Skip NavigationSkip to Content

NCI at Frederick Scientific Publications Advanced Search

Search

  1. NCI-F Publications

  2. Return to Quick Search
Search
  2. Year Published:

Your search returned 32 results.
User Information
Export Records
  1. 1.   The three-dimensional structure of the Vint domain from Tetrahymena thermophila suggests a ligand-regulated cleavage mechanism by the HINT fold
  2. Iwaï, Hideo; Beyer, Hannes M; Johansson, Julia E M; Li,Mi; Wlodawer,Alexander
  3. FEBS Letters. 2024, Feb 13;
  1. 2.   Sonic hedgehog is not a limb morphogen but acts as a trigger to specify all digits in mice
  2. Zhu, Jianjian; Patel,Rashmi; Trofka, Anna; Harfe, Brian D; Mackem,Susan
  3. Developmental Cell. 2022, Aug 13; 57(17): 2048-2062.
  1. 3.   Zic5 stabilizes Gli3 via a non-transcriptional mechanism during retinal development
  2. Sun,Jian; Yoon,Jaeho; Lee,Moonsup; Lee,Hyun Kyung; Hwang,Rich Yooseok; Daar,Ira
  3. Cell Reports. 2022, Feb 01; 38(5):
  1. 4.   Genetic and Epigenetic Regulation of the Smoothened Gene (SMO) in Cancer Cells
  2. Lou,Hong; Li,Hongchuan; Huehn, Andrew R; Tarasova,Nadya; Saleh, Bahara; Anderson, Stephen K; Dean,Michael
  3. Cancers. 2020, Aug 08; 12(8): pii: E2219.
  1. 5.   A frizzled-like cysteine rich domain in glypican-3 mediates Wnt binding and regulates hepatocellular carcinoma tumor growth in mice
  2. Li, Na; Wei, Liwen; Liu, Xiaoyu; Bai, Hongjun; Ye, Yvonne; Li, Dan; Li, Nan; Baxa,Ulrich; Wang, Qun; Lv, Ling; Chen, Yun; Feng, Mingqian; Lee, Byungkook; Gao, Wei; Ho, Mitchell
  3. Hepatology (Baltimore, Md.). 2019, OCT; 70(4): 1231-1245.
  1. 6.   A Systems Pharmacology Approach Uncovers Wogonoside as an Angiogenesis Inhibitor of Triple-Negative Breast Cancer by Targeting Hedgehog Signaling
  2. Huang, Yujie; Fang, Jiansong; Lu, Weiqiang; Wang, Zihao; Wang, Qi; Hou, Yuan; Jiang, Xingwu; Reizes, Ofer; Lathia, Justin; Nussinov,Ruth; Eng, Charis; Cheng, Feixiong
  3. Cell chemical biology. 2019, Aug 15; 26(8): 1143-1158.e.
  1. 7.   John Saunders' ZPA, Sonic hedgehog and digit identity - How does it really all work?
  2. Zhu, Jianjian; Mackem, Susan
  3. Developmental Biology. 2017, Sep 15; 429(2 Special Issue): 391-400.
  1. 8.   In Vitro Modeling Using Ciliopathy-Patient-Derived Cells Reveals Distinct Cilia Dysfunctions Caused by CEP290 Mutations
  2. Shimada, Hiroko; Lu, Quanlong; Kettenhofen, Christine; Nagashima, Kunio; English, Milton A; Semler, Elizabeth; Mahgerefteh, Jacklyn; Cideciyan, Artur V; Li, Tiansen; Brooks, Brian P; Gunay-Aygun, Meral; Jacobson, Samuel G; Cogliati, Tiziana; Westlake, Christopher; Swaroop, Anand
  3. Cell Reports. 2017, Jul 11; 20(2): 384-396.
  1. 9.   Evolution: Enhanced Footing for Snake Limb Development
  2. Kaltcheva, Maria; Lewandoski, Mark
  3. CURRENT BIOLOGY. 2016, Dec 5; 26(23): R1237-R1240.
  1. 10.   Cre-mediated recombination can induce apoptosis in vivo by activating the p53 DNA damage-induced pathway
  2. Zhu, J. J.; Nguyen, M. T.; Nakamura, E.; Yang, J. M.; Mackem, S.
  3. Genesis. 2012, Feb; 50(2): 102-111.
  1. 11.   Analysis of Mutants With Altered Shh Activity and Posterior Digit Loss Supports a Biphasic Model for Shh Function as a Morphogen and Mitogen
  2. Zhu, J. J.; Mackem, S.
  3. Developmental Dynamics. 2011, May; 240(5): 1303-1310.
  1. 12.   Osteoblast Precursors, but Not Mature Osteoblasts, Move into Developing and Fractured Bones along with Invading Blood Vessels
  2. Maes, C.; Kobayashi, T.; Selig, M. K.; Torrekens, S.; Roth, S. I.; Mackem, S.; Carmeliet, G.; Kronenberg, H. M.
  3. Developmental Cell. 2010, Aug; 19(2): 329-344.
  1. 13.   Midline signaling regulates kidney positioning but not nephrogenesis through Shh
  2. Tripathi, P.; Guo, Q. S.; Wang, Y. Q.; Coussens, M.; Liapis, H.; Jain, S.; Kuehn, M. R.; Capecchi, M. R.; Chen, F.
  3. Developmental Biology. 2010, Apr; 340(2): 518-527.
