Rapid Evolution of Recombinant Saccharomyces cerevisiae for Xylose Fermentation through Formation of Extra-chromosomal Circular DNA

Circular DNA elements are involved in genome plasticity, particularly of tandem repeats. However, amplifications of DNA segments in Saccharomyces cerevisiae reported so far involve pre-existing repetitive sequences such as ribosomal DNA, Ty elements and Long Terminal Repeats (LTRs). Here, we report the generation of an eccDNA, (extrachromosomal circular DNA element) in a region without any repetitive sequences during an adaptive evolution experiment. We performed whole genome sequence comparison between an efficient D-xylose fermenting yeast strain developed by metabolic and evolutionary engineering, and its parent industrial strain. We found that the heterologous gene XylA that had been inserted close to an ARS sequence in the parent strain has been amplified about 9 fold in both alleles of the chromosomal locus of the evolved strain compared to its parent. Analysis of the amplification process during the adaptive evolution revealed formation of a XylA-carrying eccDNA, pXI2-6, followed by chromosomal integration in tandem arrays over the course of the evolutionary adaptation. Formation of the eccDNA occurred in the absence of any repetitive DNA elements, probably using a micro-homology sequence of 8 nucleotides flanking the amplified sequence. We isolated the pXI2-6 eccDNA from an intermediate strain of the evolutionary adaptation process, sequenced it completely and showed that it confers high xylose fermentation capacity when it is transferred to a new strain. In this way, we have provided clear evidence that gene amplification can occur through generation of eccDNA without the presence of flanking repetitive sequences and can serve as a rapid means of adaptation to selection pressure.     

A new repetitive element of the CR1 family downstream of the chicken vitellogenin gene.

We have analyzed a repetitive DNA sequence found in the 3'-flanking region of the chicken vitellogenin gene. By its sequence, the repetitive DNA has been identified as a hitherto unreported member of the chicken CR1 family of repetitive elements. The CR1 sequence displays the structural characteristics of a long terminal repeat located at the 3' end of an avian retrovirus. The CR1 element lies 2.2 kb downstream of the vitellogenin gene and 'points' away from the gene rather than toward it. In this respect, this element differs from other CR1 repeats. The CR1 element is embedded in a region showing changes in chromatin structure implying a potential role for this sequence in determining the structural state of the local chromatin.     

beta, a novel repetitive DNA element associated with tRNA genes in the pathogenic yeast Candida albicans

We have identified a novel 399 bp repetitive DNA element (which we designate beta  ) 9 bp upstream of a seryl-tRNA_CAG gene in the genome of Candida albicans . There are two copies of the seryl-tRNA_CAG gene, one on each homologue of chromosome VI, and the beta element is found upstream of one copy of the gene in C. albicans strain 2005E. The beta element is not present upstream of either copy of the seryl-tRNA_CAG gene in eight other laboratory strains of C. albicans tested, but was detected in this location in several fresh clinical isolates. Southern blot analysis indicated that there are approximately eight copies of the beta element per diploid C. albicans genome and that it is a mobile element, being present on at least two different chromosomes. Three unique genomic DNA clones containing the beta element were isolated from strain 2005E; in each case, a different tRNA gene was found immediately adjacent to the beta element. Three new tRNA genes from C. albicans have thus been identified: tRNA^Asp, tRNA^Ala and tRNA^Ile. The beta element shows no significant sequence homology to other known prokaryotic or eukaryotic repetitive elements, although an 8 bp repeat at the 3' end of the element is identical to that of the Ty3 retrotransposable element of Saccharomyces cerevisiae . We propose that the beta element is a solo long terminal repeat (LTR) sequence of a Ty3/gypsy-like transposable element in C. albicans that is closely associated with tRNA genes.     

Structure and evolution of a family of interspersed repetitive DNA sequences inCaenorhabditis elegans

Summary The structure of three members of a repetitive DNA family from the genome of the nematodeCaenorhabditis elegans has been studied. The three repetitive elements have a similar unitary structure consisting of two 451-bp sequences in inverted orientation separated by 491 bp, 1.5 kb, and 2.5 kb, respectively. The 491-bp sequence separating the inverted 451-bp sequences of the shortest element is found adjacent to one of the repeats in the other two elements as well. The combination of the three sequences we define as the basic repetitive unit. Comparison of the nucleotide sequences of the three elements has allowed the identification of the one most closely resembling the primordial repetitive element. Additionally, a process of co-evolution is evident that results in the introduction of identical sequence changes into both copies of the inverted sequence within a single unit. Possible mechanisms are discussed for the homogenization of these sequences. A direct test of one possible homogenization mechanism, namely homologous recombination between the inverted sequences accompanied by gene conversion, shows that recombination between the inverted repeats does not occur at high frequency.     

