ESCRT-I Function is Required for Tyrp1 Transport from Early Endosomes to the Melanosome Limiting Membrane

Melanosomes are lysosome-related organelles that coexist with lysosomes within melanocytes. The pathways by which melanosomal proteins are diverted from endocytic organelles toward melanosomes are incompletely defined. In melanocytes from mouse models of Hermansky-Pudlak syndrome that lack BLOC-1, melanosomal proteins such as tyrosinase-related protein 1 (Tyrp1) accumulate in early endosomes. Whether this accumulation represents an anomalous pathway or an arrested normal intermediate in melanosome protein trafficking is not clear. Here, we show that early endosomes are requisite intermediates in the trafficking of Tyrp1 from the Golgi to late stage melanosomes in normal melanocytic cells. Kinetic analyses show that very little newly synthesized Tyrp1 traverses the cell surface and that internalized Tyrp1 is inefficiently sorted to melanosomes. Nevertheless, nearly all Tyrp1 traverse early endosomes since it becomes trapped within enlarged, modified endosomes upon overexpression of Hrs. Although Tyrp1 localization is not affected by Hrs depletion, depletion of the ESCRT-I component, Tsg101, or inhibition of ESCRT function by dominant-negative approaches results in a dramatic redistribution of Tyrp1 to aberrant endosomal membranes that are largely distinct from those harboring traditional ESCRT-dependent, ubiquitylated cargoes such as MART-1. The lysosomal protein content of some of these membranes and the lack of Tyrp1 recycling to the plasma membrane in Tsg101-depleted cells suggests that ESCRT-I functions downstream of BLOC-1. Our data delineate a novel pathway for Tyrp1 trafficking and illustrate a requirement for ESCRT-I function in controlling protein sorting from vacuolar endosomes to the limiting membrane of a lysosome-related organelle.     

