Extra‐mitochondrial localization and likely reproductive function of a female‐transmitted cytochrome c oxidase subunit II protein

Our previous study documented a reproductive function for the male‐transmitted mitochondrial DNA (mtDNA)‐encoded cytochrome c oxidase subunit II (MCOX2) protein in a unionoid bivalve. Here, immunoblotting, immunohistochemistry and immunoelectron microscopy analyses demonstrate that the female‐transmitted protein (FCOX2) is: (i) expressed in both male and female gonads; (ii) maximally expressed in ovaries just prior to the time of the annual fertilization event; (iii) displayed in the cytoplasm and more strongly in the plasma membrane (microvilli), vitelline matrix and vitelline envelope of mature ovarian eggs; and (iv) strongly localized to the vitelline matrix of some eggs just prior to fertilization. These findings represent evidence for the extra‐mitochondrial localization of an mtDNA‐encoded gene product and are consistent with multifunctionality for FCOX2 in eggs.     

Inconsistent detection of extinction debts using different methods

The extinction debt, delayed species extinctions following landscape degradation, is a widely discussed concept. But a consensus about the prevalence of extinctions debts is hindered by a multiplicity of methods and a lack of comparisons among habitats. We applied three contrasting species–area relationship methods to test for plant community extinction debts in three habitats which had different degradation histories over the last century: calcareous grassland, heathland and woodland. These methods differ in their data requirements, with the first two using information on past and current habitat area alongside current species richness, whilst the last method also requires data on past species richness. The most data‐intensive, and hence arguably most reliable method, identified extinction debts across all habitats for specialist species, whilst the other methods did not. All methods detected an extinction debt in calcareous grassland, which had undergone the most severe degradation. We conclude that some methods failed to detect an extinction debt, particularly in habitats that have undergone moderate degradation. Data on past species numbers are required for the most reliable method; as such data are rare, extinction debts may be under‐reported.     

A functional interaction between the MAGUK protein hDlg and the gap junction protein connexin 43 in cervical tumour cells

Gap junctions, composed of Cxs (connexins), allow direct intercellular communication. Gap junctions are often lost during the development of malignancy, although the processes behind this are not fully understood. Cx43 is a widely expressed Cx with a long cytoplasmic C-terminal tail that contains several potential protein-interaction domains. Previously, in a model of cervical carcinogenesis, we showed that the loss of gap junctional communication correlated with relocalization of Cx43 to the cytoplasm late in tumorigenesis. In the present study, we demonstrate a similar pattern of altered expression for the hDlg (human discs large) MAGUK (membrane-associated guanylate kinase) family tumour suppressor protein in cervical tumour cells, with partial co-localization of Cx43 and hDlg in an endosomal/lysosomal compartment. Relocalization of these proteins is not due to a general disruption of cell membrane integrity or Cx targeting. Cx43 (via its C-terminus) and hDlg interact directly in vitro and can form a complex in cells. This novel interaction requires the N- and C-termini of hDlg. hDlg is not required for Cx43 internalization in W12GPXY cells. Instead, hDlg appears to have a role in maintaining a cytoplasmic pool of Cx43. These results demonstrate that hDlg is a physiologically relevant regulator of Cx43?in transformed epithelial cells.     

Nobiletin protects against diabetes-induced testicular injury via hypophysis–gonadal axis upregulation and amelioration of oxidative stress

Background

Testicular injury is one of the most serious problems associated with diabetes mellitus. The present study aimed to compare the effects of two different doses of nobiletin and analyze its mechanisms of action against diabetes-induced testicular impairment in rats.

Methods and results

Streptozotocin injection was used to induce diabetes. Diabetic rats received nobiletin orally at 10 or 25 mg/kg daily for 30 days. Diabetic rats displayed significant elevations in glucose, glycosylated hemoglobin (HbA1c), Homeostatic Model of Insulin Resistance (HOMA-IR), and pro-inflammatory cytokines, while the serum levels of insulin, testosterone, luteinizing hormone (LH), and follicle-stimulating hormone (FSH) were significantly reduced. Histological changes to positivity for caspase-3 and decreased androgen receptors (AR) immunoexpression were observed in diabetic rats. Both doses of nobiletin improved hyperglycemia, reduced pro-inflammatory cytokines, and augmented insulin, testosterone, LH, and FSH levels. LH and FSH receptors and cytochrome P450 17 α-hydroxylase (CYP17A1) were markedly downregulated in terms of both gene and protein expression in testicular tissues of the diabetic group, effects that were markedly ameliorated with both doses of nobiletin. In addition, both doses significantly reduced lipid peroxidation and caspase-3 immunoexpression and improved the activity of the antioxidant enzymes and AR in testicular tissues of the diabetic group.

