Structure of the macronuclear polyubiquitin gene in Euplotes

Variations and evolution of polyubiquitin genes from ciliates

Polyubiquitin genes from seven ciliate species were amplified, cloned and sequenced. It is estimated that Strombidium sulcatum, Euplotes vannus, E. rariseta and Anteholosticha manca have a polyubiquitin gene of 3 repeats, and A. parawarreni, Paramecium caudatum and Pseudokeronopsis flava 4 repeats. The newly obtained ubiquitins mostly differ from that of humans by 1-5 residues in amino acid sequences. A neighbor-joining tree constructed based on monomeric ubiquitin genes supports the monophyly of an assemblage comprising the litostomateans and some oligohymenophoreans, but not the class Spirotrichea. The monomers from the same species are generally placed together and highly supported for the class Litostomatea, the genera Paramecium and Ichthyophthirius, but not for other species. The non-synonymous/synonymous rate ratio (dN/dS) at the protein level are less than 1, and the synonymous nucleotide differences per synonymous site (p(S)) from intraspecific comparisons are fairly high (0.02-0.72). These results indicate that ciliates have not only the conserved, but also some quite divergent, polyubiquitin genes and confirm that the polyubiquitin genes in ciliates evolve according to the birth-and-death mode of evolution under strong purifying selection.

A unique pattern of intrastrand anomalies in base composition of the DNA in hypotrichs

The 50 non-coding bases immediately internal to the telomeric repeats in the two 5' ends of macronuclear DNA molecules of a group of hypotrichous ciliates are anomalous in composition, consisting of 61% purines and 39% pyrimidines, A>T (ratio of 44:32), and G>C (ratio of 17:7). These ratio imbalances violate parity rule 2, according to which A should equal T and G should equal C within a DNA strand and therefore pyrimidines should equal purines. The purine-rich and base ratio imbalances are in marked contrast to the rest of the non-coding parts of the molecules, which have the theoretically expected purine content of 50%, with A = T and G = C. The ORFs contain an average of 52% purines as a result of bias in codon usage. The 50 bases that flank the 5' ends of macronuclear sequences in micronuclear DNA (12 cases) consist of approximately 50% purines. Thus, the 50 bases in the 5' ends of macronuclear sequences in micronuclear DNA are islands of purine richness in which A>T and G>C. These islands may serve as signals for the excision of macronuclear molecules during macronuclear development. We have found no published reports of coding or non-coding native DNA with such anomalous base composition.

Characterization of a polyubiquitin gene in T. thermophila and of ubiquitin gene expression during sexual reproduction and under stress conditions

A 5-unit polyubiquitin gene, TTU3, was isolated from a T. thermophila genomic library and sequenced. This gene presents an extra triplet coding for Phe, a AGAGA motif and a putative HSE element in its 5'-non-coding region. The ubiquitin gene expression in this ciliate was investigated by Northern blot hybridization in conjugating cells or cells under stress conditions. Exponentially growing cells express two ubiquitin mRNAs of 0.75 and 1.8 kb and a new species of 1.4 kb is induced under hyperthermic stress. During sexual reproduction of the cells (conjugation) the 1.8-kb mRNA is still transcribed whereas the steady-state population of the 0.75 mRNA transcripts is strongly diminished. Southern blot analysis suggests that ubiquitin in T. thermophila constitutes a large family of about ten members.

Macronuclear gene-sized molecules of hypotrichs

The macronuclear genome of hypotrichous ciliates consists of DNA molecules of gene-sized length. A macronuclear DNA molecule contains a single coding region. We have analyzed the many hypotrich macronuclear DNA sequences sequenced by us and others. No highly conserved promoter sequences nor replication initiation sequences have been identified in the 5' nor in the 3' non-translated regions, suggesting that promoter function in hypotrichs may differ from other eukaryotes. The macronuclear genes are intron-poor; approximately 19% of the genes sequenced to date have one to three introns. Not all macronuclear DNA molecules may be transcribed; some macronuclear molecules may not have any coding function. Codon bias in hypotrichs is different in many respects from other ciliates and from other eukaryotes.

