In vivo phosphorylation of a peptide tag for protein purification

Objectives

To design a new system for the in vivo phosphorylation of proteins in Escherichia coli using the co-expression of the α-subunit of casein kinase II (CKIIα) and a target protein, (Nanofitin) fused with a phosphorylatable tag.

Results

The level of the co-expressed CKIIα was controlled by the arabinose promoter and optimal phosphorylation was obtained with 2 % (w/v) arabinose as inductor. The effectiveness of the phosphorylation system was demonstrated by electrophoretic mobility shift assay (NUT-PAGE) and staining with a specific phosphoprotein-staining gel. The resulting phosphorylated tag was also used to purify the phosphoprotein by immobilized metal affinity chromatography, which relies on the specific interaction of phosphate moieties with Fe(III).

Conclusion

The use of a single tag for both the purification and protein array anchoring provides a simple and straightforward system for protein analysis.

     

鱼类卵子发育能力的进一步研究

作者中的二人[Tung,and Tung.(童第周与叶毓芬)1944;Tung,Chang,andTung.(童第周、张致一与叶毓芬)1945]曾以分割的方法,研究金鱼(Carassiusauratus)卵子的发育能力。他们将2至8细胞时期的金鱼卵子,在去膜后,用玻璃针,按第一次或第二次的分裂平面,将整个卵子分割为二半。每半含有半数分裂球,一半卵黄,和一半未流入分裂球的细胞质。分割后,每半都能继续发育,但产生下列6种不同的情形:(1)二半都发育为完整的,一半大小的胚胎;(2)一个为完整的胚胎,另一个为不完整的胚胎;(3)一个为完整的胚胎,另一人为囊胚;     

Dissecting structural basis of the unique substrate selectivity of human enteropeptidase catalytic subunit

Enteropeptidase is a key enzyme in the digestion system of higher animals. It initiates enzymatic cascade cleaving trypsinogen activation peptide after a unique sequence DDDDK. Recently, we have found specific activity of human enteropeptidase catalytic subunit (L-HEP) being significantly higher than that of its bovine ortholog (L-BEP). Moreover, we have discovered that L-HEP hydrolyzed several nonspecific peptidic substrates. In this work, we aimed to further characterize species-specific enteropeptidase activities and to reveal their structural basis. First, we compared hydrolysis of peptides and proteins lacking DDDDK sequence by L-HEP and L-BEP. In each case human enzyme was more efficient, with the highest hydrolysis rate observed for substrates with a large hydrophobic residue in P2-position. Computer modeling suggested enzyme exosite residues 96 (Arg in L-HEP, Lys in L-BEP) and 219 (Lys in L-HEP, Gln in L-BEP) to be responsible for these differences in enteropeptidase catalytic activity. Indeed, human-to-bovine mutations Arg96Lys, Lys219Gln shifted catalytic properties of L-HEP toward those of L-BEP. This effect was amplified in case of the double mutation Arg96Lys/Lys219Gln, but still did not cover the full difference in catalytic activities of human and bovine enzymes. To find a missing link, we studied monopeptide benzyl-arginine-β-naphthylamide hydrolysis. L-HEP catalyzed it with an order lower K (m) than L-BEP, suggesting the monopeptide-binding S1 site input into catalytic distinction between two enteropeptidase species. Together, our findings suggest structural basis of the unique catalytic properties of human enteropeptidase and instigate further studies of its tentative physiological and pathological roles.     

