Giant readthrough transcription units at the histone loci on lampbrush chromosomes of the newt Notophthalmus

The first chicken oocyte nucleus whole transcriptomic profile defines the spectrum of maternal mRNA and non-coding RNA genes transcribed by the lampbrush chromosomes

Lampbrush chromosomes, with their unusually high rate of nascent RNA synthesis, provide a valuable model for studying mechanisms of global transcriptome up-regulation. Here, we obtained a whole-genomic profile of transcription along the entire length of all lampbrush chromosomes in the chicken karyotype. With nuclear RNA-seq, we obtained information about a wider set of transcripts, including long non-coding RNAs retained in the nucleus and stable intronic sequence RNAs. For a number of protein-coding genes, we visualized their nascent transcripts on the lateral loops of lampbrush chromosomes by RNA-FISH. The set of genes transcribed on the lampbrush chromosomes is required for basic cellular processes and is characterized by a broad expression pattern. We also present the first high-throughput transcriptome characterization of miRNAs and piRNAs in chicken oocytes at the lampbrush chromosome stage. Major targets of predicted piRNAs include CR1 and long terminal repeat (LTR) containing retrotransposable elements. Transcription of tandem repeat arrays was demonstrated by alignment against the whole telomere-to-telomere chromosome assemblies. We show that transcription of telomere-derived RNAs is initiated at adjacent LTR elements. We conclude that hypertranscription on the lateral loops of giant lampbrush chromosomes is required for synthesizing large amounts of transferred to the embryo maternal RNA for thousands of genes.

Polymer Modeling Reveals Interplay between Physical Properties of Chromosomal DNA and the Size and Distribution of Condensin-Based Chromatin Loops

Transient DNA loops occur throughout the genome due to thermal fluctuations of DNA and the function of SMC complex proteins such as condensin and cohesin. Transient crosslinking within and between chromosomes and loop extrusion by SMCs have profound effects on high-order chromatin organization and exhibit specificity in cell type, cell cycle stage, and cellular environment. SMC complexes anchor one end to DNA with the other extending some distance and retracting to form a loop. How cells regulate loop sizes and how loops distribute along chromatin are emerging questions. To understand loop size regulation, we employed bead-spring polymer chain models of chromatin and the activity of an SMC complex on chromatin. Our study shows that (1) the stiffness of the chromatin polymer chain, (2) the tensile stiffness of chromatin crosslinking complexes such as condensin, and (3) the strength of the internal or external tethering of chromatin chains cooperatively dictate the loop size distribution and compaction volume of induced chromatin domains. When strong DNA tethers are invoked, loop size distributions are tuned by condensin stiffness. When DNA tethers are released, loop size distributions are tuned by chromatin stiffness. In this three-way interaction, the presence and strength of tethering unexpectedly dictates chromatin conformation within a topological domain.

Are lampbrush chromosomes unique to meiotic cells?

Lampbrush chromosomes (LBCs) are transcriptionally active chromosomes found in the germinal vesicle (GV) of large oocytes of many vertebrate and invertebrate animals and also in the giant single-celled alga Acetabularia. These cells are all in prophase of the first meiotic division. Nevertheless, many meiotic cells do not develop LBCs, arguing that LBCs are not an essential feature of meiosis. LBCs probably represent the most active transcriptional state that can be attained by cells that must give rise to diploid progeny. Polyploidy permits cells to reach higher rates of transcription per nucleus but precludes a return to diploidy. In this sense, LBCs represent a relatively inefficient transcriptional compromise employed by large meiotic cells. These considerations help to explain why transcriptionally active GVs develop LBCs, but they do not explain why LBCs have never been seen in somatic cells, diploid or otherwise. If LBCs are truly limited to germ cells, then some of their unusual features may reflect reprogramming of the genome. If this is the case, LBCs provide unique opportunities to study reprogramming at the level of the individual transcription unit.

Proteins involved in meiotic recombination: a role in male infertility?

Meiotic recombination results in the formation of crossovers, by which genetic information is exchanged between homologous chromosomes during prophase I of meiosis. Recombination is a complex process involving many proteins. Alterations in the genes involved in recombination may result in infertility. Molecular studies have improved our understanding of the roles and mechanisms of the proteins and protein complexes involved in recombination, some of which have function in mitotic cells as well as meiotic cells. Human gene sequencing studies have been performed for some of these genes and have provided further information on the phenotypes observed in some infertile individuals. However, further studies are needed to help elucidate the particular role(s) of a given protein and to increase our understanding of these protein systems. This review will focus on our current understanding of proteins involved in meiotic recombination from a genomic perspective, summarizing our current understanding of known mutations and single nucleotide polymorphisms that may affect male fertility by altering meiotic recombination.

