Cell Competition, the Kinetics of Thymopoiesis, and Thymus Cellularity Are Regulated by Double-Negative 2 to 3 Early Thymocytes.

Cell competition in the thymus is a homeostatic process that drives turnover. If the process is impaired, thymopoiesis can be autonomously maintained for several weeks, but this causes leukemia. We aimed to understand the effect of cell competition on thymopoiesis, identify the cells involved, and determine how the process is regulated. Using thymus transplantation experiments, we found that cell competition occurs within the double-negative 2 (DN2) and 3 early (DN3e) thymocytes and inhibits thymus autonomy. Furthermore, the expansion of DN2b is regulated by a negative feedback loop that is imposed by double-positive thymocytes and determines the kinetics of thymopoiesis. This feedback loop affects the cell cycle duration of DN2b, in a response controlled by interleukin 7 availability. Altogether, we show that thymocytes do not merely follow a pre-determined path if provided with the correct signals. Instead, thymopoiesis dynamically integrates cell-autonomous and non-cell-autonomous aspects that fine-tune normal thymus function.

Stability of Protein Formulations at Subzero Temperatures by Isochoric Cooling.

Optimization of protein formulations at subzero temperatures is required for many applications such as storage, transport, and lyophilization. Using isochoric cooling (constant volume) is possible to reach subzero temperatures without freezing aqueous solutions. This accelerates protein damage as protein may unfold by cold denaturation and diffusional and conformational freedom is still present. The use of isochoric cooling to faster protein formulations was first demonstrated for the biomedical relevant protein disulfide isomerase A1. Three osmolytes, sucrose, glycerol, and l-arginine, significantly increased the stability of protein disulfide isomerase A1 at -20°C with all tested under isochoric cooling within the short time frame of 700 h. The redox green fluorescent protein 2 was used to evaluate the applicability of isochoric cooling for stability analysis of highly stable proteins. This derivative of GFP is 2.6-fold more stable than the highly stable GFP ß-barrel structure. Nevertheless, it was possible to denature a fraction of roGFP2 at -20°C and to assign a stabilizing effect to sucrose. Isochoric cooling was further applied to insulin. Protein damage was evaluated through a signaling event elicited on human hepatocyte carcinoma cells. Insulin at -20°C under isochoric cooling lost 22% of its function after 15 days and 0.6M sucrose prevented insulin deactivation.

T Cell Acute Lymphoblastic Leukemia as a Consequence of Thymus Autonomy.

Thymus autonomy is the capacity of the thymus to maintain T lymphocyte development and export independently of bone marrow contribution. Prolonging thymus autonomy was shown to be permissive to the development of T cell acute lymphoblastic leukemia (T-ALL), similar to the human disease. In this study, performing thymus transplantation experiments in mice, we report that thymus autonomy can occur in several experimental conditions, and all are permissive to T-ALL. We show that wild type thymi maintain their function of T lymphocyte production upon transplantation into recipients with several genotypes (and corresponding phenotypic differences), i.e., Rag2 - / - γc - / -, γc - / -, Rag2 - / - IL-7rα - / -, and IL-7rα - / - We found that the cellularity of the thymus grafts is influenced exclusively by the genotype of the host, i.e., IL-7rα-/- versus γc -/- Nonetheless, the difference in cellularity detected in thymus autonomy bore no impact on onset, incidence, immunophenotype, or pathologic condition of T-ALL. In all tested conditions, T-ALL reached an incidence of 80%, demonstrating that thymus autonomy bears a high risk of leukemia. We also analyzed the microbiota composition of the recipients and their genetic background, but none of the differences found influenced the development of T-ALL. Taken together, our data support that IL-7 drives cellular turnover non-cell autonomously, which is required for prevention of T-ALL. We found no influence for T-ALL in the specific combination of the genotypic mutations tested (including the developmental block caused by Rag deficiency), in microbiota composition, or minor differences in the genetic background of the strains.

HIV-1 Nef Impairs the Formation of Calcium Membrane Territories Controlling the Signaling Nanoarchitecture at the Immunological Synapse.

