For the love of insects: gardening grows positive emotions (biophilia) towards invertebrates

Journal of Insect Conservation - As growing urban populations have fewer chances to experience nature, i.e., ‘the extinction of experience’, the subsequent loss of emotional affinities...     

Analysis of Phosphorylation-dependent Protein Interactions of Adhesion and Degranulation Promoting Adaptor Protein (ADAP) Reveals Novel Interaction Partners Required for Chemokine-directed T cell Migration

Stimulation of T cells leads to distinct changes of their adhesive and migratory properties. Signal propagation from activated receptors to integrins depends on scaffolding proteins such as the adhesion and degranulation promoting adaptor protein (ADAP)¹. Here we have comprehensively investigated the phosphotyrosine interactome of ADAP in T cells and define known and novel interaction partners of functional relevance. While most phosphosites reside in unstructured regions of the protein, thereby defining classical SH2 domain interaction sites for master regulators of T cell signaling such as SLP76, Fyn-kinase, and NCK, other binding events depend on structural context. Interaction proteomics using different ADAP constructs comprising most of the known phosphotyrosine motifs as well as the structured domains confirm that a distinct set of proteins is attracted by pY571 of ADAP, including the ζ-chain-associated protein kinase of 70 kDa (ZAP70). The interaction of ADAP and ZAP70 is inducible upon stimulation either of the T cell receptor (TCR) or by chemokine. NMR spectroscopy reveals that the N-terminal SH2 domains within a ZAP70-tandem-SH2 construct is the major site of interaction with phosphorylated ADAP-hSH3^N and microscale thermophoresis (MST) indicates an intermediate binding affinity (K_d = 2.3 μm). Interestingly, although T cell receptor dependent events such as T cell/antigen presenting cell (APC) conjugate formation and adhesion are not affected by mutation of Y571, migration of T cells along a chemokine gradient is compromised. Thus, although most phospho-sites in ADAP are linked to T cell receptor related functions we have identified a unique phosphotyrosine that is solely required for chemokine induced T cell behavior.T cell migration and the establishment of productive T cell/APC interactions are regulated by the activity of integrins. In resting T cells, integrins are expressed in an inactive state that adopts a conformation with low affinity for their ligands. Members of the intercellular adhesion molecule family (ICAM 1–5) are the physiological ligands of lymphocyte function-associated antigen 1 (LFA-1, αLβ2-integrin) whereas vascular cell adhesion molecule (VCAM) and fibronectin are the ligands for the β1-integrin very late antigen 4 (VLA-4) (1, 2). Triggering of the T cell receptor (TCR) by peptide-major histocompatibility complex (MHC) or stimulation of chemokine receptors (e.g. CCR7 with CCL21 or CXCR4 with CXCL12) induces a conformational change of the integrins that increases their ligand binding (affinity regulation) and subsequently mediates clustering of integrins at the cell surface (avidity regulation). The intracellular events leading to integrin activation have collectively been termed inside-out signaling. Conversely, ligand-bound integrins transmit a signal to the T cell and thereby promote adhesion, activation, proliferation, and migration of T cells (outside-in signaling) (1, 2).In both inside-out and outside-in signaling pathways tyrosine phosphorylation of adaptor proteins, either present as transmembrane scaffolds or as transiently membrane-anchored proteins, is a crucial primary event in signal transmission to integrins.An essential functional module operating at the integrin-membrane-cytoskeleton interface contains the cytosolic adaptor protein ADAP at its core. Ablation of ADAP in mice leads to dysfunctional integrin clustering and activity, thus compromising the adhesive and migratory properties of these cells. In addition to its instantaneous effects on cellular motility, ADAP was shown to act as a regulator of NFκB p65 nuclear translocation (3), a function that might well contribute to the observed modulation of cytokine production, like interleukin-2 (4, 5). A contribution of ADAP to mast cell degranulation has been postulated (6), and its complex formation with cytoskeletal regulators during early phases of phagocytosis in macrophages has been recognized early on (7). ADAP is also critical for normal platelet adhesion (8) and mutations in the human protein have recently been suggested to form an underlying genetic cause for autosomal recessive thrombocytopenia (9).ADAP interacts with several effectors of T cell function, either constitutively or phosphorylation-dependent. The SH3 domain of SKAP55 (Src-kinase associated phosphoprotein of 55 kDa) interacts with a proline-rich sequence (PRS) stretch in ADAP (Fig. 1A) (10, 11), whereas another PRS (FPPPP) is responsible for the interaction with the actin regulator Ena/VASP-like protein (EVL) (12). Membrane binding of the ADAP-SKAP55 complex is conferred by the PH domain of SKAP55 and to a lower extend by the C-terminal hSH3 domain (hSH3^C) of ADAP (13–16). Moreover, ADAP is strongly tyrosine-phosphorylated upon TCR stimulation and thereby serves as a hub for SH2 domain-containing proteins such as SLP76, FYN and NCK (Fig. 1A) (17–21). Beside these well characterized interactions, several other SH2-domain containing binders were identified by pull-down approaches using phosphorylated peptide baits (Fig. 1A) (22, 23). Most of the so far characterized SH2-pTyr interactions in ADAP are mapped to unstructured regions. An exception is Y571, which is located in close proximity to the folded hSH3^N domain of ADAP. Phosphoproteomic profiling of activated T cells has identified Y571 as a major phosphorylation site in ADAP (18, 24–30). Our rationale for the experimental approach chosen here was that the constraints imposed by the folding of the hSH3 domains impact the choice of SH2 domains that bind to such motifs in ADAP.Open in a separate windowFig. 1.Phosphotyrosine sites of ADAP and interaction partners. A, Schematic overview of the ADAP primary structure indicating interaction partners of different phosphotyrosine sites identified by peptide pull-down approaches (22, 23). Black arrows show SH2-pTyr interaction sites. White arrows show interactions dependent on proline rich sequences (PRS). B, Fyn kinase catalyzed in vitro phosphorylation of full-length ADAP. Identification and relative quantification of phosphorylation degrees of individual tyrosine residues was obtained by mass spectrometry. Phosphorylation degrees were estimated by comparing relative MS peak intensities of the corresponding peptide/phosphopeptide pairs as described (33, 34).To meet this challenge, we employed interaction proteomics and immunoprecipitation experiments using different constructs of ADAP that comprise the major phosphotyrosine sites including the two folded hSH3 domains. In particular, Y571, a residue residing at the domain border of the hSH3^N domain, is shown to interact with proteins that are not identified by the peptide pull-down approach. We identify the ZAP70 kinase as the most robust binding partner of pY571 and show that this interaction is maintained in primary T cells. Using NMR spectroscopy we further show that the N-terminal SH2 domain of ZAP70 is responsible for binding and we confirm the direct interaction between the two proteins to be inducible upon T cell receptor or CXCR4 stimulation. Abolishing the interaction by using a Y571F mutation compromises T cell migration along a CXCL12 gradient but does not affect TCR- and CXCR4-mediated adhesion and T cell interaction with APCs. In this way, the Y571F mutant of ADAP provides the striking example of a molecular switch that selectively invokes the migratory, but not the adhesive, signaling pathways in T cells.     

