Harvard University Office of Technology Development Collaborative Research Opportunity Finder

1. Jonathan Beckwith, PhD

   Study cellular processes in bacteria: protein folding, reduction and formation of protein disulfide bonds, membrane protein dynamics

   Investigate fundamental molecular processes, including protein folding and disulfide bond formation, using E. coli as a model system

   

2. Howard Berg, PhD

   Bacterial Motility: Motor Response Based on Sensory Input

   The Berg lab studies the motile behavior of bacteria in order to understand how cells sense and respond to changes in their environment. Processing external cues is a problem encountered by ...

   

3. Philippe Cluzel, PhD

   Real-time analysis of signal transduction and genetic networks at the single cell level

   Investigating genome-wide transcriptional dynamics, and studying multi-drug resistance in bacteria.

   

4. Nancy Kleckner, PhD

   Chromosome dynamics across kingdoms

   Investigation of the molecular and physical underpinnings of basic chromosomal processes.

   

Research Categories

Infectious Disease

Research Tools and Instrumentation

Sub-categories

1. Microorganism

   1. Antibiotic resistance»
   2. Aspergillus»
   3. Bacillus subtilis»
   4. Chlamydia»
   5. Escherichia coli (E. coli)»
   6. Fungus»
   7. Gram-negative bacteria»
   8. Gram-positive bacteria»
   9. mar operon»
   10. Opportunistic pathogen»
   11. Parasites»
   12. Pathogen»
   13. Proteus mirabilis»
   14. Salmonella»
   15. Staphylococcus aureus (S. aureus)»
   16. Viral structure»
   17. Virus entry»

2. Research Tools; Animal and Cell Models; Unique Resources

   1. 3-dimensional basement membrane cell cultures»
   2. Adeno-associated virus (AAV)»
   3. Alexa Fluor dyes»
   4. Artificial tether»
   5. Auditory enrichment»
   6. Automated zebrafish screening»
   7. Automation»
   8. Behavior model»
   9. Biocomputational methods»
   10. Bioinformatics»
   11. Brain plasticity»
   12. Brainbow system»
   13. C. elegans»
   14. Ca2+-GFP-Aequorin»
   15. Calcium indicators»
   16. cDNA libraries from single neurons»
   17. cell culture in linear micro-colonies»
   18. Cell-based assays»
   19. Cellular ablation»
   20. Computer-assisted image analysis»
   21. Cryo-Electron Tomography»
   22. Cyanobacteria»
   23. Drosophila»
   24. Drosophila RNAi Screening Center»
   25. Escape behavior»
   26. Escherichia coli (E. coli)»
   27. FACS analysis»
   28. Genetically-encoded biosensor»
   29. Genome mining»
   30. High resolution transcriptome sequencing»
   31. High Throughput Screening»
   32. Human cells»
   33. Insomnia model»
   34. Interactive computer software»
   35. Knockout mouse»
   36. Lab-On-A-Chip»
   37. Mammalian cells»
   38. Microorganism»
   39. Molecular modeling»
   40. Monkey»
   41. Mouse behavior»
   42. Mouse imaging»
   43. Mouse models»
   44. Mouse tumor models»
   45. Multiphoton laser scanning microscopy»
   46. Natural host»
   47. Neuronal recordings»
   48. Non-human primate»
   49. Odor map»
   50. Odor-guided perceptual decision task»
   51. OMP-ChR2 mice»
   52. Optogenetics»
   53. Physics»
   54. Primate Model»
   55. Protein and small molecule production»
   56. Rabies vector»
   57. Recombinant toxins»
   58. Retrogenic mouse»
   59. Retroviral vector»
   60. Reward-based decision making and learning»
   61. Reward-based learning and decision-making assays»
   62. Rhesus macaque»
   63. S. cerevisiae»
   64. S. pombe»
   65. Short and long-term olfactory memory tests»
   66. Sooty mangabey»
   67. SpH mice»
   68. Tissue engineering»
   69. Transcriptome comparisons»
   70. Transgenic mice»
   71. Transgenic mouse»
   72. Transgenic zebrafish»
   73. Video microscopy»
   74. Visual deprivation»
   75. Widefield FCS»
   76. Xenopus tadpoles»
   77. Yeast»
   78. Yeast microbiology»
   79. Zebrafish larvae»
   80. Zebrafish models»