Genome gymnastics: unique modes of DNA evolution and processing in ciliates

Macronuclear genome structure of the ciliate Nyctotherus ovalis: single-gene chromosomes and tiny introns

BACKGROUND

Nyctotherus ovalis is a single-celled eukaryote that has hydrogen-producing mitochondria and lives in the hindgut of cockroaches. Like all members of the ciliate taxon, it has two types of nuclei, a micronucleus and a macronucleus. N. ovalis generates its macronuclear chromosomes by forming polytene chromosomes that subsequently develop into macronuclear chromosomes by DNA elimination and rearrangement.

RESULTS

We examined the structure of these gene-sized macronuclear chromosomes in N. ovalis. We determined the telomeres, subtelomeric regions, UTRs, coding regions and introns by sequencing a large set of macronuclear DNA sequences (4,242) and cDNAs (5,484) and comparing them with each other. The telomeres consist of repeats CCC(AAAACCCC)n, similar to those in spirotrichous ciliates such as Euplotes, Sterkiella (Oxytricha) and Stylonychia. Per sequenced chromosome we found evidence for either a single protein-coding gene, a single tRNA, or the complete ribosomal RNAs cluster. Hence the chromosomes appear to encode single transcripts. In the short subtelomeric regions we identified a few overrepresented motifs that could be involved in gene regulation, but there is no consensus polyadenylation site. The introns are short (21-29 nucleotides), and a significant fraction (1/3) of the tiny introns is conserved in the distantly related ciliate Paramecium tetraurelia. As has been observed in P. tetraurelia, the N. ovalis introns tend to contain in-frame stop codons or have a length that is not dividable by three. This pattern causes premature termination of mRNA translation in the event of intron retention, and potentially degradation of unspliced mRNAs by the nonsense-mediated mRNA decay pathway.

CONCLUSION

The combination of short leaders, tiny introns and single genes leads to very minimal macronuclear chromosomes. The smallest we identified contained only 150 nucleotides.

The pathway to detangle a scrambled gene

Background

Programmed DNA elimination and reorganization frequently occur during cellular differentiation. Development of the somatic macronucleus in some ciliates presents an extreme case, involving excision of internal eliminated sequences (IESs) that interrupt coding DNA segments (macronuclear destined sequences, MDSs), as well as removal of transposon-like elements and extensive genome fragmentation, leading to 98% genome reduction in Stylonychia lemnae. Approximately 20–30% of the genes are estimated to be scrambled in the germline micronucleus, with coding segment order permuted and present in either orientation on micronuclear chromosomes. Massive genome rearrangements are therefore critical for development.

Methodology/Principal Findings

To understand the process of DNA deletion and reorganization during macronuclear development, we examined the population of DNA molecules during assembly of different scrambled genes in two related organisms in a developmental time-course by PCR. The data suggest that removal of conventional IESs usually occurs first, accompanied by a surprising level of error at this step. The complex events of inversion and translocation seem to occur after repair and excision of all conventional IESs and via multiple pathways.

Conclusions/Significance

This study reveals a temporal order of DNA rearrangements during the processing of a scrambled gene, with simpler events usually preceding more complex ones. The surprising observation of a hidden layer of errors, absent from the mature macronucleus but present during development, also underscores the need for repair or screening of incorrectly-assembled DNA molecules.

Intron Evolution and Information processing in the DNA polymerase alpha gene in spirotrichous ciliates: a hypothesis for interconversion between DNA and RNA deletion

BACKGROUND

The somatic DNA molecules of spirotrichous ciliates are present as linear chromosomes containing mostly single-gene coding sequences with short 5' and 3' flanking regions. Only a few conserved motifs have been found in the flanking DNA. Motifs that may play roles in promoting and/or regulating transcription have not been consistently detected. Moreover, comparing subtelomeric regions of 1,356 end-sequenced somatic chromosomes failed to identify more putatively conserved motifs.

