The Rate of Tau Synthesis Is Differentially Regulated During Postnatal Development in Mouse Cerebellum

1. Tau, which is a microtubule-associated protein, with mRNA targeted to the axon and growth cone, is involved in axonal elongation. During postnatal development in mouse, Tau expression in cerebellar granule cells is reduced after the second postnatal week. The aim of this work was to study the regulation of the rate of the synthesis of Tau protein during the period of granule cell axonal growth in mouse cerebellum.2. We found four [³⁵S]methionine-labeled isoforms of Tau synthesized postnataly. Their levels remain constant from postnatal day 9 to 12 (P9–P12), and decreased by P20.3. The rate of Tau synthesis showed differences with the rate of synthesis of total proteins. They also differ from proteins phosphatases 2A and 2B, both associated with the regulation of Tau function. In addition, the turnover of newly synthesized Tau increased at P20, compared with P9 and P12.4. These results imply a specific developmental regulation of mRNA translation of Tau, and indicate that, after the period of synapse formation is complete, and therefore axonal growth has finished (P20), only a limited number of new Tau molecules are synthesized. This might reflect that, after synapse formation is complete, newly synthesized Tau molecules are not longer needed.     

Rise in Extracellular Fluid Volume During High Sodium Depends on BMI in Healthy Men

A high sodium (HS) intake is associated to increased cardiovascular and renal risk, especially in overweight subjects. We hypothesized that abnormal sodium and fluid handling is involved, independent of hypertension or insulin resistance. Therefore, we studied the relation between BMI and sodium‐induced changes in extracellular fluid volume (ECFV; distribution volume of ¹²⁵I‐iothalamate) in 78 healthy men, not selected for BMI. A total of 78 subjects with a median BMI of 22.5 (range: 19.2–33.9 kg/m²) were studied after 1 week on a low sodium (LS) diet (50 mmol Na⁺/d) and after 1 week on HS (200 mmol Na⁺/d). The change from LS to HS resulted in an increase in ECFV of 1.2 ± 1.8 l. Individual changes in ECFV were correlated to BMI (r = 0.361, P < 0.01). Furthermore, in response to HS, a higher BMI was associated to a higher rise in filtered load of sodium (FL_Na+ = [Na⁺] × GFR, r = 0.281, P < 0.05). Thus, a shift to HS leads to a larger rise in ECFV in healthy subjects with higher BMI, associated with an elevated FL_Na+ during HS. Although no hypertension occurred in these healthy subjects, our data provide a potential explanation for the interaction of sodium intake and BMI on cardiovascular and renal risk. Exaggerated fluid retention may be an early pathogenic factor in the cardiorenal complications of overweight.     

Emotion Separation Is Completed Early and It Depends on Visual Field Presentation

It is now apparent that the visual system reacts to stimuli very fast, with many brain areas activated within 100 ms. It is, however, unclear how much detail is extracted about stimulus properties in the early stages of visual processing. Here, using magnetoencephalography we show that the visual system separates different facial expressions of emotion well within 100 ms after image onset, and that this separation is processed differently depending on where in the visual field the stimulus is presented. Seven right-handed males participated in a face affect recognition experiment in which they viewed happy, fearful and neutral faces. Blocks of images were shown either at the center or in one of the four quadrants of the visual field. For centrally presented faces, the emotions were separated fast, first in the right superior temporal sulcus (STS; 35–48 ms), followed by the right amygdala (57–64 ms) and medial pre-frontal cortex (83–96 ms). For faces presented in the periphery, the emotions were separated first in the ipsilateral amygdala and contralateral STS. We conclude that amygdala and STS likely play a different role in early visual processing, recruiting distinct neural networks for action: the amygdala alerts sub-cortical centers for appropriate autonomic system response for fight or flight decisions, while the STS facilitates more cognitive appraisal of situations and links appropriate cortical sites together. It is then likely that different problems may arise when either network fails to initiate or function properly.     

Adaptation of Avian Eggs to Incubation Period Variability Around Allometric Regressions Is Correlated with Time

Many morphological and physiological parameters of avian eggsare known to be correlated with fresh egg weight, i.e, to exhibitallometric relationships. It has been predicted that part ofthe variability around some of these allometric relationshipsis the result of adaptations to incubation periods of differentlengths. I performed multiple regressions of three of theseparameters (the rate of water loss in the nest, conductanceof the shell to gases and the rate of O₂ consumption just priorto hatching) versus weight and incubation period to test thesepredictions. All these parameters were significantly correlatedwith weight and for eggs of the same weight inversely correlatedwith the length of the incubation period. Other investigatorshave reported allometric interrelations between weight, lifespan and other parameters. For example the average number ofheartbeats is the same in mammals of all weights. The kind ofinterrelation reported in this study appears similar to thiskind of allometric interrelation but is actually quite differentbecause it concerns organisms of the same weight. I refer tothis kind of interrelation between various parameters for eggsof the same weight as an isometric interrelation. The two kindsof interrelations are quite independent the existence of anallometric interrelation does not prove the existence of anisometric interrelation.     