Tandem 41-bp repeats in chicken and Japanese quail genomes: FISH mapping and transcription analysis on lampbrush chromosomes

The chromosomal distribution of 41-bp repeats, known as CNM and PO41 repeats in the chicken genome and BglII repeats in the Japanese quail, was analyzed precisely using giant lampbrush chromosomes (LBC) from chicken, Japanese quail, and turkey growing oocytes. The PO41 repeat is conserved in all galliform species, whereas the other repeats are species specific. In chicken and quail, the centromere and subtelomere regions share homologous satellite sequences. RNA polymerase II transcribes the 41-bp repeats in both centromere and subtelomere regions. Ongoing transcription of these repeats was demonstrated by incorporation of BrUTP injected into oocytes at the lampbrush stage. RNA complementary to both strands of CNM and PO41 repeats is present on chicken LBC loops, whereas strand-specific G-rich transcripts are characteristic of BglII repeats in the Japanese quail. The RNA from 41-bp repeats does not undergo cotranscriptional U snRNP-dependent splicing. At the same time, the ribonucleoprotein matrix of transcription units with C-rich RNA of CNM and PO41 repeats was enriched with hnRNP protein K. Potential promoters for satellite transcription are discussed.

Read-through histone transcripts containing 3' adenylate tails are zygotically expressed in Xenopus embryos and undergo processing to mature transcripts when introduced into oocyte nuclei

Messages encoding replication-dependent histone genes generally terminate with a stem-loop structure and lack polyadenylate tails. Adenylated histone transcripts were identified in Xenopus oocytes, though the role of the adenylate tracts is unknown. We report isolation of cDNAs from Xenopus embryos encoding histone mRNAs with 3' adenylate tracts. They also contain targets for stem-loop binding protein and U7 snRNA, which are required for histone RNA processing. One sequence is a read-through transcript containing a complete version of the downstream gene from the anti-parallel strand, similar to the RNAs from lampbrush loops of Notophthalmus oocytes. We injected read-through transcripts into Xenopus oocyte nuclei and they were processed to mature histone RNAs. Our results suggest that addition of 3' adenylate sequences might be a normal part of histone RNA synthesis. Also, these results shed light on the enigma of the developmental regulation of adenylated histone transcripts in Xenopus oocytes.

Lampbrush chromosomes and associated bodies: new insights into principles of nuclear structure and function

The lampbrush chromosomes and assorted nuclear bodies of amphibian and avian oocytes provide uniquely advantageous and amenable experimental material for cell biologists to study the structure and function of the eukaryotic nucleus, and in particular to address the processes of nuclear gene expression. Recent findings discussed here include the molecular analysis of the actively elongating RNA polymerase complexes associated with lampbrush chromosome loops and of the association between loop nascent transcripts and RNA processing components. In addition, several types of chromosome structure that do not outwardly resemble simple extended loops and that may house novel nuclear functions have recently been studied in detail. Among these a type of chromosomal body that can also exist free in the oocyte nucleus, the Cajal body, has been shown to possess a range of characteristics that suggest it is involved in the assembly of macromolecular complexes required for gene expression. Homologous structures have also been described in somatic nuclei. Fundamental aspects of the looped organization exhibited by lampbrush as well as other chromosomes have also been addressed, most notably by the application of a technique for de-novo chromosome assembly.

A possible meiotic function of the peculiar patterns of gene expression in mammalian spermatogenic cells

This review focuses on the striking differences in the patterns of transcription and translation in somatic and spermatogenic cells in mammals. In early haploid cells, mRNA translation evidently functions to restrict the synthesis of certain proteins, notably protamines, to transcriptionally inert late haploid cells. However, this does not explain why a substantial proportion of virtually all mRNA species are sequestered in translationally inactive free-messenger ribonucleoprotein particles (free-mRNPs) in meiotic cells, since most mRNAs undergo little or no increase in translational activity in transcriptionally active early haploid cells. In addition, most mRNAs in meiotic cells appear to be overexpressed because they are never fully loaded on polysomes and the levels of the corresponding protein are often much lower than the mRNA and are sometimes undetectable. A large number of genes are expressed at grossly higher levels in meiotic and/or early haploid spermatogenic cells than in somatic cells, yet they too are translated inefficiently. Many genes utilize alternative promoters in somatic and spermatogenic cells. Some of the resulting spermatogenic cell-altered transcripts (SCATs) encode proteins with novel functions, while others contain features in their 5'-UTRs, secondary structure or upstream reading frames, that are predicted to inhibit translation. This review proposes that the transcriptional machinery is modified to provide access to specific DNA sequences during meiosis, which leads to mRNA overexpression and creates a need for translational fine-tuning to prevent deleterious consequences of overproducing proteins.

