RNA metabolism: putting the brake on the UPR

The unfolded protein response (UPR) is a major signaling cascade that determines cell fate under conditions of endoplasmic reticulum (ER) stress. The kinetics and amplitude of UPR responses are tightly controlled by several feedback loops and the expression of positive and negative regulators. In this issue of EMBO Reports, the Wilkinson lab uncovers a novel function of nonsense‐mediated RNA decay (NMD) in fine‐tuning the UPR 1 . NMD is an mRNA quality control mechanism known to destabilize aberrant mRNAs that contain premature termination codons. In this work, NMD was shown to determine the threshold of stress necessary to activate the UPR, in addition to adjusting the amplitude of downstream responses and the termination phase. These effects were mapped to the control of the mRNA stability of IRE1, a major ER stress transducer. This study highlights the dynamic crosstalk between mRNA metabolism and the proteostasis network demonstrating the physiological relevance of normal mRNA regulation by the NMD pathway.     

Targeting autophagy in ALS: a complex mission

Several neurodegenerative diseases share a common neuropathology, primarily featuring the presence of abnormal protein inclusions in the brain containing specific misfolded proteins. Strategies to decrease the load of protein aggregates and oligomers are considered relevant targets for therapeutic intervention. Many studies indicate that macroautophagy is a selective and efficient mechanism for the degradation of misfolded mutant proteins related to neurodegeneration, without affecting the levels of the corresponding wild-type form. In fact, activation of autophagy by rapamycin treatment decreases the accumulation of protein aggregates and alleviates disease features in animal models of Huntington disease and other disorders affecting the nervous system. Recent evidence, however, indicates that the expression of several disease-related genes may actually impair autophagy activity at different levels, including omegasome formation, substrate recognition, lysosomal acidity and autophagosome membrane nucleation. A recent report from Zhang and co-workers indicates that treatment of an amyotrophic lateral sclerosis (ALS) mouse model with rapamycin actually exacerbates neuronal loss and disease progression, associated with enhanced apoptosis. This study reflects the need for a better understanding of the contribution of autophagy to ALS and other neurodegenerative diseases since this pathway may not only operate as a cleaning-up mechanism. Then, autophagy impairment may be part of the pathological mechanisms underlying the disease, whereas augmenting autophagy levels above a certain threshold could lead to detrimental effects in neuronal function and survival. Combinatorial strategies to repair the autophagy deficit and also enhance the activation of the pathway may result in a beneficial impact to decrease the content of protein aggregates and damaged organelles, improving neuronal function and survival.     

Does Tinnitus Distress Depend on Age of Onset?

Objectives

Tinnitus is the perception of a sound in the absence of any physical source of it. About 5–15% of the population report hearing such a tinnitus and about 1–2% suffer from their tinnitus leading to anxiety, sleep disorders or depression. It is currently not completely understood why some people feel distressed by their tinnitus, while others don''t. Several studies indicate that the amount of tinnitus distress is associated with many factors including comorbid anxiety, comorbid depression, personality, the psychosocial situation, the amount of the related hearing loss and the loudness of the tinnitus. Furthermore, theoretical considerations suggest an impact of the age at tinnitus onset influencing tinnitus distress.

Methods

Based on a sample of 755 normal hearing tinnitus patients we tested this assumption. All participants answered a questionnaire on the amount of tinnitus distress together with a large variety of clinical and demographic data.

Results

Patients with an earlier onset of tinnitus suffer significantly less than patients with an onset later in life. Furthermore, patients with a later onset of tinnitus describe their course of tinnitus distress as more abrupt and distressing right from the beginning.

Conclusion

We argue that a decline of compensatory brain plasticity in older age accounts for this age-dependent tinnitus decompensation.     

Beiträge zur Physiologie der Pigmentbildung in belichteten etiolierten Blättern

Ohne Zusammenfassung     

Physiological costs of growing fast: does accelerated growth reduce pay-off in adult fitness?

Accumulating evidence suggests that, in contrast to earlier assumptions, juvenile growth rates are optimised by means of natural and sexual selection rather than maximised to be as fast as possible. Owing to the generally accepted advantage of growing fast to adulthood, such adaptive variation strongly implies the existence of costs attached to rapid growth. By using four populations of protandrous copper butterflies with known differences in intrinsic growth rates within and across populations, we investigate a potential trade-off between rapid growth and the proportionate weight loss at metamorphosis. While controlling for effects of pupal time and mass, we demonstrate that (1) protandrous males, exhibiting higher growth rates, suffer a higher weight loss than females throughout, that (2) population differences in weight loss generally follow known differences in growth rates, and that (3) males have by 6 higher metabolic rates than females during pupal development. These results support the notion that a higher weight loss during the development to adulthood may comprise a physiological cost of rapid development, with the pay-off of accelerated growth being reduced by a disproportionally smaller adult sizeCo-ordinating editor: Leimer     

Trimeric membrane-anchored gp41 inhibits HIV membrane fusion

The HIV-1 envelope glycoprotein is composed of a receptor binding subunit, gp120 that is non-covalently linked to the membrane-anchored fusion protein, gp41. Triggered by cellular receptor binding, the trimeric envelope complex mediates the fusion of viral and cellular membranes through the rearrangement of the fusion protein subunit into a six-helical bundle core structure. Here we describe the biophysical and functional properties of a membrane-anchored fragment of gp41 (gp41ctm) that includes the complete C-terminal heptad repeat region 2, the connecting part, and the transmembrane region. We show that the transmembrane domain of the envelope glycoprotein is sufficient for trimerization in vitro, contributing most of the alpha-helical content of gp41ctm. Trimeric gp41ctm is protease-resistant and recognizes neutralizing antibodies 2F5 and 4E10. However, gp41ctm and gp41ctm proteoliposomes elicit no clear neutralizing immune responses in preliminary mouse studies. We further show that gp41ctm and surprisingly also gp41ctm proteoliposomes have potent anti-viral activity. Our data suggest that liposome-anchored gp41ctm exerts its inhibitory action outside of the initial fusion contact site, and its implications for the fusion reaction are discussed.