High-performance liquid chromatographic determination of vinorelbine in human plasma and blood: application to a pharmacokinetic study

A sensitive and specific high-performance liquid chromatographic method with fluorescence detection (excitation wavelength: 280 nm; emission wavelength: 360 nm) was developed and validated for the determination of vinorelbine in plasma and blood samples. The sample pretreatment procedure involved two liquid–liquid extraction steps. Vinblastine served as the internal standard. The system uses a Spherisorb cyano analytical column (250×4.6 mm I.D.) packed with 5 μm diameter particles as the stationary phase and a mobile phase of acetonitrile–80 mM ammonium acetate (50:50, v/v) adjusted to pH 2.5 with hydrochloric acid. The assay showed linearity from 1 to 100 ng/ml in plasma and from 2.5 to 100 ng/ml in blood. The limits of quantitation were 1 ng/ml and 2.5 ng/ml, respectively. Precision expressed as RSD was in the range 3.9 to 20% (limit of quantitation). Accuracy ranged from 92 to 120%. Extraction recoveries from plasma and blood averaged 101 and 75%, respectively. This method was used to follow the time course of the concentration of vinorelbine in human plasma and blood samples after a 10-min infusion period of 20 mg/m² of this drug in patients with metastatic cancer.     

Identification of essential amino acid residues in a sterol 8,7-isomerase from Zea mays reveals functional homology and diversity with the isomerases of animal and fungal origin

A putative 8,7SI (sterol 8,7-isomerase) from Zea mays, termed Zm8,7SI, has been isolated from an EST (expressed sequence tag) library and subcloned into the yeast erg2 mutant lacking 8,7SI activity. Zm8,7SI restored endogenous ergosterol synthesis. An in vitro enzymatic assay in the corresponding yeast microsomal extract indicated that the preferred Delta(8)-sterol substrate possesses a single C4alpha methyl group, in contrast with 8,7SIs from animals and fungi, thus reflecting the diversity in the structure of their active site in relation to the distinct sterol biosynthetic pathways. In accordance with the proposed catalytic mechanism, a series of lipophilic ammonium-ion-containing derivatives possessing a variety of structures and biological properties, potently inhibited the Zm8,7SI in vitro. To evaluate the importance of a series of conserved acidic and tryptophan residues which could be involved in the Zm8,7SI catalytic mechanism, 20 mutants of Zm8,7SI were constructed as well as a number of corresponding mutants of the Saccharomyces cerevisiae 8,7SI. The mutated isomerases were assayed in vivo by sterol analysis and quantification of Delta(5,7)-sterols and directly in vitro by examination of the activities of the recombinant Zm8,7SI mutants. These studies have identified His(74), Glu(78), Asp(107), Glu(121), Trp(66) and Trp(193) that are required for Zm8,7SI activity and show that binding of the enzyme-substrate complex is impaired in the mutant T124I. They underline the functional homology between the plant and animal 8,7SIs on one hand, in contrast with the yeast 8,7SI on the other hand, in accordance with their molecular diversity and distinct mechanisms.     

Stt7-dependent Phosphorylation during State Transitions in the Green Alga Chlamydomonas reinhardtii

