Establishment of the nuclear location of Dictyostelium discoideum plasmids

The nuclear location of the Dictyostelium discoideum plasmids was studied using a biochemical approach based on the presence of plasmid sequences in nucleosomes. This analysis revealed that all four of the known plasmids (Ddp1, Ddp2, Ddp3, Ddp5) are present in chromatin. This evidence establishes that the D. discoideum plasmids are not cytoplasmic but located in the nucleus. D. discoideum is unique among eukaryotes in possessing a group of nonhomologous endogenous plasmids in its nucleus. These plasmids are excellent starting material for construction of nuclear transformation and expression vectors. Such vectors upon transformation into D. discoideum are also present in chromatin as expected for DNA located in the nucleus.     

Presence of nuclear associated plasmids in the lower eukaryote Dictyostelium discoideum

High copy number plasmids have been identified in six out of 25 wild-type strains of the cellular slime mould Dictyostelium discoideum, a model organism in developmental biology (Loomis, 1982). The characterization of three plasmids, from the NC4 (Ddp1), WS380B (Ddp2) and OHIO (Ddp3) wild isolates, is presented here. We show that they are nuclear associated and non-homologous to the mitochondrial DNA and extrachromosomal ribosomal DNA.     

Green fluorescent protein and epitope tag fusion vectors for Dictyostelium discoideum

We have constructed expression vectors for Dictyostelium discoideum which encode a green fluorescent protein (GFP) sequence upstream of a multicloning site for introduction of sequences of interest. Insertion of cDNAs into the multicloning site results in expression of fusion protein bearing an amino- or carboxyl-terminal GFP tag which can be used for fluorescent localization studies in Dictyostelium cells. A parallel construct fuses a FLAG epitope tag at the amino terminus of expressed protein. Each fusion cartridge was placed either in a G418-resistance vector allowing transactivated Ddp2-based extrachromosomal replication or in a vector allowing autonomous Ddp1-based replication. Distinct differences in expression stability were observed in the two vector types. When GFP-expressing cells were analyzed by fluorescence microscopy, significant cell-to-cell variability in expression level was observed when expression was based on the Ddp2 vector, while less cell-to-cell variation in expression level was observed when the Ddp1 backbone was used for expression.     

Copy number control and compatibility of nuclear plasmids in Dictyostelium discoideum

Copy number of the endogenous nuclear plasmids of Dictyostelium discoideum is a plasmid-specific trait. Copy number is stable over time, is constant relative to ploidy level, is independent of host cell genetic background, and is independent of the presence of a second unrelated plasmid in the same nucleus. Unrelated plasmids are compatible with one another within a single nucleus. Pairwise combinations of Ddp1, Ddp2, and Ddp5 were stably maintained over many generations in the absence of selection. In contrast, one of the D. discoideum plasmids (Ddp2) was incompatible with a recombinant plasmid derived from it (p7d2). In the absence of selection for retention of p7d2, transformants contain either one or the other but not both plasmids. The plasmids are stably maintained in host cells with differing genetic backgrounds, although plasmid-free colonies were detected at a frequency of about 1-2% in populations of some strains after 50 generations growth following a previous cloning.     

Extrachromosomal replication of shuttle vectors in Dictyostelium discoideum.

We cloned a 12.3-kilobase (kb) endogenous plasmid, Ddp1, found in several wild-type and laboratory strains of Dictyostelium discoideum into pBR322. The cloned plasmids have been used to cotransform D. discoideum cells with B10S, a transformation vector carrying a gene fusion conferring resistance to G418. Whereas B10S DNA alone appears to integrate in a tandem array, the cloned Ddp1 plasmids replicate extrachromosomally and are stably maintained in the absence of selection with an average copy number of 50 to 100 copies per cell. The Ddp1-derived plasmids can be directly recovered by transforming Escherichia coli with bulk nuclear DNA from these cells. Preliminary deletion analysis indicates that not all regions of Ddp1 are necessary for stable replication in D. discoideum. Several recombinant vectors which replicate extrachromosomally in D. discoideum were also isolated. One contains the Act6-neor gene fusion from B10S recombined into one of the cloned derivatives of Ddp1 and can be used to directly transform D. discoideum amoebae, selecting for G418 resistance. Another recombinant is only 5.6 kb and resulted from a deletion of a 16.6-kb cloned Ddp1 hybrid plasmid. An analysis of the vector DNAs present in clones derived from single D. discoideum transformants is also described.     

