Purification and characterization of anthranilate synthase component I (TrpE) from Mycobacterium tuberculosis H37Rv

The emergence of multi-drug resistant (MDR) strains of Mycobacterium tuberculosis is the main reason why tuberculosis (TB) continues to be a major health problem worldwide. It is urgent to discover novel anti-mycobacterial agents based on new drug targets for the treatment of TB, especially MDR-TB. Tryptophan biosynthetic pathway, which is essential for the survival of M. tuberculosis and meanwhile absent in mammals, provides potential anti-TB drug targets. One of the promising drug targets in this pathway is anthranilate synthase component I (TrpE), whose role is to catalyze the conversion of chorismate to anthranilate using ammonia as amino source. In order to get a deep understanding of TrpE, a study on purification and characteristic identification of TrpE is required. In this work, the putative trpE gene of M. tuberculosis H37Rv was expressed as a fusion protein with a 6x His-tag on the N-terminal (His-TrpE) in Escherichia coli. The recombinant TrpE protein was successfully purified and then its enzymatic characteristics were analyzed. The native TrpE without His-tag was obtained by removal of the N-terminal fusion partner of His-TrpE using enterokinase. It was found that N-terminal fusion partner had little influence on TrpE catalytic activity. In addition, the key residues related to enzyme catalytic activity and that involved in l-tryptophan inhibition were predicted in the structure of M. tuberculosis H37Rv TrpE. These results would be beneficial to the designing of novel anti-TB drugs with high potency and selectivity.     

A bicistronic expression strategy for large scale expression and purification of full-length recombinant human parathyroid hormone for osteoporosis therapy

Parathyroid hormone (PTH) contributes to the increase of trabecular connectivity and is a candidate medication for effective treating osteoporosis. PTH is a protein of 84 amino acids and some studies have suggested that the active site lies within the range from amino acid (aa) 1 to 34. However, a few reports have indicated a causal relationship between PTH (aa 1–34) and osteogenic sarcoma in rats, while some less obvious but important roles of the carboxyl-terminus of PTH were also found. Unfortunately, it is difficult to obtain the active integrated PTH (1–84) in vitro, due to the instability of both the protein and its mRNA. Because an alternative translation start site is located at +25 nucleotides downstream of the true start site, a truncated PTH can be translated. We constructed a rhPTH bicistronic expression plasmid (pTrepth) that could highly express non-fusion soluble rhPTH proteins in Escherichia coli. The BL-21(DE3) containing pTrepth was cultured on a small scale until satisfactory expression and purification results were obtained. We then amplified the transformed cells in a 15-L fermentor and harvested 27 g/L cells (wet weight). Extensive rhPTH purification was achieved by a three step chromatography process. Activity tests demonstrated that our purified protein could dramatically increase cAMP in osteosarcoma cells in vitro.     

Effect of N, P concentration on growth rate

The total nitrogen, phosphorus, biomass, pH, dissolved oxygen in and temperatures of three eutrophic waters were investigated in the rapid-growth season of phytoplankton (July-October). Chloromonas rosae was cultivated in water samples from three eutrophic waters and diluted water samples from Lake Donghu to determine the effect of N and P concentrations on the growth rate. The relationship between the biomass and the N and P concentrations, analyzed by regression, showed that phosphorus was the limiting factor for algae growth in eutrophic water. The relationship between the growth rate and the P concentration can be described with the regression equation y=0.0806ln(x) 0.4658, (R²=0.889). The growth rate increased linearly with the increase of P concentration when it was below 0.05 mg/L. It increased less when the P concentration was above 0.05 mg/L, and was almost unchanged when the P concentration exceeded 0.2mg/L. The P concentration corresponding to the growth rate “0” (deduced from the regression equation) was 0.003mg/L, close to the minimal P concentration of poorly nutrient lakes. This indicated that the regression equation was representative. The average values for plankton cellular N and P in the three eutrophic waters were 53% and 85%, respectively. To evaluate the levels of eutrophy, N and P, both in the water and in the plants, must be considered. The biomass of phytoplankton is controlled by concentrations of both dissolved and cellular N and P. The following linear regression equations describe the relationship between biomass and N: y=10.687x-7.8304, (R²=0.950), and between biomass and P, y=122.11x-12.069, (R²=0.991). They exemplify the absolute and relative aspects of growth-limiting factors with Redfield values. We conclude that the only way to prevent eutrophication is to maintain a balance between the input and output of nutrients and to remove excessive dissolved N and P in the water.     

