In vivo micro-CT imaging of liver lesions in small animal models

Three-dimensional micro computed tomography (microCT) offers the opportunity to capture images liver structures and lesions in mice with a high spatial resolution. Non-invasive microCT allows for accurate calculation of vessel tortuosity and density, as well as liver lesion volume and distribution. Longitudinal monitoring of liver lesions is also possible. However, distinguishing liver lesions from variations within a normal liver is impossible by microCT without the use of liver- or tumor-specific contrast-enhancing agents. The combination of microCT for morphologic imaging with functional imaging, such as positron emission tomography (PET) or single photon emission tomography (SPECT), offers the opportunity for better abdominal imaging and assessment of structure discrepancies visible by functional imaging.This paper describes methods of current microCT imaging options for imaging of liver lesions compared to other imaging techniques in small animals.     

ALMA, an editor for large sequence alignments

A dedicated sequence editor, ALMA, was developed for aligning many sequences of proteins or RNA molecules or longer DNA fragments. Like previously published editors, ALMA is menu directed, screen oriented, and offers similarity and consensus display. ALMA has the additional features of collective movement of sequences, acceptance of input from many sources including structure files and databases, secondary structure display, and easy merging of alignments. In order to maintain sequence integrity and save disk space, gaps and sequences are stored separately. Automatic recovery of a session is possible. Finally, the program allows interaction between manual and automatic alignment.     

Nonlinear Dynamics of Microtubules: Biophysical Implications

A recently developed model of nonlinear dynamics for microtubules is further expanded based on the biophysical arguments involving the secondary structure of the constitutive protein tubulin and on the ferroelectric properties of microtubules. It is demonstrated that kink excitations arise due to GTP hydrolysis that causes a dynamical transition in the structure of tubulin. The presence of an intrinsic electric field associated with the structure of a microtubule leads to unidirectional propagation of the kink excitation along the microtubule axis. This mechanism offers an explanation of the dynamic instability phenomenon in terms of the electric field effects. Moreover, a possible elucidation of the unidirectional transport of cargo via motor proteins such as kinesin and dynein is proposed within the model developed in this paper.     

High-resolution structure of viruses from random diffraction snapshots

The advent of the X-ray free-electron laser (XFEL) has made it possible to record diffraction snapshots of biological entities injected into the X-ray beam before the onset of radiation damage. Algorithmic means must then be used to determine the snapshot orientations and thence the three-dimensional structure of the object. Existing Bayesian approaches are limited in reconstruction resolution typically to 1/10 of the object diameter, with the computational expense increasing as the eighth power of the ratio of diameter to resolution. We present an approach capable of exploiting object symmetries to recover three-dimensional structure to high resolution, and thus reconstruct the structure of the satellite tobacco necrosis virus to atomic level. Our approach offers the highest reconstruction resolution for XFEL snapshots to date and provides a potentially powerful alternative route for analysis of data from crystalline and nano-crystalline objects.     

Synthetic biology: lessons from the history of synthetic organic chemistry

The mid-nineteenth century saw the development of a radical new direction in chemistry: instead of simply analyzing existing molecules, chemists began to synthesize them--including molecules that did not exist in nature. The combination of this new synthetic approach with more traditional analytical approaches revolutionized chemistry, leading to a deep understanding of the fundamental principles of chemical structure and reactivity and to the emergence of the modern pharmaceutical and chemical industries. The history of synthetic chemistry offers a possible roadmap for the development and impact of synthetic biology, a nascent field in which the goal is to build novel biological systems.     

Sperm ultrastructure in Kellia suborbicularis (Bivalvia: Galeommatoidea: Kellidae)

The sperm cells of Kellia suborbicularis are narrow with a short bullet‐shaped acrosome, a 5.0–5.5 µm long and 0.4–0.6 µm broad nucleus, and a short midpiece with a ring of five mitochondria. The disposition of the subacrosomal substance into a coronet‐like formation is unique, and the sperm structure offers no clue to the relationship between Kellia and other galeommatoidean genera. The possible significance of narrow elongate sperm for their entry into the brood pouch is discussed.     

