Satellite DNA and heterochromatin of the flour beetle Tribolium confusum

The Low-Copy-Number Satellite DNAs of the Model Beetle Tribolium castaneum

The red flour beetle Tribolium castaneum is an important pest of stored agricultural products and the first beetle whose genome was sequenced. So far, one high-copy-number and ten moderate-copy-number satellite DNAs (satDNAs) have been described in the assembled part of its genome. In this work, we aimed to catalog the entire collection of T. castaneum satDNAs. We resequenced the genome using Illumina technology and predicted potential satDNAs via graph-based sequence clustering. In this way, we discovered 46 novel satDNAs that occupied a total of 2.1% of the genome and were, therefore, considered low-copy-number satellites. Their repeat units, preferentially 140-180 bp and 300-340 bp long, showed a high A + T composition ranging from 59.2 to 80.1%. In the current assembly, we annotated the majority of the low-copy-number satDNAs on one or a few chromosomes, discovering mainly transposable elements in their vicinity. The current assembly also revealed that many of the in silico predicted satDNAs were organized into short arrays not much longer than five consecutive repeats, and some of them also had numerous repeat units scattered throughout the genome. Although 20% of the unassembled genome sequence masked the genuine state, the predominance of scattered repeats for some low-copy satDNAs raises the question of whether these are essentially interspersed repeats that occur in tandem only sporadically, with the potential to be satDNA "seeds".

Reference-Guided De Novo Genome Assembly of the Flour Beetle Tribolium freemani

The flour beetle Tribolium freemani is a sibling species of the model organism and important pest Tribolium castaneum. The two species are so closely related that they can produce hybrid progeny, but the genetic basis of their differences has not been revealed. In this work, we sequenced the T. freemani genome by applying PacBio HiFi technology. Using the well-assembled T. castaneum genome as a reference, we assembled 262 Mb of the T. freemani genomic sequence and anchored it in 10 linkage groups corresponding to nine autosomes and sex chromosome X. The assembly showed 99.8% completeness of conserved insect genes, indicating a high-quality reference genome. Comparison with the T. castaneum assembly revealed that the main differences in genomic sequence between the two sibling species come from repetitive DNA, including interspersed and tandem repeats. In this work, we also provided the complete assembled mitochondrial genome of T. freemani. Although the genome assembly needs to be ameliorated in tandemly repeated regions, the first version of the T. freemani reference genome and the complete mitogenome presented here represent useful resources for comparative evolutionary studies of related species and for further basic and applied research on different biological aspects of economically important pests.

Cytogenetic analysis of Lagria villosa (Coleoptera, Tenebrionidae): emphasis on the mechanism of association of the Xy(p) sex chromosomes

The Xy(p) sex determination mechanism is the system most frequent and ancestral to Coleoptera. Moreover, the presence of argyrophilous material associated with the sex bivalent is described as being responsible for the maintenance and association of these chromosomes. There are no karyotype data available regarding the genus Lagria and no consensus in the literature regarding the argyrophilous material present in the lumen of sex bivalent. Therefore, the aim of this work was to investigate the mechanism of sex chromosome bivalent association in Lagria villosa by analyzing the argyrophilous nature of the material present in the Xy(p) lumen. It was also intended to characterize L. villosa cytogenetically. The analysis of meiotic cells showed 2n = 18 = 16+Xy(p) for males and 2n = 18 = 16+XX in females and the meiotic formula was 2n = 8(II)+Xy(p). The C-banding showed blocks of pericentromeric heterochromatin in all chromosomes except in the y(p) chromosome. In these regions, the use of fluorochromes revealed the presence of heterochromatin containing GC rich DNA sequences. The study of synaptonemal complex showed a gradual increase in the electron-density of the axial elements of the sex chromosomes and their association with strongly electron-dense material. The pepsin pretreatment revealed that the material impregnated by silver is protein.