The ability of HIV-1 to replicate and to establish long-term reservoirs is strongly influenced by T cell activation. Through the use of membrane-tethered, genetically encoded calcium (Ca2+) indicators, we were able to detect for the first time, to our knowledge, the formation of Ca2+ territories and determine their role in coordinating the functional signaling nanostructure of the synaptic membrane. Consequently, we report a previously unknown immune subversion mechanism involving HIV-1 exploitation, through its Nef accessory protein, of the interconnectivity among three evolutionarily conserved cellular processes: vesicle traffic, signaling compartmentalization, and the second messenger Ca2+ We found that HIV-1 Nef specifically associates with the traffic regulators MAL and Rab11b compelling the vesicular accumulation of Lck. Through its association with MAL and Rab11b, Nef co-opts Lck switchlike function driving the formation Ca2+ membrane territories, which, in turn, control the fusion of LAT-transporting Rab27 and Rab37 vesicles and the formation of LAT nanoclusters at the immunological synapse. Consequently, HIV-1 Nef disengages TCR triggering from the generation of p-LAT and p-SLP nanoclusters driving TCR signal amplification and diversification. Altogether our results indicate that HIV-1 exploits the interconnectivity among vesicle traffic, Ca2+ membrane territories, and signaling nanoclusters to modulate T cell signaling and function.

FOXE1 polymorphisms are associated with familial and sporadic nonmedullary thyroid cancer susceptibility.

OBJECTIVE: FOXE1 is a transcription factor required for thyroid differentiation and function. FOXE1 locus polymorphisms (chromosome 9q22.33) were recently associated with increased sporadic thyroid cancer risk. In this study, we aimed to investigate the association of FOXE1 variants with nonmedullary thyroid cancer (NMTC), in both sporadic and familial (FNMTC) cases from the Portuguese population. DESIGN AND METHODS: Nine variants located at the FOXE1 locus were sequenced in genomic DNA from 60 FNMTC probands and 80 patients with sporadic NMTC. Alleles were tested for association with thyroid cancer, against 130 healthy matched Portuguese controls. RESULTS: All variants were significantly associated with increased thyroid cancer risk when combining familial and sporadic cases (OR range = 1·62-2·58). In particular, two reported risk variants were associated with the disease: rs965513 (allele A) with familial (OR = 2·30, 95% CI = 1·48-3·59, P = 0·0002) and sporadic (OR = 2·81, 95% CI = 1·87-4·22, P < 0·0001) NMTC and rs1867277 (allele A) with the sporadic (OR = 1·76, 95% CI = 1·18-2·62, P = 0·0052) and combined NMTC cases (OR = 1·70, 95% CI = 1·21-2·40, P = 0·0022). Interestingly, we also identified association of FOXE1 polyalanine tract expansions (>14 alanines) with thyroid cancer risk, in both familial (OR = 2·56, 95% CI = 1·64-4·01, P < 0·0001) and sporadic (OR = 2·44, 95% CI = 1·61-3·68, P < 0·0001) cases. CONCLUSIONS: We found compelling evidence of association between FOXE1 variants and thyroid cancer risk in the Portuguese population. To our knowledge, this is the first study supporting the association of this locus with both sporadic and familial NMTC susceptibility.

Survival and biofilm formation of Listeria monocytogenes in simulated vaginal fluid: influence of pH and strain origin.

Listeria monocytogenes, the agent responsible for listeriosis, can be transmitted from mother to fetus/neonates by vertical transmission, transplacentally or during passage through the birth canal. The purpose of this study was to investigate the survival and biofilm formation of L. monocytogenes (isolated from clinical cases or from food) in simulated vaginal fluid at different pH values (4.2, 5.5 and 6.5). The results demonstrated that this pathogen is inhibited by the normal vaginal pH, but may proliferate when it increases. Clinical strains were significantly more resistant to pH 4.2 than food isolates. Listeria monocytogenes survived and even grew at the higher pHs investigated, suggesting that fetus/neonates from women having increased vaginal pH values during pregnancy may be at a higher risk of listeriosis. All isolates tested were producers of biofilm at different pH values; however, L. monocytogenes produced higher quantities of biofilm in a nutrient-rich medium. No significant differences in biofilm production were detected between food and clinical isolates. As L. monocytogenes are biofilm producers, this increases the probability of occurrence of neonatal infection.

Application of an Impedimetric Technique for the Detection of Lytic Infection of Salmonella spp. by Specific Phages.

This study was performed to evaluate the adaption of the impedimetric method to detect the lytic infection by Salmonella-specific bacteriophages and to provide a higher selectivity to this rapid method in detecting Salmonella spp. by using specific agents. Three bacteriophages and twelve strains of Salmonella spp. were tested. Each of the twelve strains was used separately to inoculate TSB together with each one of the phages. The inoculum concentration was between 10(6) and 10(7) cfu/mL, at a cell: phage ratio of 1 : 100. From the sample analysis, based on conductance (G) measurements (37 degrees C), the infection could be detected, by observation of both detection-time delay and distinct curve trends. The main conclusions were that kinetic detection by impedance microbiology with phage typing constitutes a method of determining whether a test microorganism is sensitive to the bacteriophage and a method to evaluate whether a lytic bacteriophage is present in a sample, by affecting bacterial growth rate/metabolic change.