Will A. Stanley

Recognition of a Functional Peroxisome Type 1 Target by the Dynamic Import Receptor Pex5p

Peroxisomes require the translocation of folded and functional target proteins of various sizes across the peroxisomal membrane. We have investigated the structure and function of the principal import receptor Pex5p, which recognizes targets bearing a C-terminal peroxisomal targeting signal type 1. Crystal structures of the receptor in the presence and absence of a peroxisomal target, sterol carrier protein 2, reveal major structural changes from an open, snail-like conformation into a closed, circular conformation. These changes are caused by a long loop C terminal to the 7-fold tetratricopeptide repeat segments. Mutations in residues of this loop lead to defects in peroxisomal import in human fibroblasts. The structure of the receptor/cargo complex demonstrates that the primary receptor-binding site of the cargo is structurally and topologically autonomous, enabling the cargo to retain its native structure and function.

The peroxisomal receptor Pex19p forms a helical mPTS recognition domain

The protein Pex19p functions as a receptor and chaperone of peroxisomal membrane proteins (PMPs). The crystal structure of the folded C‐terminal part of the receptor reveals a globular domain that displays a bundle of three long helices in an antiparallel arrangement. Complementary functional experiments, using a range of truncated Pex19p constructs, show that the structured α‐helical domain binds PMP‐targeting signal (mPTS) sequences with about 10 μM affinity. Removal of a conserved N‐terminal helical segment from the mPTS recognition domain impairs the ability for mPTS binding, indicating that it forms part of the mPTS‐binding site. Pex19p variants with mutations in the same sequence segment abolish correct cargo import. Our data indicate a divided N‐terminal and C‐terminal structural arrangement in Pex19p, which is reminiscent of a similar division in the Pex5p receptor, to allow separation of cargo‐targeting signal recognition and additional functions.

A previously unobserved conformation for the human Pex5p receptor suggests roles for intrinsic flexibility and rigid domain motions in ligand binding

BackgroundThe C-terminal tetratricopeptide (TPR) repeat domain of Pex5p recognises proteins carrying a peroxisomal targeting signal type 1 (PTS1) tripeptide in their C-terminus. Previously, structural data have been obtained from the TPR domain of Pex5p in both the liganded and unliganded states, indicating a conformational change taking place upon cargo protein binding. Such a conformational change would be expected to play a major role both during PTS1 protein recognition as well as in cargo release into the peroxisomal lumen. However, little information is available on the factors that may regulate such structural changes.ResultsWe have used a range of biophysical and computational methods to further analyse the conformational flexibility and ligand binding of Pex5p. A new crystal form for the human Pex5p C-terminal domain (Pex5p(C)) was obtained in the presence of Sr2+ ions, and the structure presents a novel conformation, distinct from all previous liganded and apo crystal structures for Pex5p(C). The difference relates to a near-rigid body movement of two halves of the molecule, and this movement is different from that required to reach a ring-like conformation upon PTS1 ligand binding. The bound Sr2+ ion changes the dynamic properties of Pex5p(C) affecting its conformation, possibly by making the Sr2+-binding loop – located near the hinge region for the observed domain motions – more rigid.ConclusionThe current data indicate that Pex5p(C) is able to sample a range of conformational states in the absence of bound PTS1 ligand. The domain movements between various apo conformations are distinct from those involved in ligand binding, although the differences between all observed conformations so far can be characterised by the movement of the two halves of Pex5p(C) as near-rigid bodies with respect to each other.

Functional Analyses of a Putative, Membrane-Bound, Peroxisomal Protein Import Mechanism from the Apicomplexan Protozoan Toxoplasma gondii

Peroxisomes are central to eukaryotic metabolism, including the oxidation of fatty acids—which subsequently provide an important source of metabolic energy—and in the biosynthesis of cholesterol and plasmalogens. However, the presence and nature of peroxisomes in the parasitic apicomplexan protozoa remains controversial. A survey of the available genomes revealed that genes encoding peroxisome biogenesis factors, so-called peroxins (Pex), are only present in a subset of these parasites, the coccidia. The basic principle of peroxisomal protein import is evolutionarily conserved, proteins harbouring a peroxisomal-targeting signal 1 (PTS1) interact in the cytosol with the shuttling receptor Pex5 and are then imported into the peroxisome via the membrane-bound protein complex formed by Pex13 and Pex14. Surprisingly, whilst Pex5 is clearly identifiable, Pex13 and, perhaps, Pex14 are apparently absent from the coccidian genomes. To investigate the functionality of the PTS1 import mechanism in these parasites, expression of Pex5 from the model coccidian Toxoplasma gondii was shown to rescue the import defect of Pex5-deleted Saccharomyces cerevisiae. In support of these data, green fluorescent protein (GFP) bearing the enhanced (e)PTS1 known to efficiently localise to peroxisomes in yeast, localised to peroxisome-like bodies when expressed in Toxoplasma. Furthermore, the PTS1-binding domain of Pex5 and a PTS1 ligand from the putatively peroxisome-localised Toxoplasma sterol carrier protein (SCP2) were shown to interact in vitro. Taken together, these data demonstrate that the Pex5–PTS1 interaction is functional in the coccidia and indicate that a nonconventional peroxisomal import mechanism may operate in the absence of Pex13 and Pex14.

A model of the solution structure of human Pex5p obtained by small angle X-ray scattering

It is well documented that the properties and performance of polyurethanes and polyurethaneureas are strongly dependent on the degree of microphase separation and ensuing morphologies [1,2]. The morphology of segmented polyurethanes is very complicated, not only because of their two-phase structure, but also because of other physical phenomena such as crystallization and hydrogen bond formation in hard and soft domains. These phenomena have been intensively studied over years, as they are relevant to understand and control the properties of the final product. In this paper, two series of MDI and ethylene glycol adipate polyol-based polyurethane (PU) and polyurethaneurea (PUU) elastomers were examined, with emphasis on characterizing the effect of annealing on the morphology and microphase separation. Series I includes four PU samples where only aliphatic diol chain extenders were used while series II includes five PUU samples where a mixture of aliphatic diol and aromatic or heterocyclic diamine chain extenders were used. All samples were annealed at 100°C up to 14 days according to the ASTM 0573-99 method. TGA results show that annealing at 100°C does not result in any thermal degradation but mechanical characterizations show that the annealing causes a drop of the E-modulus, likely due to morphological changes. This conclusion is confirmed by SAXS, WAXD, DSC and DMA measurements where the annealed samples show different behaviour compared to the non annealed ones. Moreover, the differences are affected by the annealing time. During high temperature annealing SAXS measurements reveal that the micro phase separation gradually progresses. In addition, extra melting peaks appear in the DSC measurements together with sharp crystalline reflections in WAXD, pointing to additional crystallization.