Skip NavigationSkip to Content

NCI at Frederick Scientific Publications Advanced Search

Search
  1. NCI-F Publications

Search
  1. Year Published:

Your search returned 131 results.
User Information
Export Records
  1. 1.   Differential sensitivity of the yeast Lon protease Pim1p to impaired mitochondrial respiration
  2. Metzger,Meredith; Scales, Jessica L; Grant, Garis A; Molnar,Abby; Loncarek,Jadranka; Weissman,Allan
  3. The Journal of Biological Chemistry. 2023, Aug; 299(8): 104937.
  1. 2.   A protein quality control pathway at the mitochondrial outer membrane
  2. Metzger,Meredith; Scales, Jessica L; Dunklebarger, Mitchell F; Loncarek,Jadranka; Weissman,Allan
  3. eLife. 2020, Mar 02; 9
  1. 3.   Diverse effect of phosphatidylcholine biosynthetic genes on phospholipid homeostasis, cell autophagy and fungal developments in Metarhizium robertsii
  2. Chen, Yixiong; Li, Bing; Cen, Kai; Lu, Yuzhen; Zhang, Siwei; Wang, Chengshu
  3. Environmental Microbiology. 2018, Jan; 20(1): 293-304.
  1. 4.   Structure of a eukaryotic RNase III postcleavage complex reveals a double-ruler mechanism for substrate selection
  2. Liang, Y. H.; Lavoie, M.; Comeau, M. A.; Abou Elela, S.; Ji, X.
  3. Molecular Cell. 2014, 8-May; 54(3): 431-44.
  1. 5.   Challenges in plasma membrane phosphoproteomics
  2. Orsburn, B. C.; Stockwin, L. H.; Newton, D. L.
  3. Expert Review of Proteomics. 2011, Aug; 8(4): 483-494.
  1. 6.   Processes of fungal proteome evolution and gain of function: gene duplication and domain rearrangement
  2. Cohen-Gihon, I.; Sharan, R.; Nussinov, R.
  3. Physical Biology. 2011, Jun; 8(3): 9.
  1. 7.   Sequential requirements for the GTPase domain of the mitofusin Fzo1 and the ubiquitin ligase SCF(Mdm30) in mitochondrial outer membrane fusion
  2. Cohen, M. M.; Amiott, E. A.; Day, A. R.; Leboucher, G. P.; Pryce, E. N.; Glickman, M. H.; McCaffery, J. M.; Shaw, J. M.; Weissman, A. M.
  3. Journal of Cell Science. 2011, May; 124(9): 1403-1410.
  1. 8.   High recombination rates and hotspots in a Plasmodium falciparum genetic cross
  2. Jiang, H. Y.; Li, N.; Gopalan, V.; Zilversmit, M. M.; Varma, S.; Nagarajan, V.; Li, J.; Mu, J. B.; Hayton, K.; Henschen, B.; Yi, M.; Stephens, R.; McVean, G.; Awadalla, P.; Wellems, T. E.; Su, X. Z.
  3. Genome Biology. 2011, Apr 4; 12(4): 14.
  1. 9.   A set of aspartyl protease-deficient strains for improved expression of heterologous proteins in Kluyveromyces lactis
  2. Ganatra, M. B.; Vainauskas, S.; Hong, J. M.; Taylor, T. E.; Denson, J. P. M.; Esposito, D.; Read, J. D.; Schmeisser, H.; Zoon, K. C.; Hartley, J. L.; Taron, C. H.
  3. Fems Yeast Research. 2011, Mar; 11(2): 168-178.
  1. 10.   Sphingosine kinases and their metabolites modulate endolysosomal trafficking in photoreceptors
  2. Yonamine, I.; Bamba, T.; Nirala, N. K.; Jesmin, N.; Kosakowska-Cholody, T.; Nagashima, K.; Fukusaki, E.; Acharya, J. K.; Acharya, U.
  3. Journal of Cell Biology. 2011, Feb; 192(4): 557-567.
  1. 11.   CDase is a pan-ceramidase in Drosophila
  2. Yuan, C. Q.; Rao, R. P.; Jesmin, N.; Bamba, T.; Nagashima, K.; Pascual, A.; Preat, T.; Fukusaki, E.; Acharya, U.; Acharya, J. K.
  3. Molecular Biology of the Cell. 2011, Jan; 22(1): 33-43.
  1. 12.   The Yeast Mating-Type Switching Mechanism: A Memoir
  2. Klar, A. J. S.
  3. Genetics. 2010, Oct; 186(2): 443-449.
