Peptidoglycan recognition proteins: modulators of the microbiome and inflammation

All animals, including humans, live in symbiotic association with microorganisms. The immune system accommodates host colonization by the microbiota, maintains microbiota-host homeostasis and defends against pathogens. This Review analyses how one family of antibacterial pattern recognition molecules - the peptidoglycan recognition proteins - has evolved a fascinating variety of mechanisms to control host interactions with mutualistic, commensal and parasitic microorganisms to benefit both invertebrate and vertebrate hosts.     

Peptidoglycan recognition proteins of the innate immune system

Peptidoglycan (PGN) is the major component of bacterial cell walls and one of the main microbial products recognized by the innate immune system. PGN recognition is mediated by several families of pattern recognition molecules, including Toll-like receptors, nucleotide-binding oligomerization domain-containing proteins, and peptidoglycan recognition proteins (PGRPs). However, only the interaction of PGN with PGRPs, which are highly conserved from insects to mammals, has so far been characterized at the molecular level. Here, we describe recent structural studies of PGRPs that reveal the basis for PGN recognition and provide insights into the signal transduction and antibacterial activities of these innate immune proteins.     

昆虫肽聚糖识别蛋白研究进展

在脊椎动物和非脊椎动物中,识别非己是天生免疫反应中的第一步。肽聚糖是细菌细胞壁的必需成分,属于进化上保守的微生物表面病原相关分子模式(pathogen-associated molecular pattern, PAMP),可以被模式识别蛋白(pattern recognition proteins, PRRs)如肽聚糖识别蛋白(peptidoglycan recognition proteins, PGRPs)识别。 在昆虫的天生免疫系统中,有些PGRPs能够利用细菌独有的肽聚糖识别入侵细菌,并将细菌入侵信号传递给下游的抗菌肽(antimicrobial peptide, AMP)合成途径,启动抗菌肽基因的转录及合成;PGRPs对肽聚糖的识别也会启动酚氧化酶原途径的激活,引起黑化反应。有些具有酰胺酶活性的PGRPs可以促进吞噬作用;有些可以抑制抗菌肽合成以减弱过度免疫反应带来的损伤。还有一些PGRPs作为效应因子直接作用于细菌将细菌杀死。本文主要从昆虫PGRPs作为识别受体(recognition receptor)、调节子(regulator)和效应因子(effector) 3个方面进行了综述,并分析了目前PGRPs研究中仍不清楚的问题和未来研究的方向。     

Peptidoglycan recognition proteins are a new class of human bactericidal proteins

Skin and mucous membranes come in contact with external environment and protect tissues from infections by producing antimicrobial peptides. We report that human peptidoglycan recognition proteins 3 and 4 (PGLYRP3 and PGLYRP4) are secreted as 89-115-kDa disulfide-linked homo- and heterodimers and are bactericidal against several pathogenic and nonpathogenic transient, but not normal flora, Gram-positive bacteria. PGLYRP3 and PGLYRP4 are also bacteriostatic toward all other tested bacteria, which include Gram-negative bacteria and normal flora Gram-positive bacteria. PGLYRP3 and PGLYRP4 are also active in vivo and protect mice against experimental lung infection. In contrast to antimicrobial peptides, PGLYRPs kill bacteria by interacting with their cell wall peptidoglycan, rather than permeabilizing their membranes. PGLYRP3 and PGLYRP4 are expressed in the skin, eyes, salivary glands, throat, tongue, esophagus, stomach, and intestine. Thus, we have identified the function of mammalian PGLYRP3 and PGLYRP4, and show that they are a new class of bactericidal and bacteriostatic proteins that have different structures, mechanism of actions, and expression patterns than antimicrobial peptides.     

Targeting effectors: the molecular recognition of Type III secreted proteins

The Type III secretion system (TTSS) facilitates the export of effector proteins from pathogenic and symbiotic Gram-negative bacteria into the cytosol of eukaryotic host cells. The current functional and evolutionary knowledge on the molecular recognition of TTSS substrates and computational models of the secretion signal are discussed in this review.     

Peptidoglycan recognition proteins: a novel family of four human innate immunity pattern recognition molecules.

