RNAs transcribed from the nucleolus organizers on X and Y chromosomes of Drosophila melanogaster were compared by RNase T₁ fingerprints made with two different systems; i.e. homochromatography on DEAE-cellulose, and polyethyleneimine-cellulose thin-layer chromatography.Ribosomal RNA derived from the X-linked nucleolus organizer was obtained from a strain producing only female larvae and ribosomal RNA derived from the Y-linked nucleolus organizer was isolated from a mutant lacking the X-linked nucleolus organizer.No difference was detected between the fingerprints of 28 S RNA from these animals.In 18 S RNA, however, one oligonucleotide showed a remarkable difference in mobility. The structure of the X-linked organizer-specific oligonucleotide was 5′ U-C-U-U-U-U-U-U-C-C-U-A-U-G 3′, and that of the Y-linked organizer-specific oligonucleotide was 5′ U-C-U-C-U-U-U-U-C-C-U-A-U-G 3′, indicating one base substitution (U á3 C) between them.The absence of 5′-temninal phosphate in this oligonucleotide and available sequence data also suggest that these oligonucleotides did not come from either the 5′ or 3′ terminus of 18 S RNA.D. simulans, whose Y chromosome has no nucleolus organizer (Ritossa &; Atwood, 1966), showed an 18 S RNA fingerprint having only the X-linked organizer-specific oligonucleotide.We conclude from these results that in Drosophila the ribosomal RNA gene sequences are different for the two nucleolus organizers located on the X and Y chromosomes. The implications of those findings concerning the parallel evolution of these genes are discussed.     

Ribosomal RNA Cistron Multiplicity and Nucleolar Organizers in Hexaploid Wheat

The ribosomal DNA (DNA complementary to ribosomal RNA) content of twelve different wheat genotypes has been studied. Some of these genotypes are aneuploids with deletions or additions of chromosomes bearing nucleolar organisers. The rDNA contents of these genotypes provide several examples of a clear departure from a correlation between the number of rRNA cistrons and the number of nucleolar organisers. Thus the number of rRNA cistrons per nucleolar organiser is not constant in wheat. Wheat DNA was found to have a mean buoyant density of approximately 1.702 g/cc for all genotypes studied and rRNA hybridized selectively to DNA of buoyant density approximately 1.710 g/cc. The thermal stabilities of all the rRNA/DNA hybrids were essentially identical.     

The nucleolus organizers of Plethodon and Aneides located by in situ nucleic acid hybridization with Xenopus 3H-ribosomal RNA

The main clusters of ribosomal genes, or nucleolus organizers, have been located by in situ nucleic acid hybridization of Xenopus laevis ³H labelled ribosomal RNA to mitotic chromosomes in squash preparations of intestinal epithelium from 7 species of Plethodon and 3 species of Aneides. The species used were chosen on account of having well known karyotypes and genome sizes. The Plethodon species covered a range of genome size of 20–69.4 pg. The locations of those nucleolus organizers that could be detected by autoradiography after in situ hybridization varied from species to species, and in Aneides there were differences between two populations of the same species. On the other hand, some distantly related species of Plethodon, with widely different genome sizes, had nucleolus organizers at corresponding positions. The results are discussed in relation to ideas on karyotype stability, homosequentiality and chromosome repatterning.     

Analysis of a set of homoeologous group 1 wheat-Aegilops umbellulata recombinant chromosome lines using genetic markers

Eleven wheat-Ae. umbellulata recombinant lines involving chromosome 1U, including an important high-molecular-weight glutenin locus, were characterized by protein and RFLP markers. Four 1U-1A recombinants, one 1U-1B recombinant, two 1U deletions with either nullisomy for chromosome 1A or 1B and a 1U ditelosomic addition line were detected, while 3 recombinant lines involved 1U and non-homoeologous wheat chromosomes. Similar recombination events were found in independent lines, and no small segmental translocations of Ae. umbellulata chromatin were detected. Correlation of the markers with physical maps of the wheat-Ae. umbellulata breakpoints obtained using in situ hybridization enabled the marker order to be established on chromosomes 1A, 1B and 1U. The short arm of chromosome 1A probably differs from both 1U and 1B by one inversion. As now being found to be universal in the Triticeae, clustering of the genetical map in the distal physical regions of the group 1 chromosomes was found. Received: 3 June 1996 / Accepted: 14 June 1996