马铃薯NOA基因的克隆及序列分析(英文)

以马铃薯(Solanum tuberosum)为实验材料,利用电子克隆和RACE技术,从马铃薯中克隆出NOA(nitric oxide associated factor)基因,命名为StNOA1,测序结果表明,其cDNA序列长度为1 929 bp,此片段包含一个长为1 632 bp的完整编码框.氨基酸序列比对分析表明,StNOA1与烟草(Nicotiana benthamiana),葡萄(Vitis vinifera),蓖麻(Ricinus communis),水稻(Oryza sativa),玉米(Zea mays)以及拟南芥(Arabidopsis thaliana)均有很高的同源性 (89.44%～63.56%).同AtNOA1一样,StNOA1也具有保守的GTP结合区.从结构分析结果推测,StNOA1和AtNOA1在功能上有一定的相关性,其也可能通过调节内源NO的释放参与到植物生长、发育、抗逆等过程中.     

Morphology, function and isolation of halobacterial flagella

Halobacterium halobium has right-handed helical flagella. During the logarithmic phase of growth, cells are predominantly monopolar, whereas in the stationary phase they are mostly bipolarly flagellated. The flagellar bundle consists of several filaments. Halobacteria swim forward by clockwise and backwards by counterclockwise rotation of their flagella. The flagellar bundle does not fly apart when the sense of rotation changes. In addition to the flagella attached to the cells, large amounts of loose flagella, which aggregate into thick super-flagella, can be observed at all phases of growth. During stationary phase, the production of these super-flagella, which are generally 10 to 20 times longer than the cell body, is significantly higher. Dissociation and association by high temperature and differential centrifugation allow the isolation of pure flagella. Three different protein bands, of 23,500, 26,500 and 31,500 apparent molecular weights, are seen on sodium dodecyl sulphate/polyacrylamide gels. Antibodies against halobacterial flagella were produced in chicken; these antibodies interact with the flagella even in 4 M-NaCl. Rotation of tethered cells demonstrates that Halobacteria move due to the rotation of the flagella.     

Membrane identity and GTPase cascades regulated by toggle and cut‐out switches

Key cellular functions and developmental processes rely on cascades of GTPases. GTPases of the Rab family provide a molecular ID code to the generation, maintenance and transport of intracellular compartments. Here, we addressed the molecular design principles of endocytosis by focusing on the conversion of early endosomes into late endosomes, which entails replacement of Rab5 by Rab7. We modelled this process as a cascade of functional modules of interacting Rab GTPases. We demonstrate that intermodule interactions share similarities with the toggle switch described for the cell cycle. However, Rab5‐to‐Rab7 conversion is rather based on a newly characterized ‘cut‐out switch’ analogous to an electrical safety‐breaker. Both designs require cooperativity of auto‐activation loops when coupled to a large pool of cytoplasmic proteins. Live cell imaging and endosome tracking provide experimental support to the cut‐out switch in cargo progression and conversion of endosome identity along the degradative pathway. We propose that, by reconciling module performance with progression of activity, the cut‐out switch design could underlie the integration of modules in regulatory cascades from a broad range of biological processes.     

Another burst of smoke: atomic resolution structures of RF3 bound to the ribosome

Two recent reports provide atomic resolution information detailing the interaction of the class II release factor, RF3, with the bacterial ribosome. Differences in the composition of the two crystal forms allow us to learn a considerable amount about how translational GTPases engage the ribosome to facilitate and define conformational rearrangements involved in protein synthesis.     

Identification of residues in the human guanylate-binding protein 1 critical for nucleotide binding and cooperative GTP hydrolysis

