All Stories

  1. Alternate carbohydrate and nontraditional inducer leads to increased productivity of a collagen binding domain fusion protein via fed-batch fermentation

    Article • Journal of Biotechnology, May 2016, Elsevier

    Joshua Sakon

  2. Fluorescent ampicillin analogues as multifunctional disguising agents against opsonization

    Article • Nanoscale, January 2016, Royal Society of Chemistry

    Joshua Sakon

  3. Structures of three polycystic kidney disease-like domains fromClostridium histolyticumcollagenases ColG and ColH

    Article • Acta Crystallographica Section D Biological Crystallography, February 2015, International Union of Crystallography

    Joshua Sakon

  4. Expression of a collagen-binding domain fusion protein: Effect of amino acid supplementation, inducer type, and culture conditions

    Article • Biotechnology Progress, February 2015, Wiley

    Joshua Sakon

  5. Parathyroid hormone linked to a collagen binding domain promotes hair growth in a mouse model of chemotherapy-induced alopecia in a dose-dependent manner

    Article • Anti-Cancer Drugs, August 2014, Wolters Kluwer Health

    Joshua Sakon

  6. Crystal Structure of Staphylococcal Nuclease mutant V23L/L25V/V66L

    Article • June 2014, Protein Data Bank, Rutgers University

    Joshua Sakon

  7. Pharmacokinetics in Rats of a Long-Acting Human Parathyroid Hormone–Collagen Binding Domain Peptide Construct

    Article • Journal of Pharmaceutical Sciences, February 2014, Elsevier

    Joshua Sakon

  8. Treatment and prevention of chemotherapy-induced alopecia with PTH-CBD, a collagen-targeted parathyroid hormone analog, in a non-depilated mouse model

    Article • Anti-Cancer Drugs, January 2014, Wolters Kluwer Health

    Joshua Sakon

  9. Therapy for Alopecia Areata in Mice Using Parathyroid Hormone Agonists and Antagonists, Linked to a Collagen-Binding Domain

    Article • Journal of Investigative Dermatology Symposium Proceedings, December 2013, Elsevier

    Joshua Sakon

  10. Crystal Structure of Staphylococcal nuclease mutant V23L/V66I

    Article • May 2013, Protein Data Bank, Rutgers University

    Joshua Sakon

  11. Crystal Structure of Staphylococcal Nuclease mutant I92V/V99L

    Article • May 2013, Protein Data Bank, Rutgers University

    Joshua Sakon

  12. Crystal Structure of Staphylococcal nuclease mutant V66I/V99L

    Article • April 2013, Protein Data Bank, Rutgers University

    Joshua Sakon

  13. Crystal Structure of Staphylococcal nuclease mutant V23I/L25V/I72V/I92V

    Article • March 2013, Protein Data Bank, Rutgers University

    Joshua Sakon

  14. Crystal Structure of Staphylococcal nuclease mutant V23I/I72L

    Article • March 2013, Protein Data Bank, Rutgers University

    Joshua Sakon

  15. Structural Comparison of ColH and ColG Collagen-Binding Domains from Clostridium histolyticum

    Article • Journal of Bacteriology, November 2012, ASM Journals

    Joshua Sakon

  16. Crystal Structure of Staphylococcal nuclease mutant I72V/V99L

    Article • October 2012, Protein Data Bank, Rutgers University

    Joshua Sakon

  17. Bacterial collagen-binding domain targets undertwisted regions of collagen

    Article • Protein Science, September 2012, Wiley

    Joshua Sakon

  18. Staphylococcal Nuclease double mutant I72L, I92L

    Article • August 2012, Protein Data Bank, Rutgers University

    Joshua Sakon

  19. Treatment for chemotherapy-induced alopecia in mice using parathyroid hormone agonists and antagonists linked to a collagen binding domain

    Article • International Journal of Cancer, January 2012, Wiley

    Joshua Sakon

  20. The Crystal Structure of the Polycystic Kidney Disease Domain (PKD) from Clostridium Histolyticum Collagenase: Insight into the Role of the PKD in Collagenase

    Article • Biophysical Journal, January 2012, Elsevier

    Joshua Sakon

  21. Probing the 3-D Structure, Dynamics, and Stability of Bacterial Collagenase Collagen Binding Domain (apo- versus holo-) by Limited Proteolysis MALDI-TOF MS

    Article • Journal of the American Society for Mass Spectrometry, December 2011, Springer Science + Business Media

    Joshua Sakon

  22. Crystal structure of Clostridium histolyticum colG collagenase polycystic kidney disease domain at 1.4 Angstrom resolution

