In vivo and in vitro processing of recombinant pro-von Willebrand factor

Von Willebrand factor (vWF) is synthesized in endothelial cells as pre-pro-vWF and processed intracellularly to propeptide (vWFpp) and mature vWF. Recombinant pro-vWF when infused into animals can also be processed extracellularly in vivo. Within 1 h of infusion in a dog and mice the multimer pattern changed to that typically seen in mature vWF indicating that propeptide cleavage from unprocessed vWF occurs extracellularly in the circulation. Incubation of a recombinant pro-vWF preparation with canine and human vWF-deficient plasma induced a time-dependent decrease in pro-vWF antigen and an increase in vWFpp antigen without changing total vWF antigen or collagen-binding activity. Multimer analysis showed the gradual transformation of the pro-vWF multimers to mature vWF multimers and cleaved vWFpp was visualized on autoradiograms of SDS-polyacrylamide electrophoresis gels using (125)I-labeled pro-vWF. When recombinant pro-vWF was incubated with increasing amounts of purified thrombin, the extent of pro-vWF processing was dose dependent. The specific cleavage of vWFpp was confirmed by immunoblots using an anti-vWFpp antibody and by amino-terminal amino acid analysis. Hirudin preconditioning of vWF-deficient mice attenuated processing of infused recombinant pro-vWF suggesting that thrombin plays a part in the processing events in vivo.     

In vivo production of artificial nonribosomal peptide products in the heterologous host Escherichia coli

Nonribosomal peptide synthetases represent the enzymatic assembly lines for the biosynthesis of pharmacologically relevant natural peptides, e.g., cyclosporine, vancomycin, and penicillin. Due to their modular organization, in which every module accounts for the incorporation of a single amino acid, artificial assembly lines for the production of novel peptides can be constructed by biocombinatorial approaches. Once transferred into an appropriate host, these hybrid synthetases could facilitate the bioproduction of basically any peptide-based molecule. In the present study, we describe the fermentative production of the cyclic dipeptide D-Phe-Pro-diketopiperazine, as a prototype for the exploitation of the heterologous host Escherichia coli, and the use of artificial nonribosomal peptide synthetases. E. coli provides a tremendous potential for genetic engineering and was manipulated in our study by stable chromosomal integration of the 4'-phosphopantetheine transferase gene sfp to ensure heterologous production of fully active holoenzmyes. D-Phe-Pro-diketopiperazine is formed by the TycA/TycB1 system, whose components represent the first two modules for tyrocidine biosynthesis in Bacillus brevis. Coexpression of the corresponding genes in E. coli gave rise to the production of the expected diketopiperazine product, demonstrating the functional interaction of both modules in the heterologous environment. Furthermore, the cyclic dipeptide is stable and not toxic to E. coli and is secreted into the culture medium without the need for any additional factors. Parameters affecting the productivity were comprehensively investigated, including various genetic setups, as well as variation of medium composition and temperature. By these means, the overall productivity of the artificial system could be enhanced by over 400% to yield about 9 mg of D-Phe-Pro-diketopiperazine/liter. As a general tool, this approach could allow the sustainable bioproduction of peptides, e.g., those used as pharmaceuticals or fine chemicals.     

In vivo and in vitro interaction of DnaK and a chloroplast transit peptide

Chloroplast transit peptides have been proposed to function as substrates for Hsp70 molecular chaperones. Many models of chloroplast protein import depict Hsp70s as the translocation motors that drive protein import into the organelle, but to our knowledge, no direct evidence has demonstrated that transit peptides function either in vivo or in vitro as substrates for the chaperone. In this report, we demonstrate that DnaK binds SStp (the full-length transit peptide for the precursor to the small subunit of Rubisco) in vivo when fused to either glutathione-S-transferase (GST) or to an His6-S-peptide tag (His-S) via an ATP-dependent mechanism. Three independent biophysical and biochemical assays confirm the ability of DnaK and SStp to interact in vitro. The cochaperones, DnaJ and GrpE, were also associated with the DnaK/SStp complex. Therefore, both GST-SStp and His-S-SStp can be used as affinity-tagged substrates to study prokaryotic chaperone/transit peptide interactions as well as to provide a novel functional probe to study the dynamics of DnaK/DnaJ/GrpE interactions in vivo. The combination of these results provides the first experimental support for a transit peptide-dependent interaction between a chloroplast precursor and Hsp70. These results are discussed in light of a general mechanism for protein translocation into chloroplasts and mitochondria.     