Molecular and bioinformatic analysis of the FB-NOF transposable element

The Drosophila melanogaster transposable element FB-NOF is known to play a role in genome plasticity through the generation of all sort of genomic rearrangements. Moreover, several insertional mutants due to FB mobilizations have been reported. Its structure and sequence, however, have been poorly studied mainly as a consequence of the long, complex and repetitive sequence of FB inverted repeats. This repetitive region is composed of several 154 bp blocks, each with five almost identical repeats. In this paper, we report the sequencing process of 2 kb long FB inverted repeats of a complete FB-NOF element, with high precision and reliability. This achievement has been possible using a new map of the FB repetitive region, which identifies unambiguously each repeat with new features that can be used as landmarks. With this new vision of the element, a list of FB-NOF in the D. melanogaster genomic clones has been done, improving previous works that used only bioinformatic algorithms. The availability of many FB and FB-NOF sequences allowed an analysis of the FB insertion sequences that showed no sequence specificity, but a preference for A/T rich sequences. The position of NOF into FB is also studied, revealing that it is always located after a second repeat in a random block. With the results of this analysis, we propose a model of transposition in which NOF jumps from FB to FB, using an unidentified transposase enzyme that should specifically recognize the second repeat end of the FB blocks.     

Repetitive sequence of Leptospira interrogans serovar icterohaemorrhagiae strain Ictero No. 1: a sensitive probe for demonstration of Leptospira interrogans strains.

A 4.8-kilobase (kb) repetitive sequence element generated with KpnI digestion was cloned from the Leptospira interrogans serovar icterohaemorrhagiae strain Ictero No. 1. The sequence, repeated in tandem, was located on the 280-kb fragment between the FseI and AscI sites on the chromosome by hybridization using the 4.8-kb fragment as a probe. We cloned the fragment containing the element for the Ictero No. 1 strain in a lambda EMBL3 bacteriophage DNA, and one out of 5 clones was sequenced. Within the sequenced 9-kb segment that partially repeated, 9 putative open-reading frames and 2 transfer RNA genes, for alanine and isoleucine, were identified. A similarity search for the products deduced from the sequenced data revealed that the repeated sequence includes both beta-oxidation enzymes, acyl-CoA dehydrogenase and enoyl-CoA hydratase, and hydroxythiazole kinase protein homologues. Hybridization experiments against different leptospiral strains using the element as a probe showed a similar sequence in the strains of L. interrogans and L. kirschneri, but not in any strains of L. borgpetersenii, L. weillii, L. meyeri or L. biflexa. Results indicated that the highly repeated element in the Ictero No. 1 strain exists as a well conserved sequence, though at a moderate level of repetition, in certain strains of L. interrogans and L. kirschneri. PCR amplification targeting the repetitive element was successful and indicated that the procedure provides a sensitive and specific probe to detect leptospires.     

Nucleotide sequence and characterization of a repetitive DNA element from the genome of Bordetella pertussis with characteristics of an insertion sequence

A repeating element of DNA has been isolated and sequenced from the genome of Bordetella pertussis. Restriction map analysis of this element shows single internal ClaI, SphI, BstEII and SalI sites. Over 40 DNA fragments are seen in ClaI digests of B. pertussis genomic DNA to which the repetitive DNA sequence hybridizes. Sequence analysis of the repeat reveals that it has properties consistent with bacterial insertion sequence (IS) elements. These properties include its length of 1053 bp, multiple copy number and presence of 28 bp of near-perfect inverted repeats at its termini. Unlike most IS elements, the presence of this element in the B. pertussis genome is not associated with a short duplication in the target DNA sequence. This repeating element is not found in the genomes of B. parapertussis or B. bronchiseptica. Analysis of a DNA fragment adjacent to one copy of the repetitive DNA sequence has identified a different repeating element which is found in nine copies in B. parapertussis and four copies in B. pertussis, suggesting that there may be other repeating DNA elements in the different Bordetella species. Computer analysis of the B. pertussis repetitive DNA element has revealed no significant nucleotide homology between it and any other bacterial transposable elements, suggesting that this repetitive sequence is specific for B. pertussis.     

A human dihydrofolate reductase intronless pseudogene with an Alu repetitive sequence: multiple DNA insertions at a single chromosomal site

A dihydrofolate reductase (DHFR) pseudogene, hDHFR-psi 3 has been isolated from a human genomic DNA fragment library. Sequence analysis of this gene revealed a lack of introns and the presence of a tract of nine adenines, 90 bp downstream from the end of the coding sequence. These features suggest that hDHFR-psi 3 was derived from a processed RNA molecule that has been converted into DNA and inserted into a chromosome, analogous to the origin of three intronless human DHFR genes previously described. An interesting feature of hDHFR-psi 3 is the presence of a member of the Alu moderately repetitive DNA sequence family within the DHFR coding region. This Alu element is flanked by a 16 bp directly repeated DNA segment derived from DHFR coding sequences. The Alu element apparently has been inserted into the intronless DHFR pseudogene and thus, there have been two insertions at a single chromosomal locus. The hDHFR-psi 3 contains only the 3' half of the DHFR coding sequence. Immediately upstream from the directly repeated sequence before the Alu element is an adenine-rich tract. The DNA farther upstream is moderately repetitive and is related to neither DHFR nor Alu DNA sequence. Therefore, it seems possible that a third insertion has occurred at the same site further disrupting the hDHFR coding sequences.     