The sequence and organization of Ddp2, a high-copy-number nuclear plasmid of Dictyostelium discoideum

The complete nucleotide sequence of the plasmid Ddp2 found in the nucleus of the simple eukaryote Dictyostelium discoideum is reported. This 5852-bp plasmid contains a 2661-bp open reading frame (ORF), named the "Rep gene," and 501-bp imperfect inverted repeats. A 1762-bp section of Ddp2, which includes one of the 501-bp repeat sequences, could be deleted without abolishing extrachromosomal replication. Deletion of the second 501-bp repeat, or interruption of the Rep gene, removed the ability to replicate extrachromosomally. We suggest that Ddp2 encodes a protein, "REP," that positively regulates replication initiation, a regulatory mechanism different from that of the yeast 2 mu plasmid which also possesses inverted repeat sequences. Ddp2 has a structure similar to that of plasmid pDG1, found in an unidentified isolate of Dictyostelium, with a similar sized ORF and inverted repeats. A common evolutionary origin is suggested by considerable sequence homology between the ORFs of pDG1 and Ddp2.     

Construction of an extrachromosomally replicating transformation vector for Dictyostelium discoideum

An extrachromosomally replicating transformation vector for Dictyostelium discoideum has been constructed using sequences of the endogenous Dictyostelium plasmid Ddp2. This transformation vector pnDeI (9.6 kb) replicates as a high copy number plasmid in Dictyostelium and is located in the nucleus. It has been constructed as shuttle vector containing the Escherichia coli vector pUC19 for replication and selection in E. coli and a part of the Tn903 transposon which confers resistance to G418 for selection in Dictyostelium. In order to show that the vector can be used for cloning and stable propagation of Dictyostelium DNA, a fragment of the Dictyostelium alpha-actinin gene that was marked with a synthetic oligonucleotide was cloned into pnDeI and found to be stably maintained in the extrachromosomal vector without undergoing noticeable recombination with the endogenous gene.     

Nuclear plasmids in the Dictyostelium slime molds

Cellular slime molds are one of only three types of eukaryotes known to contain circular nuclear plasmids. Unlike the 2-microns circle in Saccharomyces, different strains of Dictyostelium can carry different, nonhomologous plasmids. Covalently closed, circular DNA plasmids have been identified in D. discoideum, D. mucoroides, D. giganteum, and D. purpureum. These plasmids range in size from 1.3-27 kb and in copy number from 50-300 molecules per cell. Plasmids have been identified in approximately one-fifth of all isolates examined. The organization of their DNA in nucleosomes establishes their presence in the nucleus. We have successfully cotransformed endogenous Dictyostelium plasmids into D. discoideum using the G418 resistance shuttle vector B10S. Transformants carrying D. discoideum plasmids are recovered at much higher frequency than those carrying plasmids from the other Dictyostelium species. We have constructed recombinant plasmids based on the D. discoideum plasmid Ddp2 and the G418 resistance gene. With these extrachromosomal vectors, transformed cells are recovered at frequencies of up to 10(-4) per input cell, the vectors are stably maintained at high copy number in the absence of selection, and the vectors can be used to introduce foreign DNA sequences into D. discoideum cells.     

Selection of Dictyostelium discoideum transformants and analysis of vector maintenance using live bacteria resistant to G418.

A protocol that allows the rapid isolation and growth of large numbers of independent G418-resistant Dictyostelium discoideum transformant colonies on the surface of agar media with live bacteria was developed. Transformants grown under these conditions form normal fruiting bodies. Discovery that aggregation of nontransformants was inhibited at a nonselective level of G418 (25 to 35 micrograms/ml) led to the development of a vector maintenance assay. Using this assay we examined the stability of recombinant plasmids derived from the D. discoideum native plasmids Ddp1 and Ddp2. We conclude that the origin of replication of plasmid Ddp1 does not alone confer stable maintenance and thus, Ddp1 must bear additional sequences required for its own maintenance. Analysis of the maintenance of vectors derived from Ddp2 showed that autonomously replicating shuttle vectors that contained bacterial plasmid DNA and from which one element of the Ddp2 inverted repeat was removed were much less stable than vectors that contained a complete inverted repeat or that did not carry a bacterial plasmid. Sequences between the 3' end of the rep gene and the inverted repeat appear to play a role in plasmid maintenance. An intact rep gene and one copy of the inverted repeat element were required for extrachromosomal replication. Maintenance of extrachromosomal vectors was found to be strain dependent. Four traits distinguishing integrating vectors from those capable of autonomous replication were identified.     