Nongenic, bidirectional transcription precedes and may promote developmental DNA deletion in Tetrahymena thermophila

A large number of DNA segments are excised from the chromosomes of the somatic nucleus during development of Tetrahymena thermophila. How these germline-limited sequences are recognized and excised is still poorly understood. We have found that many of these noncoding DNAs are transcribed during nuclear development. Transcription of the germline-limited M element occurs from both DNA strands and results in heterogeneous transcripts of < 200 b to > 1 kb. Transcripts are most abundant when developing micro- and macronuclei begin their differentiation. Transcription is normally restricted to unrearranged DNA of micronuclei and/or developing nuclei, but germline-limited DNAs can induce their own transcription when placed into somatic macronuclei. Brief actinomycin D treatment of conjugating cells blocked M-element excision, providing evidence that transcription is important for efficient DNA rearrangement. We propose that transcription targets these germline-limited sequences for elimination by altering chromatin to ensure their accessibility to the excision machinery.

Mega-introns in the dynein gene DhDhc7(Y) on the heterochromatic Y chromosome give rise to the giant threads loops in primary spermatocytes of Drosophila hydei

The heterochromatic Y chromosomes of several Drosophila species harbor a small number of male fertility genes (fertility factors) with several unusual features. Expression of their megabase-sized loci is restricted to primary spermatocytes and correlates with the unfolding of species-specific lampbrush loop-like structures resulting from huge transcripts mainly derived from clusters of loop-specific Y chromosomal satellites. Otherwise, there is evidence from genetic mapping and biochemical experiments that at least two of these loops, Threads in Drosophila hydei and kl-5 in D. melanogaster, colocalize with the genes for the axonemal dynein beta heavy chain proteins DhDhc7(Y) and Dhc-Yh3, respectively. Here, we make use of particular Threads mutants with megabase-sized deletions for direct mapping of DhDhc7(Y)-specific exons among the large clusters of satellite DNA within the 5.1-Mb Threads transcription unit. PCR experiments with exon-specific primer pairs, in combination with hybridization experiments with exon- and satellite-specific probes on filters with large PFGE-generated DNA fragments, offer a simple solution for the long-lasting paradox between megabase-sized loops and protein-encoding transcription units; the lampbrush loops Threads and the DhDhc7(Y) gene are one and the same transcription unit, and the giant size of the DhDhc7(Y) gene as well as its appearance as a giant lampbrush loop are merely the result of transcription of huge clusters of satellite DNA within some of its 20 introns.

The stem-loop binding protein (SLBP1) is present in coiled bodies of the Xenopus germinal vesicle

The stem-loop binding protein (SLBP1) binds the 3' stem-loop of histone pre-mRNA and is required for efficient processing of histone transcripts in the nucleus. We examined the localization of SLBP1 in the germinal vesicle of Xenopus laevis oocytes. In spread preparations of germinal vesicle contents, an anti-SLBP1 antibody stained coiled bodies and specific chromosomal loci, including terminal granules, axial granules, and some loops. After injection of myc-tagged SLBP1 transcripts into the oocyte cytoplasm, newly translated myc-SLBP1 protein was detectable in coiled bodies within 4 h and in terminal and axial granules by 8 h. To identify the region(s) of SLBP1 necessary for subnuclear localization, we subcloned various parts of the SLBP1 cDNA and injected transcripts of these into the cytoplasm of oocytes. We determined that 113 amino acids at the carboxy terminus of SLBP1 are sufficient for coiled body localization and that disruption of a previously defined RNA-binding domain did not alter this localization. Coiled bodies also contain the U7 small nuclear ribonucleoprotein particle (snRNP), which participates in cleavage of the 3' end of histone pre-mRNA. The colocalization of SLBP1 and the U7 snRNP in the coiled body suggests coordinated control of their functions, perhaps through a larger histone-processing particle. Some coiled bodies are attached to the lampbrush chromosomes at the histone gene loci, consistent with the view that coiled bodies in the oocyte recruit histone-processing factors to the sites of histone pre-mRNA transcription. The non-histone chromosomal sites at which SLBP1 is found include the genes coding for 5 S rRNA, U1 snRNA, and U2 snRNA, suggesting a wider role for SLBP1 in the biosynthesis of small non-spliced RNAs.

