- Volume 146, Issue 3, 2000

Insertional mutagenesis was performed with Tn1545 in the genetic background of an inlAB deletion mutant to identify new adhesion determinants in Listeria monocytogenes. Four insertion mutants defective in adhesion to eukaryotic cells were identified. Insertion sites were cloned by inverse-PCR and sequenced. The genetic organization of insertion regions was further analysed by screening and sequencing DNA fragments from a HindIII library and by searching databases. Three adhesion-defective mutants each had one copy of Tn1545 inserted into their chromosome. The insertion sites were different in the three mutants: (i) upstream from two ORFs in tandem, similar to dfp and priA of Bacillus subtilis, respectively; (ii) within an ORF encoding a putative 126 amino-acid-polypeptide with no significant similarity to any known protein; (iii) within an ORF similar to a B. subtilis ORF with no known function, just upstream from an operon similar to an ABC (ATP-binding cassette) transporter operon from B. subtilis. The excisants obtained from these mutants using the excision reporter plasmid pTCR9 recovered full adhesion capacity. A fourth mutant was the most severely defective in adhesion. It had five Tn1545 insertions, one of which was upstream from dfp and priA, and another of which was upstream from ami, a gene encoding a surface-exposed autolysin with a C terminus similar to that of InlB. Ami was clearly involved because an ami null mutant constructed in an EGDΔinlA–F background was adhesion-defective. Thus new regions involved in the adhesion of L. monocytogenes to eukaryotic cells were identified. Further study is required to define more accurately the roles of these regions in the adhesion process itself.

As a basis for studing the essential cellular processes of hyperthermophilic archaea, thermosensitive mutants of Sulfolobus acidocaldarius were isolated and characterized. Exponential-phase liquid cultures were shifted to the non-permissive temperature and growth, viability, and distributions of cell mass and DNA content were measured as a function of time after the shift. The observed phenotypes demonstrate that chromosome replication, nucleoid organization, nucleoid partition and cell division, which normally are tightly co-ordinated during cellular growth, can be inhibited or uncoupled by mutation in this hyperthermophilic archaeon.

The practice of exposing liquid cultures of the white-rot fungus Phanerochaete chrysosporium to a pure oxygen atmosphere under conditions of nutrient starvation has been widely adopted to induce lignin peroxidase (LiP) synthesis. Transmission electron microscopy was used to examine hyphal cells of carbon-limited cultures that had been exposed to an atmosphere of pure oxygen, and revealed evidence of a major loss in organization of cellular ultrastructure, which may be attributed to oxygen toxicity. Under some conditions (continuous agitation in air with cellulose as the carbon source) cultures will produce LiP without needing to be exposed to a pure oxygen atmosphere. A similar major loss of cellular ultrastructure was found in hyphal cells from such cultures upon examination. Investigation of the levels of H2O2, catalase and carbonyl content of intracellular proteins suggests that the latter cultures developed a hyperoxidant state because the rate of supply of carbon from cellulose hydrolysis was insufficient for oxygen homeostasis. The association of LiP with these cultures and with those exposed to an atmosphere of pure oxygen infers that LiP may be triggered in response to oxidant stress.