Unusual folded conformation of nicotinamide adenine dinucleotide bound to flavin reductase P.

The 2.1 A resolution crystal structure of flavin reductase P with the inhibitor nicotinamide adenine dinucleotide (NAD) bound in the active site has been determined. NAD adopts a novel, folded conformation in which the nicotinamide and adenine rings stack in parallel with an inter-ring distance of 3.6 A. The pyrophosphate binds next to the flavin cofactor isoalloxazine, while the stacked nicotinamide/adenine moiety faces away from the flavin. The observed NAD conformation is quite different from the extended conformations observed in other enzyme/NAD(P) structures; however, it resembles the conformation proposed for NAD in solution. The flavin reductase P/NAD structure provides new information about the conformational diversity of NAD, which is important for understanding catalysis. This structure offers the first crystallographic evidence of a folded NAD with ring stacking, and it is the first enzyme structure containing an FMN cofactor interacting with NAD(P). Analysis of the structure suggests a possible dynamic mechanism underlying NADPH substrate specificity and product release that involves unfolding and folding of NADP(H).     

On the origin of molecular “handedness” in living systems

Elementary particle effects (beta-decay) provide at best only a weakly handed radiation in the biologically effective energy ranges. Global magnetic effects coupled to sunlight are randomized by paleomagnetic reversals. Hence a persistent terrestrial handed bias at possible local biopoetic sites offers a more promising explanation for the origin of the "handedness" of the molecules found among living systems on earth. Magnetite in lava flows maintains a handed bias for surface catalysis through many magnetic reversals. Magnetite contaminated with sulfur has already been proposed by Granick as a biopoetic site because it provides a weak source of chemical energy derived by photochemical conversion. Indirect evidence for this hypothesis has been provided by the molecular structure of ferredoxin - a single strand of the 14 primordial amino acids wrapped around an FeS core. Lava flows have been suggested as biopoetic sites by Fox, since their temperature and chemical composition might allow for the rapid synthesis of prebiotic compounds at the surface of the primitive earth. The additional fact that magnetite in lave flows also provides a persistent handed site for surface catalysis offers a further argument for the experimental investigation of this specific biopoetic environment.     

Biosynthetic substitution of tyrosine in green fluorescent protein with its surrogate fluorotyrosine in <Emphasis Type="Italic">Escherichia coli</Emphasis>

Introduction of a fluorine moiety into green fluorescent protein offers an interesting novel spectral variant. The calculated binding energy of fluorotyrosine (F-Tyr) (−8.42 kcal/mol) for tyrosyl tRNA synthetase was moderately higher than that of tyrosine (Tyr) (−8.36 kcal/mol). This result directly correlated with the expression level of F-Tyr containing GFP (38 mg/l), which was comparably higher than that of the parent GFP expression level (34 mg/l). Finally, we generated a model structure for GFP to assess possible interaction in the chromophore of the protein structure, which plays an important role in determining the spectral and folding behaviors of the F-Tyr incorporated GFP variant.     

Ordering in a glycine-rich peptide conjugate: microscopic, fluorescence, and metalation studies

Glycine residues play an intriguing role in peptide/protein structure where they can act as tightly packing amino acids with flexible bond angles. For example, structural role of glycines is highlighted in natural silk fibers where different structural polymorphs have been reported. This study deals with a glycine-rich segment from the conserved octarepeat (PHGGGWGQ) in prion protein. We have synthesized a bis-conjugate 3, containing a truncated pentapeptide segment (GGGWG), to study its time-dependent solution phase aggregation by a combination of microscopic methods and fluorescence. This discontinuous peptide conjugate 3 exhibited interesting photophysical properties upon self-assembly allowing us to propose a possible model of peptide filament formation. Taking note of the fact that prion octarepeats bind copper, we also demonstrate the ability of this conjugate to bind copper and the growth and ultrastructure of metallized fibers formed upon incubation. Enforcing peptide fiber formation in metal binding motifs offers an entry into metal impregnated fibers for possible nanobiotechnological applications.     