Central Hemodynamic Parameters and Cardiointervalogram Features in Infants during Early Postnatal Adaptation

Central hemodynamic parameters were analyzed in 217 healthy full-term newborns. Echocardiography was performed during the first 6 h after birth; during the periods 6–12 and 12–24 h after birth; and at days 3, 5, and 7 of life. A cardiointervalogram (CIG) was recorded simultaneously. Blood pressure was measured in all newborns. Heart rate variability was estimated with standard methods, and differential criteria determined previously were used to identify three CIG types. The spectral analysis of the slow-wave oscillations was performed within the following ranges of frequencies: high frequencies, >0.15 Hz; low frequencies, 0.04 < 0.15 Hz; and very low frequencies, <0.04 Hz. The healthy newborns showed great individual variations of the cardiac index, which were associated with the hyper-, eu-, and hypokinetic types of hemodynamics, evidencing good adaptive capacity of the body. All groups of newborns had three CIG types, irrespective of the type of hemodynamics. The CIG type frequencies depended on the type of hemodynamics at the time of examination of the newborns. This was explained by different mechanisms regulating blood circulation under basal metabolic conditions during functional changes.     

Postnatal D2-CAM/N-CAM Sialylation State Is Controlled by a Developmentally Regulated Golgi Sialyltransferase

Abstract: Golgi-enriched fractions have been isolated from rat brain of increasing postnatal age and defined by electron microscopy and distribution of marker enzymes. The expression of sialyltransferase activity associated with these fractions has been demonstrated to developmentally decrease and this appeared to be, in part, dependent on endogenous competitive inhibition. The developmental regulation of this activity paralleled the sialylation state of the neural cell adhesion molecule (D2-CAM/N-CAM) and could be demonstrated to be capable of endogenously sialylating this protein in the isolated Golgi fractions. In 12-day-old animals the majority of the transferred [¹⁴C]sialic acid was found to be associated with the high-molecular-weight [>200 kilodaltons (kd)] form of D2-CAM/N-CAM, indicative of the protein having been heavily sialylated. Sialylation of the individual D2-CAM/N-CAM polypeptides was also demonstrated in both 12-day and adult animals and transfer was evident only in the 180-kd and 115-kd components and not in the 140-kd component. In contrast, Golgi-enriched fractions prepared from adult animals showed little capability of heavily sialylating D2-CAM/N-CAM to any significant extent.     

Interannual Variation in Carbon Sequestration Depends Mainly on the Carbon Uptake Period in Two Croplands on the North China Plain

Interannual variation in plant phenology can lead to major modifications in the interannual variation of net ecosystem production (NEP) and net biome production (NBP) as a result of recent climate change in croplands. Continuous measurements of carbon flux using the eddy covariance technique were conducted in two winter wheat and summer maize double-cropped croplands during 2003–2012 in Yucheng and during 2007–2012 in Luancheng on the North China Plain. Our results showed that the difference between the NEP and the NBP, i.e., the crop economic yield, was conservative even though the NEP and the NBP for both sites exhibited marked fluctuations during the years of observation. A significant and positive relationship was found between the annual carbon uptake period (CUP) and the NEP as well as the NBP. The NEP and the NBP would increase by 14.8±5.2 and 14.7±6.6 g C m⁻² yr⁻¹, respectively, if one CUP-day was extended. A positive relationship also existed between the CUP and the NEP as well as the NBP for winter wheat and summer maize, respectively. The annual air temperature, through its negative effect on the start date of the CUP, determined the length of the CUP. The spring temperature was the main indirect factor controlling the annual carbon sequestration when a one-season crop (winter wheat) was considered. Thus, global warming can be expected to extend the length of the CUP and thus increase carbon sequestration in croplands.     

Maternal Infection Is a Risk Factor for Early Childhood Infection in Filariasis

Background

Global Program to Eliminate Lymphatic Filariasis (GPELF) launched by WHO aims to eliminate the disease by 2020. To achieve the goal annual mass drug administration (MDA) with diethylcarbamazine (DEC) plus albendazole (ABZ) has been introduced in all endemic countries. The current policy however excludes pregnant mothers and children below two years of age from MDA. Since pregnancy and early childhood are critical periods in determining the disease outcome in older age, the present study was undertaken to find out the influence of maternal filarial infection at the time of pregnancy on the susceptibility outcome of children born in a community after implementation of MDA for the first time.

