Serum Ferritin Is Inversely Correlated with Testosterone in Boys and Young Male Adolescents: A Cross-Sectional Study in Taiwan

Objective

The transition from childhood to teenaged years is associated with increased testosterone and a decreased iron status. It is not clear whether higher testosterone levels cause the decreased iron status, and to what extent, obesity-related inflammation influences the iron-testosterone relationship. The aim of the present study was to examine relationships of testosterone, iron status, and anti-/proinflammatory cytokines in relation to nutritional status in boys and young adolescent Taiwanese males.

Methods

In total, 137 boys aged 7~13 yr were included. Parameters for obesity, the iron status, testosterone, and inflammatory markers were evaluated.

Results

Overweight and obese (ow/obese) boys had higher mean serum testosterone, interleukin (IL)-1β, and nitric oxide (NO) levels compared to their normal-weight counterparts (all p<0.05). Mean serum ferritin was slightly higher in ow/obese boys compared to normal-weight boys, but this did not reach statistical significance. A multiple linear regression showed that serum ferritin (β = -0.7470, p = 0.003) was inversely correlated with testosterone, while serum IL-10 (β = 0.3475, p = 0.009) was positively associated with testosterone after adjusting for covariates. When normal-weight boys were separately assessed from ow/obesity boys, the association between testosterone and serum ferritin became stronger (β = -0.9628, p<0.0001), but the association between testosterone and IL-10 became non-significant (β = 0.1140, p = 0.4065) after adjusting for covariates. In ow/obese boys, only IL-10 was weakly associated with serum testosterone (β = 0.6444, p = 0.051) after adjusting for age.

Conclusions

Testosterone and serum ferritin are intrinsically interrelated but this relationship is weaker in ow/obese boys after adjusting for age.     

A Systematic Approach to Species–Level Identification of Chile Pepper (Capsicum spp.) Seeds: Establishing the Groundwork for Tracking the Domestication and Movement of Chile Peppers through the Americas and Beyond

A Systematic Approach to Species–Level Identification of Chile Pepper (Capsicum spp.) Seeds: Establishing the Groundwork for Tracking the Domestication and Movement of Chile Peppers through the Americas and Beyond The chile pepper (Capsicum spp.), a plant held in great esteem throughout history, was independently domesticated in a series of places including highland Bolivia, central Mexico, the Amazon, the Caribbean, and other locales with a particularly long history of cultivation and use in the central Andes of South America. Though identification of chile pepper species through fruit morphology is possible and has been utilized by botanists studying modern and archaeological specimens, species–level identification of Capsicum seeds has remained undetermined. Given the greater abundance of seed remains in the archaeological record due to the higher likelihood of preservation, the ability to identify specific Capsicum domesticates has profound implications for tracking the domestication and spread of chile peppers prehistorically through the Americas and historically through trade and exchange to the rest of the world. This article presents a systematic procedure to identify Capsicum seeds to the species level created by adopting a morphometric approach to compare attributes of modern Capsicum seeds to archaeological seeds.     

Adaptation genomics: the next generation

Understanding the genetics of how organisms adapt to changing environments is a fundamental topic in modern evolutionary ecology. The field is currently progressing rapidly because of advances in genomics technologies, especially DNA sequencing. The aim of this review is to first briefly summarise how next generation sequencing (NGS) has transformed our ability to identify the genes underpinning adaptation. We then demonstrate how the application of these genomic tools to ecological model species means that we can start addressing some of the questions that have puzzled ecological geneticists for decades such as: How many genes are involved in adaptation? What types of genetic variation are responsible for adaptation? Does adaptation utilise pre-existing genetic variation or does it require new mutations to arise following an environmental change?     

Involvement of the residues of GSKIP, AxinGID, and FRATtide in their binding with GSK3β to unravel a novel C-terminal scaffold-binding region

The specificity and regulation of GSK3β are thought to involve in the docking interactions at core kinase domain because of the particular amino acid residues. Recent X-ray diffraction studies illuminated the relative binding residues on AxinGID and FRATtide for GSK3β docking and appeared that GSK3β Val267Gly (V267G) and Tyr288Phe (Y288F) could distinguish the direct interaction between AxinGID and FRATtide. In order to explore the mode that involved the binding of GSKIP to GSK3β and compare it with that of AxinGID and FRATtide, we pinpointed the binding sites of GSKIP to GSK3β through the single-point mutation of four corresponding sites within GSK3β (residues 260–300) as scaffold-binding region I (designated SBR-I_260–300). Our data showed that these three binding proteins shared similar binding sites on GSK3β. We also found that the binding of GSK3β V267G mutant to GSKIP and AxinGID, but not that of Y288F mutant (effect on FRATtide), was affected. Further, based on the simulation data, the electron-density map of GSKIPtide bore closer similarity to the map AxinGID than to that of FRATtide. Interestingly, many C-terminal helix region point-mutants of GSK3β L359P, F362A, E366K, and L367P were able to eliminate the binding with FRATtide, but not AxinGID or GSKIP. In addition, CABYR exhibited a unique mode in binding to C-terminal helix region of GSK3β. Taken together, our data revealed that in addition to the core kinase domain, SBR-I_260–300, another novel C-terminus helix region, designated SBR-II_339–383, also appeared to participate in the recognition and specificity of GSK3β in binding to other specific proteins.     

Connective Tissue Growth Factor in Regulation of RhoA Mediated Cytoskeletal Tension Associated Osteogenesis of Mouse Adipose-Derived Stromal Cells

Background

Cytoskeletal tension is an intracellular mechanism through which cells convert a mechanical signal into a biochemical response, including production of cytokines and activation of various signaling pathways.

