Use of conformationally restricted pyridinium alpha-D-N-acetylneuraminides to probe specificity in bacterial and viral sialidases.

Investigations into subtle changes in the catalytic activity of sialidases have been performed using enzymes from several different origins, and their results have been compared. This work highlights the potential pitfalls encountered when extending conclusions derived from mechanistic studies on a single enzyme even to those with high-sequence homology. Specifically, a panel of 5 pyridinium N-acetylneuraminides were used as substrates in a study that revealed subtle differences in the catalytic mechanisms used by 4 different sialidase enzymes. The lowest reactivity towards the artificial (pyridinium) substrates was displayed by the Newcastle disease virus hemagglutinin-neuraminidase. Moreover, in reactions involving aryl N-acetylneuraminides, the activity of the Newcastle enzyme was competitively inhibited by the 3,4-dihydro-2H-pyrano[3,2-c]pyridinium compound with a Ki = 58 micromol/L. Alternatively, the 3 bacterial enzymes tested, from Salmonella typhimurium, Clostridium perfringens, and Vibrio cholerae, were catalytically active against all members of the panel of substrates. Based on the observed effect of leaving-group ability, it is proposed that the rate-determining step for kcat (and likely for kcat/Km as well) with each bacterial enzyme is as follows: sialylation, which is concerted with conformational change for V. cholerae; and conformational change for S. typhimurium and C. perfringens.     

Intrinsic local destabilization of the C‐terminus predisposes integrin α1 I domain to a conformational switch induced by collagen binding

Integrin–collagen interactions play a critical role in a myriad of cellular functions that include immune response, and cell development and differentiation, yet their mechanism of binding is poorly understood. There is increasing evidence that conformational flexibility assumes a central role in the molecular mechanisms of protein–protein interactions and here we employ NMR hydrogen–deuterium exchange (HDX) experiments to explore the impact of slower timescale dynamic events. To gain insight into the mechanisms underlying collagen‐induced conformational switches, we have undertaken a comparative study between the wild type integrin α1 I and a gain‐of‐function E317A mutant. NMR HDX results suggest a relationship between regions exhibiting a reduced local stability in the unbound I domain and those that undergo significant conformational changes upon binding. Specifically, the αC and α7 helices within the C‐terminus are at the center of such major perturbations and present reduced local stabilities in the unbound state relative to other structural elements. Complementary isothermal titration calorimetry experiments have been performed to derive complete thermodynamic binding profiles for association of the collagen‐like triple‐helical peptide with wild type α1 I and E317A mutant. The differential energetics observed for E317A are consistent with the HDX experiments and support a model in which intrinsically destabilized regions predispose conformational rearrangement in the integrin I domain. This study highlights the importance of exploring different timescales to delineate allosteric and binding events.     

Exosomes Secreted by Apoptosis-Resistant Acute Myeloid Leukemia (AML) Blasts Harbor Regulatory Network Proteins Potentially Involved in Antagonism of Apoptosis

