Multidose streptozotocin induction of diabetes in BALB/cBy mice induces a T cell proliferation defect in thymocytes which is reversible by interleukin-4

Thymic T cell function in streptozotocin-treated (STZ) diabetic mice has been examined. STZ administration suppresses thymic T cell proliferation in response to mitogen stimulation in vitro. Secretion of IL-4 was dramatically reduced; however, secretion of IL-2 or IFN-gamma was not significantly inhibited. RT-PCR analysis of thymocyte RNA revealed that levels of IL-4 mRNA were dramatically decreased in STZ-treated mice. Levels of mRNA encoding IFN-gamma were similar, but the appearance was delayed in thymocytes derived from STZ-treated mice, implying differential regulation of IL-4 and IFN-gamma. Defective thymocyte proliferation was partially restored by exposure to IL-2 in vitro; however, IL-4 completely reversed the STZ-induced defect. Administration in vivo of IL-4 before STZ treatment reversed the STZ-induced thymocyte proliferation defect and prevented both pancreatic islet destruction and hyperglycemia. Thymocyte cell surface differentiation markers were not appreciably different from control mice. Collectively these experiments suggest that STZ treatment of mice reduces expression of IL-4 which is associated with development of autoimmune diabetes.     

Chloroplast DNA-relationship in palaeoaustralLopidium concinnum (Hypopterygiaceae, Musci). An example of stenoevolution in mosses Studies in austral temperate rain forest bryophytes 2

Evolutionary relationship between disjunct populations of the palaeoaustral moss taxonLopidium concinnum (Hypopterygiaceae) from New Zealand and southern South America were studied using non-coding chloroplast DNA sequences. No or only slight changes could be observed within the sequences oftrnT_UGU —trnL_UAA 5exon intergenic spacer,trnL_UAA intron andtrnL_UAA 3exon —trnF_GAA intergenic spacer. This indicates nearly no genetic divergence between extant New Zealand and Chilean populations, i.e. no significant differing pathways of evolution within the 80–60 million years of disrupted areas with interrupted gene flow. Molecular data support the idea of an old Gondwanan relict species of stenoevolutionary character. Ecological data on short-range dispersal strengthen this assessment.     

Emotional and cognitive reinforcement of rat hippocampal long-term potentiation by different learning paradigms

In earlier studies we have shown that a protein-synthesis-independent, early, long-term potentiaton (early-LTP) that lasts up to 4-5 hours can be transformed (reinforced) into a protein-synthesis-dependent late-LTP that lasts > or = 8 hours by either an emotional challenge (e.g. swim stress) or mastering a cognitive task (e.g. spatial learning). In the present study we show that LTP-reinforcement by spatial training depends on the specific constraints of the learning paradigm. In a holeboard paradigm,LTP-reinforcement is related to the formation of a lasting reference memory whereas water-maze training gives more heterogenous results. Thus, cognitive aspects interfere with emotionally challenging components of the latter paradigm. These data indicate that different spatial-learning tasks are weighted distinctly by the animal. Thus, we show that aspects of specific spatial learning paradigms such as shifts of attention and emotional content directly influence functional plasticity and memory formation.     

Investigating the independent evolution of the size of floral organs via G-matrix estimation and artificial selection

The attractiveness of a plant to pollinators is dependent on both the number of flowers produced and the size of the petals. However, limiting resources often result in a size/number trade-off, whereby the plant can make either more flowers or larger flowers, but not both. If developmental genes underlying sepal and petal identity (some of which overlap) also influence size, then this shared genetic basis could constrain the independent evolution of floral size and attractiveness. Here, we determined whether the size of sepals and petals in the dioecious perennial, Silene latifolia, are developmentally independent by performing two experiments: a genetic variance-covariance experiment to estimate genetic correlations between calyx width, petal-limb length, flower mass, and number and a four-bout artificial-selection experiment to alter calyx width and estimate the correlated response in petal-limb length. In addition, we determined whether variation in petal-limb length is the result of cell expansion or cell proliferation. The first experiment revealed that petal-limb length is not genetically correlated with calyx width, and the second experiment confirmed this; selection on calyx width did not result in a predictable or significant change in petal-limb length. Flower number was negatively correlated with all the floral traits measured, indicating a flower size/number trade-off. Cell number, but not size, explained a significant amount of the variation in petal-limb length. We conclude that the size of the two outer floral organs can evolve independently. This species can therefore increase the number of flowers produced by decreasing investment in the calyx without simultaneously decreasing petal size and the attractiveness of each individual flower to pollinators.     

