The basic repeat unit of a Chironomus Balbiani ring gene

Different evolutionary behavior of structurally related, repetitive sequences occurring in the same Balbiani ring gene in Chironomus tentans

The Balbiani ring 2 (BR 2) gene in Chironomus tentans is highly internally repeated. Two types of related repeat units-the alpha and beta types-are tandemly arranged in separate blocks, which together are likely to form the major part of the gene. Every repeat unit has one constant region and one subrepeat region. Here we analyze the length and sequence of a number of repeat units of both types and compare the units within and between the blocks. The approximately 100 alpha repeat units are essentially invariant regarding length and sequence. In contrast, when the approximately 70 beta repeat units are compared, six length variants are found, four of which have been sequenced. The length variations reside in the subrepeat regions and are due to different numbers of whole or half subrepeats. Furthermore, the subrepeat regions differ by several base-pair substitutions, many of which change the amino acid sequence. On the other hand, all beta-type constant regions are of equal length and are virtually homogeneous in sequence. The observed length distributions in combination with analysis of the basepair substitutions in the alpha-and beta-type constant and subrepeat regions suggest that the alpha and beta blocks are of different age, that seemingly homologous repeated regions may play different functional roles at the protein level, and that sequence correction mechanisms are likely to operate to different extents on the constant and subrepeat regions within the beta block.

A cell-specific glycosylated silk protein from Chironomus thummi salivary glands. Cloning, chromosomal localization, and characterization of cDNA

Chironomid salivary glands contain 40 cells dedicated to the synthesis of a relatively small ensemble of silk proteins. Glands in some species contain a special lobe composed of 4 cells distinguishable from the others. We have cloned a special lobe-specific cDNA from Chironomus thummi salivary glands. Northern blots of salivary gland RNA demonstrated that the cDNA hybridizes to a 2.5-kilobase transcript present only in the special lobe. In situ hybridization mapped the gene encoding this cDNA to region A2b on polytene chromosome IV, the locus of the special lobe-specific Balbiani ring a. The deduced amino acid sequence encodes a protein with a calculated molecular mass of 77 kDa and numerous potential glycosylation sites; it appears unrelated to other known chironomid silk proteins. Polyclonal antibody, raised against a cDNA-encoded fusion protein, reacted exclusively with a special lobe-specific 160-kDa silk protein. Lectin binding studies indicate that the immunoreactive 160-kDa protein contains both N- and O-linked glycan moieties. We conclude that glycosylation most likely contributes to the difference between calculated and apparent molecular masses and that this cDNA encodes the special lobe-specific silk protein previously described as ssp160 (Kolesnikov, N. N., Karakin, E. I., Sebeleva, T. E., Meyer, L., and Serfling, E. (1981) Chromosoma 83, 661-677).

Cytoplasmic localization of transcripts of a complex G+C-rich crab satellite DNA

The primary sequence and higher order structures of a G+C-rich satellite DNA of the Bermuda land crab Gecarcinus lateralis have been described previously. The repeat unit of the satellite is approximately 2.1 kb. In exploring a possible function for this satellite, we asked whether it is transcribed. As a probe for transcripts, we used a segment of DNA amplified from a 368 bp EcoRI fragment from the very highly conserved 3' end of the satellite DNA. During polymerase chain reaction (PCR) amplification, the probe was simultaneously either radiolabeled or biotinylated. Tissue- and stage-specific transcripts were observed when blots of poly(A)+ mRNAs recovered from polysomes isolated from crab tissues [including midgut gland (hepatopancreas), limb bud, and claw muscle] were probed with the satellite DNA fragment. The presence of satellite transcripts in polysomal mRNAs is strong evidence that the transcripts had reached the cytoplasm. To corroborate the presence of transcripts in the cytoplasm, we investigated in situ hybridization of satellite probes with RNAs in tissue sections. Biotinylated satellite DNA probes were applied to sections of midgut gland, limb bud papilla, ovary, or testis of anecdysial crabs. Retention of RNAs in tissue sections was improved by UV-irradiation prior to hybridization. Transcripts were abundant in the cytoplasm of all tissues except testis. Sections of crab midgut gland treated with RNase A prior to hybridization and sections of mouse pancreatic tumor served as controls; neither showed any signals with the probe.