RESULTS

We sequenced and compared DNA and RNA versions of the DNA polymerase alpha (pol alpha) gene from nine diverged spirotrichous ciliates. We identified a G-C rich motif aaTACCGC(G/C/T) upstream from transcription start sites in all nine pol alpha orthologs. Furthermore, we consistently found likely polyadenylation signals, similar to the eukaryotic consensus AAUAAA, within 35 nt upstream of the polyadenylation sites. Numbers of introns differed among orthologs, suggesting independent gain or loss of some introns during the evolution of this gene. Finally, we discuss the occurrence of short direct repeats flanking some introns in the DNA pol alpha genes. These introns flanked by direct repeats resemble a class of DNA sequences called internal eliminated sequences (IES) that are deleted from ciliate chromosomes during development.

CONCLUSION

Our results suggest that conserved motifs are present at both 5' and 3' untranscribed regions of the DNA pol alpha genes in nine spirotrichous ciliates. We also show that several independent gains and losses of introns in the DNA pol alpha genes have occurred in the spirotrichous ciliate lineage. Finally, our statistical results suggest that proven introns might also function in an IES removal pathway. This could strengthen a recent hypothesis that introns evolve into IESs, explaining the scarcity of introns in spirotrichs. Alternatively, the analysis suggests that ciliates might occasionally use intron splicing to correct, at the RNA level, failures in IES excision during developmental DNA elimination.

A model for the origin of internal eliminated segments (IESs) and gene rearrangement in stichotrichous ciliates

A characteristic feature of ciliates (ciliated protozoans) is their nuclear dimorphism: the presence of two kinds of functionally different nuclei in the same cell--a micronucleus (MIC) and the macronucleus (MAC). In the stichotrichous group of ciliates the organization of DNA in the MIC is dramatically different from that in the MAC. Genes in the MIC consist of the sequence of segments, called MDSs, which are separated by short noncoding pieces of DNA, called IESs. Moreover, the order of MDSs in the MIC may be scrambled compared to their order in the MAC, and also some MDSs may be inverted with respect to each other. In this paper, we consider the evolutionary origin of this bizarre form of MIC genes, and in particular we postulate that the insertion of IESs as well as possible scramblings/inversions have resulted from a repair of one or more breaks in a DNA molecule. We propose a specific repair scheme, and postulate that this repair scheme applied to a coiled structure of a DNA molecule that has undergone multiple breaks can produce IES insertions and/or scrambled/inverted MIC gene patterns. All experimentally demonstrated as well as theoretical MIC gene patterns can be produced in this way.

New Insights into the Macronuclear Development in Ciliates

During macronuclear differentiation in ciliated protozoa, most amazing "DNA gymnastics" takes place, which includes DNA excision, DNA elimination, DNA reorganization, and DNA-specific amplification. Although the morphological events occurring during macronuclear development are well described, a detailed knowledge of the molecular mechanisms and the regulation of this differentiation process is still missing. However, recently several models have been proposed for the molecular regulation of macronuclear differentiation, but these models have yet to be verified experimentally. The scope of this review is to summarize recent discoveries in different ciliate species and to compare and discuss the different models proposed. Results obtained in these studies are not only relevant for our understanding of nuclear differentiation in ciliates, but also for cellular differentiation in eukaryotic organisms in general as well as for other disciplines such as bioinformatics and computational biology.