Cytogenetics of the darkling beetles Zophobas aff. confusus and Nyctobates gigas (Coleoptera, Tenebrionidae)

Males of Zophobas aff. confusus and Nyctobates gigas (Tenebrionidae) collected in the State of Pernambuco, Brazil, were studied through conventional staining, C-banding, silver nitrate impregnation (AgNO₃), and the base specific fluorochromes CMA₃ and DAPI. Z. aff. confusus was found to have 2n = 20 (9+Xyp) while N. gigas exhibited 2n = 18 (8+neoXY). Large pericentromeric blocks of constitutive heterochromatin (CH) were detected throughout the autosomal complement of the two species, except in one autosomal pair of N. gigas in which no heterochromatic block was observed. The sex chromosomes of both species were almost totally heterochromatic. Double staining with CMA₃/DA (distamycin) and DAPI/DA marked CH in Z. aff. confusus. However, DAPI staining was more intense. N. gigas was found to possess blocks of CH-positive CMA₃ and homogeneous DAPI. AgNO₃ staining also revealed differences between the two species. In Z. confusus an NOR was observed in the sexual bivalent Xyp and N. gigas was found to have an autosomal NOR.

Karyotype analysis of four jewel-beetle species (Coleoptera, Buprestidae) detected by standard staining, C-banding, AgNOR-banding and CMA3/DAPI staining

The male karyotypes of Acmaeodera pilosellae persica Mannerheim, 1837 with 2n=20 (18+neoXY), Sphenoptera scovitzii Faldermann, 1835 (2n=38-46), Dicerca aenea validiuscula Semenov, 1895 - 2n=20 (18+Xyp) and Sphaerobothris aghababiani Volkovitsh et Kalashian, 1998 - 2n=16 (14+Xyp) were studied using conventional staining and different chromosome banding techniques: C-banding, AgNOR-banding, as well as fluorochrome Chromomycin A3 (CMA3) and DAPI. It is shown that C-positive segments are weakly visible in all four species which indicates a small amount of constitutive heterochromatin (CH). There were no signals after DAPI staining and some positive signals were discovered using CMA3 staining demonstrating absence of AT-rich DNA and presence of GC-rich clusters of CH. Nucleolus organizing regions (NORs) were revealed using Ag-NOR technique; argentophilic material mostly coincides with positive signals obtained using CMA3 staining.

Structure and population dynamics of the major satellite DNA in the red flour beetle Tribolium castaneum

In the beetle genus Tribolium, satellite DNAs comprise a significant amount of pericentromeric heterochromatin and are characterized by rapid turnover resulting in species specific profiles. In the present work we characterize the major pericentromeric satellite DNA TCAST of the beetle T. castaneum and analyse its population dynamics. Using direct sequencing of genomic PCR products we show that the TCAST satellite exists in the form of two related subfamilies: Tcast1a and Tcast1b that make up 20 and 15% of the genome, respectively. Tcast1a and Tcast1b have consensus sequences of 377 and 362 bp respectively, share an average similarity of 79% and are characterized by a divergent, subfamily specific region of approximately 100 bp. The two subfamilies are prevalently organized in the interspersed form, although a portion exists in the form of homogenous tandem arrays composed of only Tcast1a or Tcast1b. The pattern of restriction enzyme digestion indicates that Tcast1a and Tcast1b are organized in composite higher order repeats. Comparison of sequence variability of Tcast1a and Tcast1b among ten strains reveals a difference in the frequency of particular mutations present at some positions. However, no difference in the organization and in the amount of subfamilies was detected among strains. The results show that direct genomic sequencing can be a useful method for the detection of population specific features of satellite DNA. In the case of TCAST satellite DNA, changes in the mutational profiles seem to represent the first step in the genesis of a population specific satellite profile.

