Do Reactive Oxygen Species Cause Aging? / 한양의대학술지

No abstract available.

Reactive Oxygen Species and Cellular Function Switch / 한양의대학술지

Reactive oxygen species (ROS) are harmful to cellular components such as proteins, DNA and lipids. The continuous production of ROS during the respiratory electron transfer process has been regarded as the major cause of aging. However, the discoveries of proteins whose structure and function switch with cellular ROS suggest that ROS are active players in cellular regulation. OxyR is the first protein whose ROS-regulated mechanism was revealed by the atomic structure studies. The distantly-located two cysteines in OxyR form a disulfide bond by reaction with ROS, resulting in conformational and functional switches in the protein. The heat shock protein 33 is another protein that is activated by increased level of cellular ROS. Many other cellular proteins including protein tyrosine phosphatases are also regulated by ROS. This review focuses on the structure and function of the ROS-regulated proteins and their implications on the ROS's cellular roles. Detailed studies on the ROS-generating protein machinery and the ROS-regulated proteins should contribute to the therapeutic control of ROS-related diseases and aging processes.

Homophilic interaction of the L1 family of cell adhesion molecules

Homophilic interaction of the L1 family of cell adhesion molecules plays a pivotal role in regulating neurite outgrowth and neural cell networking in vivo. Functional defects in L1 family members are associated with neurological disorders such as X-linked mental retardation, multiple sclerosis, low-IQ syndrome, developmental delay, and schizophrenia. Various human tumors with poor prognosis also implicate the role of L1, a representative member of the L1 family of cell adhesion molecules, and ectopic expression of L1 in fibroblastic cells induces metastasis-associated gene expression. Previous studies on L1 homologs indicated that four N-terminal immunoglobulin-like domains form a horseshoe-like structure that mediates homophilic interactions. Various models including the zipper, domain-swap, and symmetry-related models are proposed to be involved in structural mechanism of homophilic interaction of the L1 family members. Recently, cryo-electron tomography of L1 and crystal structure studies of neurofascin, an L1 family protein, have been performed. This review focuses on recent discoveries of different models and describes the possible structural mechanisms of homophilic interactions of L1 family members. Understanding structural mechanisms of homophilic interactions in various cell adhesion proteins should aid the development of therapeutic strategies for L1 family cell adhesion molecule-associated diseases.