FAS/FASL Expression Profile as a Prognostic Marker in Squamous Cell Carcinoma of the Oral Cavity

FAS/FASL altered expression may cause tumor protecting immunomodulation, with a direct impact on patient prognosis. FAS expression was studied in 60 squamous cell carcinomas of the oral cavity. FAS expression did not show a significant association with tumor histopathological characteristics, but was significantly associated with lymph node positivity. FAS expression was significantly associated with disease specific death and negative FAS expression was an independent risk factor, increasing risk 4 times when compared to positive expression. When FAS and FASL expression results were combined, we were able to define high, intermediate and low risk profiles. Disease-free and disease-specific survival were significantly correlated with FAS/FASL expression profiles. The high risk category was an independent marker for earlier disease relapse and disease-specific death, with approximately 4- and 6-fold increased risk, respectively, when compared to the low risk profile. Risk profiles based on FAS/FASL expression showed that high risk was significantly associated with increased disease relapse and death, as well as shorter disease-free or disease-specific survival. This categorization, added to patient clinical data, may facilitate the choice of therapy, minimizing treatment failure and increasing disease control.     

Topographical analysis of Schizolobium parahyba chymotrypsin inhibitor (SPCI) by atomic force microscopy

Atomic Force Microscopy (AFM) has been a useful tool for molecular surface analysis and to estimate topographical properties of proteins. Here we report a topographical study of a chymotrypsin inhibitor from Schizolobium parahyba seeds (SPCI) by AFM. The underlying structure of SPCI oligomers has been resolved in nanometer order resolution. SPCI oligomerize in hexagonal, ellipsoid, comet, pyramidal, and "Z" shaped. The hexagonal was the most observed oligomer shape.     

Weight–length relationships for 54 species of the Arade estuary, southern Portugal

Weight–length relationships (WLRs) are presented for 54 species sampled by several types of fishing gear between February 2004 and May 2007, in the Arade estuary (southern Portugal). WLRs for six species are presented for the first time.     

Leukocyte transepithelial migration in lung induced by DMSA functionalized magnetic nanoparticles