Chromatin diminution in the copepod Mesocyclops edax: diminution of tandemly repeated DNA families from somatic cells

Chromatin diminution, i.e., the loss of selected chromosomal regions during the differentiation of early embryonic cells into somatic cells, has been described in taxa as varied as ciliates, copepods, insects, nematodes, and hagfish. The nature of the eliminated DNA has been extensively studied in ciliate, nematode, and hagfish species. However, the small size of copepods, which makes it difficult to obtain enough DNA from early embryonic cells for cloning and sequencing, has limited such studies. Here, to identify the sequences eliminated from the somatic cells of a copepod species that undergoes chromatin diminution, we randomly amplified DNA fragments from germ line and somatic line cells of Mesocyclops edax, a freshwater cyclopoid copepod. Of 47 randomly amplified germ line clones, 45 (96%) contained short, tandemly repeated sequences composed of either 2 bp CA-repeats, 8 bp CAAATAGA-repeats, or 9 bp CAAATTAAA-repeats. In contrast, of 83 randomly amplified somatic line clones, only 47 (57%) contained such short, tandemly repeated sequences. As previously observed in some nematode species, our results therefore show that there is partial elimination of chromosomal regions containing (CAAATAGA and CAAATTAAA) repeated sequences during the chromatin diminution observed in the somatic cells of M. edax. We speculate that chromatin diminution might have evolved repeatedly by recruitment of RNAi-related mechanisms to eliminate nonfunctional tandemly repeated DNA sequences from the somatic genome of some species.

snRNA and heterochromatin formation are involved in DNA excision during macronuclear development in stichotrichous ciliates

Several models for specific excision of micronucleus-specific DNA sequences during macronuclear development in ciliates exist. While the template-guided recombination model suggests recombination events resulting in specific DNA excision and reordering of macronucleus-destined sequences (MDS) guided by a template, there is evidence that an RNA interference-related mechanism is involved in DNA elimination in holotrichous ciliates. We describe that in the stichotrichous ciliate Stylonychia, snRNAs homologous to micronucleus-specific sequences are synthesized during macronuclear differentiation. Western and in situ analyses demonstrate that histone H3 becomes methylated at K9 de novo during macronuclear differentiation, and chromatin immunoprecipitation revealed that micronucleus-specific sequences are associated with methylated H3. To link both observations, expression of a PIWI homolog, member of the RNA-induced silencing complex, was silenced. In these cells, the methylated micronucleus-specific histone H3 variant "X" is still present in macronuclear anlagen and no K9 methylation of histone H3 is observed. We suggest that snRNA recruits chromatin-modifying enzymes to sequences to be excised. Based on our and earlier observations, we believe that this mechanism is not sufficient for specific excision of sequences and reordering of MDS in the developing macronucleus and propose a model for internal eliminated sequence excision and MDS reordering in stichotrichous ciliates.

Horizontal gene transfer from Bacteria to rumen Ciliates indicates adaptation to their anaerobic, carbohydrates-rich environment

Background

The horizontal transfer of expressed genes from Bacteria into Ciliates which live in close contact with each other in the rumen (the foregut of ruminants) was studied using ciliate Expressed Sequence Tags (ESTs). More than 4000 ESTs were sequenced from representatives of the two major groups of rumen Cilates: the order Entodiniomorphida (Entodinium simplex, Entodinium caudatum, Eudiplodinium maggii, Metadinium medium, Diploplastron affine, Polyplastron multivesiculatum and Epidinium ecaudatum) and the order Vestibuliferida, previously called Holotricha (Isotricha prostoma, Isotricha intestinalis and Dasytricha ruminantium).

Results

A comparison of the sequences with the completely sequenced genomes of Eukaryotes and Prokaryotes, followed by large-scale construction and analysis of phylogenies, identified 148 ciliate genes that specifically cluster with genes from the Bacteria and Archaea. The phylogenetic clustering with bacterial genes, coupled with the absence of close relatives of these genes in the Ciliate Tetrahymena thermophila, indicates that they have been acquired via Horizontal Gene Transfer (HGT) after the colonization of the gut by the rumen Ciliates.

Conclusion

Among the HGT candidates, we found an over-representation (>75%) of genes involved in metabolism, specifically in the catabolism of complex carbohydrates, a rich food source in the rumen. We propose that the acquisition of these genes has greatly facilitated the Ciliates' colonization of the rumen providing evidence for the role of HGT in the adaptation to new niches.

