Viral Plasmacytosis (Aleutian Disease) of Mink Resembling Human Collagen Disease

A disease in mink has been discovered that has many of the features of collagen diseases in man. Affected animals suffer from wasting with leukopenia and thrombocytopenia as well as plasma cell infiltration, hypergammaglobulinemia, glomerulonephritis, arteritis and amyloidosis. Cell-free filtrates and ultracentrifugates from diseased animals induced the disease in normal mink, and aleutian genotypes were unusually susceptible to infection. This genotype was characterized by abnormal lysosomal structures in all the granule-forming cells, resembling the Chediak-Higashi syndrome of man. Anti-γ-globulin factors similar to human rheumatoid factors were reported, although tests for antibodies such as ANF and LE factors have been negative. Arteritis and glomerulonephritis lesions stained positively for γ-globulin, and Coombs-type sensitized red cells have been detected in the majority of affected mink. Some mink develop a monodispersion of hypergammaglobulinemia resembling the serum protein changes in human myeloma. These studies highlight genetic, immunological and microbiological causative factors in a mink disorder resembling human collagen disease.     

The folate-binding protein of rat kidney. Purification, properties, and cellular distribution

Folate-binding protein (FBP) from rat kidney was isolated, and its properties and location in the kidney were determined. The particulate fraction of rat kidney homogenate was freed of its bound folate, solubilized with Triton X-100, and the FBP was purified using a combination of DEAE-cellulose and affinity chromatography. The purified protein migrated as a single band on sodium dodecyl sulfate-disc gel electrophoresis, has an isoelectric point of 5.7, contains 21.7% carbohydrate, and has an Mr of 28,500-30,000. The purified protein retained its affinities for different folate derivatives and its sensitivity to inorganic anions. Inorganic anions enhanced the binding of 5-methyltetrahydrofolate; chloride ion was the most effective, followed by Br- greater than I- greater than SO2-4. Chloride ion was also found to lower the dissociation constant of the folic acid-FBP complex at 50 degrees C by about 10-fold. This effect is thought to derive from the formation of a ternary FBP-folic acid-Cl- complex which is more stable than the binary FBP-folic acid complex. An antiserum raised against the purified protein in rabbits was used to determine the location of FBP in the kidney by immunofluorescence. Intense fluorescence staining for FBP was localized at the apices (brush border) of proximal tubules. The choroid plexus, an organ previously shown to contain FBP, also exhibited intense fluorescent staining.     

16S and 23S plastid rDNA phylogenies of Prototheca species and their auxanographic phenotypes

Because algae have become more accepted as sources of human nutrition, phylogenetic analysis can help resolve the taxonomy of taxa that have not been well studied. This can help establish algal evolutionary relationships. Here, we compare Auxenochlorella protothecoides and 23 strains of Prototheca based on their complete 16S and partial 23S plastid rDNA sequences along with nutrient utilization (auxanographic) profiles. These data demonstrate that some of the species groupings are not in agreement with the molecular phylogenetic analyses and that auxanographic profiles are poor predictors of phylogenetic relationships.     

Dynamic identification of H2 epitopes from Leishmania (Leishmania) amazonensis cysteine proteinase B with potential immune activity during murine infection

Peptides from the COOH‐terminal extension of cysteine proteinase B from Leishmania (Leishmania) amazonensis (cyspep) can modulate immune responses in vertebrate hosts. With this hypothesis as base, we used the online analysis tool SYFPEITHI to predict seven epitopes from this region with potential to bind H2 proteins. We performed proliferation tests and quantified reactive T lymphocytes applying a cytometry analysis, using samples from draining lymph node of lesions from L. (L.) amazonensis‐infected mice. To define reactivity of T cells, we used complexes of DimerX (H2 D^b:Ig and H2 L^d:Ig) and the putative epitopes. Additionally, we applied surface plasmon resonance to verify real time interactions between the putative epitopes and DimerX proteins. Five peptides induced blastogenesis in BALB/c cells, while only two presented the same property in C57BL/6 mouse cells. In addition, our data indicate the existence of CD8⁺ T lymphocyte populations able to recognize each tested peptide in both murine strains. We observed an overlapping of results between the peptides that induced lymphocyte proliferation and those capable of binding to the DimerX in the surface plasmon resonance assays thus indicating that using these recombinant proteins in biosensing analyses is a promising tool to study real time molecular interactions in the context of major histocompatibility complex epitopes. The data gathered in this study reinforce the hypothesis that cyspep‐derived peptides are important factors in the murine host infection by L. (L.) amazonensis. Copyright © 2014 John Wiley & Sons, Ltd.     

SHUGOSHINs and PATRONUS protect meiotic centromere cohesion in Arabidopsis thaliana

In meiosis, chromosome cohesion is maintained by the cohesin complex, which is released in a two‐step manner. At meiosis I, the meiosis‐specific cohesin subunit Rec8 is cleaved by the protease Separase along chromosome arms, allowing homologous chromosome segregation. Next, in meiosis II, cleavage of the remaining centromere cohesin results in separation of the sister chromatids. In eukaryotes, protection of centromeric cohesion in meiosis I is mediated by SHUGOSHINs (SGOs). The Arabidopsis genome contains two SGO homologs. Here we demonstrate that Atsgo1 mutants show a premature loss of cohesion of sister chromatid centromeres at anaphase I and that AtSGO2 partially rescues this loss of cohesion. In addition to SGOs, we characterize PATRONUS which is specifically required for the maintenance of cohesion of sister chromatid centromeres in meiosis II. In contrast to the Atsgo1 Atsgo2 double mutant, patronus T‐DNA insertion mutants only display loss of sister chromatid cohesion after meiosis I, and additionally show disorganized spindles, resulting in defects in chromosome segregation in meiosis. This leads to reduced fertility and aneuploid offspring. Furthermore, we detect aneuploidy in sporophytic tissue, indicating a role for PATRONUS in chromosome segregation in somatic cells. Thus, ploidy stability is preserved in Arabidopsis by PATRONUS during both meiosis and mitosis.