Subcellular localization and physiological role of alpha-methylacyl-CoA racemase

alpha-Methylacyl-CoA racemase plays an important role in the beta-oxidation of branched-chain fatty acids and fatty acid derivatives because it catalyzes the conversion of several (2R)-methyl-branched-chain fatty acyl-CoAs to their (S)-stereoisomers. Only stereoisomers with the 2-methyl group in the (S)-configuration can be degraded via beta-oxidation. Patients with a deficiency of alpha-methylacyl-CoA racemase accumulate in their plasma pristanic acid and the bile acid intermediates di- and trihydroxycholestanoic acid, which are all substrates of the peroxisomal beta-oxidation system. Subcellular fractionation experiments, however, revealed that both in humans and rats alpha-methylacyl-CoA racemase is bimodally distributed to both the peroxisome and the mitochondrion. Our findings show that the peroxisomal and mitochondrial enzymes are produced from the same gene and that, as a consequence, the bimodal distribution pattern must be the result of differential targeting of the same gene product. In addition, we investigated the physiological role of the enzyme in the mitochondrion. Both in vitro studies with purified heterologously expressed protein and in vivo studies in fibroblasts of patients with an alpha-methylacyl-CoA racemase deficiency revealed that the mitochondrial enzyme plays a crucial role in the mitochondrial beta-oxidation of the breakdown products of pristanic acid byconverting (2R,6)-dimethylheptanoyl-CoA to its (S)-stereoisomer.     

Deciphering intracellular localization and physiological role of nociceptin and nocistatin

Nociceptin and nocistatin are endogenous ligands of G protein coupled receptor family. Numerous techniques have been used to study the diverse parameters including, localization, distribution and ultrastructure of these peptides. The majority of the study parameters are based on their physiological roles in different organ systems. The present study presents an overview of the different methods used for the study of nociceptin, nocistatin and their receptors. Nociceptin has been implicated in many physiological functions including, nociception, locomotion, stressed-induced analgesia, learning and memory, neurotransmitter and hormone release, renal function, neuronal differentiation, sexual and reproductive behavior, uterine contraction, feeding, anxiety, gastrointestinal motility, cardiovascular function, micturition, cough, hypoxic–ischemic brain injury, diuresis and sodium balance, temperature regulation, vestibular function, and mucosal transport. It has been noted that the use of light and electron microscopy was less frequent, though it may be one of the most promising tools to study the intracellular localization of these neuropeptides. In addition, more studies on the level of circulating nociceptin and nocistatin are also necessary for investigating their clinical roles in health and disease. A variety of modern tools including physiological, light and electron microscopy (EM) are needed to decipher the extent of intracellular localization, tissue distribution and function of these peptides. The intracellular localization of nociceptin and nocistatin will require a high resolution transmission EM capable of identifying these peptides and other supporting molecules that co-localize with them. A tracing technique could also elucidate a possible migratory ability of nociceptin and nocistatin from one cellular compartment to the other.     

Calcium channels and their role in regenerative medicine

Stem cells hold indefinite self-renewable capability that can be differentiated into all desired cell types.Based on their plasticity potential,they are divided into totipotent(morula stage cells),pluripotent(embryonic stem cells),multipotent(hematopoietic stem cells,multipotent adult progenitor stem cells,and mesenchymal stem cells[MSCs]),and unipotent(progenitor cells that differentiate into a single lineage)cells.Though bone marrow is the primary source of multipotent stem cells in adults,other tissues such as adipose tissues,placenta,amniotic fluid,umbilical cord blood,periodontal ligament,and dental pulp also harbor stem cells that can be used for regenerative therapy.In addition,induced pluripotent stem cells also exhibit fundamental properties of self-renewal and differentiation into specialized cells,and thus could be another source for regenerative medicine.Several diseases including neurodegenerative diseases,cardiovascular diseases,autoimmune diseases,virus infection(also coronavirus disease 2019)have limited success with conventional medicine,and stem cell transplantation is assumed to be the best therapy to treat these disorders.Importantly,MSCs,are by far the best for regenerative medicine due to their limited immune modulation and adequate tissue repair.Moreover,MSCs have the potential to migrate towards the damaged area,which is regulated by various factors and signaling processes.Recent studies have shown that extracellular calcium(Ca²⁺)promotes the proliferation of MSCs,and thus can assist in transplantation therapy.Ca²⁺signaling is a highly adaptable intracellular signal that contains several components such as cell-surface receptors,Ca²⁺channels/pumps/exchangers,Ca²⁺buffers,and Ca²⁺sensors,which together are essential for the appropriate functioning of stem cells and thus modulate their proliferative and regenerative capacity,which will be discussed in this review.     

