Resistance to antimycin A in yeast by amplification of ADH4 on a linear, 42 kb palindromic plasmid

A yeast strain lacking a functional copy of ADH1 has been isolated that is resistant to antimycin A because of the presence of multiple copies of a nuclear gene, ADH4. The amplified copies of ADH4 exist on linear molecules 42 kb in length, which can be separated from chromosomal DNA by orthogonal-field-alternation gel electrophoresis. These amplified molecules are palindromes that reanneal rapidly after denaturation to form linear, snap-back molecules 21 kb in length. The amplified ADH4 sequences are bounded by telomere-homologous sequences. The chromosomal copy of ADH4 is the most distal marker on the left arm of chromosome VII, and the amplified ADH4-containing molecules appear to contain two copies of the region extending from ADH4 to the telomere.     

Spontaneous Amplification of the Adh4 Gene in Saccharomyces Cerevisiae

Five spontaneous amplifications of the ADH4 gene were identified among 1,894 antimycin A-resistant mutants isolated from a diploid strain after growth at 15 degrees. Four of these amplifications are approximately 40-kb linear extrachromosomal palindromes carrying telomere homologous sequences at each end similar to a previously isolated amplification. ADH4 is located at the extreme left end of chromosome VII, and the extrachromosomal fragments appear to be the fusion of two copies of the end of this chromosome. The fifth amplification is a chromosomal amplification carrying an extra copy of ADH4 on both homologs of chromosome VII. These results suggest that the ADH system can be used to study amplification in Saccharomyces cerevisiae.     

A minor class of 5S rRNA genes in Saccharomyces cerevisiae X2180-1B, one member of which lies adjacent to a Ty transposable element

In Saccharomyces cerevisiae the majority of the genes for 5S rRNA lie within a 9kb rDNA sequence that is present as 100-200 tandemly-repeated copies on Chromosome XII. Following our observations that about 10% of yeast 5S rRNA exists as minor variant sequences, we screened a collection of yeast DNA fragments cloned in lambda gt for 5S rRNA genes whose flanking sequences differed from those adjacent to 5S rRNA genes of the rDNA repeat. Three variant 5S rRNA genes were isolated on the basis of such dissimilarity to rDNA repeat sequences. They display a remarkable conservation of their DNA in the vicinity of the 5S coding region, and are examples of a minor form of 5S rRNA coding sequence present in a small number of copies in the yeast genome. These variant sequences appear to be transcribed as efficiently as 5S rRNA genes of the rDNA repeat. In one of our isolates of the variant sequence a Ty transposable element is inserted 145bp upstream of the initiation point for 5S rRNA synthesis.     

Mechanism of high-copy-number integration of pMIRY-type vectors into the ribosomal DNA of Saccharomyces cerevisiae

Targeted integration of the yeast plasmid pMIRY2 into the ribosomal DNA (rDNA) of Saccharomyces cerevisiae by homologous recombination results in transformants carrying 100-200 copies of the plasmid per cell which are stably maintained over a large number of generations [Lopes et al., Gene 79 (1989) 199-206]. These properties make pMIRY2 an attractive vector for high-level production of (heterologous) proteins by yeast cells. We have investigated the mechanism underlying high-copy-number (hcn) integration of pMIRY-type plasmids and show that either targeting to a location outside the rDNA locus or use of the wild-type LEU2, instead of the deficient LEU2d gene, as selection marker reduces the copy number to the low value characteristic of standard integrating (YIp-type) yeast plasmids. Further experiments demonstrate that the hcn of pMIRY-type plasmids is achieved by amplification of a small number of copies initially integrated into the rDNA locus. Amplification depends upon the strong selection pressure created by the extremely low expression of the deficient LEU2d gene, but not on the presence of this gene per se. The hcn integration also occurs when either the TRP1 or URA3 gene is used as the selection marker, provided expression of the marker gene is severely curtailed, e.g., by removal of most of its 5'-flanking region.     

