RNA association defines a functionally conserved domain in the nuclear pore protein Nup153.

Traffic between the nucleus and cytoplasm takes place through a macromolecular structure termed the nuclear pore complex. To understand how the vital process of nucleocytoplasmic transport occurs, the contribution of individual pore proteins must be elucidated. One such protein, the nucleoporin Nup153, is localized to the nuclear basket of the pore complex and has been shown to be a central component of the nuclear transport machinery. Perturbation of Nup153 function was demonstrated previously to block the export of several classes of RNA cargo. Moreover, these studies also showed that Nup153 can stably associate with RNA in vitro. In this study, we have mapped a domain within Nup153, encompassing amino acids 250-400 in human Nup153, that is responsible for RNA association. After cloning this region of Xenopus Nup153, we performed a cross-species analysis. Despite variation in sequence conservation between Drosophila, Xenopus, and human, this domain of Nup153 displayed robust RNA binding activity in each case, indicating that this property is a hallmark feature of Nup153 and pointing toward a subset of amino acid residues that are key to conferring this ability. We have further determined that a recombinant fragment of Nup153 can bind directly to RNA and that this fragment can interact with endogenous RNA targets. Our findings identify a functionally conserved domain in Nup153 and suggest a role for RNA binding in Nup153 function at the nuclear pore.

A point mutation in beta2-microglobulin results in loss of epitope expression.

A common tool in studying the structure and function of major histocompatibility complex: (MHC) class I is the generation and analysis of beta2-microglobulin (beta2m) mutations. beta2m has been shown to affect proper class I antigen presentation at the level of structural functionality. Many studies characterizing beta2m function in class I presentation have used antibody-based assays. Monitoring the effect of beta2m mutation on antibody epitope expression, therefore, is essential in being able to truly characterize the impact of a mutant interaction between beta2m and class I. Here we describe a mutant beta2m molecule, beta2m #32, that in association with class I loses reactivity with the human beta2m-specific monoclonal antibody, BBM.1. However, the BBM.1 epitope remains intact when beta2m #32 is free from class I association.

Effects of beta2-microglobulin mutations on the alpha-1 helical region of H2-Ld.

Beta-2 microglobulin (beta2m)has been shown to have an effect on the structural and functional constraints that facilitate proper class I antigen presentation. To date, no evidence has pinpointed the beta2m-specific amino acids that play an integral role in affecting structure in and around the peptide binding region of class I. To delineate beta2m amino acid positions that affect the alpha-1 helical region, we generated a series of mutant beta2m proteins bearing precise amino acid substitutions. The amino acid positions chosen were based upon previous results which demonstrated that human beta2m association with H2-Ld altered the structure of the alpha-1/alpha-2 super-domain. beta2m mutant proteins were used in beta2m exchange assays with cells expressing H2-Ld. Following exchange, cells were assayed to determine whether mutant beta2m association resulted in structural alteration of class I extracellular domains. The alteration in H2-Ld structure was evidenced by an increase in the binding of an antibody (34-1-2), specific for the alpha-1 helical region of H2-Ld. Results demonstrated that amino acid substitutions in beta2m positions 33 and 53 led to a dramatic increase in the reactivity of the alpha-1 domain-specific antibody 34-1-2. Identifying beta2m amino acid positions that influence the structure of the peptide binding region may allow for a better understanding of cellular immune responses that center upon class I/beta2m expression.