Ceramide channels and their role in mitochondria-mediated apoptosis

A key, decision-making step in apoptosis is the release of proteins from the mitochondrial intermembrane space. Ceramide can self-assemble in the mitochondrial outer membrane to form large stable channels capable of releasing said proteins. Ceramide levels measured in mitochondria early in apoptosis are sufficient to form ceramide channels in the outer membrane. The channels are in dynamic equilibrium with non-conducting forms of ceramide in the membrane. This equilibrium can be strongly influenced by other sphingolipids and Bcl-2 family proteins. The properties of ceramide channels formed in a defined system, planar phospholipid membranes, demonstrate that proteins are not required for channel formation. In addition, experiments in the defined system reveal structural information. The results indicated that the channels are barrel-like structures whose staves are ceramide columns that span the membrane. Ceramide channels are good candidates for the protein release pathway that initiates the execution phase of apoptosis.     

Membrane topology of NAADP-sensitive two-pore channels and their regulation by N-linked glycosylation

Two-pore channels (TPCs) localize to the endolysosomal system and have recently emerged as targets for the Ca(2+)-mobilizing messenger, nicotinic acid adenine dinucleotide phosphate (NAADP). However, their membrane topology is unknown. Using fluorescence protease protection assays, we show that human TPC1 and TPC2 possess cytosolic N and C termini and therefore an even number of transmembrane regions. Fluorophores placed at position 225 or 347 in TPC1, or 339 in TPC2 were also cytosolic, whereas a fluorophore at position 628 in TPC1 was luminal. These data together with sequence similarity to voltage-gated Ca(2+) and Na(+) channels, and unbiased in silico predictions are consistent with a topology in which two homologous domains are present, each comprising 6 transmembrane regions and a re-entrant pore loop. Immunocytochemical analysis of selectively permeabilized cells using antipeptide antibodies confirmed that the C-terminal tails of recombinant TPCs are cytosolic and that residues 240-254 of TPC2 prior to putative pore 1 are luminal. Both TPC1 and TPC2 are N-glycosylated with residues 599, 611, and 616 contributing to glycosylation of TPC1. This confirms the luminal position of these residues, which immediately precede the putative pore loop of the second domain. Mutation of all three glycosylation sites in TPC1 enhances NAADP-evoked cytosolic Ca(2+) signals. Our data establish essential features of the topology of two-pore channels.     

Intracellular localization of ClC chloride channels and their ability to form hetero-oligomers

ClC chloride channels (ClCs) can be classified into two groups in terms of their cellular localizations: ClCs present in the plasma membranes and those residing in intracellular organelles. Members of the latter group, including ClC-3, ClC-4, ClC-5, ClC-6, and ClC-7, are often co-expressed in a variety of cell types in many organs. Although the localization of individual channels within cells has been investigated, the degree of overlap between the locations of different ClCs in the same cell has not been clarified. To address this question, different combinations of ClCs, engineered to encode specific epitope tags (FLAG or HA), were either transiently or stably transfected into HEK293 cells, and we then compared the intracellular localization of the expressed channel proteins by immunofluorescence microscopy. Immunofluorescence images of the alternatively labeled channels clearly showed significant co-localization between all pair-wise combinations of ClCs. In particular, ClC-3, ClC-4, and ClC-5 showed a high degree of co-localization. As a significant degree of co-localization between ClCs was observed, we used co-immunoprecipitation to evaluate oligomer formation, and found that each ClC tested could form homo-oligomers, and that any pair-wise combination of ClC-3, ClC-4, and ClC-5 could also form hetero-oligomers. Neither ClC-6 nor ClC-7 was co-precipitated with any other channel protein. These results suggest that within cells ClC-3, ClC-4, and ClC-5 may have combinatorial functions, whereas ClC-6 and ClC-7 are more likely to function as homo-oligomers.     

Histochemical localization and characterization of chalcones on the foliar surface of Zuccagnia punctata Cav. Insights into their physiological role

Dihydroxychalcones as well as other metabolites synthesized via the phenylpropanoid pathway have a wide range of biological activities. Although this class of phenolic compounds is found in very large amounts in some tissues, their physiological significance remains unclear.This approach focused on the chemical analysis of Zuccagnia punctata leaf rinse extract in which dihydroxychalcones (99.25 μg 2′,4′-dihydroxychalcone/cm² and 73.38 μg 2′,4′-dihydroxy-3′-methoxychalcone/cm²) are the main constituents. Histochemical analysis (fluorescence microscope and emission scanning electron microscope coupled with an energy dispersive X-ray spectrometer) revealed a high flavonoid concentration on the foliar surface. The high accumulation of phenolic compounds, flavonoids or chalcones in the cuticle of Z. punctata leaves would act as defense mechanisms against UV radiation for the protection of photosynthetic tissues against oxidative stress.     