Evolutionarily conserved role of nucleostemin: controlling proliferation of stem/progenitor cells during early vertebrate development

Nucleostemin (NS) is a putative GTPase expressed preferentially in the nucleoli of neuronal and embryonic stem cells and several cancer cell lines. Transfection and knockdown studies indicated that NS controls the proliferation of these cells by interacting with the p53 tumor suppressor protein and regulating its activity. To assess the physiological role of NS in vivo, we generated a mutant mouse line with a specific gene trap event that inactivates the NS allele. The corresponding NS(-/-) embryos died around embryonic day 4. Analyses of NS mutant blastocysts indicated that NS is not required to maintain pluripotency, nucleolar integrity, or survival of the embryonic stem cells. However, the homozygous mutant blastocysts failed to enter S phase even in the absence of functional p53. Haploid insufficiency of NS in mouse embryonic fibroblasts leads to decreased cell proliferation. NS also functions in early amphibian development to control cell proliferation of neural progenitor cells. Our results show that NS has a unique ability, derived from an ancestral function, to control the proliferation rate of stem/progenitor cells in vivo independently of p53.     

Improved Adenovirus Type 5 Vector-Mediated Transduction of Resistant Cells by Piggybacking on Coxsackie B-Adenovirus Receptor-Pseudotyped Baculovirus

