V. Sgaramella

Different specific activities of the monomeric and oligomeric forms of plasmid DNA in transformation of B. subtilis and E. coli

Summary(1) The low residual transforming activity in preparations of monomeric, supercoiled, circular (CCC) forms of the plasmids pC194 and pHV14 could be attributed to the presence in such isolates of a small number of contaminating multimeric molecules. (2) E. coli derived preparations of pHV14, an in vitro recombinant plasmid capable of replication in both E. coli and B. subtilis, contain oligomeric forms of plasmid DNA in addition to the prevalent monomeric CCC form. The specific transforming activity of pHV14 DNA for E. coli is independent of the degree of oligomerization, whereas in transformation of B. subtilis the specific activity of the purified monomeric CCC molecules is at least four orders of magnitude less than that of the unfractionated preparation. (3) Oligomerization of linearized pHV14 DNA by T4 ligase results in a substantial increase of specific transforming activity when assayed with B. subtilis and causes a decrease when used to transform E. coli.

Lactobacillus protoplast transformation

A method for the transformation of Lactobacillus protoplasts by plasmid DNA is reported. The procedure involves polyethylene glycol treatment of protoplasts to induce DNA uptake. A transformation efficiency ranging from 5 to 1000 transformants per microgram of DNA is achieved; the efficiency of protoplast regeneration ranged from 10 to 20%.

Specific pattern of instability of Escherichia coli HisG gene cloned in Bacillus subtilis via the Staphylococcus aureus plasmid pCS194.

Abstract The plasmid pCS194, generated in vivo by recombination of two Staphylococcus aureus plasmids, pC194 and pS194, coding, respectively, for chloramphenicol (Cm) and streptomycin (Sm) resistance, can be replicated also in Bacillus subtilis in the presence of either of the two antibiotics. In their absence, no segregation of the individual components is observed, but the whole plasmid is lost at a rate of about 10% per generation. The unique EcoRI site of pCS194 is located in the SmR determinant. EcoRI-cleaved pCS194 has been joined to an EcoRI-linearized Escherichia coli replicon, the in vitro recombinant pHisG plasmid, composed of the vector pBR313 plus a BglII-segment of E. coli chromosomal DNA, containing a functional hisG gene. The ligation mixture has been used to transform either E. coli or B. subtilis. Following E. coli transformation and selection for ApR and CmR (the latter is expressed in E. coli by the pC194 determinant), two his+ clones were picked at random and the plasmids extracted. These appear identical and contain the original segments. Conversely, after transformation of B. subtilis and selection for CmR, only his− clones have been obtained. From them, deleted plasmids have been extracted. They have lost part or, more frequently, all of the E. coli DNA insert. In the latter case also most of the bracketing pS194 sequence has been lost, and the resulting plasmids are almost identical to pC194, the CmR parent of pCS194. When the intact recombinant plasmids, isolated from his+ ApR CmR E. coli clones, have been used to transform B. subtilis cells for CmR, again deleted plasmids almost identical to pC194 have been obtained. The events causing these rearrangements occur after in vitro ligation, during either transformation or early propagation of the plasmids, and are probably caused by a translocatable element present in pCS194. A detailed physical map of pC194, carrying the restriction sites for HindIII, HaeIII, HpaII, MboII, AluI, HhaI, and BglI, is presented.

Cloning of histidine genes of Azospirillum brasilense: Organization of the ABFH gene cluster and nucleotide sequence of the hisB gene

SummaryA cluster of four Azospirillum brasilense histidine biosynthetic genes, hisA, hisB, hisF and hisH, was identified on a 4.5 kb DNA fragment and its organization studied by complementation analysis of Escherichia coli mutations and nucleotide sequence. The nucleotide sequence of a 1.3 kb fragment that complemented the E. coli hisB mutation was determined and an ORF of 624 nucleotides which can code for a protein of 207 amino acids was identified. A significant base sequence homology with the carboxyterminal moiety of the E. coli hisB gene (0.53) and the Saccharomyces cerevisiae HIS3 gene (0.44), coding for an imidazole glycerolphosphate dehydratase activity was found. The amino acid sequence and composition, the hydropathic profile and the predicted secondary structures of the yeast, E. coli and A. brasilense proteins were compared. The significance of the data presented is discussed.

The origin of a morphologically unidentifiable human supernumerary minichromosome traced through sorting, molecular cloning, and in situ hybridisation.

A supernumerary minichromosome has been detected in a severely malformed patient. Attempts at identifying the marker by conventional approaches were unsuccessful. The physical isolation of the minichromosome by fluorescence activated sorting, molecular cloning of its DNA, and in situ hybridisation experiments performed with single copy DNA probes allowed us to show that it was derived from a rearrangement involving the centromere and the proximal region of the short arm of chromosome 9.