Expression of apoptosis-regulating proteins (B-cell CLL/lymphoma 2 - BCL-2, Myeloid Cell Leukemia 1 - MCL-1, BCL-2 like 1 - BCL-X and BCL-2-associated X protein - BAX) in acute myeloid leukemia (AML) blasts at diagnosis is associated with disease-free survival. We previously found that the initially high apoptosis-resistance of AML cells decreased after therapy, while regaining high levels at relapse. Herein, we further explored this aspect of dynamic apoptosis regulation in AML. First, we showed that the intraindividual ex vivo apoptosis-related profiles of normal lymphocytes and AML blasts within the bone marrow of AML patients were highly correlated. The expression values of apoptosis-regulating proteins were far beyond healthy control lymphocytes, which implicates the influence of microenvironmental factors. Second, we demonstrated that apoptosis-resistant primary AML blasts, as opposed to apoptosis-sensitive cells, were able to up-regulate BCL-2 expression in sensitive AML blasts in contact cultures (p = 0.0067 and p = 1.0, respectively). Using secretome proteomics, we identified novel proteins possibly engaged in apoptosis regulation. Intriguingly, this analysis revealed that major functional protein clusters engaged in global gene regulation, including mRNA splicing, protein translation, and chromatin remodeling, were more abundant (p = 4.01E-06) in secretomes of apoptosis-resistant AML. These findings were confirmed by subsequent extracellular vesicle proteomics. Finally, confocal-microscopy-based colocalization studies show that splicing factors-containing vesicles secreted by high AAI cells are taken up by low AAI cells. The current results constitute the first comprehensive analysis of proteins released by apoptosis-resistant and sensitive primary AML cells. Together, the data point to vesicle-mediated release of global gene regulatory protein clusters as a plausible novel mechanism of induction of apoptosis resistance. Deciphering the modes of communication between apoptosis-resistant blasts may in perspective lead to the discovery of prognostic tools and development of novel therapeutic interventions, aimed at limiting or overcoming therapy resistance.Despite good remission rates observed in acute myeloid leukemia (AML) patients, the 5-year event-free survival rates reach only 35–40% in adults and 60–70% in children (1, 2). Apoptosis is one of the crucial mechanisms influencing survival of AML cells, and its deregulation can possibly lead to chemotherapy resistance and eventually relapse (3–5). The ability of cells to undergo apoptosis is largely defined by the relative expression of anti- (i.e. BCL-2, BCL-X long isoform - BCL-XL, or MCL-1) and proapoptotic (i.e. BAX, BH3 interacting domain death agonist - BID, caspases) proteins. Several studies have shown that the levels of BCL-2 and BCL-2/BAX ratio are a determinant of apoptosis-resistance in AML blasts and are associated with survival in AML patients (3, 6). We have previously demonstrated that the expression of several apoptosis-related proteins, such as BCL-2, BCL-XL, MCL-1, and BAX, can be reliably measured in AML samples by flow cytometry (6). These four quantitative parameters, which constitute an anti-apoptosis index (AAI)¹, have proven to be a reliable predictor of AML patients'' survival, with a high apoptosis-resistant profile (i.e. higher AAI) of diagnosis leukemic blasts being associated with shorter disease-free survival (7). Accordingly, AAI determined at the time of diagnosis also correlated with the frequency of minimal residual disease (MRD), which is a reflection of drug-resistant leukemic cells that have survived chemotherapy (7). MRD can be detected at a low frequency in bone marrow (BM) at the time of remission and is thought to contain the relapse-initiating cells (8–10). These observations imply that leukemic cells that harbor an apoptosis-resistant protein profile at diagnosis can better survive chemotherapy, thereby eventually causing a relapse. Consequently, we further hypothesized that the AAI of MRD cells would be either elevated or at least similar to the profile of leukemic cells at diagnosis. Surprisingly, in complete remission patients, the AAI decreased in the MRD situation compared with apoptosis-resistant profile as measured in leukemic blasts at diagnosis. The values of the AAI profile increased again at relapse, indicating apoptosis-resistance (11). Based on these unexpected findings, we hypothesized that expression of apoptosis-related proteins in AML blasts, and possibly also in bystander cells in the bone marrow, is regulated by extracellular factors present in the AML microenvironment.Tumor cell communication with its microenvironment is emerging as an important determinant playing multiple roles in cancer. In this respect, both soluble factors and extracellular vesicles (EVs), most notably exosomes, have been shown to influence cellular processes of malignant and normal cells in the tumor microenvironment (12–14). Apoptosis in the AML setting can be regulated by several cytokines as well as by EVs, which carry variable cargoes, including multiple proteins (15–18). In line with our hypothesis, apoptosis of BM cells was shown to be inhibited in the presence of secretome derived from AML blasts (19). These observations suggest that factors secreted by apoptosis-resistant leukemic blasts are likely to confer a drug resistance phenotype upon initially sensitive blasts. Therefore, the aim of our current study was to characterize the microenvironment produced by apoptosis-resistant AML blasts in terms of its capacity to influence apoptosis regulation in neighboring cells and protein content.     

ALS/FTD‐associated FUS activates GSK‐3β to disrupt the VAPB–PTPIP51 interaction and ER–mitochondria associations

Defective FUS metabolism is strongly associated with amyotrophic lateral sclerosis and frontotemporal dementia (ALS/FTD), but the mechanisms linking FUS to disease are not properly understood. However, many of the functions disrupted in ALS/FTD are regulated by signalling between the endoplasmic reticulum (ER) and mitochondria. This signalling is facilitated by close physical associations between the two organelles that are mediated by binding of the integral ER protein VAPB to the outer mitochondrial membrane protein PTPIP51, which act as molecular scaffolds to tether the two organelles. Here, we show that FUS disrupts the VAPB–PTPIP51 interaction and ER–mitochondria associations. These disruptions are accompanied by perturbation of Ca²⁺ uptake by mitochondria following its release from ER stores, which is a physiological read‐out of ER–mitochondria contacts. We also demonstrate that mitochondrial ATP production is impaired in FUS‐expressing cells; mitochondrial ATP production is linked to Ca²⁺ levels. Finally, we demonstrate that the FUS‐induced reductions to ER–mitochondria associations and are linked to activation of glycogen synthase kinase‐3β (GSK‐3β), a kinase already strongly associated with ALS/FTD.     