The innate immune system recognizes microorganisms through a series of pattern recognition receptors that are highly conserved in evolution. Insects have a family of 12 peptidoglycan recognition proteins (PGRPs) that recognize peptidoglycan, a ubiquitous component of bacterial cell walls. We report cloning of three novel human PGRPs (PGRP-L, PGRP-Ialpha, and PGRP-Ibeta) that together with the previously cloned PGRP-S, define a new family of human pattern recognition molecules. PGRP-L, PGRP-Ialpha, and PGRP-Ibeta have 576, 341, and 373 amino acids coded by five, seven, and eight exons on chromosomes 19 and 1, and they all have two predicted transmembrane domains. All mammalian and insect PGRPs have at least three highly conserved C-terminal PGRP domains located either in the extracellular or in the cytoplasmic (or in both) portions of the molecules. PGRP-L is expressed in liver, PGRP-Ialpha and PGRP-Ibeta in esophagus (and to a lesser extent in tonsils and thymus), and PGRP-S in bone marrow (and to a lesser extent in neutrophils and fetal liver). All four human PGRPs bind peptidoglycan and Gram-positive bacteria. Thus, these PGRPs may play a role in recognition of bacteria in these organs.     

Peptidoglycan recognition proteins kill bacteria by activating protein-sensing two-component systems

Mammalian peptidoglycan recognition proteins (PGRPs), similar to antimicrobial lectins, bind the bacterial cell wall and kill bacteria through an unknown mechanism. We show that PGRPs enter the Gram-positive cell wall at the site of daughter cell separation during cell division. In Bacillus subtilis, PGRPs activate the CssR-CssS two-component system that detects and disposes of misfolded proteins that are usually exported out of bacterial cells. This activation results in membrane depolarization, cessation of intracellular peptidoglycan, protein, RNA and DNA synthesis, and production of hydroxyl radicals, which are responsible for bacterial death. PGRPs also bind the outer membrane of Escherichia coli and activate the functionally homologous CpxA-CpxR two-component system, which kills the bacteria. We exclude other potential bactericidal mechanisms, including inhibition of extracellular peptidoglycan synthesis, hydrolysis of peptidoglycan and membrane permeabilization. Thus, we reveal a previously unknown mechanism by which innate immunity proteins that bind the cell wall or outer membrane exploit the bacterial stress defense response to kill bacteria.     

Peptidoglycan recognition proteins involved in 1,3-beta-D-glucan-dependent prophenoloxidase activation system of insect

The prophenoloxidase (proPO) cascade is a major innate immune response in invertebrates, which is triggered into its active form by elicitors, such as lipopolysaccharide, peptidoglycan, and 1,3-beta-D-glucan. A key question of the proPO system is how pattern recognition proteins recognize pathogenic microbes and subsequently activate the system. To investigate the biological function of 1,3-beta-D-glucan pattern recognition protein in the proPO cascade system, we isolated eight different 1,3-beta-D-glucan-binding proteins from the hemolymph of large beetle (Holotrichia diomphalia) larvae by using 1,3-beta-D-glucan immobilized column. Among them, a 20- and 17-kDa protein (referred to as Hd-PGRP-1 and Hd-PGRP-2) show high sequence identity with the short forms of peptidoglycan recognition proteins (PGRPs-S) from human and Drosophila melanogaster. To be able to characterize the biochemical properties of these two proteins, we expressed them in Drosophila S2 cells. Hd-PGRP-1 and Hd-PGRP-2 were found to specifically bind both 1,3-beta-D-glucan and peptidoglycan. By BIAcore analysis, the minimal 1,3-beta-D-glucan structure required for binding to Hd-PGRP-1 was found to be laminaritetraose. Hd-PGRP-1 increased serine protease activity upon binding to 1,3-beta-D-glucan and subsequently induced the phenoloxidase activity in the presence of both 1,3-beta-D-glucan and Ca(2+), but no phenoloxidase activity was elicited under the same conditions in the presence of peptidoglycan and Ca(2+). These results demonstrate that Hd-PGRP-1 can serve as a receptor for 1,3-beta-D-glucan in the insect proPO activation system.     

