Comparison of the Activities of Extracts of Escherichia coli and Salmonella typhimurium in Amino Acid Incorporation

We have compared the amino acid incorporating activities of extracts of Escherichia coli and Salmonella typhimurium in in vitro protein-synthesizing systems directed by bacterial messenger ribonucleic acid (mRNA) of both species and by the genomes of coliphages Qbeta and f2. E. coli and S. typhimurium extracts translate both homologous and heterologous bacterial mRNAs at comparable rates. S. typhimurium extracts translate phage RNAs only 10 to 15% as fast as E. coli extracts do. The presence of glucose in the growth medium increases the activity of S. typhimurium extracts three- to fourfold in the phage RNA-directed systems. Glucose has a much more limited effect on the activities of E. coli extracts. We show that similar amounts of phage RNA-ribosome complexes are formed in both the E. coli and the S. typhimurium systems, indicating that the different activities observed may be attributed to different rates of peptide elongation or to the formation of complexes at different sites on the RNA strand.     

Getting to the end of RNA: Structural analysis of protein recognition of 5′ and 3′ termini

The specific recognition by proteins of the 5′ and 3′ ends of RNA molecules is an important facet of many cellular processes, including RNA maturation, regulation of translation initiation and control of gene expression by degradation and RNA interference. The aim of this review is to survey recent structural analyses of protein binding domains that specifically bind to the extreme 5′ or 3′ termini of RNA. For reasons of space and because their interactions are also governed by catalytic considerations, we have excluded enzymes that modify the 5′ and 3′ extremities of RNA. It is clear that there is enormous structural diversity among the proteins that have evolved to bind to the ends of RNA molecules. Moreover, they commonly exhibit conformational flexibility that appears to be important for binding and regulation of the interaction. This flexibility has sometimes complicated the interpretation of structural results and presents significant challenges for future investigations.     

Herbivory in a spider through exploitation of an ant–plant mutualism

Spiders are thought to be strict predators [1]. We describe a novel exception: Bagheera kiplingi, a Neotropical jumping spider (Salticidae) that exploits a well-studied ant–plant mutualism, is predominantly herbivorous. From behavioral field observations and stable-isotope analyses, we show that the main diet of this host-specific spider comprises specialized leaf tips (Beltian food bodies; Figure 1A) from Vachellia spp. ant-acacias (formerly Acacia spp.), structures traded for protection in the plant's coevolved mutualism with Pseudomyrmex spp. ants that inhabit its hollow thorns [2]. This is the first report of a spider that feeds primarily and deliberately on plants.     

Tonic Sympathetic Nervous System Inhibition of Insulin Secretion Is Diminished in Obese Zucker Rats

It has long been known that the central nervous system (CNS) directly affects pancreatic insulin release. This study was undertaken to determine the effect of the CNS on pancreatic insulin release in three-month-old female lean (Fa/Fa) and hyperinsulinemic obese (fa/fa) Zucker rats. Chloral hydrate (400 mg/kg) was used as the anesthetic agent. The in situ brain-pancreas perfusion model with intact pancreatic innervation was used in this investigation. The study measured insulin secretion in response to a 60-minute glucose stimulus (200 mg/dl). CNS-intact and CNS-functionally ablated obese and lean rats were used. During the 60-minute perfusion period significantly more insulin was released by pancreata from obese rats compared to those from lean rats. In lean rats, about twice as much insulin was released by pancreata from CNS-ablated rats than from CNS-intact rats (P < 0.05), demonstrating a CNS tonic inhibition of insulin secretion. In obese rats, there was no significant difference in insulin released by the pancreata of the CNS-intact and CNS-ablated rats. To determine if there was a masking effect of predominant PNS activity over the SNS in the CNS-intact obese rats, bilateral vagotomy was performed in a group of otherwise CNS-intact obese rats prior to the onset of perfusion. Tonic inhibition was still not observed in the CNS-vagotomized obese rats. In conclusion, hypersecretion of insulin in obese rats is partially due to diminished tonic sympathetic nervous system inhibition of insulin release. These results provide additional evidence regarding abnormal CNS control of insulin secretion in obese Zucker rats.