Quality control compartments coming of age

Maintenance of proteome integrity (proteostasis) is essential for cellular and organismal survival. Various cellular mechanisms work to preserve proteostasis by ensuring correct protein maturation and efficient degradation of misfolded and damaged proteins. Despite this cellular effort, under certain circumstances subsets of aggregation-prone proteins escape the quality control surveillance, accumulate within the cell and form insoluble aggregates that can lead to the development of disorders including late-onset neurodegenerative diseases. Cells respond to the appearance of insoluble aggregates by actively transporting them to designated deposition sites where they often undergo degradation. Although several protein aggregate deposition sites have been described and extensively studied, key questions regarding their biological roles and how they are affected by aging remained unanswered. Here we review the recent advances in the field, describe the different subtypes of these cellular compartments and outline the evidence that these structures change their properties over time. Finally, we propose models to explain the possible mechanistic links between aggregate deposition sites, neurodegenerative disorders and the aging process.     

Recursive construction of perfect DNA molecules from imperfect oligonucleotides

Making faultless complex objects from potentially faulty building blocks is a fundamental challenge in computer engineering, nanotechnology and synthetic biology. Here, we show for the first time how recursion can be used to address this challenge and demonstrate a recursive procedure that constructs error‐free DNA molecules and their libraries from error‐prone oligonucleotides. Divide and Conquer (D&C), the quintessential recursive problem‐solving technique, is applied in silico to divide the target DNA sequence into overlapping oligonucleotides short enough to be synthesized directly, albeit with errors; error‐prone oligonucleotides are recursively combined in vitro, forming error‐prone DNA molecules; error‐free fragments of these molecules are then identified, extracted and used as new, typically longer and more accurate, inputs to another iteration of the recursive construction procedure; the entire process repeats until an error‐free target molecule is formed. Our recursive construction procedure surpasses existing methods for de novo DNA synthesis in speed, precision, amenability to automation, ease of combining synthetic and natural DNA fragments, and ability to construct designer DNA libraries. It thus provides a novel and robust foundation for the design and construction of synthetic biological molecules and organisms.     

Detection and molecular characterization of 9,000-year-old Mycobacterium tuberculosis from a Neolithic settlement in the Eastern Mediterranean

Background

Mycobacterium tuberculosis is the principal etiologic agent of human tuberculosis. It has no environmental reservoir and is believed to have co-evolved with its host over millennia. This is supported by skeletal evidence of the disease in early humans, and inferred from M. tuberculosis genomic analysis. Direct examination of ancient human remains for M. tuberculosis biomarkers should aid our understanding of the nature of prehistoric tuberculosis and the host/pathogen relationship.

Methodology/Principal Findings

We used conventional PCR to examine bone samples with typical tuberculosis lesions from a woman and infant, who were buried together in the now submerged site of Atlit-Yam in the Eastern Mediterranean, dating from 9250-8160 years ago. Rigorous precautions were taken to prevent contamination, and independent centers were used to confirm authenticity of findings. DNA from five M tuberculosis genetic loci was detected and had characteristics consistent with extant genetic lineages. High performance liquid chromatography was used as an independent method of verification and it directly detected mycolic acid lipid biomarkers, specific for the M. tuberculosis complex.

Conclusions/Significance

Human tuberculosis was confirmed by morphological and molecular methods in a population living in one of the first villages with evidence of agriculture and animal domestication. The widespread use of animals was not a source of infection but may have supported a denser human population that facilitated transmission of the tubercle bacillus. The similarity of the M. tuberculosis genetic signature with those of today gives support to the theory of a long-term co-existence of host and pathogen.     

