The effect of pH dependence of antibody-antigen interactions on subcellular trafficking dynamics.

A drawback of targeting soluble antigens such as cytokines or toxins with long-lived antibodies is that such antibodies can prolong the half-life of the target antigen by a "buffering" effect. This has motivated the design of antibodies that bind to target with higher affinity at near neutral pH relative to acidic endosomal pH (~pH 6.0). Such antibodies are expected to release antigen within endosomes following uptake into cells, whereas antibody will be recycled and exocytosed in FcRn-expressing cells. To understand how the pH dependence of antibody-antigen interactions affects intracellular trafficking, we generated three antibodies that bind IL-6 with different pH dependencies in the range pH 6.0-7.4. The behavior of antigen in the presence of these antibodies has been characterized using a combination of fixed and live cell fluorescence microscopy. As the affinity of the antibody:IL-6 interaction at pH 6.0 decreases, an increasing amount of antigen dissociates from FcRn-bound antibody in early and late endosomes, and then enters lysosomes. Segregation of antibody and FcRn from endosomes in tubulovesicular transport carriers (TCs) into the recycling pathway can also be observed in live cells, and the extent of IL-6 association with TCs correlates with increasing affinity of the antibody:IL-6 interaction at acidic pH. These analyses result in an understanding, in spatiotemporal terms, of the effect of pH dependence of antibody-antigen interactions on subcellular trafficking and inform the design of antibodies with optimized binding properties for antigen elimination.

Developing intrabodies for the therapeutic suppression of neurodegenerative pathology.

Many neurodegenerative diseases have misfolded proteins as a primary occurrence in pathogenesis. A combination of antibody and genetic engineering has emerged as a powerful tool for developing reagents that specifically target the misfolding process itself, and/or abnormal interactions of the misfolded protein species. This review focuses on the selection and testing of intracellular antibody fragments (intrabodies), with a particular focus on Huntington's disease (HD) and Parkinson's disease (PD), both of which show prominent intracellular protein aggregates in affected neurons. The most dramatic advances are in HD, where in vivo efficacy of intrabodies has been demonstrated. Targets in other neurodegenerative disorders, including Alzheimer's disease and prion diseases, are noted more briefly, with an emphasis on the potential for intracellular manipulations. Given the specificity and versatility of antibody-based reagents, the wide range of options for conformational and post-translationally-modified targets, and the recent improvement in gene delivery, this should be a fertile field for 21(st) century pharmacology.

An scFv intrabody against the nonamyloid component of alpha-synuclein reduces intracellular aggregation and toxicity.

Prevention of abnormal misfolding and aggregation of alpha synuclein (syn) protein in vulnerable neurons should be viable therapeutic strategies for reducing pathogenesis in Parkinson's disease. The nonamyloid component (NAC) region of alpha-syn shows strong tendencies to form beta-sheet structures, and deletion of this region has been shown to reduce aggregation and toxicity in vitro and in vivo. The binding of a molecular species to this region may mimic the effects of such deletions. Single-chain variable fragment (scFv) antibodies retain the binding specificity of antibodies and, when genetically manipulated to create high-diversity libraries, allow in vitro selection against peptides. Accordingly, we used a yeast surface display library of an entire naive repertoire of human scFv antibodies to select for binding to a NAC peptide. Candidate scFv antibodies (after transfer to mammalian expression vectors) were screened for viability in a neuronal cell line by transient cotransfection with A53T mutant alpha-syn. This provided a ranking of the protective efficacies of the initial panel of intracellular antibodies (intrabodies). High steady-state expression levels and apparent conformational epitope binding appeared more important than in vitro affinity in these assays. None of the scFv antibodies selected matched the sequences of previously reported anti-alpha-syn scFv antibodies. A stable cell line expressing the most effective intrabody, NAC32, showed highly significant reductions in abnormal aggregation in two separate models. Recently, intrabodies have shown promising antiaggregation and neuroprotective effects against misfolded mutant huntingtin protein. The NAC32 study extends such work significantly by utilizing information about the pathogenic capacity of a specific alpha-syn region to offer a new generation of in vitro-derived antibody fragments, both for further engineering as direct therapeutics and as a tool for rational drug design for Parkinson's disease.

Dominant role of copper in the kinetic stability of Cu/Zn superoxide dismutase.

Mutations in Cu/Zn superoxide dismutase (SOD) are involved in some cases of familial amyotrophic lateral sclerosis, and it appears that misfolding and aggregation, perhaps mediated by abnormal binding or loss of copper (Cu) and/or zinc (Zn), may play a pathological role. It is known that the absence of both metals kinetically destabilizes wild type and mutant SOD leading to a 60-fold increase in their rate of unfolding. Here, the individual contributions of Cu and Zn to the kinetic stability of SOD were investigated, and the results show that Cu plays a greater role. Thus, the deficiency of Cu or Zn, especially the former, will compromise the kinetic stability of SOD, thereby increasing the probability that pathogenic mutants and even the WT protein may misfold and self-assemble into toxic species.

Kinetic stability of Cu/Zn superoxide dismutase is dependent on its metal ligands: implications for ALS.

Over 100 mutants of the enzyme Cu/Zn superoxide dismutase (SOD) have been implicated in the neurodegenerative disease familial amyotrophic lateral sclerosis (FALS). Growing evidence suggests that the aggregation of SOD mutants may play a causative role in FALS and that aberrant copper chemistry, decreased thermodynamic stability, and decreased affinity for metals may contribute independently or synergistically to this process. Since the loss of the copper and zinc ions significantly decreases the thermodynamic stability of SOD, it is expected that this would also decrease its kinetic stability, thereby facilitating partial or global unfolding transitions that may lead to misfolding and aggregation. Here we used wild-type (WT) SOD and five FALS-related mutants (G37R, H46R, G85R, D90A, and L144F) to show that the metals contribute significantly to the kinetic stability of the protein, with demetalated (apo) SOD showing acid-induced unfolding rates about 60-fold greater than the metalated (holo) protein. However, the unfolding rates of SOD WT and mutants were similar to each other in both the holo and apo states, indicating that regardless of the effect of mutation on thermodynamic stability, the kinetic barrier toward SOD unfolding is dependent on the presence of metals. Thus, these results suggest that pathogenic SOD mutations that do not significantly alter the stability of the protein may still lead to SOD aggregation by compromising its ability to bind or retain its metals and thereby decrease its kinetic stability. Furthermore, the mutant-like decrease in the kinetic stability of apo WT SOD raises the possibility that the loss of metals in WT SOD may be involved in nonfamilial forms of ALS.