Determination of composition and structure of spongy bone tissue in human head of femur by Raman spectral mapping

Biomechanical properties of bone depend on the composition and organization of collagen fibers. In this study, Raman microspectroscopy was employed to determine the content of mineral and organic constituents and orientation of collagen fibers in spongy bone in the human head of femur at the microstructural level. Changes in composition and structure of trabecula were illustrated using Raman spectral mapping. The polarized Raman spectra permit separate analysis of local variations in orientation and composition. The ratios of ν2PO43−/Amide III, ν4PO43−/Amide III and ν1CO32−/ν2PO43− are used to describe relative amounts of spongy bone components. The ν1PO43−/Amide I ratio is quite susceptible to orientation effect and brings information on collagen fibers orientation. The results presented illustrate the versatility of the Raman method in the study of bone tissue. The study permits better understanding of bone physiology and evaluation of the biomechanical properties of bone

The integration of lipid-sensing and anti-inflammatory effects: how the PPARs play a role in metabolic balance

The peroxisomal proliferating-activated receptors (PPARs) are lipid-sensing transcription factors that have a role in embryonic development, but are primarily known for modulating energy metabolism, lipid storage, and transport, as well as inflammation and wound healing. Currently, there is no consensus as to the overall combined function of PPARs and why they evolved. We hypothesize that the PPARs had to evolve to integrate lipid storage and burning with the ability to reduce oxidative stress, as energy storage is essential for survival and resistance to injury/infection, but the latter increases oxidative stress and may reduce median survival (functional longevity). In a sense, PPARs may be an evolutionary solution to something we call the 'hypoxia-lipid' conundrum, where the ability to store and burn fat is essential for survival, but is a 'double-edged sword', as fats are potentially highly toxic. Ways in which PPARs may reduce oxidative stress involve modulation of mitochondrial uncoupling protein (UCP) expression (thus reducing reactive oxygen species, ROS), optimising forkhead box class O factor (FOXO) activity (by improving whole body insulin sensitivity) and suppressing NFkB (at the transcriptional level). In light of this, we therefore postulate that inflammation-induced PPAR downregulation engenders many of the signs and symptoms of the metabolic syndrome, which shares many features with the acute phase response (APR) and is the opposite of the phenotype associated with calorie restriction and high FOXO activity. In genetically susceptible individuals (displaying the naturally mildly insulin resistant 'thrifty genotype'), suboptimal PPAR activity may follow an exaggerated but natural adipose tissue-related inflammatory signal induced by excessive calories and reduced physical activity, which normally couples energy storage with the ability to mount an immune response. This is further worsened when pancreatic decompensation occurs, resulting in gluco-oxidative stress and lipotoxicity, increased inflammatory insulin resistance and oxidative stress. Reactivating PPARs may restore a metabolic balance and help to adapt the phenotype to a modern lifestyle

Sensing the fuels: glucose and lipid signaling in the CNS controlling energy homeostasis

The central nervous system (CNS) is capable of gathering information on the body’s nutritional state and it implements appropriate behavioral and metabolic responses to changes in fuel availability. This feedback signaling of peripheral tissues ensures the maintenance of energy homeostasis. The hypothalamus is a primary site of convergence and integration for these nutrient-related feedback signals, which include central and peripheral neuronal inputs as well as hormonal signals. Increasing evidence indicates that glucose and lipids are detected by specialized fuel-sensing neurons that are integrated in these hypothalamic neuronal circuits. The purpose of this review is to outline the current understanding of fuel-sensing mechanisms in the hypothalamus, to integrate the recent findings in this field, and to address the potential role of dysregulation in these pathways in the development of obesity and type 2 diabetes mellitus

Lipid-induced secondary structures and orientations of (Leu5)-enkephalin: Helical and crystallographic double-bend conformers revealed by IRATR and molecular modelling

Lipid-induced secondary structures and orientations of the two enantiomeric [Leu5]-enkephalins, L-Tyr-Gly-Gly-L-Phe-L-Leu, and D-Tyr-Gly-Gly-D-Phe-D-Leu, on flat multi-bilayers of 1-palmitoyl-2-oleoyl-sn-glycero-3-phosphocholine (POPC) were examined with polarized attenuated total reflection IR (IRATR) spectroscopy and molecular mechanics procedures. The membrane-bound peptides showed identical IR spectra in the amide I and II band regions that indicated membrane-induced secondary structures and specific orientations of the non-zwitterionic molecules. A Lorentzian band shape analysis based on second derivatives of the original curves and the observed band polarizations suggested the presence of helical structures (βIII·-and α-turns), oriented more or less perpendicular to the membrane surface. Other folded structures, e.g. βI- and γ turns, were not excluded. Molecular modelling of non-zwitterionic [Leu5]-enkephalin with two βIII-turns or an α-turn resulted in essentially four low-energy conformers containing (i) two βIII-turns, (ii) one α-turn, (iii) a βIII-turn fused to an α-turn, and (iv) a βIII-turn fused to a βI-turn as in the crystallographic molecular conformation described by Aubry et al. [Biopolymers 28, 27-40 (1989)]. Zwitterionic [Leu5]-enkephalin with two βIII-tums collapsed to a C13 turn (a distorted α-turn) bridged by a γI-turn (v). The alignment of the amide I oscillators within the helical structures, (i), (ii) and (iii), and the double-bend structures, (iv) and (v), explained the observed amide I and II polarizations. Differences between these and other lipid-induced [Leu5]-enkephalin conformers reported in the literature may be caused by the lipid polymorphism of the model membranes used. Possible implications of the new conformers for the molecular mechanism of opioid receptor selection are discussed in terms of the membrane compartments theory