Phylogenetic relationship of ubiquitin repeats in the polyubiquitin gene from the marine sponge Geodia cydonium

Ubiquitin is a 76-residue protein which is highly conserved among eukaryotes. Sponge (Porifera) ubiquitin, isolated from Geodia cydonium, is encoded by a gene (termed GCUBI) with six repeats, GCUBI-1 to GCUBI-6. All repeat units encode the same protein (with one exception: GCUBI-4 encodes ubiquitin with a change of Leu to Val at position 71). On the nt level the sequences of the six repeats differ considerably. All changes (except in GCUBI-4) are silent substitutions, which do not affect the protein structure. However, there is one major difference between the repeats: Codons from both codon families (TCN and AGPy) are simultaneously used for the serine at position 65. Using this characteristic the repeats were divided into two groups: Group I: GCUBI-1,3 (TCT codon) and GCUBI-5 (TCC); Group II: GCUBI-2,4,6 (AGC codon). Mutational analysis suggests that the sponge polyubiquitin gene evolved from an ancestral monoubiquitin gene by gene duplication and successive tandem duplications. The ancestral monoubiquitin gene most probably coded for threonine (ACC) at position 65. The first event, duplication of the monoubiquitin gene, happened some 110 million years ago. Since sponges from the genus Geodia are known from the Cretaceous (145 million) to recent time, it is very likely that all events in the evolution of polyubiquitin gene occurred in the same genus. Alignment data of the "consensus" ubiquitin nt sequences of different animals (man to protozoa) reflect very well the established phylogenetic relationships of the chosen organisms and show that the sponge ubiquitin gene branched off first from the multicellular organisms.

The DNA of ciliated protozoa

Ciliates contain two types of nuclei: a micronucleus and a macronucleus. The micronucleus serves as the germ line nucleus but does not express its genes. The macronucleus provides the nuclear RNA for vegetative growth. Mating cells exchange haploid micronuclei, and a new macronucleus develops from a new diploid micronucleus. The old macronucleus is destroyed. This conversion consists of amplification, elimination, fragmentation, and splicing of DNA sequences on a massive scale. Fragmentation produces subchromosomal molecules in Tetrahymena and Paramecium cells and much smaller, gene-sized molecules in hypotrichous ciliates to which telomere sequences are added. These molecules are then amplified, some to higher copy numbers than others. rDNA is differentially amplified to thousands of copies per macronucleus. Eliminated sequences include transposonlike elements and sequences called internal eliminated sequences that interrupt gene coding regions in the micronuclear genome. Some, perhaps all, of these are excised as circular molecules and destroyed. In at least some hypotrichs, segments of some micronuclear genes are scrambled in a nonfunctional order and are recorded during macronuclear development. Vegetatively growing ciliates appear to possess a mechanism for adjusting copy numbers of individual genes, which corrects gene imbalances resulting from random distribution of DNA molecules during amitosis of the macronucleus. Other distinctive features of ciliate DNA include an altered use of the conventional stop codons.

Characterization of transcription initiation, translation initiation, and poly(A) addition sites in the gene-sized macronuclear DNA molecules of Euplotes

The DNA in the transcriptionally active macronucleus of the hypotrichous ciliate Euplotes crassus exists as short, linear molecules with each molecule encoding a single genetic function. Previous work has indicated that coding regions occupy the majority of macronuclear DNA molecules. In the present study we have defined the transcription initiation sites and poly(A) addition sites for a number of different macronuclear genes in Euplotes crassus. Our results indicate that mature transcripts represent all but approximately 100-200 bases of the non-telomeric sequences in macronuclear DNA molecules. We have also examined the sequences in the vicinity of transcription start sites, poly(A) addition sites, and translation initiation sites for Euplotes species genes in an attempt to define the cis-acting elements that control these processes. Our results indicate that some of the common sequence elements known to control these processes in higher eukaryotes are likely not utilized by Euplotes genes. The data do indicate the presence of other conserved sequences both preceding and at the site of poly(A) addition, as well as at the site of translation initiation. These conserved sequences may serve an analogous role in these organisms. Finally, we have found that most macronuclear DNA molecules have transcription initiation sites within 30 bp of the telomere, suggesting that the telomere may play a role in promoting transcription.

