Characterization of a loss-of-function mutation in the isopenicillin N synthetase gene of Acremonium chrysogenum

The N-2 strain of Acremonium chrysogenum accumulates the beta-lactam precursor tripeptide delta-(L-alpha-amino-adipoyl)-L-cysteinyl-D-valine and has no discernible activity for three of the cephalosporin C (Ce) biosynthetic enzymes. This phenotype is consistent with a mutation either within pcbC [the isopenicillin N synthetase (IPNS)-encoding gene] or in a pathway-regulator gene. To distinguish these possibilities we have cloned and sequenced pcbC from strain N-2. There is a single C----T mutation at nt 854 within the coding sequence, changing aa 285 from proline to leucine. An IPNS-specific monoclonal antibody recognises a catalytically inactive IPNS protein in extracts of N-2 cells. These findings suggest that strain N-2 carries a simple IPNS mutation and that IPNS or its biosynthetic product isopenicillin N is involved in regulation of the later stages of the Ce biosynthetic pathway.     

Effects of electroporation pulse wave on the incorporation of viral RNA into tobacco protoplasts

The uptake and expression of cucumber mosaic viral (CMV) RNA by tobacco protoplasts was examined using both square wave and exponential wave electroporation pulses. These electropulses, when supplied at sufficient field strength for a critical duration, enabled RNA to be incorporated and expressed in more than 60% of the surviving protoplasts. The results of experiments using these two electroporation wave forms showed significant differences in RNA uptake and expression. The number of viable protoplasts and cells showing expression of RNA was higher over a much broader range of experimental conditions using the square rather than exponential wave generator, even when both machines were optimized for maximal performance. However, at a narrow range of low field strengths the exponential wave pulse generated a higher percentage of transformants than did the square wave pulse. It was shown that after an electroporation pulse from either wave form, there were viable cells which expressed foreign RNA at predictable levels.     

Plasmid-mediated conjugative transfer of Klebsiella sp. rcs genesable to induce colanic acid capsular polysaccharide biosynthesis in Escherichia coli

Regulation of capsular biosynthesis (rcs) genes, encoding the ability to induce the production of a colanic acid polysaccharide capsule, were transferred to Escherichia coli by conjugation with Klebsiella pneumoniae (aerogenes) of capsular serotype K36. Transfer was mediated by a 58.4-MDa conjugative plasmid of incompatibility group IncM, which carried a copy of Tn7 (specifying resistance to trimethoprim and streptomycin) together with determinants for several further resistances. This plasmid did not carry the rcs genes itself, but mediated the conjugative recA-dependent transfer of part of the Klebsiella chromosome to E. coli. Once resident in E. coli, the rcs gene(s) could not be mobilised to other strains of E. coli, and the mobilising plasmid could be cured from capsulate transconjugants without loss of the ability to produce colanic acid. All such cured transconjugants contained an insertion of Tn7 in the chromosome, suggesting that the transposon might be involved in mobilisation of the rcs genes from Klebsiella sp. to E. coli. These findings explain previous observations that the ability to manufacture capsular polysaccharide could be transferred by plasmids between Klebsiella sp. and E. coli.     

Recombination-dependent recircularization of linearized pBR322 plasmid DNA following transformation of Escherichia coli

Summary Monomeric pBR322 DNA that had been linearized at its unique SalI site transformed wild-type Escherichia coli with 10² to 10³ times less efficiency than CCC plasmid DNA. Dose-response experiments indicated that a single linear plasmid molecule was sufficient to produce a transformant. Transformation with linearized pBR322 DNA was reduced 10 to 40 fold in recA ^–, recBC ^– or recF ^– backgrounds. In contrast, transformation with CCC DNA was unaffected by the rec status of the host. Transformation with linear pBR322 DNA was increased 3-fold in a DNA ligase-overproducing (lop11) mutant and decreased to a similar degree by transient inactivation of ligase in a ligts7 mutant.A proportion (ranging from about 9% in the wild-type to 42% in a recBC, lop11 mutant) of the transformants obtained with SalI-linearized pBR322 monomeric DNA contained deleted plasmids. Deletion rates were generally higher in rec ^– strains. Dephosphorylation of the termini on linear DNA or the creation of blunt-ended pBR322 molecules (by end-filling the SalI 5 protrusions or by cleavage with PvuII) decreased the transformation frequencywhilst increasing the deletion rate.Linear pBR322 dimeric DNA gave transformation frequencies in recA ⁺ and recA ^– strains that were reduced only 3 to 7 fold respectively relative to frequencies obtained with dimeric CCC DNA. Furthermore, in contrast to transformation with linear monomeric DNA, deletions were not observed.We propose that the majority of transformants arise, not by simple intracellular reannealing and ligation of the two cohesive SelI-termini of a linear molecule, but by intramolecular recombination. Deleted plasmids could be generated therefore during recyclization caused by recombination between short directly repeated sequences within a pBR322 monomer. We suggest that perfectly recircularized monomeric pBR322 molecules, which are found in the majority of transformants, arise primarily by intramolecular recombinational resolution of head-to-tail linear pBR322 dimers. Such linear oligomeric forms are created during preparation of linearized plasmid DNA by annealing of the SalI cohesive termini and constitute a variable proportion of the total molecules present.     