ASPM and CITK regulate spindle orientation by affecting the dynamics of astral microtubules

Correct orientation of cell division is considered an important factor for the achievement of normal brain size, as mutations in genes that affect this process are among the leading causes of microcephaly. Abnormal spindle orientation is associated with reduction of the neuronal progenitor symmetric divisions, premature cell cycle exit, and reduced neurogenesis. This mechanism has been involved in microcephaly resulting from mutation of ASPM, the most frequently affected gene in autosomal recessive human primary microcephaly (MCPH), but it is presently unknown how ASPM regulates spindle orientation. In this report, we show that ASPM may control spindle positioning by interacting with citron kinase (CITK), a protein whose loss is also responsible for severe microcephaly in mammals. We show that the absence of CITK leads to abnormal spindle orientation in mammals and insects. In mouse cortical development, this phenotype correlates with increased production of basal progenitors. ASPM is required to recruit CITK at the spindle, and CITK overexpression rescues ASPM phenotype. ASPM and CITK affect the organization of astral microtubules (MT), and low doses of MT‐stabilizing drug revert the spindle orientation phenotype produced by their knockdown. Finally, CITK regulates both astral‐MT nucleation and stability. Our results provide a functional link between two established microcephaly proteins.     

Race,ethnicity and German identity: a media analysis of the 2010 world cup men's national soccer team

Enjoying a surge of national pride, the German media celebrated the 2010 German World Cup team's success in South Africa. A dominant theme in this coverage was the ‘immigration background’ of 11 of the 23 players on the team and their claim to German identity despite their ethnic diversity. Amid debate over the changing nature of German citizenship, the national team's ‘multicultural kickers’ became the focal point for those who wished to re-frame German identity. This article examines German newspaper and magazine coverage of the national soccer team emphasizing the role that media played in constructing competing definitions of the German citizen and nation.     

Gebruiksvriendelijkheid van computerondersteunde cognitieve training bij psychogeriatrische patiënten met lichte tot matige cognitieve functiestoornissen

Cognitive impairment associated with dementia is characterized by a continuous decline. Cognitive training is a method to train specific brain functions such as memory and attention to prevent or slow down cognitive decline. A small number of studies has shown that cognitive training on a computer has a positive effect on both cognition and mood in people with cognitive impairment. This pilot study tested if serious games could be integrated in a psychogeriatric rehabilitation center. Fourteen psychogeriatric patients participated twice weekly in cognitive training sessions on a computer. Both the participants and the facilitator reported positive interactions and outcomes. However, after five weeks only half of the sample still participated in the training. This was partly because of patient turn-over as well as incorporating this new task in the facilitators’ daily work. Fear of failure, physical limitations and rapidly decreasing cognitive function led to drop out according to the facilitator. The engagement of patients in the games and the role of the facilitator seemed essential for success, especially monitoring (and adjusting) the difficulty level of the program for every individual participant.     

Long‐term outcomes of forest restoration in an urban park

Creating, restoring, and sustaining forests in urban areas are complicated by habitat fragmentation, invasive species, and degraded soils. Although there is some research on the outcomes of urban reforestation plantings during the first 5 years, there is little research on longer term outcomes. Here, we compare the successional trajectories of restored and unrestored forest sites 20 years after initiating restoration. The sites are located within the Rodman's Neck area of Pelham Bay Park, in the northeast corner of the Bronx in New York City (NYC), U.S.A. Compared with unrestored sites, we saw improvements in species diversity, greater forest structure complexity, and evidence of the regeneration and retention of native tree species in restored sites. In addition, we found differences in restoration outcomes depending on the level of intervention: clearing exotic shrubs and vines and planting native trees and shrubs improved tree diversity and canopy closure to a greater extent than clearing exotics alone, and the mechanical removal of invasive plants after the native plantings further improved some measures of restoration, such as tree species diversity and native tree regeneration. The results of this study suggest that the goal of a sustainable forest ecosystem dominated by native trees and other plant species may not be achievable without continued human intervention on site. In addition, these results indicate that the restoration approach adopted by NYC's reforestation practitioners is moving the site toward a more desirable vegetative community dominated by native species.