DNABII proteins play a central role in UPEC biofilm structure

Most chronic and recurrent bacterial infections involve a biofilm component, the foundation of which is the extracellular polymeric substance (EPS). Extracellular DNA (eDNA) is a conserved and key component of the EPS of pathogenic biofilms. The DNABII protein family includes integration host factor (IHF) and histone‐like protein (HU); both are present in the extracellular milieu. We have shown previously that the DNABII proteins are often found in association with eDNA and are critical for the structural integrity of bacterial communities that utilize eDNA as a matrix component. Here, we demonstrate that uropathogenic Escherichia coli (UPEC) strain UTI89 incorporates eDNA within its biofilm matrix and that the DNABII proteins are not only important for biofilm growth, but are limiting; exogenous addition of these proteins promotes biofilm formation that is dependent on eDNA. In addition, we show that both subunits of IHF, yet only one subunit of HU (HupB), are critical for UPEC biofilm development. We discuss the roles of these proteins in context of the UPEC EPS.     

Evidence for the priming role of the central retinula cell in ommatidium differentiation of Ephestia kuehniella

Summary In the developing compound eye of Ephestia kuehniella, within the advancing front of differentiation, regular cell clusters arise which consist of a central cell and two flanking cells. The central cell is destined to become the basal retinula cell later in development. Its crucial role in ommatidium formation is confirmed by ³H-thymidine labelling. Eye anlagen labelled early in the pupal stage incorporate thymidine within two distinct zones along the front of differentiation. After the ommatidia are completely differentiated, both zones contain labelled nuclei of all cell types which participate in ommatidia formation. Within the posterior zone, however, the basal retinula cells are always unlabelled, whereas in the anterior they show labelled nuclei. From this observation it must be concluded that the basal retinula cell first terminates proliferation (either alone or together with a few other cells) to become differentiated as the central retinula cell. These results agree with those found in Drosophila and indicate that the ordered stepwise addition of cells to a central founder cell is a widespread principle of ommatidia formation in insects.     

Arthritogenic T cells in autoimmune arthritis

Autoimmune diseases, including arthritis, often result from an imbalance between regulatory T (Treg) cells and IL-17-producing (Th17) cells. Dozens of studies in mice and humans have shed light on the pathological significance of T cells in RA. Since Th17 cells play an important role in the exacerbation of inflammation and bone destruction in joints, it has been an important issue how arthritic Th17 cells arise. Th17 cells are generated in the local inflammatory milieu via cytokines produced by macrophages or synovial fibroblasts, while it is reported that Th17 cells are generated in the gut in the presence of specific commensal bacteria. A recent report showed a pathogenic Th17 cell subset with a distinct pattern of gene expression and a potent osteoclastogenic ability are converted from Foxp3⁺ T cells in arthritic joints. Since Foxp3⁺ Treg cells contain T cells which recognize self-antigens, the fate of plastic Foxp3⁺ T cells can be a critical determinant of autoimmunity or self-tolerance. Further analysis on the molecular basis and antigen-specificity of arthritogenic Th17 cell subsets will be helpful to establish novel therapeutic approaches and clarify how self-tolerance breaks down in autoimmune arthritis.     

Bone marrow-derived cells play a major role in kidney fibrosis via proliferation and differentiation in the infiltrated site

Increase of interstitial cell population, resulting in the expansion of interstitium, excessive production of extracellular matrix, and reduction of functioning tubules, is critical in fibrotic progression in the kidney of patients suffering from chronic renal diseases. Here, we investigated the contribution of bone marrow-derived cells (BMDC) in kidney fibrosis caused by ureteral obstruction (UO) using eGFP bone marrow-reconstituted chimeric mice. UO caused dramatic increases in the numbers of interstitial cells and expansion of the interstitium. Most kidney interstitial cells expressed GFP. Twenty nine percent of interstitial cells were cells that had proliferated and approximately 89% among them were BMDCs. Proliferation of fibroblasts differentiated from BMDCs significantly occurred in the interstitium of UO-kidney. Removal of BMDCs by whole body irradiation after UO resulted in reduction of kidney fibrosis, while injection of RAW264.7 cells, monocytes/macrophages, into irradiated mice induced a reversal of this reduction. Treatment with apocynin, an inhibitor of NADPH oxidase, reduced infiltration of BMDCs into the UO-kidney, leading to reduction of kidney fibrosis. In addition, only a few slow-cycling cells were observed in the interstitium of normal kidney. Even after UO, no change in the number of those cells was observed. Our findings demonstrate that BMDCs are a major source for interstitial expansion during kidney fibrosis via infiltration into damaged sites, differentiation to fibroblasts, and subsequent proliferation, contributing kidney fibrosis. These data provide a clear therapeutic target for treatment of chronic kidney disease.     

