Persistent Autoantibody-Production by Intermediates between Short-and Long-Lived Plasma Cells in Inflamed Lymph Nodes of Experimental Epidermolysis Bullosa Acquisita

Autoantibodies are believed to be maintained by either the continuous generation of short-lived plasma cells in secondary lymphoid tissues or by long-lived plasma cells localized in bone marrow and spleen. Here, we show in a mouse model for the autoimmune blistering skin disease epidermolysis bullosa acquisita (EBA) that chronic autoantibody production can also be maintained in inflamed lymph nodes, by plasma cells exhibiting intermediate lifetimes. After EBA induction by immunization with a mCOL7c-GST-fusion protein, antigen-specific plasma cells and CD4 T cells were analyzed. Plasma cells were maintained for months in stable numbers in the draining lymph nodes, but not in spleen and bone marrow. In contrast, localization of mCOL7c-GST -specific CD4 T cells was not restricted to lymph nodes, indicating that availability of T cell help does not limit plasma cell localization to this site. BrdU-incorporation studies indicated that pathogenic mCOL7c- and non-pathogenic GST-specific plasma cells resemble intermediates between short-and long-lived plasma cells with half-lives of about 7 weeks. Immunization with mCOL7c-GST also yielded considerable numbers of plasma cells neither specific for mCOL7c- nor GST. These bystander-activated plasma cells exhibited much shorter half-lives and higher population turnover, suggesting that plasma cell lifetimes were only partly determined by the lymph node environment but also by the mode of activation. These results indicate that inflamed lymph nodes can harbor pathogenic plasma cells exhibiting distinct properties and hence may resemble a so far neglected site for chronic autoantibody production.     

Src Dependent Pancreatic Acinar Injury Can Be Initiated Independent of an Increase in Cytosolic Calcium

Several deleterious intra-acinar phenomena are simultaneously triggered on initiating acute pancreatitis. These culminate in acinar injury or inflammatory mediator generation in vitro and parenchymal damage in vivo. Supraphysiologic caerulein is one such initiator which simultaneously activates numerous signaling pathways including non-receptor tyrosine kinases such as of the Src family. It also causes a sustained increase in cytosolic calcium- a player thought to be crucial in regulating deleterious phenomena. We have shown Src to be involved in caerulein induced actin remodeling, and caerulein induced changes in the Golgi and post-Golgi trafficking to be involved in trypsinogen activation, which initiates acinar cell injury. However, it remains unclear whether an increase in cytosolic calcium is necessary to initiate acinar injury or if injury can be initiated at basal cytosolic calcium levels by an alternate pathway. To study the interplay between tyrosine kinase signaling and calcium, we treated mouse pancreatic acinar cells with the tyrosine phosphatase inhibitor pervanadate. We studied the effect of the clinically used Src inhibitor Dasatinib (BMS-354825) on pervanadate or caerulein induced changes in Src activation, trypsinogen activation, cell injury, upstream cytosolic calcium, actin and Golgi morphology. Pervanadate, like supraphysiologic caerulein, induced Src activation, redistribution of the F-actin from its normal location in the sub-apical area to the basolateral areas, and caused antegrade fragmentation of the Golgi. These changes, like those induced by supraphysiologic caerulein, were associated with trypsinogen activation and acinar injury, all of which were prevented by Dasatinib. Interestingly, however, pervanadate did not cause an increase in cytosolic calcium, and the caerulein induced increase in cytosolic calcium was not affected by Dasatinib. These findings suggest that intra-acinar deleterious phenomena may be initiated independent of an increase in cytosolic calcium. Other players resulting in acinar injury along with the Src family of tyrosine kinases remain to be explored.     

Toxicity and anti-angiogenicity evaluation of Pak1 inhibitor IPA-3 using zebrafish embryo model

p21-activated kinase 1 (Pak1)—a key node protein kinase regulating various cellular process including angiogenesis—has been recognised to be a therapeutic target for multitude of diseases, and hence, various small molecule inhibitors targeting its activity have been tested. However, the direct toxic and anti-angiogenic effects of these pharmacologic agents have not been examined. In this study, we evaluate the translational efficacy of Pak1 inhibitor IPA-3 using zebrafish toxicity model system to stratify its anti-angiogenic potential and off-target effects to streamline the compound for further therapeutic usage. The morphometric analysis has shown explicit delay in hatching, tail bending, pericardial sac oedema and abnormal angiogenesis. We provide novel evidence that Pak1 inhibitor could act as anti-angiogenic agents by impeding the development of sub-intestinal vessel (SIV) and intersegmental vessels (ISVs) by suppressing the expression of vascular endothelial growth factor (VEGF), VEGF receptor 2 (VEGFR2), neurophilin 1 (NRP1) and its downstream genes matrix metalloproteinase (MMP)-2 and MMP-9. Knockdown studies using 2-O-methylated oligoribonucleotides targeting Pak1 also revealed similar phenotypes with inhibition of angiogenesis accompanied with deregulation of major angiogenic factor and cardiac-specific genes. Taken together, our findings indicate that Pak1 signalling facilitates enhanced angiogenesis and also advocated the design and use of small molecule inhibitors of Pak1 as potent anti-angiogenic agents and suggest their utility in combinatorial therapeutic approaches targeting anomalous angiogenesis.     

