A novel shuttle cloning vector for the cyanobacterium Anacystis nidulans

Abstract Shuttle cloning vectors for use with the cyanobacterium Anacystis nidulans and Escherichia coli were constructed by combining an endogenous A. nidulans plasmid with an E. coli vector containing a 14 site non-symmetrical polylinker. The resulting plasmids, designated pPLAN B1 and pPLAN B2, transform A. nidulans with high efficiency and contain 7 unique restriction enzyme sites suitable for cloning.     

Shuttle cloning vectors for the cyanobacterium Anacystis nidulans.

Hybrid plasmids capable of acting as shuttle cloning vectors in Escherichia coli and the cyanobacterium Anacystis nidulans R2 were constructed by in vitro ligation. DNA from the small endogenous plasmid of A. nidulans was combined with two E. coli vectors, pBR325 and pDPL13, to create vectors containing either two selectable antibiotic resistance markers or a single marker linked to a flexible multisite polylinker. Nonessential DNA was deleted from the polylinker containing plasmid pPLAN B2 to produce a small shuttle vector carrying part of the polylinker (pCB4). The two polylinker-containing shuttle vectors, pPLAN B2 and pCB4, transform both E. coli and A. nidulans efficiently and provide seven and five unique restriction enzyme sites, respectively, for the insertion of a variety of DNA fragments. The hybrid plasmid derived from pBR325 (pECAN1) also transforms both E. coli and A. nidulans, although at a lower frequency, and contains two unique restriction enzyme sites.     

A host-vector system for gene cloning in the cyanobacterium Anacystis nidulans R2

We describe the construction of a series of vectors suitable for gene cloning in the Cyanobacterium Anacystis nidulans R2. From the indigenous plasmid pUH24, derivatives were constructed with streptomycin as the selective marker; one of these plasmids was used to construct pUC303, a shuttle vector capable of replication in A. nidulans R2 as well as in Escherichia coli K12. It has two markers, streptomycin and chloramphenicol resistance, and three unique restriction sites. Instability of recombinant plasmids was overcome by using a derivative of A. nidulans R2 cured of the indigenous plasmid pUH24. This strain, R2-SPc, can be transformed stably and at high frequency by the plasmids described in this paper. The combination of the cured strain R2-SPc and the new plasmid pUC303 serves as a suitable host-vector system for gene cloning in cyanobacteria.     

Biochemical and biophysical characterization of herbicide-resistant mutants of the unicellular cyanobacterium,Anacystis nidulans R2

Two herbicide-resistant mutants of the unicellular cyanobacterium, Anacystis nidulans R2, were obtained by mutagenesis with N-methyl-N′-nitro-N-nitrosoguanidine. These mutants, A. nidulans R2D1 and R2D2, were selected by growth of mutagenized cells in the presence of 10^?6 M and 10^?5 M 3-(3,4-dichlorophenyl)-1,1-dimethyl urea (DCMU), respectively. Both were found to be cross-resistant to 2-chloro-4-ethylamino-6-isopropylamino-s-triazine (atrazine) and 2-n-heptyl-4-hydroxyquinoline-n-oxide (HQNO) by measurement of Photosystem II activity in the presence of the inhibitors. The DCMU-resistance trait from each mutant was transferred to a wild-type genetic background by DNA-mediated transformation of A. nidulans cells. The two resulting transformants, A. nidulans R2D1-X1 and R2D2-X1, were similar to the original mutants with respect to DCMU- and HQNO-resistance. However, both exhibited increased sensitivity to atrazine relative to the mutants from which they were derived. Polyacrylamide gel electrophoretic analysis revealed that the mutants and transformants were deficient in a 34 kDa, surface-exposed polypeptide which was present in the wild-type strain; the transformants exhibited a new polypeptide of 35.5 kDa which was also highly surface-exposed.     

A hybrid plasmid is a stable cloning vector for the cyanobacterium Anacystis nidulans R2.

Anacystis nidulans R2 is a highly transformable strain which is suitable as a recipient for molecular cloning in cyanobacteria. In an effort to produce an appropriate cloning vector, we constructed a hybrid plasmid molecule, pSG111, which contained pBR328 from Escherichia coli and the native pUH24 plasmid of A. nidulans. pSG111 replicated in and conferred ampicillin and chloramphenicol resistance to both hosts. It contained unique sites for the restriction enzymes EcoRI, SalI, SphI, and XhoI, which could be used for the insertion of exogenous DNA. To demonstrate that a molecule like pSG111 could serve as a shuttle vector for the cloning of A. nidulans genes, we constructed a hybrid plasmid, pRNA404, containing an A. nidulans rRNA operon. This recombinant molecule was genetically and structurally stable during passage through A. nidulans and E. coli. The stability of the hybrid plasmid and the inserted rRNA operon demonstrates the feasibility of cloning in A. nidulans with hybrid vectors, with the subsequent retrieval of cloned sequences.     

