Cyclodipeptide synthases explained

Cyclodipeptide synthases (CDPSs) are a newly defined family of peptide-bond forming enzymes that are responsible for the ribosome-independent biosynthesis of various cyclodipeptides, which are the precursors of many natural products with important biological activities.^{[1] [2]} As a substrate for this synthesis, CDPSs use two amino acids activated as aminoacyl-tRNAs (aa-tRNAs), therefore diverting them from the ribosomal machinery.^{[3] [4] [5]} The first member of this family was identified in 2002 during the characterization of the albonoursin biosynthetic pathway in Streptomyces noursei.^[6] CDPSs are present in bacteria, fungi, and animal cells.^[7]

History and research

From 2002, when the first description of a CDPSs was done, until now, the number of reported CDPSs in databases has experienced a significant growth (800 in June 2017). It is probable that these cyclopeptides are implicated in numerous biosynthetic pathways. However, their products’ diversity has not been very explored. The activity of 32 new CPDS has been described.^[8] This fact raises the number of experimentally characterized CDPS up to 100 (approximately). Moreover, this research has identified several consensus sequences associated to the formation of a specific cyclodipeptide, enhancing the predictive model of specificity of CDPS. This improved prediction method facilitates the deciphering of independent ways of CDPS.^[9]

Structure

CDPSs don’t have a specific structure, given each one has its own specific function, but they still have common architectures, such as a Rossmann-fold domain. CDPSs are monomers that have been found to display a strong structural similarity to the catalytic domains of class Ic aminoacyl tRNA synthetases: both these families, CDPSs and class Ic aaRSs, have a Rossmann-fold domain and their structures can be superimposed showing many structural analogies.

CDPSs characteristically feature a deep surface-accessible pocket bordered by the catalytic residues, which is where the catalysis of amide bond formation takes place. This structure is positioned similarly to the aminoacyl binding pocket in aaRSs, which leads to thinking that CDPSs evolved from class Ic aaRSs.

CDPSs and aaRSs present substantial differences though, such as the absence of ATP-binding motifs in CDPSs, given that these use, unlike aaRSs, amino acids that have already been activated.

Catabolic reaction: How do CDPSs synthesize cyclodipeptides?

It was firstly thought that nonribosomal peptide synthetases (NRPSs) were the responsible ones of CDPs construction, either through specific biosynthetic pathways or with the premature liberation of dipeptidyl intermediates meanwhile the elongation process was done.^[10] On account of AlbC discovery, an enzyme with the ability to specifically create CDP using loaded ARNt as substrates, it was disclosed that there was a second route for the cyclodipeptide production.^[11]

CDPSs' catalytic cycle begins with the binding of the first aa-tRNA, with its aminoacyl transferred onto a conserved serine residue to form an aminoacyl-enzyme intermediate. The second aa-tRNA interacts with this intermediate so that its aminoacyl is transferred to the aminoacyl-enzyme to form a dipeptidyl-enzyme intermediate. Finally, the dipeptidyl goes through an intramolecular cyclization leading to the final cyclodipeptide.

Classification

CDPSs can be divided into two distinct subfamilies named NYH and XYP, distinguished depending on the conserved residues within their respective active sites, which let experts predict their aminoacyl-tRNA substrates. Both subfamilies mainly differ in the first half of their Rossmann fold, this two structures correspond to two different structural solutions to facilitate the reactivity of the catalytic serine residue.^[12] Some NYH’s crystal structures have been identified. These CDPSs’ structure contain a Rossmann fold domain.

NYH form a larger group than XYP, therefore there is more information about them than about the XYP subfamily.

Biosynthesis

CDPS-encoding genes are found in genomic locations with genes encoding additional biosynthetic enzymes (CDPS DmtB1 is an example, encoded by the gene of dmt1 locus). These additional biosynthetic enzymes are for example: oxidoreductases, prenyltransferases, methyltransferases, or cyclases and some proteins as cytochrome P450s.^{[13] [14]}

Applications

Recently bioinformatics are designing a way to predict CDPSs products to understand better how their catalytic process works. Moreover, research has brought to light a lot of chemical information about CDPSs pathways. Different projects can also create chemical diversity.

The importance of the cyclodipeptides production has attracted immense attention because of their properties, not only as antifungal or antibacterial but also as a biological target. That is why an important part of the pharmaceutical products contain CDPs.

See also

• Cyclic peptide
• Aminoacyl tRNA synthetase

Notes

In elongation reference, go for "Part of transcription of DNA into mRNA".

