Site directed mutagenesis of Drosophila flightin disrupts phosphorylation and impairs flight muscle structure and mechanics

Flightin is a myosin rod binding protein that in Drosophila melanogaster is expressed exclusively in the asynchronous indirect flight muscles (IFM). Hyperphosphorylation of flightin coincides with the completion of myofibril assembly and precedes the emergence of flight competency in young adults. To investigate the role of flightin phosphorylation in vivo we generated three flightin null (fln ⁰ ) Drosophila strains that express a mutant flightin transgene with two (Thr158, Ser 162), three (Ser139, Ser141, Ser145) or all five potential phosphorylation sites mutated to alanines. These amino acid substitutions result in lower than normal levels of flightin accumulation and transgenic strains that are unable to beat their wings. On two dimensional gels of IFM proteins, the transgenic strain with five mutant sites (fln ^5STA ) is devoid of all phosphovariants, the transgenic strain with two mutant sites (fln ^2TSA ) expresses only the two least acidic of the nine phosphovariants, and the transgenic strain with three mutant sites (fln ^3SA ) expresses all nine phosphovariants, as the wild-type strain. These results suggest that phosphorylation of Thr158 and/or Ser162 is necessary for subsequent phosphorylation of other sites. All three transgenic strains show normal, albeit long, IFM sarcomeres in newly eclosed adults. In contrast, sarcomeres in fully mature fln ^5STA and fln ^2TSA adults show extensive breakdown while those in fln ^3SA are not as disordered. The fiber hypercontraction phenotype that characterizes fln ⁰ is fully evident in fln ^5STA and fln ^2TSA but partially rescued in fln ^3SA . Mechanics on skinned fibers from newly eclosed flies show alterations in viscous modulus for fln ^5STA and fln ^2TSA that result in a significant reduction in oscillatory power output. Expression of fln ^5STA and fln ^2TSA , but not fln ^3SA , in a wild-type (fln ⁺ /fln ⁺ ) background resulted in a dominant negative effect manifested as flight impairments and hypercontracted IFM fibers. Our studies indicate that Thr158 and/or Ser162 are (is) indispensable for flightin function and suggest that phosphorylation of one or both residues fulfills an essential role in IFM structural stability and mechanics.     

Reference frames for reach planning in macaque dorsal premotor cortex

When a human or animal reaches out to grasp an object, the brain rapidly computes a pattern of muscular contractions that can acquire the target. This computation involves a reference frame transformation because the target's position is initially available only in a visual reference frame, yet the required control signal is a set of commands to the musculature. One of the core brain areas involved in visually guided reaching is the dorsal aspect of the premotor cortex (PMd). Using chronically implanted electrode arrays in two Rhesus monkeys, we studied the contributions of PMd to the reference frame transformation for reaching. PMd neurons are influenced by the locations of reach targets relative to both the arm and the eyes. Some neurons encode reach goals using limb-centered reference frames, whereas others employ eye-centered reference fames. Some cells encode reach goals in a reference frame best described by the combined position of the eyes and hand. In addition to neurons like these where a reference frame could be identified, PMd also contains cells that are influenced by both the eye- and limb-centered locations of reach goals but for which a distinct reference frame could not be determined. We propose two interpretations for these neurons. First, they may encode reach goals using a reference frame we did not investigate, such as intrinsic reference frames. Second, they may not be adequately characterized by any reference frame.     

Lupus resistance is associated with marginal zone abnormalities in an NZM murine model

The NZM2410 and NZM TAN (TAN) are two of 27 inbred strains derived from an intercross between the NZW and NZB strains. NZM2410 mice develop a highly penetrant lupus nephritis mediated by three susceptibility loci, Sle1, Sle2 and Sle3. These three loci have been combined on a C57BL/6 background in a triple congenic strain that reconstitutes the NZM2410 autoimmune phenotype. Remarkably, inspite of the presence of Sle1, Sle2 and Sle3, TAN mice display a mild autoimmune phenotype reminiscent of NZW. Contrary to the lupus-prone strains, the majority of TAN CD4(+) T cells are in a na?ve-inactivated stage. TAN mice show B-cell developmental abnormalities similar to lupus-prone mice, such an accumulation of transitional T1 cells and peritoneal B-1a cells. TAN mice show, however, a unique expansion of the splenic marginal zone, in which B cells express high levels of CD5 and CD9, fail to migrate to the follicles in response to LPS, and show sub-optimal binding of T-independent type 2 antigens. Therefore, TAN mice present a functional silencing of marginal zone B cells, which have been previously implicated with autoimmune process. The TAN strain thus provides a novel model for the analysis of the genetic determinants of B-cell autoreactivity.     