Coilin can form a complex with the U7 small nuclear ribonucleoprotein

Coiled bodies (CBs) in the amphibian oocyte nucleus are spherical structures up to 10 microm or more in diameter, much larger than their somatic counterparts, which rarely exceed 1 microm. Oocyte CBs may have smaller granules attached to their surface or embedded within them, which are identical in structure and composition to the many hundreds of B-snurposomes found free in the nucleoplasm. The matrix of the CBs contains the diagnostic protein p80-coilin, which is colocalized with the U7 small nuclear ribonucleoprotein (snRNP), whereas the attached and embedded B-snurposomes contain splicing snRNPs. A few of the 50-100 CBs in the oocyte nucleus are attached to lampbrush chromosomes at the histone gene loci. By coimmunoprecipitation we show that coilin and the U7 snRNP can form a weak but specific complex in the nucleoplasm, which is dependent on the special U7 Sm-binding site. Under the same conditions coilin does not associate with the U1 and U2 snRNPs. Coilin is a nucleic acid-binding protein, as shown by its interaction with single-stranded DNA and with poly r(U) and poly r(G). We suggest that an important function of coilin is to form a transient complex with the U7 snRNP and accompany it to the CBs. In the case of CBs attached to chromosomes at the histone gene loci, the U7 snRNP is thus brought close to the actual site of histone pre-mRNA transcription.

Transcription of lampbrush chromosomes of a centromerically localized highly repeated DNA in pigeon (Columba) relates to sequence arrangement

A highly repetitive, centromerically localized DNA sequence (PR1) has been isolated from the genomic DNA of two species of pigeon (Columba livia and C. palumbus). PR1 is approximately 900 bp long. It includes a sequence that is similar to the CENP-B box of mammals. It represents about 5% of the genome in C. livia and 2% in C. palumbus. In both species, tandem arrays of PR1 form part of larger repeating units. The organization of PR1 repeats and the larger repeating units is strikingly different in the two species. The large repeating units in C. livia include long (at least 14 units) tandem arrays of PR1 interspersed with relatively short intervening sequences. The large repeats of C. palumbus have much shorter (4 units or fewer) PR1 arrays interspersed with longer sections of non-PR1 DNA. PR1 is transcribed on short lampbrush loops in the centromeric regions of all lampbrush bivalents of C. palumbus. In C. livia, it is not transcribed at any of the major pericentromeric sites at which it is known to be present, although it is transcribed at one minor centromeric site on chromosome 2. It is proposed that transcription of the noncoding PR1 sequence on lampbrush chromosomes of pigeons relates to its genomic organization. The proposal is discussed with regard to the 'read-through' hypothesis for transcription on lampbrush loops.

Characterization of DNA sequences constituting the terminal heterochromatin of the chicken Z chromosome

Two clones, pCZTH5-8 and pCZTH12-8, were isolated from a female chicken genomic library by screening with sequences obtained from genomic libraries which had been constructed from a terminal region of a single Z chromosome of chicken utilizing laser microbeam irradiation and PCR amplification. Fluorescence in situ hybridization to the mitotic Z chromosome and the lampbrush ZW bivalent of chicken demonstrated that both the cloned sequences are located in the heterochromatic region of the Z chromosome at the end opposite to the pairing region with the W chromosome. The sequences pCZTH-8 and pCZTH12-8 are distributed widely on both the telomeric bow-like loops (TBL) and the region I (short loops region) of the Z lampbrush chromosome. These clones, pCZTH12-8 particularly notably, hybridized also to the TBLs of lampbrush bivalents 1-4 of chicken. Both sequences are transcribed in the lampbrush stage oocytes on the Z chromosome and on other macrobivalents. The subfragment of pCZTH5-8 which hybridizes to the TBLs and the insert of pCZTH12-8 contain regions that are closely similar in sequence. The pCZTH-8 sequence has no internal repeats and may be part of the 24-kb macrosatellite repeating unit that is evident after Nhel digestion of the genomic DNA. A cloned 24-kb unit, pFN-1, does not show significant DNA curvature, but cytosines of its CpG dinucleotides may be highly methylated in vivo. This contrasts with the repeat sequences of the W heterochromatin which not only have highly methylated CpG but are also strongly curved. The 24-kb unit is repeated about 830 times in the diploid genome of a female chicken, suggesting that nearly the entire terminal heterochromatin on the Z chromosome consists of this macrosatellite family. Sequences of the greater part of the pCZTH-8 are restricted to the genus Gallus but the sequence of one subregion which hybridizes to TBLs is present in the genomes of the order Galliformes.