Notes and References

1. Canu . Nicolas . Moutiez . Mireille . Belin . Pascal . Gondry . Muriel . 2020-03-25 . Cyclodipeptide synthases: a promising biotechnological tool for the synthesis of diverse 2,5-diketopiperazines . 2020-11-09 . Natural Product Reports . 37 . 3 . 312–321 . en . 10.1039/C9NP00036D. 31435633 . 201278253 .
2. Gondry . Muriel . Sauguet . Ludovic . Belin . Pascal . Thai . Robert . Amouroux . Rachel . Tellier . Carine . Tuphile . Karine . Jacquet . Mickaël . Braud . Sandrine . June 2009 . Cyclodipeptide synthases are a family of tRNA-dependent peptide bond-forming enzymes . 2020-11-09 . Nature Chemical Biology . 5 . 6 . 414–420 . 10.1038/nchembio.175 . 19430487.
3. Moutiez. Mireille. Belin. Pascal. Gondry. Muriel. 2017-04-26. Aminoacyl-tRNA-Utilizing Enzymes in Natural Product Biosynthesis. Chemical Reviews. en. 117. 8. 5578–5618. 10.1021/acs.chemrev.6b00523. 28060488. 0009-2665.
4. Sauguet. Ludovic. Moutiez. Mireille. Li. Yan. Belin. Pascal. Seguin. Jérôme. Le Du. Marie-Hélène. Thai. Robert. Masson. Cédric. Fonvielle. Matthieu. Pernodet. Jean-Luc. Charbonnier. Jean-Baptiste. May 2011. Cyclodipeptide synthases, a family of class-I aminoacyl-tRNA synthetase-like enzymes involved in non-ribosomal peptide synthesis. Nucleic Acids Research. en. 39. 10. 4475–4489. 10.1093/nar/gkr027. 21296757. 3105412. 1362-4962. free.
5. Jacques. Isabelle B. Moutiez. Mireille. Witwinowski. Jerzy. Darbon. Emmanuelle. Martel. Cécile. Seguin. Jérôme. Favry. Emmanuel. Thai. Robert. Lecoq. Alain. Dubois. Steven. Pernodet. Jean-Luc. September 2015. Analysis of 51 cyclodipeptide synthases reveals the basis for substrate specificity. Nature Chemical Biology. en. 11. 9. 721–727. 10.1038/nchembio.1868. 26236937. 1552-4450.
6. Schmitt. Emmanuelle. Bourgeois. Gabrielle. Gondry. Muriel. Aleksandrov. Alexey. 2018-05-04. Cyclization Reaction Catalyzed by Cyclodipeptide Synthases Relies on a Conserved Tyrosine Residue. Scientific Reports. en. 8. 1. 7031. 10.1038/s41598-018-25479-5. 2045-2322. 5935735. 29728603. 2018NatSR...8.7031S.
7. Mishra. Awdhesh. Choi. Jaehyuk. Choi. Seong-Jin. Baek. Kwang-Hyun. 2017-10-23. Cyclodipeptides: An Overview of Their Biosynthesis and Biological Activity. Molecules. en. 22. 10. 1796. 10.3390/molecules22101796. 1420-3049. 6151668. 29065531. free.
8. 5816076. 2018. Gondry. M.. Jacques. I. B.. Thai. R.. Babin. M.. Canu. N.. Seguin. J.. Belin. P.. Pernodet. J. L.. Moutiez. M.. A Comprehensive Overview of the Cyclodipeptide Synthase Family Enriched with the Characterization of 32 New Enzymes. Frontiers in Microbiology. 9. 46. 10.3389/fmicb.2018.00046. 29483897. free.
9. Gondry. Muriel. Jacques. Isabelle B.. Thai. Robert. Babin. Morgan. Canu. Nicolas. Seguin. Jérôme. Belin. Pascal. Pernodet. Jean-Luc. Moutiez. Mireille. 2018-02-12. A Comprehensive Overview of the Cyclodipeptide Synthase Family Enriched with the Characterization of 32 New Enzymes. Frontiers in Microbiology. 9. 46. 10.3389/fmicb.2018.00046. 1664-302X. 5816076. 29483897. free.
10. 10.1016/j.sbi.2010.01.009 . Nonribosomal peptide synthetases: Structures and dynamics . 2010 . Strieker . Matthias . Tanović . Alan . Marahiel . Mohamed A. . Current Opinion in Structural Biology . 20 . 2 . 234–240 . 20153164 .
11. Giessen; A. Marahiel. Tobias; Mohamed. August 2014. The tRNA-Dependent Biosynthesis of Modified Cyclic Dipeptides. International Journal of Molecular Sciences. 15. 8. 14610–14631. 10.3390/ijms150814610. 25196600. 4159871. ResearchGate. free.
12. Bourgeois. Gabrielle. Seguin. Jérôme. Babin. Morgan. Belin. Pascal. Moutiez. Mireille. Mechulam. Yves. Gondry. Muriel. Schmitt. Emmanuelle. July 2018. Structural basis for partition of the cyclodipeptide synthases into two subfamilies. Journal of Structural Biology. en. 203. 1. 17–26. 10.1016/j.jsb.2018.03.001. 29505829. 3739860 .
13. Borgman. Paul. Lopez. Ryan D.. Lane. Amy L.. 2019. The expanding spectrum of diketopiperazine natural product biosynthetic pathways containing cyclodipeptide synthases. Organic & Biomolecular Chemistry. en. 17. 9. 2305–2314. 10.1039/C8OB03063D. 30688950. 59306358 . 1477-0520.
14. Yao. Tingting. Liu. Jing. Liu. Zengzhi. Li. Tong. Li. Huayue. Che. Qian. Zhu. Tianjiao. Li. Dehai. Gu. Qianqun. Li. Wenli. December 2018. Genome mining of cyclodipeptide synthases unravels unusual tRNA-dependent diketopiperazine-terpene biosynthetic machinery. Nature Communications. en. 9. 1. 4091. 10.1038/s41467-018-06411-x. 2041-1723. 6173783. 30291234. 2018NatCo...9.4091Y.