Identification of the spI products of Balbiani ring genes in Chironomus thummi

The spI fraction of high molecular weight secretory proteins was analysed in Chironomus thummi. These proteins are encoded by giant Balbiani ring (BR) genes which develop specifically in salivary gland cells. Each component of the spI fraction was studied electrophoretically from early and middle 4th instar larvae and prepupae, as well from galactose-treated larvae where changes in the relative puffing pattern of BR1 and BR2 are known to occur. The spI fraction consists of at least two bands with electrophoretic mobilities slower than those of the spI components of Camptochironomus. The slow migrating component remains throughout the 4th larval instar, while the amount of the faster component changes, being abundant in early 4th instar and prepupae, but not present (or very weak) in middle 4th instar. The correlated shifts in BR puffing pattern during these developmental stages suggest that the slow and fast components are encoded by BR2 and BR1. The spI fraction is modified by galactose treatment, the fast component being induced in parallel with a decrease in the slow component. These changes are correlated with changes in the steady-state levels of RNA: an increase in BR1 RNA and a decrease in BR2 RNA, and of proteins. These proteins could correspond to the spIb and spIa fractions allocated to BR2 and BR1, respectively, in Camptochironomus. After galactose treatment a new faster band sometimes appears, that could correspond to the spIc fraction of Camptochironomus. A possible spId equivalent was also identified. In conclusion the main features of the spI family in C. thummi are similar to those of spI in Camptochironomus.

Possible correlations of polypeptides and Balbiani rings in the salivary glands of Drosophila auraria Peng

Salivary glands of various stocks of Drosophila auraria and some of its close relatives were examined with a variety of electrophoretic techniques both from larval and prepupal stages, and after ecdysterone treatments, in an effort to detect possible translation products of the two Balbiani rings (BR1 and BR2) found in the salivary gland chromosomes of these species. Two polypeptides (P2 and P1), with molecular weights of 12,000 and 53,000, respectively, have been detected, the appearance of which coincides with the presence of BR2. The results do not allow the correlation of BR1 action with any specific polypeptide(s).

A BR 1 gene in Chironomus tentans has a composite structure: a large repetitive core block is separated from a short unrelated 3'-terminal domain by a small intron

The large Balbiani ring (BR) genes in the dipteran genus Chironomus have been considered to be homogeneous repetitive structures. Analysis of a genomic DNA segment now reveals that a BR 1 gene in C. tentans is a composite gene, consisting of two different types of sequences. A 15-20 kb core block of tandemly arranged repeat units extends close to the 3' end of the BR 1 gene and ends in repetitive structures partly different from the repeat units in the core block. A 55 bp long intron separates the core block, which probably constitutes a single exon, from a non-related 3'-exon, comprising the final 332 bp of the translated part of the gene. According to hydrophobicity and secondary structure predictions, the 3'-exon encoded peptide is distinctly different from the repetitive core block domain and attains a globular structure. The carboxyl-terminal peptide domain is likely to be a general feature of BR encoded proteins and may have important functions in the excretion and polymerisation of the secretory proteins.

Structural implications of primary sequences from a family of Balbiani ring-encoded proteins in Chironomus