Photosynthetic organisms are able to adapt to changes in light conditions by balancing the light excitation energy between the light-harvesting systems of photosystem (PS) II and photosystem I to optimize the photosynthetic yield. A key component in this process, called state transitions, is the chloroplast protein kinase Stt7/STN7, which senses the redox state of the plastoquinone pool. Upon preferential excitation of photosystem II, this kinase is activated through the cytochrome b₆f complex and required for the phosphorylation of the light-harvesting system of photosystem II, a portion of which migrates to photosystem I (state 2). Preferential excitation of photosystem I leads to the inactivation of the kinase and to dephosphorylation of light-harvesting complex (LHC) II and its return to photosystem II (state 1). Here we compared the thylakoid phosphoproteome of the wild-type strain and the stt7 mutant of Chlamydomonas under state 1 and state 2 conditions. This analysis revealed that under state 2 conditions several Stt7-dependent phosphorylations of specific Thr residues occur in Lhcbm1/Lhcbm10, Lhcbm4/Lhcbm6/Lhcbm8/Lhcbm9, Lhcbm3, Lhcbm5, and CP29 located at the interface between PSII and its light-harvesting system. Among the two phosphorylation sites detected specifically in CP29 under state 2, one is Stt7-dependent. This phosphorylation may play a crucial role in the dissociation of CP29 from PSII and/or in its association to PSI where it serves as a docking site for LHCII in state 2. Moreover, Stt7 was required for the phosphorylation of the thylakoid protein kinase Stl1 under state 2 conditions, suggesting the existence of a thylakoid protein kinase cascade. Stt7 itself is phosphorylated at Ser⁵³³ in state 2, but analysis of mutants with a S533A/D change indicated that this phosphorylation is not required for state transitions. Moreover, we also identified phosphorylation sites that are redox (state 2)-dependent but independent of Stt7 and additional phosphorylation sites that are redox-independent.The primary photochemical reactions of photosynthesis are catalyzed by the pigment-protein complexes photosystem II (PSII)¹ and PSI (PSI), which are linked in series through the plastoquinone pool, the cytochrome b₆f complex, and plastocyanin in the thylakoid membranes. Upon light absorption by the antenna systems of PSII and PSI, charge separations occur across the membrane that lead to the oxidation of water by PSII and electron flow to PSI and ultimately to the reduction of NADP⁺. Because the antenna systems of PSII and PSI have different pigment composition, they are differentially sensitized upon changes in light quality and quantity. However, photosynthetic organisms have the ability to adapt to changes in light. They balance energy input and consumption in the short term through dissipation of excess absorbed light energy into heat through non-photochemical quenching and regulate absorption of excitation energy between PSII and PSI through state transitions (supplemental Fig. 1). This reversible redistribution leads to an overall increase in photosynthetic quantum yield. State transitions occur when preferential excitation of PSII reduces the plastoquinone pool. This leads to the activation of a thylakoid protein kinase as a result of the docking of plastoquinol to the Qo site of the cytochrome b₆f complex (1, 2) and to the phosphorylation of the polypeptides of the light-harvesting complex II (LHCII), a part of which migrates to PSI (state 2) (3–5). The process is reversible as preferential excitation of PSI inactivates the kinase and allows for dephosphorylation of LHCII and its return to PSII (state 1) (3, 6). In the green alga Chlamydomonas reinhardtii, the LHCII protein set consists of Type I (Lhcbm3, Lhcbm4, Lhcbm6, Lhcbm8, and Lhcbm9), Type II (Lhcbm5), Type III (Lhcbm2 and Lhcbm7), and Type IV (Lhcbm1 and Lhcbm10) proteins and of Lhcb7, CP26, and CP29 (7). Because of their nearly identical sequences and sizes, several of these Lhcbm proteins cannot be distinguished by SDS-PAGE. Most of them fractionate into four bands called P11 and P13 (Type I), P16 (Type IV), and P17 (Type III). Whereas P16 is not phosphorylated, phosphorylation events occur on P11, P13, and P17 (7, 8).The association of the mobile part of LHCII to PSI during a transition from state 1 to state 2 requires the PsaH subunit (9) and CP29, which also moves to PSI and is essential for docking LHCII to PSI (10–12). The lateral displacement of LHCII from the PSII-rich grana to the PSI-rich lamellar thylakoid regions results in transfer to PSI of about 80% of the excitation energy absorbed by LHCII in C. reinhardtii (13), a considerably higher amount than in land plants in which only 15–20% of LHCII is mobile (3). In C. reinhardtii, state transitions are associated with a reorganization of the photosynthetic electron transfer chain with a switch from linear to cyclic electron flow during a transition from state 1 to state 2 (14, 15). Thus, cells produce ATP and NADPH in state 1 but only ATP in state 2. It appears that the major function of state transitions in this alga is to adjust the level of ATP and the ATP/NADPH ratio to cellular demands (5).Thylakoid membranes contain appressed grana and nonappressed stromal domains in which PSII and PSI are enriched, respectively. Because LHCII is a major stabilizer of the grana structure (16), the movement of LHCII from PSII to PSI is expected to lead to major rearrangements of these membranes during state transitions. Indeed, based on extensive electron microscope studies, it was proposed that fusion and fission events occur at the interface between the grana and stroma lamellar domains that lead to a remodeling of the membranes (17).Mapping of in vivo protein phosphorylation sites in photosynthetic membranes of Chlamydomonas revealed a total of 19 sites corresponding to 15 genes (18). It was shown that the major changes are clustered at the interface between the PSII core and the associated LHCII proteins during state transitions. Phosphorylation of the PSII core subunits D2 and PsbR and multiple phosphorylations of the minor LHCII antenna subunit CP29 were detected as well as phosphorylation of Lhcbm1, which belongs to the major LHCII complex (18).Although the phosphorylation of LHCII was observed many years ago (6), it is only recently that kinases involved in this process were uncovered. Fleischmann et al. (19) and Kruse et al. (20) used a genetic approach in C. reinhardtii with the aim of dissecting the signal transduction chain of state transitions. Two allelic mutants blocked in state 1 were identified that are affected in the Stt7 gene encoding a thylakoid Ser-Thr protein kinase that is required for LHCII phosphorylation during a transition from state 1 to state 2 (21). This Stt7 kinase is conserved in land plants and has an ortholog, STN7, in Arabidopsis (22).The 754-amino acid Stt7 kinase has a catalytic domain characteristic of Ser-Thr kinases (21). It contains a putative 41-amino acid transit peptide at its N-terminal end, and the protein is localized on the thylakoid membrane. Stt7 is associated with photosynthetic complexes including LHCII, PSI, and the cytochrome b₆f complex (23). Stt7 also contains a transmembrane region that separates its catalytic kinase domain on the stromal side from its N-terminal end in the thylakoid lumen with two conserved Cys residues that are critical for its activity and state transitions (23). Moreover, the level of Stt7 decreases considerably under state 1 conditions, and the kinase acts in catalytic amounts (23). However, it is not yet known whether this kinase directly phosphorylates LHCII or whether it is part of a kinase cascade involved in the signaling pathway of state transitions.In this work, we used a mass spectrometry-based approach (24) to map the in vivo Stt7-dependent protein phosphorylation sites within thylakoid membranes isolated from the green alga C. reinhardtii subjected to state 1 and state 2 conditions. In contrast with the earlier studies via direct MS/MS sequencing of the IMAC-enriched phosphorylated peptides from thylakoid proteins (18, 25), we performed additional LC-MS/MS-based analyses using alternating collision-induced dissociation and electron transfer dissociation of peptide ions. This approach revealed novel phosphorylation sites in LHCII polypeptides, in several other membrane and membrane-associated proteins, and in the thylakoid protein kinases Stt7 and Stl1, suggesting the existence of a thylakoid protein kinase cascade. Relative quantification of phosphorylated peptides labeled with stable isotopes determined the specific Stt7-dependent phosphorylation site in CP29 linker protein under state 2. Moreover, we also identified phosphorylation sites that are redox-dependent but independent of Stt7 and additional phosphorylation sites that are redox-independent. This mapping provides new insights into the regulatory network of protein phosphorylation in algal photosynthetic membranes during state transitions.     