    Article • September 2010, Protein Data Bank, Rutgers University

    Joshua Sakon

  23. Aqueous-phase synthesis of monodisperse plasmonic gold nanocrystals using shortened single-walled carbon nanotubes

    Article • Chemical Communications, January 2010, Royal Society of Chemistry

    Joshua Sakon

  24. Characterization of the Minimalistic Fgf-D2 Domain Interface

    Article • Biophysical Journal, January 2010, Elsevier

    Joshua Sakon

  25. Crystal Structure of Synaptotagmin I C2A domain with Cu(II)

    Article • October 2009, Protein Data Bank, Rutgers University

    Joshua Sakon

  26. Crystal Structure of Synaptotagmin I C2A domain with Mn(II)

    Article • October 2009, Protein Data Bank, Rutgers University

    Joshua Sakon

  27. Crystal Structure of Synaptotagmin I C2A domain

    Article • September 2009, Protein Data Bank, Rutgers University

    Joshua Sakon

  28. Crystal Structure of Synaptotagmin I C2A domain with Cu(II)

    Article • September 2009, Protein Data Bank, Rutgers University

    Joshua Sakon

  29. Crystal structure of the FGFR2 D2 domain

    Article • August 2009, Protein Data Bank, Rutgers University

    Joshua Sakon

  30. Ca2+-induced linker transformation leads to a compact and rigid collagen-binding domain of Clostridium histolyticum collagenase

    Article • FEBS Journal, June 2009, Wiley

    Joshua Sakon

  31. Crystal Structure of 2:2:2 FGFR2D2:FGF1:SOS complex

    Article • April 2009, Protein Data Bank, Rutgers University

    Joshua Sakon

  32. Crystal Structure of hFGFR2 D2 Domain

    Article • January 2009, Protein Data Bank, Rutgers University

    Joshua Sakon

  33. 1H, 13C and 15N resonance assignments of Ca2+ bound collagen-binding domain derived from a clostridial collagenase

    Article • Biomolecular NMR Assignments, July 2008, Springer Science + Business Media

    Joshua Sakon

  34. Hepatitis C Virus NS3 Helicase Forms Oligomeric Structures That Exhibit Optimal DNA Unwinding Activity in Vitro

    Article • Journal of Biological Chemistry, February 2008, American Society for Biochemistry & Molecular Biology (ASBMB)