High-copy-number integration into the ribosomal DNA of Saccharomyces cerevisiae: a new vector for high-level expression

Yeast vectors suitable for high-level expression of heterologous proteins should combine a high copy number with a high mitotic stability under non-selective conditions. Since high stability can best be assured by integration of the vector into chromosomal DNA we have set out to design a vector that is able to integrate into the yeast genome in a large number of copies. The rDNA locus appeared to be an attractive target for such multiple integration since it encompasses 100-200 tandemly repeated units. Plasmids containing several kb of rDNA for targeted homologous recombination, as well as the deficient LEU2-d selection marker were constructed and, after transformation into yeast, tested for both copy number and stability. One of these plasmids, designated pMIRY2 (for multiple integration into ribosomal DNA in yeast), was found to be present in 100-200 copies per cell by restriction analysis. The pMIRY2 transformants retained 80-100% of the plasmid copies over a period of 70 generations of growth in batch culture under non-selective conditions. To explore the potential of pMIRY2 as an expression vector we have inserted the homologous genes for phosphoglycerate kinase (PGK) and Mn2+-dependent superoxide dismutase (SOD) as well as the heterologous genes for thaumatin from Thaumatococcus danielli (under the GAPDH promoter), into this plasmid and analyzed the yield of the various proteins. Under optimized conditions the level of PGK in cells transformed with pMIRY2-PGK was about 50% of total soluble protein. The yield of thaumatin in the pMIRY2-thaumatin transformants exceeded by about a factor of 100 the level of thaumatin observed in transformants carrying only a single thaumatin gene integrated at the TRP1 locus in chromosome IV.     

Insertion of a genetic marker into the ribosomal DNA of yeast

Plasmid pBR322 carrying the yeast LEU2+ gene transforms leu⁻ yeast into LEU+ at a low frequency by integration at homologous chromosomal DNA. When one-half of the yeast rDNA repeat unit (BglII-A) is inserted into the plasmid, the frequency of yeast transformation increases 100- to 200-fold, in proportion to the increased amount of homologous repetitive rDNA available for integration. When the other half of the repeat unit (BglII-B) is inserted into the plasmid, the transformation frequency increases by a factor of 10⁴, and the transformants are very unstable. It is likely that this fragment of rDNA contains a yeast origin of replication. This plasmid is a useful vector for cloning fragments of yeast DNA in yeast. We have used the LEU2+ gene, inserted into the rDNA locus, as a genetic marker for mapping the rDNA, in a procedure analogous to the use of antibiotic resistance transposons in the mapping of bacterial genes. Yeast ribosomal DNA is on chromosome XII between asp5 and ura4 as determined by mitotic linkage. Genetic analysis of markers inserted at the rDNA locus should be a useful tool for studying the conservation of sequence homology and the conservation of copy number of repeated genes.     

Intervening sequences in the ribosomal RNA genes of Ascaris lumbricoides: DNA sequences at junctions and genomic organization

An rDNA size class in the genome of the nematode Ascaris lumbricoides is described which is interrupted by a 4.5-kb long intervening sequence located in the 26S coding region. This molecular form occurs in approximately 15 copies per haploid genome and amounts to approximately 5% of the total nuclear rDNA. Intervening sequences are present only in the 8.8-kb rDNA, but not in the 8.4-kb rDNA repeating units of A. lumbricoides. Cloning of the interrupted rDNA units revealed, in addition to the main 4.5-kb insertion, shorter intervening sequences of 4-kb and 119-bp length. Both shorter rDNA forms are present in the single copy range of the haploid genome. Sequence analyses of the intervening sequence/rDNA junctions show an identical right-hand junction for all of the three different rDNA forms. The two shorter intervening sequences are a coterminal subset of the right-hand end of the main 4.5-kb insertion, whereas all three insertions have a different left-hand junction with the coding region of rDNA. Each intervening sequence is flanked by a short direct repeat of variable length, being only once present in the uninterrupted rDNA. The intervening sequences of A. lumbricoides show striking similarity to the organization of type I insertion family in dipteran flies, even though they are inserted at different positions in the 26S coding region. Additional rDNA intervening sequences may be present outside of the rDNA cluster, but in not more than 15-20 homologous copies per haploid genome.     