Conclusion

Both nobiletin doses showed protective effects against diabetes-induced testicular injury by reducing oxidative stress, hyperglycemia, inflammation, and caspase-3 and upregulating the hypophysis–gonadal axis and AR. The high dose of nobiletin was more effective than the lower one.

     

p53 and Translation Attenuation Regulate Distinct Cell Cycle Checkpoints during Endoplasmic Reticulum (ER) Stress

Cell cycle checkpoints ensure that proliferation occurs only under permissive conditions, but their role in linking nutrient availability to cell division is incompletely understood. Protein folding within the endoplasmic reticulum (ER) is exquisitely sensitive to energy supply and amino acid sources because deficiencies impair luminal protein folding and consequently trigger ER stress signaling. Following ER stress, many cell types arrest within the G₁ phase, although recent studies have identified a novel ER stress G₂ checkpoint. Here, we report that ER stress affects cell cycle progression via two classes of signal: an early inhibition of protein synthesis leading to G₂ delay involving CHK1 and a later induction of G₁ arrest associated both with the induction of p53 target genes and loss of cyclin D1. We show that substitution of p53/47 for p53 impairs the ER stress G₁ checkpoint, attenuates the recovery of protein translation, and impairs induction of NOXA, a mediator of cell death. We propose that cell cycle regulation in response to ER stress comprises redundant pathways invoked sequentially first to impair G₂ progression prior to ultimate G₁ arrest.     

A Role for p38 Stress-Activated Protein Kinase in Regulation of Cell Growth via TORC1