Nitrate-Dependent Control of Shoot K Homeostasis by the Nitrate Transporter1/Peptide Transporter Family Member NPF7.3/NRT1.5 and the Stelar K+ Outward Rectifier SKOR in Arabidopsis

Root-to-shoot translocation and shoot homeostasis of potassium (K) determine nutrient balance, growth, and stress tolerance of vascular plants. To maintain the cation-anion balance, xylem loading of K⁺ in the roots relies on the concomitant loading of counteranions, like nitrate (NO₃⁻). However, the coregulation of these loading steps is unclear. Here, we show that the bidirectional, low-affinity Nitrate Transporter1 (NRT1)/Peptide Transporter (PTR) family member NPF7.3/NRT1.5 is important for the NO₃⁻-dependent K⁺ translocation in Arabidopsis (Arabidopsis thaliana). Lack of NPF7.3/NRT1.5 resulted in K deficiency in shoots under low NO₃⁻ nutrition, whereas the root elemental composition was unchanged. Gene expression data corroborated K deficiency in the nrt1.5-5 shoot, whereas the root responded with a differential expression of genes involved in cation-anion balance. A grafting experiment confirmed that the presence of NPF7.3/NRT1.5 in the root is a prerequisite for proper root-to-shoot translocation of K⁺ under low NO₃⁻ supply. Because the depolarization-activated Stelar K⁺ Outward Rectifier (SKOR) has previously been described as a major contributor for root-to-shoot translocation of K⁺ in Arabidopsis, we addressed the hypothesis that NPF7.3/NRT1.5-mediated NO₃⁻ translocation might affect xylem loading and root-to-shoot K⁺ translocation through SKOR. Indeed, growth of nrt1.5-5 and skor-2 single and double mutants under different K/NO₃⁻ regimes revealed that both proteins contribute to K⁺ translocation from root to shoot. SKOR activity dominates under high NO₃⁻ and low K⁺ supply, whereas NPF7.3/NRT1.5 is required under low NO₃⁻ availability. This study unravels nutritional conditions as a critical factor for the joint activity of SKOR and NPF7.3/NRT1.5 for shoot K homeostasis.The macronutrient potassium (K) is essential for plant growth and development because of its crucial roles in various cellular processes (i.e. regulation of enzyme activities), stabilization of protein synthesis, and neutralization of negative charges. In addition, it is a major component of the cation-anion balance and osmoregulation in plants, thereby influencing cellular turgor, xylem and phloem transport, pH homeostasis, and the setting of membrane potentials (Maathuis, 2009; Marschner, 2012; Sharma et al., 2013). K⁺ uptake and distribution in Arabidopsis (Arabidopsis thaliana) are accomplished by a total of 71 membrane proteins that have been assigned to five gene families: the Shaker and Tandem-Pore K⁺ channels (now also including the inward-rectifier K-like (K_ir-like) channels), the K⁺ uptake permeases (KUP/HAK/KT), the K⁺ transporter (HKT) family, and the cation proton antiporters (CPA; Gierth and Mäser, 2007; Gomez-Porras et al., 2012; Sharma et al., 2013).Root xylem loading is a key step for the delivery of nutrients to the shoot (Poirier et al., 1991; Engels and Marschner, 1992a; Gaymard et al., 1998; Takano et al., 2002; Park et al., 2008). Root-to-shoot translocation of K⁺ is mediated by the voltage-dependent Shaker family K⁺ channel Stelar K⁺ Outward Rectifier (SKOR). The gene is primarily expressed in pericycle and root xylem parenchyma cells, and it is down-regulated upon K shortage and in response to treatments with the phytohormones abscisic acid, cytokinin, and auxin. Such gene expression changes are thought to control K⁺ secretion into the xylem sap and K⁺ reallocation through the phloem to adjust root K⁺ transport activity to K⁺ availability and shoot demand (Pilot et al., 2003). SKOR is activated upon membrane depolarization, and it is in a closed state when the driving force for K⁺ is inwardly directed. It elicits outward K⁺ currents, facilitating the release of the cation from the cells into the xylem. The voltage dependency of the channel is modulated by the external K⁺ concentration to minimize the risk of an undesired K⁺ influx under high K⁺ availability (Johansson et al., 2006). Root-to-shoot K⁺ transfer was strongly reduced in the knockout mutant skor-1, resulting in a decreased shoot K content, whereas the root K content remained unaffected (Gaymard et al., 1998).Root xylem loading is subject to the maintenance of a cation-anion balance, and nitrate (NO₃⁻) is the quantitatively