Nitric oxide in fruit ripening: Trends and opportunities

Monitoring ethylene is crucial in regulating post-harvest life of fruits. The concept of nitric oxide (NO) involvement in antagonizing ethylene is new. NO mediated physiologies casted through regulation of plant hormones are widely reported during developmental and stress chemistry having no direct link with ripening. Research in NO biology and understanding its interplay with other signal molecules in ripening fruits suggest ways of achieving greater synergies with NO applications. Experiments focused at convincingly demonstrating the involvement of NO in altering ripening-related ethylene profile of fruits, would help develop new processes for shelf life extension. This issue being the central theme of this review, the putative mechanisms of NO intricacies with other primary and secondary signals are hypothesized. The advantage of eliciting NO endogenously may open up various biotechnological opportunities for its precise delivery into the target tissues.     

Allosteric effects of the antipsychotic drug trifluoperazine on the energetics of calcium binding by calmodulin

Trifluoperazine (TFP; Stelazine?) is an antagonist of calmodulin (CaM), an essential regulator of calcium‐dependent signal transduction. Reports differ regarding whether, or where, TFP binds to apo CaM. Three crystallographic structures (1CTR, 1A29, and 1LIN) show TFP bound to (Ca²⁺)₄‐CaM in ratios of 1, 2, or 4 TFP per CaM. In all of these, CaM domains adopt the “open” conformation seen in CaM‐kinase complexes having increased calcium affinity. Most reports suggest TFP also increases calcium affinity of CaM. To compare TFP binding to apo CaM and (Ca²⁺)₄‐CaM and explore differential effects on the N‐ and C‐domains of CaM, stoichiometric TFP titrations of CaM were monitored by ¹⁵N‐HSQC NMR. Two TFP bound to apo CaM, whereas four bound to (Ca²⁺)₄‐CaM. In both cases, the preferred site was in the C‐domain. During the titrations, biphasic responses for some resonances suggested intersite interactions. TFP‐binding sites in apo CaM appeared distinct from those in (Ca²⁺)₄‐CaM. In equilibrium calcium titrations at defined ratios of TFP:CaM, TFP reduced calcium affinity at most levels tested; this is similar to the effect of many IQ‐motifs on CaM. However, at the highest level tested, TFP raised the calcium affinity of the N‐domain of CaM. A model of conformational switching is proposed to explain how TFP can exert opposing allosteric effects on calcium affinity by binding to different sites in the “closed,” “semi‐open,” and “open” domains of CaM. In physiological processes, apo CaM, as well as (Ca²⁺)₄‐CaM, needs to be considered a potential target of drug action. Proteins 2010. © 2010 Wiley‐Liss, Inc.     

Identification of protein stability determinants in chloroplasts

Although chloroplast protein stability has long been recognised as a major level of post‐translational regulation in photosynthesis and gene expression, the factors determining protein stability in plastids are largely unknown. Here, we have identified stability determinants in vivo by producing plants with transgenic chloroplasts that express a reporter protein whose N‐ and C‐termini were systematically modified. We found that major stability determinants are located in the N‐terminus. Moreover, testing of all 20 amino acids in the position after the initiator methionine revealed strong differences in protein stability and indicated an important role of the penultimate N‐terminal amino acid residue in determining the protein half life. We propose that the stability of plastid proteins is largely determined by three factors: (i) the action of methionine aminopeptidase (the enzyme that removes the initiator methionine and exposes the penultimate N‐terminal amino acid residue), (ii) an N‐end rule‐like protein degradation pathway, and (iii) additional sequence determinants in the N‐terminal region.     