Taking advantage of the wide tropism of baculoviruses (BVs), we constructed a recombinant BV (BV^CAR) pseudotyped with human coxsackie B-adenovirus receptor (CAR), the high-affinity attachment receptor for adenovirus type 5 (Ad5), and used the strategy of piggybacking Ad5-green fluorescent protein (Ad5GFP) vector on BV^CAR to transduce various cells refractory to Ad5 infection. We found that transduction of all cells tested, including human primary cells and cancer cell lines, was significantly improved using the BV^CAR-Ad5GFP biviral complex compared to that obtained with Ad5GFP or BV^CARGFP alone. We determined the optimal conditions for the formation of the complex and found that a high level of BV^CAR-Ad5GFP-mediated transduction occurred at relatively low adenovirus vector doses, compared with transduction by Ad5GFP alone. The increase in transduction was dependent on the direct coupling of BV^CAR to Ad5GFP via CAR-fiber knob interaction, and the cell attachment of the BV^CAR-Ad5GFP complex was mediated by the baculoviral envelope glycoprotein gp64. Analysis of the virus-cell binding reaction indicated that the presence of BV^CAR in the complex provided kinetic benefits to Ad5GFP compared to the effects with Ad5GFP alone. The endocytic pathway of BV^CAR-Ad5GFP did not require Ad5 penton base RGD-integrin interaction. Biodistribution of BV^CAR-Ad5Luc complex in vivo was studied by intravenous administration to nude BALB/c mice and compared to Ad5Luc injected alone. No significant difference in viscerotropism was found between the two inocula, and the liver remained the preferred localization. In vitro, coagulation factor X drastically increased the Ad5GFP-mediated transduction of CAR-negative cells but had no effect on the efficiency of transduction by the BV^CAR-Ad5GFP complex. Various situations in vitro or ex vivo in which our BV^CAR-Ad5 duo could be advantageously used as gene transfer biviral vector are discussed.Adenoviruses (Ads) are extensively used today as gene transfer vectors for in vitro, ex vivo, and in vivo gene transfer protocols (reviewed in reference 65). Cell entry of human Ad type 5 (Ad5), the serotype most widely used as a gene vector, occurs most efficiently by the receptor-mediated endocytosis pathway (reviewed in references 64 and 65), via the coxsackievirus B-adenovirus receptor (CAR) (3, 77) and αvβ3/αvβ5 integrins (84, 85), although alternative receptors have been described (11, 12, 14, 27). Cell surface expression of CAR differs with different cell types, and this represents one of the major determinants of the efficiency of Ad5-mediated transduction (43). The ubiquitous nature of CAR is responsible for transduction of nontarget tissues by Ad vectors. Paradoxically, many target cells such as dermal fibroblasts, synoviocytes, mesenchymal stem cells (MSCs), peripheral blood mononuclear cells (PBMCs), and dendritic cells (DCs), express no or very low levels of CAR at their surface and are relatively resistant to Ad transduction (14, 15, 19). Much work has been done with different strategies to promote the entry of Ad5 into CAR-defective cells. These strategies include (i) the genetic modification of Ad capsid proteins to carry cell ligands (2, 15, 20, 28, 49, 50), (ii) pseudotyping Ad5 vectors with fibers from other serotypes (13, 57, 74, 86), (iii) using bispecific adapters or peptides (25, 40), (iv) chemical modification of Ad (9, 42), and (v) tethering on nanoparticles (7). The limitations to these strategies are that modifications of the Ad capsid are susceptible to negatively affecting the virus growth or viability, due to an alteration of virion assembly, stability, the viral uncoating process, and/or intracellular trafficking (13, 51).Other viruses which are gaining popularity as gene transfer vectors are the baculoviruses (BVs). Autographa californica multiple nucleopolyhedrosis virus (AcMNPV) is an insect virus with a large double-stranded DNA genome packaged in a membrane-enveloped, rod-shaped protein capsid (70). Since the 1980s, the BV-insect cell expression system has been highly exploited for the production of recombinant proteins. In the mid-1990s, it was shown that recombinant BVs carrying reporter genes under cytomegalovirus (CMV) or retroviral Rous sarcoma virus promoter efficiently expressed reporter genes in mammalian cells (6, 22, 38, 41, 44, 69), as well as in avian cells (72) and fish cells (45). Since then, BVs have been reported to transduce numerous cells originating from species as various as humans, bovines, and fish (8, 32, 41, 73). As gene transfer vectors, BVs have been found to be rapidly inactivated by human serum complement (23), but exposing decay-accelerating factor (DAF) at the surface of BV by fusion with the baculoviral envelope glycoprotein can overcome this inactivation (33). BVs also have a good biosafety profile due to their incapacity to replicate in mammalian cells (31).Taking advantage of the ability of BVs to transduce a large repertoire of cells of invertebrate and vertebrate origins, including human primary cells, we investigated whether a recombinant AcMNPV could act as a carrier or macroadapter for Ad5 vectors to enter Ad5-refractory cells. To this aim, we pseudotyped AcMNPV virions with the high-affinity receptor for Ad5, the human CAR glycoprotein (BV^CAR), to enable the formation of complexes between vector particles of BV^CAR and Ad5-green fluorescent protein (Ad5GFP) mediated by Ad5 fiber and CAR interaction. We found that transduction of cell lines which were poorly permissive to Ad5, including human cancer cells and primary cells, was significantly improved using this strategy of piggybacking Ad5 vector on BV^CAR. More importantly, the increase in BV^CAR-Ad5-mediated transduction was obtained with a low range of Ad5 inputs, i.e., at multiplicities of infection (MOI) of less than 50 Ad5 vector particles per cell. We also found that the cell transduction enhancement observed with BV^CAR-Ad5 required the direct coupling of Ad5 to BV^CAR via fiber-CAR binding and that the cell attachment of the complex was mediated by the baculoviral envelope glycoprotein gp64. Kinetic analysis of virus-cell binding showed that the presence of BV^CAR in the complex was beneficial to Ad5 vector, not only in terms of tropism but also in terms of number of cell-bound virions and rate of cell attachment. In addition, the endocytic pathway of BV^CAR-Ad5 did not require Ad5 penton base RGD-integrin interaction. When administered in vivo to nude BALB/c mice, BV^CAR-Ad5 complex showed the same biodistribution as that of control Ad5 vector injected alone. In vitro, transduction of CAR-negative cells by BV^CAR-Ad5 was insensitive to coagulation factor X (FX), in contrast to Ad5 vector alone.Our novel strategy of gene delivery using the BV^CAR-Ad5 duo could be advantageously applied to various situations in vitro or ex vivo, e.g., for transducing Ad5-refractory cells when Ad5 capsid modifications cannot be envisaged, when oncolytic Ads need to be delivered to tumors via nonpermissive cell carriers belonging to the immune system, or when the simultaneous delivery of two transgenes by two separate vectors might be beneficial in terms of timing and/or level of cellular expression of the transgene products.     

