Participação dos neutrófilos durante a implantação embrionária no desenvolvimento da placenta em camundongos / Participation of neutrophils during embryonic implantation in the placental development in mice

A implantação do embrião na parede uterina é um processo complexo que consiste na interação do blastocisto com as células epiteliais do útero, e depende de diferentes tipos celulares do microambiente uterino. Embora a literatura mostre a participação de neutrófilos neste processo, os dados ainda são incipientes para proposição da função exata destas células nos períodos iniciais da gestação. Dados do nosso grupo de pesquisa mostraram que neutrófilos pró-angiogênicos induzem a tolerância gestacional, e que a depleção de neutrófilos durante as fases iniciais da gestação prejudica a implantação do blastocisto e a progressão da gestação. Com base nestes resultados, o presente estudo visou investigar se a depleção de neutrófilos na fase pré-receptiva da janela de implantação do blastocisto altera a morfologia placentária. Para tanto, foi utilizado o modelo de gestação alogênica, onde camundongos fêmeas C57BL/6, após cruzamento com machos Balb/C foram tratadas com anticorpo anti-Ly6G ou isotipo no dia 1,5 da gestação (24 horas após a detecção do plug vaginal) em dose suficiente para manter a depleção de neutrófilos circulantes por 48 horas (200µg/ 500µL; i.p). No final da gestação (dia 18,5), o sangue periférico foi coletado e, em seguida, os animais foram submetidos a laparotomia para retirada da placenta, a qual foi submetida à análise histológica. As análises dos leucócitos circulantes evidenciaram a efetividade do tratamento para depleção de neutrófilos periféricos. A análise histológica mostrou alterações significativas na morfologia da placenta nos animais tratados com anti-Ly6G. Foram detectadas a redução da zona juncional, de células trofoblásticas e de fatores angiogênicos, como fator de crescimento do endotélio vascular (VEGF), e das moléculas de adesão intracelular-1 (ICAM-1) e de plaqueta e endotélio (PECAM-1). Esses dados evidenciam a importância dos neutrófilos nos primeiros dias de gestação para o desenvolvimento da placenta

Blastocyst implantation is a complex process, consisting of the interaction between blastocyst and uterine epithelial cells. Also, it is well known that the implantation site resembles an inflammatory response, with a profusion of recruited immune cells into the endometrial stroma and lumen from the blood. The role of macrophages, natural killers, and dendritic cells have been extensively studied, however, the participation of neutrophils in this process remains unclear. Data from our research group showed that pro-angiogenic neutrophils induced gestation tolerance, also peripheral neutrophils depletion at the time of active placental development led to smaller embryo sizes and abnormal placentation in mice. In this context, the present study aimed to investigate whether pharmacological depletion of neutrophils in mice in the blastocyst implantation phase alters placental morphology. Therefore, C7/BL/6 female mice, after mating with Balb/C males, were treated with an anti-Ly6G antibody or isotype on day 1 of gestation (after detection of the vaginal plug) at a dose sufficient to maintain the depletion of circulating neutrophils for 48 hours (200 µg/500µL; i.p). At the end of the gestational day (day 18), peripheral blood was collected, and then the animals were submitted to laparotomy for the placenta removal and subsequent histological analysis. The analysis of circulating leukocytes from neutrophils depleted mice showed a reduction of peripheral neutrophils up to 48 hours after antibody injection. The histological analysis showed significant alterations in the placenta morphology of the animals treated with anti-Ly6G. The morphometric analyses showed a reduction in the size of neutrophils depleted placenta due to diminished junctional zone and reduction of trophoblast cells. Also, it was observed a reduction of vascular endothelial growth factors (VEGF), reduction of adhesion molecules intracell-1 (ICAM-1), and platelets and endothelium (PECAM-1) positive cells in the junctional zone. In conclusion, these data show the importance of neutrophils on the first days of pregnancy for the development of the placenta

CD31 Mimetic Coating Enhances Flow Diverting Stent Integration into the Arterial Wall Promoting Aneurysm Healing.

