Areas of Activity#

• 1972-1974 Part time teaching positions at Depts. of Anatomy, Medical and Physiological Chemistry, and Physiology Go to
  Fields of Scholarship

• 1975-1980 Graduate student scholarship at Dept of Medical and Physiological Chemistry combined with a part time teaching position Go to

• 1980 Research Assistant at Dept of Medical and Physiological Chemistry Go to

• 1981 Lecturer at Dept of Medical and Physiological Chemistry Go to

• Adenoviral proteome Go to

• Adenovirus Go to

• Adhesion molecules Go to

• Adhesion Signalling Go to

• Aging und adaptation of the cardiovascular system Go to

• Amino acid and phenylpropanoid biosynthesis Go to

• Anaerobic ammonium oxidation Go to

• Anaerobic methane oxidation Go to

• Apoptosis Go to

• Basic and clinical aspects of cancer Go to

• Basic and clinical immunology Go to

• Biochemical effects of mutations Go to

• biochemistry & cell biology Go to

• Biochemistry Go to

• biochemistry Go to

• Bioinformatics Go to

• biology Go to

• Biology Go to

• Biology Go to

• Biophysics Go to

• Biophysics: Neefjes developed various technologies to measure FRET and FRAP for single cell biochemistry. Go to

• Biosynthesis of alkaloids Go to

• Biosythesis of dyes and terpenes in plants Go to

• Bladder cancer Go to

• Caenorhabditis elegans Go to

• Cancer Go to

• cancer research Go to

• Cancer Stem Cells Go to

• Cancer therapy Go to

• Cancer: utilizing biophysics showed conformational changes estrogen receptor and deciphered new resistance mechanism Go to

• cardiovascular research Go to

• cell adhesion Go to

• Cell and Developmental Biology Go to

• Cell and gene therapy Go to

• cell biology Go to

• Cell biology Go to

• Cell biology Go to

• Cell Biology Go to

• Cell Biology: identified MHC class I and MHC class II cell biology, dynein motor control of vesicles, PI3kinase in MVB biogeneses Go to

• cell biology, immunology Go to

• Cell cycle checkpoints Go to

• cell cycle control Go to

• Cell cycle control Go to

• Cell Cycle Control Go to

• cell cycle Go to

• Cell cycle regulation Go to

• cell & developmental biology Go to

• Cell Differentiation Go to

• Cell fate determination Go to

• Cell Migration, Cell Proliferation and Signaling Go to

• cell & molecular biology Go to

• cell recognition Go to

• cell reproduction Go to

• Cell Therapy Go to

• Chemical Biology: developed reciprocal chemical genetics to find host targets controlling bacterial infections and lead structures Go to

• Chemistry: Neefjes applies chemistry in cell biology. Generated first inhibitors for TAP and for host factor antibiotics Go to

• Cholesterol dysfunction Go to

• Chromatin replication Go to

• Chromosomal Translocations Go to

• Chromosome pairing and recombination during meiosis Go to

• chromosome segregation Go to

• Classical biology Go to

• clinical chemistry (clinical pathology) Go to

• clinical immunology Go to

• Cloning Go to

• cohesins Go to

• Colorectal cancers Go to

• Computational biology and medicine Go to

• Control of gene expression Go to

• Cyclin proteolysis Go to

• Cytotoxic T cells Go to

• developmental biology & genetics Go to

• Developmental biology Go to

• developmental biology Go to

• Developmental Biology Go to

• Developmental biology Go to

• Developmental biology Go to

• developmental biology, mouse genetics Go to

• developmental genetics Go to

• Development of electron microscope tomography Go to

• Development of structured controlled vocabularies (ontologies) for use in the context of biological databases Go to

• Differentiation Go to

• Discovering a novel type regulatory RNA - siRNA Go to

• discovery of the human immunodeficiency virus (HIV) Go to

• DNA damage Go to

• DNA profiling Go to

• Double helix structure of DNA Go to

• Ecology Go to

• Endothelial cells Go to

• enhancement of the immune response and its relevance to vaccines Go to

• Enzyme inhibitors Go to

• Epidermis Go to

• Epigenetic control of gene expression Go to

• Epigenetics Go to

• Epithelial Cancer Go to

• Epithelial cells Go to

• Epithelial-mesenchymal interactions Go to

• Establishment of cell polarity in Drosophila Go to

• exploring the possible clinical utility of signal transduction antagonists Go to

• Extravasation of lymphocytes Go to

• Field cancerization Go to

• Formation of morphine in mammals and in the human organism Go to

• formation of new blood vessels (angiogenesis) Go to

• gametogenesis Go to

• Gene expression Go to

• genetic aspects of tumor biology Go to

• Genetic fingerprinting Go to

• Genetic mechanisms existing in bacteria and bacteriophages Go to

• Genetics Go to

• genetics Go to

• genetics, immunology Go to

• Genome organization and evolution in Drosophila Go to

• genome organization and stability Go to

• Genomics Go to

• G protein-coupled receptors Go to

• Growth and cell migration in the zebrafish Go to

• Hair follicle Go to

• Hematology Go to

• Hereditary diseases Go to

• High throughput screenings: Neefjes performed various genetic and chemical screens to successfully find new targets and leads Go to