Comparative aspects of intracellular proteolytic processing of peptide hormone precursors: studies of proopiomelanocortin processing

In this review, the mechanisms underlying the intracellular processing of peptide hormone precursors, with a focus on proopiomelanocortin (POMC), were discussed on the basis of recent information. POMC as well as other prohormones is processed to active peptides through proteolytic cleavage by prohormone convertases PC1 and/or PC2. However, the cleavage-specificity of PC1 and PC2 in mammals is somewhat different from that in amphibians. From the comparative endocrinological point of view, expression and tissue distribution of PC1 and PC2 were discussed here. In mammals, proteolytic processing of POMC occurs coordinately with the maturation of secretory granules. Studies using immunoelectron microscopy with DAMP (3-[2,4-dinitroanilino]-3'-amino-N-methyldipropylamine) as a pH probe revealed that the acidic pH in the secretory granules, generated by vacular type-H+-ATPase, provides a favorable environment for activating PC1 in AtT-20 cells, a mouse corticotrope tumor cell line. Recent data indicate that the 7B2 protein serves as a chaperone in the regulation of PC2 activation and to control the timing for activating the convertase. Together, secretory granules in endocrine and neuroendocrine cells provide proper sites for biosynthesizing hormones in addition to serving as storage sites and vehicles for the transport of peptide hormones.     

In vitro and in vivo activity of an antibacterial peptide analog against uropathogens

The alarming rate of bacterial resistance induction highlights the clinical need for antimicrobial agents that act by novel modes of action. Based on the activity profile, the general tissue distribution and renal clearance of peptide-based drugs, we hypothesized that our newly developed pyrrhocoricin derivative would be able to fight resistant uropathogens in vitro and in vivo. Indeed, the Pip-pyrr-MeArg dimer killed all 11 urinary tract infection-related Escherichia coli and Klebsiella pneumoniae strains we studied in the sub-low micromolar concentration range. Almost all control antibiotics, including the currently leading trimethoprim-sulfametoxazole combination for urinary tract infection, remained without considerable activity against two or more of these bacterial strains. In a mouse ascending urinary tract infection model with E. coli CFT073 as pathogen, two doses of intravenous, subcutaneous or oral treatment with the Pip-pyrr-MeArg derivative reduced the bacterial counts in the kidneys, bladder and urine to varying levels. Statistically significant elimination or reduction of bacteria compared to untreated animals was observed at dual intravenous or subcutaneous doses of 0.4 or 10mg/kg, respectively. Serial passage of the same E. coli strain in the presence of sublethal doses of the designed peptide failed to generate resistant mutants. The Pip-pyrr-MeArg dimer showed no toxicity to COS-7 cells to the highest 500microM concentration studied.     

In vivo and in vitro studies of phage T4 lysozyme mRNA translation]

Translation of phage T4 lysozyme mRNA is studied in vivo and in vitro. Polyribosomes, carrying growing lysozyme polypeptides, are found to be homogenous enough and to contain 6 ribosomes. Complete molecules of phage lysozyme, which possess an enzymatic activity and are similar to the native enzyme in its electrophoretic mobility in polyacrylamide gel, have been synthetized in vitro on RNA isolated from phage-infected cells. The efficiency of RNA translation in cell-free system is discussed on the model of synthesis of functionally active individual protein.     

In vitro and in vivo degradation of Abeta peptide by peptidases coupled to erythrocytes

It is generally believed that amyloid β peptides (Aβ) are the key mediators of Alzheimer's disease. Therapeutic interventions have been directed toward impairing the synthesis or accelerating the clearance of Aβ. An equilibrium between blood and brain Aβ exists mediated by carriers that transport Aβ across the blood–brain barrier. Passive immunotherapy has been shown to be effective in mouse models of AD, where the plasma borne antibody binds plasma Aβ causing an efflux of Aβ from the brain. As an alternative to passive immunotherapy we have considered the use of Aβ-degrading peptidases to lower plasma Aβ levels. Here we compare the ability of three Aβ-degrading peptidases to degrade Aβ. Biotinylated peptidases were coupled to the surface of biotinylated erythrocytes via streptavidin. These erythrocyte-bound peptidases degrade Aβ peptide in plasma. Thus, peptidases bound to or expressed on the surface of erythroid cells represent an alternative to passive immunotherapy.     

