Håkan Steiner

Monomeric and Polymeric Gram-Negative Peptidoglycan but Not Purified LPS Stimulate the Drosophila IMD Pathway

Insects depend solely upon innate immune responses to survive infection. These responses include the activation of extracellular protease cascades, leading to melanization and clotting, and intracellular signal transduction pathways inducing antimicrobial peptide gene expression. In Drosophila, the IMD pathway is required for antimicrobial gene expression in response to gram-negative bacteria. The exact molecular component(s) from these bacteria that activate the IMD pathway remain controversial. We found that highly purified LPS did not stimulate the IMD pathway. However, lipid A, the active portion of LPS in mammals, activated melanization in the silkworm Bombyx morii. On the other hand, the IMD pathway was remarkably sensitive to polymeric and monomeric gram-negative peptidoglycan. Recognition of peptidoglycan required the stem-peptide sequence specific to gram-negative peptidoglycan and the receptor PGRP-LC. Recognition of monomeric and polymeric peptidoglycan required different PGRP-LC splice isoforms, while lipid A recognition required an unidentified soluble factor in the hemolymph of Bombyx morii.

A scavenger function for a Drosophila peptidoglycan recognition protein

Recent studies of peptidoglycan recognition protein (PGRP) have shown that 2 of the 13 Drosophila PGRP genes encode proteins that function as receptors mediating immune responses to bacteria. We show here that another member, PGRP-SC1B, has a totally different function because it has enzymatic activity and thereby can degrade peptidoglycan. A mass spectrometric analysis of the cleavage products demonstrates that the enzyme hydrolyzes the lactylamide bond between the glycan strand and the cross-linking peptides. This result assigns the protein as anN-acetylmuramoyl-l-alanine amidase (EC3.5.1.28), and the corresponding gene is thus the first of this class to be described from a eukaryotic organism. Mutant forms of PGRP-SC1B lacking a potential zinc ligand are enzymatically inactive but retain their peptidoglycan affinity. The immunostimulatory properties of PGRP-SC1B-degraded peptidoglycan are much reduced. This is in striking contrast to lysozyme-digested peptidoglycan, which retains most of its elicitor activity. This points toward a scavenger function for PGRP-SC1B. Furthermore, a sequence homology comparison with phage T7 lysozyme, also an N-acetylmuramoyl-l-alanine amidase, shows that as many as six of the Drosophila PGRPs could belong to this class of proteins.

Binding and action of cecropin and cecropin analogues: antibacterial peptides from insects.

The mechanism of action of cecropin was studied by using liposomes as a model system. The bilayer was efficiently destroyed if the liposome net charge was zero or negative. Cecropin analogues with an impaired N-terminal helix had reduced membrane disrupting abilities that correlate with their lower antibacterial activity. The reduced bactericidal activity of the analogues was rationalized in terms of reduced binding to bacteria. The stoichiometry of cecropin killing of bacteria suggests that amounts of cecropin sufficient to form a monolayer strongly modify the bacterial membrane. Although some bacteria were resistant to cecropin they did bind large amounts in a non-productive manner. In contrast, mammalian erythrocytes achieve resistance by avoiding the binding of cecropin.

Peptidoglycan recognition proteins: on and off switches for innate immunity

Summary:  Insects rely on innate immune mechanisms to defend themselves against microbes. The inducible anti‐microbial peptides constitute an important arm of this defense. In Drosophila, the Toll and the Imd pathways are the major routes to induce the peptides, and it has become clear that to a certain extent, these pathways can discriminate between different microbes and mount an appropriate response to eliminate the intruder. This review discusses the proteins responsible for this discriminatory recognition, the peptidoglycan recognition proteins (PGRPs). The serum protein PGRP‐SA triggers a humoral cascade of proteases upon infection by certain gram‐positive bacteria to activate the Toll pathway. The membrane‐bound receptor PGRP‐LC activates the Imd pathway in response to certain gram‐ negative bacteria or their peptidoglycans. Other PGRPs have enzymatic activity, cleaving lactylamide bonds in peptidoglycan to eliminate its immunogenicity, thus turning off the immune response. The PGRP family is conserved from insects to man. Short mammalian PGRP variants are synthesized in neutrophils and stored in granules. These PGRPs seem to influence the survival of phagocytosed non‐pathogenic bacteria. Long PGRP variants are expressed in the liver and secreted into the bloodstream where their peptidoglycan‐degrading activity might serve scavenger functions.

