Low-density lipoprotein receptor overexpression enhances the rate of brain-to-blood Aß clearance in a mouse model of ß-amyloidosis.

The apolipoprotein E (APOE)-ε4 allele is the strongest genetic risk factor for late-onset, sporadic Alzheimer's disease, likely increasing risk by altering amyloid-ß (Aß) accumulation. We recently demonstrated that the low-density lipoprotein receptor (LDLR) is a major apoE receptor in the brain that strongly regulates amyloid plaque deposition. In the current study, we sought to understand the mechanism by which LDLR regulates Aß accumulation by altering Aß clearance from brain interstitial fluid. We hypothesized that increasing LDLR levels enhances blood-brain barrier-mediated Aß clearance, thus leading to reduced Aß accumulation. Using the brain Aß efflux index method, we found that blood-brain barrier-mediated clearance of exogenously administered Aß is enhanced with LDLR overexpression. We next developed a method to directly assess the elimination of centrally derived, endogenous Aß into the plasma of mice using an anti-Aß antibody that prevents degradation of plasma Aß, allowing its rate of appearance from the brain to be measured. Using this plasma Aß accumulation technique, we found that LDLR overexpression enhances brain-to-blood Aß transport. Together, our results suggest a unique mechanism by which LDLR regulates brain-to-blood Aß clearance, which may serve as a useful therapeutic avenue in targeting Aß clearance from the brain.

Quantitative proteomic analysis of distinct mammalian Mediator complexes using normalized spectral abundance factors.

Components of multiprotein complexes are routinely determined by using proteomic approaches. However, this information lacks functional content except when new complex members are identified. To analyze quantitatively the abundance of proteins in human Mediator we used normalized spectral abundance factors generated from shotgun proteomics data sets. With this approach we define a common core of mammalian Mediator subunits shared by alternative forms that variably associate with the kinase module and RNA polymerase (pol) II. Although each version of affinity-purified Mediator contained some kinase module and RNA pol II, Mediator purified through F-Med26 contained the most RNA pol II and the least kinase module as demonstrated by the normalized spectral abundance factor approach. The distinct forms of Mediator were functionally characterized by using a transcriptional activity assay, where F-Med26 Mediator/RNA pol II was the most active. This method of protein complex visualization has important implications for the analysis of multiprotein complexes and assembly of protein interaction networks.

Principles and applications of multidimensional protein identification technology.

Multidimensional chromatography coupled to tandem mass spectrometry is an emerging technique for the analysis of proteomes and is rapidly being implemented by many researchers for proteomic analysis. In this technology profile, a particular proteomic approach known as multidimensional protein identification technology (MudPIT) is discussed. In MudPIT, a biphasic microcapillary column is packed with high-performance liquid chromatography grade reversed phase and strong cation exchange packing materials, loaded with a complex peptide mixture and placed in line with quaternary high-performance liquid chromatography and a tandem mass spectrometer. MudPIT has the capability to analyze highly complex proteomic mixtures such as whole proteomes, organelles and protein complexes.

Stem of SL1 RNA in HIV-1: structure and nucleocapsid protein binding for a 1 x 3 internal loop.

The 5'-leader of HIV-1 RNA controls many viral functions. Nucleocapsid (NC) domains of gag-precursor proteins select genomic RNA for packaging by binding several sites in the leader. One is likely to be a stem defect in SL1 that can adopt either a 1 x 3 internal loop, SL1i (including G247, A271, G272, G273) or a 1 x 1 internal loop (G247 x G273) near a two-base bulge (A269-G270). It is likely that these two conformations are both present and exchange readily. A 23mer RNA construct described here models SL1i and cannot slip into the alternate form. It forms a 1:1 complex with NCp7, which interacts most strongly at G247 and G272 (K(d) = 140 nM). This demonstrates that a linear G-X-G sequence is unnecessary for high-affinity binding. The NMR-based structure shows an easily broken G247:A271 base pair. G247 stacks on both of its immediate neighbors and A271 on its 5'-neighbor; G272 and G273 are partially ordered. A bend in the helix axis between the SL1 stems on either side of the internal loop is probable. An important step in maturation of the virus is the transition from an apical loop-loop interaction to a dimer involving intermolecular interactions along the full length of SL1. A bend in the stem may be important in relieving strain and ensuring that the strands do not become entangled during the transition. A stem defect with special affinity for NCp7 may accelerate the rate of the dimer transformation. This complex could become an important target for anti-HIV drug development, where a drug could exert its action near a high-energy intermediate on the pathway for maturation of the dimer.