Summarizing benchmarks in the national database of nursing quality indicators using bootstrap confidence intervals

When summarizing the benchmarks for nursing quality indicators with confidence intervals around the means, bounds too high or too low are sometimes found due to small sample size or violation of the normality assumption. Transforming the data or truncating the confidence intervals at realistic values can solve the problem of out of range values. However, truncation does not improve upon the non-normality of the data, and transformations are not always successful in normalizing the data. The percentile bootstrap has the advantage of providing realistic bounds while not relying upon the assumption of normality and may provide a convenient way of obtaining appropriate confidence intervals around the mean for nursing quality indicators.     

Global Analysis Reveals the Complexity of the Human Glomerular Extracellular Matrix

The glomerulus contains unique cellular and extracellular matrix (ECM) components, which are required for intact barrier function. Studies of the cellular components have helped to build understanding of glomerular disease; however, the full composition and regulation of glomerular ECM remains poorly understood. We used mass spectrometry-based proteomics of enriched ECM extracts for a global analysis of human glomerular ECM in vivo and identified a tissue-specific proteome of 144 structural and regulatory ECM proteins. This catalog includes all previously identified glomerular components plus many new and abundant components. Relative protein quantification showed a dominance of collagen IV, collagen I, and laminin isoforms in the glomerular ECM together with abundant collagen VI and TINAGL1. Protein network analysis enabled the creation of a glomerular ECM interactome, which revealed a core of highly connected structural components. More than one half of the glomerular ECM proteome was validated using colocalization studies and data from the Human Protein Atlas. This study yields the greatest number of ECM proteins relative to previous investigations of whole glomerular extracts, highlighting the importance of sample enrichment. It also shows that the composition of glomerular ECM is far more complex than previously appreciated and suggests that many more ECM components may contribute to glomerular development and disease processes. The mass spectrometry proteomics data have been deposited to the ProteomeXchange Consortium with the dataset identifier PXD000456.The glomerulus is a sophisticated organelle comprising unique cellular and extracellular matrix (ECM) components. Fenestrated capillary endothelial cells and overlying podocytes are separated by a specialized glomerular basement membrane (GBM), and these three components together form the filtration barrier. Mesangial cells and their associated ECM, the mesangial matrix, exist between adjacent capillary loops and maintain the three-dimensional organization of the capillary bundle. In turn, the parietal epithelial cells and ECM of Bowman’s capsule enclose this network of capillaries. Cells adhere to ECM proteins by adhesion receptors, and these interactions are required to maintain intact barrier function of the glomerulus.^1,2In addition to operating as a signaling platform, ECM provides a structural scaffold for adjacent cells and has a tissue-specific molecular composition.^3,4 Candidate-based investigations of glomerular ECM have focused on the GBM and shown that it resembles the typical basal lamina found in multicellular organisms, containing a core of glycoproteins (collagen IV, laminins, and nidogens) and heparan sulfate proteoglycans (agrin, perlecan, and collagen XVIII).⁵ Mesangial and parietal cell ECMs have been less well investigated; nonetheless, they are also thought to contain similar core components in addition to other glycoproteins, including fibronectin.^6,7 Thus, the glomerulus consists of a combination of condensed ECM within the GBM and Bowman’s capsule and loose ECM supporting the mesangial cells.The ECM compartments in the glomerulus are thought to be distinct and exhibit different functional roles. The GBM is integral to the capillary wall and therefore, functionally linked to glomerular filtration.⁵ Mutations of tissue-restricted isoforms of collagen IV (COL4A3, COL4A4, and COL4A5) and laminin (LAMB2), which are found in the GBM, cause significant barrier dysfunction and ultimately, renal failure.^8,9 Less is understood about the functions of mesangial and parietal cell ECMs, although expansion of the mesangial compartment is a histologic pattern seen across the spectrum of glomerular disease.¹⁰Compositional investigation of the distinct glomerular ECM compartments is limited by the technical difficulties of separation. Early investigations of GBM constituents used the relative insolubility of ECM proteins to facilitate separation from cellular proteins in the glomerulus but did not separate the GBM from mesangial and parietal cells ECMs.^11,12 Recently, studies incorporating laser microdissection of glomerular sections have been coupled with proteomic analyses.^13,14 These studies report both cellular and ECM components and typically require pooled material from glomerular sections to improve protein identification. The ability of laser microdissection to separate glomerular ECM compartments has not yet been tested; however, this approach will be limited by the amount of protein that is possible to retrieve. To achieve good coverage of ECM proteins within a tissue, proteomic studies need to combine a reduction in sample complexity with maximal protein quantity. Currently, the inability to separate glomerular ECM compartments in sufficient quantity is a limitation that prohibits proteomic studies of these structures; however, for other tissues, proteomic analysis of ECM has been achieved by enrichment of ECM combined with sample fractionation.¹⁵Although the composition of the ECM in other tissues has been addressed using proteomic approaches,¹⁵ studies of glomerular ECM to date have used candidate-based technologies. These studies have identified key molecular changes during development and disease and highlighted the compositional and organizational dynamics of glomerular ECM. Nonetheless, the extracellular environment within the glomerulus is the setting for a complex series of interactions between both structural ECM proteins and ECM-associated proteins, such as growth factors^16–18 and proteases,¹⁹ which together provide a specialized niche to support glomerular cell function. Therefore, to interrogate this complexity effectively, a systems-level understanding of glomerular ECM is required. To address the need for a global analysis of the extracellular environment within the glomerulus, we used mass spectrometry (MS)-based proteomics of glomerular ECM fractions to define the human glomerular ECM proteome.     