Impaired integrin α5/β1‐mediated hepatocyte growth factor release by stellate cells of the aged liver

Hepatic blood flow and sinusoidal endothelial fenestration decrease during aging. Consequently, fluid mechanical forces are reduced in the space of Disse where hepatic stellate cells (HSC) have their niche. We provide evidence that integrin α₅/β₁ is an important mechanosensor in HSC involved in shear stress‐induced release of hepatocyte growth factor (HGF), an essential inductor of liver regeneration which is impaired during aging. The expression of the integrin subunits α₅ and β₁ decreases in liver and HSC from aged rats. CRISPR/Cas9‐mediated integrin α₅ and β₁ knockouts in isolated HSC lead to lowered HGF release and impaired cellular adhesion. Fluid mechanical forces increase integrin α₅ and laminin gene expression whereas integrin β₁ remains unaffected. In the aged liver, laminin β2 and γ1 protein chains as components of laminin‐521 are lowered. The integrin α₅ knockout in HSC reduces laminin expression via mechanosensory mechanisms. Culture of HSC on nanostructured surfaces functionalized with laminin‐521 enhances Hgf expression in HSC, demonstrating that these ECM proteins are critically involved in HSC function. During aging, HSC acquire a senescence‐associated secretory phenotype and lower their growth factor expression essential for tissue repair. Our findings suggest that impaired mechanosensing via integrin α₅/β₁ in HSC contributes to age‐related reduction of ECM and HGF release that could affect liver regeneration.     

mTOR and differential activation of mitochondria orchestrate neutrophil chemotaxis

Neutrophils use chemotaxis to locate invading bacteria. Adenosine triphosphate (ATP) release and autocrine purinergic signaling via P2Y2 receptors at the front and A2a receptors at the back of cells regulate chemotaxis. Here, we examined the intracellular mechanisms that control these opposing signaling mechanisms. We found that mitochondria deliver ATP that stimulates P2Y2 receptors in response to chemotactic cues, and that P2Y2 receptors promote mTOR signaling, which augments mitochondrial activity near the front of cells. Blocking mTOR signaling with rapamycin or PP242 or mitochondrial ATP production (e.g., with CCCP) reduced mitochondrial Ca²⁺ uptake and membrane potential, and impaired cellular ATP release and neutrophil chemotaxis. Autocrine stimulation of A2a receptors causes cyclic adenosine monophosphate accumulation at the back of cells, which inhibits mTOR signaling and mitochondrial activity, resulting in uropod retraction. We conclude that mitochondrial, purinergic, and mTOR signaling regulates neutrophil chemotaxis and may be a pharmacological target in inflammatory diseases.     