  1. 13.   Sequence signatures and mRNA concentration can explain two-thirds of protein abundance variation in a human cell line
  2. Vogel, C.; Abreu, R. D.; Ko, D. J.; Le, S. Y.; Shapiro, B. A.; Burns, S. C.; Sandhu, D.; Boutz, D. R.; Marcotte, E. M.; Penalva, L. O.
  3. Molecular Systems Biology. 2010, Aug; 6: 9.
  1. 14.   A Mechanistic View of the Role of E3 in Sumoylation
  2. Tozluoglu, M.; Karaca, E.; Nussinov, R.; Halilogiu, T.
  3. Plos Computational Biology. 2010, Aug; 6(8): 10.
  1. 15.   Conformational coupling, bridge helix dynamics and active site dehydration in catalysis by RNA polymerase
  2. Seibold, S. A.; Singh, B. N.; Zhang, C. F.; Kireeva, M.; Domecq, C.; Bouchard, A.; Nazione, A. M.; Feig, M.; Cukier, R. I.; Coulombe, B.; Kashlev, M.; Hampsey, M.; Burton, Z. F.
  3. Biochimica Et Biophysica Acta-Gene Regulatory Mechanisms. 2010, Aug; 1799(8): 575-587.
  1. 16.   Schizosaccharomyces pombe Dss1p Is a DNA Damage Checkpoint Protein That Recruits Rad24p, Cdc25p, and Rae1p to DNA Double-strand Breaks
  2. Selvanathan, S. P.; Thakurta, A. G.; Dhakshnamoorthy, J.; Zhou, M.; Veenstra, T. D.; Dhar, R.
  3. Journal of Biological Chemistry. 2010, May; 285(19): 14122-14133.
  1. 17.   P-Body Components Are Required for Ty1 Retrotransposition during Assembly of Retrotransposition-Competent Virus-Like Particles
  2. Checkley, M. A.; Nagashima, K.; Lockett, S. J.; Nyswaner, K. M.; Garfinkel, D. J.
  3. Molecular and Cellular Biology. 2010, Jan; 30(2): 382-398.
  1. 18.   A Mutation Associated with CMT2A Neuropathy Causes Defects in Fzo1 GTP Hydrolysis, Ubiquitylation, and Protein Turnover
  2. Amiott, E. A.; Cohen, M. M.; Saint-Georges, Y.; Weissman, A. M.; Shaw, J. M.
  3. Molecular Biology of the Cell. 2009 20(23): 5026-5035.
  1. 19.   Ty3 Nuclear Entry Is Initiated by Viruslike Particle Docking on GLFG Nucleoporins
  2. Beliakova-Bethell, N.; Terry, L. J.; Bilanchone, V.; DaSilva, R.; Nagashima, K.; Wente, S. R.; S, meyer
  3. Journal of Virology. 2009 83(22): 11914-11925.
  1. 20.   Energetic determinants of protein binding specificity: Insights into protein interaction networks
  2. Carbonell, P.; Nussinov, R.; del Sol, A.
  3. Proteomics. 2009 9(7): 1744-1753.
  1. 21.   A Ubc7p-binding domain in Cue1p activates ER-associated protein degradation
  2. Kostova, Z.; Mariano, J.; Scholz, S.; Koenig, C.; Weissman, A. M.
  3. Journal of Cell Science. 2009 122(9): 1374-1381.
  1. 22.   Posttranslational interference of Ty1 retrotransposition by antisense RNAs
  2. Matsuda, E.; Garfinkel, D. J.
  3. Proceedings of the National Academy of Sciences of the United States of America. 2009 106(37): 15657-15662.
  1. 23.   Functional Analysis of N-Terminal Residues of Ty1 Integrase
  2. Moore, S. P.; Garfinkel, D. J.
  3. Journal of Virology. 2009 83(18): 9502-9511.
  1. 24.   Transposition into Replicating DNA Occurs through Interaction with the Processivity Factor
  2. Parks, A. R.; Li, Z. P.; Shi, Q. J.; Owens, R. M.; Jin, M. M.; Peters, J. E.
  3. Cell. 2009 138(4): 685-695.
  1. 25.   Rpb9 Subunit Controls Transcription Fidelity by Delaying NTP Sequestration in RNA Polymerase II
  2. Walmacq, C.; Kireeva, M. L.; Irvin, J.; Nedialkov, Y.; Lubkowska, L.; Malagon, F.; Strathern, J. N.; Kashlev, M.
  3. Journal of Biological Chemistry. 2009 284(29): 19601-19612.
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