17 research outputs found
SNX27 mediates PDZ-directed sorting from endosomes to the plasma membrane
G protein–coupled receptors rely on the PDZ domain of SNX27 for endosomal recycling
Racial differences in systemic sclerosis disease presentation: a European Scleroderma Trials and Research group study
Objectives. Racial factors play a significant role in SSc. We evaluated differences in SSc presentations between white patients (WP), Asian patients (AP) and black patients (BP) and analysed the effects of geographical locations.Methods. SSc characteristics of patients from the EUSTAR cohort were cross-sectionally compared across racial groups using survival and multiple logistic regression analyses.Results. The study included 9162 WP, 341 AP and 181 BP. AP developed the first non-RP feature faster than WP but slower than BP. AP were less frequently anti-centromere (ACA; odds ratio (OR) = 0.4, P < 0.001) and more frequently anti-topoisomerase-I autoantibodies (ATA) positive (OR = 1.2, P = 0.068), while BP were less likely to be ACA and ATA positive than were WP [OR(ACA) = 0.3, P < 0.001; OR(ATA) = 0.5, P = 0.020]. AP had less often (OR = 0.7, P = 0.06) and BP more often (OR = 2.7, P < 0.001) diffuse skin involvement than had WP.AP and BP were more likely to have pulmonary hypertension [OR(AP) = 2.6, P < 0.001; OR(BP) = 2.7, P = 0.03 vs WP] and a reduced forced vital capacity [OR(AP) = 2.5, P < 0.001; OR(BP) = 2.4, P < 0.004] than were WP. AP more often had an impaired diffusing capacity of the lung than had BP and WP [OR(AP vs BP) = 1.9, P = 0.038; OR(AP vs WP) = 2.4, P < 0.001]. After RP onset, AP and BP had a higher hazard to die than had WP [hazard ratio (HR) (AP) = 1.6, P = 0.011; HR(BP) = 2.1, P < 0.001].Conclusion. Compared with WP, and mostly independent of geographical location, AP have a faster and earlier disease onset with high prevalences of ATA, pulmonary hypertension and forced vital capacity impairment and higher mortality. BP had the fastest disease onset, a high prevalence of diffuse skin involvement and nominally the highest mortality
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Protein Interactions Mediating Endocytic Recycling of G Protein-Coupled Receptors
G protein-coupled receptors (GPCRs) comprise the largest family of transmembrane signaling receptors known and account for roughly half of all pharmaceutical targets. Receptor regulation is known to influence cellular signaling strength and specificity, but the mechanisms conferring cellular-level regulation are largely unclear. An important process impacting cellular sensitivity is the post-endocytic sorting of receptors between a downregulating lysosomal fate and a resensitizing recycling pathway to the cell surface. GPCR recycling, in particular, is itself a regulated process that requires recognition of cytoplasmic receptor motifs. The first motif recognized as a recycling sequence is a protein interaction ligand found at the C-terminus of the β2 adrenoceptor. This ligand has shown affinity for multiple proteins, several of which have been proposed to mediate recycling of the receptor. Using a combination of mutational, protein engineering, and RNA interference techniques to probe the recycling activity of three candidate interaction types in the HEK293 cell culture model, we have distinguished these interactions as necessary, sufficient, or dispensable with respect to mediating receptor recycling. In particular, we have identified a dichotomy between the sufficiency of the connectivity in the NHERF/ERM/Actin protein complex to promote recycling of engineered receptors and the necessity of a novel and functionally distinct interaction with Sortin Nexin 27 that is the only interaction detectably required for recycling of the β2 adrenoceptor. In addition, a competing interaction with the N-Ethylmaleimide Sensitive Factor was found to be relatively dispensable in this regard despite showing the capacity for physiologic fine-tuning of receptor trafficking and signaling. These results identify a new function of sorting nexin 27 in promoting PDZ-dependent recycling of an integral membrane protein, expand our basic understanding of trafficking mechanisms that regulate a prototypic signaling receptor, while additionally providing information critical to understanding the physiologic consequences of receptor regulation
Sequence-dependent sorting of recycling proteins by actin-stabilized endosomal microdomains.