most important anion counterbalancing xylem loading of K⁺ (Engels and Marschner, 1993). Members of the Nitrate Transporter1 (NRT1)/Peptide Transporter (PTR) transporter family (NPF) play a prominent role in NO₃⁻ uptake and allocation in Arabidopsis (summarized in Krouk et al., 2010; Wang et al., 2012; and Léran et al., 2014). Two of them have recently been reported to control xylem NO₃⁻ loading and unloading. The low-affinity, pH-dependent bidirectional NO₃⁻ transporter NPF7.3/NRT1.5 (subsequently termed NRT1.5) mediates NO₃⁻ efflux from pericycle cells to the xylem vessels, whereas the low-affinity influx protein NPF7.2/NRT1.8 removes NO₃⁻ from the xylem sap and transfers it into xylem parenchyma cells (Lin et al., 2008; Li et al., 2010; Chen et al., 2012). Accordingly, the expression of both genes is oppositely regulated under various stress conditions (Li et al., 2010). In nrt1.5 mutants, NRT1.8 expression is increased, which is thought to enhance NO₃⁻ reallocation to the root (Chen et al., 2012).The NRT1.5 gene is mainly expressed in root pericycle cells close to the xylem, and the protein localizes to the plasma membrane. In nrt1.5 mutants, less NO₃⁻ is transported from the root to the shoot, and the NO₃⁻ concentration in the xylem sap is reduced. However, root-to-shoot NO₃⁻ transport is not completely abolished in these mutants, indicating the existence of additional xylem-loading activities for NO₃⁻ (Lin et al., 2008; Wang et al., 2012). The recent observation that NPF6.3/NRT1.1/CHL1 and NPF6.2/NRT1.4 are also capable of mediating bidirectional NO₃⁻ transport in Xenopus laevis oocytes might indicate that more NPF family members are contributing to xylem loading with NO₃⁻ (Léran et al., 2013).Electrophysiological studies with NRT1.5-expressing X. laevis oocytes revealed that NO₃⁻ excited an inward current at pH 5.5, which would be expected for a proton-coupled nitrate transporter with a proton to nitrate ratio larger than one (Lin et al., 2008). The inward currents elicited by exposure to nitrate were pH dependent, and Lin et al. (2008) observed that NRT1.5 can also facilitate nitrate efflux when the oocytes were incubated at pH 7.4. Lin et al. (2008) concluded that NRT1.5 can transport nitrate in both directions, presumably through a proton-coupled mechanism. Interestingly, a K⁺ gradient was not sufficient to drive NRT1.5-mediated NO₃⁻ export. However, the determination of root and shoot cation concentrations in the nrt1.5-1 mutant revealed that the amount of K⁺ translocated to the shoot was reduced when NO₃⁻ but not NH₄⁺ was supplied as the N source. Therefore, Lin et al. (2008) suggested a regulatory loop between NO₃⁻ and K⁺ at the xylem loading step.A close relationship between these two nutrients concerning uptake, translocation, recycling, and reduction (of NO₃⁻) has been described in physiological studies since the 1960s (e.g. Ben Zioni et al., 1971; Blevins et al., 1978; Barneix and Breteler, 1985), but only recently, common components in the NO₃⁻ and K⁺ uptake pathways were identified and led to the first ideas of how such a cross talk might be coordinated on the molecular level. The uptake activity of the K⁺ channel AKT1 as well as the affinity of the NO₃⁻ transporter NPF6.3/NRT1.1/CHL1 are both modulated by the activity of CALCINEURIN B-LIKE PROTEIN-INTERACTING PROTEIN KINASE23 (CIPK23), which itself is regulated by CALCINEURIN B-LIKE PROTEIN9 (CBL9) under both deficiencies (Xu et al., 2006; Ho et al., 2009). Yet, the details of this interaction in root K⁺ uptake, the (regulation of) xylem loading with K⁺ and NO₃⁻, and the involvement of SKOR and NRT1.5 in this process are unknown.In this study, we approached this problem by investigating the molecular and physiological responses of Arabidopsis wild-type (Columbia-0 [Col-0]), nrt1.5, and skor transfer DNA (T-DNA) insertion lines to varying NO₃⁻ and K⁺ regimes. The nrt1.5 mutant developed an early senescence phenotype under low NO₃⁻ nutrition, which could be attributed to a reduced K⁺ translocation to the shoot. The assessment of nrt1.5 and skor single- and double-knockout lines disclosed an interplay of the two proteins in the NO₃⁻-dependent control of shoot K homeostasis. The presented data indicate that SKOR mediates K⁺ root-to-shoot translocation under high NO₃⁻ and low K⁺ availability, whereas NRT1.5 is important for K⁺ translocation under low NO₃⁻ availability, irrespective of the K⁺ supply.