In vitro selection of a peptide with high selectivity for cardiomyocytes in vivo

One approach to targeted therapies for cardiovascular disease relies on isolating ligands that enhance the tissue-specific uptake of genes or drugs by heart cells. To obtain heart-targeting ligands, phage display biopanning was used to isolate a 20-mer peptide that binds to isolated primary cardiomyocytes. The isolated phage, PCM.1, displays the peptide WLSEAGPVVTVRALRGTGSW, and binds these cells 180 times better than a control phage from the library. Furthermore, phage displaying this peptide preferentially bind to cardiomyocytes when compared with a panel of other cell types. A BLAST search revealed that this peptide contains a 12 amino acid segment with sequence identity to a peptide in tenascin-X, an extracellular matrix protein. Synthetic peptides containing the complete 20-mer or a 12-mer tenascin peptide partially blocked phage binding to the cardiomyocytes. We developed a quantitative real-time PCR assay to assess uptake of this phage by tissues in vivo. Using this assay, preferential localization of the PCM.1 phage in heart was observed compared to the uptake of this phage by other tissues or other phage by heart. Furthermore, PCM.1 phage was associated with cardiomyocytes isolated from mice treated with a phage in vivo. These results demonstrate the utility of biopanning on isolated cells for identifying specific binding peptides that can target a tissue in vivo.     

In vivo fate analysis reveals the multipotent and self-renewal features of embryonic AspM expressing cells

Radial Glia (RG) cells constitute the major population of neural progenitors of the mouse developing brain. These cells are located in the ventricular zone (VZ) of the cerebral cortex and during neurogenesis they support the generation of cortical neurons. Later on, during brain maturation, RG cells give raise to glial cells and supply the adult mouse brain of Neural Stem Cells (NSC). Here we used a novel transgenic mouse line expressing the CreER(T2) under the control of AspM promoter to monitor the progeny of an early cohort of RG cells during neurogenesis and in the post natal brain. Long term fate mapping experiments demonstrated that AspM-expressing RG cells are multi-potent, as they can generate neurons, astrocytes and oligodendrocytes of the adult mouse brain. Furthermore, AspM descendants give also rise to proliferating progenitors in germinal niches of both developing and post natal brains. In the latter--i.e. the Sub Ventricular Zone--AspM descendants acquired several feature of neural stem cells, including the capability to generate neurospheres in vitro. We also performed the selective killing of these early progenitors by using a Nestin-GFP(flox)-TK allele. The forebrain specific loss of early AspM expressing cells caused the elimination of most of the proliferating cells of brain, a severe derangement of the ventricular zone architecture, and the impairment of the cortical lamination. We further demonstrated that AspM is expressed by proliferating cells of the adult mouse SVZ that can generate neuroblasts fated to become olfactory bulb neurons.     

The Caenorhabditis elegans mRNA 5'-capping enzyme. In vitro and in vivo characterization

Eukaryotic mRNA capping enzymes are bifunctional, carrying both RNA triphosphatase (RTPase) and guanylyltransferase (GTase) activities. The Caenorhabditis elegans CEL-1 capping enzyme consists of an N-terminal region with RTPase activity and a C-terminal region that resembles known GTases, However, CEL-1 has not previously been shown to have GTase activity. Cloning of the cel-1 cDNA shows that the full-length protein has 623 amino acids, including an additional 38 residues at the C termini and 12 residues at the N termini not originally predicted from the genomic sequence. Full-length CEL-1 has RTPase and GTase activities, and the cDNA can functionally replace the capping enzyme genes in Saccharomyces cerevisiae. The CEL-1 RTPase domain is related by sequence to protein-tyrosine phosphatases; therefore, mutagenesis of residues predicted to be important for RTPase activity was carried out. CEL-1 uses a mechanism similar to protein-tyrosine phosphatases, except that there was not an absolute requirement for a conserved acidic residue that acts as a proton donor. CEL-1 shows a strong preference for RNA substrates of at least three nucleotides in length. RNA-mediated interference in C. elegans embryos shows that lack of CEL-1 causes development to arrest with a phenotype similar to that seen when RNA polymerase II elongation activity is disrupted. Therefore, capping is essential for gene expression in metazoans.     