Recent developments in effector biology of filamentous plant pathogens

Filamentous pathogens, such as plant pathogenic fungi and oomycetes, secrete an arsenal of effector molecules that modulate host innate immunity and enable parasitic infection. It is now well accepted that these effectors are key pathogenicity determinants that enable parasitic infection. In this review, we report on the most interesting features of a representative set of filamentous pathogen effectors and highlight recent findings. We also list and describe all the linear motifs reported to date in filamentous pathogen effector proteins. Some of these motifs appear to define domains that mediate translocation inside host cells.     

Targeting DNA with novel diphenylcarbazoles

Double-stranded DNA is a therapeutic target for a variety of anticancer and antimicrobial drugs. Noncovalent interactions of small molecules with DNA usually occur via intercalation of planar compounds between adjacent base pairs or minor-groove recognition by extended crescent-shaped ligands. However, the dynamic and flexibility of the DNA platform provide a variety of conformations that can be targeted by structurally diverse compounds. Here, we propose a novel DNA-binding template for construction of new therapeutic candidates. Four bisphenylcarbazole derivatives, derived from the combined molecular architectures of known antitumor bisphenylbenzimidazoles and anti-infectious dicationic carbazoles, have been designed, and their interaction with DNA has been studied by a combination of biochemical and biophysical methods. The substitutions of the bisphenylcarbazole core with two terminal dimethylaminoalkoxy side chains strongly promote the interaction with DNA, to prevent the heat denaturation of the double helix. The deletion or the replacement of the dimethylamino-terminal groups with hydroxyl groups strongly decreased DNA interaction, and the addition of a third cationic side chain on the carbazole nitrogen reinforced the affinity of the compound for DNA. Although the bi- and tridentate molecules both derive from well-characterized DNA minor-groove binders, the analysis of their binding mode by means of circular and linear dichroism methods suggests that these compounds form intercalation complexes with DNA. Negative-reduced dichroism signals were recorded in the presence of natural DNA and synthetic AT and GC polynucleotides. The intercalation hypothesis was validated by unwinding experiments using topoisomerase I. Prominent gel shifts were observed with the di- and trisubstituted bisphenylcarbazoles but not with the uncharged analogues. These observations, together with the documented stacking properties of such molecules (components for liquid crystals), prompted us to investigate their binding to the human telomeric DNA sequence by means of biosensor surface plasmon resonance. Under conditions favorable to G4 formation, the title compounds showed only a modest interaction with the telomeric quadruplex sequence, comparable to that measured with a double-stranded oligonucleotide. Their sequence preference was explored by DNase I footprinting experiments from which we identified a composite set of binding sequences comprising short AT stretches and a few other mixed AT/GC blocks with no special AT character. The variety of the binding sequences possibly reflects the coexistence of distinct positioning of the chromophore in the intercalation sites. The bisphenylcarbazole unit represents an original pharmacophore for DNA recognition. Its branched structure, with two or three arms suitable to introduce a structural diversity, provides an interesting scaffold to built molecules susceptible to discriminate between the different conformations of nucleic acids.     

