Common symbiosis signaling pathway

The common symbiosis signaling pathway occurs within plant root cells. It links the perception of fungal or bacterial signals to plant transcriptional responses required for accommodation of the symbiont via arbuscule or nodule formation. Myc factors or Nod factors are perceived by LysM receptor-like kinases at the plant plasma membrane, triggering downstream signaling through additional proteins such as SYMRK. The signal is then transduced to the nucleus, where it generates nuclear calcium oscillations via ion channels and nucleoporins. These calcium signals are decoded by the calcium- and calmodulin-dependent protein kinase CCaMK, which activates transcription factors such as CYCLOPS. CYCLOPS is generally considered the final component of the canonical CSSP. At this point in nodulation or AMF colonisation, downstream responses diverge depending on the symbiosis, with CYCLOPS regulating genes that control the formation of either arbuscules or nodules. ==Pre-Contact Signaling==

Chemical signaling between plants and symbiotic microorganisms begins prior to physical contact. In arbuscular mycorrhizal symbiosis, host plants synthesize and secrete strigolactones into the rhizosphere, which stimulate hyphal branching and directional growth of fungi towards the root Strigolactone biosynthesis occurs mainly in plastids, through the action of enzymes including D27 (Rice DWARF 27; Arabidopsis ortholog ATD27), an iron-binding beta-carotene isomerase. In addition to strigolactones, other signaling molecules contribute to pre-contact communication in AMF symbiosis. The transporter protein NOPE1 ('NO PERCEPTION 1') is also required for AMF colonisation in rice and maize, and appears to function as part of a parallel signaling mechanism. NOPE1 is a member of the major facilitator superfamily of transport proteins. It imports N-acetylglucosamine (GlcNAc), a fungal-derived molecule, into plant cells, allowing them to detect the presence of nearby fungi. NOPE1 is involved in the production of root exudates that induce fungal transcription, but whether it directly exports signaling molecules or acts indirectly via GlcNAc uptake and downstream signaling remains unresolved. Internal plant signaling pathways upstream of the CSSP are also important for symbiosis. D14L/KAI2 is an α/β-hydrolase receptor which perceives endogenous karrikin-like molecules (KLs). KLs, associated with phosphate starvation responses, trigger D14L and D3-mediated degradation of SMAX1. Removal of SMAX1 derepresses genes required for the CSSP, including the LysM receptor-like kinases (RLKs) that detect the fungal/bacterial signal and initiate the CSSP. Pre-contact signaling ultimately enables the perception of fungal or bacterial signals by plant receptor-like kinases, leading to activation of the common symbiosis signaling pathway. ==Perception==

File:MycRi-IV_(C16-0,S).svg|alt=chemical structure of a LipoChitoOligosaccharide molecule|thumb|323x323px|The chemical structure of MycRi-IV (C16:0,S), a Myc factor of Rhizophagus irregularis as indicated in 'Maillet, F et al.' (2011) "Fungal lipochitooligosaccharide symbiotic signals in arbuscular mycorrhiza." Nature 469:58–63.The factor was first identified by Fabienne Maillet and coworkers in a groundbreaking work published in Nature, where they have extracted three hundred litre mycorrhized carrot roots and exudates from 40 million germinating spores of Rhizophagus irregularis and purified the active fraction. They demonstrated this active principle is lipo-chito-oligosaccharide in nature. There are two main type of root symbiosis; one is root nodule symbiosis by Rhizobia (RN-type) and another is Arbuscular Mycorrhiza (AM-type). There are common genes involved in between these two pathways. these key common components, form the Common Symbiosis pathway (CSP or CSSP). The perception of the presence of the fungal symbiont takes place mainly through fungal chemical secretions generally termed as Myc-factors. Receptors for Myc-factors are yet to be identified. However, DMI2/SYMRK probably acts as a co-receptor of Myc factor receptor (MFR). The AM fungal secreted materials relevant to symbiosis are Myc-LCOs, Myc-COs, N-Acetylglucosamine Fungal Molecules that triggers CSSP Myc-LCOs (lipochitooligosaccharides) Like Rhizobial LCOs (Nod factors); Myc-LCOs play important role in perception stage. They are a kind of secreted compounds from AM fungi, mainly mixtures of lipo-chito-oligosaccharides (Myc-LCOs). In Lotus japonicus, LYS11, a receptor for LCOs, was expressed in root cortex cells associated with intra-radical colonizing arbuscular mycorrhizal fungi Cell Surface Receptors There are multiple families of pattern recognition receptors and co-receptors involved in recognition of microbial pathogens and symbionts. Some of the relevant families involved in CSSP, are Membrane bound LysMs (LYM), Soluble LysM Receptor like Protein, LYK (LysM receptors with active Kinase domain), LYR (LysM proteins with inactive kinase domain), etc. Seemingly, different combinations of a LYK and LYR receptors perceive and generate differential signals, such as some combinations generate a pathogen recognition signal whereas some combinations generate symbiotic signals. Receptor-like Kinases (RLKs) DMI2/ SYMRK is a receptor-like kinase, an important protein in endosymbiosis signal perception, reported in several plants (Mt-DMI2 or Mt-NORK in Medicago truncatula; Lj-SYMRK in Lotus japonicas; Ps-SYM19 in Pisum sativum; OsSYMRK in Rice). OsSYMRK lacks an N-terminal domain and exclusively regulate AM symbiosis (is not involved in the RN symbiosis). LysM receptor-like kinase Lysin Motif (LysM) receptor-like kinase are a subfamily related to membrane bound Receptor-like kinase (RLKs) with an extracellular region consisting of 3 Lysine motifs. They have some important orthologs in different plants, that vary in their function. In some plant species they are involved in AM symbiosis, in others they are not. Tomato (Solanum lycopersicum), a non-legume eudicot, also have a similar LysM receptor, SlLYK10 that Promotes AM symbiosis. There are some co-receptors of Myc-factor receptor viz., OsCEBiP in Rice, a LysM membrane protein can function as a co-receptor of OsCERK1 but it participates in a different pathway. Most of these kinases are serine/threonine kinases, some are tyrosine kinases. Also, they are type-1 transmembrane proteins, that indicates their N-terminal domain towards the outside of the cell, and the C-terminal domain is towards inside of the cell. ==Transmission==