Magnetic nanoparticles surface-covered with meso-2,3-dimercaptosuccinic acid (MNPs-DMSA) constitute a promising approach for tissue- and cell-targeted delivery of therapeutic drugs in the lung. However, they can also induce a transient transendothelial migration of leukocytes in the organ as a side effect after endovenous administration of MNPs-DMSA. We demonstrated that monocytes/macrophages constitute the main subpopulation of leukocytes involved in this process. Our recent research found that MNPs-DMSA upregulated the mRNA expression of E-, L- and P-selectin and macrophage-1 antigen and increased concentration of tumor necrosis factor α (TNFα) in lung, in a time dependent manner. The critical relevance of the β₂ integrin-dependent pathway in leukocyte transmigration elicited by MNPs-DMSA was demonstrated by use of knockout mice. Our work characterizes mechanisms of the pro-inflammatory effects of MNPs-DMSA in the lung and identifies β₂ integrin-targeted interventions as promising strategies to reduce pulmonary side effects of MNPs-DMSA during biomedical applications. In addition, MNPs-DMSA could be used as modulators of lung immune response.Key words: magnetic nanoparticles, DMSA, nanobiotechnology, transepithelial migration, cell adhesion molecules, integrins, monocytes, lungNanotechnology deals with structures of 100 nm or smaller in at least one dimension and has the potential to create many new materials and devices with a vast range of applications. Materials can be produced that are nanoscale in one dimension (for example, very thin surface coatings), in two dimensions (for example, nanowires and nanotubes) or in all three dimensions (for example, nanoparticles).Magnetic nanoparticles (MNPs) are a class of nanoparticles that can be manipulated using a magnetic field. MNPs are traditionally ferrite-based materials with the general formula MFe₂O₄, where M is a doubly charged metal-ion, such as iron, nickel or cobalt. Magnetic fluids (MFs) are colloidal mixtures composed of MNPs suspended in a carrier fluid, usually an organic or inorganic solvent. There is an increasing interest in developing biocompatible MFs for biomedical applications¹ for instance, for detection of circulating tumor cells,² contrast agents for magnetic resonance imaging³ and in an experimental cancer treatment called magnetic hyperthermia in which the fact that nanoparticles heat when they are placed in an alternative magnetic field is used.⁴ Another potential use includes attaching magnetic nanoparticles to drug/gene for targeting purposes.⁵ In order to be used for medical applications, magnetic nanoparticles are coated with a surfactant to prevent their agglomeration (due to van der Waals and magnetic forces) and allow the association of MNPs surface with different molecules.^6,7In previous studies, we have shown that MNPs surface-coated with meso-2,3-dimercaptosuccinic acid (MNPs-DMSA) (Fig. 1), with average diameter of about 9 nm, presented preferential distribution in the lung tissue, after intravenous administration in mice.^8–10 This target specificity of MNPs-DMSA offers a unique property that may be successfully exploited for the treatment of lung diseases.¹¹ In addition, we reported that the presence of MNPs-DMSA in the lung led to trafficking of leukocytes from blood vessels into pulmonary parenchyma and airspace and that interleukin-1 (IL-1) and interleukin-6 (IL-6) were overexpressed.¹² IL-1 acts as a trigger that activates a cascade of cytokine production and induces the production of a wide range of immunomodulatory cytokines.¹³ IL-6 is among the mediators regulated by IL-1 and is often increased in inflammatory processes in the lung.¹³ These differential expressions were particularly associated with blood vessels and cells of airway ducts suggesting that they could have some role during the recruitment process of inflammatory cells, as observed in histological analyses. In fact, these cytokines are commonly associated with the activation of cells concerning the expression of adhesion surface proteins.¹³ This is in agreement with several studies that described the requirement of IL-1α production in rat airways for full polymorphonuclear cell migration in models for immune-complex deposition or inhalation of cement dust, coal dust or diesel exhaust particles.^14–16Open in a separate windowFigure 1Schematic representation of DMSA-functionalized maghemite nanoparticles.Cell migration plays a key role in a wide variety of biological phenomena. This process is particularly important for leukocyte function and the inflammatory response. A mechanistic understanding of cellular interactions with synthetic surfaces, particularly in the context of inflammatory and healing responses, has been a major goal of biomaterial science.Leukocyte trafficking in the lung involves transendothelial migration, migration in tissue interstitium and transepithelial migration. In addition, leukocyte emigration involves regulatory mechanisms including complement activation, cytokine regulation, chemokine production, activation of adhesion molecules and their respective counter receptors. The process is presumably initiated and modulated by the production of early response cytokines such as IL-1 and tumor necrosis factor (TNF) from lung cells, especially from alveolar macrophages, setting the stage for leukocyte migration through endothelium.¹⁷ On the other hand, ensuing production of interleukin-10 (IL-10) brings into play powerful anti-inflammatory factors that strongly regulate inflammatory responses, functioning as intrinsic regulators of the lung inflammatory response.