Table 1.
Identified effector–immunity pairs.
| E–I Pairs | Organisms | Effector Activity | Paper Highlights | Citation |
|---|---|---|---|---|
| Cell wall Targeting | ||||
| Tse1, 3/Tsi1, 3 | P. aeruginosa | Amidase (Tse1), Muramidase(Tse3) | Tse1, 3 hydrolyze PG and Tsi1, 3 are the immunity proteins | [32] |
| Tse1(Tae1)/Tsi1(Tai1) | P. aeruginosa | Amidase | Analyzed the crystal structures of Tse1 and Tse1/Tsi1 complex | [39] |
| Tse3(Tge1)/Tsi3(Tgi1) | P. aeruginosa | Hydrolyse PG | Revealed a calcium-dependent membrane-binding mechanism | [43] |
| Tae1–4/Tai1–4 | B. thailandensis | Amidase | Defined the Tae superfamily | [14] |
| Tae3/Tai3 | R. pickettii | Amidase | Analyzed the structures of Tae3, Tai3 and Tae3/Tai3 complex | [42] |
| Tae4/Tai4 | E. cloacae, S. Typhimurium | DL-endopeptidase | Analyzed the structure of Tae4/Tai4 | [33] |
| Proved the cross-immunity of T6SS E–I pairs | [44] | |||
| Tae4/Tai4 | S. Typhimurium | Muramidase | Tae4 contributes to bacteria competition and infection | [45] |
| Tae/Tai | A. tumefaciens | Target the PG | Indentified Tae/Tai pairs | [58] |
| VgrG3/TsaB(TsiV3) | V. cholerae | Degrade PG | Identified the VgrG-3 and the antitoxin TsaB | [18] |
| Analyzed the structures of native TsaB and the VgrG3C-TsaB complex | [37] | |||
| VgrG3/TsiV3(TsaB) | V. cholerae | Disrupt bacterial cell wall | Identified E–I pairs with Tn-seq | [12] |
| Tge1–3/Tgi1–3 | P. protegens | PG glycoside hydrolase | Identified Tge/Tgi Families | [13] |
| Ssp1, 2/Rap1a, 2a | S. marcescens | Target cell wall | Identified new toxic T6SS pairs | [46] |
| PG DL-endopeptidase | Analyzed the E–I pair structures | [47] | ||
| Ssp1, 2/Rap1, 2 | S. marcescens | Predicted amidases | Identified the Ssp1-6 toxins with proteomic method | [48] |
| TseH/TsiH | V. cholerae | Predicted amidase | Identified a new E–I pair with secretome analysis | [72] |
| Membrane Targeting | ||||
| VasX/TsiV2, TseL/TsiV1(Tle2/Tli2) | V. cholerae | Lipase activity | Identified E–I pairs with Tn-seq | [12] |
| The two immunity proteins possess a dual regulatory profile | [50] | |||
| Tle1–4, 5(PldA)/Tli1–5 | B. thailandensis, et al. | Esterases | Discovered a superfamily of bacterial phospholipase | [16] |
| PldB/PA5088, PA5087, and PA5086 | P. aeruginosa | Phospholipase D | PldB targets the bacterial periplasm and activate eukaryotic PI3K/Akt pathway | [52] |
| TplE/TplEi(Tle4/Tli4) | P. aeruginosa | Phospholipase A1 and Lipase activity | Toxicity in bacterial periplasm and could induce host cell ER stress and autophagy | [53] |
| Tle1/Tli1 | E. coli EAEC 17-2 | Phospholipase A1 and A2 activities | The transport of antibacterial Tle1 is mediated by the C-terminus of VgrG | [51] |
| Hcp-ET2/ETi2 (Tle1/Tli1) | E. coli STEC004, E. coli PE321 | Tle1 Phospholipase | Defined Hcp-ET1-5 and the immunity proteins | [59] |
| Nucleotides Targeting | ||||
| Tde1, 2/Tdi1, 2 | A. tumefaciens | Nucleases | Indentified Tde/Tdi superfamily | [58] |
| RhsA, B/RhsIA, B | D. dadantii | Nucleases | Rhs proteins mediate intercellular competition | [15] |
| Rhs2-CT/RhsI2 | S. marcescens | HNH endonuclease | Analyzed the Rhs effectors in intraspecies competition | [34] |
| Rhs-CT3-8/Rhs-CTI3-8 | E. coli STEC004, E. coli PE027 | DNase and RNase | Analyzed the Rhs-CTs family | [20] |
| Hcp-ET1, 3, 4/ETi1, 3, 4 | E. coli STEC004, E. coli PE321 | HNH-DNase (1), Pyocin S3 (3), Colicin-DNase (4) | Defined Hcp-ET1-5 and the immunity proteins | [59] |
| Tke2/Tki2 | P. putida | Nucleases | Toxic Rhs-type effectors were identified and characterized | [57] |
| Other effectors | ||||
| Hcp-ET5/ETi5 | E. coli STEC004, E. coli PE321 | Papain-like peptidase | Defined Hcp-ET1-5 and the immunity proteins | [59] |
| Tse2/Tsi2 | P. aeruginosa | Arrest bacteria growth | Identified Tse1–3 effectors and immunity protein Tsi2 | [17] |
| Tse2/Tsi2 | P. aeruginosa | Induce bacterial quiescence | Structure analysis revealed the interaction mechanism of Tse2/Tsi2 | [60] |
| Tse2/Tsi2 | P. aeruginosa | NAD-dependent ADP-ribosylating toxins | Analyzed the structure of Tse2 and Tsi2 | [61] |
| Tse4-6/Tsi4-6 | P. aeruginosa | Antibacterial effectors | Proteomics screen for T6SS substrates | [62] |
| Tse6/Tsi6 | P. aeruginosa | NAD(P)+ Glycohydrolase | Analyzed the function, delivery and structure of Tse6 toxin | [64] |
| Tke1, 3/Tki1, 3 | P. putida | NAD(P)+ Glycohydrolase (Tke1), unknown for Tke3 | Toxic Rhs-type effectors were identified and characterized | [57] |
| TseC/TsiC | A. hydrophila | Antibacterial toxicity with a predicted colicin domain | Identified T6SS effector using a conserved chaperone domain | [67] |
| RhsP1, 2-CT/RhsI1, 2 | P. aeruginosa | Antibacterial toxicity | Identified new E–I pairs carried by VgrG | [65] |
| Rhs-CT1, 2, 9/Rhs-CTI1, 2, 9 | E. coli STEC004, E. coli PE027 | Metallopeptidase (1, 2) or Deaminase (9) | Analyzed the Rhs-CTs family | [20] |
| Bfe1, 2/Bfi1, 2 | B. fragilis | Antagonism function | T6SS E–I pairs were responsible for antagonism to gut Bacteroidales species | [66] |