Michel Guerineau

Recombinant environmental libraries provide access to microbial diversity for drug discovery from natural products

ABSTRACT To further explore possible avenues for accessing microbial biodiversity for drug discovery from natural products, we constructed and screened a 5,000-clone “shotgun” environmental DNA library by using an Escherichia coli-Streptomyces lividans shuttle cosmid vector and DNA inserts from microbes derived directly (without cultivation) from soil. The library was analyzed by several means to assess diversity, genetic content, and expression of heterologous genes in both expression hosts. We found that the phylogenetic content of the DNA library was extremely diverse, representing mostly microorganisms that have not been described previously. The library was screened by PCR for sequences similar to parts of type I polyketide synthase genes and tested for the expression of new molecules by screening of live colonies and cell extracts. The results revealed new polyketide synthase genes in at least eight clones. In addition, at least five additional clones were confirmed by high-pressure liquid chromatography analysis and/or biological activity to produce heterologous molecules. These data reinforce the idea that exploiting previously unknown or uncultivated microorganisms for the discovery of novel natural products has potential value and, most importantly, suggest a strategy for developing this technology into a realistic and effective drug discovery tool.

Organization and nucleotide sequence analysis of a ribosomal RNA gene cluster from Streptomyces ambofaciens

The Streptomyces ambofaciens genome contains four rRNA gene clusters. These copies are called rrnA, B, C and D. The complete nucleotide (nt) sequence of rrnD has been determined. These genes possess striking similarity with other eubacterial rRNA genes. Comparison with other rRNA sequences allowed the putative localization of the sequences encoding mature rRNAs. The structural genes are arranged in the order 16S-23S-5S and are tightly linked. The mature rRNAs are predicted to contain 1528, 3120 and 120 nt, for the 16S, 23S and 5S rRNAs, respectively. The 23S rRNA is, to our knowledge, the longest of all sequenced prokaryotic 23S rRNAs. When compared to other large rRNAs it shows insertions at positions where they are also present in archaebacterial and in eukaryotic large rRNAs. Secondary structure models of S. ambofaciens rRNAs are proposed, based upon those existing for other bacterial rRNAs. Positions of putative transcription start points and of a termination signal are suggested. The corresponding putative primary transcript, containing the 16S, 23S and 5S rRNAs plus flanking regions, was folded into a secondary structure, and sequences possibly involved in rRNA maturation are described. The G + C content of the rRNA gene cluster is low (57%) compared with the overall G + C content of Streptomyces DNA (73%).

Plasmids in different strains of Streptomyces ambofaciens: free and integrated form of plasmid pSAM2

SummaryFive strains of Streptomyces ambofaciens were examined for their plasmid content. Among these strains, four belong to the same lineage (strains B) and the other was isolated independently (strain A). A large plasmid (ca. 80 kb), called pSAM1 in this paper and already described, was present in all B strains, and absent in strain A. A second plasmid, not described before, was found as covalently closed circular DNA in two of the four B strains. This plasmid with a size 11.1 kb was called pSAM2. A restriction map for 14 enzymes was established. Hybridization experiments showed that a unique sequence homologous to this plasmid is integrated in a larger replicon, which is not pSAM1 and is probably the chromosome, in all B strains and not in strain A. It seems probable that the integrated se1uence is the origin of the free plasmid found in two strains of the B family. It is noteworthy that the integrated form and the free plasmid may be found together. Transformation experiments proved that pSAM2 may be maintained autonomously in S. ambofaciens strain A and in S. lividans. pSAM2 is a self-transmissible plasmid, able to elicit the lethal zygosis reaction. pSAM2 was compared to the plasmids SLP1, pIJ110 and pIJ408, which all come from integrated sequences in three Streptomyces species and are found as autonomous plasmids after transfer to S. lividans. If pSAM2 resembles these plasmids in its origin, it does not appear to be related directly to them. Concerning their plasmid content, the two isolates of S. ambofaciens are very different. One of them contains neither pSAM1 not pSAM2. As this isolate produces spiramycin, these plasmids probably do not play an important role in spiramycin production. Apart from its intrinsic biological interest, pSAM2 may be useful in the construction of cloning vectors for S. ambofaciens. Very stable transformants might be obtained in certain strains of S. ambofaciens, because of the possibility of integration of the pSAM2 derivative vector.