Unrestricted lineage differentiation of parthenogenetic ES cells

 The developmental potential of parthenogenetic embryonic stem (P-ES) cells was studied in teratomas and mouse chimaeras. Teratomas derived from P-ES cells contained a mixture of tissue types with variable proportions of specific tissues. Three of the eight P-ES cell lines analysed showed high proportions of striated muscle in teratomas, similar to teratomas from normal embryos or ES cell lines derived from fertilised embryos (F-ES cells). Our study also revealed that one P-ES cell line showed little lineage restriction in injection chimaeras. Descendants of the P-ES cells contributed to most tissues of chimaeric fetuses in patterns similar to F-ES cells. Normal colonisation of muscle, liver and pancreas was found in adult chimaeras. P-ES cells also showed similar haematopoietic differentiation and maturation as F-ES cells. However, extensive P-ES cell contribution was associated with a reduction in body size. These findings suggest that, while P-ES cells display more extensive developmental potential than the cells of parthenogenetic embryos from which they were derived, they only retained properties related to the presence of the maternal genome. To elucidate the molecular basis for the lack of lineage restriction during in vivo differentiation, the expression of four imprinted genes, H19, Igf2r, Igf2 and Snrpn was compared among five P-ES and two F-ES cell lines. Expression levels of these genes varied among the different ES cell lines, both in undifferentiated ES cells and in embryoid bodies.     

Electrostatic effects play a central role in cold adaptation of trypsin.

Organisms that live in constantly cold environments have to adapt their metabolism to low temperatures, but mechanisms of enzymatic adaptation to cold environments are not fully understood. Cold active trypsin catalyses reactions more efficiently and binds ligands more strongly in comparison to warm active trypsin. We have addressed this issue by means of comparative free energy calculations studying the binding of positively charged ligands to two trypsin homologues. Stronger inhibition of the cold active trypsin by benzamidine and positively charged P1-variants of BPTI is caused by rather subtle electrostatic effects. The different affinity of benzamidine originates solely from long range interactions, while the increased binding of P1-Lys and -Arg variants of BPTI is attributed to both long and short range effects that are enhanced in the cold active trypsin compared to the warm active counterpart. Electrostatic interactions thus provide an efficient strategy for cold adaptation of trypsin.     

p53 plays a regulatory role in differentiation and apoptosis of central nervous system-associated cells.

This study demonstrated the involvement of the tumor suppressor protein p53 in differentiation and programmed cell death of neurons and oligodendrocytes, two cell types that leave the mitotic cycle early in development and undergo massive-scale cell death as the nervous system matures. We found that primary cultures of rat oligodendrocytes and neurons, as well as of the neuronal PC12 pheochromocytoma cell line, constitutively express the p53 protein. At critical points in the maturation of these cells in vitro, the subcellular localization of p53 changes: during differentiation it appears mainly in the nucleus, whereas in mature differentiated cells it is present mainly in the cytoplasm. These subcellular changes were correlated with changes in levels of immunoprecipitated p53. Infection of cells with a recombinant retrovirus encoding a C-terminal p53 miniprotein (p53 DD), previously shown to act as a dominant negative inhibitor of endogenous wild-type p53 activity, inhibited the differentiation of oligodendrocytes and of PC12 cells and protected neurons from spontaneous apoptotic death. These findings suggest that p53, upon receiving appropriate signals, is recruited into the nucleus, where it plays a regulatory role in directing primary neurons', oligodendrocytes, and PC12 cells toward either differentiation or apoptosis in vitro.     

Integrin functions play a key role in the differentiation of thymocytes in vivo

T cells express a variety of surface proteins as they develop to maturity in the thymus. In addition to the TCR-CD3 complex and the two major coreceptors, CD4 and CD8, other surface proteins expressed include receptors for cytokines, growth factors, counterreceptors, and extracellular matrix molecules. To determine the role of integrin adhesion receptors in T cell development, we have expressed a trans-dominant inhibitor of integrin function in the thymus. This inhibitor leads to a block of adhesion to fibronectin due to reduced activation of integrin receptors. This reduced adhesion leads to a partial block in differentiation from CD4-CD8- cells to CD4+CD8+ cells, after the CD25+ stage, suggesting that integrins are important during Lck-mediated differentiation. Furthermore, the overall production of CD4+ cells is reduced compared with that of CD8+ cells without changes in negative selection, suggesting that integrins may be involved in the determination of the fate of the cell as well. These results demonstrate that integrin receptor function is required for proper thymocyte development in vivo.     

Oxygen free radicals play a role in cellular differentiation: An hypothesis

Evidence from a variety of sources supports the view that oxygen free radicals play a role in cellular differentiation. It is postulated that cellular differentiation is accompanied by changes in the redox state of cells. Differentiated cells have a relatively more prooxidizing or less reducing intracellular environment than the undifferentiated or dedifferentiated cells. Changes in the redox balance during differentiation appear to be due to an increase in the rate of O₂⁻ generation. Differentiated cells, in general, exhibit higher rates of cyanide-resistant respiration, cyanide-insensitive SOD activity, and peroxide concentration and lower levels of GSH as compared to undifferentiated cells. The effects of free radicals on cellular differentiation may be mediated by the consequent changes in ionic composition.     