DNA sequencing has revealed an internal, tandemly repetitive structure in the family of giant polypeptides encoded by three types of Balbiani ring (BR) genes, in three different species of Chironomus. Each major BR repeat can be subdivided into two halves: a region consisting of short subrepeats and a more constant region that lacks obvious subrepeats. Comparative predictions of secondary structure indicate that an alpha-helical segment is consistently present in the amino-terminal half of the constant region in all known BR proteins. Comparative predictions, coupled with consideration of the known phosphorylation of serine and threonine residues in BR proteins, suggest that the alpha-helical structure may also extend into the carboxy-terminal half of the constant region, possibly interrupted by beta-turn(s). However, it is also possible that the structure is variable, and that a beta-strand is present in that half in some cases. All of the constant regions conserve one methionine and one phenylalanine residue, as well as all four cysteines; these residues presumably play roles in the packing or cross-linking of aligned constant regions. The structure of the subrepeat region is not clear, but the prevalence of a tripeptide pattern (basic-proline-acidic) suggests some type of structural regularity, possibly an extended helix. The possible significance of these conserved molecular features is discussed in the context of how they may serve the elasticity, insolubility, and hydrophilicity of the fibrils and threads formed by the BR polypeptides.

Conserved and nonconserved structures in the secretory proteins encoded in the Balbiani ring genes of Chironomus tentans

The large, repetitive Balbiani ring (BR) genes, BR 1, 2, and 6, in Chironomus tentans originated from a short ancestral sequence and have all evolved according to analogous amplification schemes. We analyzed the structures of the BR-encoded secretory proteins and defined the parts that have been conserved during the evolutionary process. The BR products show striking similarities, with the BR 1 and BR 2 products being more similar to each other than to the BR 6 product. In the constant (C) region of the repeat units, 7 of the 30 amino acid residues are strictly conserved; 4 of these are the cysteine residues. The subrepeat (SR) regions of all the BR products are dominated by repeated tripeptide elements rich in proline and charged amino acid residues. Most of the amino acid replacements in both regions are conservative. Secondary structure predictions suggested that the C regions of the BR 1 and BR 2 products have several elements of secondary structure: an alpha-helix, a beta-strand, and one or two reverse turns, as in "globular structures." The prediction for the C region of the BR 6 product is similar but lacks a beta-strand. The predictions for the intervening SR regions appear less conclusive, but are clearly different from those for the C regions, and suggest regular structures not differing in their conformational elements. The SR regions evolved from an ancestor sequence similar to the C region; thus, the BR products seem to represent an example of evolution from one structure to two differently folded products.(ABSTRACT TRUNCATED AT 250 WORDS)

Balbiani ring DNA: sequence comparisons and evolutionary history of a family of hierarchically repetitive protein-coding genes

All known types of Balbiani ring (BR) genes consist of multiple, tandemly arranged, ca. 180 to 300-bp repeat units that can be divided into a constant region and a subrepeat region. The latter region includes short tandem subrepeats (SRs). Comparison of all available BR sequences using computer methods has enabled us (a) to define more precisely the constant and subrepeat regions, (b) to infer the evolutionary relationships among the various types of BR repeats, (c) to derive a consensus approximation of an ancestral sequence from a small segment of which the highly diverse present-day SRs may have originated, and (d) to detect an underlying substructure in the constant region, evident in the consensus but not in the present-day sequences and possibly corresponding to an original 39-bp DNA segment from which the extant, giant BR sequences may have evolved. We discuss the processes of reduplication, diversification, and homogenization within the hierarchically repetitive BR sequences as examples of how a simple DNA element may evolve into a diverse family of large, protein-coding genes.

Self-complementary DNA sequences within the BRc gene of Chironomus thummi

The Balbiani ring c (BRc) DNA of Chironomus thummi consists of tandemly arranged 249-base pair (bp) repeats, which represent the major part of the gene (Bäumlein et al. 1982a) and are transcribed and translated in a periodic polypeptide of unusual size. To obtain further information on the DNA sequence organization of that gene a recombinant phage (lambda CthBRc-1) with a relatively long insert (containing predominantly 249-bp repeats) was studied by electron microscopy (EM). lambda CthBRc-1 was found to undergo specific sequence elimination of BRc DNA resulting in heterogeneous size distribution of insert length within the limits of the cloning capacity of the phage with a maximum around 15 kilobase pairs (kb). The EM analysis of R loops formed between recombinant molecules and poly(A)+RNA (containing the transcripts of BRc and BRb) revealed the existence of self-complementary inverted and direct repeats as further sequence elements of BRc DNA scattered throughout a long portion of the BRc transcription unit. Different intrastrand structures (stems, hairpins, complex loops) originate from the renaturation of several sets of self-complementary repeats. Most double-stranded regions fell into one main-size class with an average length of 0.1 kb. The overall data suggest that self-complementary repeats belong to the same DNA sequence family and are able to cooperate in the formation of loops of different size and complexity. The results are discussed in relation to the functional significance of self-complementary inverted repeats (palindromes) for BRc expression.

