Establishment of dependence relationships between genome replication and mitosis

Although budding yeast cell biology and genetics provided a powerful system to isolate S-phase checkpoint mutants, initial studies relied on a defect not likely to be relevant in higher eukaryotes. The first mutants were isolated for their inability to restrain mitotic spindle elongation in S-phase. Since most eukaryotes do not assemble spindles until prometaphase the validity of this approach might have been questioned. However, these early studies were designed with a highly valid assumption in mind; that checkpoints have a variety of targets, but comprise conserved kinase cascades that make up these signaling pathways. The task that lies ahead is to determine targets of the S-phase checkpoint relevant to mammals. One step forward might be the realization that the budding yeast S-phase checkpoint prevents loss of sister chromatid cohesion while DNA replication is ongoing. If this mechanism is conserved in mammals, it could prove vital for chromosome segregation fidelity.     

Factors influencing eating ability of old in-patients in a rehabilitation hospital in Japan

Objectives: This study was designed to determine the factors influencing eating ability of old in‐patients in a rehabilitation hospital. Design: Cross‐sectional investigation. Setting: Forty‐six in‐patients in the rehabilitation ward of Hashimoto Hospital in Kagawa Prefecture in Japan were investigated using a multi‐disciplinary approach. Main outcome measures: Age, gender, state of dentition, muscle activity of lip, cheek and tongue, biting force, salivary flow rate per a minute (SFR), masticatory ability for gummy jelly, swallowing ability, texture of meal, independency of walking (Functional Independence Measure=FIM) and ability to communicate. Results: Bivariate analysis for the relationship between surveyed items and masticatory ability (chi‐square test) identified that better masticatory ability for gummy jelly was associated with age (<85 years), gender (male), state of dentition (dentate), SFR (high), activity of lip (good), biting force (high), swallowing ability (good) and activity of communication (high). Among these items, SFR (p=0.001), gender (p=0.004), ability to communicate (p=0.005) and age (p=0.012) were found having an influence on the masticatory ability (logistic regression analysis). On the other hand, age (<85years), gender (male), SFR (high), activity of lip (good), activity of cheek (good), biting force (high), masticatory ability (good) and swallowing ability (good) had a relationship with normal texture of meal. In regression analysis, only two items, activity of lip (p=0.003) and swallowing ability (p=0.024) emerged as factors on texture of meal. Conclusions: Masticatory ability for gummy jelly was influenced by cognitive function and was excluded from the factors on the state of meal. These results suggested the limitation of evaluation using test food, so dentists should observe eating behaviour of in‐patients. In addition, dentists should pay attention to the activity of the lip and swallowing ability as well as dentition and prostheses in the rehabilitation of eating ability. As SFR was the most significant factor on masticatory ability, this emphasizes the necessity of care for dry mouth caused by side effects of multi‐medication     

Fluorescent dyes as probes to study lipid-binding proteins

We studied the equilibrium binding of two hydrophobic fluorescent dyes, ANS and bisANS, to four members of a family of intracellular lipid-binding proteins: IFABP, CRABP I, CRABP II, and ILBP. The spectral and binding parameters for the probes bound to the proteins were determined. Typically, there was a single binding site on each protein for the ligands. However, IFABP cooperatively bound a second bisANS molecule in the binding pocket. Comparative analysis of affinities and spectral characteristics for the two probes allowed us to examine the contributions of electrostatic and hydrophobic interactions to the binding process, and to address some aspects of the internal structure of the studied proteins.     

Structure of human aldose reductase holoenzyme in complex with statil: an approach to structure-based inhibitor design of the enzyme

Aldose reductase, a monomeric NADPH-dependent oxidoreductase, catalyzes the reduction of a wide variety of aldehydes and ketones to their corresponding alcohols. The X-ray structure of human aldose reductase holoenzyme in complex with statil was determined at a resolution of 2.1 A. The carboxylate group of statil interacted with the conserved anion binding site located between the nicotinamide ring of the coenzyme and active site residues Tyr48, His110, and Trp111. Statil's hydrophobic phthalazinyl ring was bound in an adjacent pocket lined by residues Trp20, Phe122, and Trp219, with the bromo-fluorobenzyl group penetrating the "specificity" pocket. The interactions between the inhibitor's bromo-fluorobenzyl group and the enzyme include the stacking against the side-chain of Trp111 as well as hydrogen bonding to residues Leu300 and Thr113. Based on the model of the ternary complex, the program GRID was used in an attempt to design novel potential inhibitors of human aldose reductase with enhanced binding energies of the complex. Molecular modeling calculations suggested that the replacement of the fluorine atom of statil with a carboxylate functional group may enhance the binding energies of the complex by 33%.     

Modeling alpha-helical coiled-coil interactions: the axial and azimuthal alignment of 1B segments from vimentin intermediate filaments

Attempts at predicting the relative axial alignments of fibrous protein molecules in filamentous structures have relied upon representing the (multichain) molecular structure by a one-dimensional sequence of amino acids. Potential intermolecular ionic and apolar interactions were counted and determined as a function of the relative axial stagger between the molecules. No attempts were made to consider the azimuthal aspect of the interacting molecules and neither were apolar or ionic energy terms used. Surprisingly, this simple approach proved remarkably informative and yielded accurate predictions of the axial periods present. However, a more comprehensive analysis involving the energetics of aggregation taking due regard for the relative azimuths of the molecules as well as their separation should decrease the noise level in the calculations and reveal other pertinent information. Toward that end, we have modeled the interaction between two alpha-helical coiled-coil segments in intermediate filament molecules (1B segments from human vimentin). The relative axial alignment and polarity of the molecules is already known from detailed crosslinking studies and this provides a criterion against which the success (or otherwise) of the modeling can be judged. The results confirm that an antiparallel alignment of two 1B segments is preferred over any of the parallel options (as observed experimentally). The calculated axial alignment, however, is not identical to that observed from detailed crosslinking studies indicating that other parts of the molecule (probably the head and tail domains as well as other coiled-coil segments) have a crucial role in determining the precise mode of axial aggregation. The results also show that the apolar interactions seem to be significantly less important in the alignment process than the ionic ones. This is consistent with the observation of a well-defined period in the linear disposition of the charged (but not apolar) residues along the length of the outer surface of the vimentin molecule.     