Cytogenetic analysis of Astylus antis (Perty, 1830) (Coleoptera, Melyridae): Karyotype, heterochromatin and location of ribosomal genes

Cytogenetic analysis of Astylus antis using mitotic and meiotic cells was performed to characterize the haploid and diploid numbers, sex determination system, chromosome morphology, constitutive heterochromatin distribution pattern and chromosomes carrying nucleolus organizer regions (NORs). Analysis of spermatogonial metaphase cells revealed the diploid number 2n = 18, with mostly metacentric chromosomes. Metaphase I cells exhibited 2n = 8II+Xyp and a parachute configuration of the sex chromosomes. Spermatogonial metaphase cells submitted to C-banding showed the presence of small dots of constitutive heterochromatin in the centromeric regions of nearly all the autosomes and on the short arm of the X chromosome (Xp), as well as an additional band on one of the arms of pair 1. Mitotic cells submitted to double staining with base-specific fluorochromes (DAPI-CMA(3) ) revealed no regions rich in A+T or G+C sequences. Analysis of spermatogonial mitotic cells after sequential Giemsa/AgNO (3) staining did not reveal any specific mark on the chromosomes. Meiotic metaphase I cells stained with silver nitrate revealed a strong impregnation associated to the sex chromosomes, and in situ hybridization with an 18S rDNA probe showed ribosomal cistrons in an autosomal bivalent.

Parallelism in evolution of highly repetitive DNAs in sibling species

Characterization of heterochromatin in the flour beetle Tribolium audax revealed two highly repetitive DNA families, named TAUD1 and TAUD2, which together constitute almost 60% of the whole genome. Both families originated from a common ancestral approximately 110-bp repeating unit. Tandem arrangement of these elements in TAUD1 is typical for satellite DNAs, whereas TAUD2 represents a dispersed family based on 1412-bp complex higher-order repeats composed of inversely oriented approximately 110 bp units. Comparison with repetitive DNAs in the sibling species Tribolium madens showed similarities in nucleotide sequence and length of basic repeating units and also revealed structural and organizational parallelism in tandem and dispersed families assembled from these elements. In both Tribolium species, one tandem and one dispersed family build equivalent distribution patterns in the pericentromeric heterochromatin of all chromosomes including supernumeraries. Differences in the nucleotide sequence and in the complexity of higher-order structures between families of the same type suggest a scenario according to which rearranged variants of the corresponding ancestral families were formed and distributed in genomes during or after the speciation event, following the same principles independently in each descendant species. We assume that random effects of sequence dynamics should be constrained by organizational and structural features of repeating units and possible requirements for spatial distribution of particular sequence elements. An interspersed pattern of repetitive families also points to the intensive recombination events in heterochromatin. Synergy between the meiotic bouquet stage and satellite DNA sequence dynamics could make a positive feedback loop that promotes the observed genome-wide distribution. At the same time, considering the abundance of these DNAs in heterochromatin spanning the (peri)centromeric chromosomal segments, we speculate that diverged repetitive sequences might represent the DNA basis of reproductive barrier between the two sibling species.

Analysis of repetitive DNA distribution patterns in the Tribolium castaneum genome

BACKGROUND

Insect genomes vary widely in size, a large fraction of which is often devoted to repetitive DNA. Re-association kinetics indicate that up to 42% of the genome of the red flour beetle, Tribolium castaneum, is repetitive. Analysis of the abundance and distribution of repetitive DNA in the recently sequenced genome of T. castaneum is important for understanding the structure and function of its genome.

RESULTS

Using TRF, TEpipe and RepeatScout we found that approximately 30% of the T. castaneum assembled genome is composed of repetitive DNA. Of this, 17% is found in tandem arrays and the remaining 83% is dispersed, including transposable elements, which in themselves constitute 5-6% of the genome. RepeatScout identified 31 highly repetitive DNA elements with repeat units longer than 100 bp, which constitute 7% of the genome; 65% of these highly repetitive elements and 74% of transposable elements accumulate in regions representing 40% of the assembled genome that is anchored to chromosomes. These regions tend to occur near one end of each chromosome, similar to previously described blocks of pericentric heterochromatin. They contain fewer genes with longer introns, and often correspond with regions of low recombination in the genetic map.

CONCLUSION

Our study found that transposable elements and other repetitive DNA accumulate in certain regions in the assembled T. castaneum genome. Several lines of evidence suggest these regions are derived from the large blocks of pericentric heterochromatin in T. castaneum chromosomes.

