Evolution of the repression mechanisms in circadian clocks

Background Circadian (daily) timekeeping is essential to the survival of many organisms. An integral part of all circadian timekeeping systems is negative feedback between an activator and repressor. However, the role of this feedback varies widely between lower and higher organisms. Results Here, we study repression mechanisms in the cyanobacterial and eukaryotic clocks through mathematical modeling and systems analysis. We find a common mathematical model that describes the mechanism by which organisms generate rhythms; however, transcription’s role in this has diverged. In cyanobacteria, protein sequestration and phosphorylation generate and regulate rhythms while transcription regulation keeps proteins in proper stoichiometric balance. Based on recent experimental work, we propose a repressor phospholock mechanism that models the negative feedback through transcription in clocks of higher organisms. Interestingly, this model, when coupled with activator phosphorylation, allows for oscillations over a wide range of protein stoichiometries, thereby reconciling the negative feedback mechanism in Neurospora with that in mammals and cyanobacteria. Conclusions Taken together, these results paint a picture of how circadian timekeeping may have evolved.

Impaired LAIR-1-mediated immune control due to collagen degradation in fibrosis

SummaryTissue repair is disturbed in fibrotic diseases like systemic sclerosis (SSc), where the deposition of large amounts of extracellular matrix components such as collagen interferes with organ function. LAIR-1 is an inhibitory collagen receptor highly expressed on tissue immune cells. We questioned whether in SSc, impaired LAIR-1-collagen interaction is contributing to the ongoing inflammation and fibrosis.We found that SSc patients do not have an intrinsic defect in LAIR-1 expression or function. Instead, fibroblasts from SSc patients deposit disorganized collagen products in vitro, which are dysfunctional LAIR-1 ligands. This can be mimicked in healthy fibroblast stimulated by soluble factors that drive inflammation and fibrosis in SSc and is dependent of matrix metalloproteinases and platelet-derived growth factor receptor signaling.In support of a non-redundant role of LAIR-1 in the control of fibrosis, we found that LAIR-1-deficient mice have increased skin fibrosis in the bleomycin mouse model for SSc. Thus, LAIR-1 represents an essential control mechanism for tissue repair. In fibrotic disease, excessive collagen degradation may lead to a disturbed feedback loop. The presence of functional LAIR-1 in patients provides a therapeutic opportunity to reactivate this intrinsic negative feedback mechanism in fibrotic diseases.Abstract Figure

Maternal starvation primes progeny response to nutritional stress

Organisms adapt to environmental changes in order to survive. Mothers exposed to nutritional stresses can induce an adaptive response in their offspring. However, the molecular mechanisms behind such inheritable links are not clear. Here we report that in Drosophila, starvation of mothers primes the progeny against subsequent nutritional stress. We found that RpL10Ab represses TOR pathway activity by genetically interacting with TOR pathway components TSC2 and Rheb. In addition, starved mothers produce offspring with lower levels of RpL10Ab in the germline, which results in higher TOR pathway activity, conferring greater resistance to starvation-induced oocyte loss. The RpL10Ab locus encodes for the RpL10Ab mRNA and a stable intronic sequence RNA (sisR-8), which collectively repress RpL10Ab pre-mRNA splicing in a negative feedback mechanism. During starvation, an increase in maternally deposited RpL10Ab and sisR-8 transcripts leads to the reduction of RpL10Ab expression in the offspring. Our study suggests that the maternally deposited RpL10Ab and sisR-8 transcripts trigger a negative feedback loop that mediates intergenerational adaptation to nutritional stress as a starvation response.

