Plasma-based approach to measure target engagement for liver-targeting stearoyl-CoA desaturase 1 inhibitors

A positive correlation between stearoyl-CoA desaturase (SCD)1 expression and metabolic diseases has been reported in rodents and humans. These findings indicate that SCD1 is a promising therapeutic target for the chronic treatment of diabetes and dyslipidemia. The SCD1 enzyme is expressed at high levels in several human tissues and is required for the biosynthesis of monounsaturated fatty acids, which are involved in many biological processes. Liver-targeted SCD inhibitors were designed to pharmacologically manipulate SCD1 activity in the liver to avoid adverse events due to systemic inhibition. This article describes the development of a plasma-based SCD assay to assess the level of SCD inhibition, which is defined in this article as target engagement. Essentially, animals are dosed with an exogenous deuterated tracer (d7-stearic acid) as substrate, and the converted d7-oleic acid product is measured to monitor SCD1 inhibition. This study reveals that this plasma-based assay correlates with liver SCD1 inhibition and can thus have clinical utility.     

The MMS22L-TONSL complex mediates recovery from replication stress and homologous recombination

Genome integrity is jeopardized each time DNA replication forks stall or collapse. Here we report the identification of a complex composed of MMS22L (C6ORF167) and TONSL (NFKBIL2) that participates in the recovery from replication stress. MMS22L and TONSL are homologous to yeast Mms22 and plant Tonsoku/Brushy1, respectively. MMS22L-TONSL accumulates at regions of ssDNA associated with distressed replication forks or at processed DNA breaks, and its depletion results in high levels of endogenous DNA double-strand breaks caused by an inability to complete DNA synthesis after replication fork collapse. Moreover, cells depleted of MMS22L are highly sensitive to camptothecin,?a topoisomerase I poison that impairs DNA replication progression. Finally, MMS22L and TONSL are necessary for the efficient formation of RAD51 foci after DNA damage, and their depletion impairs homologous recombination. These results indicate that MMS22L and TONSL are genome caretakers that stimulate the recombination-dependent repair of stalled or collapsed replication forks.     

Knee biomechanics of moderate OA patients measured during gait at a self-selected and fast walking speed

Osteoarthritis (OA) is a chronic disorder resulting in degenerative changes to the knee joint. Three-dimensional gait analysis provides a unique method of measuring knee dynamics during activities of daily living such as walking. The purpose of this study was to identify biomechanical features characterizing the gait of patients with mild-to-moderate knee OA and to determine if the biomechanical differences become more pronounced as the locomotor system is stressed by walking faster. Principal component analysis was used to compare the gait patterns of a moderate knee OA group (n=41) and a control group (n=43). The subjects walked at their self-selected speed as well as at 150% of that speed. The two subject groups did not differ in knee joint angles, stride length, and stride time or walking speed. Differences in the magnitude and shape of the knee joint moment waveforms were found between the two groups. The OA group had larger adduction moment magnitudes during stance and this higher magnitude was sustained for a longer portion of the gait cycle. The OA group also had a reduced flexion moment and a reduced external rotation moment during early stance. Increasing speed was associated with an increase in the magnitude of all joint moments. The fast walks did not, however, increase or bring out any biomechanical differences between the OA and control groups that did not exist at the self-selected walks.     

The J-domain of Hsp40 couples ATP hydrolysis to substrate capture in Hsp70

The Escherichia coli Hsp40 DnaJ uses its J-domain to target substrate polypeptides for binding to the Hsp70 DnaK, but the mechanism of J-domain function has been obscured by a substrate-like interaction between DnaJ and DnaK. ATP hydrolysis in DnaK is associated with a conformational change that captures the substrate, and both DnaJ and substrate can stimulate ATP hydrolysis. However, substrates cannot trigger capture by DnaK in the presence of ATP, and substrates stimulate a DnaK conformational change that is uncoupled from ATP hydrolysis. The role of the J-domain was examined using the fluorescent derivative of a fusion protein composed of the J-domain and a DnaK-binding peptide. In the absence of ATP, DnaK-binding affinity of the fusion protein is similar to that of the unfused peptide. However, in the presence of ATP, the affinity of the fusion protein is dramatically increased, which is opposite to the decrease in DnaK affinity typically exhibited by peptides. Binding of a fusion protein that contains a defective J-domain is insensitive to ATP. According to results from isothermal titration calorimetry, the J-domain binds to the DnaK ATPase domain with weak affinity (K(D) = 23 microM at 20 degrees C). The interaction is characterized by a positive enthalpy, small heat capacity change (DeltaC(p)= -33 kcal mol(-1)), and increasing binding affinity for increasing temperatures in the physiological range. In conditions that support binding of the J-domain to the ATPase domain, the J-domain accelerates ATP hydrolysis and a simultaneous conformational change in DnaK that is associated with peptide capture. The defective J-domain is inactive, despite the fact that it binds to the DnaK ATPase domain with higher than wild-type affinity. The results are most consistent with an allosteric mechanism of J-domain action in which the J-domain couples ATP hydrolysis to peptide capture by accelerating ATP hydrolysis and delaying DnaK closure until ATP is hydrolyzed.     