Plasmid maintenance functions encoded on Dictyostelium discoideum nuclear plasmid Ddp1.

All of the plasmid-carried genes expressed during vegetative growth are essential for long-term maintenance of plasmid Ddp1 in the nucleus of Dictyostelium discoideum. Deletion of Ddp1 genes expressed only during development had no detectable effect on plasmid maintenance. Deletion of vegetatively expressed genes, either singly or in pairs, resulted in (i) a rapid loss of plasmid from cells grown in the absence of selection for plasmid retention, (ii) variation in the proportion of monomer to multimer forms of the plasmid molecules, and/or (iii) abnormalities in plasmid copy number. At least two plasmid-encoded gene products influence patterns of expression of plasmid genes.     

Identification of the origin of replication of the eukaryote Dictyostelium discoideum nuclear plasmid Ddp2

Ddp2 is a 5.8-kb, high-copy-number, nuclear plasmid found in the eukaryote Dictyostelium discoideum. We have identified two functional domains, a large open reading frame (Rep gene) and a 626-bp fragment containing an origin of replication (ori). The ori, when cloned into a shuttle vector, confers stable extrachromosomal replication in D. discoideum, provided that the Rep gene, which acts in trans, is integrated into the host genome. Ddp2 carries a 501-bp imperfect inverted repeat, and part of the ori overlaps with one of these repeats. The ori sequence contains two direct repeats of 49 bp comprising two 10-bp "TGTCATGACA" palindromes separated by a poly(T.A) sequence. Deletion of either 49-bp repeat abolished extrachromosomal replication.     

新型重组糖蛋白表达载体--盘基网柄菌

近年来,盘基网柄菌作为异源重组糖蛋白表达载体的研究受到了学术界的重视,已经有多种具有生物活性的复杂糖蛋白成功地得到了表达。通过对表达产物的研究发现,盘基网柄菌具有各种翻译后加工机制,例如磷酸化、酰基化及形成GPI(糖基磷脂酰基醇)锚点等,具有类似于高等动物的糖基化修饰能力。与哺乳动物细胞表达载体相比较,盘基网柄菌具有培养成本低廉、细胞生长迅速及易于大规模培养的优势。盘基网柄菌有可能发展成为一种有重要应用前景的糖蛋白表达载体系统。     

Identification of sialic acids in cell adhesion molecule, contact site A from Dictyostelium discoideum.

It has been believed that Dictyostelium discoideum cell membranes contain no sialic acid. In this study, however, we found that contact site A, the cell adhesion molecule of D. discoideum, is a major glycoprotein containing sialic acids. This suggests that sialic acid in non-reducing terminal plays an important role in the cell adhesion in which contact site A is involved.     

Insertion of transformation vector DNA into different chromosomal sites of Dictyostelium discoideum as determined by pulse field electrophoresis

Chromosomes of the cellular slime mold Dictyostelium discoideum were fractionated on three pulse field gel electrophoresis systems (pulse field, orthogonal field and C.H.E.F. (Contour-clamped Homogeneous Electric Fields] into a series of 13 bands ranging from 0.1 Mb to over 2 Mb in size. Since this organism has only seven chromosomes (estimated to be 1-10 Mb), and -90 copies of an 88-kilobase linear ribosomal DNA molecule (14% of genome), it was apparent that not all of these bands were whole chromosomes. However these bands were reproducibly obtained with the cell preparation used. They fell into three categories: i) four large poorly resolved DNA molecules (-2 Mb in size) which represent very large fragments or intact chromosomes, ii) eight faint bands ranging from 0.1 Mb to 2 Mb, iii) a prominent band in the apparent size range of about 0.15 Mb. Cloned Fragment V of an EcoR1 digest of the ribosomal DNA, hybridized to the 0.15 Mb band indicating it contained the linear ribosomal DNA. This chromosomal banding pattern was used to examine the stability and location of vector DNA in 16 transformed strains of D. discoideum. Each transformed strain was initially selected on the basis of G418 resistance with an integrating vector containing pBR322 sequences. Eleven transformants still carried pBR322 sequences after more than 60 generations of growth without selection on G418. All four strains transformed with constructs containing regions of the D. discoideum plasmid Ddp1 had lost their pBR322 insert, indicating that integration of Dictyostelium plasmid DNA into chromosomes leads to instability. Orthogonal field electrophoresis of the eleven strains still carrying pBR322 sequences revealed at least seven different integrating sites for the transforming DNA. We conclude that these vectors have many possible sites of integration in the D. discoideum genome.