Methodology and Principal Findings

The participants in this cohort consists of pregnant mothers and their subsequently born children living in eight adjacent villages endemic for filarial infections, in Khurda District, Odisha, India, where MDA has reduced microfilariae (Mf) rate from 12% to 0.34%. Infection status of mother and their children were assessed by detection of Mf as well as circulating filarial antigen (CFA) assay. The present study reveals a high rate of acquiring filarial infection by the children born to infected mother than uninfected mothers even though Mf rate has come down to < 1% after implementation of ten rounds of MDA.

Significance

To attain the target of eliminating lymphatic filariasis the current MDA programme should give emphasis on covering the women of child bearing age. Our study recommends incorporating supervised MDA to Adolescent Reproductive and Sexual Health Programme (ARSH) to make the adolescent girls free from infection by the time of pregnancy so as to achieve the goal.     

Prenatal and Early Postnatal Exposure to Total Mercury and Methylmercury from Low Maternal Fish Consumption

Biological Trace Element Research - The aim of this study was to investigate the influence of low fish consumption on prenatal and early postnatal exposure to mercury species. The samples of...     

Cellular Expression and Proteolytic Processing of Presenilin Proteins Is Developmentally Regulated During Neuronal Differentiation

Abstract: We have determined the expression of the Alzheimer's disease-associated proteins presenilin-1 and presenilin-2 in primary cultures of rat hippocampal neurons. Neurons highly express presenilin-1 and presenilin-2, whereas both proteins were not detected in astrocytes. Further, we have analyzed the subcellular localization and expression in rat hippocampal neurons during development. Although presenilin proteins were localized predominantly to the endoplasmic reticulum in nonneuronal cells transfected with presenilin cDNAs, in neurons, presenilin proteins were also found in compartments not staining with antibodies to grp78(BiP). Presenilin-1 and presenilin-2 were predominantly detected in vesicular structures within the somatodendritic compartment with much less expression in axons. Polarized distribution of presenilin-1 and presenilin-2 differs slightly, with more presenilin-2 expressed in axons compared with presenilin-1. Presenilin expression was found to be developmentally regulated. Presenilin expression strongly increased during neuronal differentiation until full morphological polarization and then declined. No full-length presenilin-1 or presenilin-2 could be detected within cell lysates. At early developmental stages the expected ～34-kDa N-terminal proteolytic fragment of presenilin-1 and the ～38-kDa fragment of presenilin-2 were detected. Later during differentiation we predominantly detected a ～38-kDa fragment for presenilin-1 and a ～42-kDa fragment for presenilin-2. By epitope mapping, we show that these slower migrating peptides represent N-terminal proteolytic fragments, cleaved C-terminal to the conventional site of processing. It is noteworthy that both presenilin-1 and presenilin-2 undergo alternative proteolytic cleavage at the same stage of neuronal differentiation. Regulation of presenilin expression and proteolytic processing might have implications for the pathological as well as the biological function of presenilins during aging in the human brain.     

Stability of the Maternal Gut Microbiota During Late Pregnancy and Early Lactation

Scarce research has been performed to assess whether the human maternal gut microbiota undergoes changes during the perinatal period. Therefore, in the present study, gut microbiota composition of seven healthy mothers(to-be) was assessed at different time points during the perinatal period (i.e. weeks 3–7 prepartum and days 3–6, 9–14, and 25–30 postpartum) using quantitative polymerase chain reaction (qPCR) and pyrosequencing, and was complemented by short-chain fatty acids (SCFA) and calprotectin quantification using high-performance liquid chromatography and enzyme-linked immunosorbent assay, respectively. qPCR revealed the predominance of members of the Firmicutes, Bacteroides, and Bifidobacterium without detectable changes over the perinatal period. Pyrosequencing supported these data in terms of microbiota stability for any population at any taxonomic level, although ratios of members of the Actinobacteria and Bacteroidetes differed between the two methods. However, the number of operational taxonomic units observed by pyrosequencing was subjected to fluctuations and the relative abundance of Streptococcus decreased numerically postpartum (P = 0.11), which may indicate that aberrancies in subdominant populations occur perinatally. Furthermore, total fecal SCFA concentrations, particularly the branched-chain fatty acids isobutyrate and isovalerate, were higher than for non-pregnant subjects throughout the perinatal period. This suggests metabolic changes and increased energy extraction via proteolytic, in addition to saccharolytic fermentation, accompanied by low-grade inflammation based on fecal calprotectin levels. Our data show that the maternal gut microbiota remained stable over the perinatal period despite altered metabolic activity and low-grade inflammation; however, it remains to be confirmed whether changes preceded earlier during pregnancy and succeeded later postpartum.     