Ca2+-inactivation of the mammalian ryanodine receptor type 1 in a lipidic environment revealed by cryo-EM

Activation of the intracellular Ca2+ channel ryanodine receptor (RyR) triggers a cytosolic Ca2+ surge, while elevated cytosolic Ca2+ inhibits the channel in a negative feedback mechanism. Cryo-EM carried out under partially inactivating Ca2+ conditions revealed two conformations of RyR1, an open state and an inactivated state, resolved at 4.0 and 3.3 Angstroms resolution, respectively. RyR1s were embedded in nanodiscs with two lipids resolved at each inter-subunit crevice. Ca2+ binding to the high affinity site engages the central (CD) and C-terminal domains (CTD) into a quasi-rigid unit, which separates the S6 four-helix bundle and opens the channel. Further out-of-plane rotation of the quasi-rigid unit pushes S6 towards the central axis, closing (inactivating) the channel. The inactivated conformation is characterized by a downward conformation of the cytoplasmic assembly, a tightly-knit subunit interface contributed by a fully occupied and partially remodeled Ca2+ activation site, and two salt bridges between the EF hand domain and the S2-S3 loop of the neighboring subunit validated by naturally-occurring disease-causing mutations. Ca2+ also bound to ATP, mediating a tighter interaction between S6 and CTD. Our study suggests that the closed-inactivated is a distinctive state of the RyR1 and its transition to the closed-activable state is not a simple reverse of the Ca2+ mediated activation pathway.

Effect of Winter Feeding Frequency on Growth Performance, Biochemical Blood Parameters, Oxidative Stress, and Appetite-Related Genes in Takifugu Rubripes

We evaluated the effect of winter feeding frequencies (F1: one daily meal; F2: two daily meals; F3: four daily meals; F4: continuous diurnal feeding using a belt feeder) on the growth performance, biochemical blood parameters, oxidative stress, and appetite-related genes in Takifugu rubripes held at a constant temperature (18.0 ± 1.0°C) for 60 days. The results showed that the final weight, weight gain rate, specific growth rate, and survival of tiger puffer in the F3 group showed the best growth performance. The total cholesterol, triglyceride, and glucose levels were significantly higher with the increased feeding frequency. We also observed the antioxidant enzymes (superoxide dismutase, catalase, glutathione, and glutathione peroxidase) and the digestive enzyme activities (trypsin, amylase, and lipase) in tiger puffers cultured in the F1 group were significantly higher than those in the F3 and F4 groups. In addition, the tiger puffers in the F1 group exhibited the highest expression of orexin and the lowest contents of glucose, tachykinin, cholecystokinin, and leptin among all the groups. In contrast, the mRNA levels of tachykinin, cholecystokinin, and leptin in the tiger puffers in the F4 group may be attributed to the negative feedback mechanism in the brain-hypothalamus-neuropeptide axis. All parameters exhibited relatively optimal levels in the F3 group. In conclusion, inappropriate feeding frequencies could have negative effects on growth and physiological indicators. The optimal feeding frequency for enhanced growth performance while maintaining a relatively good physical condition in juveniles of this species was four times a day.

Prospects for the use of collagen-containing matrices in directed tissue regeneration. Literature review

Studies of recent decades have convincingly shown that collagen in connective tissue plays not only a structural role. In the 80s of the XX centu[1]ry, A. Pishinger and H. Heine suggested the informative-regulatory role of collagen in the extracellular matrix (A. Pischinger, 1990). In recent years, the morphogenetic function of collagen has been actively studied, the implementation of which is possible due to the presence of collagen re[1]ceptors on the surface of various cell populations, such as platelets and fibroblasts. Collagen regulates the remodeling of the extracellular matrix (J. D. San Antonio et al., 2020). At the same time, its decay products, which stimulate growth by the negative feedback mechanism, are probably of great importance. In general, the relationship between the synthesis and breakdown of collagen is of fundamental importance for the regulation of connective tissue growth.

Riboflavin transporter SLC52A1, a target of p53, suppresses cellular senescence by activating mitochondrial complex II

Cellular senescence is a state of permanent proliferative arrest induced by a variety of stresses, such as DNA damage. The transcriptional activity of p53 has been known to be essential for senescence induction. It remains unknown, however, whether among the downstream genes of p53, there is a gene that has anti-senescence function. Our recent studies have indicated that the expression of SLC52A1 (also known as GPR172B/RFVT1), a riboflavin transporter, is upregulated specifically in senescent cells depending on p53, but the relationship between senescence and SLC52A1 or riboflavin has not been described. Here, we examined the role of SLC52A1 in senescence. We found that knockdown of SLC52A1 promoted senescence phenotypes induced by DNA damage in tumor and normal cells. The senescence suppressive-action of SLC52A1 was dependent on its riboflavin transport activity. Furthermore, elevation of intracellular riboflavin led to activation of mitochondrial membrane potential (MMP) mediated by the mitochondrial electron transport chain complex II. Finally, the SLC52A1-dependent activation of MMP inhibited the AMPK-p53 pathway, a central mediator of mitochondria dysfunction-related senescence. These results suggest that SLC52A1 contributes to suppress senescence through the uptake of riboflavin and acts downstream of p53 as a negative feedback mechanism to limit aberrant senescence induction.

