Gating strategy for plasmablast enumeration after hepatitis B vaccination

B cell stimulation develops upon vaccination, thus causing occurrence of activated B cells (plasmoblasts) in bloodstream. Similar cells are also observed in some viral infections. The contents of plasmablasts may be a marker of successful vaccination, or a diagnostic feature of ongoing infection. The plasmablasts are normally represented by a small cell subpopulation which is not easy to detect. A study was performed with 15 healthy volunteers who were subjected to a single immunization with a recombinant vaccine against hepatitis B virus. To identify the plasmablasts, we have used labeled antibodies prepared in our laboratory. These reagents were previously validated for counting the plasmablasts. Different gating strategies for plasmablast gating have been compared. Upon staining of lymphocytes from immunized volunteers, we observed a distinct cluster of plasmablasts with CD27++CD38++ phenotype using the following antibody set: CD19-PE, CD3/CD14/CD16-FITC, CD27-PC5.5 and CD38-PC7. Inclusion of a CD20-FITC antibody into the panel caused an increase of CD27++CD38++ plasmablast ratio among CD19+ lymphocytes to > 60%. Upon substitution of CD38 antibody by anti-CD71, a distinct plasmablast cluster was again revealed, which contained ca. 5 per cent В cells. Two strategies for the plasmablast gating using the CD27/ CD38 and CD27/CD71 combinations were compared in dynamics with lymphocyte samples from a single vaccinated volunteer. When applying the CD27/CD38 combination, a sharp and pronounced plasmablast peak was registered on day 7 post-vaccination. With CD27/CD71 combination, the peak was extended between day 7 and day 14 following immunization. Hence, time kinetics of the CD27+CD71+ population proved to be different from occurrence of classic plasmablasts with CD27++CD38++ phenotype. This finding suggests that the CD27++CD71+population contains both plasmablasts and other types of activated B cells. A minor HBV surface antigen was prepared and labeled with phycoerythrin (HBsAg-PE), thus allowing to quantify the antigen-specific plasmablasts. The results of HBsAg-PE-based detection of antigen-specific cells were in compliance with the data obtained by ELISpot technique. At the present time, we use the original plasmablast gating technique for detection of activated B cells in SARS-CoV-2 infection. At the next step, this technique will be applied to sorting of antigen-specific B cells, thus permitting sequencing of Ig genes and design of novel human antibodies against viral antigens.B cell stimulation develops upon vaccination, thus causing occurrence of activated B cells (plasmoblasts) in bloodstream. Similar cells are also observed in some viral infections. The contents of plasmablasts may be a marker of successful vaccination, or a diagnostic feature of ongoing infection. The plasmablasts are normally represented by a small cell subpopulation which is not easy to detect. A study was performed with 15 healthy volunteers who were subjected to a single immunization with a recombinant vaccine against hepatitis B virus. To identify the plasmablasts, we have used labeled antibodies prepared in our laboratory. These reagents were previously validated for counting the plasmablasts. Different gating strategies for plasmablast gating have been compared. Upon staining of lymphocytes from immunized volunteers, we observed a distinct cluster of plasmablasts with CD27++CD38++ phenotype using the following antibody set: CD19-PE, CD3/CD14/CD16-FITC, CD27-PC5.5 and CD38-PC7. Inclusion of a CD20-FITC antibody into the panel caused an increase of CD27++CD38++ plasmablast ratio among CD19+ lymphocytes to > 60%. Upon substitution of CD38 antibody by anti-CD71, a distinct plasmablast cluster was again revealed, which contained ca. 5 per cent В cells. Two strategies for the plasmablast gating using the CD27/ CD38 and CD27/CD71 combinations were compared in dynamics with lymphocyte samples from a single vaccinated volunteer. When applying the CD27/CD38 combination, a sharp and pronounced plasmablast peak was registered on day 7 post-vaccination. With CD27/CD71 combination, the peak was extended between day 7 and day 14 following immunization. Hence, time kinetics of the CD27+CD71+ population proved to be different from occurrence of classic plasmablasts with CD27++CD38++ phenotype. This finding suggests that the CD27++CD71+ population contains both plasmablasts and other types of activated B cells. A minor HBV surface antigen was prepared and labeled with phycoerythrin (HBsAg-PE), thus allowing to quantify the antigen-specific plasmablasts. The results of HBsAg-PE-based detection of antigen-specific cells were in compliance with the data obtained by ELISpot technique. At the present time, we use the original plasmablast gating technique for detection of activated B cells in SARS-CoV-2 infection. At the next step, this technique will be applied to sorting of antigen-specific B cells, thus permitting sequencing of Ig genes and design of novel human antibodies against viral antigens