Long inversely oriented subunits form a complex monomer of Tribolium brevicornis satellite DNA

Highly abundant satellite DNA named TBREV is detected and characterized in the beetle Tribolium brevicornis (Insecta: Coleoptera). An outstanding peculiarity of the TBREV satellite monomer is its complex structure based on the two approximately 470-bp-long subunits, inversely oriented within a 1061-bp-long monomer sequence. The proposed evolutionary history demonstrates a clear trend toward increased complexity and length of the TBREV satellite monomer. This tendency has been observed on three levels: first as direct and inverted duplications of short sequence motifs, then by inverse duplication of the approximately 470-bp sequence segment, and, finally, by spread of inversely duplicated elements in a higher-order register and formation of extant monomers. Inversely oriented subunits share a similarity of 82% and have a high capacity to form a thermodynamically stable dyad structure that is, to our knowledge, the longest ever described in any satellite monomer. Analysis of divergences between inversely oriented subunits shows a tendency to a further reduction in similarity between them. Except in its centromeric localization, the TBREV satellite does not show similarity to other known Tribolium satellites, either in nucleotide sequence or in monomer length and complexity. However, TBREV shares common features of other Tribolium satellites that might be under functional constraints: nonconstant rate of evolution along the monomer sequence, short inverted repeats in the vicinity of an A+T tract, nonrandom distribution of A or T >/=3 tracts, and CENP-B box-like motifs. Although long inverted subunits might reinforce structural characteristics of the satellite monomer, their nucleotide sequence does not seem to be under constraints in order to preserve the dyad structure.

Uniform distribution of satellite DNA variants on the chromosomes of tenebrionid species Alphitobius diaperinus and Tenebrio molitor

The chromosomes of tenebrionid species Alphitobius diaperinus contain large blocks of pericentromerically located constitutive heterochromatin, as revealed by C-banding procedure. As previously reported, satellite DNA of this species is composed of two related monomeric units organized in three satellite subfamilies. In order to analyze the chromosomal location of the satellite DNA and the distribution of monomeric variants within it, and compare it with the distribution of monomer variants in Tenebrio molitor satellite DNA, the methods of in situ hybridization and restriction enzyme/nick translation were performed. Fluorescent in situ hybridization with the entire satellite DNA reveals the pericentromerically located signals on all chromosomes of the complement, coinciding with heterochromatic blocks. Results of fluorescent in situ hybridization with particular monomeric variants and of in situ restriction enzyme/nick translation show that monomeric variants are homogeneously dispersed within the entire satellite DNA. The spreading of satellite monomeric variants of the related species T. molitor within the pericentromeric heterochromatin of the entire complement, is demonstrated using the method of in situ restriction enzyme/nick translation. Although the complexity of organization of satellite DNAs is quite distinct in these two species, obtained results suggest similar efficiency of mechanisms of spreading and homogenization resulting in random chromosomal distribution of their satellite variants.

Characterization of the heterochromatin of the darkling beetle Misolampus goudoti: cloning of two satellite DNA families and digestion of chromosomes with restriction enzymes

The darkling beetle Misolampus goudoti Er. has 58% of C-banded chromosome material. In this paper we deal with the study of the heterochromatin of this insect both by molecular and cytogenetical methods. Two different satellite DNA families have been characterized in Misolampus goudoti by agarose gel electrophoresis of EcoRI and PstI restriction fragments, respectively. The EcoRI family is composed of a monomeric unit of 196 bp (64.3% A-T rich) DNA sequence, representing about 120,000 copies per haploid genome. The presence of frequent intermediate-size satellite variants and an internal direct repetition of 61 bp in the EcoRI repetitive main monomer suggest that the evolution of this satellite proceeded by unequal crossing-over, occurring both within and between the 196 bp unit. Another highly repetitive sequence, defined by digestion of genomic DNA with PstI, has a more complex unit of 1.2 kb with about 70,000 copies per haploid genome. In situ digestion of M. goudoti chromosomes with restriction enzymes shows a non-specific chromosome DNA extraction from pericentromeric positions with EcoRI and chromosome specific extraction of DNA with PstI and HinfI. This is discussed in relation to the chromosomal location of both satellites.

