The current model of immune activation in bacteria. Various fungi stimulated antimicrobial peptides through at least two different pathways requiringRelish and/or Dif. Induction of Attacin A by Geotrichum candidum required Relish, whereas activation by Beauvaria bassiana required Dif, suggesting that the Drosophila immune system can distinguish between at least these two fungi. We conclude that the Drosophila immune system is more complex than the current model. We propose a new model to account for this immune system complexity, incorporating distinct pattern recognition receptors of the Drosophila immune system, which can distinguish between various fungi and G ؉ bacteria, thereby leading to selective induction of antimicrobial peptides via differential activation of Relish and Dif.
Background: The ninR region of phage λ contains two recombination genes, orf (ninB) and rap (ninG), that were previously shown to have roles when the RecF and RecBCD recombination pathways of E. coli, respectively, operate on phage λ. Results: When λ DNA replication is blocked, recombination is focused at the termini of the virion chromosome. Deletion of the ninR region of λ decreases the sharpness of the focusing without diminishing the overall rate of recombination. The phenotype is accounted for in large part by the deletion of rap and of orf. Mutation of the recJ gene of the host partially suppresses the Rap– phenotype. Conclusion: ninR functions Orf and Rap participate in Red recombination, the primary pathway operating when wild‐type λ grows lytically in rec+ cells. The ability of recJ mutation to suppress the Rap– phenotype indicates that RecJ exonuclease can participate in Red‐mediated recombination, at least in the absence of Rap function. A model is presented for Red‐mediated RecA‐dependent recombination that includes these newly identified participants.
A mass tagging approach is described for mitochondrial thiol proteins under nondenaturing conditions. This approach utilizes stable isotope-coded, thiol-reactive (4-iodobutyl)triphenylphosphonium (IBTP) reagents, i.e., the isotopomers IBTP-d(0) and IBTP-d(15). The mass spectrometric properties of IBTP-labeled peptides were evaluated using an ESI-q-TOF and a MALDI-TOF/TOF instrument. High energy collision induced dissociation (CID) in the TOF/TOF instrument caused side-chain fragmentation in the butyltriphenylphosphonium moiety-containing Cys-residue. By contrast, low energy CID in the qTOF instrument yielded sequence tags of IBTP-labeled peptides that were suitable for automated database searching. The IBTP labeling strategy was then applied to the analysis of a protein extract obtained from cardiac mitochondria. The relative abundance measurements for identified IBTP-labeled peptides showed an average variability for peptide quantitation of approximately 10% based on peak area ratios of ion signals for the d(0)/d(15)-tagged peptide pairs. The reactivity of the IBTP reagents was further studied by molecular modeling and visualization. The present study suggests that the IBTP reagent seems to show a bias toward highly surface-exposed protein thiols. Hence, the described mass tagging approach might become potentially useful in redox proteomics studies designed to identify protein thiols that are particularly prone to oxidative modifications.
Both hyphal and yeastlike development of Mucor racemosus and M. rouxii were demonstrated under 100% N2. Under standardized conditions in yeast extract-peptone-glucose medium, the morphology depended on the N2 flow rate and not on the glucose concentration. The effect was related to the rate of flushing of the atmosphere over the culture medium. The results indicate that a volatile compound produced by Mucor is involved in morphogenesis.
The interactions of the 936-species phages sk1, jj50, and 64 with the cell surface of Lactococcus lactis LM0230 were analyzed. Cell envelopes (walls + plasma membrane), cell wall, or plasma membrane from L. lactis ssp. lactis LM0230 each inactivated the phages in vitro. However, other 936-species phages kh and P008, which do not infect strain LM0230, were not inactivated by any of the subcellular fractions. Treating cell walls or plasma membrane with the cell wall hydrolase mutanolysin eliminated inactivation of phage sk1. This suggested that intact cell wall fragments were required for inactivation. A role for plasma membrane in phage sk1 inactivation was further investigated. Boiling, washing in 2 M KCl, 8 M urea, or 0.1 M Na(2)CO(3)/pH 11, or treating the plasma membrane with proteases did not reduce adsorption or inactivation of phage. Adding lipoteichoic acid or antibodies to lipoteichoic acid did not reduce inactivation of phage in a mixture with membrane, suggesting that lipoteichoic acid was not involved. Inactivation by envelopes or cell wall correlated with ejection of DNA from the phage sk1 capsid. Although calcium is required for plaque formation, it was not required for adsorption, inactivation, or ejection of phage DNA by envelopes or cell wall. The results suggest that at least for phages sk1, jj50, and 64, adsorption and phage DNA injection into the host does not require a host membrane protein or lipoteichoic acid, and that cell wall components are sufficient for these initial steps of phage infection.
The amino acid sequence of the phage infection protein (Pip) of Lactococcus lactis predicts a multiple-membrane-spanning region, suggesting that Pip may be anchored to the plasma membrane. However, a near-consensus sortase recognition site and a cell wall anchoring motif may also be present near the carboxy terminus. If functional, this recognition site could lead to covalent linkage of Pip to the cell wall. Pip was detected in both plasma membranes and envelopes (plasma membrane plus peptidoglycan) isolated from the wild-type Pip strain LM2301. Pip was firmly attached to membrane and envelope preparations and was solubilized only by treatment with detergent. Three mutant Pip proteins were separately made in which the multiple-membrane-spanning region was deleted (Pip-Deltammsr), the sortase recognition site was converted to the consensus (Pip-H841G), or the sortase recognition site was deleted (Pip-Delta6). All three mutant Pip proteins co-purified with membranes and could not be solubilized except with detergent. When membranes containing Pip-Deltammsr were sonicated and re-isolated by sucrose density gradient centrifugation, Pip-Deltammsr remained associated with the membranes. Strains that expressed Pip-H841G or Pip-Delta6 formed plaques with near unit efficiency, whereas the strain that expressed Pip-Deltammsr did not form plaques of phage c2. Both membranes and cell-free culture supernatant from the strain expressing Pip-Deltammsr inactivated phage c2. These results suggest that Pip is an integral membrane protein that is not anchored to the cell wall and that the multiple-membrane-spanning region is required for productive phage infection but not phage inactivation.
The T4 gene 23 product (gp23) encodes the major structural protein of the mature capsid. Mutations in this gene have been described which disrupt the normal length-determining mechanism (A. H. Doermann, F. A. Eiserling, and L. Boehner, J. Virol. 12:374-385, 1973). Mutants which produce high levels of petite and giant phage (ptg) are restricted to three tight clusters in gene 23 (A.
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