Epimerization at carbon-5' of (5'R)-[5'-2H]adenosylcobalamin by ribonucleoside triphosphate reductase: cysteine 408-independent cleavage of the Co-C5' bond

The adenosylcobalamin-dependent ribonucleoside triphosphate reductase (RTPR) from Lactobacillus leichmannii catalyzes the reduction of ribonucleoside triphosphates to deoxyribonucleoside triphosphates. RTPR also catalyzes the exchange of the C5'-hydrogens of adenosylcobalalamin with solvent hydrogen. A thiyl radical located on Cys 408 is generated by reaction of adenosylcobalamin at the active site and is proposed to be the intermediate for both the nucleotide reduction and the 5'-hydrogen exchange reactions. In the present research, a stereochemical approach is used to study the mechanism of the Co-C5' bond cleavage of adenosylcobalamin in the reaction of RTPR. When stereoselectively deuterated coenzyme, (5'R)-[5'-(2)H(1)] adenosylcobalamin (5'R/S = 3:1), was incubated with RTPR or the Cys 408 viariants, C408A-RTPR and C408S-RTPR in the presence of dGTP, the deuterium at the 5'-carbon was stereochemically scrambled, leading to epimerization of the (5'S)-[5'-(2)H(1)]- and (5'R)-[5'-(2)H(1)]-isotopomers. Observation of epimerization with mutated RTPR proves that transient cleavage of the Co-C5' bond occurs in the absence of the thiol group on Cys 408. The rate constants for epimerization by RTPR, C408A-RTPR, and C408S-RTPRs in the presence of dGTP are 5.1, 0.28, and 0.42 s(-1), respectively. Only the wild-type RTPR catalyzes the 5'-hydrogen exchange reaction. Both epimerization and 5'-hydrogen exchange reactions are stimulated by the allosteric effector dGTP, and epimerization is not detected in the absence of the effector. Mechanistic implications with respect to wt-RTPR-mediated carbon cobalt bond homolysis and the intermediacy of the 5'-deoxyadenosyl radical will be presented.     

Crystal structure of LexA: a conformational switch for regulation of self-cleavage

LexA repressor undergoes a self-cleavage reaction. In vivo, this reaction requires an activated form of RecA, but it occurs spontaneously in vitro at high pH. Accordingly, LexA must both allow self-cleavage and yet prevent this reaction in the absence of a stimulus. We have solved the crystal structures of several mutant forms of LexA. Strikingly, two distinct conformations are observed, one compatible with cleavage, and the other in which the cleavage site is approximately 20 A from the catalytic center. Our analysis provides insight into the structural and energetic features that modulate the interconversion between these two forms and hence the rate of the self-cleavage reaction. We suggest RecA activates the self-cleavage of LexA and related proteins through selective stabilization of the cleavable conformation.     

Proteome, transcriptome and genome: top down or bottom up analysis?

Biological systems are comprised of protein components found at a wide variety of abundances from millions of molecules of a single species per cell to less than one copy per cell. Because of this wide range of concentrations, measurement or a full accounting of each system is presently unavailable. Conventional separation and analytical methods (two-dimensional gel electrophoresis and mass spectrometry) allow identification and quantitation of many of the most abundant gene products (top down methods); and the majority of gene products, which are found at low abundance, can be neither identified nor measured in complex mixtures at present. The gene products that are found at low levels can be characterized and their properties analyzed by preparing ordered gene libraries of limited complexity from mRNA. When such preparations are expressed in cell free systems and analyzed by two-dimensional gel electrophoresis, the features of the gene products are available for analysis. This 'bottom up' approach allows identification of gene product properties so that analytical procedures can be devised and applied to complex mixtures.     

Purification of recombinant green fluorescent protein using chromatofocusing with a pH gradient composed of multiple stepwise fronts

Green fluorescent protein (GFP), which fluoresces in the green region of the visible spectrum and is widely used as a reporter for gene expression and regulation, was overexpressed in the JM105 strain of Escherichia coli transformed with pBAD-GFP. A two-step chromatofocusing procedure was used to purify GFP starting from cell lysate, with each step employing a pH gradient extending from pH 5.5 to 4.0. The first chromatofocusing step was performed using a low-pressure column in which a retained stepwise pH front formed by adsorbed buffering species was used to capture GFP directly from clarified cell lysate and selectively focus it into a chromatographic band. The second step utilized a high-performance column under mass overloaded conditions where a similar pH front acted as a protein displacer and led to the formation of a highly concentrated rectangular band of GFP. The overall procedure yielded a 50-fold increase in purity, a 20-fold volume reduction, and a recovery and purity for GFP of 60% and 80%, respectively. Because the method employs a strong-base ion-exchange column packing and low-cost buffers formed with formic and acetic acids instead of the proprietary column packings and polyampholyte elution buffers more generally used for chromatofocusing, it appears to be a practical alternative for the preparative ion-exchange chromatography of GFP in particular and for the recovery of recombinant proteins from cell lysate in general. A discussion is also given concerning the choice of appropriate buffers for the rational design of pH gradients involving retained, stepwise pH fronts that span a given pH range and of the use of the fluorescence properties of GFP for flow visualization and chromatographic process development.