Aryl Acylamidase Activity on Acetylcholinesterase Is High During Early Chicken Brain Development

Acetylcholinesterase (AChE) and butyrylcholinesterase (BChE) are known to exhibit aryl acylamidase activities (here called AAA(AChe) and AAA(BChe), respectively), which have been suggested to be involved in developmental and pathological processes. We here have investigated the developmental profiles of both AAA(AChe) and AAA(BChe) activities along with their AChE and BChE activities from embryonic days E3 to hatching (E21) in Triton-extracted homogenates from chicken embryonic brains. AAA(AChe) follows continuously an increase that is typical for AChE expression itself, whereas AAA(BChe) was relatively high before E10 to then become negligible toward hatching. Sucrose gradient centrifugation of both homogenized and immunopurified samples from E6-E18 brains showed that all globular forms (G1, G2, G4) of AChE present AAA(AChe) activity. Interestingly, the ratio of AAA(AChe) to AChE is highest at E6, and here again higher on G1/G2- over the G4-form. Noticeably, the sensitivity of AAA(AChe) toward the specific AChE inhibitor BW284c51 at all stages is higher than that of AChE itself. These data of high ratios of AAA associated at young stages with cholinesterases strongly indicate a role of AAA in early brain development.     

Yeast Colony Survival Depends on Metabolic Adaptation and Cell Differentiation Rather Than on Stress Defense

Enzymes scavenging reactive oxygen species (ROS) are important for cell protection during stress and aging. A deficiency in these enzymes leads to ROS imbalance, causing various disorders in many organisms, including yeast. In contrast to liquid cultures, where fitness of the yeast population depends on its ROS scavenging capability, the present study suggests that Saccharomyces cerevisiae cells growing in colonies capable of ammonia signaling use a broader protective strategy. Instead of maintaining high levels of antioxidant enzymes for ROS detoxification, colonies activate an alternative metabolism that prevents ROS production. Colonies of the strain deficient in cytosolic superoxide dismutase Sod1p thus developed the same way as wild type colonies. They produced comparable levels of ammonia and underwent similar developmental changes (expression of genes of alternative metabolism and center margin differentiation in ROS production, cell death occurrence, and activities of stress defense enzymes) and did not accumulate stress-resistant suppressants. An absence of cytosolic catalase Ctt1p, however, brought colonies developmental problems, which were even more prominent in the absence of mitochondrial Sod2p. sod2Δ and ctt1Δ colonies failed in ammonia production and sufficient activation of the alternative metabolism and were incapable of center margin differentiation, but they did not increase ROS levels. These new data indicate that colony disorders are not accompanied by ROS burst but could be a consequence of metabolic defects, which, however, could be elicited by imbalance in ROS produced in early developmental phases. Sod2p and homeostasis of ROS may participate in regulatory events leading to ammonia signaling.     

FGF-23 Is a Negative Regulator of Prenatal and Postnatal Erythropoiesis

Abnormal blood cell production is associated with chronic kidney disease (CKD) and cardiovascular disease (CVD). Bone-derived FGF-23 (fibroblast growth factor-23) regulates phosphate homeostasis and bone mineralization. Genetic deletion of Fgf-23 in mice (Fgf-23^−/−) results in hypervitaminosis D, abnormal mineral metabolism, and reduced lymphatic organ size. Elevated FGF-23 levels are linked to CKD and greater risk of CVD, left ventricular hypertrophy, and mortality in dialysis patients. However, whether FGF-23 is involved in the regulation of erythropoiesis is unknown. Here we report that loss of FGF-23 results in increased hematopoietic stem cell frequency associated with increased erythropoiesis in peripheral blood and bone marrow in young adult mice. In particular, these hematopoietic changes are also detected in fetal livers, suggesting that they are not the result of altered bone marrow niche alone. Most importantly, administration of FGF-23 in wild-type mice results in a rapid decrease in erythropoiesis. Finally, we show that the effect of FGF-23 on erythropoiesis is independent of the high vitamin D levels in these mice. Our studies suggest a novel role for FGF-23 in erythrocyte production and differentiation and suggest that elevated FGF-23 levels contribute to the pathogenesis of anemia in patients with CKD and CVD.