Myeong-Su Kim

Structural modifications of outer membrane vesicles to refine them as vaccine delivery vehicles.

In an effort to devise a safer and more effective vaccine delivery system, outer membrane vesicles (OMVs) were engineered to have properties of intrinsically low endotoxicity sufficient for the delivery of foreign antigens. Our strategy involved mutational inactivation of the MsbB (LpxM) lipid A acyltransferase to generate OMVs of reduced endotoxicity from Escherichia coli (E. coli) O157:H7. The chromosomal tagging of a foreign FLAG epitope within an OmpA-fused protein was exploited to localize the FLAG epitope in the OMVs produced by the E. coli mutant having the defined msbB and the ompA::FLAG mutations. It was confirmed that the desired fusion protein (OmpA::FLAG) was expressed and destined to the outer membrane (OM) of the E. coli mutant from which the OMVs carrying OmpA::FLAG are released during growth. A luminal localization of the FLAG epitope within the OMVs was inferred from its differential immunoprecipitation and resistance to proteolytic degradation. Thus, by using genetic engineering-based approaches, the native OMVs were modified to have both intrinsically low endotoxicity and a foreign epitope tag to establish a platform technology for development of multifunctional vaccine delivery vehicles.

Identification of novel retromer complexes in the mouse testis

A family of vacuolar protein sorting (Vps) proteins, which are components of mammalian retromer complex, has been studied in the mouse. Vps26a is known as a retromer component that plays an important role in embryonic development: however, its cell-type expression and precise role remain to be elucidated. In this study, we identified a new isoform of Vps26a, called Vps26aT, which was expressed specifically in the mouse testis. Diverse expression patterns of Vps26 variants in mouse tissues were determined by Western blot and RT-PCR analyses, and the direct interaction of Vps26aT with Vps35 was also demonstrated by immunoprecipitation and pull-down assay using antibodies raised against each Vps component. Our results revealed that the retromer complex could be formed from different Vps26 isoforms in a tissue-specific manner, resulting in more than two types of the retromer complex, including the Vps26a-Vps29-Vps35, Vps26aT-Vps29-Vps35, and Vps26b-Vps29-Vps35 complexes in mouse tissues.

Alu-derived old world monkeys exonization event and experimental validation of the LEPR gene

The leptin receptor (LEPR) is a crucial regulatory protein that interacts with Leptin. In our analysis of LEPR, novel AluJb-derived alternative transcripts were identified in the genome of the rhesus monkey. In order to investigate the occurrence of AluJb-derived alternative transcripts and the mechanism underlying exonization events, we conducted analyses using a number of primate genomic DNAs and adipose RNAs of tissue and primary cells derived from the crab-eating monkey. Our results demonstrate that the AluJb element has been integrated into our common ancestor genome prior to the divergence of simians and prosimians. The lineage-specific exonization event of the LEPR gene in chimpanzees, orangutans, and Old World monkeys appear to have been accomplished via transition mutations of the 5′ splicing site (second position of C to T). However, in New World monkeys and prosimians, the AluJb-related LEPR transcript should be silenced by the additional transversion mutation (fourth position of T to G). The AluJb-related transcript of human LEPR should also be silenced by a mutation of the 5′ splicing site (first position of G to A) and the insertion of one nucleotide sequence (minus fourth position of A). Our data suggests that lineage-specific exonization events should be determined by the combination event of the formation of splicing sites and protection against site-specific mutation pressures. These evolutionary mechanisms could be major sources for primate diversification.

Processing and subcellular localization of ADAM2 in the Macaca fascicularis testis and sperm

Fertilin, a heterodimeric protein complex composed of ADAM1 and ADAM2 located on the sperm surface, is involved in sperm-egg interaction. In our study, we examined the physiological processing and subcellular localization of M. fascicularis ADAM2 during spermatogenesis in the testis and epididymal tract. M. fascicularis ADAM2 was initially synthesized as a 100 kDa precursor in testicular germ cells. After passing into 50 kDa intermediate form in the epididymal tracts, the precursor form was finally processed into a 47 kDa protein in sperm. We found that M. fascicularis ADAM2 is localized on the sperm surface and contributes to the formation of a candidate fertilin complex. In particular, Far-Western blot analysis revealed that M. fascicularis ADAM2 cystein-rich domain may be related to protein-protein interaction. Therefore, the cystein-rich domain of ADAM2 could provide a mechanism to form a fertilin complex.