Cloning and characterization of a rat-specific repetitive DNA sequence

A 2.1-kb EcoRI fragment of rat DNA has been cloned and sequenced. This fragment contained a repetitive element which was highly specific for rat DNA and widely dispersed throughout the rat genome. The repetitive element is homologous to a sequence found in the 3' end of the rat LINE family. Because of its high degree of species specificity and its heterodisperse distribution, this sequence provided a useful marker for rat DNA in DNA transfection experiments into mouse host cells.     

Molecular cloning of cDNAs encoding a putative cell wall protein from Zea mays and immunological identification of related polypeptides

Copy DNAs corresponding to a highly repetitive, proline-rich protein from maize have been cloned by differential screening of a coleoptile cDNA library. The deduced amino acid sequence contains a single repetitive element of carrot extensin (Ser-Pro-Pro-Pro-Pro). The related mRNAs have a defined distribution in tissues of the plant and are accumulated mainly in the coleoptile node and root tip. A peptide that corresponds to one of the repetitive elements of the protein has been synthesized and antisera have been obtained in rabbits. These antibodies react against crude preparations of coleoptile cell wall and against polypeptides extracted following the protocols described for the extraction of extensin. From these data it is concluded that the cDNAs correspond to a family of cell wall glycoproteins from maize.     

Organization of the micronuclear genome of oxytricha nova

In the hypotrichous ciliated protozoan Oxytricha nova, approximately 95% of the micronuclear genome, including all of the repetitive DNA and most of the unique sequence DNA, is eliminated during the formation of the macronuclear genome. We have examined the interspersion patterns of repetitive and unique and eliminated and retained sequences in the micronuclear genome by characterizing randomly selected clones of micronuclear DNA. Three major classes of clones have been defined: (1) those containing primarily unique, retained sequences; (2) those containing only unique, eliminated sequences; and (3) those containing only repetitive, eliminated sequences. Clones of type one and three document two aspects of organization observed previously: clustering of macronuclear destined sequences and the presence of a prevalent repetitive element. Clones of the second type demonstrate for the first time that eliminated unique sequence DNA occurs in long stretches uninterrupted by repetitive sequences. To further examine repetitive sequence interspersion, we characterized the repetitive sequence family that is present in 50% of the clones (class three above). A consensus map of this element was obtained by mapping approximately 80 phage clones and by hybridization to digests of micronuclear DNA. The repeat element is extremely large (approximately 24 kb) and is interspersed with both macronuclear destined sequences and eliminated unique sequences.     

逆转座子样元件Tca1用于白色念珠菌的分类鉴定

已分离到一中等重复序列以及具有逆转座子样结构的元件Tcal(Transposon Candida albicans)。Tcal两端存在两个完全相同同向排列的序列LTR(Long Terminal Repeat)388bp,中间被一5.5kbDNA片段隔开。以alpha及Tcal为探针对40多种来自美国和中国的临床分离到的致病菌株进行杂交分析,根据杂交图谱,这些白色念株菌可被分成若干组,令人感兴趣的是来自同一地区菌种的遗传相关性比来自不同地区的大。比较URA3等基因的杂交结果,支持这种分析。尚未观察到alpha重复序列与其他酵母菌染色体DNA杂交的杂交条带,认为Tcal元件也许与C. albicans的遗传进化及其致病性有某种内在联系。     

A family of small repeated elements with some transposon-like properties in the genome of Neisseria gonorrhoeae

A physical technique known as two-dimensional S1 nuclease heteroduplex mapping has been applied to genomic DNA from the Gram-negative coccus Neisseria gonorrhoeae. This has resulted in the detection of two novel types of repetitive sequences. The first type is a repetitive sequence family of 152 base pairs (bp), whose ends are composed of inverted repeats of 26 bp. There are approximately 20 copies of this sequence, in both N. gonorrhoeae and Neisseria meningitidis (Correia, F., Inouye, S., and Inouye, M. (1986) J. Bacteriol. 167, 1009-1011). The second type of sequence is a 1443-bp duplication in the N. gonorrhoeae genome. The two classes of sequence are linked positionally. Each copy of the long duplicated sequence is adjacent to a member of the 152-bp repetitive sequence. In one instance two copies of the 152-bp repetitive sequence are separated by a 436-bp central region and are in an inverted orientation with respect to one another, resembling a compound transposable element.     