Construction of new shuttle plasmid vectors for Escherichia coli-Bacteroides transgeneric cloning

Abstract An Escherichia coli-Bacteroides shuttle vehicle (pKBF367-1) was constructed by combining the pBR322 derivative pKC7 (5.9 kb) with [1] a 4.6 kb cryptic plasmid from Bacteroides fragilis ; and [2] the 4.2 kb Eco RI-B fragment of the B. fragilis plasmid pBFTM10. This latter component allowed selection of clindamycin-resistant transconjugants upon helper plasmid-mediated transfer to a recipient strain of Bacteroides distasonis . To improve the potential of pKBF367-1 (14.7 kb) as cloning vector, successive deletions generated derivatives of 12.8, 10.5 and 9.3 kb, which were still able to replicate in B. distasonis 419. These bifunctional vectors were successfully employed to introduce transposon Tn 501 (Hg^r) into B. distasonis 419, but expression of mercury resistance was not observed. This plasmid vehicles series may be useful for cloning Bacteroides genes in E. coli and studying their expression in a heterologous Bacteroides strain.     

Optimal conditions for genetic transformation of the cyanobacterium Anacystis nidulans R2

Under optimal conditions, the cyanobacterium Anacystis nidulans R2 was transformed to ampicillin resistance at frequencies of greater than 10(7) transformants per microgram of plasmid (pCH1) donor DNA. No stringent period of competency was detected, and high frequencies of transformation were achieved with cultures at various growth stages. Transformation increased with time after addition of donor DNA up to 15 to 18 h. The peak of transformation efficiency (transformants/donor molecule) occurred at plasmid concentrations of 125 to 325 ng/ml with an ampicillin resistance donor plasmid (pCH1) and 300 to 625 ng/ml for chloramphenicol resistance conferred by plasmid pSG111. The efficiency of transformation was enhanced by excluding light during the incubation or by blocking photosynthesis with the electron transport inhibitor 3-(3, 4-dichlorophenyl)-1, 1-dimethylurea (DCMU) or the uncoupler carbonyl cyanide-m-chlorophenyl hydrazone. Preincubation of cells in darkness for 15 to 18 h before addition of donor DNA significantly decreased transformation efficiency. Growth of cells in iron-deficient medium before transformation enhanced efficiency fourfold. These results were obtained with selection for ampicillin (pCH1 donor plasmid)- or chloramphenicol (pSG111 donor plasmid)-resistant transformants. Approximately 1,000 transformants per microgram were obtained when chromosomal DNA from an herbicide (DCMU)-resistant mutant was used as donor DNA. DCMU resistance was also transferred to recipient cells by using restriction fragments of chromosomal DNA from DCMU-resistant mutants. This procedure allowed size classes of fragments to be assayed for the presence of the DCMU resistance gene.     

Hybrid vectors for the cyanobacterium Anacystis nidulans R2, containing the plasmid pUB110 from Staphylococcus aureus

The recombinant vector plasmids were constructed having the DNA of pUB110 plasmid (4,5 kb, KmR) from Staphylococcus aureus inserted into the cryptic plasmids pANS (8 Kb) and pANL (48,5 kb) of cyanobacterium Anacystis nidulans R2. The hybrid plasmids transform cyanobacterial cells to Km-resistance with high efficiency. The plasmid pBS20, containing the complete sequence of pANS and pUB110 DNA, transforms Bacillus subtilis rec E4 protoplasts being, however, unstable in bacilli cells and disintegrates deriving a parent pUB110 plasmid.     