Sequence and functional analysis of a divergent promoter from a cryptic plasmid of Lactobacillus acidophilus 168 S

We have characterized three of at least five plasmids borne by Lactobacillus acidophilus 168 S. Restriction mapping indicates extensive sequence homology between at least two of them (p1 and p3). We have cloned them in Escherichia coli, and for the smallest (p1) we present the sequence of a region with two divergently arranged promoters which probably share a symmetrical (TTTAAA)-35 box and function efficiently in E. coli cells; an open reading frame contiguous to the promoter, which codes for a 120 amino acid protein of unknown function, and is transcribed in E. coli; and a transcription termination sequence next to this open reading frame. The promoter region contains an AT cluster which is similar to that of the ori2 region of the E. coli F plasmid, and is probably involved in the control of the replication of p1.

Lawyers' delights and geneticists' nightmares: at forty, the double helix shows some wrinkles

The National Institutes of Health (NIH) request to patent the base sequences of incomplete and uncharacterized fragments of DNA copied on messenger RNAs (cDNAs) extracted from human tissues, the refusal by the patent office, and the appeal placed by NIH, have incited a violent controversy, fueled by rational, as well as emotional elements. In a compromising mode between liberalism and protectionism, I propose that legal protection be considered only for those RNA/DNA sequences, either natural or artificial, which can generate practical applications per se, and not through their expression products. Another controversy is developing around a popular tool for genomic research: the fidelity of yeast artificial chromosome (YAC) libraries being distributed worldwide for physical mapping is being questioned. Some of these libraries have been shown to be affected by surprisingly high levels of co-cloning, in addition to more common gene reshuffling instances. Also in this case, scientific as well as non-scientific components have to be considered. Possible remedies for the underlying problems may be found in the proper use of kinetic, enzymatic and microbiological variables in the production of YACs. Here too, a sharper distinction between the secular and scientific gratifications of research could help.

Cytological analysis and sorting of a human supernumerary minichromosome

In a newborn female, an abnormal karyotype, 46,XX/47,XX,+mar/47,XX,+9, was found associated with several malformations. The marker chromosome was present in 70% of peripheral blood lymphocytes, and its size appeared to be less than half of the smallest chromosomes. Several differential staining methods provided no indication as to its origin.Chromosomes isolated from EBV-immortalized lymphocytes of the patient were fractionated on a FACS-440. The marker was resolved as a sharp peak in the region close to the chromosomal debris: its DNA content seemed to be close to 40% of chromosomes 21 and 22.About 580000 minichromosomes were sorted. In order to optimize cloning conditions, a pilot cloning experiment was performed on a pool of sorted chromosomes 9, 10, 11 and 12.

Heterologous expression in Bacillus subtilis. II. In vitro removal of the attenuator sequence of the Escherichia coli his operon allows expression of the cloned hisG gene in B. subtilis.

The promoter-proximal region of the Escherichia coli histidine (his) operon, including the promoter, the attenuator and the hisG gene, as well as the first of the nine structural genes of the his operon, have been cloned in Bacillus subtilis. In this host, the hisG gene could not be expressed because its transcription appeared to be irreversibly terminated at the attenuator (Ferretti et al., 1984). When the attenuator plus various lengths of the two bordering regions were removed, one of the attenuatorless sequences cloned in B. subtilis allowed the progression of transcription and complementation of the corresponding hisA mutation in this Gram-positive host. The deletion removed a 349-bp segment which contained the his attenuator and promoter. In B. subtilis, the productive transcription of the hisG gene started at a site in pAT153 and terminated in pC194. Sequence analysis of the deletion indicates that the E. coli ribosome-binding site of the his operon was used for the translation of the E. coli hisG gene mRNA in B. subtilis cells, which can thus grow in the absence of histidine.

R-factor-mediated suppression of the galactose-sensitive phenotype of Escherichia coli K-12 galE Mutants.

Abstract Plasmids S-a and Rts1 suppress the galactose-sensitive phenotype of galE mutants of Escherichia coli K-12, giving rise to both galactose-fermenting and nonfermenting strains. Fermenting strains produce normal inducible UDP-galactose epimerase. Plasmids extracted from either a fermenting or a nonfermenting strain are indistinguishable when examined by either measurements of length of relaxed circular molecules by electron microscopy or electrophoretic pattern of restriction endonuclease digestion products. The phenomenon could be explained by reversible recombination between a plasmid-borne epimerase gene and homologous chromosomal sequences.