Evolution of developmentally regulated genome rearrangements in eukaryotes

Developmentally regulated genome rearrangements (DRGR)--processes that alter genomes either in specific cells or during specific life cycle stages--are widespread throughout eukaryotes. This contrasts with the view that genome structure and content remain essentially constant throughout an organism's life cycle. Here we review three categories of developmentally regulated genome processing in eukaryotes: genome-wide rearrangements, targeted rearrangements, and a special case of amplification of ribosomal DNA genes. Mapping these types of DRGR onto eukaryotic phylogeny indicates that each type of processing is found in multiple independent lineages. We propose that such genome rearrangements were present within the last common ancestor of extant eukaryotes, and that future research will yield evidence of homologous epigenetic mechanisms underlying genome processing among diverse eukaryotes.

A new scrambled gene in the ciliate Uroleptus

In the germline micronucleus of spirotrichous ciliates, the gene segments, or macronuclear destined sequences (MDSs), that give rise to the somatic macronucleus are interrupted by internal eliminated sequences (IESs). For some genes, the MDSs are not arranged sequentially, but rather are scrambled, in the micronucleus. Three scrambled genes have been extensively studied in many species: actin I, alpha-telomere binding protein, and DNA polymerase alpha. However, in the past decade, no new scrambled genes have been reported, and the prevalence of scrambled genes is still an important question. To screen for scrambled genes, we completely sequenced 11 macronuclear chromosomes in the spirotrich Uroleptus sp., and then pursued their micronuclear organization. This allowed us to identify new scrambled genes, which also display novel features. In this study we describe one of these newly discovered scrambled genes. This gene, tentatively named USG1 (Unknown Scrambled Gene 1), encodes a putative protein of 1016 aa. While the function of this protein product is not clear, dN/dS calculated from the two alleles suggests the encoded protein is under purifying selection. USG1 consists of 16 germline MDSs, of which 14 are located on one locus. The other locus, which is at least 3 kb away from the main locus, contains two scrambled MDSs separated by a nonscrambled IES. Curiously, one MDS and its outgoing (3') pointer (direct repeat) overlap intron splice sites, indicating that these DNA sequences may be under dual (or multiple) constraints. Our findings identify a new scrambled gene in the micronuclear genome of a spirotrichous ciliate, and suggest that even more complicated structures may be present.

Gene structure of the ciliate Sterkiella histriomuscorum based on a combined analysis of DNA and cDNA sequences from 21 macronuclear chromosomes

Macronuclear deoxyribonucleic acid (DNA) in hypotrichous ciliates consists of a set of linear molecules ranging in size from 0.5 to several tens of kilobases and typically carrying a single gene. Each minichromosome is present at a ploidy of >or=1,000 per macronucleus. These molecules are known as gene-sized molecules. Multigene molecules are also present, but are still poorly described. In analyzing the encystment-excystment cycle of Sterkiella histriomuscorum, we have characterized a set of 21 macronuclear molecules both at the DNA and complementary DNA (cDNA) levels. On a total of 23 validated coding sequences, we mapped the 5' and 3' untranslated regions for a subset of 10 and 18 transcripts, respectively. A combination of DNA and cDNA data allows us to precisely determine several structural features of macronuclear chromosomes, such as the organization of multigene molecules, an intron content higher than expected, and a conserved sequence surrounding the initiation transcription site. It also reveals one coding sequence containing a transcribed 10-bp element that displays the characteristic features of internal eliminated sequences (IES). Its presence in a fraction of the minichromosomes carrying this gene raises the possibility of an incomplete IES excision process during the development of the S. histriomuscorum macronucleus.