Is the sphere organelle/coiled body a universal nuclear component?

We present evidence for the essential homology of four nuclear organelles that have previously been described under four different names: coiled bodies in mammalian somatic nuclei, prenucleolar bodies in nuclei assembled in vitro in Xenopus egg extract, sphere organelles in amphibian germinal vesicles (GVs), and Binnenkörper in insect GVs. Each of these organelles contains coilin or a coilin-related protein plus a variety of small nuclear ribonucleoproteins. We suggest that the sphere organelle/coiled body is a "universal" nuclear component in the sense that it is involved in common nuclear processes and hence will be found in one form or another in most eukaryotic cells. We postulate that it functions in the assembly and sorting of snRNP complexes for three RNA processing pathways: pre-mRNA splicing, rRNA processing, and histone pre-mRNA 3' end formation. Specifically, the sphere organelle/coiled body may be the initial site for assembly of processing complexes, which are then sorted to other places in the nucleus, where the actual RNA processing takes place.

Transcribed repetitive DNA sequences in telomeric regions of rice (Oryza sativa)

We have isolated and characterized from rice three repetitive DNA sequences, Os48, Osc-567, and OsG3-430. Our results indicate that these repetitive sequences are highly transcribed, and transcripts complementary to both strands of the Os48 family of sequences account for up to 3% of the total cellular RNA. Pulsed-field gel electrophoresis, restriction mapping, and DNA sequence analyses have revealed a complex pattern of structural organization of the three families of repetitive sequences. Os48 and Osc-567 are organized in long tandem arrays, whereas copies of the OsG3-340 sequence are interspersed with other sequences including arrays of the Os48 and Osc567 families. Interestingly, the three families of repetitive sequences are closely linked not only to each other, but also to telomeric sequences of rice, suggesting that transcription of these repetitive sequences may occur in regions very close to telomeres in rice.

U7 small nuclear RNA in C snurposomes of the Xenopus germinal vesicle

In the amphibian germinal vesicle small nuclear RNAs (snRNAs) occur in morphologically distinct structures called snurposomes. Three types (A, B, and C) have been distinguished on the basis of cytological appearance and snRNA composition. C snurposomes in Xenopus are spherical bodies ranging in diameter from < 1 microns to about 10 microns. They stain intensely with antibodies against trimethylguanosine and the small nuclear ribonucleoprotein-specific Sm antigen but give weak or negative in situ hybridization reactions for the snRNAs involved in pre-mRNA splicing (U1, U2, U4, U5, and U6). We show here that C snurposomes in the Xenopus germinal vesicle contain U7 snRNA, an snRNA of low abundance involved in processing the 3' end of histone pre-mRNA. Xenopus U7 is 58 nucleotides long and is capped at the 5' end with trimethylguanosine. C snurposomes are often associated with B snurposomes, which contain the splicing snRNAs but not U7; B and C snurposomes together constitute a morphologically complex structure known as a sphere or sphere organelle. Although most spheres and C snurposomes are extrachromosomal, a few are attached at the histone gene loci on chromosomes 8, 9, and 16. Because they contain U7 snRNA and occur at the sites of histone pre-mRNA synthesis, C snurposomes presumably play a role in processing histone transcripts.

Histone genes are located at the sphere loci of Xenopus lampbrush chromosomes

In the anuran Xenopus, as has been demonstrated previously in several species of urodele Amphibia, histone genes lie at the sphere organizer loci of the lampbrush chromosomes. They were located by in situ hybridization of a 3H-labelled histone H4 anti-sense cRNA probe applied to lampbrush preparations in which transcript RNA had been retained, and likewise to preparations in which transcripts were absent but whose DNA had been denatured prior to hybridization. In Xenopus the histone genes lie in intimate association with the spheres that are attached to the lampbrush chromosomes, but they are absent from spheres that lie free in the germinal vesicle. The Anura separated from the Urodela several hundred million years ago, so the sphere organizer/histone gene association is of great antiquity. This suggests that the association has a functional significance, though it is one that has yet to be discovered.