High frequency of yeast transformation by plasmids carrying part of entire 2-μm yeast plasmid

Abstract By using two chimeric plasmids containing yeast ura3 gene and 2-μm yeast DNA linked to the bacterial plasmid pCR1, yeast transformation of a high frequency has been achieved. The first plasmid is such that the 2-μm DNA part, in which the ura3 gene is incorporated, can be removed in one step and thus the 2-μm—ura3 sequence can be considered as a “transposable” block. In contrast, the second one bears the entire 2-μm plasmid and the ura3 gene is inserted in the bacterial plasmid part. As shown through hybridization experiments and genetic studies, the ura3 gene was maintained as a cytoplasmic element. Plasmids recovered from the yeast transformants were used to transform Escherichia coli. Their analysis by EcoRI showed that in many cases the vector had recombined with the endogenous 2-μm DNA of the recipient strain. The specific activity of orotidine 5′-monophosphate decarboxylase (coded by ura3) in yeast transformants was 10- to 30-fold higher than in the wild type.

The integrative element pSAM2 from Streptomyces: kinetics and mode of conjugal transfer

pSAM2 is an 11 kb integrative element from Streptomyces ambofaciens that is capable of conjugal transfer. A system based on differential DNA modification by SalI methyltransferase was used to localize pSAM2 in the donor or recipient strain, and thus to determine the various steps associated with transfer. Initiation (i.e. excision and replication of pSAM2 in the donor) occurs a few hours after mating with a recipient strain. pSAM2 replicates in the recipient strain, spreads within the mycelium and then integrates into the chromosome. Transfer generally involves single‐stranded DNA. In Streptomyces, only a few genes, such as traSA for pSAM2, are required for conjugal transfer. Using the differential sensitivity to the SalI restriction–modification system of transfers involving single‐ and double‐stranded DNA, we found that pSAM2 was probably transferred to the recipient as double‐stranded DNA. This provides the first experimental evidence for the transfer of double‐stranded DNA during bacterial conjugation. Thus, TraSA, involved in pSAM2 transfer, and SpoIIIE, which is involved in chromosome partitioning in Bacillus subtilis, display similarities in both sequence and function: both seem to transport double‐stranded DNA actively, either from donor to recipient or from mother cell to prespore.

Yeast episome: Oligomycin resistance associated with a small covalently closed non-mitochondrial circular DNA

Abstract We have isolated a single step spontaneous mutant of S. cerevisiae resistant simultaneously to oligomycin, venturicidin, chloramphenicol, cycloheximide and triethyltin. This multiple drug resistance results from the interaction of two genetic factors showing both chromosomal location and episomal characteristics. One factor (π) confers oligomycin resistance, the other (τ) confers the other resistances. π can be lost spontaneously while τ can be completely eliminated with ethidium bromide. All π + strains, whether grande or petite, τ + or τ − , carry a covalently closed circular DNA while π − strains are devoid of it. We hypothesise that this circular DNA may play an informational role in the biogenesis and/or function of membranes.

Characterization of a new class of circular DNA molecules in yeast

Abstract This paper describes the isolation of a pure population of covalently closed circular twisted DNA molecules from yeast. These molecules are homogeneous in size, that is consist of monomers of 2.2μ and of multiple length oligomers of n x 2.2μ. While no data rule out the mitochondrial origin of this DNA, its actual intracellular localization remains unknown; it displays the same buoyant density as the main nuclear DNA and therefore is not the heavy nuclear satellite DNA (γ-DNA described by Moustacchi and Williamson (1966) ); although circular molecules represent only 1 to 5 % of the total DNA, they can be prepared in sizable and reproducible amounts by a method based on the use of mechanical disruption of yeast cells rather than lysis by snail gut juice.

