The structure of a filamentous bacteriophage

Many thin helical polymers, including bacterial pili and filamentous bacteriophage, have been seen as refractory to high-resolution studies by electron microscopy. Studies of the quaternary structure of such filaments have depended upon techniques such as modeling or X-ray fiber diffraction, given that direct visualization of the subunit organization has not been possible. We report the first image reconstruction of a filamentous virus, bacteriophage fd, by cryoelectron microscopy. Although these thin ( approximately 70 A in diameter) rather featureless filaments scatter weakly, we have been able to achieve a nominal resolution of approximately 8 A using an iterative helical reconstruction procedure. We show that two different conformations of the virus exist, and that in both states the subunits are packed differently than in conflicting models previously proposed on the basis of X-ray fiber diffraction or solid-state NMR studies. A significant fraction of the population of wild-type fd is either disordered or in multiple conformational states, while in the presence of the Y21M mutation, this heterogeneity is greatly reduced, consistent with previous observations. These results show that new computational approaches to helical reconstruction can greatly extend the ability to visualize heterogeneous protein polymers at a reasonably high resolution.     

A257T linker region mutant of T7 helicase-primase protein is defective in DNA loading and rescued by T7 DNA polymerase

The helicase and primase activities of the hexameric ring-shaped T7 gp4 protein reside in two separate domains connected by a linker region. This linker region is part of the subunit interface between monomers, and point mutations in this region have deleterious effects on the helicase functions. One such linker region mutant, A257T, is analogous to the A359T mutant of the homologous human mitochondrial DNA helicase Twinkle, which is linked to diseases such as progressive external opthalmoplegia. Electron microscopy studies show that A257T gp4 is normal in forming rings with dTTP, but the rings do not assemble efficiently on the DNA. Therefore, A257T, unlike the WT gp4, does not preassemble on the unwinding DNA substrate with dTTP without Mg(II), and its DNA unwinding activity in ensemble assays is slow and limited by the DNA loading rate. Single molecule assays measured a 45 times slower rate of A257T loading on DNA compared with WT gp4. Interestingly, once loaded, A257T has almost WT-like translocation and DNA unwinding activities. Strikingly, A257T preassembles stably on the DNA in the presence of T7 DNA polymerase, which restores the ensemble unwinding activity of A257T to ～75% of WT, and the rescue does not require DNA synthesis. The DNA loading rate of A257T, however, remains slow even in the presence of the polymerase, which explains why A257T does not support T7 phage growth. Similar types of defects in the related human mitochondrial DNA helicase may be responsible for inefficient DNA replication leading to the disease states.     

The N-terminal domains of myosin binding protein C can bind polymorphically to F-actin

The regulation of vertebrate striated muscle contraction involves a number of different molecules, including the thin-filament accessory proteins tropomyosin and troponin that provide Ca²⁺-dependent regulation by controlling access to myosin binding sites on actin. Cardiac myosin binding protein C (cMyBP-C) appears to modulate this Ca²⁺-dependent regulation and has attracted increasing interest due to links with inherited cardiac diseases. A number of single amino acid mutations linked to clinical diseases occur in the N-terminal region of cMyBP-C, including domains C0 and C1, which previously have been shown to bind to F-actin. This N-terminal region also has been shown to both inhibit and activate actomyosin interactions in vitro. Using electron microscopy and three-dimensional reconstruction, we show that C0 and C1 can each bind to the same two distinctly different positions on F-actin. One position aligns well with the previously reported binding site that clashes with the binding of myosin to actin, but would force tropomyosin into an “on” position that exposes myosin binding sites along the filament. The second position identified here would not interfere with either myosin binding or tropomyosin positioning. It thus appears that the ability to bind to at least two distinctly different positions on F-actin, as observed for tropomyosin, may be more common than previously considered for other actin binding proteins. These observations help to explain many of the seemingly contradictory results obtained with cMyBP-C and show how cMyBP-C can provide an additional layer of regulation to actin-myosin interactions. They also suggest a redundancy of C0 and C1 that may explain the absence of C0 in skeletal muscle.     

SV40 large T antigen hexamer structure: domain organization and DNA-induced conformational changes

Simian Virus 40 replication requires only one viral protein, the Large T antigen (T-ag), which acts as both an initiator of replication and as a replicative helicase (reviewed in ). We used electron microscopy to generate a three-dimensional reconstruction of the T-ag hexameric ring in the presence and absence of a synthetic replication fork to locate the T-ag domains, to examine structural changes in the T-ag hexamer associated with DNA binding, and to analyze the formation of double hexamers on and off DNA. We found that binding DNA to the T-ag hexamer induces large conformational changes in the N- and C-terminal domains of T-ag. Additionally, we observed a significant increase in density throughout the central channel of the hexameric ring upon DNA binding. We conclude that conformational changes in the T-ag hexamer are required to accommodate DNA and that the mode of DNA binding may be similar to that suggested for some other ring helicases. We also identified two conformations of T-ag double hexamers formed in the presence of forked DNA: with N-terminal hexamer-hexamer contacts, similar to those formed on origin DNA, or with C-terminal contacts, which are unlike any T-ag double hexamers reported previously.     