Crystal growth and spectroscopic characterization of Yb:YMgB5O10

A transparent Yb:YMgB5O10 single crystal with dimensions up to 25×23×25 mm was grown. Absorption cross-section spectra were produced. The luminescence spectra of the Yb: YMgB5O10 crystal were measured in the spectral range of 950–1100 nm. The luminescence kinetics of the 2F5/2 energy level were investigated and the lifetime was determined

Two‑Dimensional Copper Coordination Polymer Assembled with Fumarate and 5,5’‑Dimethyl‑2,2’‑bipyridine: Synthesis, Crystal Structure and Magnetic Properties

[[Cu(fum)(dmb)]·H2O]n, exhibiting weak antiferromagnetic interactions, displays a two-dimensional array comprised of rhombic dinuclear units, where the carboxylate moieties of fumarate bridging ligand displays monodentate and oxo-bridging coordination modes connecting two Cu centers.[[Cu(fum)(dmb)]·H2O]n (1) (fum = fumarate; dmb = 5,5’-dimethyl-2,2’-bipyridine) was obtained by a self-assembly solution reaction, at ambient conditions, and characterized by elemental analysis, IR spectroscopy and X-ray single crystal diffraction. Crystallographic studies show that 1 crystallizes in a triclinic system with a P-1 space group, with a = 8.2308(2) Å, b = 9.7563(2) Å, c = 10.3990(2) Å; α = 80.3444(4)°, β = 77.9517(4)°, γ = 82.0440(5)°; V = 800.45(3) Å3. The Cu(II) centers are five-coordinated with a distorted square pyramidal configuration. The formation of a two-dimensional (2D) array in 1 can be explained by the presence of two different coordination modes in the fumarate ligand: μ-η1:η0 and μ2-η2:η0, both in a bridging monodentate manner, the latter generating distinctive rhombic-dinuclear units. The thermal stability of 1 has also been analyzed. Magnetic measurements revealed that this polymer exhibits weak antiferromagnetic ordering.Universidad Autonoma del Estado de México Universidad Nacional Autónoma de Méxic

Finishing the euchromatic sequence of the human genome

The sequence of the human genome encodes the genetic instructions for human physiology, as well as rich information about human evolution. In 2001, the International Human Genome Sequencing Consortium reported a draft sequence of the euchromatic portion of the human genome. Since then, the international collaboration has worked to convert this draft into a genome sequence with high accuracy and nearly complete coverage. Here, we report the result of this finishing process. The current genome sequence (Build 35) contains 2.85 billion nucleotides interrupted by only 341 gaps. It covers ∼99% of the euchromatic genome and is accurate to an error rate of ∼1 event per 100,000 bases. Many of the remaining euchromatic gaps are associated with segmental duplications and will require focused work with new methods. The near-complete sequence, the first for a vertebrate, greatly improves the precision of biological analyses of the human genome including studies of gene number, birth and death. Notably, the human enome seems to encode only 20,000-25,000 protein-coding genes. The genome sequence reported here should serve as a firm foundation for biomedical research in the decades ahead

Extracorporeal photopheresis as a non-specific immune therapy of autoimmune diseases and skin T-cell lymphoma (a review of the literature and own studies)

Aim: To present well-known and disputable mechanisms of the effects of extracorporeal photopheresis (ECP) in heterogeneous clinical conditions, as well as to demonstrate its advantages over conventional hormonal, immunosuppressive and cytostatic treatments, with a recommendation to widely implement it into practical management of autoimmune disease and cutaneous T-cell lymphomas (CTCLs).Key points: Despite convincing evidence of the ECP efficacy in the treatment of T-cell mediated disorders, a unifying concept of its mechanism has not been established so far. In this review, we attempted to determine the value of multiple, sometimes contradictory and equivocal points of view to immunobiochemical processes underlying the restoration of mechanism of immune tolerance in some autoimmune diseases and CTCLs. We focused our attention on our own clinical and immunological data obtained during a 20-years' experience with the use of ECP in clinical departments of MONIKI (Russia). Based on this, we have shown that ECP is more effective in autoimmune diseases than conventional treatment approaches with hormones, immunosuppressants and cytostatics. Unlike them, ECP is selectively targeted to auto-aggressive T-cells without induction of systemic immunosuppression. The leading role is played by the transformation of activated (immunogenic) myeloid dendrite cells (DC) into tolerogenic cell associated with their synthesis of inhibitor cytokines. The interplay of the cytokines with an antigen results in polarization of CD4+ Т lymphocytes via the Th2 pathway with restoration of the Th1/Th2 balance and their cytokine production. ECP triggers regulatory anti-clonotypic effector memory cells at the end stage of CD3+/CD8+/CD27-/CD28-/CD62L+ differentiation, that provide and maintain the peripheral immune tolerance, by deletion of the clone of auto-reactive cytotoxic lymphocytes and inducing their apoptosis. In autoimmune disorders, ECP results in reduction of the expression of integrin adhesion molecules on auto-reactive cell membranes with subsequent loss of their ability to migrate through the endothelium to their target cells. In its turn, it leads to decreasing immunoinflammatory response in the lesion. Both clinical and experimental data indicate that the mechanism of ECP action against CTCLs is characterized by activation of tumor cell apoptosis, unblocking of co-activation receptors on the antigen-presenting DC providing the functioning of the second signaling pathway for T lymphocyte activation. This results in proliferation of anti-tumor effector cells pool, production of DC activating cytokines that participate in the CD4+ polarization via Th1 pathway. In addition, this review considers the mechanism of the immunomodulating effect of ECP in the context of its influence at the levels of transcription and translation of proteins contributing to the pathophysiology of the disorders, based on molecular immunogenetic studies. Thus, ECP is able to induce antigen-specific immunological tolerance through the transformation of antigen-presenting cells, modulation of cytokine profile, adhesion and activation molecules, as well as through formatting of the regulatory T cells (Tregs).Conclusion: Undoubtedly, the immunobiological ECP technique has significant advantages over well-known conventional hormonal, immunosuppressive, and cytostatic therapies of autoimmune diseases and CTCLs