PP2A is required for centromeric localization of Sgo1 and proper chromosome segregation

Loss of sister-chromatid cohesion triggers chromosome segregation in mitosis and occurs through two mechanisms in vertebrate cells: (1) phosphorylation and removal of cohesin from chromosome arms by mitotic kinases, including Plk1, during prophase, and (2) cleavage of centromeric cohesin by separase at the metaphase-anaphase transition. Bub1 and the MEI-S332/Shugoshin (Sgo1) family of proteins protect centromeric cohesin from mitotic kinases during prophase. We show that human Sgo1 binds to protein phosphatase 2A (PP2A). PP2A localizes to centromeres in a Bub1-dependent manner. The Sgo1-PP2A interaction is required for centromeric localization of Sgo1 and proper chromosome segregation in human cells. Depletion of Plk1 by RNA interference (RNAi) restores centromeric localization of Sgo1 and prevents chromosome missegregation in cells depleted of PP2A_Aalpha. Our findings suggest that Bub1 targets PP2A to centromeres, which in turn maintains Sgo1 at centromeres by counteracting Plk1-mediated chromosome removal of Sgo1.     

New regulators in adult neurogenesis and their potential role for repair

Adult neural stem cells hold great promise for repair because of their unique location within the central nervous system, their potential to proliferate and to differentiate into all major neural lineages, and their ability to incorporate functionally into the existing neuronal circuitry. However, recruitment of these cells for repair is hampered by the lack of knowledge about the signals that control the generation of a functional neuron from adult neural stem cells. Here, we discuss recent findings on the regulatory mechanisms that underlie neurogenesis from neural stem cells in the adult hippocampus and the implications of these findings for future stem-cell-based repair strategies.     

pistillata-5, an Arabidopsis B class mutant with strong defects in petal but not in stamen development

The Arabidopsis floral organ identity genes APETALA3 (AP3) and PISTILLATA (PI) encode related DNA-binding proteins of the MADS family. Considerable evidence supports the hypothesis that a heterodimer of AP3 and PI is an essential component of B class activity. All ap3 and pi alleles characterized to date exhibit equivalent phenotypic defects in both whorls 2 and 3. In strong ap3 and pi mutants, petals and stamens are missing and sepals and carpels develop in their place. Weak ap3 and pi mutants exhibit partial conversions of petals to sepals and stamens to carpels. In this report, we describe the isolation and characterization of pi-5, an unusual B class mutant that exhibits defects in whorl 2 where sepals develop in place of petals, but third whorl stamens are most often normal. pi-5 flowers resemble those from 35S::SEP3 antisense plants. pi-5 contains missense mutation in the K domain (PIE125K). PIE125K exhibits defects in heterodimerization with its partner protein AP3. Via a reverse yeast two-hybrid screen, AP3K139E was isolated as a compensatory mutant of PIE125K. The compensatory interaction between PIE125K and AP3K139E is observed both in yeast two-hybrid assays and in planta. On its own, AP3K139E exhibits defects in specifying both petal and stamen identity. In addition, PIE125K is defective in interaction with SEPALLATA proteins in both two- and three-hybrid assays suggesting that PIE125K is defective in forming higher order complexes of MADS proteins. The decreased concentration of PI/AP3/SEP complexes offers an explanation for the petal defects observed in both pi-5 and 35S::SEP3 antisense plants.     

Identification and characterization of a regulatory sequence recognized by Mycobacterium tuberculosis persistence regulator MprA

Establishment and maintenance of persistent, latent infection by Mycobacterium tuberculosis are dependent on expression of the mprA-mprB regulatory system. Previously, MprA and MprB were shown to participate in phosphotransfer reactions characteristic of two-component signaling systems. To begin identifying downstream effector genes regulated by mprA-mprB during persistent stages of infection, a search for the regulatory sequence(s) recognized by response regulator MprA was carried out. Here, evidence is presented demonstrating that MprA recognizes a 19-bp sequence comprising two loosely conserved 8-bp direct repeat subunits separated by 3 nucleotides. This motif, termed the MprA box, is found upstream of the mprA coding sequence and that of downstream gene pepD (Rv0983). Protein phosphorylation was not required for binding to this DNA sequence by MprA in vitro; however, phosphorylation enhanced DNA binding by MprA and was required for the regulation of mprA and pepD by MprA in vivo. Binding of MprA to the MprA box was dependent on conserved nucleotides contained within repeat subunits and on the spacer length separating these repeats. In addition, recognition of this sequence proceeded via tandem binding of two monomers of MprA. Identification of the genetic determinants regulated by MprA will ultimately enhance our understanding of the mechanisms utilized by M. tuberculosis to undergo latency.