C-bands on chromosomes of 32 beetle species (Coleoptera: Elateridae, Cantharidae, Oedemeridae, Cerambycidae, Anthicidae, Chrysomelidae, Attelabidae and Curculionidae)

C-banding patterns of 32 beetle species from the families Elateridae, Cantharidae, Oedemeridae, Cerambycidae, Anthicidae, Chrysomelidae, Attelabidae and Curculionidae were studied using the C-banding technique. Mitotic and meiotic chromosomes were previously described for 14 species. From among 18 species that had never been cytogenetically studied, we determined the diploid and haploid chromosome numbers and the sex determination system for 12 beetles. The karyotype for 6 species is not described because of a lack of mitotic and meiotic metaphases. Results confirm that most of the beetle species possess a small amount of heterochromatin and C-positive segments are weakly visible in pachytene stages and weakly or imperceptible in mitotic and meiotic metaphases. In some species with a large amount of heterochromatin, C-bands were observed in the centromeric region in all autosomes and the X chromosome. The Y chromosome does not show C-bands with the exception of Oedemera viridis in which it possesses a small band of heterochromatin.

Conserved patterns in the evolution of Tribolium satellite DNAs

Two satellite DNAs, TANAPH and TDEST, isolated from the beetle species Tribolium anaphe and Tribolium destructor, respectively, are characterized and compared with previously described Tribolium satellites, in order to deduce possible constraints on satellite sequence evolution between closely related species. Sequence diversity analysis of cloned monomers reveals the presence of variable and conserved segments in both satellites. In addition, non-random organization of As or Ts and their periodical distribution in the form of A or T >/=3 tracts, as well as CENP-B box-like motifs and dyad structures have been found in both satellites. Similar structural features are also present in satellites from other Tribolium species. We therefore propose that they, together with the observed non-constant rate of evolution along the satellite sequence, could be related to putative protein binding sites and suggest a possible selective pressure affecting these sequences. Tribolium satellites, including TANAPH and TDEST, are located in the pericentromeric heterochromatin of all chromosomes of the corresponding species. Since satellites from different species exhibit no significant sequence homology, we propose that they did not originate from a common ancestral sequence. More probably, they derive from simple sequence modules some of which could represent protein binding sites. Shuffling of simple sequence modules could generate different satellites, able to perform a similar role in different species.

A genetic linkage map for Tribolium confusum based on random amplified polymorphic DNAs and recombinant inbred lines

Tribolium beetles provide an excellent and easily manipulated model system for the study of genetics. However, despite significant increases in the availability of molecular markers for the study of genetics in recent years, a significant genetic linkage map for these beetles remains undeveloped. We present the first molecular genetic linkage map for Tribolium confusum using random amplified polymorphic DNA markers. The linkage map contains 137 loci mapped on to eight linkage groups totaling 968.5 cM.

Karyotypic characterization of representatives from Melolonthinae (Coleoptera: Scarabaeidae): karyotypic analysis, banding and fluorescent in situ hybridization (FISH)

Meiotic chromosomes of Phyllophaga (Phytalus) vestita, Phyllophaga (Phyllophaga) aff capillata and Lyogenys fuscus (Melolonthinae) were analyzed by conventional staining, C-banding, fluorochromes, silver nitrate and FISH. The three species had a diploid number of 2n=20 and a sex mechanism of the (Xyp; XYp) parachute type. P. (Phytalus) vestita,P. (Phyllophaga) aff capillata and Lyogenys fuscus showed pericentromeric constitutive heterochromatin (CH) in all autosomal bivalents and on X chromosomes. Staining with CMA3 and DAPI fluorochromes showed that the CH of P. (Phytalus) vestita is not specifically rich in AT and GC-base pairs, whereas in P. (Phyllophaga) aff capillata the sex bivalent and one autosomal pair were found to be enriched in GC base pairs with CMA3, and in Lyogenys fuscus CH was positive for DAPI. Silver nitrate staining revealed nucleolar remnants in all three species. However, FISH obtained a precise identification of nucleolar organizing regions with an rDNA 18S and 25S probe. A signal of hybridization was seen in each species, being detected in the X chromosome of P. (Phytalus) vestita and Lyogenys fuscus, and in a small autosomal bivalent of P. (Phyllophaga) aff capillata.