Intracellular distribution of lysosomal sialidase is controlled by the internalization signal in its cytoplasmic tail

Sialidase (neuraminidase), encoded by the neu-1 gene in the major histocompatibility complex locus catalyzes the intralysosomal degradation of sialylated glycoconjugates. Inherited deficiency of sialidase results in sialidosis or galactosialidosis, both severe metabolic disorders associated with lysosomal storage of oligosaccharides and glycopeptides. Sialidase also plays an important role in cellular signaling and is specifically required for the production of cytokine interleukin-4 by activated T lymphocytes. In these cells, neu-1-encoded sialidase activity is increased on the cell surface, suggesting that a specific mechanism regulates sorting of this enzyme to the plasma membrane. We investigated that mechanism by first showing that sialidase contains the internalization signal found in lysosomal membrane proteins targeted to endosomes via clathrin-coated pits. The signal consists of a C-terminal tetrapeptide (412)YGTL(415), with Tyr(412) and Leu(415) essential for endocytosis of the enzyme. We further demonstrated that redistribution of sialidase from lysosomes to the cell surface of activated lymphocytes is accompanied by increased reactivity of the enzyme with anti-phosphotyrosine antibodies. We speculate that phosphorylation of Tyr(412) results in inhibition of sialidase internalization in activated lymphocytes.     

Evolutionary rescue by compensatory mutations is constrained by genomic and environmental backgrounds

Since deleterious mutations may be rescued by secondary mutations during evolution, compensatory evolution could identify genetic solutions leading to therapeutic targets. Here, we tested this hypothesis and examined whether these solutions would be universal or would need to be adapted to one's genetic and environmental makeups. We performed experimental evolutionary rescue in a yeast disease model for the Wiskott–Aldrich syndrome in two genetic backgrounds and carbon sources. We found that multiple aspects of the evolutionary rescue outcome depend on the genotype, the environment, or a combination thereof. Specifically, the compensatory mutation rate and type, the molecular rescue mechanism, the genetic target, and the associated fitness cost varied across contexts. The course of compensatory evolution is therefore highly contingent on the initial conditions in which the deleterious mutation occurs. In addition, these results reveal biologically favored therapeutic targets for the Wiskott–Aldrich syndrome, including the target of an unrelated clinically approved drug. Our results experimentally illustrate the importance of epistasis and environmental evolutionary constraints that shape the adaptive landscape and evolutionary rate of molecular networks.     

Activation of Ca2+-dependent processes during heat shock: role in cell thermoresistance

In this brief review, it is proposed that some Ca2+-dependent processes are induced upon subjecting cells to hyperthermic temperature, and play an essential role in the final cell responses. The triggering signal does not involve external Ca2+. Instead, it is most likely to be generated by a redistribution of Ca2+ between the internal pools. A role for heat-induced Ca2+-dependent processes is supported by findings that Ca2+-active agents such as chelators, ionophores, or anticalmodulin drugs modify the cytotoxic action of hyperthermia and that some heat shock proteins are calmodulin-binding proteins. Furthermore, within minutes at hyperthermic temperature, changes are observed in the pattern of phosphoproteins suggesting that heat shock activates kinase or phosphatase activities, processes which are often mediated by Ca2+. Suggestive evidence that these phosphorylation events are determinants of cell thermoresistance is provided by the fact that one of these proteins whose phosphorylation changes rapidly upon hyperthermia is a heat shock protein (HSP28) and that the content of HSP28 is elevated not only in thermotolerant cells but also in a family of thermoresistant variants isolated after mutagenesis of Chinese hamster cells.     

The Hsp40 J‐domain modulates Hsp70 conformation and ATPase activity with a semi‐elliptical spring

Regulatory protein interactions are commonly attributed to lock‐and‐key associations that bring interacting domains together. However, studies in some systems suggest that regulation is not achieved by binding interactions alone. We report our investigations on specific physical characteristics required of the Hsp40 J‐domain to stimulate ATP hydrolysis in the Hsp40‐Hsp70 molecular chaperone machine. Biophysical analysis using isothermal titration calorimetry, and nuclear magnetic resonance spectroscopy reveals the importance of helix rigidity for the maintenance of Hsp40 function. Our results suggest that the functional J‐domain acts like a semi‐elliptical spring, wherein the resistance to bending upon binding to the Hsp70 ATPase modulates the ATPase domain conformational change and promotes ATP hydrolysis.     

A rapid assay for chloroplast-encoded triazine resistance in higher plants

We have designed a simple and rapid assay for chloroplast-based triazine resistance in higher plants using PCR amplification of thepsbA gene coupled toMaeI digestion of the amplified product to distinguish triazine resistant from sensitive biotypes. Our assay is universal and avoids the need of lengthy procedures of previously published assays, which either required spraying of seedlings in a controlled environment, quantification of chlorophyll fluorescence of leaf discs after incubation in triazine solution, DNA sequencing of thepsbA gene, or Southern-blot analysis. Our diagnostic system is qualitative, reliable, fast and simple. More than 100 seedlings taken directly from the field can be analyzed in one day. This system has a direct application towards a more rational use of herbicides in production fields. It also represents a valuable tool to monitor spreading of resistant biotypes through time and space and can serve as a model system applicable to other gene monitoring needs.