All‐atom chain‐building by optimizing MODELLER energy function using conformational space annealing

We have investigated the effect of rigorous optimization of the MODELLER energy function for possible improvement in protein all‐atom chain‐building. For this we applied the global optimization method called conformational space annealing (CSA) to the standard MODELLER procedure to achieve better energy optimization than what MODELLER provides. The method, which we call MODELLERCSA , is tested on two benchmark sets. The first is the 298 proteins taken from the HOMSTRAD multiple alignment set. By simply optimizing the MODELLER energy function, we observe significant improvement in side‐chain modeling, where MODELLERCSA provides about 10.7% (14.5%) improvement for χ₁ (χ₁ + χ₂) accuracy compared to the standard MODELLER modeling. The improvement of backbone accuracy by MODELLERCSA is shown to be less prominent, and a similar improvement can be achieved by simply generating many standard MODELLER models and selecting lowest energy models. However, the level of side‐chain modeling accuracy by MODELLERCSA could not be matched either by extensive MODELLER strategies, side‐chain remodeling by SCWRL3, or copying unmutated rotamers. The identical procedure was successfully applied to 100 CASP7 template base modeling domains during the prediction season in a blind fashion, and the results are included here for comparison. From this study, we observe a good correlation between the MODELLER energy and the side‐chain accuracy. Our findings indicate that, when a good alignment between a target protein and its templates is provided, thorough optimization of the MODELLER energy function leads to accurate all‐atom models. Proteins 2009. © 2008 Wiley‐Liss, Inc.     

Alteration of kynurenic acid concentration in rat plasma following optically pure kynurenine administration: a comparative study between enantiomers

L-Kynurenine (KYN), a tryptophan metabolite, is metabolized to kynurenic acid (KYNA), which is an antagonist of N-methyl-D-aspartate and alpha7 nicotinic acetylcholine receptors, by kynurenine aminotransferase (KAT) I and KAT II. In this study, optically pure KYN, namely L-KYN or D-KYN, was administered intraperitoneally to male Sprague-Dawley rats (16.3 micromol kg(-1)), and the change in plasma KYNA was investigated by using column-switching high-performance liquid chromatography (HPLC) with fluorescence detection. Unexpectedly, no remarkable alteration in the plasma KYNA was observed when a natural isomer, L-KYN, was administered, whereas plasma KYNA concentration was unequivocally increased when an unnatural isomer, D-KYN, was administered. Serum protein bindings of L-KYN and D-KYN were also studied, and the protein binding of L-KYN (approximately 65%) in rat serum was larger than that of D-KYN (approximately 12%), suggesting that D-KYN may be easily incorporated and metabolized in tissues during blood circulation to generate KYNA in mammals. In addition, the increase in plasma KYNA by the administration of D-KYN was suppressed in rats pretreated with a selective inhibitor of D-amino acid oxidase (DAAO), 5-methylpyrazole-3-carboxylic acid (80 mg/kg). These results suggest that DAAO might be responsible for the production of KYNA from D-KYN in vivo.     

Rapid adaptation: a new dimension for evolutionary perspectives in ecology

Although the study of adaptation is central to biology, two types of adaptation are recognized in the biological field: physiological adaptation (accommodation or acclimation; an individual organism’s phenotype is adjusted to its environment) and evolutionary–biological adaptation (adaptation is shaped by natural selection acting on genetic variation). The history of the former concept dates to the late nineteenth and early twentieth centuries, and has more recently been systemized in the twenty-first century. Approaches to the understanding of phenotypic plasticity and learning behavior have only recently been developed, based on cellular–histological and behavioral–neurobiological techniques as well as traditional molecular biology. New developments of the former concepts in phenotypic plasticity are discussed in bacterial persistence, wing di-/polymorphism with transgenerational effects, polyphenism in social insects, and defense traits for predator avoidance, including molecular biology analyses. We also discuss new studies on the concept of genetic accommodation resulting in evolution of phenotypic plasticity through a transgenerational change in the reaction norm based on a threshold model. Learning behavior can also be understood as physiological phenotypic plasticity, associating with the brain–nervous system, and it drives the accelerated evolutionary change in behavioral response (the Baldwin effect) with memory stock. Furthermore, choice behaviors are widely seen in decision-making of animal foragers. Incorporating flexible phenotypic plasticity and learning behavior into modeling can drastically change dynamical behavior of the system. Unification of biological sciences will be facilitated and integrated, such as behavioral ecology and behavioral neurobiology in the area of learning, and evolutionary ecology and molecular developmental biology in the theme of phenotypic plasticity.     