The tumor necrosis factor family member LIGHT is a target for asthmatic airway remodeling

Individuals with chronic asthma show a progressive decline in lung function that is thought to be due to structural remodeling of the airways characterized by subepithelial fibrosis and smooth muscle hyperplasia. Here we show that the tumor necrosis factor (TNF) family member LIGHT is expressed on lung inflammatory cells after allergen exposure. Pharmacological inhibition of LIGHT using a fusion protein between the IgG Fc domain and lymphotoxin β receptor (LTβR) reduces lung fibrosis, smooth muscle hyperplasia and airway hyperresponsiveness in mouse models of chronic asthma, despite having little effect on airway eosinophilia. LIGHT-deficient mice also show a similar impairment in fibrosis and smooth muscle accumulation. Blockade of LIGHT suppresses expression of lung transforming growth factor-β (TGF-β) and interleukin-13 (IL-13), cytokines implicated in remodeling in humans, whereas exogenous administration of LIGHT to the airways induces fibrosis and smooth muscle hyperplasia, Thus, LIGHT may be targeted to prevent asthma-related airway remodeling.     

Genotypic richness and dissimilarity opposingly affect ecosystem functioning

Biodiversity is an essential determinant of ecosystem functioning. Numerous studies described positive effects of diversity on the functioning of communities arising from complementary resource use and facilitation. However, high biodiversity may also increase competitive interactions, fostering antagonism and negatively affecting community performance. Using experimental bacterial communities we differentiated diversity effects based on genotypic richness and dissimilarity. We show that these diversity characteristics have opposite effects on ecosystem functioning. Genotypic dissimilarity governed complementary resource use, improving ecosystem functioning in complex resource environments. Contrastingly, genotypic richness drove allelopathic interactions, mostly reducing ecosystem functioning. The net biodiversity effect on community performance resulted from the interplay between the genetic structure of the community and resource complexity. These results demonstrate that increasing richness, without concomitantly increasing dissimilarity, can decrease ecosystem functioning in simple environments due to antagonistic interactions, an effect insufficiently considered so far in mechanistic models of the biodiversity-ecosystem functioning relationship.     

Arthropod food webs in organic and conventional wheat farming systems of an agricultural long‐term experiment: a stable isotope approach

• 1 Agricultural intensification not only alters the structure of arthropod communities, but also may affect biotic interactions by altering the availability of basal resources. We analyzed variations in stable isotope ratios (¹⁵N/¹⁴N and ¹³C/¹²C) of fertilizers, plants, prey and generalist predators in organic and conventional farming systems in a long‐term agricultural experiment [DOK trial (bioDynamic, bioOrganic, Konventionell)]. Two basal resources with pronounced differences in carbon isotope signatures, wheat litter (C₃ plant) and maize litter (C₄ plant), were used to uncover differences in food web properties between the two farming systems (conventional versus organic).
• 2 Predators incorporated significantly higher proportions of carbon from wheat sources in organically managed fields, suggesting that they were more closely linked to wheat‐consuming prey in this system. The δ¹⁵N values of three predaceous species were more than 2‰ greater in summer than in spring.
• 3 The results obtained suggest that generalist predators consumed higher proportions of herbivore prey in the organic system and that starvation and intraguild predation rates increased in some predator species with time.
• 4 Because the effects of farming system and sampling date on predators were species‐specific, conserving a diverse natural enemy community including species with different phenologies and sensitivities to management practices may, in the long term, be a good strategy for maintaining high pest suppression throughout the growing season.

     

Covalent immunoglobulin labeling through a photoactivable synthetic Z domain

Traditionally, labeling of antibodies has been performed by covalent conjugation to amine or carboxyl groups. These methods are efficient but suffer from nonspecificity, since all free and available amine/carboxyl groups have the possibility to react. This drawback may lead to uncontrolled levels and locations of the labeling. Hence, the labeled molecules might behave differently and, possibly, the binding site of the antibody will also be affected. In this project, we have developed a highly stringent method for labeling of antibodies by utilizing an immunoglobulin-binding domain from protein A, the Z domain. Domain Z has been synthesized with an amino acid analogue, benzoylphenylalanine, capable of forming covalent attachment to other amino acids upon UV-exposure. This feature has been used for directed labeling of immunoglobulins and subsequent use of these in different assays.     

Novel temporal, fine-scale and growth variation phenotypes in roots of adult-stage maize (Zea mays L.) in response to low nitrogen stress

There is interest in discovering root traits associated with acclimation to nutrient stress. Large root systems, such as in adult maize, have proven difficult to be phenotyped comprehensively and over time, causing target traits to be missed. These challenges were overcome here using aeroponics, a system where roots grow in the air misted with a nutrient solution. Applying an agriculturally relevant degree of low nitrogen (LN) stress, 30-day-old plants responded by increasing lengths of individual crown roots (CRs) by 63%, compensated by a 40% decline in CR number. LN increased the CR elongation rate rather than lengthening the duration of CR growth. Only younger CR were significantly responsive to LN stress, a novel finding. LN shifted the root system architectural balance, increasing the lateral root (LR)-to-CR ratio, adding ～70 m to LR length. LN caused a dramatic increase in second-order LR density, not previously reported in adult maize. Despite the near-uniform aeroponics environment, LN induced increased variation in the relative lengths of opposing LR pairs. Large-scale analysis of root hairs (RHs) showed that LN decreased RH length and density. Time-course experiments suggested the RH responses may be indirect consequences of decreased biomass/demand under LN. These results identify novel root traits for genetic dissection.