    Joshua Sakon

  35. Crystal structure of Staphylococcal nuclease mutant L25I

    Article • October 2006, Protein Data Bank, Rutgers University

    Joshua Sakon

  36. Crystal structure of Staphylococcal nuclease mutant V66I

    Article • October 2006, Protein Data Bank, Rutgers University

    Joshua Sakon

  37. Crystal structure of Staphylococcal nuclease mutant V23L/I72L

    Article • October 2006, Protein Data Bank, Rutgers University

    Joshua Sakon

  38. Crystal structure of Staphylococcal nuclease mutant L25I/I72L

    Article • October 2006, Protein Data Bank, Rutgers University

    Joshua Sakon

  39. Crystal structure of Staphylococcal nuclease mutant V66I/I72V

    Article • October 2006, Protein Data Bank, Rutgers University

    Joshua Sakon

  40. Crystal structure of Staphylococcal nuclease mutant V66L/V99I

    Article • October 2006, Protein Data Bank, Rutgers University

    Joshua Sakon

  41. Crystal structure of Staphylococcal nuclease mutant I72L

    Article • October 2006, Protein Data Bank, Rutgers University

    Joshua Sakon

  42. Crystal structure of Staphylococcal nuclease mutant T120C

    Article • October 2006, Protein Data Bank, Rutgers University

    Joshua Sakon

  43. Crystal structure of Staphylococcal nuclease mutant T41S

    Article • October 2006, Protein Data Bank, Rutgers University

    Joshua Sakon

  44. Crystal structure of Staphylococcal nuclease mutant T41V

    Article • October 2006, Protein Data Bank, Rutgers University

    Joshua Sakon

  45. Crystal structure of Staphylococcal nuclease mutant T22V

    Article • October 2006, Protein Data Bank, Rutgers University

    Joshua Sakon

  46. Crystal structure of Staphylococcal nuclease mutant T41C

    Article • October 2006, Protein Data Bank, Rutgers University

    Joshua Sakon

  47. Crystal structure of Staphylococcal nuclease mutant T82S

    Article • October 2006, Protein Data Bank, Rutgers University

    Joshua Sakon

  48. Crystal structure of Staphylococcal nuclease mutant T44V

    Article • October 2006, Protein Data Bank, Rutgers University

    Joshua Sakon

  49. Crystal structure of Staphylococcal nuclease mutant T120S

    Article • October 2006, Protein Data Bank, Rutgers University

    Joshua Sakon

  50. Crystal structure of Staphylococcal nuclease mutant T62S

    Article • October 2006, Protein Data Bank, Rutgers University

    Joshua Sakon

  51. Crystal structure of Staphylococcal nuclease mutant T62V

    Article • October 2006, Protein Data Bank, Rutgers University

    Joshua Sakon

  52. Crystal structure of Staphylococcal nuclease mutant T120V

    Article • October 2006, Protein Data Bank, Rutgers University

    Joshua Sakon

  53. Crystal structure of Staphylococcal nuclease mutant T22C

    Article • October 2006, Protein Data Bank, Rutgers University

    Joshua Sakon

  54. Crystal structure of Staphylococcal nuclease mutant V23L

    Article • October 2006, Protein Data Bank, Rutgers University

    Joshua Sakon

  55. Crystal structure of Staphylococcal nuclease mutant I92V

    Article • October 2006, Protein Data Bank, Rutgers University

    Joshua Sakon

  56. Crystal structure of Staphylococcal nuclease mutant V23L/I72V

    Article • October 2006, Protein Data Bank, Rutgers University

    Joshua Sakon

  57. Crystal structure of Staphylococcal nuclease mutant V66L

    Article • October 2006, Protein Data Bank, Rutgers University

    Joshua Sakon

  58. Crystal structure of Staphylococcal nuclease mutant I72V

    Article • October 2006, Protein Data Bank, Rutgers University

    Joshua Sakon

  59. Crystal structure of Staphylococcal nuclease mutant V23I/L25I/I72V

    Article • October 2006, Protein Data Bank, Rutgers University

    Joshua Sakon

  60. Crystal structure of Staphylococcal nuclease mutant V23L/V66L/I72L

    Article • October 2006, Protein Data Bank, Rutgers University

    Joshua Sakon

  61. Crystal structure of Staphylococcal nuclease mutant V23I/L25I

    Article • October 2006, Protein Data Bank, Rutgers University

    Joshua Sakon

  62. Crystal structure of Staphylococcal nuclease mutant V66I/V99I

    Article • October 2006, Protein Data Bank, Rutgers University

    Joshua Sakon

  63. Crystal structure of Staphylococcal nuclease mutant V66L/I92L

    Article • October 2006, Protein Data Bank, Rutgers University

    Joshua Sakon

  64. Crystal structure of Staphylococcal nuclease mutant V66L/I92V

    Article • October 2006, Protein Data Bank, Rutgers University

    Joshua Sakon

  65. Crystal structure of Staphylococcal nuclease mutant V23I/L25I/V66L/I72L

    Article • October 2006, Protein Data Bank, Rutgers University

    Joshua Sakon

  66. Two hepatitis c virus ns3 helicase domains complexed with the same strand of dna

    Article • December 2005, Protein Data Bank, Rutgers University

    Joshua Sakon

  67. Crystal structure of the cell wall targeting domain of peptidylglycan hydrolase ALE-1

    Article • April 2005, Protein Data Bank, Rutgers University

    Joshua Sakon

  68. Catalytically Enhanced Endocellulase Cel5A from Acidothermus cellulolyticus

    Article • Applied Biochemistry and Biotechnology, January 2005, Springer Science + Business Media

    Joshua Sakon

  69. Proteins with simplified hydrophobic cores compared to other packing mutants

    Article • Biophysical Chemistry, August 2004, Elsevier

    Joshua Sakon

  70. Structure of S. nuclease mutant quintuple mutant V23L/V66L/I72L/I92L/V99L

    Article • June 2003, Protein Data Bank, Rutgers University

    Joshua Sakon

  71. Structure of S. nuclease quintuple mutant V23I/V66L/I72L/I92L/V99L

    Article • June 2003, Protein Data Bank, Rutgers University

    Joshua Sakon

  72. Exploration of Cellulose Surface-Binding Properties of Acidothermus cellulolyticus Cel5A by Site-Specific Mutagenesis

    Article • January 2002, Springer Science + Business Media

    Joshua Sakon

  73. Exploration of Cellulose Surface-Binding Properties of Acidothermus cellulolyticus Cel5A by Site-Specific Mutagenesis

    Article • Applied Biochemistry and Biotechnology, January 2002, Springer Science + Business Media

    Joshua Sakon

  74. Characterization of metal affinity of green fluorescent protein and its purification through salt promoted, immobilized metal affinity chromatography