Association of RNA with the B and C snurposomes of Xenopus oocyte nuclei

We studied the time course of [3H]-uridine incorporation into the B and C snurposomes of Xenopus oocyte nuclei. B snurposomes constitute most of the non-nucleolar granules in the 1-4 micron size range; they contain the five splicing small nuclear RNAs (snRNAs; U1, U2, U4, U5 and U6) plus a variety of associated proteins. The organelles referred to as spheres consist of a C snurposome with one or more B snurposomes on its surface. C snurposomes can exist independently of Bs and many are smaller than the structures usually classified as spheres. C snurposomes contain the trimethylguanosine moiety characteristic of snRNAs, as well as the Sm epitope found on several small nuclear ribonucleoproteins (snRNPs), but it is not known which snRNA(s) they contain. When oocytes are incubated with [3H]uridine, all of the nucleoli and chromosome loops label strongly and rapidly. By contrast, labelled RNA appears slowly in the B snurposomes and then only in a fraction of them. After a 24 h incubation, about half of the Bs are labelled, and half are unlabelled or weakly labelled. This observation suggests that there are "mature" and "immature" B snurposomes, and that only the latter acquire newly synthesized RNA. The nature of this RNA is unknown, but it probably includes the splicing snRNAs. B snurposomes on the surface of Cs also constitute a heterogeneous population, some becoming labelled and some remaining unlabelled during a 24 h incubation. An analysis of the label in "doublets" (one B and one C snurposome) suggests that RNA may pass from the Bs to the Cs.

Poly[d(C-A)].poly[d(G-T)] is highly transcribed in the testes of Drosophila hydei

Microdissection of the lampbrush loops "threads" and "pseudonucleolus" of Y chromosomes from primary spermatocytes of Drosophila hydei and subsequent microcloning of the DNA yielded several recombinant DNA clones which cross-hybridized in screening the different clone banks. By DNA sequencing we found that the inserts of these cross-hybridizing clones contain blocks of poly[d(C-A].poly[d(G-T)]. Testis RNA contains a large fraction of transcripts with this simple repeated nucleotide sequence. With the aid of transcript in situ hybridization we discovered that the "cones" and "pseudonucleolus" lampbrush loops are the primary sites of transcription of poly[d(C-A)].poly[d(G-T)] in spermatocytes. In addition, we found a strand-specific transcription of (CA/GT)n. In both the "cones" and "pseudonucleolus" the (CA)n strand is transcribed, while in the "pseudonucleolus" (GT)n is also transcribed. Labelled (CA)n probes also react with the protein bodies in spermatid nuclei. These observations are discussed in the context of possible functions of (CA/GT)n transcripts in spermatogenesis.

Transcription of a satellite DNA on two Y chromosome loops of Drosophila melanogaster

Primary spermatocyte nuclei of Drosophila melanogaster exhibit three giant lampbrush-like loops formed by the kl-5, kl-3 and ks-1 Y chromosome fertility factors. Detailed mapping of satellite DNA sequences along the Y chromosome has recently shown that AA-GAC satellite repeats are a significant component of the kl-5 and ks-1 loop-forming regions. To determine whether these simple repeated sequences are transcribed on the loop structures we performed a series of DNA-RNA in situ hybridization experiments to fixed loop preparations using as a probe cloned AAGAC repeats. These experiments showed that the probe hybridizes with homologous transcripts specifically associated with the kl-5 and ks-1 loops. These transcripts are detected at all stages of development of these two loops, do not appear to migrate to the cytoplasm and are degraded when loops disintegrate during the first meiotic prophase. Moreover, an examination of the testes revealed that the transcription of the AAGAC sequences is restricted to the loops of primary spermatocytes; the other cell types of D. melanogaster spermatogenesis do not exhibit nuclear or cytoplasmic labeling. These experiments were confirmed by RNA blotting analysis which showed that transcription of the AAGAC sequences occurs in wild-type testes but not in X/O testes. The patterns of hybridization to the RNA blots indicated that the transcripts are highly heterogeneous in size, from large (migration at limiting mobility) to less than 1 kb. We discuss the possible function of the AAGAC satellite transcripts, in the light of the available information on the Y chromosome loops of D. melanogaster.

An oocyte-expressed alpha-tubulin gene in Xenopus laevis; sequences required for the initiation of transcription

We have studied the expression of X alpha T14, a member of the alpha-tubulin multigene family in Xenopus laevis. Small amounts of X alpha T14 RNA are detectable in a range of cell types, but much higher levels are present in ovary and tissue culture cells. In oocytes X alpha T14 transcripts accumulate during early vitellogenesis but their level declines in more advanced stages. Faithful and efficient initiation of transcription occurred on cloned X alpha T14 injected into oocytes even at low template levels. We have examined the amount of transcript produced by various deletion mutants relative to a co-injected control gene. The presence of 200bp of DNA 5' and 53bp of DNA 3' to the initiation site sufficed for high levels of promoter activity, although maximum activity required 560 bp of 5' flanking DNA. The DNA between -200 and -60 was necessary for transcription in oocytes and contains several sequence motifs implicated in transcriptional regulation including three CCAAT boxes and a sequence resembling a heat shock element. An 8 bp deletion that removed the latter element from 5kb of 5'-flanking DNA reduced promoter activity by 60%.