Viral security proteins: counteracting host defences

Interactions with host defences are key aspects of viral infection. Various viral proteins perform counter-defensive functions, but a distinct class, called security proteins, is dedicated specifically to counteracting host defences. Here, the properties of the picornavirus security proteins L and 2A are discussed. These proteins have well-defined positions in the viral polyprotein, flanking the capsid precursor, but they are structurally and biochemically unrelated. Here, we consider the impact of these two proteins, as well as that of a third security protein, L(*), on viral reproduction, pathogenicity and evolution. The concept of security proteins could serve as a paradigm for the dedicated counter-defensive proteins of other viruses.     

Complement C1q-target proteins recognition is inhibited by electric moment effectors

Classical complement pathway is an important innate immune mechanism, which is usually triggered by binding of C1q to immunoglobulins, pentraxins and other target molecules. Although the activation of the classical pathway is crucial in the host defence, its undesirable and uncontrolled activation can lead to tissue damage. Thus, understanding the molecular basis of complement activation and its inhibition are of great biomedical importance. Recently, we proposed a mechanism for target recognition and classical pathway activation by C1q, which is likely governed by calcium-controlled reorientation of macromolecular electric moment vectors. Here we sought to define the mechanism of C1q inhibition by low molecular weight disulphate compounds that bind to the globular (gC1q) domain, using experimental, computational docking and theoretical modelling approaches. Our experimental results demonstrate that betulin disulphate (B2S) and 9,9-bis(4'-hydroxyphenyl)fluorene disulphate (F2S) inhibit the interaction of C1q and its recombinant globular modules with target molecules IgG1, C-reactive protein (CRP) and long pentraxin 3 (PTX3). In most C1q-inhibitor docked complexes, there is a reduction of electric moment scalar values and similarly altered direction of electric/dipole moment vectors. This could explain the inhibitory effect by impaired electrostatic steering, lacking optimal target recognition and formation of functional complex. In the presence of the inhibitor, the tilt of gC1q domains is likely to be blocked by the altered direction of the electric moment vector. Thus, the transition from the inactive (closed) towards the active (open) conformation of C1q (i.e. the complement activation signal transmission) will be impaired and the cascade initiation disrupted. These results could serve as a starting point for the exploration of a new form of 'electric moment inhibitors/effectors'.     

Peptidoglycan recognition proteins-maintaining immune homeostasis and normal development

Peptidoglycan recognition proteins (PGRPs) are innate immune molecules with a diverse array of functions. In this issue of Cell Host & Microbe, Maillet and colleagues demonstrate that a Drosophila PGRP, PGRP-LF, functions as a negative regulator of the Drosophila immune deficiency (IMD) pathway, an innate immune signaling mechanism responsive to Gram-negative bacteria. PGRP-LF deficiency results in unregulated immune signaling, causing excessive antimicrobial peptide synthesis and, surprisingly, developmental defects.     

The aldehyde hypothesis: metabolic intermediates as antimicrobial effectors

There are many reactive intermediates found in metabolic pathways. Could these potentially toxic molecules be exploited for an organism''s benefit? We propose that during certain microbial infections, the production of inherently reactive aldehydes by an infected host is a previously unappreciated innate immune defence mechanism. While there has been a significant focus on the effects of aldehydes on mammalian physiology, the idea that they might be exploited or purposefully induced to kill pathogens is new. Given that aldehydes are made as parts of metabolic programmes that accompany immune cell activation by the cytokine interferon-gamma (IFN-γ) during infections, we hypothesize that aldehydes are among the arsenal of IFN-γ-inducible effectors needed for pathogen control.     

Peptidoglycan recognition protein LF: a negative regulator of Drosophila immunity

Peptidoglycan recognition proteins (PGRPs) play important roles in the innate immune defence. Each PGRP detects a distinct subset of peptidoglycans and initiate immune signalling or enzymatic degradation of peptidoglycans. Here we characterize one of the 13 Drosophila PGRPs, PGRP-LF. PGRP-LF is membrane bound and has its two PGRP domains, z and w, localized outside the cell. Our data demonstrate that the z-and w-domain differ in their affinities to peptidoglycan. The z-domain has affinity to several groups of peptidoglycans while the w-domain only recognizes peptidoglycan from Escherichia coli. In addition, we observed that overexpression of PGRP-LF in Drosophila melanogaster Schneider 2 cells (S2 cells) promotes aggregation of cells. Furthermore, following immune stimulation of S2 cells overexpressing PGRP-LF, we noticed a reduced up-regulation of expression of antimicrobial peptide genes, in consonance with an immune suppressive role for PGRP-LF.     