DNA characterization and karyotypic evolution in the bee genus Melipona (Hymenoptera, Meliponini)

We analyzed patterns of heterochromatic bands in the Neotropical stingless bee genus Melipona (Hymenoptera, Meliponini). Group I species (Melipona bicolor bicolor, Melipona quadrifasciata, Melipona asilvae, Melipona marginata, Melipona subnitida) were characterized by low heterochromatic content. Group II species (Melipona capixaba, Melipona compressipes, Melipona crinita, Melipona seminigra fuscopilosa e Melipona scutellaris) had high heterochromatic content. All species had 2n = 18 and n = 9. In species of Group I heterochromatin was pericentromeric and located on the short arm of acrocentric chromosomes, while in Group II species heterochromatin was distributed along most of the chromosome length. The most effective sequential staining was quinacrine mustard (QM)/distamycin (DA)/chromomycin A3(CMA3)/4-6-diamidino-2-phenylindole (DAPI). Heterochromatic and euchromatic bands varied extensively within Group I. In Group II species euchromatin was restricted to the chromosome tips and it was uniformly GC+. Patterns of restriction enzymes (EcoRI, DraI, HindIII) showed that heterochromatin was heterogeneous. In all species the first pair of homologues was of unequal size and showed heteromorphism of a GC+ pericentromeric heterochromatin. In M. asilvae (Group I) this pair bore NOR and in M. compressipes (Group II) it hybridized with a rDNA FISH probe. As for Group I species the second pair was AT+ in M. subnitida and neutral for AT and GC in the remaining species of this group. Outgroup comparison indicates that high levels of heterochromatin represent a derived condition within Melipona. The pattern of karyotypic evolution sets Melipona in an isolated position within the Meliponini.

Repetitive A-T rich DNA sequences from the Y chromosome of the Mediterranean fruit fly, Ceratitis capitata

Copies of a repetitive DNA sequence distributed over 90% of the length of the long arm of the Y chromosome of the Mediterranean fruit fly, Ceratitis capitata (medfly), have been characterized. Sequencing reveals that these repeats, ranging in size from approximately 1.3 to 1.7 kb, are A-T rich overall (67%). In most cases the repeat units appear to occur in tandemly linked arrays. The repeat copies also all contain a highly similar internal region, approximately 200 bp in length, with a more extreme A-T content bias. This internal region, designated as the AT element, exhibits an A-T content of at least 83%. This exceeds what has been described for any comparable element among invertebrates. Using primers designed from the DNA sequence, PCR amplification of an internal region encompassing the AT element also reveals that these sequences are present only in the male genome in different strains of the medfly.

A theoretical perusal of the satellite DNA curvature in tenebrionid beetles

The curvature patterns of seven satellite DNAs taken from beetles belonging to the family Tenebrionidae (Coleoptera) were modelled utilising a number of computer programs that describe and plot the curvature profiles of DNA. The theoretical analysis agreed with the experimentally observed curvature of most of these satellite DNAs, and its absence in Tribolium freemani and Tenebrio obscurus satellite I. In many cases, the tenebrionid satellite DNAs lack periodically repeated runs of phased-A-tracts, yet they represent a clear example of curved DNA. The macroscopic curvature of satellites from these closely related organisms confirmed that other sequence elements must be participating in the bending of these DNAs. Our modelling approaches are discussed, together with previous experimental results, in terms of the role played by DNA curvature in the organisation of satellite DNA and the tight compacting of heterochromatin.