Mass spectral characterization of organophosphate-labeled lysine in peptides

Organophosphate (OP) esters bind covalently to the active site serine of enzymes in the serine hydrolase family. Recently, mass spectrometry identified covalent binding of OPs to tyrosine in a wide variety of proteins when purified proteins were incubated with OPs. In the current work, manual inspection of tandem mass spectrometry (MS/MS) data led to the realization that lysines also make a covalent bond with OPs. OP-labeled lysine residues were found in seven proteins that had been treated with either chlorpyrifos oxon (CPO) or diisopropylfluorophosphate (DFP): human serum albumin (K212, K414, K199, and K351), human keratin 1 (K211 and K355), human keratin 10 (K163), bovine tubulin alpha (K60, K336, K163, K394, and K401), bovine tubulin beta (K58), bovine actin (K113, K291, K326, K315, and K328), and mouse transferrin (K296 and K626). These results suggest that OP binding to lysine is a general phenomenon. Characteristic fragments specific for CPO-labeled lysine appeared at 237.1, 220.0, 192.0, 163.9, 128.9, and 83.9 amu. Characteristic fragments specific for DFP-labeled lysine appeared at 164.0, 181.2, and 83.8 amu. This new OP-binding motif to lysine suggests new directions to search for mechanisms of long-term effects of OP exposure and in the search for biomarkers of OP exposure.     

Tracking the cell hierarchy in the human intestine using biochemical signatures derived by mid-infrared microspectroscopy

Markers of gastrointestinal (GI) stem cells remain elusive. We employed synchrotron Fourier-transform infrared (FTIR) microspectroscopy to derive mid-infrared (IR) spectra along the length of human GI crypts. Tissue sections (10-μm thick) were floated onto BaF₂ windows and image maps were acquired of small intestine and large bowel crypts in transmission mode with an aperture of ≤  10 μm × 10 μm. Counting upwards in a step-size (≤ 10 μm) fashion from the crypt base, IR spectra were extracted from the image maps and each spectrum corresponding to a particular location was identified. Spectra were analyzed using principal component analysis plus linear discriminant analysis. Compared to putative crypt base columnar/Paneth cells, those assigned as label-retaining cells were chemically more similar to putative large bowel stem cells and, the small intestine transit-amplifying cells were closest to large bowel transit-amplifying cells; interestingly, the base of small intestine crypts was the most chemically-distinct. This study suggests that in the complex cell lineage of human GI crypts, chemical similarities as revealed by FTIR microspectroscopy between regions putatively assigned as stem cell, transit-amplifying and terminally-differentiated facilitates identification of cell function.     

UV and X‐ray structural studies of a 101‐residue long Tat protein from a HIV‐1 primary isolate and of its mutated,detoxified, vaccine candidate

The 101‐residue long Tat protein of primary isolate 133 of the human immunodeficiency virus type 1 (HIV‐1), wt‐Tat₁₃₃ displays a high transactivation activity in vitro, whereas the mutant thereof, STLA‐Tat₁₃₃, a vaccine candidate for HIV‐1, has none. These two proteins were chemically synthesized and their biological activity was validated. Their structural properties were characterized using circular dichroism (CD), fluorescence emission, gel filtration, dynamic light scattering, and small angle X‐ray scattering (SAXS) techniques. SAXS studies revealed that both proteins were extended and belong to the family of intrinsically unstructured proteins. CD measurements showed that wt‐Tat₁₃₃ or STLA‐Tat₁₃₃ underwent limited structural rearrangements when complexed with specific fragments of antibodies. Crystallization trials have been performed on the two forms, assuming that the Tat₁₃₃ proteins might have a better propensity to fold in supersaturated conditions, and small crystals have been obtained. These results suggest that biologically active Tat protein is natively unfolded and requires only a limited gain of structure for its function. Proteins 2010. © 2009 Wiley‐Liss, Inc