Identification of a recent recombination event within the human beta-globin gene cluster.

In a detailed study of inheritance of DNA sequence polymorphism in a large reference pedigree, an individual was identified with an apparent genetic recombination event within the human beta-globin gene cluster. Analysis of the haplotypes of relevant individuals within this pedigree suggested that the meiotic crossing-over event is likely to have occurred within a 19.8-kilobase-pair region of the beta-globin gene cluster. Analysis of other DNA markers closely linked to the beta-globin gene cluster--segment 12 of chromosome 11 (D11S12) and loci for insulin, the cellular oncogene c-Ha-ras, and preproparathyroid hormone--confirmed that a crossover event must have occurred within the region of chromosome 11 between D11S12 and the beta-globin gene cluster. It is suggested that the event observed has occurred within a DNA region compatible with recombinational "hot spots" suggested by population studies.     

Ambulatory morning report

We assessed the ability of a novel ambulatory morning report format to expose internal medicine residents to the breadth of topics covered by the American Board of Internal Medicine (ABIM) exam. Cases were selected by the Ambulatory Assistant Chief Residents and recorded in a logbook to limit duplication. We conducted a retrospective review of 406 cases discussed from July 1998 to July 2000 and cataloged each according to the primary content area. The percentage of cases in each area accurately reflected that covered by the ABIM exam, with little redundancy or over-selection of esoteric diseases. Our data suggest that a general medicine clinic is capable of exposing house staff to the wide breadth of internal medicine topics previously thought to be unique to subspecialty clinics.     

Determinants of insulin secretion after renal transplantation

The high prevalence of post-transplant glucose intolerance and insulin resistance (IR) is associated with older age, family history of diabetes, immunosuppressive drugs, and antihypertensive therapy. However, the potential determinants of post-transplant beta-cell dysfunction are largely unknown. The objective of the present study was to address this issue in detail. A total of 167 previously nondiabetic renal transplant recipients underwent a 75-g oral glucose tolerance test (OGTT)10 weeks after transplantation. Serum glucose and insulin were measured at 0, 1, and 2 hours. Three insulin release indices (Secr(AUC), Secr(1.phase), and Secr(2.phase)) were calculated to assess the insulin secretory response as the dependent variable. To account for variations in insulin sensitivity (IS), beta-cell function was also estimated as the disposition index (DI); the product of the IS index (ISI(TX)) and Secr(1.phase). Increasing age was strongly and independently associated with a blunted insulin secretory response even after adjustment for IS (P =.001). An 80-year-old recipient had an approximately 50% lower insulin release than a 20-year-old individual, based on the linear regression model. Cytomegalovirus (CMV) disease and treatment with furosemide were both independently associated with beta-cell dysfunction (DI; P <.001 and P =.008). Patients treated with angiotensin-converting enzyme (ACE)-inhibitors had an enhanced absolute insulin release, but the DI was similar in both treated and untreated recipients. We conclude that older age is an important determinant of beta-cell dysfunction after renal transplantation. CMV disease and treatment with furosemide may also negatively influence pancreatic insulin release in renal transplant recipients.     

Shuttling of initiating kinase between discrete aggregates of the high affinity receptor for IgE regulates the cellular response

Using defined oligomers of IgE, our group previously studied the quantitative relationship between the aggregation of the high affinity receptors for IgE (FcRI) and the earliest signals initiated by such aggregation: the phosphorylation of tyrosines on the receptor. Notably, at certain doses of the oligomers such phosphorylation reached a plateau level well before the aggregation of the receptors had reached a maximum. These findings and others led us to propose that aggregates of the receptor were competing for a limited amount of the critical kinase—thought to be Lyn in this system. This paper describes a test of this proposal. We incubated cells with two distinguishable IgEs and examined the effect of aggregating one or the other or both types on the phosphorylation. When receptors binding antigen-specific IgE were aggregated with polyvalent antigen, they became rapidly phosphorylated as expected. Remarkably, however, FcRI that had already been phosphorylated by the binding of dimers of IgE, became dephosphorylated simultaneously. Furthermore, when the antigen-driven aggregates were dissociated with hapten, the phosphorylation pattern reverted to that seen prior to the addition of antigen: as the antigen-driven aggregates became dephosphorylated, the receptors stably aggregated by the bound oligomers became rapidly rephosphorylated. Dephosphorylation of oligomer-driven aggregates was also partially reversed during the “spontaneous” dephosphorylation of the antigen-driven receptors seen at longer times after addition of antigen. Thus signal transduction in this system is in part regulated by the shuttling of limited amounts of the kinase that initiates the cascade of phosphorylations.