Image analysis shows that variations in actin crossover spacings are random, not compensatory.

A recent paper by Bremer et al. (1991. J. Cell Biol. 115:689-703) has argued that the random angular disorder model for actin is wrong, and that the variations in crossover spacing observed in electron micrographs of F-actin filaments can be best explained by a compensatory disorder caused by the lateral slipping of the twin (or two-start) strands which comprise the actin filament. We have analyzed the images of F-actin presented in Bremer et al. and show that their data argues against compensatory disorder and in favor of random disorder, independent of the cause of the disorder. We also revise our estimate of the angular component and show that the magnitude of this disorder is about 5-6 degrees per subunit, which is less than the 10-12 degrees that we originally proposed.     

清醒猫摄食过程中的胃电活动

本文报告慢性清醒猫正常摄食过程中胃电的变化,以及脑室注射心得安和动物麻醉对胃电的影响。结果显示,空腹饥饿状态下,猫胃电图上出现具有特征性的高振幅的“饥饿波”;摄食时胃电慢波抑制,可见较小快波;进食后半小时左右,胃电开始出现每分钟4—5次的振幅逐渐增大的正弦形慢波,多数慢波负载有快波。脑室注射心得安,可使饱猫胃电慢波抑制期出现饥饿波。动物在饥饿时麻醉,胃电慢波幅度显著降低,饥饿波完全不出现,苏醒后逐渐恢复。     

Angular disorder in actin: is it consistent with general principles of protein structure?

Harold Erickson has recently provided a useful analysis of helical structures having one class versus two classes of intersubunit bonds. His analysis is based upon an assumption that the subunits themselves are essentially unchanged upon bond formation (polymerization). He shows that such a structure having two classes of bonds (i.e. one in which each subunit interacts with four of its neighbors rather than two) can explain some of the features of actin. While he acknowledges that for actin there could be a conformational change and that, in principle, it could explain such features, he argues that the allowed magnitude of such a conformational change is inadequate. Since kinetics and thermodynamics cannot distinguish between the energy derived from the formation of a bond from that due to a conformational change, the question of whether the features of F-actin are derived from a conformational change or a system of two classes of bonds or both must be answered with high-resolution structural information. Recent studies by K. C. Holmes and others suggest that the second possibility might be closest to the truth. The heart of our disagreement is not whether Erickson's thermodynamic analysis is correct, given rigid subunits, but whether all protein polymers are characterized by rigid subunits with rigid intersubunit contacts. Erickson maintains that the observation of an angular disorder of 12 degrees per subunit within the actin filament conflicts with his formalism of rigid subunit interfaces and must therefore result from the erroneous interpretation of measurements. He presents an alternative model to explain the observations. His model, however, does not account for the observations and we will argue that, ultimately, like the resolution of the matter of the number of classes of bonds and the extent of their contact, the amount of angular disorder will require higher-resolution structural studies.     

Functional reconstitution of the type IVa pilus assembly system from enterohaemorrhagic Escherichia coli

Type 4a pili (T4aP) are long, thin and dynamic fibres displayed on the surface of diverse bacteria promoting adherence, motility and transport functions. Genomes of many Enterobacteriaceae contain conserved gene clusters encoding putative T4aP assembly systems. However, their expression has been observed only in few strains including Enterohaemorrhagic Escherichia coli (EHEC) and their inducers remain unknown. Here we used EHEC genomic DNA as a template to amplify and assemble an artificial operon composed of four gene clusters encoding 13 pilus assembly proteins. Controlled expressions of this operon in nonpathogenic E. coli strains led to efficient assembly of T4aP composed of the major pilin PpdD, as shown by shearing assays and immunofluorescence microscopy. When compared with PpdD pili assembled in a heterologous Klebsiella T2SS type 2 secretion system (T2SS) by using cryo‐electron microscopy (cryoEM), these pili showed indistinguishable helical parameters, emphasizing that major pilins are the principal determinants of the fibre structure. Bacterial two‐hybrid analysis identified several interactions of PpdD with T4aP assembly proteins, and with components of the T2SS that allow for heterologous fibre assembly. These studies lay ground for further characterization of the T4aP structure, function and biogenesis in enterobacteria.     

Methods for peptide identification by spectral comparison

Background  

Tandem mass spectrometry followed by database search is currently the predominant technology for peptide sequencing in shotgun proteomics experiments. Most methods compare experimentally observed spectra to the theoretical spectra predicted from the sequences in protein databases. There is a growing interest, however, in comparing unknown experimental spectra to a library of previously identified spectra. This approach has the advantage of taking into account instrument-dependent factors and peptide-specific differences in fragmentation probabilities. It is also computationally more efficient for high-throughput proteomics studies.