The target of rapamycin (TOR) complex 1 (TORC1) signaling pathway is a critical regulator of translation and cell growth. To identify novel components of this pathway, we performed a kinome-wide RNA interference (RNAi) screen in Drosophila melanogaster S2 cells. RNAi targeting components of the p38 stress-activated kinase cascade prevented the cell size increase elicited by depletion of the TOR negative regulator TSC2. In mammalian and Drosophila tissue culture, as well as in Drosophila ovaries ex vivo, p38-activating stresses, such as H₂O₂ and anisomycin, were able to activate TORC1. This stress-induced TORC1 activation could be blocked by RNAi against mitogen-activated protein kinase kinase 3 and 6 (MKK3/6) or by the overexpression of dominant negative Rags. Interestingly, p38 was also required for the activation of TORC1 in response to amino acids and growth factors. Genetic ablation either of p38b or licorne, its upstream kinase, resulted in small flies consisting of small cells. Mutants with mutations in licorne or p38b are nutrition sensitive; low-nutrient food accentuates the small-organism phenotypes, as well as the partial lethality of the p38b null allele. These data suggest that p38 is an important positive regulator of TORC1 in both mammalian and Drosophila systems in response to certain stresses and growth factors.The target of rapamycin, TOR, is a highly conserved serine/threonine kinase that is a critical regulator of cell growth. It is a core component of two signaling complexes, TORC1 and TORC2 (60, 74). TORC1 is defined by the presence of Raptor in the complex, while TORC2 contains Rictor. Rictor and Raptor are mutually exclusive. Activation of the TORC1 pathway leads to increased protein translation, increased cell size, and increased proliferation, making this pathway an important target for emerging cancer therapies. Rapamycin is an inhibitor of TORC1 that is commonly used as an immunosuppressant following kidney transplantation (51). At least three analogs of rapamycin are currently being tested in solid and hematological tumors and have shown some promising results (21).The TORC1 pathway responds to numerous inputs, sensing both the desirability of and the capacity for growth. Many of these pathways control TORC1 signaling through phosphorylation of the tuberous sclerosis protein TSC2. TSC2 associates with TSC1 to form a heterodimeric GTPase-activating protein complex (GAP) that inactivates the small GTPase Rheb (24, 29, 67). While the exact molecular mechanism remains a topic of debate, activation of Rheb promotes the kinase activity of TORC1 (24, 29, 67). Rheb is required for the activation of TORC1 in response to both amino acids and growth factors (55, 62). In Drosophila melanogaster, mutation of either TOR or Rheb inhibits growth, leading to reduced body size and reduced cell size in mutant clones (42, 64). Mutation of either TSC1 or TSC2 has the predicted opposite effect, as tissue deficient for either of these proteins overgrows and contains large cells (49, 66).TORC1 is activated via the phosphatidylinositol 3′ kinase (PI3′K) pathway by growth-promoting mitogens, such as insulin and growth factors. Drosophila mutants with mutations of PI3′K pathway components have size phenotypes similar to those of the TOR and Rheb mutants (71). In mammalian cells, the PI3′K-mediated activation of TORC1 occurs at least in part through the phosphorylation of TSC2 by the PI3′K target AKT (30, 50). Interestingly, mutation of these residues in Drosophila has no impact on TSC2 function in vivo, suggesting that there may be other mechanisms through which PI3′K can activate Drosophila TOR (20). Recent work has suggested that the proline-rich AKT substrate PRAS40 may provide part of this link (23, 59, 69, 70). In addition, signaling through RAS activates extracellular signal-regulated kinase (ERK) and ribosomal S6 kinase (RSK), which can phosphorylate TSC2 and Raptor to activate TORC1 (13, 40, 56). There are also likely to be additional mechanisms through which growth factors activate Drosophila TOR that have not yet been identified.TORC1 activity is also controlled by the intracellular building blocks necessary to support cellular growth. The energy-sensing AMP-activated protein kinase (AMPK) pathway relays information about the energy status of the cell to TORC1 by phosphorylating TSC2. Unlike the inactivating phosphorylation of TSC2 by Akt, phosphorylation of TSC2 by AMPK promotes the GAP activity of the TSC complex (31). AMPK also phosphorylates Raptor, leading to decreased TORC1 activity (28). Thus, when energy levels are low, active AMPK inhibits TORC1.Amino acids also activate the TORC1 pathway, through a mechanism that requires Rheb, as well as the type III PI3′K VPS34 and the serine/threonine kinase mitogen-activated protein kinase kinase kinase kinase 3 (MAP4K3) (11, 22, 43). TORC1 thereby integrates information about the availability of amino acids and the amount of energy available for growth with growth factor signaling. Given its ancient function in adapting growth rates to environmental conditions, it is likely that TOR responds to a variety of stimuli, suggesting that many TOR control mechanisms remain to be uncovered. The Rag family of Ras-related small GTPases has recently been identified as a key component of the amino acid-sensing pathway, acting in parallel to Rheb (34, 58). Rag GTPases form heterodimers; RagA or RagB interacts with RagC or RagD. RagA and RagB are active when GTP bound, while RagC and RagD are active when bound to GDP (34, 58). Activation of the Rags by amino acids results in TOR relocalization to Rab7-containing vesicles (58). While the function of these vesicles in TORC1 signaling remains unclear, this relocalization is associated with increased TORC1 activity.TORC1 controls cell growth and translation through the phosphorylation and activation of components of the translational machinery, such as S6 kinase (S6K) and 4EBP1, an inhibitor of eukaryotic translation initiation factor 4E (eIF4E) activity (reviewed in reference 27). S6K phosphorylates the S6 ribosomal subunit, thereby increasing translation. Mice deficient for S6K1 are small and have small pancreatic beta cells and a correspondingly low level of circulating insulin (45). Mutation of the phosphorylation sites on S6 results in a similar phenotype, with small beta cells and fibroblasts (57). In Drosophila, mutation of S6K again reduces both cell and organism size (42), as does the overexpression of 4EBP (41).Interestingly, while mutation of the TORC1 pathway in mammalian cells reduces cell size by 10 to 15%, ablation of core TORC1 pathway components in Drosophila cells can affect cell size by up to 40% (73). In an attempt to identify novel components of the TORC1 pathway, we undertook an RNA interference (RNAi)-based screen of Drosophila S2 cells. We reasoned that the extreme size phenotypes observed in Drosophila cells upon TORC1 manipulations would facilitate the identification of modulators. In order to increase the likelihood of isolating novel regulators of TOR, we uncoupled TOR activity from many of its known nutritional controls by depleting TSC2 and screened for double-stranded RNAs (dsRNAs) that could reverse the cell size increase elicited by loss of TSC2. Depletion of multiple components of the p38 pathway was found to revert the TSC2 RNAi-induced cell size increase. Furthermore, activation of p38 is necessary and sufficient for the activation of TOR. Strikingly, mutation of components of the stress-activated p38 pathway in Drosophila has a similar phenotype to mutations in the TOR and insulin signaling pathway: a cell-autonomous cell size decrease, reduced body size, and a sensitization to the effects of nutritional stress.     

