Thomas H. Lubben

Transport of Proteins into Chloroplasts

The import of cytoplasmically synthesized proteins into chloroplasts involves an interaction between at least two components; the precursor protein, and the import apparatus in the chloroplast envelope membrane. This review summarizes the information available about each of these components. Precursor proteins consist of an amino terminal transit peptide attached to a passenger protein. Transit peptides from various precurosrs are diverse with respect to length and amino acid sequence; analysis of their sequences has not revealed insight into their mode of action. A variety of foreign passenger proteins can be imported into chloroplasts when a transit peptide is present at the amino terminus. However, foreign passenger proteins are not imported as efficiently as natural passenger proteins, and some chimeric precursor proteins are not imported into chloroplasts at all. Therefore, the passenger protein, as well as the transit peptide, influences the import process. Import begins by binding of the precursor to the chloroplast surface. It has been suggested that this binding is mediated by a receptor, but evidence to support this hypothesis remains incomplete and a receptor protein has not yet been characterized. Protein translocation requires energy derived from ATP hydrolysis, although there are conflicting reports as to where hydrolysis occurs and it is unclear how this energy is utilized. The mechanism(s) whereby proteins are translocated across either the two envelope membranes or the thylakoid membrane is not known.

Imported large subunits of ribulose bisphosphate carboxylase/oxygenase, but not imported β-ATP synthase subunits, are assembled into holoenzyme in isolated chloroplasts

The large subunit of ribulose bisphosphate carboxylase from Anacystis nidulans 6301, and the β subunit of chloroplast ATP synthase from maize, were fused to the transit peptide of the small subunit of ribulose bisphosphate carboxylase from soybean. These proteins were assayed for post‐translational import into isolated pea chloroplasts. Both proteins were imported into chloroplasts. Imported large subunits were associated with two distinct macromolecular structures. The smaller of these structures was a hybrid ribulose bisphosphate carboxylase holoenzyme, and the larger was the binding protein oligomer. Time‐course experiments following import of the large subunit revealed that the amount of large subunit associated with the binding protein oligomer decreased over time, and that the amount of large subunit present in the assembled holoenzyme increased. We also observed that imported small subunits of ribulose bisphosphate carboxylase, although predominantly present in the holoenzyme, were also found associated with the binding protein oligomer. In contrast, the imported β subunit of chloroplast ATP synthase did not assemble into a thylakoid‐bound coupling factor complex.

Chloroplast import characteristics of chimeric proteins

We have examined the import of a series of chimeric precursor proteins into chloroplasts. These fusion proteins contained the transit peptide, and various amounts of the amino-terminal region of the mature peptide, from the small subunit of ribulose 1,5-bisphosphate carboxylase, linked to the coat protein of brome mosaic virus. Chimeric genes were cloned into SP6 plasmids and in vitro transcription/translation was used to produce fusion proteins, which were examined in a quantitative in vitro import assay. A chimeric protein which contained only the transit peptide fused to the coat protein was imported into chloroplasts. A second chimeric precursor, which also contained a small portion of the mature peptide, was imported at nearly the same rate. A chimeric protein which contained the transit peptide and most of the mature peptide fused to the coat protein was not imported. These results suggest that secondary or tertiary structural features of precursor proteins are important for protein import, and that the presence of a transit peptide in a protein does not necessarily ensure import of that protein into chloroplasts.

Stop-transfer regions do not halt translocation of proteins into chloroplasts.

Protein targeting in eukaryotic cells is determined by several topogenic signals. Among these are stop-transfer regions, which halt translocation of proteins across the endoplasmic reticulum membrane. Two different stop-transfer regions were incorporated into precursors for a chloroplast protein, the small subunit of ribulose-1,5-bisphosphate carboxylase/oxygenase. Both chimeric proteins were imported into chloroplasts and did not accumulate in the envelope membranes. Thus, the stop-transfer signals did not function during chloroplast protein import. These observations support the hypothesis that the mechanism for translocation of proteins across the chloroplast envelope is significantly different from that for translocation across the endoplasmic reticulum membrane.

A high throughput fluorescent assay for measuring the activity of fatty acid amide hydrolase

Fatty acid amide hydrolase (FAAH) is the enzyme responsible for the rapid degradation of fatty acid amides such as the endocannabinoid anandamide. Inhibition of FAAH activity has been suggested as a therapeutic approach for the treatment of chronic pain, depression and anxiety, through local activation of the cannabinoid receptor CB1. We have developed a high throughput screening assay for identification of FAAH inhibitors using a novel substrate, decanoyl 7-amino-4-methyl coumarin (D-AMC) that is cleaved by FAAH to release decanoic acid and the highly fluorescent molecule 7-amino-4-methyl coumarin (AMC). This assay gives an excellent signal window for measuring FAAH activity and, as a continuous assay, inherently offers improved sensitivity and accuracy over previously reported endpoint assays. The assay was validated using a panel of known FAAH inhibitors and purified recombinant human FAAH, then converted to a 384 well format and used to screen a large library of compounds (>600,000 compounds) to identify FAAH inhibitors. This screen identified numerous novel FAAH inhibitors of diverse chemotypes. These hits confirmed using a native FAAH substrate, anandamide, and had very similar rank order potency to that obtained using the D-AMC substrate. Collectively these data demonstrate that D-AMC can be successfully used to rapidly and effectively identify novel FAAH inhibitors for potential therapeutic use.