DNA-binding proteins on lampbrush chromosome loops

When fixed newt lampbrush chromosomes are treated with RNase to remove nascent transcripts and are then probed with radiolabeled single-stranded DNA in 0.1 x SSC, proteins associated with the majority of the lateral loops bind the probe nonspecifically. One or more common hnRNP proteins, several of which are known to bind single-stranded DNA, could be responsible for this generalized binding. In 1.0 x SSC only a relatively small subset of loops continues to bind the probe. In order to characterize this subset of loops, we prepared polyclonal antibodies against DNA-binding proteins initially identified by "Southwestern" analysis. We show by an in situ double labeling experiment that a polyclonal serum raised against gel-eluted histone H1 recognizes the same lateral loops that bind DNA in 1.0 x SSC.

Expression of dispersed 36 bp sequences in Drosophila virilis

A major fraction of mobile dispersed elements described in Drosophila virilis (pDv elements) consists of tandem 36 bp repeats. These repeat units were cloned into pUC19 and used as a hybridization probe. DNA blotting showed that these 36 bp repeats in the D. virilis genome are included in rather large (5-6 kb) structural and probably functional domains. The 36 bp repeat units in the D. virilis and D. lummei genomes exist in three different orientations relative to one another, i.e. tail-to-tail, tail-to-head and head-to-head. These repeats are actively transcribed and, as shown by in situ hybridization studies and RNA blotting, most of their transcripts are found in nuclei. Cloning of tandem repeats into bacterial expression vectors (pEX) with subsequent immunoblotting revealed translation of these sequences predominantly in one of the three possible reading frames.

An abundant testis RNA species shows sequence similarity to Y chromosomal and other genomic sites in Drosophila hydei

A cDNA clone bank was constructed from testis poly(A)+ RNA of Drosophila hydei and screened for clones which hybridize to Y chromosomal DNA sequences. The insert of clone cDhT14 hybridizes to a family of repeated DNA sequences with members distributed within the Y chromosome and elsewhere in the genome. This type of sequence has earlier been described as the Y-associated class of DNA. Southern blot analysis of DNA from different wild-type strains of D. hydei suggests that members of the T14 family of repeated DNA sequences are parts of a family of transposable elements. The genomic localization of the T14 family of repeated DNA sequences was revealed by in situ hybridization to metaphase and polytene chromosomes, and to transcripts of Y chromosomal lampbrush loops. Approximately 10-15 members (20%-30%) of the T14 sequence family reside in 8.3 kb PstI restriction fragments. A genomic clone of one of these DNA fragments, DhT14-8.3, hybridizes to transcripts on the Y chromosomal lampbrush loop "cones", and in conventional in situ hybridization experiments to region 12D/13A of the X chromosome and to region 112 of chromosome 5. The cDNA clone cDhT14 represents a part of an abundant testis RNA species of 5.0 kb. This RNA is also present in ovaries and in 0-3 h, 3-6 h and 6-12 h embryos, but less abundantly than in testes. Both the Y chromosomal site of the 8.3 kb PstI fragments and sites elsewhere in the genome are actively transcribed. At least one of the latter genomic sites is transcribed into the 5.0 kb RNA species.(ABSTRACT TRUNCATED AT 250 WORDS)

Ultrastructure of somatic and meiotic nucleoids

In this review emphasis is placed on the contribution of transmission electron microscopy to the analysis of spread chromosomes and nucleoids. Support is advanced for the DNA loop and rosette organization of meiotic and metaphase chromosomes and nucleoids. Extensive discussion is given to the biochemical treatments used for producing nucleoids and the effect of divalent cations and chelating agents on chromatin compactization (supercoiling). Detailed studies on nucleoids from hepatocytes are presented, with emphasis on the significance of DNA attachment to the internal nuclear matrix and to the nuclear lamina. It is firmly predicted that from the increasing knowledge of the structural organization of eukaryotic chromatin and the genome, a greater understanding of the functional roles of the various intranuclear structures will ultimately follow.