• Host cell gene expression Go to

• Human genetics Go to

• Huntington's disease Go to

• immunology, cancer biology Go to

• Immunology Go to

• Immunology Go to

• Immunology Go to

• immunology Go to

• Immunology Go to

• immunology Go to

• Immunology Go to

• Immunology: Mechanisms of control of MHC class I and MHC class II expression, bacterial control phagosomes Go to

• immunopathology, particularly in relation to systemic LE and to multiple sclerosis Go to

• Induction Go to

• Inflammation Go to

• insect sting allergy Go to

• Keratinocytes Go to

• Kinases Go to

• Lymphendothelial cells Go to

• Lymphocytes Go to

• Lymphocyte trafficking Go to

• mammalian genetics Go to

• medical genetics Go to

• Medical genomics Go to

• meiosis Go to

• meiosis Go to

• Metagenomics of complex microbial communities Go to

• Microbial ecology of anaerobic micro organism Go to

• microbial immunology. Particular topics include microbial subversion of the innate immune response and the immunology of measles Go to

• Microbial physiology of nitrogen and methane cycle bacteria Go to

• Microbiology Go to

• microbiology Go to

• Microbiology Go to

• microbiology Go to

• Microbiology, Tumour and Cell Biology Go to

• Mitosis Go to

• Molecular and genetic analysis of development Go to

• Molecular Biology Go to

• molecular biology Go to

• molecular biology Go to

• molecular biology Go to

• molecular biology Go to

• Molecular biology Go to

• Molecular Cell Biology Go to

• Molecular cell biology Go to

• Molecular Cell Biology Go to

• Molecular control of heart and skeletal muscle development Go to

• Molecular developmental biology Go to

• molecular endocrinology Go to

• molecular machinery that drives cell division and controls cell shape Go to

• molecular medicine Go to

• Molecular Medicine: Neefjes applied cell biology and next generation sequencing to find new modes of actions of anticancer drug Go to

• Molecular Neurobiology Go to

• molecular pharmacology Go to

• molecular plant genetics Go to

• Morphogenesis Go to

• Morphogenesis Go to

• Mouse genetics Go to

• Muscle Cell Biology (Skeletal and Cardiac Muscle) Go to

• Muscle development Go to

• Muscle Physiology Go to

• myogenic cell lineages Go to

• Nanobiology Go to

• Nature and fate of transcription products Go to

• Nervous system development Go to

• Neural development (developmental neurobiology) Go to

• Neurodegenerative diseases Go to

• neurodegenerative diseases Go to

• Neuroendocrine Signaling Go to

• Niche Go to

• Notch Go to

• Nuclear transplantation Go to

• oogenesis Go to

• Papilloma virus Go to

• Pathology Go to

• Pattern formation Go to

• Physiology Go to

• Phytochelatins Go to

• pioneer in the area of cellular biology Go to

• Plant biology Go to

• plant developmental biology Go to

• plant ecophysiology Go to

• plant genetics Go to

• Plant hormones Go to

• Plant metabolism Go to

• plant molecular biology Go to

• Plant physiology Go to

• Plant physiology Go to

• plant science Go to

• Prep1 transcription factor in mammalian development and regulation of Hox activity Go to

• protein-dna interactions Go to

• Protein Engineering Go to

• Protein signaling in cells Go to

• Proteomic strategies in health and disease Go to

• Regeneration Go to

• Regulation of gene expression Go to

• Regulation of genetic activity Go to

• Retro viral oncogenes Go to

• Retro viral oncogenes Go to

• role of pericytes (smooth muscle-like cells in microvessels) in vessel integrity Go to

• Signal transduction Go to

• Skin Go to

• Somatic mutations Go to

• spindle assembly checkpoint Go to

• Spindle assembly Go to

• Stem cell biology Go to

• Stem Cell Biology Go to

• Stem cell biology Go to

• Stem cell commitment in hematopoiesis Go to

• Stem cell neurobiology and differentiation Go to

• Stem cell research Go to

• Stem cells and the regeneration of contractile tissues Go to

• Stem cells Go to

• Stem cells Go to

• Structural Biology Go to

• structure and biology of basement membranes Go to

• synaptonemal complex Go to

• Systems Biology: Neefjes has performed integrated screens to generate new biology that was experimentally validated Go to

• Taxonomy Go to

• Telomeres and genome stability in ageing Go to

• the cell cycle in yeast Go to

• the immunochemistry, biology and genetics of the complement system Go to

• the pathophysiology of AIDS Go to

• the PDGF receptor Go to

• Thymus Go to

• Tissue Regeneration Go to

• Transcellular migration Go to

• Transcriptional regulation Go to

• Transcriptional regulation of urokinase (uPA) gene expression Go to

• Transplantation Go to

• Tropical diseases Go to

• Tumor biology Go to

• tumor biology Go to

• Tyrosine phosphorylation Go to

• Urinary proteome Go to

• Virology Go to

• virology Go to

• virology Go to

• virology Go to

• virology Go to

• virology Go to

• Virology Go to

• virology Go to