Reactions of peroxynitrite with globin proteins and their possible physiological role

It is now widely accepted that, besides their well-established function in O(2) transport, hemoglobin and myoglobin also undergo several redox reactions aimed to scavenge toxic free radicals and reactive oxygen and nitrogen species. At least some of these reactions are believed to play an important physiological role in the defense against oxidative stress. This aspect is exemplified by the recently discovered neuroglobin, a globin expressed in the brain. Rather than being considerably involved in reversible O(2) binding, neuroglobin is likely to undergo redox reactions to protect neurons against oxidative and potentially pathogenic pathways, as those operating after episodes of tissue hypoxia or ischemia. A major part of the cellular damage occurring under such conditions has been ascribed to formation of peroxynitrite, that originates from the reaction between two biologically important free radicals, nitric oxide (NO ) and superoxide. Here we review the current knowledge of the reactions of different forms of hemoglobin, myoglobin, and neuroglobin with peroxynitrite and discuss their physiological role on the basis of measured rate constants and on the probability of occurrence of these reactions in vivo.     

人新基因hbrp的染色体定位及其对TPK活性的抑制作用（简报）

hbrp(Human BSP-Related Protein)是我们实验室最近在睾丸组织中克隆的一个人与BSP（bovine seminal plasma)蛋白相关的新基因。为了将有关该新基因信息与现有人类基因组转录图相整合,我们应用荧光原位杂交(fluorescent in situ hybridizationFISH)法进行了该基因的人染色体基因定位,结果成功地将hbrp基因定位在人19号染色体长臂1区3带上。hbrp基因是在对BSP蛋白功能的研究过程中发现并克隆的,其同源性分析发现,与其序列最相近     

Some aspects of the physiological role of ion channels in the nervous system

Recent analyses of the genomes of several animal species, including man, have revealed that a large number of ion channels are present in the nervous system. Our understanding of the physiological role of these channels in the nervous system has followed the evolution of biophysical techniques during the last century. The observation and the quantification of the electrical events associated with the operation of the ionic channels has been, and still is, one of the best tools to analyse the various aspects of their contribution to nerve function. For this reason, we have chosen to use electrophysiological recordings to illustrate some of the main functions of these channels. The properties and the roles of Na+ and K+ channels in neuronal resting and action potentials are illustrated in the case of the giant axons of the squid and the cockroach. The nature and role of the calcium currents in the bursting behaviour of the neurons are illustrated for Aplysia giant neurons. The relationship between presynaptic calcium currents and synaptic transmission is shown for the squid giant synapse. The involvement of calcium channels in survival and neurite outgrowth of cultured neurons is exemplified using embryonic cockroach brain neurons. This same neuronal preparation is used to illustrate ion channel noise and single-channel events associated with the binding of agonists to nicotinic receptors. Some features of the synaptic activity in the central nervous system are shown, with examples from the cercal nerve giant-axon preparation of the cockroach. The interplay of different ion conductances involved in the oscillatory behaviour of the Xenopus spinal motoneurons is illustrated and discussed. The last part of this review deals with ionic homeostasis in the brain and the function of glial cells, with examples from Necturus and squids.     

Steroid hormones: their physiological role and diagnostic value during pregnancy

Steroid hormones play a key role in the beginning, development and termination of gestation. This reveiw is devoted for physiological effects of estrogens, progesterone, cortisole, ACTH, CRH in various pregnancy events: implantation, fetus development, maternal adaptation and birth initiation. Priority is fixed for estrogens--steroids that vastly increase maternal circulating blood value, induce progesterone action on uterus, regulate fetal "hypothalamic-pituitary-adrenocortical" axis, control free cortisole level in feminine blood. Diagnostic criterions of steroid hormone determination durijng pregnancy are presented. To day unconjugated estriol is the only steroid hormone that implicated in total pregnancy screening programs. Its concentration reduction has been noted in pregnancies with Dawn syndrome, some child enzyme defetcs, intrauterine growth retardation and fetal death incidents.     

Anion channels in higher plants: functional characterization, molecular structure and physiological role

Anion channels are well documented in various tissues, cell types and membranes of algae and higher plants, and current evidence supports their central role in cell signaling, osmoregulation, plant nutrition and metabolism. It is the aim of this review to illustrate through a few selected examples the variety of anion channels operating in plant cells and some of their regulation properties and unique physiological functions. In contrast, information on the molecular structure of plant anion channels has only recently started to emerge. Only a few genes coding for putative plant anion channels from the large chloride channel (CLC) family have been isolated, and current molecular data on these plant CLCs are presented and discussed. A major challenge remains to identify the genes encoding the various anion channels described so far in plant cells. Future prospects along this line are briefly outlined, as well as recent advances based on the use of knockout mutants in the model plant Arabidopsis thaliana to explore the physiological functions of anion channels in planta.