Specific activation of open complex formation at an Escherichia coli promoter by oligo(N-methylpyrrolecarboxamide)s: effects of peptide length and identification of DNA target sites

It has previously been shown that open complex formation at a promoter containing a block substitution of nonalternating A-T sequences in the spacer DNA separating the contacted -10 and -35 regions could be accelerated by distamycin. No stimulation was observed at a promoter with a substitution of alternating A-T base pairs in the same region or at the promoter with wild-type spacer. Here we compare the effect of distamycin [tris(N-methylpyrrolecarboxamide), formally a P3] with that of its extended homologues P4, P5, and P6. It is found that the stimulatory potential of these synthetic oligopeptides which bind in the minor groove of DNA ranks in the order P4 greater than (distamycin, P5) greater than P6. The interaction of these peptides with the three promoters was studied by monitoring the positions of the promoter DNA protected from MPE-Fe(II) cleavage in the presence of different concentrations of ligand. The results suggest that a higher affinity of oligopeptide for the spacer DNA than for the -10 and/or -35 region is a necessary, but not sufficient condition for stimulation. Different patterns of protected DNA regions are seen with each of the three promoters; with distamycin, P4, and P5, a unique arrangement of protected regions is observed for the variant containing nonalternating A-T base pairs in its spacer DNA. These data support the hypothesis that differences in the ways the minor-groove binders interact with each of the promoter variants account for the observed differential stimulation. We further postulate that it is a ligand-induced structural change in the nonalternating A-T DNA which is responsible for the activation of open complex formation at the promoter containing this substitution.     

Mechanism of phosphatidylinositol-specific phospholipase C: origin of unusually high nonbridging thio effects

Phosphatidylinositol-specific phospholipase C (PI-PLC) has been proposed previously to employ a catalytic mechanism highly reminiscent of that of ribonuclease A (RNase A). Both catalytic sites are comprised of two histidine side chains acting as a general base-general acid pair and a phosphate-activating residue: an arginine in the case of PI-PLC and a lysine in RNase A. Despite these structural similarities, the PI-PLC reaction is slowed 10(5)-fold upon substitution of one of the phosphate nonbridging oxygen atoms with sulfur, whereas a much smaller effect is observed in the analogous RNase A reaction. Here, we report a systematic study of this property in PI-PLC, conducted by means of site-directed chemical modification of a cysteine residue replacing the arginine at position 69. The results show that mutant enzymes featuring bidentate side chains at this position display significantly higher activity, higher thio effects, and greater stereoselectivity than do those with monodentate side chains. The results suggest that the bidentate nature of Arg69 is the origin of the large thio effects and stereoselectivity in PI-PLC. We propose that in addition to binding the phosphate, the function of arginine 69 is to bring the phosphate group and the 2-OH group of inositol into proximity and to induce proper alignment for nucleophilic attack, and possibly to lower the pK(a) of the 2-OH. The results presented here could be important to mechanisms of phosphoryl transfer enzymes in general, suggesting that a major part of thio effects observed in enzymatic phosphoryl transfer reactions can originate from factors other than direct interaction between a side chain and a phosphate group, and caution the use of the absolute magnitude of the thio effect as an indicator of the strength of such interactions.     

STING Millennium Suite: integrated software for extensive analyses of 3d structures of proteins and their complexes

Background  

The integration of many aspects of protein/DNA structure analysis is an important requirement for software products in general area of structural bioinformatics. In fact, there are too few software packages on the internet which can be described as successful in this respect. We might say that what is still missing is publicly available, web based software for interactive analysis of the sequence/structure/function of proteins and their complexes with DNA and ligands. Some of existing software packages do have certain level of integration and do offer analysis of several structure related parameters, however not to the extent generally demanded by a user.     