Complex germline architecture: two genes intertwined on two loci

The germline micronuclear genome of some ciliated protists can be scrambled, with coding segments disordered relative to the expressed macronuclear genome. Here, we report a surprisingly complex pair of genes that assemble from interwoven segments on two germline loci in the ciliate Uroleptus. This baroque organization requires two scrambled genes to be disentangled from each other from two clusters in the genome, one containing segments 1-2-4-5-6-8-11-13-15-16 and the other 7-9-3-10-12-14, with pieces 1-5 comprising the first gene and 6-16 the second gene. Both genes remain linked in the somatic genome on a 1.5-kb "nanochromosome." This study is the first to reveal that two genes can become scrambled during evolution with their coding segments intertwined. These twin scrambled genes underscore the beauty and exceptions of protist genome architecture, pointing to the critical need for evolutionary biologists to survey protist genomes broadly.

Why repetitive DNA is essential to genome function

There are clear theoretical reasons and many well-documented examples which show that repetitive, DNA is essential for genome function. Generic repeated signals in the DNA are necessary to format expression of unique coding sequence files and to organise additional functions essential for genome replication and accurate transmission to progeny cells. Repetitive DNA sequence elements are also fundamental to the cooperative molecular interactions forming nucleoprotein complexes. Here, we review the surprising abundance of repetitive DNA in many genomes, describe its structural diversity, and discuss dozens of cases where the functional importance of repetitive elements has been studied in molecular detail. In particular, the fact that repeat elements serve either as initiators or boundaries for heterochromatin domains and provide a significant fraction of scaffolding/matrix attachment regions (S/MARs) suggests that the repetitive component of the genome plays a major architectonic role in higher order physical structuring. Employing an information science model, the 'functionalist' perspective on repetitive DNA leads to new ways of thinking about the systemic organisation of cellular genomes and provides several novel possibilities involving repeat elements in evolutionarily significant genome reorganisation. These ideas may facilitate the interpretation of comparisons between sequenced genomes, where the repetitive DNA component is often greater than the coding sequence component.

MDS_IES_DB: a database of macronuclear and micronuclear genes in spirotrichous ciliates

Ciliated protozoa have two kinds of nuclei: Macronuclei (MAC) and Micronuclei (MIC). In some ciliate classes, such as spirotrichs, most genes undergo several layers of DNA rearrangement during macronuclear development. Because of such processes, these organisms provide ideal systems for studying mechanisms of recombination and gene rearrangement. Here, we describe a database that contains all spirotrich genes for which both MAC and MIC versions are sequenced, with consistent annotation and easy access to all the features. An interface to query the database is available at http://oxytricha.princeton.edu/dimorphism/database.htm.

Epigenetic control of chromosome breakage at the 5' end of Paramecium tetraurelia gene A

Macronuclei and micronuclei of ciliates have related genomes, with macronuclei developing from zygotic micronuclei through programmed DNA rearrangements. While Paramecium tetraurelia wild-type strain 51 and mutant strain d48 have the same micronuclear genome, qualitative differences between their macronuclear genomes have been described, demonstrating that programmed DNA rearrangements could be epigenetically controlled in ciliates. Macronuclear chromosomes end downstream of gene A (A51 Mac ends) and at the 5' end of gene A (Ad48 Mac ends) in strains 51 and d48, respectively. To gain further insight into the process of chromosome end formation, we performed an extensive analysis of locus A rearrangement in strains d48 and 51, in strain d12, which harbors a gene A deletion, and in interstrain cross progeny. We show that (i) allele Ad12 harbors a deletion of >16 kb, (ii) A51 Mac ends distribute over four rather than three DNA regions, (iii) strains d48 and 51 display only quantitative differences (rare Ad48 and A51 Mac ends do form in strains 51 and d48, respectively), (iv) the level of A51 Mac ends is severalfold enhanced in d12- and d48-derived progeny, and (v) this level inversely correlates with the level of Ad48 Mac ends in the d48 parent. Together, these data lead to a model in which the formation of Ad48 Mac ends is epigenetically controlled by a d48 factor(s). We propose that the d48 factor(s) may be derived from RNA molecules transcribed from the Ad48 Mac ends and encompassing the truncated A gene and telomeric repeats.

