21 research outputs found
Drosophila comes of age as a model system for understanding the function of cytoskeletal proteins in cells, tissues, and organisms
available in PMC 2016 June 30For the last 100 years, Drosophila melanogaster has been a powerhouse genetic system for understanding mechanisms of inheritance, development, and behavior in animals. In recent years, advances in imaging and genetic tools have led to Drosophila becoming one of the most effective systems for unlocking the subcellular functions of proteins (and particularly cytoskeletal proteins) in complex developmental settings. In this review, written for non-Drosophila experts, we will discuss critical technical advances that have enabled these cell biological insights, highlighting three examples of cytoskeletal discoveries that have arisen as a result: (1) regulation of Arp2/3 complex in myoblast fusion, (2) cooperation of the actin filament nucleators Spire and Cappuccino in establishment of oocyte polarity, and (3) coordination of supracellular myosin cables. These specific examples illustrate the unique power of Drosophila both to uncover new cytoskeletal structures and functions, and to place these discoveries in a broader in vivo context, providing insights that would have been impossible in a cell culture model or in vitro. Many of the cellular structures identified in Drosophila have clear counterparts in mammalian cells and tissues, and therefore elucidating cytoskeletal functions in Drosophila will be broadly applicable to other organisms.National Institutes of Health (U.S.) (NIH/NINDS (DP2 NS082127))Pew Scholars Program in the Biomedical SciencesNational Institutes of Health (U.S.) (NIH/NIGMS (R01-GM084947))American Cancer Society (Research Scholar Award
Conformation-sensitive Antibodies against Alzheimer Amyloid-β by Immunization with a Thioredoxin-constrained B-cell Epitope Peptide
Immunotherapy against the amyloid-beta (Abeta) peptide is a valuable potential treatment for Alzheimer disease (AD). An ideal antigen should be soluble and nontoxic, avoid the C-terminally located T-cell epitope of Abeta, and yet be capable of eliciting antibodies that recognize Abeta fibrils and neurotoxic Abeta oligomers but not the physiological monomeric species of Abeta. We have described here the construction and immunological characterization of a recombinant antigen with these features obtained by tandem multimerization of the immunodominant B-cell epitope peptide Abeta1-15 (Abeta15) within the active site loop of bacterial thioredoxin (Trx). Chimeric Trx(Abeta15)n polypeptides bearing one, four, or eight copies of Abeta15 were constructed and injected into mice in combination with alum, an adjuvant approved for human use. All three polypeptides were found to be immunogenic, yet eliciting antibodies with distinct recognition specificities. The anti-Trx(Abeta15)4 antibody, in particular, recognized Abeta42 fibrils and oligomers but not monomers and exhibited the same kind of conformational selectivity against transthyretin, an amyloidogenic protein unrelated in sequence to Abeta. We have also demonstrated that anti-Trx(Abeta15)4, which binds to human AD plaques, markedly reduces Abeta pathology in transgenic AD mice. The data indicate that a conformational epitope shared by oligomers and fibrils can be mimicked by a thioredoxin-constrained Abeta fragment repeat and identify Trx(Abeta15)4 as a promising new tool for AD immunotherapy
Modulation of nucleosome dynamics in Huntington's disease
Transcriptional dysregulation and aberrant chromatin remodeling are central features in the pathology of Huntington's disease (HD). In order to more fully characterize these pathogenic events, an assessment of histone profiles and associated gene changes were performed in transgenic N171-82Q (82Q) and R6/2 HD mice. Analyses revealed significant chromatin modification, resulting in reduced histone acetylation with concomitant increased histone methylation, consistent with findings observed in HD patients. While there are no known interventions that ameliorate or arrest HD progression, DNA/RNA-binding anthracyclines may provide significant therapeutic potential by correcting pathological nucleosome changes and realigning transcription. Two such anthracyclines, chromomycin and mithramycin, improved altered nucleosome homeostasis in HD mice, normalizing the chromatin pattern. There was a significant shift in the balance between methylation and acetylation in treated HD mice to that found in wild-type mice, resulting in greater acetylation of histone H3 at lysine 9 and promoting gene transcription. Gene expression profiling in anthracycline-treated HD mice showed molecular changes that correlate with disease correction, such that a subset of downregulated genes were upregulated with anthracycline treatment. Improved nucleosomal dynamics were concurrent with a significant improvement in the behavioral and neuropathological phenotype observed in HD mice. These data show the ability of anthracycline compounds to rebalance epigenetic histone modification and, as such, may provide the rationale for the design of human clinical trials in HD patient
dOCRL maintains immune cell quiescence in Drosophila by regulating endosomal traffic
Lowe Syndrome is a developmental disorder characterized by eye, kidney, and neurological pathologies, and is caused by mutations in the phosphatidylinositol-5-phosphatase OCRL. OCRL plays diverse roles in endocytic and endolysosomal trafficking, cytokinesis, and ciliogenesis, but it is unclear which of these cellular functions underlie specific patient symptoms. Here, we show that mutation of Drosophila OCRL causes cell-autonomous activation of hemocytes, which are macrophage-like cells of the innate immune system. Among many cell biological defects that we identified in docrl mutant hemocytes, we pinpointed the cause of innate immune cell activation to reduced Rab11-dependent recycling traffic and concomitantly increased Rab7-dependent late endosome traffic. Loss of docrl amplifies multiple immune-relevant signals, including Toll, Jun kinase, and STAT, and leads to Rab11-sensitive mis-sorting and excessive secretion of the Toll ligand SpĂĄtzle. Thus, docrl regulation of endosomal traffic maintains hemocytes in a poised, but quiescent state, suggesting mechanisms by which endosomal misregulation of signaling may contribute to symptoms of Lowe syndrome
Rubens' jachttaferelen
Despite the advancement of molecular
imaging techniques, there
is an unmet need for probes for direct imaging of membrane dynamics
of live cells. Here we report a novel type of active (or enzyme responsive)
probes to directly image membrane dynamics of live cells with high
spatial and temporal resolution over extended time scales and areas.