The transmission of signal cascades into the nucleus is not well understood. However, this transmission includes carrying the message up to the nuclear membrane and generation of a calcium wave. Some elements involved in this process are: Nucleoporins Lotus japonicus Nucleoporins LjNUP85 and LjNUP133 has potential role in transmission of the signal. Lj-NENA is another important nucleoporin that plays role in AM symbiosis. HMGR and Mevalonate. It has been proposed that the enzyme 3-hydroxy-3-methylglutaryl-CoA reductase (HMG CoA reductase or HMGR) has potential role in the transmission stage. The enzyme is activated by SYMRK/DMI2, and forms mevalonate. This mevalonate acts as a second messenger, and activates a nuclear potassium channel, DMI1 or POLLUX. Nuclear membrane cation channels. The nuclear calcium channel CNGC15, which is cyclic nucleotide gated ion channel; mediates the symbiotic nuclear Ca2+ influx, and it is countered by K+ efflux by DMI1. ==Transcription==

Calmodulin is a widespread regulatory protein that functions along with Ca2+ in various biological processes. In AM symbiosis signalling, it modulates CCaMK. There are two DELLA proteins in Medicago truncatula and Pisum sativum that play a role in symbiosis whereas in rice only one DELLA protein fulfils this task. protein whose gene is directly regulated by DELLA and CCaMK/ CYCLOPS. WRKY transcription factor genes are thought to play very important roles in establishment of mycorrhizal symbiosis and they perhaps work through regulating plant defense genes. ==The Accommodation program==

Root cortex cells experience important changes in order to accommodate for the fungal endosymbiont. The pre-penetration apparatus (PPA) in outer cell layers and the peri-arbuscular membrane that surrounds arbuscules in inner cell layers need to be formed and the plant cell cytoplasm needs to rearrange, Genes and proteins playing a role in the accommodation programme Although various proteins have been identified which may play role on how this accommodation process occurs, the detailed signalling cascade is not fully understood. Some of the proteins and mechanisms involved in the deposition on peri-arbuscular membrane are EXOCYST complex, EXO70 subunit, a symbiosis-specific splice variant of SYP132, VAPYRIN, and two variants of VAMP721. and ABC transporter STR/STR2 are putatively involved in the synthesis and supplying of a lipid 16:0 β-monoacylglycerol to the AM fungi. Recently discovered kinases that regulate the AMF accommodation program include ADK1, AMK8, AMK24, ARK1 and ARK2. The protein composition of the peri-arbuscular membrane is very different from that of the plasma membrane. It includes some special transporters such as phosphate transporters (Mt-PT4, Os-PT11, Os-PT13) and ammonium transporters (Mt-AMT2 and 3). It also includes ABC transporters such as STR/STR2 putatively involved in lipid transport. == Evolutionary significance ==

AM fungi and plants co-evolved and developed a very complex interaction that allow the plant accommodate the AM-fungal host. It has been proposed that the RN symbiosis has originated from the AM symbiosis. ==See also==