Balbiani ring 6 gene in Chironomus tentans: a diverged member of the Balbiani ring gene family

We describe the internal organization of a large part of the Balbiani ring (BR) 6 gene in Chironomus tentans. The BR6 gene is a diverged member of the BR gene family. It displays the characteristic hierarchic organization of repetitive sequences, but in the constant region of the repeat units the overall sequence homology is only 49% when compared to other BR genes. All four cysteines are among the few amino acids conserved in the constant region. In the subrepeat region the central part is built from a repeated tripeptide, Pro-Glu--Arg+. A similar charge distribution adjacent to prolines is found in other BR gene subrepeat regions, most pronouncedly in the BR2-encoded protein. These conserved properties of the BR gene products are relevant to the issue how the various BR gene products interact to form a supramolecular structure, the larval tube, and how functional demands influence the evolution of a eucaryotic gene family.

Evolution of the albumin: alpha-fetoprotein ancestral gene from the amplification of a 27 nucleotide sequence

The genes for alpha-fetoprotein and albumin arose by duplication of an ancestral gene that contained three genetic domains. These domains were generated by the triplication of a primordial genetic domain composed of five exons or subdomains. That the primordial domain itself arose by amplification of a simpler sequence is suggested by nucleotide sequence homologies among the subdomains of the mouse alpha-fetoprotein gene. A detailed analysis of these homologies reveals that each of the five subdomain families contains remnants of a 27-base-long repeat from which the entire alpha-fetoprotein coding sequence has been assembled. A consensus sequence for the 27 nucleotide repeat is derived, and the positions of the repeats within each subdomain are described. A model is proposed for the evolution of the primordial domain by the amplification and divergence of the 27 base-pair sequence, along with the condensation of the repeats into subdomains separated by intervening sequences. It is postulated that the role of intervening sequences may be to limit sequence amplification in genes such as alpha-fetoprotein and albumin whose protein products cannot tolerate size variation.

A variant tandemly repeated nucleotide sequence in Balbiani ring 2 of Chironomus tentans

pCtBR2-2 is a genomic clone from Chironomus tentans that hybridized in situ to Balbiani ring 2 (BR2) on salivary gland polytene chromosome IV. DNA sequencing indicated that the insert contained nearly four copies of a 180 bp tandemly repeated nucleotide sequence that was distinctly different from a previously reported BR2 repeat. Sequence titration experiments detected about 70 copies of the 180 bp repeat per haploid genome, which would correspond to approximately 34% of a 37 kb BR2 gene. Each 180 bp repeat included a conserved 90 bp segment whose sequence was internally nonrepeating (INR), and a variable 90 bp repeated (R) segment comprised of three 30 bp repeats that may have evolved from a 9 bp consensus sequence. Results presented here raise the distinct possibility that other BR genes may contain significantly different repeated sequences that have not been identified.

[Do repetitive DNA sequences have a biological function?]

By DNA reassociation kinetics it is known that the eucaryotic genome consists of non-repetitive DNA, middle-repetitive DNA and highly repetitive DNA. Whereas the majority of protein-coding genes is located on non-repetitive DNA, repetitive DNA forms a constitutive part of eucaryotic DNA and its amount in most cases equals or even substantially exceeds that of non-repetitive DNA. During the past years a large body of data on repetitive DNA has accumulated and these have prompted speculations ranging from specific roles in the regulation of gene expression to that of a selfish entity with inconsequential functions. The following article summarizes recent findings on structural, transcriptional and evolutionary aspects and, although by no means being proven, some possible biological functions are discussed.