Identification of key genes responsible for cytokine-induced erythroid and myeloid differentiation and switching of hematopoietic stem cells by RAGE

We utilized a unique culture system to analyze the expression patterns of gene, protein, and cell surface antigen, and the biological process of the related genes in erythroid and myeloid differentiation and switching of hematopoietic stem cells （HSCs） in response to cytokine alterations. Gene-specific fragments （266） identified from five populations of cytokine-stimulated HSCs were categorized into three groups： （1） expressed specifically in a single cell population; （2） expressed in two cell populations, and （3） expressed in three or more populations. Of 145 defined cDNAs, three （2%） were novel genes. Protein two-dimensional gel electrophoresis and flow cytometry analyses showed overlapped and distinguished protein expression profiles in the cell populations studied. Biological process mapping of mRNAs expressed in erythroid and myeloid lineages indicated that mRNAs shared by both lineages attended ＇core processes,＇ whereas genes specifically expressed in either lineage alone were related to specific processes or cellular maturation. Data from this study support the hypothesis that committed HSCs （El4 or G14） cells can still be redirected to develop into myeloid or erythroid cells when erythropoietin （EPO） is replaced with granulocyte-colony stimulating factor （G-CSF） under erythroid-cultured condition or G-CSF with EPO in myeloid-cultured environment, respectively. Our results suggest that genes or proteins co-expressed in erythroid and myeloid lineages may be essential for the lineage maintenance and switching in hematopoiesis.     

Solvent-induced anomeric diastereoselectivity switching using a single glycosyl donor

Highly diastereoselective glycosylation reactions have been developed; however, not all glycosylation reactions are diastereoselective and these reactions have probably not been reported. For some fucosylation reactions, unusually low or abnormally opposite selectivities have been demonstrated. In the present study, the fucosylation reaction of long-chain hydrocarbon alcohols, ethyl 9-hydroxynonanoate and decanol using a series of the 2-O-benzyl-protected fucopyranosyl donors were investigated. The resulting products demonstrated the solvent-induced diastereoselectivity switching using diethyl ether (Et₂O) or dichloromethane (CH₂Cl₂). Practical α-selectivities were observed using ether solvents. In contrast, practical β-selectivities were observed using CH₂Cl₂. The anomeric diastereoselectivity switching was similarly observed in the alcohol galactosylation reaction. The larger spin-lattice relaxation time constant (T₁) actually indicated that molecular motion of ethyl 9-hydroxynonanoate was more vigorous in Et₂O than in CH₂Cl₂, suggesting its dissociation in Et₂O and association in CH₂Cl₂. The bulkiness of the associated alcohols is most likely responsible for the observed diastereoselectivity.     

RNA templating of molecular assembly and covalent modification patterning in early molecular evolution and modern biosystems

The Direct RNA Template (DRT) hypothesis proposes that an early stage of genetic code evolution involved RNA molecules acting as stereochemical recognition templates for assembly of specific amino acids in sequence-ordered arrays, providing a framework for directed covalent peptide bond formation. It is hypothesized here that modern biological precedents may exist for RNA-based structural templating with functional analogies to hypothetical DRT systems. Beyond covalent molecular assembly, an extension of the DRT concept can include RNA molecules acting as dynamic structural template guides for the specific non-covalent assembly of multi-subunit complexes, equivalent to structural assembly chaperones. However, despite numerous precedents for RNA molecules acting as scaffolds for protein complexes, true RNA-mediated assembly chaperoning appears to be absent in modern biosystems. Another level of function with parallels to a DRT system is possible if RNA structural motifs dynamically guided specific patterns of catalytic modifications within multiple target sites in a pre-formed polymer or macromolecular complex. It is suggested that this type of structural RNA templating could logically play a functional role in certain areas of biology, one of which is the glycome of complex organisms. If any such RNA templating processes are shown to exist, they would share no necessary evolutionary relationships with events during early molecular evolution, but may promote understanding of the practical limits of biological RNA functions now and in the ancient RNA World. Awareness of these formal possibilities may also assist in the current search for functions of extensive non-coding RNAs in complex organisms, or for efforts towards artificial rendering of DRT systems.     

The genomic architecture of the PROS1 gene underlying large tandem duplication mutation that causes thrombophilia from hereditary protein S deficiency

Hereditary protein S deficiency from a mutation in the PROS1 gene causes a genetic predisposition to develop venous thromboembolic disorders in humans. Recently, the acknowledgment of the clinical significance of large copy number mutations in protein S deficiency has increased. In this study, the authors investigated the genomic architecture of PROS1 in order to understand the microscopic sequence environment leading to large intragenic copy number mutations in the gene. The study subjects were 3 unrelated male patients with hereditary protein S deficiency from a tandem duplication mutation involving exons 5–10 of PROS1. Breakpoint analyses revealed 10-bp microhomology sequences in the intervening sequence (IVS)-4 and IVS-10 at the duplication junction without additional sequence changes, suggesting a single replication-based event as the potential molecular mechanism of rearrangement and founder effect in the mutant alleles. Further analyses on nucleotide sequences flanking the microhomology sequence revealed the presence of a repeat element (LTR-ERV1) and quadruplex-forming G-rich sequences in IVS-4. The results from genotyping multi-allelic short tandem repeats supported founder effect in the identical mutations in the 3 unrelated patients. In conclusion, we identified unique genomic architectures in the intervening sequences of PROS1 that underlie a large intragenic tandem duplication mutation leading to inherited thrombophilia.