The innate immune system in the intestine

The innate immune system provides the first line of host defense against invading pathogens. Innate immune responses are initiated by germline-encoded PRR, which recognize specific structures expressed by microorganisms. TLR are a family of PRR which sense a wide range of microorganisms, including bacteria, fungi, protozoa and viruses. TLR are also expressed in the intestine and are critical for intestinal homeostasis. Recently, cytoplasmic PRR, such as NLR and RLR, have been shown to detect pathogens that have invaded the cytosol. One of the NLR, NOD2, is thought to be involved in the pathogenesis of Crohn's disease. This review focuses on the innate immune responses triggered by PRR in the intestine.     

Sde2 is an intron‐specific pre‐mRNA splicing regulator activated by ubiquitin‐like processing

The expression of intron‐containing genes in eukaryotes requires generation of protein‐coding messenger RNAs (mRNAs) via RNA splicing, whereby the spliceosome removes non‐coding introns from pre‐mRNAs and joins exons. Spliceosomes must ensure accurate removal of highly diverse introns. We show that Sde2 is a ubiquitin‐fold‐containing splicing regulator that supports splicing of selected pre‐mRNAs in an intron‐specific manner in Schizosaccharomyces pombe. Both fission yeast and human Sde2 are translated as inactive precursor proteins harbouring the ubiquitin‐fold domain linked through an invariant GGKGG motif to a C‐terminal domain (referred to as Sde2‐C). Precursor processing after the first di‐glycine motif by the ubiquitin‐specific proteases Ubp5 and Ubp15 generates a short‐lived activated Sde2‐C fragment with an N‐terminal lysine residue, which subsequently gets incorporated into spliceosomes. Absence of Sde2 or defects in Sde2 activation both result in inefficient excision of selected introns from a subset of pre‐mRNAs. Sde2 facilitates spliceosomal association of Cactin/Cay1, with a functional link between Sde2 and Cactin further supported by genetic interactions and pre‐mRNA splicing assays. These findings suggest that ubiquitin‐like processing of Sde2 into a short‐lived activated form may function as a checkpoint to ensure proper splicing of certain pre‐mRNAs in fission yeast.     

Is histoaspartic protease a serine protease with a pepsin‐like fold?

The primary structure of the so-called histoaspartic protease from Plasmodium falciparum has a very high percentage of identity and homology with the pepsin-like enzyme plasmepsin II. A homology modeling approach was used to calculate the three-dimensional structure of the enzyme. Molecular dynamics (MD) simulations were applied to find those structural properties of the histoaspartic protease that had a tendency to remain stable during all runs. The results have shown that hydrogen-bonded residues Ser37-His34-Asp214 are arranged without any strain, in a manner that resembles the active site of a serine protease, while Ser38 and Asn39 take up positions appropriate to formation of an oxyanion hole. Although there are several important differences between the enzyme and plasmepsin II, all of the structural features associated with a typical pepsin-like aspartic protease are present in the final model of the histoaspartic protease. A possibility that this enzyme may function as a serine protease is discussed.     

Ovariectomy in grasshoppers increases somatic storage, but proportional allocation of ingested nutrients to somatic tissues is unchanged

Reduced reproduction increases storage and extends lifespan in several animal species. The disposable soma hypothesis suggests this life extension occurs by shifting allocation of ingested nutrients from reproduction to the soma. A great deal of circumstantial evidence supports this hypothesis, but no direct tracking of nutrients has been performed in animals that are long-lived because of direct reduction in reproduction. Here, we use the stable isotopes to track carbon and nitrogen from ingestion to somatic organs in long-lived, ovariectomized grasshoppers. Three estimates of somatic storage (viz., quantity of hemolymph storage proteins, amount of femur muscle carbohydrates, and size of the fat body) all doubled upon ovariectomy. In stark contrast, ovariectomy did not increase the proportion of these tissues that were made from recently ingested foods. In other words, the physiology underlying relative allocation to these somatic tissues was not affected by ovariectomy. Thus, at the level of whole tissue storage, these results are consistent with a trade-off between reproduction and longevity. In contrast, our stable isotope data are inconsistent with the prediction that enhanced storage in ovariectomized females results from a physiological shift in allocation of ingested nutrients.