Genome-scale metabolic reconstruction and <Emphasis Type="Italic">in silico</Emphasis> analysis of methylotrophic yeast <Emphasis Type="Italic">Pichia pastoris</Emphasis> for strain improvement

Background  

Pichia pastoris has been recognized as an effective host for recombinant protein production. A number of studies have been reported for improving this expression system. However, its physiology and cellular metabolism still remained largely uncharacterized. Thus, it is highly desirable to establish a systems biotechnological framework, in which a comprehensive in silico model of P. pastoris can be employed together with high throughput experimental data analysis, for better understanding of the methylotrophic yeast's metabolism.     

Apoptosis,cytokine and chemokine induction by non-structural 1 (NS1) proteins encoded by different influenza subtypes

Background

Influenza pandemic remains a serious threat to human health. Viruses of avian origin, H5N1, H7N7 and H9N2, have repeatedly crossed the species barrier to infect humans. Recently, a novel strain originated from swine has evolved to a pandemic. This study aims at improving our understanding on the pathogenic mechanism of influenza viruses, in particular the role of non-structural (NS1) protein in inducing pro-inflammatory and apoptotic responses.

Methods

Human lung epithelial cells (NCI-H292) was used as an in-vitro model to study cytokine/chemokine production and apoptosis induced by transfection of NS1 mRNA encoded by seven infleunza subtypes (seasonal and pandemic H1, H2, H3, H5, H7, and H9), respectively.

Results

The results showed that CXCL-10/IP10 was most prominently induced (> 1000 folds) and IL-6 was slightly induced (< 10 folds) by all subtypes. A subtype-dependent pattern was observed for CCL-2/MCP-1, CCL3/MIP-1α, CCL-5/RANTES and CXCL-9/MIG; where induction by H5N1 was much higher than all other subtypes examined. All subtypes induced a similar temporal profile of apoptosis following transfection. The level of apoptosis induced by H5N1 was remarkably higher than all others. The cytokine/chemokine and apoptosis inducing ability of the 2009 pandemic H1N1 was similar to previous seasonal strains.

Conclusions

In conclusion, the NS1 protein encoded by H5N1 carries a remarkably different property as compared to other avian and human subtypes, and is one of the keys to its high pathogenicity. NCI-H292 cells system proves to be a good in-vitro model to delineate the property of NS1 proteins.

     

Structural and Functional Characterization of an Anesthetic Binding Site in the Second Cysteine-Rich Domain of Protein Kinase Cδ?

Elucidating the principles governing anesthetic-protein interactions requires structural determinations at high resolutions not yet achieved with ion channels. Protein kinase C (PKC) activity is modulated by general anesthetics. We solved the structure of the phorbol-binding domain (C1B) of PKCδ complexed with an ether (methoxymethylcycloprane) and with an alcohol (cyclopropylmethanol) at 1.36-Å resolution. The cyclopropane rings of both agents displace a single water molecule in a surface pocket adjacent to the phorbol-binding site, making van der Waals contacts with the backbone and/or side chains of residues Asn-237 to Ser-240. Surprisingly, two water molecules anchored in a hydrogen-bonded chain between Thr-242 and Lys-260 impart elasticity to one side of the binding pocket. The cyclopropane ring takes part in π-acceptor hydrogen bonds with the amide of Met-239. There is a crucial hydrogen bond between the oxygen atoms of the anesthetics and the hydroxyl of Tyr-236. A Tyr-236-Phe mutation results in loss of binding. Thus, both van der Waals interactions and hydrogen-bonding are essential for binding to occur. Ethanol failed to bind because it is too short to benefit from both interactions. Cyclopropylmethanol inhibited phorbol-ester-induced PKCδ activity, but failed to do so in PKCδ containing the Tyr-236-Phe mutation.     

SR proteins are required for nematode trans-splicing in vitro.