Triton X-114 phase fractionation of membrane proteins of the cyanobacterium Anacystis nidulans R2

The thylakoid polypeptides of the cyanobacterium Anacystis nidulans R2 were analyzed by Triton X-114 phase fractionation [C. Bordier (1981) J. Biol. Chem.256, 1604–1607, as adapted for photosynthetic membranes by T. M. Bricker and L. A. Sherman (1982) FEBS Lett.149, 197–202]. In this procedure, polypeptides with extensive hydrophobic regions (i.e., intrinsic proteins) form mixed micelles with Triton X-114, and are separated from extrinsic proteins by temperature-mediated precipitation of the mixed Triton X-114-intrinsic protein micelles. The polypeptide pattern after phase fractionation was highly complementary, with 62 of the observed 110 polypeptide components partitioning into the Triton X-114-enriched fraction. Identified polypeptides fractionating into the Triton X-114 phase included the apoproteins for Photosystems I and II, cytochromes f and b₆, and the herbicide-binding protein. Identified polypeptides fractioning into the Triton X-114-depleted (aqueous) phase included the large and small subunits of RuBp carboxylase, cytochromes c₅₅₀ and c₅₅₄, and ferredoxin. Enzymatic radioiodination of the photosynthetic membranes followed by Triton X-114 phase fractionation allowed direct identification of intrinsic polypeptide components which possess surface-exposed regions susceptible to radioiodination. The most prominent of these polypeptides was a 34-kDa component which was associated with photosystem II. This phase partitioning procedure has been particularly helpful in the clarification of the identity of the membrane-associated cytochromes, and of photosystem II components. When coupled with surface-probing techniques, this procedure is very useful in identifying intrinsic proteins which possess surface-exposed domains. Phase fractionation, in conjunction with the isolation of specific membrane components and complexes, has allowed the identification of many of the important intrinsic thylakoid membrane proteins of A. nidulans R2.     

Cloning of a third nitrate reductase gene from the cyanobacterium Anacystis nidulans R2 using a shuttle cosmid library

A strategy for gene cloning in the cyanobacterium Anacystis nidulans R2 was developed which made use of a gene library constructed in a shuttle cosmid vector. The method involved phenotypic complementation of mutants with pooled cosmid DNA. The development of the procedure and its application to the cloning of a third gene involved in nitrate reduction are described.     

Characterization of phycobilisome glycoproteins in the cyanobacterium Anacystis nidulans R2.

Concanavalin A-reactive linker and anchor subunits of phycobilisomes from Anacystis nidulans R2 (H. C. Riethman, T. P. Mawhinney, and L. A. Sherman, FEBS Lett. 215:209-214, 1987) were purified electrophoretically and analyzed for carbohydrate composition and quantity. Different quantities of glucose and N-acetylgalactosamine were found on the concanavalin A-reactive subunits analyzed. Proteolytic analysis of the purified subunits suggested that small regions of the 33- and 27-kilodalton linker polypeptides previously shown to be important for in vitro phycobilisome assembly contained the concanavalin A-reactive carbohydrates present on these subunits. The linker and anchor subunits from the morphologically different phycobilisome of Synechocystis sp. strain PCC6714 were also shown to be concanavalin A reactive. Membranes from iron-starved Anacystis nidulans, which lack assembled phycobilisomes and are associated with glycogen deposits, were shown to be depleted of linker and anchor proteins and to accumulate very large quantities of a concanavalin A-reactive, extrinsic membrane glycoprotein. We suggest that this iron stress-induced glycoprotein is associated with the glycogen deposits on the thylakoid surface and that the glycosylation of phycobilisome linker and anchor subunits is involved in the physiological regulation of phycobilisome assembly and degradation.     

A host-vector system for gene cloning in the cyanobacterium Synechocystis PCC 6803

Summary Synechocystis 6803 contains at least four cryptic plasmids of 2.27 kb (pUS1, pUS2 and pUS3) and 5.20 kb (pUS4). The 1.70 kb HpaI fragments of the related plasmids pUS2 and pUS3 were cloned into the Ap^r gene of the E. coli plasmid pACYC177, yielding the Km^r hybrid plasmids pUF12 and pUF3 respectively. pUF3 recombines in Synechocystis 6803 with a 2.27 kb plasmid giving the Km^r shuttle vector pUF311. The 1.35 kb HaeII fragment containing the Cm² gene of the E. coli plasmid pACYC184 was cloned in pUF311 generating the Cm^r Km^r shuttle vector pFCLV7. Wild-type cells of Synechocystis 6803 are transformed, albeit poorly, by the plasmids pUF3, pUF12 and pFCLV7. pFCLV7 very efficiently transforms the SUF311 strain of Synechocystis 6803 containing pUF311 as a resident plasmid. This is due to recombination between the homologous parts of pFCLV7 and pUF311. For the same reason the strain SUF311 is also efficiently transformable by E. coli plasmids, as shown for pLF8, provided that they have some homology with the E. coli part of pUF311.The combined use of Synechocystis 6803 strain SUF311 and of plasmids pFCLV7 and pLF8 generates an efficient host-vector system for gene cloning in this facultatively heterotrophic cyanobacterium.     