A long, nontranslatable poly(A) RNA stored in the egg of the sea urchin Strongylocentrotus purpuratus

Nontranslatable transcripts containing interspersed repetitive sequence elements constitute a major fraction of the poly(A) RNA stored in the cytoplasm of both the sea urchin egg and the amphibian oocyte. We report the first complete sequence of a representative interspersed maternal RNA transcript, called ISp1. The transcript is about 3.7 kb in length [including poly(A) tail]; and the 5' half consists of a cluster of repetitive sequences, whereas the 3' half is single copy. Other repetitive sequences occur in the 5' and 3' regions flanking the transcription unit. In several cloned alleles, the flanking repetitive and single-copy sequences differ, indicating a high degree of insertional and deletional rearrangement around, as well as within, the transcription unit. No significant open reading frames exist in any region of the ISp1 transcript, nor is it spliced to give rise to translatable mRNA in egg or embryo. A 620-nucleotide repetitive sequence element at the 5' end of the ISp1 transcript is also represented in a large number of other long interspersed maternal poly(A) RNAs. In addition, this sequence appears in a prevalent set of small polyadenylated RNAs about 600-nucleotides in length, which disappear almost completely by the gastrula stage of development. The structural features of the ISp1 RNA uncovered in this work exclude several hypotheses of interspersed maternal poly(A) RNA origin and function.

Transcription of the histone loci on lampbrush chromosomes of the newt Notophthalmus viridescens

We have investigated transcription of the histone gene cluster on lampbrush chromosomes of the newt Notophthalmus viridescens. Clusters of the five histone genes are separated by long tracts of a DNA repeat called satellite 1. Previous in situ hybridization results demonstrated the presence of histone gene coding regions, intergene spacers, and flanking satellite repeats in giant transcription units on lampbrush chromosomes. These results suggested a model in which transcription initiates at histone gene promoters and continues through the rest of the gene cluster into satellite repeats. The readthrough transcription model predicts that spacer regions upstream of the first promoter in the gene cluster should be absent from nascent transcripts on chromosome loops. We have used such upstream spacer probes for in situ hybridization to lampbrush chromosomes. Contrary to our expectation, the results show that upstream spacer regions are transcribed, and indicate that transcription often initiates upstream of the first histone gene promoter. The relationship of giant transcription units in oocyte nuclei to cytoplasmic histone mRNA is discussed.

The lampbrush chromosomes of Xenopus laevis: preparation, identification, and distribution of 5S DNA sequences

Details are given of a technique for making permanent preparations of the lampbrush chromosomes of Xenopus laevis. Stained preparations allow all 18 bivalent chromosomes to be identified, and a working map showing the major features has been constructed. Fifteen of the Xenopus chromosomes have one telomere conspicuously larger than the other; the two smallest chromosomes, and one other, lack large telomeres. Similar preparations, extracted with RNase and denatured, have been hybridized in situ with a 3H-labelled 5S cRNA probe. Chromosomes can be identified in the resulting autoradiographs. 5S DNA sequences are present at all the larger telomeres and at three of the smaller ones, but are absent from the telomeres at both ends of the two smallest chromosomes. There are also five interstitial sites of hybridization. At one of these, label is on the chromosome axis; at the other four, label extends well away from the axis.

A maternal mRNA localized to the animal pole of Xenopus eggs encodes a subunit of mitochondrial ATPase

We have previously isolated several cDNA clones of mRNAs that have the unusual property of being localized to either the animal pole or the vegetal pole of frog eggs. To gain insight into the function of these maternal mRNAs we have determined their DNA sequence and deduced the sequence of the proteins they encode. Here we report that An2, an mRNA localized to the animal pole of Xenopus oocytes and eggs, codes for the alpha chain of mitochondrial ATPase. Furthermore, we compare the intracellular localization of the An2 mRNA and mitochondria in oocytes and eggs and find that they do not have the same degree of localization. In the light of these results we discuss possible reasons for the maternal localization of the An2 mRNA.

A transcribed satellite DNA from the bullfrog Rana catesbeiana

We have cloned and sequenced a 360 bp repeated sequence from genomic DNA of the bullfrog Rana catesbeiana. This sequence, which we call satellite 1, makes up 0.7% of the genome (1.6 X 10(5) repeats) and is scattered throughout the length of all the chromosomes. In situ hybridization with strand-specific probes demonstrated that transcripts from both strands of satellite 1 occur on lamp-brush chromosome loops. We suggest that these transcripts arise by readthrough from upstream structural gene promoters. Sequences that cross-react with satellite 1 were found in genomic DNA of four out of five other Rana species that we tested, but were absent from the DNA of Xenopus, Bombina, and Acris.