^18,19Tissue infiltration by circulating leukocytes is a three-step process involving rolling on the endothelium, attachment to the endothelium and transmigration across the endothelial cells lining blood vessel walls (Fig. 2). Leukocyte migration out of the blood is initiated by leukocyte rolling on the luminal side of the endothelium, as mediated by the low-affinity receptors selectins (E-, L- and P-selectin).^20–22 Binding of selectins on leukocytes stimulates “outside-in” signals in these cells, increasing the affinity of the integrin family of receptors (cell surface receptors consisting of an α- and a β-subunit, which are grouped in distinct subfamilies based on β-subunit utilization), which then bind to endothelial cell adhesion molecules such as intercellular adhesion molecule-1 [(ICAM-1)/CD54] and vascular cellular adhesion molecule-1 (VCAM-1). Function-blocking studies have identified the β₁ (CD29) and β₂ (CD18) integrins as the major players involved in leukocyte adhesion and migration.²³ Leukocyte integrin affinity is also rapidly increased by “inside-out” signals from leukocyte chemokine receptors triggered by chemokines displayed on the surface of endothelial cells.²⁴ With an increase in leukocyte integrin receptor affinity, leukocyte rolling is arrested.²⁴Open in a separate windowFigure 2Schematic representation of leukocyte endothelial migration into lung parenchyma.Using immunohistochemistry, we demonstrated that following injection of MF-DMSA, the distribution pattern of E-selectin and members of the β₂ integrin subfamily (macrophage-1 antigen, Mac-1; leukocyte function associated antigen-1, LFA-1) was changed in the lung vessels, but not of β₁ integrin.¹⁰ For L and P selectins no differences were observed between treated and control animals. However, for E-selectin, labeling was found in the endothelium of veins and venules 12 h after MF-DMSA administration, but not in the lung''s vascular compartments of the control and 4 h treatment groups.¹² Concerning integrins, in the control group, leukocytes labeled with Mac-1 and LFA-1 were found only in post-capillary sites. Four hours after MF-DMSA administration, leukocytes expressing these β₂ integrins were also found in capillaries.¹⁰ Our findings expand on other studies showing that the capillary network constitutes an important migration site in the lung.²⁵ Thus, the modulation of Mac-1 and LFA-1 expression in leukocytes located inside capillaries supports the importance of these integrins and capillaries for migratory activity in the lung, in this case after MF-DMSA administration. However, we cannot discard the participation of larger vessels in the migration induced by MNPs-DMSA. In fact, some images from our laboratory have showed that this is also a route used by the leukocytes after injection of these nanoparticles (Fig. 3).Open in a separate windowFigure 3Light microscopy image of leukocytes containing MNPs-DMSA inside a vein. Note that the cells (yellow arrows) are close or attached to the endothelium.It is worth noting that 12 h after MF-DMSA administration, leukocytes labeled with LFA-1 were observed only in post-capillary sites, similar to the control. We speculated that the absence of LFA-1 labeling in capillaries in the period of 12 h after MF-DMSA administration is due to the accentuated decrease of LFA-1 expression levels in the leukocyte over the course of time. In fact, as will be discussed below, we obtained a decrease in the LFA-1 mRNA 12 h after MNPs-DMSA administration. This point of view is in agreement with other studies that demonstrated the distinct contribution of LFA-1 and Mac-1 to transendothelial migration in the lung.²⁶ While both Mac-1 and LFA-1 participate in transendothelial migration at the beginning of the inflammatory process, over time Mac-1 becomes the predominant member of the β₂ integrin subfamily mediating migration of leukocytes.²⁶These results raised several questions related to MNPs-DMSA administration, such as: what is the time profile of leukocyte migration into the airspace? Which is the principal leukocyte subpopulation involved in this process? Is it a fact that the mechanism by which the presence of MNPs-DMSA induces transendothelial migration of leukocytes into the lung is based on their ability to somehow change the expression of cell adhesion molecules on leukocytes and lung vascular endothelial cells? Is β₂ or β₁ integrin, or both, the main receptor involved in MNPs-DMSA leukocyte-induced migration?Recently, we uncovered some of these answers including the main adhesion molecules that are involved in this migration. We first determined that the number of leukocytes in the bronchoalveolar lavage fluid reached its peak 12 h after MNPs-DMSA administration, decreasing to normal values in 48–72 h. Cytologic and FACS analysis demonstrated that the main subpopulation of leukocytes involved in this process was monocyte/macrophage.