Bioenergetic characterization of transient state phosphate uptake by the cyanobacterium Anacystis nidulans

A force flow relationship based on nonequilibrium thermodynamics was derived to analyze the variable transient state phosphate uptake phenomena of cyanobacteria seen under different growth conditions and external phosphate concentrations. This relationship postulates the following basic properties of the uptake system: First, a threshold value exists, below which incorporation is energetically impossible. Second, threshold values are influenced by the activity of the phosphate uptake system, such that a decrease of the activity increases the threshold level. Third, near the thermodynamic equilibrium the uptake rate is linearly dependent on the free energy of polyphosphate formation and the pH-gradient at the thylakoid membrane. Experiments performed with Anacystis nidulans showed that phosphate uptake characteristics conformed to the properties predicted by the linear force-flow relationship. Linearity extented into regions far form thermodynamic equilibrium, e.g. to high phosphate concentrations, when algae were preconditioned to high phosphate levels. Under phosphate limited growth linearity was confined to a small concentration range, threshold values decreased below 10 nM, and the external concentration approached threshold. The data suggest that the uptake system responds to changes in the external phosphate concentration in the same way as sensory systems to input stimuli by amplifying signals and adapting to them.Abbreviations chl chlorophyll - H _e ⁺ , H _C ⁺ , H _T ⁺ protons in the external medium, the cytoplasmic and thylakoid space respectively - P_c phosphate in the cytoplasmic space - P_e phosphate in the external medium - P_n, P_n+1 polyphosphates - pH_T pH-gradient across the thylakoid membrane     

Recombinant plasmids capable of integration into the chromosome of the cyanobacterium Anacystis nidulans R2

Recombinant plasmids, series pIAB and pIAH, have been constructed by insertion of BamHI or HindIII chromosomal fragments from Anacystis nidulans R2 into the tet gene of plasmid pACYC184. Plasmids pIAB and pIAH are stably maintained in Escherichia coli cells and transfer the CmR marker in transformation of Anacystis nidulans. Blot hybridization technique has shown the formation of CmR clones in transformation to result from integration of plasmid pACYC184 with the chromosome of cyanobacterium.     

Instability of Tn5 in a plasmid cloning vector for the cyanobacterium Anacystis nidulans.

Transposon Tn5 was used to produce insertions within the region of a cyanobacterial shuttle vector previously identified as necessary for transformation of Anacystis nidulans. These transposon-containing plasmids were used to transform a plasmid-cured derivative of Anacystis strain R2 and tested for structural stability of the transforming plasmid. The transposon DNA was deleted from all the plasmids containing Tn5 within the cyanobacterial replication region. Inserts in the vector DNA were physically stable and expressed the kanr gene. The internal Tn5 HindIII fragment was also cloned into each of the three HindIII sites in the shuttle plasmid. Inserts in two of these sites were stable, whereas inserts into the third site were not.     

Purification and characterization of a DNA polymerase from the cyanobacterium Anacystis nidulans R2.

A DNA polymerase has been highly purified from Anacystis nidulans R2. Electrophoretic analysis in sodium dodecyl sulfate-polyacrylamide gels revealed that the final fraction contains three bands of Mr 107,000, 93,000, and 51,000, respectively. Analysis of purified DNA polymerase activity in situ indicates that of the three polypeptides the Mr 107,000 species has the catalytic activities. The native molecular weight of the enzyme was estimated by glycerol gradient sedimentation to be 100,000. The enzyme has an absolute requirement for a divalent cation. Mg2+ can be replaced with Mn2+, but the DNA polymerase is less active. Potassium chloride stimulates the enzyme, while potassium phosphate has no apparent effect. The enzyme is active over a pH range from 7.5 to 9.5 in 50mM Tris-HCl buffer. The ability of the cyanobacterial DNA polymerase to use activated DNA as a template, its associated 3'----5' and 5'----3' exonuclease activities, as well as its resistance to N-ethylmaleimide, dideoxynucleotides, arabinosyl-CTP and aphidicolin suggest a similarity between this enzyme and E. coli DNA polymerase I. This is the first characterization of a DNA polymerase from a cyanobacterium.