Cloning and expression of the structural gene for β-glucosidase of Kluyveromyces fragilis in Escherichia coli and Saccharomyces cerevisiae

SummaryCellobiose, the last product in cellulose degradation, is converted into two molecules of glucose by a β-glucosidase. S. cerevisiae does posses the structural gene for a β-glucosidase, but it is very poorly expressed; we thus decided to isolate and characterize that of Kluyveromyces fragilis.We constructed in E. coli HB101 strain a genomic library of the Kluyveromyces fragilis Y610 strain (ATCC 12424), a yeast able to grow on cellobiose and which constitutively produces the β-glucosidase. The structural gene for β-glucosidase was identified by its expression in E. coli. The initial isolated cosmid KF1 contained an insert of 35 Kb and by successive subcloning the insert size was reduced to 3.5 Kb (KF4).This cloned β-glucosidase gene introduced in S. cerevisiae by transformation is expressed at a level of about 500 times that of K. fragilis. We checked by Southern hybridization that the high expression level was not due to a rearrangement of K. fragilis DNA during the cloning experiments. Nevertheless to obtain yeast transformants able to grow on cellobiose a yeast strain whose permeability to sugar is increased must be used and this last point is discussed.

A map of the restriction targets in yeast 2 micron plasmid DNA cloned on bacteriophage lambda

SummaryThe 2 micron circular DNA from S. cerevisiae has been cloned on bacteriophage λ. The two forms of circular DNA which exist in equilibrium due to recombination between inverted repeat sequences were separated as stable clones, and a map of the targets for restriction endonucleases EcoRI, HindIII and HpaI was constructed. The circular DNAs isolated from a particular oligomycin resistant strain and its parent oligomycin sensitive strain were compared by restriction endonuclease analysis, and no difference was detected. The potential uses of cloned 2 micron DNA in determining the possible biological role of these plasmids are considered.

Structural analysis of loci involved in pSAM2 site-specific integration in Streptomyces

pSAM2 is an 11-kb plasmid integrated in the Streptomyces ambofaciens ATCC23877 and ATCC15154 genomes and found additionally as a free replicon in an uv derivative. After transfer into S. ambofaciens DSM40697 (devoid of pSAM2) or into Streptomyces lividans, specific integration of pSAM2 occurred very efficiently. A 58-bp sequence (att) present in both pSAM2 (attP) and S. ambofaciens strain DSM40697 (attB) attachment regions is found at the boundaries (attL and attR) of integrated pSAM2 in S. ambofaciens strain ATCC23877. The S. lividans chromosomal integration zone contained an imperfectly conserved att sequence (attB), and the integration event of pSAM2 was located within a 49-bp sequence of attB. Only one primary functional attB sequence was present in the S. lividans or S. ambofaciens DSM40697 total DNA. The integration zone of S. lividans hybridized with the integration zone of S. ambofaciens DSM40697. The two integration zones were homologous only to the right side of the att sequence. The conserved region contained an open reading frame (ORF A) with a stop codon located 99 bp from the attB sequence in both strains. S. ambofaciens DSM40697 contained DNA sequences related to pSAM2 on the left side of the att site. The att sequence was included in a region conserved in Streptomyces antibioticus, Streptomyces actuosus, Streptomyces bikiniensis, Streptomyces coelicolor, Streptomyces glaucescens, and Streptomyces parvulus. Site-specific integration of a pSAM2 derivative was characterized in another unrelated strain, Streptomyces griseofuscus. This strain contained an imperfectly conserved 58-bp attB sequence, and the integration event took place within a 45-bp sequence of attB. Site-specific integration of pSAM2 in three nonrelated Streptomyces strains suggests the wide host range of pSAM2 integration in Streptomyces.