²⁷It is well known that the reticuloendothelial system, in particular macrophage cells, actively neutralizes and eliminates foreign matter from the body, including nonbiological particles. These and other particulated materials in the lung may lead to lung damage. In fact, transmission electron microscopy analysis clearly demonstrated an uptake of MNPs-DMSA by monocyte/macrophage cells,²⁷ indicating that this may be a mechanism of nanoparticle clearance used by the lung in order to avoid further damage. It is worth noting that an increase in the relative percentage of lymphocytes after MNPs-DMSA administration was also observed. The importance of this finding was not addressed in the paper, but we speculate that it could be important for the control of the inflammatory process initiated by the MNPs-DMSA injection. Failure in control of the inflammatory processes could potentially lead to chronic inflammatory diseases and pulmonary fibrosis. In spite of the fact that we did not determine which was the main source of the production of two different cytokines, one considered pro-inflammatory (TNFα) and the other anti-inflammatory (IL-10), we found an increase in the ratio of IL-10/TNFα cytokine release 12 h after MNPs-DMSA administration. This is clearly a signal that the inflammatory process was being controlled, in agreement with previous reports showing that IL-10 is able to limit the induction of cell adhesion molecules in the lung.²⁸ We presume that lymphocytes are taking part in this process. Further studies are necessary to clarify this point.The nature of the cells present in the pulmonary tissue parenchyma was not determined in this study. However, these cells were not able to cause tissue damage in the lung. We observed no histological or ultrastructural damage in the lung of animals treated with MNPs-DMSA, indicating that the nanoparticle-induced inflammation is not enough to cause chronic disease, such as pulmonary fibrosis.We then determined the effect of MNPs-DMSA on mRNA expression of selectins, integrin β₁ and integrin β₂.²⁷ We found that MNPs-DMSA upregulated the mRNA expression of E-, L- and P-selectin, as well as Mac-1. Further, using knockout mice (deficient in the β₂-subunit common to all β₂ integrins), we observed that, compared to wild-type mice, the recruitment of leukocytes to the airspace following administration of MNPs-DMSA was completely blocked in the former.²⁷ The fact that transmigration of β₂ integrin-deficient monocytes was affected when compared with wild-type monocytes strongly argues in favor of a major contribution by β₂ integrins to monocyte trans-epithelial migration in our system, which is additionally supported by the increase of mRNA of β₂ integrins, as cited above.We should remember, however, that the absence of change in LFA-1 and very late antigen-4 (VLA-4) mRNA does not exclude a role for them in leukocyte migration induced by MNPs-DMSA. Integrins are cell adhesion molecules constitutively expressed on the cell surface and also stored within intracellular vesicles.^29,30 In addition, transendothelial migration of leukocytes depends not only on the number of integrins on the cell surface but also on the change in conformation of these molecules reflecting their activation.³² Therefore, our results did not exclude the possibility that MNPs-DMSA induce the activation of LFA-1 and VLA-4 constitutively located on the surface of leukocytes or the translocation of these integrins from intracellular vesicles to the plasma membrane. On the other hand, the absence of a significant change in the mRNA expression of VCAM-1, which is the major endothelial cell ligand for VLA-4, can be regarded as an indirect indicator that VLA-4 is not involved in this process.The fact that an increase in the mRNA of Mac-1 occurred and there is no change in the mRNA levels of VLA-4 (and LFA-1) corroborates the hypothesis that migration of leukocytes induced by MNPs-DMSA is mainly dependent on β₂ integrins and not β₁ integrins pathway. In addition, we can presume that MAC-1 is the main β₂ integrin molecule involved in the process of leukocyte trafficking.The increased use of nanoparticles in medicine has raised concerns on their ability to gain access to privileged sites in the body. In fact, a study has shown that, in some cases, they can potentially cause damage to tissues located behind cellular barriers. Therefore, it is fundamental to understand the mechanisms underlying interactions between nanoparticles and the body, for their safe and effective use. In the case of MNPs-DMSA, we can use this knowledge for treatment of lung diseases when associated with drugs, as well as for downregulation or upregulation of the local immune system.One important question still unanswered about the use of magnetic nanoparticles in lung disease treatments is what could be expected if more than one dose is necessary in a short period of time. Recent research of Mejias et al.³¹ was close to answer this question. In their study the authors injected repeated doses (nine in total) of magnetic nanoparticles stabilized with DMSA, but unfortunately, they did not analyze the lungs, assuming that the particles would be stocked in the liver, spleen and kidney. For these organs, however, the authors did not refer to any observed damage. We believe that the answer to this question is related with several factors such as physical-chemical features of the nanoparticles (size, hydrodynamic radius, etc.) interval between the injections, amount of iron injected, among others. These features are also important for a second open question: what happens if the organ has a preexistent disease? Further studies are necessary to clarify this point. It is important to minimize, in all cases, the amount of injected iron, increasing, when possible, the amount of drug attached to the nanoparticles. The use of magnetic nanoparticles is already a reality as a contrast agent. It is possible that in the future they also can be used as drug delivery carriers.In resume our work characterizes mechanisms of the pro-inflammatory effects of MNPs-DMSA in the lung and identifies β₂ integrin-targeted interventions as promising strategies to reduce pulmonary side effects of MNPs-DMSA during biomedical applications. In addition, MNPs-DMSA could be used as modulators of lung immune response.     