Extracorporeal photopheresis in solid organ transplantation

Despite the use of up-to-date immunosuppressive agents, graft rejection episodes are quite common and pose a serious threat to thousands of solid organ recipients. Continuous use of various combinations of immunosuppressants cause serious complications, such as arterial hypertension, post-transplant diabetes mellitus, renal failure, increased risk of infections, malignant neoplasms, etc. The attempts to achieve the desired or forced minimization of the graft immunosuppression are associated with the threat of its rejection, which makes it necessary to search for less toxic, non-medical, immunological, including cellular, management methods. One of the promising methods based on cell technology is extracorporeal photopheresis (ECP). ECP is a well-established second line therapy recommended for the prevention and treatment of refractory rejection of a heart transplant. ECP improves the pulmonary allograft functioning in patients with treatment resistant obliterating bronchiolitis syndrome. However, its value as a preventive method has not yet been established. ECP effectiveness for induction, maintenance, or anti-crisis therapy in transplantation of kidney, liver or other solid organs has been rather convincing, but the lack of randomized multicenter studies limits its use. The optimal ECP strategy has not been yet established. Nevertheless, current understanding of the pathophysiological and immunological aspects of ECP is sufficient to develop a standard methodology and technology for the procedure, as well as for a quality control system for ECP in kidney and liver transplant recipients. The review discusses possible mechanisms of the immunomodulating effect of ECP. ECP is being increasingly studied in prospective randomized trials with larger samples. This allows for an extension of its clinical indications with clear criteria, as well as for studying its multifactorial underlying immunomodulating mechanism of action. Further research is needed to identify biomarkers that could predict ECP effectiveness in solid organ transplantation

Luminescent properties of LuPO4\mathrm{LuPO_4}-Pr and LuPO4\mathrm{LuPO_4}-Eu nanoparticles

Spectral-luminescence parameters of $LuPO_{4}-Eu$ and $LuPO_{4}-Pr$ nanoparticles of different sizes are studied upon excitation by the synchrotron radiation with photon energies 4–40 eV. Influence of the nanoparticle size on $Eu^{3+}$ and $Pr^{3+}$ impurity luminescence is analyzed for intracenter and recombination excitation. It is shown that the luminescence intensity of impurities in the case of recombination excitation significantly stronger decreases with decreasing of nanoparticle size compared to intracenter excitation. This feature is explained by the influence of thermalization length to nanoparticle size ratio on the recombination luminescence. Electron recombination luminescence inherent for $LuPO_{4}-Eu$ nanoparticles shows a weaker dependence on the nanoparticle size than the hole one in $LuPO_{4}-Pr$ nanoparticles. The difference between energy states of praseodymium impurity ions in nanoparticles of different sizes is revealed

Luminescence and scintillation properties of LuPO4−CeLuPO_{4}-Ce nanoparticles

Study of the spectral-luminescence parameters of LuPO4-Ce nanoparticles upon the excitation by X-ray quanta and synchrotron radiation with photon energies of 4–25 eV was performed. Nanoparticles with mean size about a=35 nm and nanoparticles with size less than 12 nm reveal the different structures of cerium centers. Luminescence efficiency of LuPO4-Ce nanoparticles of a<12 nm size strongly decreases upon the excitation in the range of band-to-band transitions as well as in the case of X-ray excitation