Abstract
Phospholipases D (PLDs) play important roles in different organisms and in vitro phospholipid modifications, which attract strong interests for investigation. However, the lack of PLD structural information has seriously hampered both the understanding of their structure–function relationships and the structure-based bioengineering of this enzyme. Herein, we presented the crystal structure of a PLD from the plant-associated bacteria Serratia plymuthica strain AS9 (SpPLD) at a resolution of 1.79 Å. Two classical HxKxxxxD (HKD) motifs were found in SpPLD and have shown high structural consistence with several PLDs in the same family. While comparing the structure of SpPLD with the previous resolved PLDs from the same family, several unique conformations on the C-terminus of the HKD motif were demonstrated to participate in the arrangement of the catalytic pocket of SpPLD. In SpPLD, an extented loop conformation between β9 and α9 (aa228–246) was found. Moreover, electrostatic surface potential showed that this loop region in SpPLD was positively charged while the corresponding loops in the two Streptomyces originated PLDs (PDB ID: 1F0I, 2ZE4/2ZE9) were neutral. The shortened loop between α10 and α11 (aa272–275) made the SpPLD unable to form the gate-like structure which existed specically in the two Streptomyces originated PLDs (PDB ID: 1F0I, 2ZE4/2ZE9) and functioned to stabilize the substrates. In contrast, the shortened loop conformation at this corresponding segment was more alike to several nucleases (Nuc, Zuc, mZuc, NucT) within the same family. Moreover, the loop composition between β11 and β12 was also different from the two Streptomyces originated PLDs (PDB ID: 1F0I, 2ZE4/2ZE9), which formed the entrance of the catalytic pocket and were closely related to substrate recognition. So far, SpPLD was the only structurally characterized PLD enzyme from Serratia. The structural information derived here not only helps for the understanding of the biological function of this enzyme in plant protection, but also helps for the understanding of the rational design of the mutant, with potential application in phospholipid modification.
Highlights
Phospholipases D (PLDs, EC 3.1.4.4) belong to the phospholipase superfamily and they are ubiquitously distributed in various organisms including mammals, plants and microorganisms [1]
Some achievements have been made by comparing to the large amount of sequence information in this family, the lack of structural information has hindered the in-depth understanding of the structure–function relationship of PLDs
The first GG/S motif was composed of GS which appreared in the nulceases Zuc (PDB ID: 4GEL), NucT (PDB ID: 6EHI), Nuc (PDB ID: 1BYR) and mZuc (PDB ID:4GGJ) within the same family
Summary
Phospholipases D (PLDs, EC 3.1.4.4) belong to the phospholipase superfamily and they are ubiquitously distributed in various organisms including mammals, plants and microorganisms [1]. According to the PFam database (http://pfam.xfam.org/ (accessed on 5 February 2021)), currently there are 58,157 protein sequences from 7682 species in the PLD superfamily (Clan: CL0479) [6] This superfamily contains 11 subfamilies and most of the reported PLDs belong to the PLDc 2 family (28,771 sequences from 6957 species). In 2007, crystal structures of the apo Streptomyces antibioticus PLD (SaPLD) and the complex with phosphatidylcholine have been resolved Based on these structures, various SaPLD mutants with enhanced thermostability and selectivity have been designed and discovered, which further promoted the industrial application of this enzyme [14,15,16]. Some achievements have been made by comparing to the large amount of sequence information in this family, the lack of structural information has hindered the in-depth understanding of the structure–function relationship of PLDs
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