A 169-base pair tandem repeat DNA marker for subtelomeric heterochromatin and chromosomal rearrangements in aphids of the Myzus persicae group

Numerous copies of a 169-base pair DNA sequence (Myzus persicae group repeat; MpR) occur at subtelomeric locations on all chromosomes of three members of the Myzus persicae species group (Myzus persicae, M. antirrhinii, M. certus). MpR occurs in large tandem arrays at both ends of all autosomes of the standard 2n = 12 karyotype, and near one end of the X chromosome (the end opposite to the nucleolar organizer) and is estimated to make up about 5% of the genome (a total of about 200000 copies). Locations of MpR were compared in various karyotypes to determine the likely nature of the rearrangements (fusions, dissociations, translocations) that are found in this species group which, like other Hemiptera, has holocentric chromosomes that are devoid of morphological markers. Aphid clones heterozygous for autosome dissociations do not have any detectable MpR at 'new' chromosome ends, indicating that this sequence is not involved in 'capping' of chromosomes. However, a clone with a de novo autosome fusion had an interstitial block of MpR marking the point of fusion, and clones heterozygous for an autosomal 1,3 translocation had MpR from autosome 1 translocated to a new site on autosome 3. The isolation from M. antirrhinii of the telomeric repeat TTAGG, which is found in several insect groups, is also reported.

Fine structure of the kinetochores in six species of the Coleoptera

Kinetochore structure was examined in a total of 6 species from 5 different families of the Coleoptera using transmission electron microscopy of ultrathin serial sections. Metaphase spermatogonia and primary and secondary spermatocytes were studied in Tenebrio molitor (Tenebrionidae) to determine whether kinetochore structure varies depending on the cell type. In all three cell types, the kinetochore microtubules (MTs) were in direct contact with the chromosomal surface, and kinetochore plates were not detectable. In the other species, only metaphase I spermatocytes were examined. As in T. molitor, distinct kinetochore plates were also absent in Adelocera murina (Elateridae), Agapanthia villosoviridescens (Cerambycidae), and Coccinella septempunctata (Coccinellidae). However, bivalents in male meiosis of two representatives of the Chrysomelidae, Agelastica alni and Chrysolina graminis, showed roughly spherical kinetochores at their poleward surfaces. Microtubules were in contact with this material. Thus, although the present survey covers only a small number of species, it is clear that at least two kinetochore types occur in the Coleoptera. The cytological findings are discussed in the context of chromosome number and genome size variability in the Coleopteran families studied. It is suggested that properties of the kinetochores could play a role in karyotype evolution in the Coleoptera.

Useful DNA polymorphisms are identified by snapback, a midrepetitive element in Tribolium castaneum

The red flour bettle, Tribolium castaneum, is both a pest of stored grain products and an important experimental organism. To improve its facility as a genetic model, we are developing DNA fingerprinting methods for this insect. A Tribolium DNA fragment, snapback-1 (SBI), identified among sequences that reassociate before a Cot of 0.03 mol.s/L, was found to produce a banding pattern in restriction endonuclease digested genomic DNA that is characteristic of a midrepetitive element. DNA fingerprints of individual beetles demonstrated that unvarying inherited DNA polymorphism is revealed, and that polymorphism is inherited in a dominant Mendelian fashion. Linkage between bands was minimal. The sequence of SBI was determined, and hybridization experiments indicated that SBI is a fragment of a larger midrepetitive element. Fingerprinting individuals with known inbreeding coefficients indicated that SBI loci have relatively high mutation rates. The possibility that SBI is a fragment of a transposable element is discussed.

Cytogenetics of chromosome rearrangements inTribolium castaneum

The karyotype of the red flour beetle, Tribolium castaneum, was reexamined and improved by restriction enzyme banding with HpaII. After this treatment, each of the 10 chromosomes were identified in spermatogonial metaphase cells and 3 of the 8 autosomal bivalents and the XY pair were identified in spermatocyte metaphase I nuclei. Based on centromere position, relative length, and banding pattern, probable correlations between some of the mitotic chromosomes and some of the metaphase I bivalents were ascertained. Thus improved, the karyotypes of beetles harboring genetically defined translocations were investigated. Spermatocyte metaphase I nuclei were most informative, as normal chromosome pairing was visibly disrupted by rearrangements. Bivalents associated with each rearrangement were identified. Results demonstrated that each of the five best defined T. castaneum linkage groups corresponds to a different chromosome and established correspondence between bivalents and linkage groups 1–4. The relevance of these findings is discussed with regard to Tribolium genetics and evolution.Key words: beetles, red flour beetle, Coleoptera, linkage groups, chromosome banding.