MICROGEOGRAPHIC LINEAGE ANALYSIS BY MITOCHONDRIAL GENOTYPE: VARIATION IN THE COTTON RAT (SIGMODON HISPIDUS)

We evaluate the use of mitochondrial DNA (mtDNA) genetic markers to describe population structure and matrilineal kinship on a microgeographic scale. An analysis of restriction site variation in 134 cotton rats (Sigmodon hispidus) collected from a 3.2 hectare field revealed significant spatial and temporal heterogeneity in frequencies of mtDNA genotypes among nest sites. Inspection of particular genotypes provided additional information about minimum numbers of female lineages (family units) per nest site, and the possible matrilineal affiliations of individuals. However, since shared genotypes are not necessarily synapomorphs having arisen within the study area, conclusions about dispersal must remain reserved. Study of the maternally-transmitted mtDNA genome offers novel perspectives on the meaning of microgeographic population structure.     

Name that microbe: rapid identification of taxa responsible for individual fragments in fingerprints of microbial community structure

Polymerase chain reaction (PCR)‐based ‘fingerprinting’ methods, such as Terminal restriction fragment length polymorphism, Length Heterogeneity‐Polymerase Chain Reaction (LH‐PCR) and Automated Ribosomal Intergenic Spacer Analysis (ARISA) make possible quantitative studies of microbial community structure and dynamics. Here we outline a strategy for the rapid and cost‐effective isolation of 16S clones corresponding to particular fragment sizes in a fingerprint, based on applying the fingerprinting method to pools of colonies from a clone library. This allows the definitive identification of taxa responsible for the most important bands in the community fingerprint from a full 16S sequence. It offers significant advantages over random selection of clones and removes a significant barrier to the use of these methods.     

Survey, analysis and genetic organization of genes encoding eukaryotic-like signaling proteins on a cyanobacterial genome.

Bacteria usually use two-component systems for signal transduction, while eukaryotic organisms employ Ser/Thr and Tyr kinases and phosphatases for the same purpose. Many prokaryotes turn out to harbor Ser/Thr and Tyr kinases, Ser/Thr and Tyr phosphatases, and their accessory components as well. The sequence determination of the genome of the cyanobacterium Synechocystis sp. strain PCC 6803 offers the possibility to survey the extent of such molecules in a prokaryotic organism. This cyanobacterium possesses seven Ser/Thr kinases, seven Ser/Thr and Tyr phosphatases, one protein kinase interacting protein, one protein kinase regulatory subunit and several WD40-repeat-containing proteins. The majority of the protein phosphatases presented in this study were previously reported as hypothetical proteins. We analyze here the structure and genetic organization of these ORFs in the hope of providing a guidance for their functional analysis. Unlike their eukaryotic counterparts, many of these genes are clustered on the chromosome, and this genetic organization offers the opportunity to study their possible interaction. In several cases, genes of two-component transducers are found within the same cluster as those encoding a Ser/Thr kinase or a Ser/Thr phosphatase; the implication for signal transduction mechanism will be discussed.     

Automation of random conical tilt and orthogonal tilt data collection using feature-based correlation

Visualization by electron microscopy has provided many insights into the composition, quaternary structure, and mechanism of macromolecular assemblies. By preserving samples in stain or vitreous ice it is possible to image them as discrete particles, and from these images generate three-dimensional structures. This ‘single-particle’ approach suffers from two major shortcomings; it requires an initial model to reconstitute 2D data into a 3D volume, and it often fails when faced with conformational variability. Random conical tilt (RCT) and orthogonal tilt (OTR) are methods developed to overcome these problems, but the data collection required, particularly for vitreous ice specimens, is difficult and tedious. In this paper, we present an automated approach to RCT/OTR data collection that removes the burden of manual collection and offers higher quality and throughput than is otherwise possible. We show example datasets collected under stain and cryo conditions and provide statistics related to the efficiency and robustness of the process. Furthermore, we describe the new algorithms that make this method possible, which include new calibrations, improved targeting and feature-based tracking.     