SV40 PolyA序列及其AATAAA信号对上游GFP基因表达及转录终止的影响

SV40 PolyA(猴空泡病毒PolyA,简称PolyA)序列是有转录终止作用和使转录的mRNA添加PolyA尾的DNA序列(240 bp),含有AATAAA六核苷酸多腺苷化信号(Polyadenylation signal)。在pEGFP-C1质粒的GFP基因下游插入14个同向串联的Alu序列(Alu14),构建pAlu14质粒,瞬时转染HeLa细胞,用Northern blot检测和荧光显微镜观察GFP RNA和GFP蛋白表达,发现Alu串联序列强烈抑制GFP基因表达,该序列没有转录终止作用产生高分子量GFP融合RNA。又在pAlu14质粒GFP基因和Alu串联序列之间按正、反方向插入PolyA序列及去除AATAAA信号的PolyA序列,插入的这些PolyA序列均能部分解除Alu14对GFP基因的抑制作用;去除AATAAA信号的PolyA正、反序列仍然引起转录终止。将PolyA反序(PolyAas)分为4段每段60 bp,中间的2段分别称为2F2R和3F3R,将2F2R或3F3R插在pAlu14质粒的Alu串联序列的上游,随着插入2F2R片段拷贝数的增加转录的GFP融合RNA的分子量增加;2F2R的下游如果依然是2F2R那么2F2R可以支持转录延伸,如果2F2R下游是Alu串联序列则2F2R导致转录终止。无论插入一个3F3R或插入64个3F3R,均产生低分子量GFP RNA。     

金针菇rDNA序列结构特征分析

rDNA序列中的ITS作为DNA barcoding广泛应用于真菌的系统发育与物种辅助鉴定,IGS被认为可以用于种内水平不同菌株的鉴别。食用菌中还没有完整的rDNA序列的报道。本研究采用二代和三代测序技术分别对金针菇单核菌株“6-3”进行测序,用二代测序的数据对三代测序组装得到的基因组序列进行修正,得到一个在基因完整性、连续性和准确性均较好的基因组序列,对比Fibroporia vaillantii rDNA序列,获得金针菇完整的rDNA序列。金针菇rDNA序列结构分析表明,它有8个rDNA转录单元,长度均为5 903bp,有9个基因间隔区,其长度有较大差异,3 909-4 566bp。rDNA转录单元中,各元件的序列长度分别为：18S rDNA 1 796bp、ITS1 234bp、5.8S rDNA 173bp、ITS2 291bp、28S rDNA 3 410bp。基因间间隔区中,IGS1 1 351-1 399bp、5S rDNA 124bp、IGS2 2 435-3 092bp。金针菇的5S、5.8S、18S、28S rDNA序列准确性得到转录组数据的验证,也得到系统发育分析结果的支持。多序列比对发现,不同拷贝的基因间间隔区序列（IGS1和IGS2）存在丰富的多态性,多态性来源于SNP、InDel和TRS（串联重复序列）,而TRS来源于重复单元的类型和数量。9个基因间间隔区之间,IGS1只有少量的SNP和InDel,IGS2不仅有SNP和InDel,还有TRS。本研究结果提示,在应用IGS进行种内水平不同菌株之间的鉴别时,需要选取不同拷贝之间的保守IGS序列。     

Retinoic acid response element in the human alcohol dehydrogenase gene ADH3: implications for regulation of retinoic acid synthesis.

Retinoic acid regulation of one member of the human class I alcohol dehydrogenase (ADH) gene family was demonstrated, suggesting that the retinol dehydrogenase function of ADH may play a regulatory role in the biosynthetic pathway for retinoic acid. Promoter activity of human ADH3, but not ADH1 or ADH2, was shown to be activated by retinoic acid in transient transfection assays of Hep3B human hepatoma cells. Deletion mapping experiments identified a region in the ADH3 promoter located between -328 and -272 bp which confers retinoic acid activation. This region was also demonstrated to confer retinoic acid responsiveness on the ADH1 and ADH2 genes in heterologous promoter fusions. Within a 34-bp stretch, the ADH3 retinoic acid response element (RARE) contains two TGACC motifs and one TGAAC motif, both of which exist in RAREs controlling other genes. A block mutation of the TGACC sequence located at -289 to -285 bp eliminated the retinoic acid response. As assayed by gel shift DNA binding studies, the RARE region (-328 to -272 bp) of ADH3 bound the human retinoic acid receptor beta (RAR beta) and was competed for by DNA containing a RARE present in the gene encoding RAR beta. Since ADH catalyzes the conversion of retinol to retinal, which can be further converted to retinoic acid by aldehyde dehydrogenase, these results suggest that retinoic acid activation of ADH3 constitutes a positive feedback loop regulating retinoic acid synthesis.     