DVL genes play a role in the coordination of socket cell recruitment and differentiation

Specialized plant cells arise from undifferentiated cells through a series of developmental steps. The decision to enter into a certain differentiation pathway depends in many cases on signals from neighbouring cells. The ability of cells to engage in short-range intercellular communication permits the coordination of cell actions necessary in many developmental processes. Overexpression of genes from the DEVIL/ROTUNDIFOLIA (DVL/ROT) family results in severe developmental alterations, but very little is known about their mechanism of action. This work presents evidence that suggests a role for these genes in local signalling, specifically in the coordination of socket cell recruitment and differentiation. Overexpression of different DVL genes results in protuberances at the base of the trichomes surrounded by several rows of elongated epidermal cells, morphologically similar to socket cells. Localized overexpression of DVL4 in trichomes and socket cells during early developmental stages activates expression of socket cell markers in additional cells, farther away from the trichome. The same phenomenon is observed in an activation tagged line of DVL1, which also shows an increase in the number of socket cells in contact with the trichome. The roles of individual DVL genes have been difficult to discover since their overexpression phenotypes are quite similar. In gl1 leaves that lack trichomes and socket cells DVL1 expression shows a 69% reduction, suggesting that this gene could be involved in the coordination of socket cell development in wild-type plants.     

Ascorbic acid might play a role in the sclerotial differentiation of Sclerotium rolfsii

Certain phytopathogenic fungi differentiate by forming sclerotia by an unclear biochemical mechanism. We have proposed that sclerotial differentiation might be regulated by fungal antioxidant defense. Part of this defense might be ascorbic acid, which in its reduced form is a well-known antioxidant. This natural antioxidant was studied in Sclerotium rolfsii in relation to oxidative-growth conditions, developmental stages and strain-differentiating ability. The transition of a sclerotial strain from the undifferentiated to the differentiated stage was accompanied by a sharp shift in the ratio of reduced/oxidized ascorbate toward the oxidized form. Ascorbate profiles and lipid peroxidation levels were different between the sclerotial strain grown under high- and low-oxidative stress conditions, as well as between a nonsclerotial S. rolfsii strain grown under high-oxidative stress conditions. In addition, the ratio of reduced/oxidized ascorbate in the nonsclerotial strain remained unchanged throughout growth. Lipid peroxidation under high-oxidative stress conditions in sclerotial S. rolfsii colonies one day before differentiation was 3.6-fold higher than in same-day colonies of this strain grown under low-oxidative stress conditions and 2.5-fold higher than in similar-day colonies of the nonsclerotial strain grown under high-oxidative stress conditions. Exogenous ascorbate caused a concentration-dependent reduction of lipid peroxidation and a proportional inhibition of the degree of sclerotial differentiation in the sclerotial strain grown under high-oxidative stress conditions by lowering its lipid peroxidation before differentiation to levels similar to the strain grown under low-oxidative stress conditions and to the nonsclerotial strain. Ascorbic acid might be produced by the sclerotial strain to reduce oxidative stress, although less efficiently than the nondifferenting strain. The data of this study support our theory that oxidative stress might be the triggering factor of sclerotial differentiation in phytopathogenic fungi.     

miRNAs在干细胞自我更新和分化中的调控作用

干细胞与microRNAs(miRNAs)均为近年来研究的热点问题。干细胞是一类具有自我更新与多项分化潜能的细胞, 因与生物发育和癌症发生的密切联系而越来越受到人们的重视。miRNAs是一类长约22nt的小分子非编码RNA, 具有高度的种间保守性和时空特异性, 在转录后水平调节靶基因的表达, 是细胞内基因表达的基本调控机制之一。最近的一些研究表明, miRNAs在干细胞的自我更新和分化过程中具有重要的调控作用。这些研究主要采用两种策略: (1)缺失/突变干细胞中miRNAs合成途径必需酶(包括Dicer1、Loqs、DGCR8、Argnaute蛋白等), 通过细胞特性变化来研究其功能; (2)直接筛选干细胞中的特异性miRNAs并研究其功能。针对干细胞中miRNAs的研究对深入了解干细胞自我更新和分化的机制以及干细胞的鉴定具有重要的意义。文章基于近年来的研究对干细胞相关的miRNAs进行了综述。     

Antigen presentation for priming T cells in central system

Generation of myelin antigen-specific T cells is a major event in neuroimmune responses that causes demyelination. The antigen-priming of T cells and its location is important in chronic and acute inflammation. In autoimmune multiple sclerosis, the effector T cells are considered to generate in periphery. However, the reasons for chronic relapsing-remitting events are obscure. Considering mechanisms, a feasible aim of research is to investigate the role of antigen-primed T cells in lupus cerebritis. Last thirty years of investigations emphasize the relevance of microglia and infiltrated dendritic cells/macrophages as antigen presenting cells in the central nervous system. The recent approach towards circulating B-lymphocytes is an important area in the context. Here, we analyze the existing findings on antigen presentation in the central nervous system. The aim is to visualize signaling events of myelin antigen presentation to T cells and lead to the strategy of future goals on immunotherapy research.