In vivo and in vitro analysis of cardiac troponin I phosphorylation

Adrenergic stimulation induces positive changes in cardiac contractility and relaxation. Cardiac troponin I is phosphorylated at different sites by protein kinase A and protein kinase C, but the effects of these post-translational modifications on the rate and extent of contractility and relaxation during beta-adrenergic stimulation in the intact animal remain obscure. To investigate the effect(s) of complete and chronic cTnI phosphorylation on cardiac function, we generated transgenic animals in which the five possible phosphorylation sites were replaced with aspartic acid, mimicking a constant state of complete phosphorylation (cTnI-AllP). We hypothesized that chronic and complete phosphorylation of cTnI might result in increased morbidity or mortality, but complete replacement with the transgenic protein was benign with no detectable pathology. To differentiate the effects of the different phosphorylation sites, we generated another mouse model, cTnI-PP, in which only the protein kinase A phosphorylation sites (Ser(23)/Ser(24)) were mutated to aspartic acid. In contrast to the cTnIAllP, the cTnI-PP mice showed enhanced diastolic function under basal conditions. The cTnI-PP animals also showed augmented relaxation and contraction at higher heart rates compared with the nontransgenic controls. Nuclear magnetic resonance amide proton/nitrogen chemical shift analysis of cardiac troponin C showed that, in the presence of cTnI-AllP and cTnI-PP, the N terminus exhibits a more closed conformation, respectively. The data show that protein kinase C phosphorylation of cTnI plays a dominant role in depressing contractility and exerts an antithetic role on the ability of protein kinase A to increase relaxation.     

In vitro selection of state-specific peptide modulators of G protein signaling using mRNA display

The G protein regulatory (GPR) motif is a approximately 20-residue conserved domain that acts as a guanine dissociation inhibitor (GDI) for G(i/o)(alpha) subunits. Here, we describe the isolation of peptides derived from a GPR consensus sequence using mRNA display selection libraries. Biotinylated G(i)(alpha)(1), modified at either the N or C terminus, serves as a high-affinity binding target for mRNA-displayed GPR peptides. In vitro selection using mRNA display libraries based on the C terminus of the GPR motif revealed novel peptide sequences with conserved residues. Surprisingly, selected peptides contain mutations to a highly conserved Arg in the GPR motif, previously shown to be crucial for binding and inhibition activities. The dominant peptide from the selection, R6A, and a minimal 9-mer peptide, R6A-1, do not contain Arg residues yet retain high affinity (K(D) = 60 and 200 nM, respectively) and specificity for the GDP-bound state of G(i)(alpha)(1), as measured by surface plasmon resonance. The selected peptides also maintain GDI activity for G(i)(alpha)(1), inhibiting both the exchange of GDP in GTPgammaS binding assays and the AlF(4)(-)-stimulated enhancement of intrinsic tryptophan fluorescence. The kinetics of GDI activity, however, are different for the selected peptides and demonstrate biphasic kinetics, suggesting a complex mechanism for inhibition. Like the GPR motif, the R6A and R6A-1 peptides compete with G(betagamma) subunits for binding to G(i)(alpha)(1), suggesting their use as activators of G(betagamma) signaling.     

In vivo bioluminescence for tracking cell fate and function

Tracking the fate and function of cells in vivo is paramount for the development of rational therapies for cardiac injury. Bioluminescence imaging (BLI) provides a means for monitoring physiological processes in real time, ranging from cell survival to gene expression to complex molecular processes. In mice and rats, BLI provides unmatched sensitivity because of the absence of endogenous luciferase expression in mammalian cells and the low background luminescence emanating from animals. In the field of stem cell therapy, BLI provides an unprecedented means to monitor the biology of these cells in vivo, giving researchers a greater understanding of their survival, migration, immunogenicity, and potential tumorigenicity in a living animal. In addition to longitudinal monitoring of cell survival, BLI is a useful tool for semiquantitative measurements of gene expression in vivo, allowing a better optimization of drug and gene therapies. Overall, this technology not only enables rapid, reproducible, and quantitative monitoring of physiological processes in vivo but also can measure the influences of therapeutic interventions on the outcome of cardiac injuries.     

Analysis of human papillomavirus type 16 late mRNA 3' processing signals in vitro and in vivo.

In the human papillomavirus type 16 genome, three late mRNA putative 3' processing signals, designated LP1, LP2, and LP3, are located downstream of the late coding region. Our results show, both in vitro and in vivo, that in HeLa cells, the LP2 signal functions. Thus, the restriction in human papillomavirus type 16 late-gene expression observed in HeLa cells and other nondifferentiated epithelial cells is not achieved by regulation of late mRNA poly(A) site usage. Interestingly, alteration of three nucleotides in the GU-rich downstream sequence element converts the nonfunctional LP1 to an efficient 3' processing site, suggesting that LP1 may function in cell types other than HeLa, such as differentiated keratinocytes. Our transfection studies have identified a negative regulatory element located immediately upstream of the late mRNA 3' processing signals; this element was not associated with any alteration in 3' processing and may act as an mRNA instability element.