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Abstract The exon junction complex (EJC) is conserved across eukaryotes and is involved in metabolism of post-transcriptional mRNAs, including mRNA localization, alternative splicing, nonsense mediated decay (NMD), and nuclear export. It consists of a core protein cluster including Mago, Y14, eIF4AIII, and Btz. Mago and Y14 form a heterodimer, and UPF3, a protein triggering NMD, binds to the C-terminus of Y14 in the heterodimer. This signals the degradation of mRNAs with premature termination codons (PTCs). A mutation, hap1-2, was created by a T-DNA insertion (sail_269_C02) in the Arabidopsis Mago protein coding gene, which introduced a PTC. This alternative transcript can be translated into a truncated protein, AtMagoΔC. In vitro pull-down assay showed that the C-terminal domain of AtMago is required for the Y14-Mago heterodimer. Heterozygous mutants (qrt;hap1-2/+) exhibited abnormal nuclear distribution or lack of nuclei in pollen grains and the mutant pollen eventually aborted. The phenotypic changes due to the hap1-2 mutation were most prominent in haploid cells because the genotype is no longer masked as in the heterozygous form. A chromosome spread technique was used to examine meiosis in both wild-type and mutant anthers with DAPI. Preliminary results found an abnormal chromosome distribution pattern during metaphase II in some mutants, but not in the wild-type. In conclusion, we hypothesize that the hap1-2 mutation prevents the formation of the Mago-Y14 heterodimer, which hinders UPF3 from tethering to the EJC. This causes PTC-containing transcripts to escape from surveillance and leads to faulty proteins disturbing critical bioprocesses, such as meiosis. Our goal is to determine the mechanism that causes only some of the chromosomes to lose their ability to separate correctly during meiosis. We are in the process of quantifying meiotic abnormality associated with the hap1-2 mutation. Effects of AtMago∆C mutation on EJC function during Arabidopsis thaliana pollen development Sarah Metcalfe, Zachary Mazanek, Meera Babu, Kevin Cilano, Aubrie Russell, Xiao-Ning Zhang Department of Biology, St. Bonaventure University, St. Bonaventure, N.Y. 14778 Conclusions and Future Work • There is an abnormal distribution of chromosomes in metaphase II of the hap1-2/+ male gametes • The hap1-2 mutation prevents the formation of the Mago-Y14 heterodimer, which may stop UPF3 from binding to the EJC. This results in transcripts with PTCs being translated and not degraded. These misfolded proteins could disrupt normal processes like meiosis. • Our goal is to find out the mechanism of this mutation that causes only some of the proteins to separate incorrectly. • We also would like to find any other defects caused by the truncated AtMago protein. References • Bono, F., Ebert, J., Lorentzen, E., & Conti, E. (2006). Cell, 126, 713-725. http://dx.doi.org/10.1016/j.cell. 2006.08.006 . • Buchwald, G., Ebert, J., Basquin, C., Sauliere, J., Jayachandran, U., Bono, F.,Conti,E.(2010).PNAS,107(22), 10050-10055. • Ross, K. J., Fransz, P., & Jones, G. H. (1996). Figure 3. AtY14 only binds to full length AtMago. Figure 1. Structure of the EJC. A. The core complex of the EJC binding to RNA and ATP (Bono, et al., 2006). B. UPF3b binding to the Mago-Y14 heterodimer (Buchwald et al. 2010) . C. Full length AtMago protein with 6 β- sheets and 3 α-helices. D. AtMagoΔC protein with the C terminus end truncated leaving 4β-sheets and one α- helix (Shi and Xu 2003). B. C. D . Figure 4. Meiosis in wildtype (qrt) Arabidopsis Thaliana. Prepared by a chromosome spread technique and stained with DAPI. Bar = 10μm Figure 5. Meiosis in mutant (qrt;hap1-2/+) Arabidopsis thaliana. Prepared by a chromosome spread technique and stained with DAPI. Bar = 10μm A. Figure 2. A. Location of hap1-2 mutation. B. Pollen grains in bright field (left panel) and pollen grains stained with DAPI (right panels). Bar = 20μm. Abnormal nuclei indicated by *. T-DNA insertion (sail_269_C02) Normal splicin g Splicing of hap1-2 mutant Normal length protein Truncate d Protein 5’ 3 ’ 5’ 5 ’ 3 ’ 3 ’ A. B.