SR (ser/arg) proteins have been shown to play roles in numerous aspects of pre-mRNA splicing, including modulation of alternative splicing, commitment of substrates to the splicing pathway, and splice site communication. The last of these, splice site communication, is particularly relevant to trans-splicing in which the 5' and 3' exons originate on separate molecules. The participation of SR proteins in naturally occurring, spliced leader RNA-dependent transsplicing has not been examined. Here, we have isolated SR proteins from an organism that performs both trans- and cis-splicing, the nematode Ascaris lumbricoides. To examine their activity in in vitro splicing reactions, we have also developed and characterized an SR protein-depleted whole-cell extract. When tested in this extract, the nematode SR proteins are required for both trans- and cis-splicing. In addition, the state of phosphorylation of the nematode SR proteins is critical to their activity in vitro. Interestingly, mammalian (HeLa) and A. lumbricoides SR proteins exhibit equivalent activities in cis-splicing, while the nematode SR proteins are much more active in trans-splicing. Thus, it appears that SR proteins purified from an organism that naturally trans-splices its pre-mRNAs promote this reaction to a greater extent than do their mammalian counterparts.     

Polymer optoelectronic structures for retinal prosthesis

This commentary highlights the effectiveness of optoelectronic properties of polymer semiconductors based on recent results emerging from our laboratory, where these materials are explored as artificial receptors for interfacing with the visual systems. Organic semiconductors based polymer layers in contact with physiological media exhibit interesting photophysical features, which mimic certain natural photoreceptors, including those in the retina. The availability of such optoelectronic materials opens up a gateway to utilize these structures as neuronal interfaces for stimulating retinal ganglion cells. In a recently reported work entitled “A polymer optoelectronic interface provides visual cues to a blind retina,” we utilized a specific configuration of a polymer semiconductor device structure to elicit neuronal activity in a blind retina upon photoexcitation. The elicited neuronal signals were found to have several features that followed the optoelectronic response of the polymer film. More importantly, the polymer-induced retinal response resembled the natural response of the retina to photoexcitation. These observations open up a promising material alternative for artificial retina applications.     

Multiple Propofol-binding Sites in a γ-Aminobutyric Acid Type A Receptor (GABAAR) Identified Using a Photoreactive Propofol Analog

Propofol acts as a positive allosteric modulator of γ-aminobutyric acid type A receptors (GABA_ARs), an interaction necessary for its anesthetic potency in vivo as a general anesthetic. Identifying the location of propofol-binding sites is necessary to understand its mechanism of GABA_AR modulation. [³H]2-(3-Methyl-3H-diaziren-3-yl)ethyl 1-(phenylethyl)-1H-imidazole-5-carboxylate (azietomidate) and R-[³H]5-allyl-1-methyl-5-(m-trifluoromethyl-diazirynylphenyl)barbituric acid (mTFD-MPAB), photoreactive analogs of 2-ethyl 1-(phenylethyl)-1H-imidazole-5-carboxylate (etomidate) and mephobarbital, respectively, have identified two homologous but pharmacologically distinct classes of intersubunit-binding sites for general anesthetics in the GABA_AR transmembrane domain. Here, we use a photoreactive analog of propofol (2-isopropyl-5-[3-(trifluoromethyl)-3H-diazirin-3-yl]phenol ([³H]AziPm)) to identify propofol-binding sites in heterologously expressed human α1β3 GABA_ARs. Propofol, AziPm, etomidate, and R-mTFD-MPAB each inhibited [³H]AziPm photoincorporation into GABA_AR subunits maximally by ∼50%. When the amino acids photolabeled by [³H]AziPm were identified by protein microsequencing, we found propofol-inhibitable photolabeling of amino acids in the β3-α1 subunit interface (β3Met-286 in β3M3 and α1Met-236 in α1M1), previously photolabeled by [³H]azietomidate, and α1Ile-239, located one helical turn below α1Met-236. There was also propofol-inhibitable [³H]AziPm photolabeling of β3Met-227 in βM1, the amino acid in the α1-β3 subunit interface photolabeled by R-[³H]mTFD-MPAB. The propofol-inhibitable [³H]AziPm photolabeling in the GABA_AR β3 subunit in conjunction with the concentration dependence of inhibition of that photolabeling by etomidate or R-mTFD-MPAB also establish that each anesthetic binds to the homologous site at the β3-β3 subunit interface. These results establish that AziPm as well as propofol bind to the homologous intersubunit sites in the GABA_AR transmembrane domain that binds etomidate or R-mTFD-MPAB with high affinity.