Analysis of the dynein-dynactin interaction in vitro and in vivo

Cytoplasmic dynein and dynactin are megadalton-sized multisubunit molecules that function together as a cytoskeletal motor. In the present study, we explore the mechanism of dynein-dynactin binding in vitro and then extend our findings to an in vivo context. Solution binding assays were used to define binding domains in the dynein intermediate chain (IC) and dynactin p150Glued subunit. Transient overexpression of a series of fragments of the dynein IC was used to determine the importance of this subunit for dynein function in mammalian tissue culture cells. Our results suggest that a functional dynein-dynactin interaction is required for proper microtubule organization and for the transport and localization of centrosomal components and endomembrane compartments. The dynein IC fragments have different effects on endomembrane localization, suggesting that different endomembranes may bind dynein via distinct mechanisms.     

Nudel/NudE and Lis1 promote dynein and dynactin interaction in the context of spindle morphogenesis

Lis1, Nudel/NudE, and dynactin are regulators of cytoplasmic dynein, a minus end–directed, microtubule (MT)-based motor required for proper spindle assembly and orientation. In vitro studies have shown that dynactin promotes processive movement of dynein on MTs, whereas Lis1 causes dynein to enter a persistent force-generating state (referred to here as dynein stall). Yet how the activities of Lis1, Nudel/NudE, and dynactin are coordinated to regulate dynein remains poorly understood in vivo. Working in Xenopus egg extracts, we show that Nudel/NudE facilitates the binding of Lis1 to dynein, which enhances the recruitment of dynactin to dynein. We further report a novel Lis1-dependent dynein–dynactin interaction that is essential for the organization of mitotic spindle poles. Finally, using assays for MT gliding and spindle assembly, we demonstrate an antagonistic relationship between Lis1 and dynactin that allows dynactin to relieve Lis1-induced dynein stall on MTs. Our findings suggest the interesting possibility that Lis1 and dynactin could alternately engage with dynein to allow the motor to promote spindle assembly.     

Dynactin helps target Polo‐like kinase 1 to kinetochores via its left‐handed beta‐helical p27 subunit

Dynactin is a protein complex required for the in vivo function of cytoplasmic dynein, a microtubule (MT)‐based motor. Dynactin binds both dynein and MTs via its p150^Glued subunit, but little is known about the ‘pointed‐end complex’ that includes the protein subunits Arp11, p62 and the p27/p25 heterodimer. Here, we show that the p27/p25 heterodimer undergoes mitotic phosphorylation by cyclin‐dependent kinase 1 (Cdk1) at a single site, p27 Thr186, to generate an anchoring site for polo‐like kinase 1 (Plk1) at kinetochores. Removal of p27/p25 from dynactin results in reduced levels of Plk1 and its phosphorylated substrates at kinetochores in prometaphase, which correlates with aberrant kinetochore–MT interactions, improper chromosome alignment and abbreviated mitosis. To investigate the structural implications of p27 phosphorylation, we determined the structure of human p27. This revealed an unusual left‐handed β‐helix domain, with the phosphorylation site located within a disordered, C‐terminal segment. We conclude that dynactin plays a previously undescribed regulatory role in the spindle assembly checkpoint by recruiting Plk1 to kinetochores and facilitating phosphorylation of important downstream targets.     

Epidemiology of Pneumocystis jirovecii Pneumonia in Venezuela

Current Fungal Infection Reports - The aim of this work is to contribute to the knowledge of the epidemiology of pneumocystosis or Pneumocystis jirovecii pneumonia (PCP) in Venezuela, by an updated...     

Amino acid profiles in first trimester amniotic fluids of healthy bovine cloned pregnancies are similar to those of IVF pregnancies,but not nonviable cloned pregnancies

Somatic cell nuclear transfer (SCNT), or cloning, is one of the assisted reproductive technologies currently used in agriculture. Commercial applications of SCNT are presently limited to the production of animals of high genetic merit or the production of the most elite show cattle owing to its relatively low efficiency. In current practice, 20% to 40% of SCNT pregnancies do not result in viable offspring. In an effort to better understand some of the anomalies associated with SCNT pregnancies, we investigated amino acid compositions of first trimester amniotic fluid. In this retrospective study, amniotic fluids were collected from SCNT and control IVF pregnancies at Day 75 of gestation and grouped according to the pregnancy results: control IVF (IVF), viable SCNT pregnancies that resulted in live healthy calves (SCNT-HL), nonviable SCNT pregnancies that were aborted before Day 150 (SCNT-ED), and nonviable SCNT pregnancies that were aborted after Day 150 or produced deceased calves (SCNT-LD). High-performance liquid chromatography (HPLC) was used to analyze the concentrations of 22 amino acids (AAs) in the amniotic fluid samples. There were no differences in average AA concentrations between IVF and SCNT-HL groups, whereas SCNT-LD and SCNT-ED had higher levels of total AA concentrations. Concentrations of asparagine, citruline, arginine, and valine were significantly higher in the SCNT-LD group. Both SCNT-LD and SCNT-ED groups had relatively large intragroup variances in AA concentrations. Urea concentration was also measured in the SCNT amniotic fluid samples. No correlations between urea concentrations and arginine concentrations or pregnancy outcomes were found. The findings in this study not only deepen the understanding on SCNT pregnancy anomalies, but also provide a potentially useful screening tool for assessing viable and nonviable SCNT pregnancies.     

