Developing Connections Between LINC00298 RNA and Alzheimer's Disease Through Mapping Its Interactome and Through Biochemical Characterization.

BACKGROUND: Long non-coding RNAs are ubiquitous throughout the human system, yet many of their biological functions remain unknown. LINC00298 RNA, a long intergenic non-coding RNA, has been shown to have preferential expression in the central nervous system where it contributes to neuronal differentiation and development. Furthermore, previous research has indicated that LINC00298 RNA is known to be a genetic risk factor for the development of Alzheimer's disease. OBJECTIVE: To biochemically characterize LINC00298 RNA and to elucidate its biological function within hippocampal neuronal cells, thereby providing a greater understanding of its role in Alzheimer's disease pathogenesis. METHODS: LINC00298 RNA was in vitro transcribed and then subjected to structural analysis using circular dichroism, and UV-Vis spectroscopy. Additionally, affinity column chromatography was used to capture LINC00298 RNA's protein binding partners from hippocampal neuronal cells, which were then identified using liquid chromatography and mass spectrometry (LC/MS). RESULTS: LINC00298 RNA is comprised of stem-loop secondary structural elements, with a cylindrical tertiary structure that has highly dynamic regions, which result in high positional entropy. LC/MS identified 24 proteins within the interactome of LINC00298 RNA. CONCLUSION: Through analysis of LINC00298 RNA's 24 protein binding partners, it was determined that LINC00298 RNA may play significant roles in neuronal development, proliferation, and cellular organization. Furthermore, analysis of LINC00298 RNA's interactome indicated that LINC00298 RNA is capable of intracellular motility with dual localization in the nucleus and the cytosol. This biochemical characterization of LINC00298 RNA has shed light on its role in Alzheimer's disease pathogenesis.

Characterization of tRNALeu binding interactions with Cu2+ and Pb2+ and their biological implications.

RNA is known to interact with Mg2+ when assuming higher-ordered tertiary configurations. Structurally, when tRNA molecules interact with Mg2+, they consistently form a "L-shape" conformation each time they are synthesized. Therefore, if Mg2+ can induce tertiary structure formation, then binding to alternative cations could produce alternative tertiary configurations. By utilizing circular dichroism and mobility gel-shift assays it was observed that tRNA structure can be altered when in the presence of different divalent cationic species. Formation of these alternative structural configurations was further validated by aminoacylating these tRNA structural anomalies with their native enzyme, which resulted in markedly different degrees of activity. Thus, it was confirmed that structural changes do occur when tRNA forms complexes with different cations. To better understand these structural changes, quantitative cation binding to tRNA was determined through titrations as well as ICP-OES analysis, which indicated that the metal ions can bind to the tRNA structure in specific and non-specific ways. Lastly, it was observed through stopped-flow kinetics that tRNA can associate/dissociate from different cations to varying degrees, thus forming cation-specific complexes at unique rates.

Zinc is the molecular "switch" that controls the catalytic cycle of bacterial leucyl-tRNA synthetase.

The Escherichia coli (E. coli) leucyl-tRNA synthetase (LeuRS) enzyme is part of the aminoacyl-tRNA synthetase (aaRS) family. LeuRS is an essential enzyme that relies on specialized domains to facilitate the aminoacylation reaction. Herein, we have biochemically characterized a specialized zinc-binding domain 1 (ZN-1). We demonstrate that the ZN-1 domain plays a central role in the catalytic cycle of E. coli LeuRS. The ZN-1 domain, when associated with Zn(2+), assumes a rigid architecture that is stabilized by thiol groups from the residues C159, C176 and C179. When LeuRS is in the aminoacylation complex, these cysteine residues form an equilateral planar triangular configuration with Zn(2+), but when LeuRS transitions to the editing conformation, this geometric configuration breaks down. By generating a homology model of LeuRS while in the editing conformation, we conclude that structural changes within the ZN-1 domain play a central role in LeuRS's catalytic cycle. Additionally, we have biochemically shown that C159, C176 and C179 coordinate Zn(2+) and that this interaction is essential for leucylation to occur, but is not essential for deacylation. Furthermore, calculated Kd values indicate that the wild-type enzyme binds Zn(2+) to a greater extent than any of the mutant LeuRSs. Lastly, we have shown through secondary structural analysis of our LeuRS enzymes that Zn(2+) is an architectural cornerstone of the ZN-1 domain and that without its geometric coordination the domain collapses. We believe that future research on the ZN-1 domain may reveal a possible Zn(2+) dependent translocation mechanism for charged tRNA(Leu).