Proline-Rich Peptide from the Coral Pathogen Vibrio shiloi That Inhibits Photosynthesis of Zooxanthellae

The coral-bleaching bacterium Vibrio shiloi biosynthesizes and secretes an extracellular peptide, referred to as toxin P, which inhibits photosynthesis of coral symbiotic algae (zooxanthellae). Toxin P was produced during the stationary phase when the bacterium was grown on peptone or Casamino Acids media at 29°C. Glycerol inhibited the production of toxin P. Toxin P was purified to homogeneity, yielding the following 12-residue peptide: PYPVYAPPPVVP (molecular weight, 1,295.54). The structure of toxin P was confirmed by chemical synthesis. In the presence of 12.5 mM NH₄Cl, pure natural or synthetic toxin P (10 μM) caused a 64% decrease in the photosynthetic quantum yield of zooxanthellae within 5 min. The inhibition was proportional to the toxin P concentration. Toxin P bound avidly to zooxanthellae, such that subsequent addition of NH₄Cl resulted in rapid inhibition of photosynthesis. When zooxanthellae were incubated in the presence of NH₄Cl and toxin P, there was a rapid decrease in the pH (pH 7.8 to 7.2) of the bulk liquid, suggesting that toxin P facilitates transport of NH₃ into the cell. It is known that uptake of NH₃ into cells can destroy the pH gradient and block photosynthesis. This mode of action of toxin P can help explain the mechanism of coral bleaching by V. shiloi.     

Small-grained wild grasses as staple food at the 23 000-year-old site of Ohalo II,Israel

More than 16 000 grains of small-grained grasses were retrieved at Ohalo II, a submerged 23 000-year-old site on the shore of the Sea of Galilee, Israel. The grains were part of a very large archaeobotanical assemblage, unique for its period and region, as well as its exceptionally good preservation. This paper proposes that these grains were a staple food at Ohalo II, based on several lines of evidence: 1. the large number of grains found; 2. the fact that all grains were fully mature; and 3. ethnographic parallels for the use of small-grained grasses in hunter-gatherers’ societies as well as among present-day agriculturalists.     

Electron microscopical analysis of surface charge labelling density at various stages of the erythroid line

Summary With use of the positively charged, colloidal ferric oxide labelling technique for electron microscopy of sections of rabbit marrow, a reduction in labelling density on the surface of differentiating red cell precursors was demonstrated. The number of iron particles per unit length of membrane was counted. A progressive diminution in labelling density follows cell division, reaching a minimum in the orthochromatic erythroblast, from which the nucleus is expelled. A slight increase in charge density is noted in the reticulocyte, and further increase is observed with its maturation to the erythrocyte. The results indicate that biosynthesis of n-acetyl neuraminic acid stops at the earliest recognizable stage of erythroid differentiation.The Patrick E. Gorman Professor of Biological Ultrastructure.     

Cytokinin Activity in Avocado Seeds during Fruit Development

The soybean callus bioassay was used to determine levels of cytokinin activity in avocado (Persea americana) seeds.     

Structural and thermodynamic characterization of the Escherichia coli RelBE toxin-antitoxin system: indication for a functional role of differential stability

The RelE and RelB proteins constitute the RNA interferase (toxin) and its cognate inhibitor (antitoxin) components of the Escherichia coli relBE toxin-antitoxin system. Despite the well-described functionality and physiological activity of this system in E. coli, no structural study was performed on the folding and stability of the protein pair in solution. Here we structurally and thermodynamically characterize the RelBE system components from E. coli in solution, both separately and in their complexed state. The RelB antitoxin, an alpha-helical protein according to circular dichroism and infrared spectroscopy, forms oligomers in solution, exhibits high thermostability with a TM of 58.5 degrees C, has a considerable heat resistance, and has high unfolding reversibility. In contrast, the RelE toxin includes a large portion of antiparallel beta-sheets, displays lower thermostability with a TM of 52.5 degrees C, and exhibits exceptional sensitivity to heat. Complex formation, accompanied by a structural transition, leads to a 12 degrees C increase in the TM and substantial heat resistance. Moreover, in vivo interaction and protein footprint experiments indicate that the C-terminal part of RelB is responsible for RelB-RelE interaction, being protease sensitive in its free state, while it becomes protected from proteolysis when complexed with RelE. Overall, our findings support the notion that RelB lacks a well-organized hydrophobic core in solution whereas RelE is a well-folded protein. Furthermore, our results support that RelB protein from E. coli is similar to ParD and CcdA antitoxins in both fold and thermodynamic properties. The differential folding state of the proteins is discussed in the context of their physiological activities.