A three-step model for the rearrangement of the chloroplast trnK-psbA region of the gymnosperm Pinus contorta.

A region of the Pinus contorta chloroplast genome which contains a duplication of the psbA gene was characterized. From previous experiments it was known that the two copies of the psbA gene were located approximately 3.3 kilobase pairs (kbp) apart, that they had the same orientation and that one endpoint of the duplication was 19 base pairs (bp) downstream of the psbA stop codon. In order to determine the size and additional genetic content of the duplicated segment, both copies as well as the intervening DNA were sequenced completely. It was found that the duplicated segment was 1969 bp long, that the two copies were completely identical and were separated by 2431 bp. The duplicated segment carried, in addition to psbA, the 3' exon of the trnK gene, which was partially included in a 124 bp direct repeat. The translocated copy of the duplicated segment was found to be inserted upstream of the trnK(UUU) gene and was immediately followed by a repeated 41 bp stretch from the psbA coding region. The trnK gene was split by a 2509 bp intron which contained an open reading frame of 515 codons. Sequence comparisons of the duplicated segment and its flanking DNA to the corresponding regions of P. sylvestris, a species which lacks the rearrangements found in P. contorta, made it possible to identify 3-9 bp homologies within which recombinations had occurred. A model was derived which would accommodate the conversion of a trnK-psbA locus of the ancestral P. sylvestris-like organization into the rearranged structure found in P. contorta.     

The four ribosomal DNA units of the malaria parasite Plasmodium berghei. Identification, restriction map, and copy number analysis

The four ribosomal RNA genes (rDNA units) of the rodent malaria parasite, Plasmodium berghei, were identified and mapped by restriction enzyme analysis and Southern blot hybridization of genomic DNA. Although the four genes share common characteristics, they appear to be internally different from each other in expanse and sequence. One HindIII site near the 3' end of the coding region for the large rRNA is the only restriction site which we have detected that is conserved in all of the genes. The distance between the conserved HindIII site and the coding region for the small rRNA is at least 1-2 kilobases longer in two of the rDNA units than in a third unit. None of the four rDNA units were linked by restriction mapping where about 150 kilobases of the genome were accounted for. The copy number of two of the rDNA units was determined to be approximately 1 per haploid genome by quantitative analysis of cloned (plasmid) DNA versus genomic DNA digests on Southern blots. The other two genes also appear to be present in 1 copy. Restriction analysis confirms both the low copy number and that these genes are not in an easily recognizable tandem array. The low number of rDNA units requires that new copies of the genome produced during intraerythrocytic growth be active in RNA synthesis soon after their replication.     

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.     

Anatomy and dynamics of DNA replication fork movement in yeast telomeric regions

Replication initiation and replication fork movement in the subtelomeric and telomeric DNA of native Y' telomeres of yeast were analyzed using two-dimensional gel electrophoresis techniques. Replication origins (ARSs) at internal Y' elements were found to fire in early-mid-S phase, while ARSs at the terminal Y' elements were confirmed to fire late. An unfired Y' ARS, an inserted foreign (bacterial) sequence, and, as previously reported, telomeric DNA each were shown to impose a replication fork pause, and pausing is relieved by the Rrm3p helicase. The pause at telomeric sequence TG(1-3) repeats was stronger at the terminal tract than at the internal TG(1-3) sequences located between tandem Y' elements. We show that the telomeric replication fork pause associated with the terminal TG(1-3) tracts begins approximately 100 bp upstream of the telomeric repeat tract sequence. Telomeric pause strength was dependent upon telomere length per se and did not require the presence of a variety of factors implicated in telomere metabolism and/or known to cause telomere shortening. The telomeric replication fork pause was specific to yeast telomeric sequence and was independent of the Sir and Rif proteins, major known components of yeast telomeric heterochromatin.