Methods/Principal Findings

Adipose-derived stromal cells (ASCs) were allowed to spread into large cells by seeding them at a low-density (1,250 cells/cm²), which was observed to induce osteogenesis. Conversely, ASCs seeded at a high-density (25,000 cells/cm²) featured small cells that promoted adipogenesis. RhoA and actin filaments were altered by changes in cell size. Blocking actin polymerization by Cytochalasin D influenced cytoskeletal tension and differentiation of ASCs. To understand the potential regulatory mechanisms leading to actin cytoskeletal tension, cDNA microarray was performed on large and small ASCs. Connective tissue growth factor (CTGF) was identified as a major regulator of osteogenesis associated with RhoA mediated cytoskeletal tension. Subsequently, knock-down of CTGF by siRNA in ASCs inhibited this osteogenesis.

Conclusions/Significance

We conclude that CTGF is important in the regulation of cytoskeletal tension mediated ASC osteogenic differentiation.     

Comparison of pulsed‐field gel electrophoresis and three rep‐PCR methods for evaluating the genetic relatedness of Stenotrophomonas maltophilia isolates

Aims: In this study, three facile repetitive‐sequence PCR (rep‐PCR) techniques have been compared with the pulsed‐field gel electrophoresis (PFGE) method for differentiating the genetic relatedness of clinical Stenotrophomonas maltophilia isolates. Methods and Results: The dendrograms of 20 S. maltophilia isolates were constructed based on the data obtained from PFGE and three PCR‐based methods, i.e. enterobacterial repetitive intergenic consensus‐PCR (ERIC‐PCR), BOX‐PCR and repetitive extragenic palindromic‐PCR (REP‐PCR). When compared with PFGE, ERIC‐PCR displayed a much lower discriminatory power, whereas BOX‐PCR and REP‐PCR had a comparable discriminatory power for close genetic‐related isolates. Conclusion: BOX‐PCR and REP‐PCR can be convenient and effective methods for evaluating the close genetic relatedness of clinical S. maltophilia isolates. Significance and Impact of the Study: A rapid method for determining S. maltophilia’s close genetic relatedness provides a convenient tool for understanding the epidemiology of S. maltophilia.     

A synthetic entry to pladienolide B and FD-895

Presented within are syntheses of the pladienolide B and FD-895 side-chains, as well as models of the essential ring-closing metathesis and Stille coupling that will be used to complete their total syntheses. Several analogs of the pladienolide B side-chain were also prepared in order to evaluate the scope of the methodology and to create a library of structures that could be used for stereochemical and SAR analyses.     

The PNPase,exosome and RNA helicases as the building components of evolutionarily-conserved RNA degradation machines

The structure and function of polynucleotide phosphorylase (PNPase) and the exosome, as well as their associated RNA-helicases proteins, are described in the light of recent studies. The picture raised is of an evolutionarily conserved RNA-degradation machine which exonucleolytically degrades RNA from 3′ to 5′. In prokaryotes and in eukaryotic organelles, a trimeric complex of PNPase forms a circular doughnut-shaped structure, in which the phosphorolysis catalytic sites are buried inside the barrel-shaped complex, while the RNA binding domains create a pore where RNA enters, reminiscent of the protein degrading complex, the proteasome. In some archaea and in the eukaryotes, several different proteins form a similar circle-shaped complex, the exosome, that is responsible for 3′ to 5′ exonucleolytic degradation of RNA as part of the processing, quality control, and general RNA degradation process. Both PNPase in prokaryotes and the exosome in eukaryotes are found in association with protein complexes that notably include RNA helicase.     

Diverse selective modes among orthologs/paralogs of the chalcone synthase (Chs) gene family of Arabidopsis thaliana and its relative A. halleri ssp. gemmifera

As a model system, Arabidopsis thaliana and its wild relatives have played an important role in the study of genomics and evolution in plants. In this study, we examined the genetic diversity of the chalcone synthase (Chs) gene, which encodes a key enzyme of the flavonoid pathway and is located on chromosome five, as well as two Chs-like genes on the first and fourth chromosomes of Arabidopsis. The objectives of the study are to determine if natural selection operates differentially on the paralogs of the Chs gene family in A. thaliana and Arabidopsis halleri ssp. gemmifera. The mode of selection was inferred from Tajima's D values from noncoding and coding regions, as well as from the ratio of nonsynonymous to synonymous substitutions. Both McDonald-Kreitman and HKA tests revealed the effects of selection on the allelic distribution, except for the chromosome 1 paralog in ssp. gemmifera. The Chs gene on chromosome 5 was under purifying selection in both species. Significant, negative Tajima's D values at synonymous sites and positive Fay and Wu's H values within coding region, plus reduced genetic variability in introns, indicated effects of background selection in shaping the evolution of this gene region in A. thaliana. The Chs paralog on chromosome 1 was under positive selection in A. thaliana, while interspecific introgression and balancing selection determined the fates of the paralog and resulted in high heterogeneity in ssp. gemmifera. Local adaptation differentiated populations of Japan and China at the locus. In contrast, the other Chs-paralog of chromosome 4 was shaped by purifying selection in A. thaliana, while under positive selection in ssp. gemmifera, as indicated by dn/ds>1. Moreover, these contrasting patterns of selection have likely resulted in functional divergence in Arabidopsis, as indicated by radical amino acid substitutions at the chalcone synthase/stilbene synthase motif of the Chs genes. Unlike previous studies of the evolutionary history of A. thaliana, the high levels of genetic diversity in most gene regions of Chs paralogs and nonsignificant Tajima's D in the intron sequences of the Chs gene family in A. thaliana did not reflect the effects of a recent demographic expansion.