Do Roads Reduce Painted Turtle (Chrysemys picta) Populations?

Road mortality is thought to be a leading cause of turtle population decline. However, empirical evidence of the direct negative effects of road mortality on turtle population abundance is lacking. The purpose of this study was to provide a strong test of the prediction that roads reduce turtle population abundance. While controlling for potentially confounding variables, we compared relative abundance of painted turtles (Chrysemys picta) in 20 ponds in Eastern Ontario, 10 as close as possible to high traffic roads (Road sites) and 10 as far as possible from any major roads (No Road sites). There was no significant effect of roads on painted turtle relative abundance. Furthermore, our data do not support other predictions of the road mortality hypothesis; we observed neither a higher relative frequency of males to females at Road sites than at No Road sites, nor a lower average body size of turtles at Road than at No Road sites. We speculate that, although roads can cause substantial adult mortality in turtles, other factors, such as release from predation on adults and/or nests close to roads counter the negative effect of road mortality in some populations. We suggest that road mitigation for painted turtles can be limited to locations where turtles are forced to migrate across high traffic roads due, for example, to destruction of local nesting habitat or seasonal drying of ponds. This conclusion should not be extrapolated to other species of turtles, where road mortality could have a larger population-level effect than on painted turtles.     

Two-dimensional averaged images of the dynactin complex revealed by single particle analysis

The dynactin complex interacts with dynein and numerous other proteins to provide for a wide range of subcellular transport functions. A detailed understanding of the structure and subunit organization of dynactin should yield new insights into its function. In the present study, we used single particle analysis to obtain a two-dimensional averaged image of dynactin isolated from chick embryo brains and visualized by negative stain electron microscopy (EM). Each individual image, consisting of the shoulder/sidearm and the rod, closely resembled the previously published quick-freeze deep-etch rotary-shadow electron micrographs. However, the averaged image revealed novel structural features that may have functional significance. The bulky shoulder complex has a triangular shape and is 13 nm wide and 8 nm high. The rod, with an overall length of 40 nm, consists of clearly defined lobes that are apparently grouped into three parts, the pointed-end complex, the middle segment, and the extra lobes at the barbed end. The pointed-end complex reveals the characteristic protrusions and clefts that were previously observed only in the isolated pointed-end complex. In the middle segment, the seven lobes are fitted to the helical symmetry of F-actin. A narrow but prominent gap separates the previously unidentified extra three lobes at the barbed end from the middle segment. The averaged image we obtained contrasts dramatically with the simple Arp1 polymer that was previously reported by single particle analysis of bovine brain dynactin. These apparent structural differences are probably due to the greater stability and integrity of the chick embryo brain dynactin preparation. We propose a new structural model for dynactin, based on our observations.     

Dynamitin mutagenesis reveals protein-protein interactions important for dynactin structure

Dynactin is a highly conserved, multiprotein complex that works in conjunction with microtubule-based motors to power a variety of intracellular motile events. Dynamitin (p50) is a core element of dynactin structure. In the present study, we use targeted mutagenesis to evaluate how dynamitin's different structural domains contribute to its ability to self-associate, interact with dynactin and assemble into a complex with its close binding partner, p24. We show that these interactions involve three distinct structural elements: (i) a previously unidentified dimerization motif in the N-terminal 100 amino acids, (ii) an α-helical motif spanning aa 106–162 and (iii) the C-terminal half of the molecule (aa 213–406), which is predicted to fold into an antiparallel α-helix bundle. The N-terminal half of dynamitin by itself is sufficient to disrupt dynactin, although very high concentrations are required. The ability of mutations in dynamitin's interaction domains to disrupt dynactin in vitro was found to correlate with their inhibitory effects when expressed in cells. We determined that the dynactin subunit, p24, governs dynamitin oligomerization by binding dynamitin along its length. This suppresses aberrant multimerization and drives formation of a protein complex that is identical to the native dynactin shoulder.