The organization of the ribosomal RNA genes in the fungus Mucor racemosus.

The rDNA of Mucor racemosus is contained on a 6.4 megadalton repeat unit. Two Bam H-1 restriction fragments that encompass the entire rDNA repeat, as well as two Hind III restriction fragments that lie within the region, have been cloned and analyzed. The rDNA unit has been defined with respect to eight restriction endonucleases and the position of the sequences encoding the 25S, 18S, and 5.8S rRNA species have been localized. In addition, the 55 RNA encoding sequence was found to reside within the basic repeat unit. The results indicate the organization of the rDNA of Mucor more closely resembles the arrangement observed in yeast than that observed in other eukaryotic organisms.     

Species-specific repetitive extragenic palindromic (REP) sequences in Pseudomonas putida

Pseudomonas putida KT2440 is a soil bacterium that effectively colonises the roots of many plants and degrades a variety of toxic aromatic compounds. Its genome has recently been sequenced. We describe that a 35 bp sequence with the structure of an imperfect palindrome, originally found repeated three times downstream of the rpoH gene terminator, is detected more than 800 times in the chromosome of this strain. The structure of this DNA segment is analogous to that of the so-called enterobacteriaceae repetitive extragenic palindromic (REP) sequences, although its sequence is different. Computer-assisted analysis of the presence and distribution of this repeated sequence in the P.putida chromosome revealed that in at least 80% of the cases the sequence is extragenic, and in 82% of the cases the distance of this extragenic element to the end of one of the neighbouring genes was <100 bp. This 35 bp element can be found either as a single element, as pairs of elements, or sometimes forming clusters of up to five elements in which they alternate orientation. PCR scanning of chromosomes from different isolates of Pseudomonas sp. strains using oligonucleotides complementary to the most conserved region of this sequence shows that it is only present in isolates of the species P.putida. For this reason we suggest that the P.putida 35 bp element is a distinctive REP sequence in P.putida. This is the first time that REP sequences have been described and characterised in a group of non-enterobacteriaceae.     

The human THE-LTR(O) and MstII interspersed repeats are subfamilies of a single widely distributed highly variable repeat family.

Fifteen examples of the transposon-like human element (THE) LTR and thirteen examples of the MstII interspersed repeat are aligned to generate new consensus sequences for these human repetitive elements. The consensus sequences of these elements are very similar, indicating that they compose subfamilies of a single human interspersed repetitive sequence family. Members of this highly polymorphic repeat family have been mapped to at least 11 chromosomes. Seven examples of the THE internal sequence are also aligned to generate a new consensus sequence for this element. Estimates of the abundance of this repetitive sequence family, derived from both hybridization analysis and frequency of occurrence in GenBank, indicate that THE-LTR/MstII sequences are present every 100-3000 kb in human DNA. The widespread occurrence of members of this family makes them useful landmarks, like Alu, L1, and (GT)n repeats, for physical and genetic mapping of human DNA.     

Preservation of a complex satellite DNA in two species of echinoderms.

The cloning and sequencing of a tandemly arrayed repetitive DNA sequence from the sea cucumber Holothuria tubulosa has been recently described (Sainz, J., Azorín, F. and Cornudella, L. 1989. Gene 80, 57-64). We have now searched the genomes of several echinoderm species for the presence of homologous repetitive elements. A close but not identical repeated sequence has been identified in a related holothuroid, H. polii. The monomeric repeat unit is 391 bp long and has a base composition of 66.8% A and T residues, lined up in tracts of 4 nt or larger. The monomeric sequence lacks any internal subrepeat organization although it displays a substantial degree of internal redundancy in the form of inverted and direct repeats. The repeated element accounts for 0.34% of the genome which corresponds to a repetition frequency of about 0.5 x 10(5) copies per haploid complement. The intra- and interspecific homologies among monomers of the satellite DNA as derived from sequence analyses are very high, averaging 97%. The results suggest that the homogeneity of the highly reiterated DNA sequence may be attributed to evolutionary conservative trends.     

Interactions between transposable elements and Argonautes have (probably) been shaping the Drosophila genome throughout evolution

Transposable elements (TEs) are powerful mutagenic agents responsible for generating variation in the host genome. As TEs can be overtly deleterious, a variety of different mechanisms have evolved to keep their activities in check. In plants, fungi, and animals, RNA silencing has been implicated as a major defense against repetitive element transposition. This nucleic acid-based defense mechanism also appears to be directed at inherited silencing of TEs without altering the underlying DNA sequence. Complex interactions between TEs and RNA silencing machineries have been co-opted to regulate cellular genes.