Tri-allelic pattern at the TPOX locus: A familial study

Alleles at the TPOX STR locus have 6–14 different numbers of a four-nucleotide (AATG) repeat motif arranged in tandem. Although tri-allelic genotypes are generally rare, the TPOX tri-allelic pattern has a higher frequency, varying widely among populations. Despite this, there are few accurate reports to disclose the nature of the TPOX third allele. In this work we present data obtained from 45 individuals belonging to the same pedigree, in which there are cases of tri-allelic TPOX genotypes. The subjects were apparently healthy with a normal biological development. We noticed six tri-allelic cases in this family, and all of them were women. Karyotype analysis showed no occurrence of partial 2p trisomy. All the tri-allelic cases had the genotype 8–10–11, probably due to three copies of the TPOX STR sequence in all cells (Type 2 tri-allelic pattern). Based on previous data we assumed the allele 10 as the TPOX third allele. The pedigree analyses show evidences that the TPOX extra-allele was the allele10, it is placed far from the main TPOX locus, and that there is a potential linkage of the TPOX extra-allele-10 with Xq. This was the first study that included a large pedigree analysis in order to understand the nature TPOX tri-allelic pattern.     

Higher frequency of septic shock in septic patients with the 47C allele (rs4880) of the SOD2 gene

Aim

To analyze the effect of the two different versions of the manganese superoxide dismutase gene (SOD2) on sepsis. The SOD2 gene presents the 47C > T single nucleotide polymorphism (SNP; ID: rs4880) which produces MnSOD with different activities. The − 9Val MnSOD (47T allele) is less efficient than the − 9Ala version (47C allele). During sepsis there are abundance of ROS, high SOD2 expression and excess of H₂O₂ synthesis. High concentrations of H₂O₂ could affect the sepsis scenario and/or the sepsis outcome.

Methods

We determined the 47C > T single nucleotide polymorphism (SNP) frequencies in 529 critically ill patients with or without sepsis, facing outcome. To collect information on population frequencies, we obtained a pilot 47C > T genotypic and allelic frequencies in a random group of 139 healthy subjects.

Results

We compared the 47C allele carriers (47CC + 47CT genotypes) with 47TT homozygotes and noticed a significant association between 47C allele carriers and septic shock in septic patients (P = 0.025). With an adjusted binary multivariate logistic regression, incorporating 47C > T SNP and the main clinical predictors, we showed high SOFA scores [P < 0.001, OR = 9.107 (95% CI = 5.319–15.592)] and 47C allele [P = 0.011, OR = 2.125 (95% CI = 1.190–3.794)] were significantly associated with septic shock outcome. With this information we presented a hypothesis suggesting that this negative outcome from sepsis is possibly explained by effects on cellular stress caused by 47C allele.

Conclusion

In our population there was a significant higher frequency of septic shock in septic patients with the 47C allele of the SOD2 gene. This higher 47C allele frequency in septic patients with negative outcome could be explained by effects of higher activity MnSOD on cellular stress during the sepsis.     

Morphological Analysis of Reticuloendothelial System in Capuchin Monkeys (Sapajus spp.) after Meso-2,3-Dimercaptosuccinic Acid (DMSA) Coated Magnetic Nanoparticles Administration

Magnetic nanoparticles can be used for numerous in vitro and in vivo applications. However, since uptake by the reticuloendothelial system represents an obstacle for the achievement of nanoparticle diagnostic and therapeutic goals, the aim of the present study was to evaluate the uptake of dimercaptosuccinic acid coated magnetic nanoparticles by reticuloendothelial system phagocytic cells present in lymph nodes, spleen, and liver tissue and how the presence of these particles could have an impact on the morphology of these organs in capuchin monkeys (Sapajus spp.). Animals were intravenously injected with dimercaptosuccinic acid coated magnetic nanoparticles and euthanized 12 hours and 90 days post-injection. Organs were processed by transmission electron microscopy and histological techniques. Samples of spleen and lymph nodes showed no morphological changes. Nevertheless, liver samples collected 90 days post-administration showed slight morphological alteration in space of Disse. Moreover, morphometrical analysis of hepatic mitochondria was performed, suggesting a clear positive correlation between mitochondrial area and dimercaptosuccinic acid coated magnetic nanoparticles administration time. The present results are directly relevant to current safety considerations in clinical diagnostic and therapeutic uses of magnetic nanoparticles.     

By-catch and discarding practices in five Algarve (southern Portugal) métiers

The catches and discards of trawlers, seiners and trammel netters were studied in the Algarve (southern Portugal) using observers onboard commercial fishing vessels. Species diversity was high, with 236 species recorded as occasionally, frequently or regularly discarded. Mean discard rates per trip were 0.13, 0.20, 0.27, 0.62 and 0.70, respectively, for trammel nets, demersal purse seines, pelagic purse seines, fish trawls and crustacean trawls, with high variability in terms of discard volume and discard rate. This was especially so for seiners where from 0 to 100% of the total catch might be discarded. No significant relationships were found between discard quantity or discard rate and characteristics of the fishing vessels sampled within each métier (total length, TAB, hp, kW). Based on the above discard rates and the official landings, it was estimated that in 1996, Algarve trawlers discarded 9000–13000 tonnes (t) while seiners discarded 5500–8200 t. Discarding practices in these fisheries are reviewed and the reasons for discarding are presented by species and métier basis. The results support the need for more studies on the factors contributing to discarding, variability in discard quantities and rates, the fate of discards and their importance to the marine ecosystem, and on ways of reducing by-catch and discarding in these fisheries.