Crystal structure of the receptor-binding protein head domain from Lactococcus lactis phage bIL170

Lactococcus lactis, a gram-positive bacterium widely used by the dairy industry, is subject to lytic phage infections. In the first step of infection, phages recognize the host saccharidic receptor using their receptor binding protein (RBP). Here, we report the 2.30-A-resolution crystal structure of the RBP head domain from phage bIL170. The structure of the head monomer is remarkably close to those of other lactococcal phages, p2 and TP901-1, despite any sequence identity with them. The knowledge of the three-dimensional structures of three RBPs gives a better insight into the module exchanges which have occurred among phages.     

"Immunetworks", intersecting circuits and dynamics

This paper proposes a study of biological regulation networks based on a multi-level strategy. Given a network, the first structural level of this strategy consists in analysing the architecture of the network interactions in order to describe it. The second dynamical level consists in relating the patterns found in the architecture to the possible dynamical behaviours of the network. It is known that circuits are the patterns that play the most important part in the dynamics of a network in the sense that they are responsible for the diversity of its asymptotic behaviours. Here, we pursue further this idea and argue that beyond the influence of underlying circuits, intersections of circuits also impact significantly on the dynamics of a network and thus need to be payed special attention to. For some genetic regulation networks involved in the control of the immune system (“immunetworks”), we show that the small number of attractors can be explained by the presence, in the underlying structures of these networks, of intersecting circuits that “inter-lock”.     

Probing plasmid partition with centromere-based incompatibility

Low-copy number plasmids of bacteria rely on specific centromeres for regular partition into daughter cells. When also present on a second plasmid, the centromere can render the two plasmids incompatible, disrupting partition and causing plasmid loss. We have investigated the basis of incompatibility exerted by the F plasmid centromere, sopC, to probe the mechanism of partition. Measurements of the effects of sopC at various gene dosages on destabilization of mini-F, on repression of the sopAB operon and on occupancy of mini-F DNA by the centromere-binding protein, SopB, revealed that among mechanisms previously proposed, no single one fully explained incompatibility. sopC on multicopy plasmids depleted SopB by titration and by contributing to repression. The resulting SopB deficit is proposed to delay partition complex formation and facilitate pairing between mini-F and the centromere vector, thereby increasing randomization of segregation. Unexpectedly, sopC on mini-P1 exerted strong incompatibility if the P1 parABS locus was absent. A mutation preventing the P1 replication initiation protein from pairing (handcuffing) reduced this strong incompatibility to the level expected for random segregation. The results indicate the importance of kinetic considerations and suggest that mini-F handcuffing promotes pairing of SopB-sopC complexes that can subsequently segregate as intact aggregates.     

Structure-function relationships of the intact aIF2alpha subunit from the archaeon Pyrococcus abyssi

Eukaryotic and archaeal initiation factor 2 (e- and aIF2, respectively) are heterotrimeric proteins (alphabetagamma) supplying the small subunit of the ribosome with methionylated initiator tRNA. The gamma subunit forms the core of the heterotrimer. It resembles elongation factor EF1-A and ensures interaction with Met-tRNA(i)(Met). In the presence of the alpha subunit, which is composed of three domains, the gamma subunit expresses full tRNA binding capacity. This study reports the crystallographic structure of the intact aIF2alpha subunit from the archaeon Pyrococcus abyssi and that of a derived C-terminal fragment containing domains 2 and 3. The obtained structures are compared with those of N-terminal domains 1 and 2 of yeast and human eIF2alpha and with the recently determined NMR structure of human eIF2alpha. We show that the three-domain organization in the alpha subunit is conserved in archaea and eukarya. Domains 1 and 2 form a rigid body linked to a mobile third domain. Sequence comparisons establish that the most conserved regions in the aIF2alpha polypeptide lie at opposite sides of the protein, within domain 1 and domain 3, respectively. These two domains are known to exhibit RNA binding capacities. We propose that domain 3, which is known to glue the alpha subunit onto the gamma subunit, participates in Met-tRNA(i)(Met) binding while domain 1 recognizes either rRNA or mRNA on the ribosome. Thereby, the observed structural mobility within the e- and aIF2alpha molecules would be an integral part of the biological function of this subunit in the heterotrimeric e- and aIF2alphabetagamma factors.