A 21st century view of evolution: genome system architecture, repetitive DNA, and natural genetic engineering

The last 50 years of molecular genetics have produced an abundance of new discoveries and data that make it useful to revisit some basic concepts and assumptions in our thinking about genomes and evolution. Chief among these observations are the complex modularity of genome organization, the biological ubiquity of mobile and repetitive DNA sequences, and the fundamental importance of DNA rearrangements in the evolution of sequenced genomes. This review will take a broad overview of these developments and suggest some new ways of thinking about genomes as sophisticated informatic storage systems and about evolution as a systems engineering process.

Phylogenetic relationships among 28 spirotrichous ciliates documented by rDNA

The contiguous sequence of the SSU rDNA, ITS 1, 5.8S, ITS 2, and approximately 1370 bp at the 5(') end of the LSU rDNA was determined in 25 stichotrichs, one oligotrich, and two hypotrichs. Maximum parsimony, neighbor-joining, and quartet-puzzling analyses were used to construct individual phylogenetic trees for SSU rDNA, for LSU rDNA, and ITS 1+5.8S+ITS 2, as well as for all these components combined. All trees were similar, with the greatest resolution obtained with the combined components. Phylogenetic relationships were largely consistent with classical taxonomy, with notable disagreements. DNA sequences indicate that Oxytricha granulifera and Oxytricha longa are rather distantly related. The oligotrich, Halteria grandinella, is placed well within the order Stichotrichida. Uroleptus pisces and Uroleptus gallina probably belong to different genera. Holosticha polystylata (family Holostichidae) and Urostyla grandis (family Urostylidae) are rather closely related. These rDNA sequence analyses imply the need for some modifications of classical taxonomic schemes.

Template-guided recombination for IES elimination and unscrambling of genes in stichotrichous ciliates

The micronuclear versions of genes in stichotrichous ciliates are interrupted by multiple, short, non-coding DNA segments called internal eliminated segments, or IESs. IESs divide a gene into macronuclear destined segments, or MDSs. In some micronuclear genes MDSs are in a scrambled disorder. During development of a micronucleus into a macronucleus after cell mating the IESs are excised from micronuclear genes and the MDSs are spliced in the sequentially correct order. Pairs of short repeat sequences in the ends of MDSs undergo homologous recombination to excise IESs and splice MDSs. However, the repeat sequences are too short to guide unambiguously their own alignment in preparation for recombination. Based on experiments by others on the distantly related ciliate, Paramecium, we propose a molecular model of template-guided recombination to explain the excision of the 100,000-150,000 IESs and splicing of MDSs, including unscrambling, in the genome of stichotrichous ciliates. The model solves the problem of correct pairing of pointers, precisely identifies MDS-IES junctions, and provides for irreversible recombination.

Genome remodeling in ciliated protozoa

The germline genomes of ciliated protozoa are dynamic structures, undergoing massive DNA rearrangement during the formation of a functional macronucleus. Macronuclear development involves chromosome fragmentation coupled with de novo telomere synthesis, numerous DNA splicing events that remove internal segments of DNA, and, in some ciliates, the reordering of scrambled gene segments. Despite the fact that all ciliates share similar forms of DNA rearrangement, there appears to be great diversity in both the nature of the rearranged DNA and the molecular mechanisms involved. Epigenetic effects on rearrangement have also been observed, and recent work suggests that chromatin differentiation plays a role in specifying DNA segments either for rearrangement or for elimination.

Why are parasite contingency genes often associated with telomeres?