The functional consequences of signaling receptor endocytosis are determined by the endosomal sorting of receptors between degradation and recycling pathways. How receptors recycle efficiently, in a sequence-dependent manner that is distinct from bulk membrane recycling, is not known. Here, in live cells, we visualize the sorting of a prototypical sequence-dependent recycling receptor, the beta-2 adrenergic receptor, from bulk recycling proteins and the degrading delta-opioid receptor. Our results reveal a remarkable diversity in recycling routes at the level of individual endosomes, and indicate that sequence-dependent recycling is an active process mediated by distinct endosomal subdomains distinct from those mediating bulk recycling. We identify a specialized subset of tubular microdomains on endosomes, stabilized by a highly localized but dynamic actin machinery, that mediate this sorting, and provide evidence that these actin-stabilized domains provide the physical basis for a two-step kinetic and affinity-based model for protein sorting into the sequence-dependent recycling pathway.</p
Sequence-Dependent Sorting of Recycling Proteins by Actin-Stabilized Endosomal Microdomains
The functional consequences of signaling receptor endocytosis are determined by the endosomal sorting of receptors between degradation and recycling pathways. How receptors recycle efficiently, in a sequence-dependent manner that is distinct from bulk membrane recycling, is not known. Here, in live cells, we visualize the sorting of a prototypical sequence-dependent recycling receptor, the beta-2 adrenergic receptor, from bulk recycling proteins and the degrading delta-opioid receptor. Our results reveal a remarkable diversity in recycling routes at the level of individual endosomes, and indicate that sequence-dependent recycling is an active process mediated by distinct endosomal subdomains distinct from those mediating bulk recycling. We identify a specialized subset of tubular microdomains on endosomes, stabilized by a highly localized but dynamic actin machinery, that mediate this sorting, and provide evidence that these actin-stabilized domains provide the physical basis for a two-step kinetic and affinity-based model for protein sorting into the sequence-dependent recycling pathway. © 2010 Elsevier Inc
2002 Research Honors Program Abstracts
Faculty in the College of Agriculture and Life Sciences at Cornell University mentor and guide undergraduate students who have chosen to pursue a research project and graduate with honors. These abstracts reflect the depth of their scholarship and intellectual ability. The research projects encompass work in animal science, biological science, entomology, natural resources, physical science, plant science, and social science
Engineered Protein Connectivity to Actin Mimics PDZ-dependent Recycling of G Protein-coupled Receptors but Not Its Regulation by Hrs*
Many G protein-coupled receptors (GPCRs) recycle after agonist-induced
endocytosis by a sequence-dependent mechanism, which is distinct from default
membrane flow and remains poorly understood. Efficient recycling of the
β2-adrenergic receptor (β2AR) requires a C-terminal PDZ
(PSD-95/Discs Large/ZO-1) protein-binding determinant (PDZbd), an intact actin
cytoskeleton, and is regulated by the endosomal protein Hrs (hepatocyte growth
factor-regulated substrate). The PDZbd is thought to link receptors to actin
through a series of protein interaction modules present in NHERF/EBP50
(Na+/H+ exchanger 3 regulatory factor/ezrin-binding phosphoprotein
of 50 kDa) family and ERM (ezrin/radixin/moesin) family proteins. It is not
known, however, if such actin connectivity is sufficient to recapitulate the
natural features of sequence-dependent recycling. We addressed this question
using a receptor fusion approach based on the sufficiency of the PDZbd to
promote recycling when fused to a distinct GPCR, the δ-opioid receptor,
which normally recycles inefficiently in HEK293 cells. Modular domains
mediating actin connectivity promoted receptor recycling with similarly high
efficiency as the PDZbd itself, and recycling promoted by all of the domains
was actin-dependent. Regulation of receptor recycling by Hrs, however, was
conferred only by the PDZbd and not by downstream interaction modules. These
results suggest that actin connectivity is sufficient to mimic the core
recycling activity of a GPCR-linked PDZbd but not its cellular regulation