  1. 14.   Limb Development Takes a Measured Step Toward Systems Analysis
  2. Mackem, S.; Lewandoski, M.
  3. Science Signaling. 2009, May; 2(71): 4.
  1. 15.   Invasive prostate cancer cells are tumor initiating cells that have a stem cell-like genomic signature
  2. Klarmann, G. J.; Hurt, E. M.; Mathews, L. A.; Zhang, X. H.; Duhagon, M. A.; Mistree, T.; Thomas, S. B.; Farrar, W. L.
  3. Clinical & Experimental Metastasis. 2009 26(5): 433-446.
  1. 16.   Embryonic hair follicle fate change by augmented beta-catenin through Shh and Bmp signaling
  2. Suzuki, K.; Yamaguchi, Y.; Villacorte, M.; Mihara, K.; Akiyama, M.; Shimizu, H.; Taketo, M. M.; Nakagata, N.; Tsukiyama, T.; Yamaguchi, T. P.; Birchmeier, W.; Kato, S.; Yamada, G.
  3. Development. 2009 136(3): 367-372.
  1. 17.   LIM homeobox transcription factors integrate signaling events that control three-dimensional limb patterning and growth
  2. Tzchori, I.; Day, T. F.; Carolan, P. J.; Zhao, Y.; Wassif, C. A.; Li, L.; Lewandoski, M.; Gorivodsky, M.; Love, P. E.; Porter, F. D.; Westphal, H.; Yang, Y.
  3. Development. 2009 136(8): 1375-1385.
  1. 18.   Targeted therapy for cancer stem cells: the patched pathway and ABC transporters
  2. Lou, H.; Dean, M.
  3. Oncogene. 2007, Feb; 26(9): 1357-1360.
  1. 19.   Cancer stem cells - Redefining the paradigm of cancer treatment strategies
  2. Dean, M.
  3. Molecular Interventions. 2006, Jun; 6(3): 140-148.
  1. 20.   Pathology of genetically engineered mouse models of pancreatic exocrine cancer: Consensus report and recommendations
  2. Hruban, R. H.; Adsay, N. V.; Albores-Saavedra, J.; Anver, M. R.; Biankin, A. V.; Boivin, G. P.; Furth, E. E.; Furukawa, T.; Klein, A.; Klimstra, D. S.; Kloppel, G.; Lauwers, G. Y.; Longnecker, D. S.; Luttges, J.; Maitra, A.; Offerhaus, G. J. A.; Perez-Gallego, L.; Redston, M.; Tuveson, D. A.
  3. Cancer Research. 2006, Jan 1; 66(1): 95-106.
  1. 21.   FGFR1 function at the earliest stages of mouse limb development plays an indispensable role in subsequent autopod morphogenesis
  2. Li, C. L.; Xu, X. L.; Nelson, D. K.; Williams, T.; Kuehn, M. R.; Deng, C. X.
  3. Development. 2005, NOV; 132(21): 4755-4764.
  1. 22.   Frontonasal dysplasia in 3H1 Br/Br mice
  2. McBratney, B. M.; Margaryan, E.; Ma, W. B.; Urban, Z.; Lozanoff, S.
  3. Anatomical Record Part a-Discoveries in Molecular Cellular and Evolutionary Biology. 2003 271A(2): 291-302.
  1. 23.   GLIS3, a novel member of the GLIS subfamily of Kruppel-like zinc finger proteins with repressor and activation functions
  2. Kim, Y. S.; Nakanishi, G.; Lewandoski, M.; Jetten, A. M.
  3. Nucleic Acids Research. 2003 31(19): 5513-5525.
  1. 24.   Identification of Glis1, a novel Gli-related, Kruppel-like zinc finger protein containing transactivation and repressor functions
  2. Kim, Y. S.; Lewandoski, M.; Perantoni, A. O.; Kurebayashi, S.; Nakanishi, G.; Jetten, A. M.
  3. Journal of Biological Chemistry. 2002 277(34): 30901-30913.
  1. 25.   Characterization of Glis2, a novel gene encoding a Gli-related, Kruppel-like transcription factor with Transactivation and repressor functions - Roles in kidney development and neurogenesis
  2. Zhang, F.; Nakanishi, G.; Kurebayashi, S.; Yoshino, K.; Perantoni, A.; Kim, Y. S.; Jetten, A. M.
  3. Journal of Biological Chemistry. 2002 277(12): 10139-10149.
NCI at Frederick

You are leaving a government website.

This external link provides additional information that is consistent with the intended purpose of this site. The government cannot attest to the accuracy of a non-federal site.

Linking to a non-federal site does not constitute an endorsement by this institution or any of its employees of the sponsors or the information and products presented on the site. You will be subject to the destination site's privacy policy when you follow the link.

ContinueCancel