TY - JOUR
AU - 
AB - R EPORTS 17. J. G. Postma, E. Jacobsen, W. J. Feenstra, J. Plant 30. C. Venter et al., Science 291, 1304 (2001). similar to Arabidopsis CLV2 and an extra- Physiol. 132, 424 (1988). 31. We thank the AGRF facility, B. Simpson, K. Meksem, cellular peptide similar to Arabidopsis 18. S. J. Park, B. R. Buttery, Can. J. Plant Sci. 68, 199 R. Wing, N. Young, M. Bhattacharyya, C. Beveridge, R. CLV3 (1, 5). Other proteins involved in (1988). Birch, and L. Matthew for technical support and/or 19. J. Wopereis et al., Plant J. 23, 97 (2000). signal transduction have also been shown to critical comments. We also thank Q. Jiangfor pho- 20. A. C. Delves, A. Higgins, P. M. Gresshoff, Plant Cell interact with CLV1 in Arabidopsis (5). tography in Fig. 1. Research was supported by The Environ. 15, 249 (1992). University of Queensland (UQ) Vice Chancellor’s Intriguingly, GmNARK is most similar to 21. P. B. J. Francisco, J. E. Harper, Plant Sci. 107, 167 Strategic Funds, SRDC Scholarship (to I.R.S.); IPRS and CLV1, whereas two receptor-like kinase (1995). UQPRS awards (to T.S.L. and D.M.B.); and a UQ 22. A. C. Delves et al., Plant Physiol. 82, 588 (1986). 
TI - Modulation of ATP-Dependent Chromatin-Remodeling Complexes by Inositol Polyphosphates
JF - Science
DO - 10.1126/science.1078068
DA - 2003-01-03
UR - https://www.deepdyve.com/lp/unpaywall/modulation-of-atp-dependent-chromatin-remodeling-complexes-by-inositol-Hmzpr2sM06
DP - DeepDyve
ER -