Characterization of two abundant satellite DNAs from the mealworm Tenebrio obscurus

Two highly abundant satellite DNAs comprise 36% of the Tenebrio obscurus (Tenebrionidae, Coleoptera) genome. They are designated as satellite I and satellite II with the monomer length of 344 and 142 base pairs (bp), respectively. Both satellites differ in their nucleotide (nt) sequences, but the frequency of point mutations, well-conserved length of monomer variants, stretches of shared mutations characteristic for the process of gene conversion, and distribution of both satellites in regions of centromeric heterochromatin of all chromosomes indicate that the same evolutionary processes act on both of them with the same, or similar, rate. While satellite I shares no sequence similarity with any other known nt sequence, satellite II is 79.7% homologous with the highly abundant satellite from closely related Tenebrio molitor. Difference in the frequency of point mutations and absence of shared mutations indicating gene conversion strongly suggest that in these two closely related species mutational processes affecting satellite DNAs seem to be changed. Retarded electrophoretic mobility, due to sequence-induced curvature of DNA helix axis, was observed for T. obscurus satellite II, but not for satellite I. Although evolutionary processes act with different rates in T. obscurus and T. molitor satellites the monomer length and sequence-induced curvature are well preserved in both 142-bp satellites, as well as in, at the nt sequence level completely divergent, Palorus ratzeburgii (Tenebrionidae) satellite, indicating potential importance of these parameters in their evolution.

Analysis of divergence of Alphitobius diaperinus satellite DNA--roles of recombination, replication slippage and gene conversion

Satellite DNA is highly abundant in Alphitobius diaperinus (Tenebrionidae, Coleoptera), comprising 25% of the total genomic DNA. Sequence analysis reveals an average GC content of 50.8% and the presence of three different groups of satellite monomer variants, tH1, tH2 and tH3 with corresponding lengths of 123, 128 and 126 bp. Their mutual homologies range between 65 and 81%. Sequence comparison shows that the monomer variant tH2 has been formed by a recombination process between tH1 and tH3, which have a low average homology of only 65.15%. The longest stretch of 100% homology between the recombining units is 17 bp and is located 3' to the predicted recombination site. There is also an indication from sequence analysis that replication slippage and gene conversion play a part in the formation of satellite units and contribute to their divergence. The tH1, tH2 and tH3 monomer variants are organized in higher order repeating structures: a dimer, composed of tH1 and tH3, and a trimer containing tH1, tH2 and tH3 in series. The dimeric and trimeric repeat units furthermore create three higher order satellite subfamilies. Two of them contain either tandemly arranged dimers or trimers, while the third one is composed of both types of repeats, mutually interspersed.

Localization of tandemly repeated DNA sequences in beetle chromosomes by fluorescent in situ hybridization

In situ hybridization to chromosomes and nuclei of Tenebrio molitor shows the massive presence of a species-specific satellite DNA in all chromosomes and six sites of rDNA in mitotic chromosomes. These sites are located in two autosomal pairs and in the X and Y chromosomes. In a related species, Misolampus goudoti, in which two different families of highly repetitive DNA have been previously characterized, one family is located in centromeric regions of all chromosomes with the exception of chromosome Y, while the other repeated DNA family is present both in centromeric and distal regions of all chromosomes. rRNA genes in this species are present in a medium-sized autosomal pair only. These results show that molecular cytogenetics can be applied to coleopteran chromosomes and open the way for a physical mapping of DNA sequences in these organisms. The results also provide insights into the type of meiotic association of the X and Y chromosomes in Coleoptera and the distribution of repeated DNAs within the genome of these insects.