Dynamin2 GTPase and Cortactin Remodel Actin Filaments

The large GTPase dynamin, best known for its activities that remodel membranes during endocytosis, also regulates F-actin-rich structures, including podosomes, phagocytic cups, actin comet tails, subcortical ruffles, and stress fibers. The mechanisms by which dynamin regulates actin filaments are not known, but an emerging view is that dynamin influences F-actin via its interactions with proteins that interact directly or indirectly with actin filaments. We show here that dynamin2 GTPase activity remodels actin filaments in vitro via a mechanism that depends on the binding partner and F-actin-binding protein, cortactin. Tightly associated actin filaments cross-linked by dynamin2 and cortactin became loosely associated after GTP addition when viewed by transmission electron microscopy. Actin filaments were dynamically unraveled and fragmented after GTP addition when viewed in real time using total internal reflection fluorescence microscopy. Cortactin stimulated the intrinsic GTPase activity of dynamin2 and maintained a stable link between actin filaments and dynamin2, even in the presence of GTP. Filaments remodeled by dynamin2 GTPase in vitro exhibit enhanced sensitivity to severing by the actin depolymerizing factor, cofilin, suggesting that GTPase-dependent remodeling influences the interactions of actin regulatory proteins and F-actin. The global organization of the actomyosin cytoskeleton was perturbed in U2-OS cells depleted of dynamin2, implicating dynamin2 in remodeling actin filaments that comprise supramolecular F-actin arrays in vivo. We conclude that dynamin2 GTPase remodels actin filaments and plays a role in orchestrating the global actomyosin cytoskeleton.Controlled assembly and disassembly of actin filaments underlies movement, shape, division, trafficking of lipids and proteins of the cell and pathogenesis by infectious bacteria and viruses. Several proteins and signaling circuits modulate actin filament dynamics, including proteins that nucleate formation of new filaments, filament cross-linking proteins that stabilize branched and bundled filament arrays, and depolymerizing factors that promote filament disassembly (1). Studies with reconstituted systems show that a single actin nucleating factor, such as the Arp2/3 complex together with a nucleation-promoting factor, a barbed end capping protein to preserve the actin monomer pool and promote nucleation, and a filament disassembly factor, such as ADF/cofilin, are sufficient to establish a dynamic dendritic actin network in vitro that mimics many properties of actin networks at the leading edge of migrating cells (2–4). However, the mechanisms for coordinating the organization and dynamics of actin filaments associated with higher-order cellular structures such as the subcortical F-actin network, F-actin at focal adhesions, and actomyosin arrays are not as well understood.Considerable evidence indicates that the large GTPase dynamin, a key mediator of membrane remodeling and fission, also influences actin filaments (reviewed in Refs. 5–7). Although the mechanisms are unknown, dynamin could influence actin filaments via its interactions with a number of proteins that directly or indirectly regulate actin filament assembly, filament stability, or filament organization. For example, several protein scaffolds biochemically link dynamin and the Arp2/3 complex activating factor, N-WASP, suggesting that the machinery for de novo actin assembly may be targeted or activated by dynamin (6, 8, 9). Dynamin2 is associated with several dynamic F-actin-containing structures in vivo, including podosomes, F-actin comet tails, phagocytic cups, dynamic cortical ruffles, and pedestal structures elaborated by enteropathogenic Escherichia coli (10–20). Cortactin, which directly binds both dynamin and actin filaments, is associated with many of the same dynamic actin structures as dynamin (5, 7) and is required for both clathrin-dependent and -independent endocytosis (21, 22). Thus, dynamin-cortactin interaction may be an important link between actin filaments and dynamin during formation or turnover of F-actin-rich structures.Considerable evidence supports the notion that GTP hydrolysis by dynamin catalyzes membrane fission activity via GTPase-dependent changes in conformation (23, 24) or via GTPase-dependent cycles of assembly and disassembly (25, 26). We hypothesize that GTPase-dependent changes in dynamin linked via its interacting proteins to actin filaments or actin regulators could similarly influence actin filaments. Overexpressed, dominant negative dynamin mutant proteins impaired in binding or hydrolyzing GTP (most often the dynamin-K44A mutation) perturb a variety of F-actin-rich cellular structures, including stress fibers and focal adhesions (27, 28), dendritic spines of neurons (29), podosomes (12, 30), actin comet tails (13, 14), phagocytic cups and bacteria-induced pedestal structures (16, 19), and dynamic cortical ruffles (15, 17). In addition, F-actin of stress fibers and overall cell morphology were perturbed in Clone9 cells expressing a mutant dynamin2 protein lacking the C-terminal proline-rich domain, the domain through which dynamin2 interacts with actin regulatory factors (11). Whereas existing data indicates that the specific effects of dynamin GTPase activity on F-actin structures are cell type- and structure-specific, a general conclusion is that dynamin GTPase activity influences the organization or turnover of a subset of actin filaments.To determine the mechanisms by which dynamin2 GTPase activity influences actin filaments, we developed biochemical and microscopic approaches to quantitatively assess and observe GTPase-dependent effects on actin filaments formed in vitro with Arp2/3 complex, cortactin, and dynamin2. The activities of dynamin2 on actin filaments in vivo were examined in cells with disrupted dynamin2 function using siRNA²-mediated suppression or pharmacologic inhibition. We report that dynamin2 GTPase, together with cortactin, functions as a dynamic actin filament remodeling complex that influences the global organization of the actomyosin cytoskeleton.     

Efficient temporally-controlled targeted mutagenesis in smooth muscle cells of the adult mouse

To generate temporally-controlled targeted somatic mutations selectively and efficiently in smooth muscles, we have established a transgenic SMA-Cre-ER(T2) mouse line in which the expression of the Tamoxifen-dependent Cre-ER(T2) recombinase is under the control of a large genomic DNA segment of the mouse smooth muscle alpha actin (SMA) gene, contained in a Bacterial artificial chromosome (Bac). In this transgenic mouse line, Cre-ER(T2)-mediated recombination of LoxP-flanked target DNA is strictly Tamoxifen-dependent, and efficient in both vascular and visceral smooth muscle cells. Moreover, with the exception of few cardiomyocytes, LoxP-flanked DNA excision is restricted to smooth muscle cells. Thus, SMA-Cre-ER(T2) mice should be of great value to analyze gene function in smooth muscles, and to establish new animal models of human smooth muscle disorders.     