Inaccessibility of the Euplotes telomere binding protein

The telomere binding protein (TP) from the macronucleus of the ciliate Euplotes eurystomus was purified by removal of tenaciously bound DNA with hydroxylapatite, and the purified TP partially sequenced. Rabbit antiserum was generated against a synthetic peptide of 14 amino acids at the amino-terminus of the TP. This antiserum was employed to examine the accessibility of TP antigenic determinants in nuclei and chromatin. Immunofluorescent staining of isolated macronuclei revealed only weak reactivity with specific antiserum. Reactivity within replication bands was demonstrated, and could be augmented by preparation of nuclear scaffolds. Employing a dot immunoblot analysis, the amino-terminal antigenic determinants of TP were revealed after extraction of histone H1 (and some nonhistones). A different aspect of TP inaccessibility was demonstrated by immunoblot analysis of trypsin-treated macronuclei and chromatin; TP was considerably less susceptible to digestion by trypsin than were histones H1 and H3. The relative inaccessibility of TP was not a consequence of chromatin higher-order structure, since soluble macronuclear chromatin in low salt exhibited the same burying of antigenic determinants by dot blot analysis, and the same decreased susceptibility to trypsin, as did isolated nuclei. Electron microscopy of soluble macronuclear chromatin spread in low salt revealed that most telomeres appear unfolded, without stable higher-order structure. The mechanisms for the relative inaccessibility of TP are not yet known, but probably arise as a consequence of the strong interactions of TP with the telomere nucleotide sequence and additional interactions of TP with various chromatin proteins, perhaps including histone H1.

Cloning of the polyubiquitin cDNA from the marine sponge Geodia cydonium and its preferential expression during reaggregation of cells

Ubiquitination of proteins is a critical step in the controlled degradation process of many polypeptides. Here we show that sponges, the simplest multicellular group of eukaryotic organisms, are also equipped with the ubiquitin pathway. The polyubiquitin cDNA was isolated and characterized from the marine sponge Geodia cydonium. The open reading frame contains six ubiquitin moieties, which are lined up head to tail without spacers. A comparison of the predicted amino acid sequence of the six sponge ubiquitin-coding units with those from other organisms revealed a high degree of homology (> 93%). The ubiquitin gene is expressed to almost the same extent in the two main compartments of the sponge, the cortex and the medulla. However, only in the cortex are detectable amounts of the ubiquitin protein synthesized. The ubiquitin protein isolated from the sponge organism was found to initiate protein degradation in the heterologous reticulocyte system in the same manner as bovine ubiquitin. In vitro studies with dissociated sponge cells revealed that the homologous aggregation factor causes (i) a strong increase in the steady-state level of mRNA coding for ubiquitin and (ii) a drastic increase in ubiquitin protein synthesis, while the homologous lectin failed to display that effect in isolated cells. These data suggest that ubiquitin may play a role in sponge morphogenesis.

Euplotes crassus has genes encoding telomere-binding proteins and telomere-binding protein homologs

We have identified two 1.6 kb macronuclear DNA molecules from Euplotes crassus that hybridize to the alpha subunit of the Oxytricha telomere protein. We have shown that one of these molecules encodes the 51 kDa Euplotes telomere protein while the other appears to encode a homolog of the telomere protein. Although this homolog clearly differs in sequence from the Euplotes telomere protein, the two proteins share extensive amino acid sequence identity with each other and with the alpha subunit of the Oxytricha telomere protein. In all three proteins 35-36% of the amino acids are identical, while 54-56% are similar. The most extended regions of sequence conservation map within the N-terminal section; this section has been shown to comprise the DNA-binding domain in the Euplotes telomere protein. Our findings suggest that some of the conserved amino acids may be involved in DNA recognition and binding. The gene encoding the telomere protein homolog contains two introns; one of these introns is only 24 bp in length. This is the smallest mRNA intron reported to date.