A new occurrence of ambient inclusion trails from the ~1900‐million‐year‐old Gunflint Formation,Ontario: nanocharacterization and testing of potential formation mechanisms

Ambient inclusion trails (AITs) are tubular microstructures thought to form when a microscopic mineral crystal is propelled through a fine‐grained rock matrix. Here, we report a new occurrence of AITs from a fossilized microbial mat within the 1878‐Ma Gunflint Formation, at Current River, Ontario. The AITs are 1–15 μm in diameter, have pyrite as the propelled crystal, are infilled with chlorite and have been propelled through a microquartz (chert) or chlorite matrix. AITs most commonly originate at the boundary between pyrite‐ and chlorite‐rich laminae and chert‐filled fenestrae, with pyrite crystals propelled into the fenestrae. A subset of AITs originate within the fenestrae, rooted either within the chert or within patches of chlorite. Sulphur isotope data (³⁴S/³²S) obtained in situ from AIT pyrite have a δ³⁴S of ?8.5 to +8.0 ‰, indicating a maximum of ~30 ‰ fractionation from Palaeoproterozoic seawater sulphate (δ³⁴S ≈ +20 ‰). Organic carbon is common both at the outer margins of the fenestrae and in patches of chlorite where most AITs originate, and can be found in smaller quantities further along some AITs towards the terminal pyrite grain. We infer that pyrite crystals now found within the AITs formed via the action of heterotrophic sulphate‐reducing bacteria during early diagenesis within the microbial mat, as pore waters were becoming depleted in seawater sulphate. Gases derived from this process such as CO₂ and H₂S were partially trapped within the microbial mat, helping produce birds‐eye fenestrae, while rapid microquartz precipitation closed porosity. We propose that propulsion of the pyrite crystals to form AITs was driven by two complementary mechanisms during burial and low‐grade metamorphism: firstly, thermal decomposition of residual organic material providing CO₂, and potentially CH₄, as propulsive gases, plus organic acids to locally dissolve the microquartz matrix; and secondly, reactions involving clay minerals that potentially led to enhanced quartz solubility, plus increases in fluid and/or gas pressure during chlorite formation, with chlorite then infilling the AITs. This latter mechanism is novel and represents a possible way to generate AITs in environments lacking organic material.     

Six Year Refractive Change among White Children and Young Adults: Evidence for Significant Increase in Myopia among White UK Children

Objective

To determine six-year spherical refractive error change among white children and young adults in the UK and evaluate differences in refractive profiles between contemporary Australian children and historical UK data.

Design

Population-based prospective study.

Participants

The Northern Ireland Childhood Errors of Refraction (NICER) study Phase 1 examined 1068 children in two cohorts aged 6–7 years and 12–13 years. Prospective data for six-year follow-up (Phase 3) are available for 212 12–13 year olds and 226 18–20 year olds in each cohort respectively.

Methods

Cycloplegic refractive error was determined using binocular open-field autorefraction (Shin-Nippon NVision-K 5001, cyclopentolate 1%). Participants were defined by spherical equivalent refraction (SER) as myopic SER ≤-0.50D, emmetropic -0.50D<SER<+2.00 or hyperopic SER≥+2.00D.

Main Outcome Measures

Proportion and incidence of myopia.

Results

The proportion of myopes significantly increased between 6–7 years (1.9%) and 12–13 years (14.6%) (p<0.001) but not between 12–13 and 18–20 years (16.4% to 18.6%, p = 0.51). The estimated annual incidence of myopia was 2.2% and 0.7% for the younger and older cohorts respectively. There were significantly more myopic children in the UK at age 12–13 years in the NICER study (16.4%) than reported in Australia (4.4%) (p<0.001). However by 17 years the proportion of myopia neared equivalence in the two populations (NICER 18.6%, Australia 17.7%, p = 0.75). The proportion of myopic children aged 12–13 years in the present study (2006–2008) was 16.4%, significantly greater than that reported for children aged 10–16 years in the 1960’s (7.2%, p = 0.01). The proportion of hyperopes in the younger NICER cohort decreased significantly over the six year period (from 21.7% to 14.2%, p = 0.04). Hyperopes with SER ≥+3.50D in both NICER age cohorts demonstrated persistent hyperopia.

Conclusions

The incidence and proportion of myopia are relatively low in this contemporary white UK population in comparison to other worldwide studies. The proportion of myopes in the UK has more than doubled over the last 50 years in children aged between 10–16 years and children are becoming myopic at a younger age. Differences between the proportion of myopes in the UK and in Australia apparent at 12–13 years were eliminated by 17 years of age.