Contingency genes are common in pathogenic microbes and enable, through pre-emptive mutational events, rapid, clonal switches in phenotype that are conducive to survival and proliferation in hosts. Antigenic variation, which is a highly successful survival strategy employed by eubacterial and eukaryotic pathogens, involves large repertoires of distinct contingency genes that are expressed differentially, enabling evasion of host acquired immunity. Most, but not all, antigenic variation systems make extensive use of subtelomeres. Study of model systems has shown that subtelomeres have unusual properties, including reversible silencing of genes mediated by proteins binding to the telomere, and engagement in ectopic recombination with other subtelomeres. There is a general theory that subtelomeric location confers a capacity for gene diversification through such recombination, although experimental evidence is that there is no increased mitotic recombination at such loci and that sequence homogenisation occurs. Possible benefits of subtelomeric location for pathogen contingency systems are reversible gene silencing, which could contribute to systems for gene switching and mutually exclusive expression, and ectopic recombination, leading to gene family diversification. We examine, in several antigenic variation systems, what possible benefits apply.

On the roles of repetitive DNA elements in the context of a unified genomic-epigenetic system

Repetitive DNA sequences comprise a substantial portion of most eukaryotic and some prokaryotic chromosomes. Despite nearly forty years of research, the functions of various sequence families as a whole and their monomer units remain largely unknown. The inability to map specific functional roles onto many repetitive DNA elements (REs), coupled with the taxon-specificity of sequence families, have led many to speculate that these genomic components are "selfish" replicators generating genomic "junk." The purpose of this paper is to critically examine the selfishness, evolutionary effects, and functionality of REs. First, a brief overview of the range of ideas pertaining to RE function is presented. Second, the argument is presented that the selfish DNA "hypothesis" is actually a narrative scheme, that it serves to protect neo-Darwinian assumptions from criticism, and that this story is untestable and therefore not a hypothesis. Third, attempts to synthesize the selfish DNA concept with complex systems models of the genome and RE functionality are critiqued. Fourth, the supposed connection between RE-induced mutations and macroevolutionary events are stated to be at variance with empirical evidence and theoretical considerations. Hypotheses that base phylogenetic transitions in repetitive sequence changes thus remain speculative. Fifth and finally, the case is made for viewing REs as integrally functional components of chromosomes, genomes, and cells. It is argued throughout that a new conceptual framework is needed for understanding the roles of repetitive DNA in genomic/epigenetic systems, and that neo-Darwinian "narratives" have been the primary obstacle to elucidating the effects of these enigmatic components of chromosomes.

Genome organization and reorganization in evolution: formatting for computation and function

This volume deals with the role of epigenetics in life and evolution. The most dynamic forms of functional genome formatting involve DNA interacting with cellular complexes that do not alter sequence information. Such important epigenetic phenomena are the main subjects of other articles in this volume. This article focuses on the long-lived form of genome formatting that lies within the DNA sequence itself. I argue for a computational view of genome function as the long-term information storage organelle of each cell. Structural formatting consists of organizing various signals and coding sequences into computationally ready systems facilitating genome expression and genome transmission. The basic features of genome organization can be understood by examining the E. coli lac operon as a paradigmatic genomic system. Multiple systems are connected through distributed signals and repetitive DNA to form higher-order genome system architectures. Molecular discoveries about mechanisms of DNA restructuring show that cells possess the natural genetic engineering functions necessary for evolutionary change by rearranging genomic components and reorganizing system architectures. The concepts of cellular computation and decision-making, genome system architecture, and natural genetic engineering combine to provide a new way of framing evolutionary theories and understanding genome sequence information.

A PIWI homolog is one of the proteins expressed exclusively during macronuclear development in the ciliate Stylonychia lemnae

In the course of macronuclear differentiation in spirotrichous ciliates massive DNA reorganization processes take place, which include splicing, cutting, rearranging and eliminating specific DNA sequences. In order to identify genes involved in these processes we took advantage of suppression subtractive hybridization. We have identified three transcripts that are exclusively expressed during macronuclear development in the ciliate Stylonychia lemnae. Two of the three differentially expressed mRNAs we have analyzed encode for novel proteins. One gene, mdp1 [macronuclear development protein 1 (MDP1)], encodes a homolog of the PIWI protein family. PIWI proteins are involved in germline differentiation processes and RNA silencing in worms, flies, mice, humans and in plants. Possible functions of the S.lemnae PIWI related protein MDP1 in the regulation of macronuclear development will be discussed.