Subunit E of mitochondrial ATP synthase: a bioinformatic analysis reveals a phosphopeptide binding motif supporting a multifunctional regulatory role and identifies a related human brain protein with the same motif

The mitochondrial adenosine triphosphate (ATP) synthase is located in the inner membrane and consists of at least 16 subunit types in animals, one of which is subunit e, the function of which is not clearly defined. A highly homologous protein is located in the nucleus and named progesterone receptor binding protein (RBF), to designate its role in this organelle. In addition, the expression level of subunit e in mammalian cells fluctuates greatly and is induced by certain carcinogens and elevated in liver cancers. Because these previous observations suggested to us that subunit e may play multifunctional regulatory roles, we employed a bioinformatic approach to test this view. First, from sequence alignment studies, secondary structure analyses, and basic local alignment search tool (BLAST) searches, we concluded that mitochondrial subunit e and the homologous nuclear protein RBF are most likely the same protein. Second, we examined the known sequence and structure of one of the most common multifunctional cell regulatory proteins, the 14-3-3 protein, involved in phosphopeptide binding, and deduced that it has an apparent binding motif (-KX(6)R---RY-). Third, from careful examination of the conserved residues within all subunit e sequences in the database, we discovered that this protein has a comparable binding motif (-RY---KX(6)R-). Finally, in a BLAST search for additional homologs of subunit e, we found a human brain protein, KIAA1578, the C-terminal 30 amino acids of which are identical to those of human subunit e. This protein also contains a potential phosphopeptide binding motif. In summary, these studies provide support for the view that subunit e is a multifunctional cell regulator involved in cell signaling, and implicate the involvement of the KIAA1578 protein in cell signaling as well. These studies suggest also that, while functioning as a subunit of mitochondrial ATP synthases, subunit e may help regulate these complexes by binding to phosphopeptides within one or more of the other subunit types.     

Insights into the bile acid transportation system: the human ileal lipid-binding protein-cholyltaurine complex and its comparison with homologous structures

Bile acids are generated in vivo from cholesterol in the liver, and they undergo an enterohepatic circulation involving the small intestine, liver, and kidney. To understand the molecular mechanism of this transportation, it is essential to gain insight into the three-dimensional (3D) structures of proteins involved in the bile acid recycling in free and complexed form and to compare them with homologous members of this protein family. Here we report the solution structure of the human ileal lipid-binding protein (ILBP) in free form and in complex with cholyltaurine. Both structures are compared with a previously published structure of the porcine ILBP-cholylglycine complex and with related lipid-binding proteins. Protein structures were determined in solution by using two-dimensional (2D)- and 3D-homo and heteronuclear NMR techniques, leading to an almost complete resonance assignment and a significant number of distance constraints for distance geometry and restrained molecular dynamics simulations. The identification of several intermolecular distance constraints unambiguously determines the cholyltaurine-binding site. The bile acid is deeply buried within ILBP with its flexible side-chain situated close to the fatty acid portal as entry region into the inner ILBP core. This binding mode differs significantly from the orientation of cholylglycine in porcine ILBP. A detailed analysis using the GRID/CPCA strategy reveals differences in favorable interactions between protein-binding sites and potential ligands. This characterization will allow for the rational design of potential inhibitors for this relevant system.     

Comparison of prostate gene expression and tissue weight changes as monitors of antiandrogen activity in GNRH-inhibited rats

BACKGROUND: The Hershberger assay for antiandrogens and modifiers of steroid biosynthesis uses surgically‐castrated rats. We described an adaptation of the assay using the GnRH inhibitor Antarelix in place of surgical castration [Ashby J, Lefevre PA, Deghenghi R, Wallis N. Regulatory Toxicology and Pharmacology 34:188–203, 2001], and concomitantly described changes in expression of the androgen‐dependent prostatic genes PBP C3, TRPM‐2, and ODC as a possible complement to gravimetric analysis of the sex accessory tissues (SAT) [Nellemann C, Vinggaard AM, Dalgaard M, Hossaini A, Larsen J‐J. Toxicology 163:29–38, 2001]. METHODS: The present study describes the results of combining these two modifications into a single assay. During the course of these experiments it was shown that SD rats gave similar results to AP rats and that the higher stimulatory dose of testosterone propionate (TP) used in our experiments gave stronger assay responses to FLU than the lower dose of TP used by some earlier investigators. The potent antiandrogen flutamide (FLU) and the weak antiandrogen DDE were used to evaluate this modified assay. RESULTS: For all parameters studied (SAT weights and changes in expression of the 3 prostatic genes) FLU gave the expected positive results. The weak antiandrogen DDE gave variable and mainly non‐reproducible responses. Use of DDE as a weak antiandrogen accelerated assessment of the new assay. CONCLUSIONS: Possible reasons for this failure to detect DDE are discussed, and it is concluded that the modified assay is unsuitable for use in its present form. The use of gene expression analyses together with evaluation of SAT weights is a promising tool as an early and sensitive marker of antiandrogen action, but more work is needed on the choice of time frame as well as the selection of genes to monitor. Birth Defects Res B 68:344–354, 2003. © 2003 Wiley‐Liss, Inc.