A new modified Edman procedure for analysis of N-terminal valine adducts in hemoglobin by LC–MS/MS

A rapid and sensitive method using liquid chromatography–tandem mass spectrometry (LC–MS/MS) for simultaneous determination of adducts from acrylamide, glycidamide and ethylene oxide to N-terminal valines in hemoglobin (Hb) was developed. This new procedure is based on the same principles as the N-alkyl Edman procedure for analysis of adducts from electrophilic agents to N-terminal valines in Hb. The N-substituted valines can be detached, enriched and measured selectively as thiohydantoins by the use of an Edman reagent, in this case fluorescein isothiocyanate (FITC). This procedure is denoted as the “adduct FIRE procedure” as the FITC reagent is used for measurement of adducts (R) formed from electrophilic compounds with a modified Edman procedure. In this study, fluorescein thiohydantoin (FTH) analytes of N-substituted valines from acrylamide, glycidamide and ethylene oxide, as well as their corresponding hepta- and tri-deuterium-substituted analogues, were synthesized. These analytes (n = 8) were then characterized by LC–MS/MS (ESI, positive ion mode) and obtained product ions were interpreted. A considerable work with optimization of the FIRE procedure™, resulted in a procedure in which low background levels of the studied adducts could be measured from 250 μL lyzed whole blood samples (human non-smokers). The analytes were enriched and purified with solid phase extraction columns and analyzed by LC–MS/MS with LOQ down to 1 pmol adduct/g Hb. Compared to other procedures for determination of N-terminal Hb adducts, the introduction of FITC has led to a simplified procedure, where whole blood also can be used, giving new opportunities and reduced hand on time with increased sample throughput.     

Strategy for comprehensive identification of human N‐myristoylated proteins using an insect cell‐free protein synthesis system

To establish a strategy for the comprehensive identification of human N‐myristoylated proteins, the susceptibility of human cDNA clones to protein N‐myristoylation was evaluated by metabolic labeling and MS analyses of proteins expressed in an insect cell‐free protein synthesis system. One‐hundred‐and‐forty‐one cDNA clones with N‐terminal Met‐Gly motifs were selected as potential candidates from ～2000 Kazusa ORFeome project human cDNA clones, and their susceptibility to protein N‐myristoylation was evaluated using fusion proteins, in which the N‐terminal ten amino acid residues were fused to an epitope‐tagged model protein. As a result, the products of 29 out of 141 cDNA clones were found to be effectively N‐myristoylated. The metabolic labeling experiments both in an insect cell‐free protein synthesis system and in the transfected COS‐1 cells using full‐length cDNA revealed that 27 out of 29 proteins were in fact N‐myristoylated. Database searches with these 27 cDNA clones revealed that 18 out of 27 proteins are novel N‐myristoylated proteins that have not been reported previously to be N‐myristoylated, indicating that this strategy is useful for the comprehensive identification of human N‐myristoylated proteins from human cDNA resources.     

Structural and functional analysis of NS1 and NS2 proteins of H1N1 subtype

Influenza A virus (H1N1), a genetic reassortment of endemic strains of human, avian and swine flu, has crossed species barrier to human and apparently acquired the capability of human to human transmission. Some strains of H5N1 subtype are highly virulent because NS1 protein inhibits antiviral interferon α/β production. Another protein NS2 mediates export of viral ribonucleoprotein from nucleus to the cytoplasm through export signal. In this paper, we have studied structure-function relationships of these proteins of H1N1 subtype and have determined the cause of their pathogenicity. Our results showed that non-conservative mutations slightly stabilized or destabi- lized structural domains of NS1 or NS1-dsRNA complex, hence slightly increased or decreased the function of NS1 protein and consequently enhanced or reduced the pathogenicity of the H1N1 virus. NS2 protein of different strains carried non-conservative mutations in different domains, resulting in slight loss of function. These mutations slightly decreased the pathogenicity of the virus. Thus, the results confirm the structure-function relationships of these viral proteins.     