Affinities of the nucleocapsid protein for variants of SL3 RNA in HIV-1.

Efficient packaging of genomic RNA into new HIV-1 virus particles requires that nucleocapsid domains of precursor proteins bind the SL3 tetraloop (G317-G-A-G320) from the 5'-untranslated region. This paper presents the affinities of 35 RNA variants of SL3 for the mature 55mer NC protein, as measured by fluorescence quenching of tryptophan-37 in the protein by nucleobases. The 1:1 complexes that form in 0.2 M NaCl have dissociation constants ranging from 8 nM (GGUG) to 20 microM (GAUA). The highly conserved (GGAG) sequence for the wild type is not the most stable (K(d) = 28 nM), suggesting that other selective pressures beyond the stability of the complex must be satisfied. The leading requirement for strong interaction is for G320, followed closely by G318. Replacing either with U, A, or C reduces affinity by a factor of 15-120. NC-domains from multiple proteins combine to recognize unpaired G(2)-loci, where two guanines are in close proximity. We have previously measured affinities of the NC protein for the important stem-loops of the major packaging domain [Shubsda, M. F., Paoletti, A. C., Hudson, B. S., and Borer, P. N. (2002) Biochemistry 41, 5276-82]. Comparison with the present work shows that the nature of the stem also modulates NC-RNA interactions. Placing the G(2)-loci from the apical SL2 or SL1 loops on the SL3 stem increases affinity by a factor of 2-3, while placing the SL4 loop on the SL3 stem reduces affinity 50-fold. These results are interesting in the context of RNA-protein interaction, as well as for the discovery of antiNC agents for AIDS therapy.

Affinities of packaging domain loops in HIV-1 RNA for the nucleocapsid protein.

To design anti-nucleocapsid drugs, it is useful to know the affinities the protein has for its natural substrates under physiological conditions. Dissociation equilibrium constants are reported for seven RNA stem-loops bound to the mature HIV-1 nucleocapsid protein, NCp7. The loops include SL1, SL2, SL3, and SL4 from the major packaging domain of genomic RNA. The binding assay is based on quenching the fluorescence of tryptophan-37 in the protein by G residues in the single-stranded loops. Tightly bound RNA molecules quench nearly all the fluorescence of freshly purified NCp7 in 0.2 M NaCl. In contrast, when the GGAG-tetraloop of tight-binding SL3 is replaced with UUCG or GAUA, quenching is almost nil, indicating very low affinity. Interpreting fluorescence titrations in terms of a rapidly equilibrating 1:1 complex explains nearly all of the experimental variance for the loops. Analyzed in this way, the highest affinities are for 20mer SL3 and 19mer SL2 hairpin constructs (K(d) = 28 +/- 3 and 23 +/- 2 nM, respectively). The 20mer stem-UUCG-loop and GAUA-loop constructs have <0.5% of the affinity for NCp7 relative to SL3. Affinities relative to SL3 for the other stem-loops are the following: 10% for a 16mer construct to model SL4, 30% for a 27mer model of the 9-residue apical loop of SL1, and 20% for a 23mer model of a 1 x 3 asymmetric internal loop in SL1. A 154mer construct that includes all four stem-loops binds tightly to NCp7, with the equivalent of three NCp7 molecules bound with high affinity per RNA; it is also possible that two strong sites and several weaker ones combine to give the appearance of three strong sites.