    Article • Journal of Chromatography A, February 2001, Elsevier

    Joshua Sakon

  75. STRUCTURE OF S. NUCLEASE STABILIZING MUTANT S59A

    Article • October 2000, Protein Data Bank, Rutgers University

    Joshua Sakon

  76. STRUCTURE OF S. NUCLEASE STABILIZING MUTANT T33V

    Article • October 2000, Protein Data Bank, Rutgers University

    Joshua Sakon

  77. STRUCTURE OF S. NUCLEASE STABILIZING MUTANT T41I

    Article • October 2000, Protein Data Bank, Rutgers University

    Joshua Sakon

  78. STRUCTURE OF S. NUCLEASE STABILIZING MUTANT T33V

    Article • October 2000, Protein Data Bank, Rutgers University

    Joshua Sakon

  79. STRUCTURE OF S. NUCLEASE STABILIZING MUTANT S128A

    Article • October 2000, Protein Data Bank, Rutgers University

    Joshua Sakon

  80. STRUCTURE OF S. NUCLEASE STABILIZING QUADRUPLE MUTANT T41I/P117G/H124L/S128A

    Article • October 2000, Protein Data Bank, Rutgers University

    Joshua Sakon

  81. STRUCTURE OF S. NUCLEASE STABILIZING SEXTUPLE MUTANT T33V/T41I/S59A/P117G/H124L/S128A

    Article • October 2000, Protein Data Bank, Rutgers University

    Joshua Sakon

  82. STRUCTURE OF WILD-TYPE S. NUCLEASE AT 1.6 A RESOLUTION

    Article • October 2000, Protein Data Bank, Rutgers University

    Joshua Sakon

  83. STRUCTURE OF S. NUCLEASE STABILIZING TRIPLE MUTANT P117G/H124L/S128A

    Article • October 2000, Protein Data Bank, Rutgers University

    Joshua Sakon

  84. STRUCTURE OF WILD-TYPE S. NUCLEASE AT 1.7 A RESOLUTION

    Article • October 2000, Protein Data Bank, Rutgers University

    Joshua Sakon

  85. STRUCTURE OF S. NUCLEASE STABILIZING QUINTUPLE MUTANT T33V/T41I/P117G/H124L/S128A

    Article • October 2000, Protein Data Bank, Rutgers University

    Joshua Sakon

  86. STRUCTURE OF S. NUCLEASE STABILIZING QUINTUPLE MUTANT T41I/S59A/P117G/H124L/S128A

    Article • October 2000, Protein Data Bank, Rutgers University

    Joshua Sakon

  87. Ab Initio Study of the Conformational Dependence of the Nonplanarity of the Peptide Group

    Article • The Journal of Physical Chemistry A, October 2000, American Chemical Society (ACS)

    Joshua Sakon

  88. ENDOCELLULASE E1 FROM ACIDOTHERMUS CELLULOLYTICUS MUTANT Y245G

    Article • July 1999, Protein Data Bank, Rutgers University

    Joshua Sakon

  89. Structure and mechanism of endo/exocellulase E4 from Thermomonospora fusca

    Article • Nature Structural Biology, October 1997, Nature

    Joshua Sakon

  90. ENDO/EXOCELLULASE:CELLOBIOSE FROM THERMOMONOSPORA

    Article • September 1997, Protein Data Bank, Rutgers University

    Joshua Sakon

  91. ENDO/EXOCELLULASE FROM THERMOMONOSPORA

    Article • September 1997, Protein Data Bank, Rutgers University

    Joshua Sakon

  92. ENDO/EXOCELLULASE:CELLOTRIOSE FROM THERMOMONOSPORA

    Article • September 1997, Protein Data Bank, Rutgers University

    Joshua Sakon

  93. ENDO/EXOCELLULASE:CELLOPENTAOSE FROM THERMOMONOSPORA

    Article • September 1997, Protein Data Bank, Rutgers University

    Joshua Sakon

  94. Polysaccharide hydrolase folds diversity of structure and convergence of function

    Article • Applied Biochemistry and Biotechnology, March 1997, Springer Science + Business Media

    Joshua Sakon

  95. Polysaccharide Hydrolase Folds Diversity of Structure and Convergence of Function

    Article • January 1997, Springer Science + Business Media

    Joshua Sakon

  96. ACIDOTHERMUS CELLULOLYTICUS ENDOCELLULASE E1 CATALYTIC DOMAIN IN COMPLEX WITH A CELLOTETRAOSE

    Article • October 1996, Protein Data Bank, Rutgers University

    Joshua Sakon

  97. Crystal Structure of Thermostable Family 5 Endocellulase E1 fromAcidothermus cellulolyticusin Complex with Cellotetraose†,‡

    Article • Biochemistry, January 1996, American Chemical Society (ACS)

    Joshua Sakon

  98. Molecular structure of kanamycin nucleotidyltransferase determined to 3.0-.ANG. resolution

    Article • Biochemistry, November 1993, American Chemical Society (ACS)

    Joshua Sakon

  99. Crystallization and preliminary crystallographic analysis of a thermostable mutant of kanamycin nucleotidyltransferase

    Article • Archives of Biochemistry and Biophysics, May 1992, Elsevier

    Joshua Sakon

  100. Catalytically Enhanced Endocellulase CeI5A from Acidothermus cellulolyticus

    Article • Springer Science + Business Media

    Joshua Sakon