Gene cloning and expression of aminopeptidase N and cadherin from midgut of the rice stem borer,Chilo suppressalis

Abstract The rice stem borer, Chilo suppressalis Walker is one of the most important insect pests on rice in Asia, north Africa and southern Europe. Transgenic Bt rice has been developed in the laboratory with good resistance to this pest and other Lepidopteran insects, which will provide a possible alternative tool for this pest control. The full-length cDNAs encoding an aminopeptidase N (CsAPN) and a cadherin (CsCad) were cloned from C. suppressalis. CsAPN showed common features of, and high identities to, other insect APNs in its deduced amino acid sequence. Although a full-length cDNA encoding cadherin-like protein has been reported in GenBank, the newly isolated cadherin here (CsCad) showed some differences in its amino acid sequence, especially at the 7th cadherin repeat region (CR7), which indicated the newly isolated CsCad might be another allele. CsAPN and CsCad were successfully expressed in insect Tn cells, and the blot analysis showed these two proteins could bind Bt toxin Cry1Ab. The results will provide valuable information for the studies of toxin mode of action and the possible toxin resistance mechanisms in this pest.     

How does a valine residue that modulates heme-NO binding kinetics in inducible NO synthase regulate enzyme catalysis?

Nitric oxide (NO) release from nitric oxide synthases (NOSs) depends on the dissociation of a ferric heme-NO product complex (Fe^IIINO) that forms immediately after NO is made in the heme pocket. The NOS-like enzyme of Bacillus subtilis (bsNOS) has 10-20 fold slower Fe^IIINO dissociation rate (k_d) and NO association rate (k_on) compared to mammalian NOS counterparts. We previously showed that an Ile for Val substitution at the opening of the heme pocket in bsNOS contributes to these differences. The complementary mutation in mouse inducible NOS oxygenase domain (Val346Ile) decreased the NO k_on and k_d by 8 and 3-fold, respectively, compared to wild-type iNOSoxy, and also slowed the reductive processing of the heme-O₂ catalytic intermediate. To investigate how these changes affect steady-state catalytic behaviors, we generated and characterized the V346I mutant of full-length inducible NOS (iNOS). The mutant exhibited a 4-5 fold lower NO synthesis activity, an apparent uncoupled NADPH consumption, and formation of a heme-NO complex during catalysis that was no longer sensitive to solution NO scavenging. We found that these altered catalytic behaviors were not due to changes in the heme reduction rate or in the stability of the enzyme heme-O₂ intermediate, but instead were due to the slower NO k_on and k_d and a slower oxidation rate of the enzyme ferrous heme-NO complex. Computer simulations that utilized the measured kinetic values confirmed this interpretation, and revealed that the V346I iNOS has an enhanced NADPH-dependent NO dioxygenase activity that converts almost 1 NO to nitrate for every NO that the enzyme releases into solution. Together, our results highlight the importance of heme pocket geometry in tuning the NO release versus NO dioxygenase activities of iNOS.     

Kinetic model of the inhibition of respiration by endogenous nitric oxide in intact cells

Nitric oxide (NO) inhibits mitochondrial respiration by decreasing the apparent affinity of cytochrome c oxidase (CcO) for oxygen. Using iNOS-transfected HEK 293 cells to achieve regulated intracellular NO production, we determined NO and O₂ concentrations and mitochondrial O₂ consumption by high-resolution respirometry over a range of O₂ concentrations down to nanomolar. Inhibition of respiration by NO was reversible, and complete NO removal recovered cell respiration above its routine reference values. Respiration was observed even at high NO concentrations, and the dependence of IC₅₀ on [O₂] exhibits a characteristic but puzzling parabolic shape; both these features imply that CcO is protected from complete inactivation by NO and are likely to be physiologically relevant. We present a kinetic model of CcO inhibition by NO that efficiently predicts experimentally determined respiration at physiological O₂ and NO concentrations and under hypoxia, and accurately predicts the respiratory responses under hyperoxia. The model invokes competitive and uncompetitive inhibition by binding of NO to the reduced and oxidized forms of CcO, respectively, and suggests that dissociation of NO from reduced CcO may involve its O₂-dependent oxidation. It also explains the non-linear dependence of IC₅₀ on O₂ concentration, and the hyperbolic increase of c₅₀ as a function of NO concentration.