2lp0 Citations

Structural basis for homeodomain recognition by the cell-cycle regulator Geminin.

Zhou B, Liu C, Xu Z, Zhu G
Proc Natl Acad Sci U S A 109 8931-6 (2012)
Cited: 20 times
EuropePMC logo PMID: 22615398

Abstract

Homeodomain-containing transcription factors play a fundamental role in the regulation of numerous developmental and cellular processes. Their multiple regulatory functions are accomplished through context-dependent inputs of target DNA sequences and collaborating protein partners. Previous studies have well established the sequence-specific DNA binding to homeodomains; however, little is known about how protein partners regulate their functions through targeting homeodomains. Here we report the solution structure of the Hox homeodomain in complex with the cell-cycle regulator, Geminin, which inhibits Hox transcriptional activity and enrolls Hox in cell proliferative control. Side-chain carboxylates of glutamates and aspartates in the C terminus of Geminin generate an overall charge pattern resembling the DNA phosphate backbone. These residues provide electrostatic interactions with homeodomain, which combine with the van der Waals contacts to form the stereospecific complex. We further showed that the interaction with Geminin is homeodomain subclass-selective and Hox paralog-specific, which relies on the stapling role of residues R43 and M54 in helix III and the basic amino acid cluster in the N terminus. Interestingly, we found that the C-terminal residue Ser184 of Geminin could be phosphorylated by Casein kinase II, resulting in the enhanced binding to Hox and more potent inhibitory effect on Hox transcriptional activity, indicating an additional layer of regulation. This structure provides insight into the molecular mechanism underlying homeodomain-protein recognition and may serve as a paradigm for interactions between homeodomains and DNA-competitive peptide inhibitors.

Articles - 2lp0 mentioned but not cited (1)

  1. Structural basis for homeodomain recognition by the cell-cycle regulator Geminin. Zhou B, Liu C, Xu Z, Zhu G. Proc Natl Acad Sci U S A 109 8931-8936 (2012)


Reviews citing this publication (8)

  1. Role of HOXA9 in leukemia: dysregulation, cofactors and essential targets. Collins CT, Hess JL. Oncogene 35 1090-1098 (2016)
  2. Homeodomain proteins in action: similar DNA binding preferences, highly variable connectivity. Bobola N, Merabet S. Curr Opin Genet Dev 43 1-8 (2017)
  3. Non-transcriptional interactions of Hox proteins: inventory, facts, and future directions. Rezsohazy R. Dev Dyn 243 117-131 (2014)
  4. Kinase Regulation of HOX Transcription Factors. Primon M, Hunter KD, Pandha HS, Morgan R. Cancers (Basel) 11 E508 (2019)
  5. Geminin a multi task protein involved in cancer pathophysiology and developmental process: A review. Kushwaha PP, Rapalli KC, Kumar S. Biochimie 131 115-127 (2016)
  6. Role of Geminin in cell fate determination of hematopoietic stem cells (HSCs). Yasunaga S, Ohno Y, Shirasu N, Zhang B, Suzuki-Takedachi K, Ohtsubo M, Takihara Y. Int J Hematol 104 324-329 (2016)
  7. Regulation of geminin by neuropeptide Y in vascular smooth muscle cell proliferation : A current review. Liang SY, Zhou YL, Shu MQ, Lin S. Herz 44 712-716 (2019)
  8. Role of HOXA9 in solid tumors: mechanistic insights and therapeutic potential. Tang L, Peng L, Tan C, Liu H, Chen P, Wang H. Cancer Cell Int 22 349 (2022)

Articles citing this publication (11)

  1. Gene regulatory networks in neural cell fate acquisition from genome-wide chromatin association of Geminin and Zic1. Sankar S, Yellajoshyula D, Zhang B, Teets B, Rockweiler N, Kroll KL. Sci Rep 6 37412 (2016)
  2. The Geminin and Idas coiled coils preferentially form a heterodimer that inhibits Geminin function in DNA replication licensing. Caillat C, Pefani DE, Gillespie PJ, Taraviras S, Blow JJ, Lygerou Z, Perrakis A. J Biol Chem 288 31624-31634 (2013)
  3. Emerging players in the initiation of eukaryotic DNA replication. Shen Z, Prasanth SG. Cell Div 7 22 (2012)
  4. Geminin deletion in mouse oocytes results in impaired embryo development and reduced fertility. Ma XS, Lin F, Wang ZW, Hu MW, Huang L, Meng TG, Jiang ZZ, Schatten H, Wang ZB, Sun QY. Mol Biol Cell 27 768-775 (2016)
  5. Molecular Analysis of the HOXA2-Dependent Degradation of RCHY1. Bridoux L, Deneyer N, Bergiers I, Rezsohazy R. PLoS One 10 e0141347 (2015)
  6. Manipulation of Cell Cycle and Chromatin Configuration by Means of Cell-Penetrating Geminin. Ohno Y, Suzuki-Takedachi K, Yasunaga S, Kurogi T, Santo M, Masuhiro Y, Hanazawa S, Ohtsubo M, Naka K, Takihara Y. PLoS One 11 e0155558 (2016)
  7. SIX3 and SIX6 interact with GEMININ via C-terminal regions. Turcu DC, Lillehaug JR, Seo HC. Biochem Biophys Rep 20 100695 (2019)
  8. (1)H, (15)N and (13)C chemical shift assignments of the homeodomain of Hoxc9 in complex with the cell cycle regulator Geminin. Zhou B, Liu C, Zhu G. Biomol NMR Assign 9 165-168 (2015)
  9. Correlation between DNA Methylation and Cell Proliferation Identifies New Candidate Predictive Markers in Meningioma. Hergalant S, Saurel C, Divoux M, Rech F, Pouget C, Godfraind C, Rouyer P, Lacomme S, Battaglia-Hsu SF, Gauchotte G. Cancers (Basel) 14 6227 (2022)
  10. Geminin is required for Hox gene regulation to pattern the developing limb. Lewis EMA, Sankar S, Tong C, Patterson ES, Waller LE, Gontarz P, Zhang B, Ornitz DM, Kroll KL. Dev Biol 464 11-23 (2020)
  11. Letter The Biophysical Society of Hong Kong (BPHK): past, present, and future. Zhu G. Biophys Rev 11 259-261 (2019)


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