The guanylate-binding proteins (GBPs) form a group of interferon-gamma inducible GTP-binding proteins which belong to the family of dynamin-related proteins. Like other members of this family, human guanylate-binding protein 1 (hGBP1) shows nucleotide-dependent oligomerisation that stimulates the GTPase activity of the protein. A unique feature of the GBPs is their ability to hydrolyse GTP to GDP and GMP. In order to elucidate the relationship between these findings, we designed point mutants in the phosphate-binding loop (P-loop) as well as in the switch I and switch II regions of the protein based on the crystal structure of hGBP1. These mutant proteins were analysed for their interaction with guanine nucleotides labeled with a fluorescence dye and for their ability to hydrolyse GTP in a cooperative manner. We identified mutations of amino acid residues that decrease GTPase activity by orders of magnitude a part of which are conserved in GTP-binding proteins. In addition, mutants in the P-loop were characterized that strongly impair binding of nucleotide. In consequence, together with altered GTPase activity and given cellular nucleotide concentrations this results in hGBP1 mutants prevailingly resting in the nucleotide-free (K51A and S52N) or the GTP bound form (R48A), respectively. Using size-exclusion chromatography and analytical ultracentrifugation we addressed the impact on protein oligomerisation. In summary, mutants of hGBP1 were identified and biochemically characterized providing hGBP1 locked in defined states in order to investigate their functional role in future cell biology studies.     

De novo design of a molecular switch: phosphorylation-dependent association of designed peptides

The de novo design of peptides that switch their oligomerization state in response to a chemical stimulus is of interest, both as a tool for understanding the basis of molecular switching as well as development of reagents for the study of signal transduction in cells. The target of the current study is the design of a series of peptides that undergo a transition from an unstructured monomer to a four-helical bundle upon phosphorylation by the enzyme cyclic AMP-dependent protein kinase (PKA). The designed peptides are based on the 20-residue Lac repressor tetramerization domain. Beginning with this structure, we introduced a phosphorylation site near the N terminus. Phosphorylation leads to a 2-4.6 kcal/mol increase in the stability of the tetramer, depending on the design. The most successful switches were designed such that phosphorylation would increase the stability of the individual helices and also relieve an unfavorable electrostatic interaction in the tetramer.     

Classification and evolution of P-loop GTPases and related ATPases

Sequences and available structures were compared for all the widely distributed representatives of the P-loop GTPases and GTPase-related proteins with the aim of constructing an evolutionary classification for this superclass of proteins and reconstructing the principal events in their evolution. The GTPase superclass can be divided into two large classes, each of which has a unique set of sequence and structural signatures (synapomorphies). The first class, designated TRAFAC (after translation factors) includes enzymes involved in translation (initiation, elongation, and release factors), signal transduction (in particular, the extended Ras-like family), cell motility, and intracellular transport. The second class, designated SIMIBI (after signal recognition particle, MinD, and BioD), consists of signal recognition particle (SRP) GTPases, the assemblage of MinD-like ATPases, which are involved in protein localization, chromosome partitioning, and membrane transport, and a group of metabolic enzymes with kinase or related phosphate transferase activity. These two classes together contain over 20 distinct families that are further subdivided into 57 subfamilies (ancient lineages) on the basis of conserved sequence motifs, shared structural features, and domain architectures. Ten subfamilies show a universal phyletic distribution compatible with presence in the last universal common ancestor of the extant life forms (LUCA). These include four translation factors, two OBG-like GTPases, the YawG/YlqF-like GTPases (these two subfamilies also consist of predicted translation factors), the two signal-recognition-associated GTPases, and the MRP subfamily of MinD-like ATPases. The distribution of nucleotide specificity among the proteins of the GTPase superclass indicates that the common ancestor of the entire superclass was a GTPase and that a secondary switch to ATPase activity has occurred on several independent occasions during evolution. The functions of most GTPases that are traceable to LUCA are associated with translation. However, in contrast to other superclasses of P-loop NTPases (RecA-F1/F0, AAA+, helicases, ABC), GTPases do not participate in NTP-dependent nucleic acid unwinding and reorganizing activities. Hence, we hypothesize that the ancestral GTPase was an enzyme with a generic regulatory role in translation, with subsequent diversification resulting in acquisition of diverse functions in transport, protein trafficking, and signaling. In addition to the classification of previously known families of GTPases and related ATPases, we introduce several previously undetected families and describe new functional predictions.     

