2ayv Citations

Genome-scale protein expression and structural biology of Plasmodium falciparum and related Apicomplexan organisms.

Vedadi M, Lew J, Artz J, Amani M, Zhao Y, Dong A, Wasney GA, Gao M, Hills T, Brokx S, Qiu W, Sharma S, Diassiti A, Alam Z, Melone M, Mulichak A, Wernimont A, Bray J, Loppnau P, Plotnikova O, Newberry K, Sundararajan E, Houston S, Walker J, Tempel W, Bochkarev A, Kozieradzki I, Edwards A, Arrowsmith C, Roos D, Kain K, Hui R
Mol Biochem Parasitol 151 100-10 (2007)

Cited: 149 times
EuropePMC logo PMID: 17125854

Abstract

Parasites from the protozoan phylum Apicomplexa are responsible for diseases, such as malaria, toxoplasmosis and cryptosporidiosis, all of which have significantly higher rates of mortality and morbidity in economically underdeveloped regions of the world. Advances in vaccine development and drug discovery are urgently needed to control these diseases and can be facilitated by production of purified recombinant proteins from Apicomplexan genomes and determination of their 3D structures. To date, both heterologous expression and crystallization of Apicomplexan proteins have seen only limited success. In an effort to explore the effectiveness of producing and crystallizing proteins on a genome-scale using a standardized methodology, over 400 distinct Plasmodium falciparum target genes were chosen representing different cellular classes, along with select orthologues from four other Plasmodium species as well as Cryptosporidium parvum and Toxoplasma gondii. From a total of 1008 genes from the seven genomes, 304 (30.2%) produced purified soluble proteins and 97 (9.6%) crystallized, culminating in 36 crystal structures. These results demonstrate that, contrary to previous findings, a standardized platform using Escherichia coli can be effective for genome-scale production and crystallography of Apicomplexan proteins. Predictably, orthologous proteins from different Apicomplexan genomes behaved differently in expression, purification and crystallization, although the overall success rates of Plasmodium orthologues do not differ significantly. Their differences were effectively exploited to elevate the overall productivity to levels comparable to the most successful ongoing structural genomics projects: 229 of the 468 target genes produced purified soluble protein from one or more organisms, with 80 and 32 of the purified targets, respectively, leading to crystals and ultimately structures from one or more orthologues.

Articles - 2ayv mentioned but not cited (2)

  1. How far are we from automatic crystal structure solution via molecular-replacement techniques? Burla MC, Carrozzini B, Cascarano GL, Giacovazzo C, Polidori G. Acta Crystallogr D Struct Biol 76 9-18 (2020)
  2. The Automatic Solution of Macromolecular Crystal Structures via Molecular Replacement Techniques: REMO22 and Its Pipeline. Carrozzini B, Cascarano GL, Giacovazzo C. Int J Mol Sci 24 6070 (2023)


Reviews citing this publication (34)