BACKGROUND AND PURPOSE: Beyond aneurysmal occlusion, metallic flow diverters (FDs) can induce an adverse endovascular reaction due to the foreignness of metal devices, hampering FD endothelialization across the aneurysm neck, and arterial healing of intracranial aneurysms. Here, we evaluated the potential benefits of an FD coating mimicking CD31, a coreceptor critically involved in endothelial function and endovascular homeostasis, on the endothelialization of FDs implanted in vivo. METHODS: Nitinol FD (Silk Vista Baby) and flat disks were dip-coated with a CD31-mimetic peptide via an intermediate layer of polydopamine. Disks were used to assess the reaction of endothelial cells and blood elements in vitro. An aneurysm rabbit model was used to compare in vivo effects on the arterial wall of CD31-mimetic-coated (CD31-mimetic, n=6), polydopamine-coated (polydopamine, n=6), and uncoated FDs (bare, n=5) at 4 weeks post-FD implantation. In addition, long-term safety was assessed at 12 weeks. RESULTS: In vitro, CD31-mimetic coated disks displayed reduced adhesion of blood elements while favoring endothelial cell attachment and confluence, compared to bare and polydopamine disks. Strikingly, in vivo, the neoarterial wall formed over the CD31-mimetic-FD struts at the aneurysm neck was characteristic of an arterial tunica media, with continuous differentiated endothelium covering a significantly thicker layer of collagen and smooth muscle cells as compared to the controls. The rates of angiographic complete occlusion and covered branch arterial patency were similar in all 3 groups. CONCLUSIONS: CD31-mimetic coating favors the colonization of metallic endovascular devices with endothelial cells displaying a physiological phenotype while preventing the adhesion of platelets and leukocytes. These biological properties lead to a rapid and improved endothelialization of the neoarterial wall at the aneurysm neck. CD31-mimetic coating could therefore represent a valuable strategy for FD biocompatibility improvement and aneurysm healing.

Changes in plasma gelsolin concentration during acute oxidant lung injury in mice.

Oxidant stress may contribute to acute lung injury under some circumstances. The rapid depletion of plasma gelsolin following major trauma in patients who subsequently develop respiratory distress suggests that this actin-scavenging protein might protect against delayed pulmonary complications. The specific aim of these experiments was to explore the temporal and quantitative relationship between gelsolin levels and lung damage. Gelsolin levels were measured in three murine models of oxidant injury: immunotargeting of pulmonary endothelium with an H2O2-generating enzyme; continuous exposure to >95% O2; and single high-dose thoracic radiation. The degree of lung injury was inversely related to gelsolin levels in mice treated with glucose oxidase-conjugated antibodies against platelet endothelial cell adhesion molecule-1 (p <0.0001). By 60-72 hours of hyperoxic exposure, gelsolin levels had dropped precipitously in all mice who sustained major lung damage (p <0.0001), establishing a quantitative association between gelsolin concentration and hyperoxic lung injury (r = -0.72; 95% confidence interval: ?0.81 to ?0.59). Gelsolin levels modestly but progressively fell in irradiated mice over the 3 days following treatment (p = 0.012) despite the development of only microscopic lung damage during this timeframe. These findings are consistent with the hypothesis that gelsolin depletion is involved in the pathogenesis of acute oxidant lung injury.

The significance of adhesion molecules in nephrology.

Our knowledge of adhesion molecules has exploded over the last 5 years and has swamped most fields of medicine including nephrology. This is not surprising because adhesion molecules play a pivotal role in all aspects of cell to cell contact. Thus, they are involved in important issues, such as fetal development, in any kind of inflammatory or immune response including allograft rejection, as well as thrombus formation, and in tumor growth and metastasis (1-3). This short overview briefly reports some aspects of the biology of relevant adhesion molecules and their significance in inflammatory kidney diseases and in hemodialysis and renal allograft rejection. Finally, new therapeutic opportunities that arise by blocking adhesion molecule function are discussed.