Spectral analysis of the DNA targeting bisalkylaminoanthraquinone DRAQ5 in intact living cells.

BACKGROUND: We report on the potential DNA binding modes and spectral characteristics of the cell-permeant far red fluorescent DNA dye, DRAQ5, in solution and bound within intact cells. Our aim was to determine the constraints for its use in flow cytometry and bioimaging. METHODS: Solution characteristics and quantum yields were determined by spectroscopy. DRAQ5 binding to nuclear DNA was analyzed using fluorescence quenching of Hoechst 33342 dye, emission profiling by flow cytometry, and spectral confocal laser scanning microscopy of the complex DRAQ5 emission spectrum. Cell cycle profiling utilized an EGFP-cyclin B1 reporter as an independent marker of cell age. Molecular modeling was used to explore the modes of DNA binding. RESULTS: DRAQ5 showed a low quantum yield in solution and a spectral shift upon DNA binding, but no significant fluorescence enhancement. DRAQ5 caused a reduction in the fluorescence intensity of Hoechst 33342 in live cells prelabeled with the UV excitable dye, consistent with molecular modeling that suggests AT preference and an engagement of the minor groove. In vivo spectral analysis of DRAQ5 demonstrated shifts to longer wavelengths upon binding with DNA. Analysis of spectral windows of the dual emission peaks at 681 and 707 nm in cells showed that cell cycle compartment recognition was independent of the far red-near IR emission wavelengths monitored. CONCLUSIONS: The study provides new clues to modes of DNA binding of the modified anthraquinone molecule in vivo, and its AT base-pair selectivity. The combination of low quantum yield but high DNA affinity explains the favorable signal-to-noise profile of DRAQ5-nuclear fluorescence. The robust nature of cell cycle reporting using DRAQ5, even when restricted spectral windows are selected, facilitates the analysis of encroaching spectral emissions from other fluorescent reporters, including GFP-tagged proteins.     

P metabolism and transport in AM fungi

The arbuscular mycorrhizal symbiosis is mutualistic, based on reciprocal transfer of P from the fungus to the plant and carbon from the plant to the fungus. Thus P is a most important `currency' in the symbiosis. After absorbing P from the soil solution, the fungi first incorporate it into the cytosolic pool, and the excess P is transferred to the vacuoles. The vacuolar P pool probably plays a central role in P supply to the plant. The main forms of inorganic P in fungal vacuoles are orthophosphate and polyphosphate, but organic P molecules may also be present. Long distance translocation of P from the site of uptake in the external mycelium to the site of transfer to the plant is probably achieved via transfer of vacuolar components. This transport would be mediated either by protoplasmic streaming or the motile tubular vacuole-like system. The site of release of P into the interfacial apoplast and thence to the plant is most probably the fungal arbuscules. The biochemical and biophysical processes involved in P metabolism and transfer between cellular compartments in the symbiosis are currently not well understood. Some recent investigations of substrate specificities of phosphatase-type enzymes in AM fungi and other eukaryotic microorganisms, however, have shed new light on earlier results and permit the construction of a hypothetical scheme of P-flow, including possible regulatory factors. Steps in this scheme are experimentally testable and should stimulate future research.