  1. Structure-based insights into the catalytic power and conformational dexterity of peroxiredoxins. Hall A, Nelson K, Poole LB, Karplus PA. Antioxid Redox Signal 15 795-815 (2011)
  2. ClpP: a distinctive family of cylindrical energy-dependent serine proteases. Yu AY, Houry WA. FEBS Lett 581 3749-3757 (2007)
  3. Structural biology of the purine biosynthetic pathway. Zhang Y, Morar M, Ealick SE. Cell Mol Life Sci 65 3699-3724 (2008)
  4. Malaria research in the post-genomic era. Winzeler EA. Nature 455 751-756 (2008)
  5. ATP-binding cassette transporters in Escherichia coli. Moussatova A, Kandt C, O'Mara ML, Tieleman DP. Biochim Biophys Acta 1778 1757-1771 (2008)
  6. DYNLL/LC8: a light chain subunit of the dynein motor complex and beyond. Rapali P, Szenes Á, Radnai L, Bakos A, Pál G, Nyitray L. FEBS J 278 2980-2996 (2011)
  7. 21st century natural product research and drug development and traditional medicines. Ngo LT, Okogun JI, Folk WR. Nat Prod Rep 30 584-592 (2013)
  8. Plasmodium immunomics. Doolan DL. Int J Parasitol 41 3-20 (2011)
  9. The structure and function of the retromer protein complex. Collins BM. Traffic 9 1811-1822 (2008)
  10. Global phenotypic screening for antimalarials. Guiguemde WA, Shelat AA, Garcia-Bustos JF, Diagana TT, Gamo FJ, Guy RK. Chem Biol 19 116-129 (2012)
  11. Antimalarial Drugs as Immune Modulators: New Mechanisms for Old Drugs. An J, Minie M, Sasaki T, Woodward JJ, Elkon KB. Annu Rev Med 68 317-330 (2017)
  12. Peroxiredoxins in parasites. Gretes MC, Poole LB, Karplus PA. Antioxid Redox Signal 17 608-633 (2012)
  13. Toward the development of effective transmission-blocking vaccines for malaria. Nikolaeva D, Draper SJ, Biswas S. Expert Rev Vaccines 14 653-680 (2015)
  14. The wheat germ cell-free protein synthesis system: a key tool for novel malaria vaccine candidate discovery. Tsuboi T, Takeo S, Arumugam TU, Otsuki H, Torii M. Acta Trop 114 171-176 (2010)
  15. Dynamics of the ClpP serine protease: a model for self-compartmentalized proteases. Liu K, Ologbenla A, Houry WA. Crit Rev Biochem Mol Biol 49 400-412 (2014)
  16. Heterologous expression of plasmodial proteins for structural studies and functional annotation. Birkholtz LM, Blatch G, Coetzer TL, Hoppe HC, Human E, Morris EJ, Ngcete Z, Oldfield L, Roth R, Shonhai A, Stephens L, Louw AI. Malar J 7 197 (2008)
  17. The acidocalcisome as a target for chemotherapeutic agents in protozoan parasites. Docampo R, Moreno SN. Curr Pharm Des 14 882-888 (2008)
  18. Large screen approaches to identify novel malaria vaccine candidates. Davies DH, Duffy P, Bodmer JL, Felgner PL, Doolan DL. Vaccine 33 7496-7505 (2015)
  19. Biophysical characterization of recombinant proteins: a key to higher structural genomics success. Vedadi M, Arrowsmith CH, Allali-Hassani A, Senisterra G, Wasney GA. J Struct Biol 172 107-119 (2010)
  20. Anti-infectives targeting the isoprenoid pathway of Toxoplasma gondii. Moreno SN, Li ZH. Expert Opin Ther Targets 12 253-263 (2008)
  21. Production of recombinant proteins from protozoan parasites. Fernández-Robledo JA, Vasta GR. Trends Parasitol 26 244-254 (2010)
  22. Structural genomics and drug discovery: all in the family. Weigelt J, McBroom-Cerajewski LD, Schapira M, Zhao Y, Arrowsmith CH. Curr Opin Chem Biol 12 32-39 (2008)
  23. Target identification and validation of novel antimalarials. McNamara C, Winzeler EA. Future Microbiol 6 693-704 (2011)
  24. The Implications of Zinc Therapy in Combating the COVID-19 Global Pandemic. Samad N, Sodunke TE, Abubakar AR, Jahan I, Sharma P, Islam S, Dutta S, Haque M. J Inflamm Res 14 527-550 (2021)
  25. Vaccine candidate discovery for the next generation of malaria vaccines. Tuju J, Kamuyu G, Murungi LM, Osier FHA. Immunology 152 195-206 (2017)
  26. Hydroxychloroquine and Covid-19: A Cellular and Molecular Biology Based Update. Pal A, Pawar A, Goswami K, Sharma P, Prasad R. Indian J Clin Biochem 35 274-284 (2020)
  27. Screening for small molecule inhibitors of Toxoplasma gondii. Kortagere S. Expert Opin Drug Discov 7 1193-1206 (2012)
  28. From crystal to compound: structure-based antimalarial drug discovery. Drinkwater N, McGowan S. Biochem J 461 349-369 (2014)
  29. The Potential of Secondary Metabolites from Plants as Drugs or Leads against Protozoan Neglected Diseases-Part III: In-Silico Molecular Docking Investigations. Ogungbe IV, Setzer WN. Molecules 21 E1389 (2016)
  30. Malaria invasion ligand RH5 and its prime candidacy in blood-stage malaria vaccine design. Ord RL, Rodriguez M, Lobo CA. Hum Vaccin Immunother 11 1465-1473 (2015)
  31. Inhibitors of the Plasmodium falciparum Hsp90 towards Selective Antimalarial Drug Design: The Past, Present and Future. Stofberg ML, Caillet C, de Villiers M, Zininga T. Cells 10 2849 (2021)
  32. Structural biology of plasmodial proteins. Gayathri P, Balaram H, Murthy MR. Curr Opin Struct Biol 17 744-754 (2007)
  33. Structural atlas of dynein motors at atomic resolution. Toda A, Tanaka H, Kurisu G. Biophys Rev 10 677-686 (2018)
  34. Structural insights into Plasmodium PPIases. Rajan S, Yoon HS. Front Cell Infect Microbiol 12 931635 (2022)

Articles citing this publication (113)



Quick links