Immunoanalogue of vertebrate beta-adrenergic receptor in the unicellular eukaryote Paramecium

Cell fractionation, SDS-PAGE, quantitative Western blot, confocal immunolocalization and immunogold labelling were performed to find an interpretation of the physiological response of the unicellular eukaryote Paramecium to beta-adrenergic ligands. The 69 kDa polypeptide separated by SDS-PAGE in S2 and P2 Paramecium subcellular fractions cross-reacted with antibody directed against human beta2-adrenergic receptor. This was detected by Western blotting followed by chemiluminescent detection. Quantitative image analysis showed that beta-selective adrenergic agonist (-)-isoproterenol--previously shown to enhance phagocytic activity--evoked redistribution of the adrenergic receptor analogue from membraneous (P2) to cytosolic (S2) fraction. The relative increase in immunoreactive band intensity in S2 reached 80% and was paralleled by a 59% decrease in P2 fraction. Confocal immunofluorescence revealed beta2-adrenergic receptor sites on the cell surface and at the ridge of the cytopharynx--where nascent phagosomes are formed. This localization was confirmed by immunoelectron microscopy. These results indicate that the 69 kDa Paramecium polypeptide immunorelated to vertebrate beta2-adrenergic receptor appeared in this evolutionary ancient cell as a nutrient receptor.

Evolution of IESs and scrambling in the actin I gene in hypotrichous ciliates

Germ-line (micronuclear) genes in hypotrichous ciliates are interrupted by numerous, short, noncoding, AT-rich segments called internal eliminated segments, or IESs. IESs divide a gene into macronuclear destined segments, or MDSs. IESs are excised from micronuclear genes, and the MDSs are spliced when a micronuclear genome is processed into a macronuclear genome after cell mating. In the micronuclear version of the actin I gene intramolecular recombination between IESs during evolution has put MDSs into a scrambled disorder in some but not all hypotrichs. Studies using rDNA sequences to define phylogenetic relationships among eight hypotrichs suggests that evolution of the micronuclear actin I gene proceeds by successive addition of IESs in earlier diverging species, without MDS scrambling. Continued addition of IESs and recombination among IESs in later diverging species produced actin I genes with scrambled MDSs. Subsequent to MDS scrambling, additional IESs were inserted into the more recently evolved species. Thus, IES insertions and gene scrambling occur in a progressive manner during species evolution to produce micronuclear actin I genes of increasing structural complexity.

Control of DNA excision efficiency in Paramecium

Programmed excision of internal eliminated sequences (IESs) occurs at thousands of sites in ciliate genomes. How this is controlled is largely unknown. Here, we report the characterization of the non-efficiently excised 156psiG-11 IES from Paramecium primaurelia strain 156 and that of the efficiently excised 168psiG-11 IES, an allelic variant from strain 168. Then, we report a genetic and molecular analysis of IES excision efficiency in F(1) progeny derived from interstrain crosses and in F(2) homozygous progeny derived from F(1) autogamy. IES 168psiG-11 excision efficiency was approximately 100% in all cases. IES 156psiG-11 excision efficiency was 19 +/- 13% in F(1) progeny and 0.6 +/- 1.1% in F(2) progeny. No trans-excision event between IESs 156psiG-11 and 168psiG-11 was detected within the F(1) progeny. These data demonstrate that the excision efficiency of this IES is variable and controlled by a cis-acting element. This should encompass positions 8 and/or 9 of the right IES end, which display allele differences. Finally, the 30-fold stimulation of IES 156psiG-11 excision efficiency within F(1) progeny relative to F(2) progeny demonstrates that Paramecium IES excision efficiency is sensitive either to a conjugation-specific trans-acting factor provided by the zygotic genome, or to homologous chromosome cross-talk.