Comprehensive Mechanism of Gene Silencing and Its Role in Plant Growth and Development

Gene silencing is a negative feedback mechanism that regulates gene expression to define cell fate and also regulates metabolism and gene expression throughout the life of an organism. In plants, gene silencing occurs via transcriptional gene silencing (TGS) and post-transcriptional gene silencing (PTGS). TGS obscures transcription via the methylation of 5′ untranslated region (5′UTR), whereas PTGS causes the methylation of a coding region to result in transcript degradation. In this review, we summarized the history and molecular mechanisms of gene silencing and underlined its specific role in plant growth and crop production.

Nodular fasciitis: a comprehensive, time-correlated investigation of 17 cases

The self-limited nature of nodular fasciitis (NF) is well-known but its precise mechanism has not yet been clarified. We observed that “young” NF (preoperative duration <1 month) consistently contains a higher percentage (~80%) of USP6 break-apart FISH signals than “old” NF (preoperative duration >3 months) (~20%). Thus, we hypothesized that our original observation may reflect a connection with the self-limited nature of NF. Seventeen cases with reliable data concerning the onset were selected, thus approximating the lifetime of each tumor. Besides the USP6 interphase FISH examination, we also checked the most common MYH9-USP6 fusion using RT-PCR. Because of the known pathways of the tumorigenesis of NF, the mRNA level of USP6, TRAIL, IFN-beta, JAK1, STAT1, STAT3, JUN, and CDKN2A was measured using qRT-PCR. Regarding proteins, USP6, p16, p27, TRAIL, and IFN-beta were examined using immunohistochemistry. Targeted gene panel next-generation sequencing (NGS) of three cases was additionally performed. We found a strong negative correlation (p = 0.000) between the lifetime and percentage of USP6 break-apart signals and a strong positive relationship (p = 0.000) between USP6 break-apart signals and mitotic counts. Results of immunostainings, along with qRT-PCR results, favored the previously-suggested USP6-induced negative feedback mechanism through activation of TRAIL and IFN-beta, likely resulting in apoptosis and senescence of tumor cells harboring USP6 fusions. Targeted-NGS resulted in the detection of several variants, but no additional recurrent changes in the pathogenesis of these tumors. We revealed on a cellular level the USP6-induced negative feedback mechanism. In conclusion, we emphasize that in “old” NF, the percentage of USP6 break-apart FISH signals can be as low as 14–27% which can be very important from a differential diagnostic point of view. We emphasize that a careful examination and interpretation of the NGS data is needed before clinical decision-making on treatment.

Regulation of Store-Operated Ca2+ Entry by SARAF

Calcium (Ca2+) signaling plays a dichotomous role in cellular biology, controlling cell survival and proliferation on the one hand and cellular toxicity and cell death on the other. Store-operated Ca2+ entry (SOCE) by CRAC channels represents a major pathway for Ca2+ entry in non-excitable cells. The CRAC channel has two key components, the endoplasmic reticulum Ca2+ sensor stromal interaction molecule (STIM) and the plasma-membrane Ca2+ channel Orai. Physical coupling between STIM and Orai opens the CRAC channel and the resulting Ca2+ flux is regulated by a negative feedback mechanism of slow Ca2+ dependent inactivation (SCDI). The identification of the SOCE-associated regulatory factor (SARAF) and investigations of its role in SCDI have led to new functional and molecular insights into how SOCE is controlled. In this review, we provide an overview of the functional and molecular mechanisms underlying SCDI and discuss how the interaction between SARAF, STIM1, and Orai1 shapes Ca2+ signaling in cells.