Biological synthesis of circular polypeptides

Here, we review the use of different biochemical approaches for biological synthesis of circular or backbone-cyclized proteins and peptides. These methods allow the production of circular polypeptides either in vitro or in vivo using standard recombinant DNA expression techniques. Protein circularization can significantly impact protein engineering and research in protein folding. Basic polymer theory predicts that circularization should lead to a net thermodynamic stabilization of a folded protein by reducing the entropy associated with the unfolded state. Protein cyclization also provides a valuable tool for exploring the effects of topology on protein folding kinetics. Furthermore, the biological production of cyclic polypeptides makes possible the production of cyclic polypeptide libraries. The generation of such libraries, which was previously restricted to the domain of synthetic chemists, now offers biologists access to highly diverse and stable molecular libraries for probing protein structure and function.     

影响动物细胞同源重组发生与基因打靶效率的分子机制

真核细胞的基因打靶是基因结构与功能研究的一种非常有价值的技术,也是可应用于基因治疗的具有潜力的工具。有2个限制因素束缚真核细胞基因打靶的发展,即同源重组(HR)率非常低而随机整合率非常高。通过特定基因的过表达或表达干涉,使一些参与DNA重组的蛋白表达水平瞬间改变,可能会增加HR率,降低随机整合率。本文列举了一些与HR相关的候选基因,详细介绍了其中的Rad52上位簇基因,还讨论了打靶载体的设计与修饰、DNA转染方法的有效性等。     

Omptin proteins: an expanding family of outer membrane proteases in Gram-negative Enterobacteriaceae

The Escherichia coli K-12 outer membrane protein OmpT is a prototype of a unique family of bacterial endopeptidases known as the omptins. This family includes OmpT and OmpP of E. coli, SopA of Shigella flexneri, PgtE of Salmonella enterica, and Pla of Yersinia pestis. Despite their sequence similarities, the omptins vary in their reported functions. The OmpT protease is characterized by narrow cleavage specificity defined by the extracellular loops of the beta-barrel protruding above the lipid bilayer. It employs a distinct proteolytic mechanism that involves a histidine and an aspartate residue. Most of the omptin proteins have been implicated in bacterial pathogenesis. As a result, the omptins are potential targets for antimicrobial drug and vaccine development. This review summarizes recent developments in omptins structure and function, emphasizes their role in pathogenesis, proposes evolutionary relation among the existing omptins, and offers possible directions for future research.     

Pelvic Exenteration

Pelvic exenteration offers the only possibility for cure in patients who have pelvic recurrence after receiving optimum amounts of irradiation. With improved radiotherapy techniques, the number of patients with isolated central failure is steadily diminishing, but there remains a significant number of patients with recurrent cancer of the cervix after radiation therapy for whom the procedure offers the only chance for life. Each patient must be assessed individually, with the risks of the procedure weighed against the possible benefits. Technical advances continue to reduce the operative mortality and ameliorate the postoperative morbidity associated with pelvic exenteration.     

The Leeuwenhoek lecture 2006. Microscopy goes cold: frozen viruses reveal their structural secrets

The electron microscope provides a powerful tool for investigating the structure of biological complexes such as viruses. A modern instrument is fully capable of atomic resolution on suitable non-biological specimens, but biological materials are difficult to preserve, owing to their fragility, and to image, owing to their radiation, sensitivity. The act of imaging the specimen severely damages it. Originally, samples were prepared by staining with a heavy metal salt, which provides a stable specimen but limits the amount of details that can be retrieved. Now particulate specimens, such as viruses, are prepared by rapid freezing of unstained material and observed in a frozen state with low doses of electrons. The resulting images require extensive computer processing to extract fully detailed three-dimensional information about the specimen. The whole process is referred to as single-particle electron cryomicroscopy. Using this approach, the structure of the human hepatitis B virus core was solved at the level of the protein fold. By comparing maps of RNA- and DNA-containing cores, it was possible to propose a model for the maturation and control of the envelopment of the virus during assembly. These examples show that cryomicroscopy offers great potential for understanding the structure and function of complex biological assemblies.