Because lipid rafts enrich cholesterols and GPI-anchored enzymes (e.g.,
ectophosphatases), we design probes that consist of an enzymatic trigger,
a fluorophore, and a cholesterol that are affinitive to the cell membrane.
Being water-soluble and as the substrate of ectophosphatase, these
cell compatible probes preferentially and rapidly assemble in plasma
membrane, exhibit strong fluorescence, work at micromolar concentrations,
and easily achieve high resolution monitoring of nanoscale heterogeneity
in membranes of live cells, the release of exosomes, and the membrane
dynamics of live cells. This work provides a facile means to link
membrane dynamics and heterogeneity to cellular processes for understanding
the interactions between membranes and proteins
Active Probes for Imaging Membrane Dynamics of Live Cells with High Spatial and Temporal Resolution over Extended Time Scales and Areas
Despite the advancement of molecular
imaging techniques, there
is an unmet need for probes for direct imaging of membrane dynamics
of live cells. Here we report a novel type of active (or enzyme responsive)
probes to directly image membrane dynamics of live cells with high
spatial and temporal resolution over extended time scales and areas.
Because lipid rafts enrich cholesterols and GPI-anchored enzymes (e.g.,
ectophosphatases), we design probes that consist of an enzymatic trigger,
a fluorophore, and a cholesterol that are affinitive to the cell membrane.
Being water-soluble and as the substrate of ectophosphatase, these
cell compatible probes preferentially and rapidly assemble in plasma
membrane, exhibit strong fluorescence, work at micromolar concentrations,
and easily achieve high resolution monitoring of nanoscale heterogeneity
in membranes of live cells, the release of exosomes, and the membrane
dynamics of live cells. This work provides a facile means to link
membrane dynamics and heterogeneity to cellular processes for understanding
the interactions between membranes and proteins
Active Probes for Imaging Membrane Dynamics of Live Cells with High Spatial and Temporal Resolution over Extended Time Scales and Areas
Despite the advancement of molecular
imaging techniques, there
is an unmet need for probes for direct imaging of membrane dynamics
of live cells. Here we report a novel type of active (or enzyme responsive)
probes to directly image membrane dynamics of live cells with high
spatial and temporal resolution over extended time scales and areas.
Because lipid rafts enrich cholesterols and GPI-anchored enzymes (e.g.,
ectophosphatases), we design probes that consist of an enzymatic trigger,
a fluorophore, and a cholesterol that are affinitive to the cell membrane.
Being water-soluble and as the substrate of ectophosphatase, these
cell compatible probes preferentially and rapidly assemble in plasma
membrane, exhibit strong fluorescence, work at micromolar concentrations,
and easily achieve high resolution monitoring of nanoscale heterogeneity
in membranes of live cells, the release of exosomes, and the membrane
dynamics of live cells. This work provides a facile means to link
membrane dynamics and heterogeneity to cellular processes for understanding
the interactions between membranes and proteins
An autoinhibitory clamp of actin assembly constrains and directs synaptic endocytosis
Synaptic membrane-remodeling events such as endocytosis require force-generating actin assembly. The endocytic machinery that regulates these actin and membrane dynamics localizes at high concentrations to large areas of the presynaptic membrane, but actin assembly and productive endocytosis are far more restricted in space and time. Here we describe a mechanism whereby autoinhibition clamps the presynaptic endocytic machinery to limit actin assembly to discrete functional events. We found that collective interactions between the Drosophila endocytic proteins Nwk/FCHSD2, Dap160/intersectin, and WASp relieve Nwk autoinhibition and promote robust membrane-coupled actin assembly in vitro. Using automated particle tracking to quantify synaptic actin dynamics in vivo, we discovered that Nwk-Dap160 interactions constrain spurious assembly of WASp-dependent actin structures. These interactions also promote synaptic endocytosis, suggesting that autoinhibition both clamps and primes the synaptic endocytic machinery, thereby constraining actin assembly to drive productive membrane remodeling in response to physiological cues. </p