A mammalian peptidoglycan recognition protein with N-acetylmuramoyl-L-alanine amidase activity

The family of peptidoglycan recognition proteins (PGRPs) is conserved from insects to mammals. Recently, Drosophila PGRP-SC1B was demonstrated to be an N-acetylmuramoyl-L-alanine amidase (NAMLAA), an enzyme that cleaves the lactylamide bond between muramic acid and the peptide chain in peptidoglycan (PGN). We now show an M x mPGRP-L mRNA to be expressed in the liver. The recombinant M x mPGRP-L protein has NAMLAA activity and degrades PGN from both Escherichia coli and Staphylococcus aureus; however, the Gram-positive PGN was a better substrate after lysozyme treatment. The activity of M x mPGRP-L was further analysed using Bordetella pertussis tracheal toxin as a substrate. Cleavage products were separated on HPLC and identified using mass spectrometry. From these results we conclude that M x mPGRP-L has activity and other properties identifying it as the NAMLAA protein present in mammalian sera.

Secondary structure of the cecropins: antibacterial peptides from the moth Hyalophora cecropia

The existence of an inducible humoral immune system in insects has been long known (review [ 11). Apart from the presence of lysozyme activity the molecular basis for the killing of bacteria was unknown until cecropins A and B from Hyalophom cecropia were isolated [2]. They were shown to be 2 small, basic peptides that could kill and lyse a variety of Gram-positive and Gram-negative bacteria. The amino acid sequences of the cecropins contained a basic Nterminal and a more hydrophobic central part [3]. A synthetic peptide with a sequence similar to residues l-33 in cecropin A has been shown to have almost full anti-bacterial activity . were prepared by sonicating a thin-film of phospholipids with 2.5 mM Na-phosphate buffer (8.5 mg lipid/ml) until the solution became almost clear. ‘H NMR spectra were recorded on a Brucker WH270 Fourier Transform Spectrometer.

A humoral stress response in Drosophila.

The ability to react to unfavorable environmental changes is crucial for survival and reproduction, and several adaptive responses to stress have been conserved during evolution [1-3]. Specific immune and heat shock responses mediate the elimination of invading pathogens and of damaged proteins or cells [4-6]. Furthermore, MAP kinases and other signaling factors mediate cellular responses to a very broad range of environmental insults [7-9]. Here we describe a novel systemic response to stress in Drosophila. The Turandot A (TotA) gene encodes a humoral factor, which is secreted from the fat body and accumulates in the body fluids. TotA is strongly induced upon bacterial challenge, as well as by other types of stress such as high temperature, mechanical pressure, dehydration, UV irradiation, and oxidative agents. It is also upregulated during metamorphosis and at high age. Strikingly, flies that overexpress TotA show prolonged survival and retain normal activity at otherwise lethal temperatures. Although TotA is only induced by severe stress, it responds to a much wider range of stimuli than heat shock genes such as hsp70 or immune genes such as Cecropin A1.

Humoral Immunity in Cecropia Pupae

There are four main reasons to study the factors which in nature regulate the equilibrium between insects and bacteria. Each of these reasons is of such a nature that it could be the subject for a review of its own. However, we will not elaborate but only state the arguments briefly as follows: 1. More than 106 insect species have been described and the number of individuals has been estimated to be as large as 1018 (Wiggelsworth 1968). These high numbers show that during evolution insects have been extremely successful in the competition with other forms of life. Thus, from these numbers alone one would predict that insects are successful in dealing with infections, since otherwise they would not be so numerous.

Purification of the prophenoloxidase from Hyalophora cecropia and four proteins involved in its activation

Abstract Prophenoloxidase (PPO) has been purified to homogeniety from hemolymph of Hyalophora cecropia . There are two forms of the enzyme with identical molecular weights (76 kDa). Four proteins directly involved in the activation of PPO have also been purified from the hemolymph. Active phenoloxidase is elicited by the addition of factor C1 and a serine protease (SPII), which alone cannot activate PPO. Purified SPII contains two proteins with M r 43 and 53 kDa, the larger molecule may represent the unactivated enzyme. An inhibitor of the SPII catalyzed activation of PPO has been isolated. In addition a protein presumed to be dopa quinone imine conversion factor has been purified.

PCR differential display of immune gene expression in Trichoplusia ni

The immune state of insects is defined by a set of proteins that is absent in the naive state. To explore the immune system of Trichoplusia ni in more detail we have employed a PCR differential display technique to compare the mRNA population of untreated last instar larvae to that of immunized animals. In the primary display, more than one hundred bands seemed induced upon bacterial challenge. When they were used as probes in Northern blots, 35% of these probes detected inducible mRNA species. Such probes were used to screen a cDNA library from immunized larvae. We isolated clones for T. ni homologs of cecropin A, lysozyme and attacin. One differentially expressed band hybridized to clones for BJHSP1, a hemacy-anin-related protein which is hormonally up-regulated in last instar larvae; this induction is probably not related to the bacterial infection. Still other probes recognized inducible mRNAs of 1.6 and 1.0 kb. The corresponding cDNA clones did not show strong sequence homology to any known proteins. We have demonstrated the potential of this PCR technique to display both known and unknown genes specific for the immune state of whole insects against a background of genes involved in larval development.