Crystal structure of an archaeal actin homolog

Prokaryotic homologs of the eukaryotic structural protein actin, such as MreB and ParM, have been implicated in determination of bacterial cell shape, and in the segregation of genomic and plasmid DNA. In contrast to these bacterial actin homologs, little is known about the archaeal counterparts. As a first step, we expressed a predicted actin homolog of the thermophilic archaeon Thermoplasma acidophilum, Ta0583, and determined its crystal structure at 2.1A resolution. Ta0583 is expressed as a soluble protein in T.acidophilum and is an active ATPase at physiological temperature. In vitro, Ta0583 forms sheets with spacings resembling the crystal lattice, indicating an inherent propensity to form filamentous structures. The fold of Ta0583 contains the core structure of actin and clearly belongs to the actin/Hsp70 superfamily of ATPases. Ta0583 is approximately equidistant from actin and MreB on the structural level, and combines features from both eubacterial actin homologs, MreB and ParM. The structure of Ta0583 co-crystallized with ADP indicates that the nucleotide binds at the interface between the subdomains of Ta0583 in a manner similar to that of actin. However, the conformation of the nucleotide observed in complex with Ta0583 clearly differs from that in complex with actin, but closely resembles the conformation of ParM-bound nucleotide. On the basis of sequence and structural homology, we suggest that Ta0583 derives from a ParM-like actin homolog that was once encoded by a plasmid and was transferred into a common ancestor of Thermoplasma and Ferroplasma. Intriguingly, both genera are characterized by the lack of a cell wall, and therefore Ta0583 could have a function in cellular organization.     

Membrane fission by dynamin: what we know and what we need to know

The large GTPase dynamin is the first protein shown to catalyze membrane fission. Dynamin and its related proteins are essential to many cell functions, from endocytosis to organelle division and fusion, and it plays a critical role in many physiological functions such as synaptic transmission and muscle contraction. Research of the past three decades has focused on understanding how dynamin works. In this review, we present the basis for an emerging consensus on how dynamin functions. Three properties of dynamin are strongly supported by experimental data: first, dynamin oligomerizes into a helical polymer; second, dynamin oligomer constricts in the presence of GTP; and third, dynamin catalyzes membrane fission upon GTP hydrolysis. We present the two current models for fission, essentially diverging in how GTP energy is spent. We further discuss how future research might solve the remaining open questions presently under discussion.     

Bacterial actin: architecture of the ParMRC plasmid DNA partitioning complex

The R1 plasmid employs ATP-driven polymerisation of the actin-like protein ParM to move newly replicated DNA to opposite poles of a bacterial cell. This process is essential for ensuring accurate segregation of the low-copy number plasmid and is the best characterised example of DNA partitioning in prokaryotes. In vivo, ParM only forms long filaments when capped at both ends by attachment to a centromere-like region parC, through a small DNA-binding protein ParR. Here, we present biochemical and electron microscopy data leading to a model for the mechanism by which ParR-parC complexes bind and stabilise elongating ParM filaments. We propose that the open ring formed by oligomeric ParR dimers with parC DNA wrapped around acts as a rigid clamp, which holds the end of elongating ParM filaments while allowing entry of new ATP-bound monomers. We propose a processive mechanism by which cycles of ATP hydrolysis in polymerising ParM drives movement of ParR-bound parC DNA. Importantly, our model predicts that each pair of plasmids will be driven apart in the cell by just a single double helical ParM filament.     

Helix dynamics in a membrane transport protein: comparative simulations of the glycerol-3-phosphate transporter and its constituent helices

The glycerol-3-phosphate transporter (GlpT) is a member of the major facilitator superfamily (MFS). GlpT is an organic phosphate/inorganic phosphate antiporter. It shares a similar fold with other MFS transporters (e.g. LacY and EmrD) consisting of 12 transmembrane (TM) helices which form two domains (each of six TM helices) surrounding a central ligand-binding cavity. The TM helices (especially the cavity-lining helices) contain a large number of proline and glycine residues, which may aid in the conformational changes believed to underline the transport mechanism. Molecular dynamics simulations in a phospholipid bilayer have been used to compare the conformational properties of the isolated TM helices with those in the intact GlpT protein. Analysis of these simulations focuses on the role of proline-induced flexibility in the TM helices. Our results are consistent with the proposed rocker switch mechanism for transport by GlpT. In particular, the simulations highlight the cavity-lining helices (H4, H5, H10 and H11) as being significantly flexible, suggesting that the transport mechanism may involve intra-helix motions in addition to pseudo-rigid body motions of the N- and C-terminal domains relative to one another.