Unmasking immune sensing of retroviruses: Interplay between innate sensors and host effectors

Retroviruses can selectively trigger an array of innate immune responses through various PRR. The identification and the characterization of the molecular basis of retroviral DNA sensing by the DNA sensors IFI16 and cGAS has been one of the most exciting developments in viral immunology in recent years. DNA sensing by these cytosolic sensors not only leads to the initiation of the type I interferon (IFN) antiviral response and the induction of the inflammatory response, but also triggers cell death mechanisms including pyroptosis and apoptosis in retrovirus-infected cells, thereby providing important insights into the pathophysiology of chronic retroviral infection. Host restriction factors such as SAMHD1 and Trex1 play important roles in regulating innate immune sensing, and have led to the idea that innate immune defense and host restriction actually converge at different levels to determine the outcome of retroviral infection. In this review, we discuss the sensing of retroviruses by cytosolic DNA sensors, the relevance of host factors during retroviral infection, and the interplay between host factors and the innate antiviral response in different cell types, within the context of two human pathogenic retroviruses – human immunodeficiency virus (HIV-1) and human T cell-leukemia virus type I (HTLV-1).     

Molecular sensors for plant immunity; pattern recognition receptors and race-specific resistance proteins

Plants have to molecularly sense invasions from pathogenic microbes to activate their built-in immune responses. There are two different types of sensor proteins, called immune receptors. They are the indispensible molecular instruments to perceive non-self molecules derived from microbes. A genetic defect of the immune receptors fails to activate immune responses, consequently resulting in disease susceptibility. In general, membrane-bound immune receptors, known to be pattern recognition receptors and exposed on the outside of the cell, recognize microbe-associated molecular patterns from pathogens. Intracellular immune receptors, also called plant disease resistance proteins, directly perceive pathogen-derived effectors or indirectly recognize the effector-mediated modification of host proteins inside the cells. In this review, we introduce the classes and functions of pattern recognition receptors that were molecularly identified so far. Additionally, we summarize recent progresses in structural functions and molecular dynamics of the plant disease resistance proteins.     

G proteins, effectors and GAPs: structure and mechanism

G proteins form a diverse family of regulatory GTPases which, in the GTP-bound state, bind to and activate downstream effectors. Structure of Ras homologs bound to effector domains have revealed mechanisms by which G proteins couple GTP binding to effector activation and achieve specificity. Complexes between structurally unrelated GTPase-activating proteins with complementary G proteins suggest common mechanisms by which GTP hydrolysis is stimulated via direct interactions with conformationally labile switch regions of the G protein.     

The role of cationic antimicrobial peptides in innate host defences

Cationic antimicrobial peptides are found in all living species. A single animal can contain >24 different antimicrobial peptides, which fall into four structural classes. These peptides are produced in large quantities at sites of infection and/or inflammation and can have broad-spectrum antibacterial, antifungal, antiviral, antiprotozoan and antisepsis properties. In addition, they interact directly with host cells to modulate the inflammatory process and innate defences.     

Feather micro-organisms and uropygial antimicrobial defences in a colonial passerine bird

1.  The relationship between the composition of communities of micro-organisms and their hosts remains poorly understood. We conducted extensive field studies of feather-degrading bacteria, other cultivable bacteria, and fungi on the plumage of a migratory bird, the barn swallow Hirundo rustica Linnaeus, to understand the association between micro-organisms, host sociality and host antimicrobial defences, as reflected by the size of the uropygial gland.
2.  The abundance of feather-degrading bacteria, but not other cultivable bacteria or fungi, decreased with increasing size of the uropygial gland.
3.  Females had more feather-degrading bacteria than males.
4.  Barn swallows living in larger colonies had more feather-degrading bacteria than less social conspecifics.
5.  These findings suggest that the uropygial gland plays a specific role in regulating the abundance of feather-degrading bacteria that furthermore depends on the social environment of the host.