Antikinetoplastid antimitotic activity and metabolic stability of dinitroaniline sulfonamides and benzamides

N(1)-Phenyl-3,5-dinitro-N(4),N(4)-di-n-propylsulfanilamide (1) and N(1)-phenyl-3,5-dinitro-N(4),N(4)-di-n-butylsulfanilamide (2) show potent in vitro antimitotic activity against kinetoplastid parasites but display poor in vivo activity. Seventeen new dinitroaniline sulfonamide and eleven new benzamide analogs of these leads are reported here. Nine of the sulfonamides display in vitro IC(50) values under 500 nM against African trypanosomes, and the most active antikinetoplastid compounds also inhibit the in vitro assembly of purified leishmanial tubulin with potencies similar to that of 2. While several of the potent compounds are rapidly degraded by rat liver S9 fractions in vitro, N(1)-(3-hydroxy)phenyl-3,5-dinitro-N(4),N(4)-di-n-butylsulfanilamide (21) displays an IC(50) value of 260 nM against African trypanosomes in vitro and is more stable than 2 in the in vitro metabolism assay.     

First investigation of the microbiology of the deepest layer of ocean crust

The gabbroic layer comprises the majority of ocean crust. Opportunities to sample this expansive crustal environment are rare because of the technological demands of deep ocean drilling; thus, gabbroic microbial communities have not yet been studied. During the Integrated Ocean Drilling Program Expeditions 304 and 305, igneous rock samples were collected from 0.45-1391.01 meters below seafloor at Hole 1309D, located on the Atlantis Massif (30 °N, 42 °W). Microbial diversity in the rocks was analyzed by denaturing gradient gel electrophoresis and sequencing (Expedition 304), and terminal restriction fragment length polymorphism, cloning and sequencing, and functional gene microarray analysis (Expedition 305). The gabbroic microbial community was relatively depauperate, consisting of a low diversity of proteobacterial lineages closely related to Bacteria from hydrocarbon-dominated environments and to known hydrocarbon degraders, and there was little evidence of Archaea. Functional gene diversity in the gabbroic samples was analyzed with a microarray for metabolic genes ("GeoChip"), producing further evidence of genomic potential for hydrocarbon degradation--genes for aerobic methane and toluene oxidation. Genes coding for anaerobic respirations, such as nitrate reduction, sulfate reduction, and metal reduction, as well as genes for carbon fixation, nitrogen fixation, and ammonium-oxidation, were also present. Our results suggest that the gabbroic layer hosts a microbial community that can degrade hydrocarbons and fix carbon and nitrogen, and has the potential to employ a diversity of non-oxygen electron acceptors. This rare glimpse of the gabbroic ecosystem provides further support for the recent finding of hydrocarbons in deep ocean gabbro from Hole 1309D. It has been hypothesized that these hydrocarbons might originate abiotically from serpentinization reactions that are occurring deep in the Earth's crust, raising the possibility that the lithic microbial community reported here might utilize carbon sources produced independently of the surface biosphere.     

Serum Leptin and Adiponectin Levels and Risk of Barrett's Esophagus and Intestinal Metaplasia of the Gastroesophageal Junction

Persons diagnosed with Barrett's esophagus (BE) are at increased risk of developing esophageal adenocarcinoma (EA). Obesity is a major risk factor for both BE and EA. The primary purposes of this study were to determine whether circulating levels of leptin and adiponectin, both of which are deregulated in obese states, predict risk of specialized intestinal metaplasia (SIM) occurring in the esophagus (BE) and/or gastroesophageal junction, and evaluate the extent to which they mediate the relationship between obesity and these conditions. In this case‐control study, 177 persons newly diagnosed with SIM were compared with 173 general population controls using unconditional logistic regression. Females in the highest tertiles of BMI and waist circumference were at the greatest risk (adjusted odds ratio (OR) = 4.6 (95% confidence interval (CI) = 1.9, 11.6), P_trend = 0.002; OR = 5.1 (95% CI = 2.0, 13.0), P_trend = 0.002, respectively) compared to females in the lowest tertiles. Adjustment for leptin and adiponectin attenuated these associations by 52 and 42%, respectively. Males in the highest tertile of waist‐to‐hip ratio were at the greatest risk (adjusted OR = 2.8 (95% CI = 1.3, 5.9), P_trend = 0.014) compared to males in the lowest tertile. However, adjustment for leptin and adiponectin did not attenuate these associations. Our study results are consistent with the notion that circulating leptin and adiponectin partially mediate the obesity‐BE relationship in women. Leptin and adiponectin's role in the progression from normal epithelium to SIM/BE and on to EA should be further elucidated.