Characterization of cholylglycine hydrolase from a bile-adapted strain of Xanthomonas maltophilia and its application for quantitative hydrolysis of conjugated bile salts

Purified bile salt hydrolase from bile-adapted Xanthomonas maltophilia displays Michaelis-Menten kinetics on cholylglycine and cholyltaurine and hydrolyzes bile salts also in crude bovine bile. The protein is a dimer and is resistant to proteinases and to heating at 55 to 60 degrees C for up to 60 min, in agreement with calorimetric data.     

Comparison of protein fragments identified by limited proteolysis and by computational cutting of proteins

Here we present a comparison between protein fragments produced by limited proteolysis and those identified by computational cutting based on the building block folding model. The principles upon which the two methods are based are different. Limited proteolysis of natively folded proteins occurs at flexible sites and never at the level of chain segments of regular secondary structure such as alpha-helices. Therefore, the targets for limited proteolysis are locally unfolded regions. In contrast, the computational cutting algorithm considers the compactness of the fragments, their nonpolar buried surface area, and their isolatedness, that is, the surface area which was buried prior to the cutting and becomes exposed subsequently. Despite the different criteria, there is an overall correspondence between sites or regions of limited proteolysis with those identified by computational cutting. The computational cutting method has been applied to several model proteins for which detailed limited proteolysis data are available, namely apomyoglobin, cytochrome c, ribonuclease A, alpha-lactalbumin, and thermolysin. As expected, more cuts are obtained computationally than experimentally and the agreement is better when a number of proteolytic enzymes are used. For example, cytochrome c is cleaved by thermolysin at 56-57, 45-46, and at 80-81, and by proteinase K at 48-49 and 50-51. Incubation of the noncovalent and native-like complex of cytochrome c fragments 1-56 and 57-104 with proteinase K yielded the gapped protein species 1-48/57-104 and finally 1-40/57-104. Computational cutting of cytochrome c reproduced the major experimental observations, with cuts at 47, 64-65 or 65-66 and 80-81 and an unstable 32-47 region not assigned to any building block. The next step, not addressed in this work, is to probe the ability of the generated fragments to fold independently. Since both the computational algorithm and limited proteolysis attempt to dissect the protein folding problem, the general agreement between the two procedures is gratifying. This consistency allows us to propose the use of limited proteolysis to produce protein fragments that can adopt an independent folding and, therefore, to study folding intermediates. The results of the present study appear to validate the building block folding model and are in line with the proposal that protein folding is a hierarchical process, where parts constituting local minima of energy fold first, with their subsequent association and mutual stabilization to finally yield the global fold.     

On the complexities of ceramide changes in cells undergoing apoptosis: lack of evidence for a second messenger function in apoptotic induction

The generation of cellular ceramides as a second messenger has been implicated as a regulatory and required step for the induction of apoptosis. In this study, we have applied a recently developed mass spectrometric technique to the determination of changes in physiological ceramide levels during apoptosis induced by tumor necrosis factor plus cycloheximide in U937 cells and the chemical agents anisomycin or geranylgeraniol in HL-60 cells. The mass spectrometric method has significant advantages over traditional methods for ceramide quantitation in that it determines the relative abundance of all ceramide species present in complex biological lipid mixtures individually and simultaneously. We quantitiated ceramides ranging from C14 to C26, finding that their basal levels and relative distribution varied significantly, both within and between different cell types. However, we were not able to detect any significant changes in either total ceramide content or species distribution until 1 h or more post-stimulation with any of these treatments, by which time the cells were in an advanced stage of apoptosis. Differences were also seen between all three treatments in the ceramide species distribution observed in these late stages of apoptosis. These data indicate that in vivo ceramide generation occurs as a consequence of apoptosis rather than as an essential second messenger involved in its induction. They also pose new questions about the potential roles that certain ceramide species may play in the late stages of apoptosis, and demonstrate a clear need to utilize the resolving power of mass spectrometry-based assays in any future investigations into the biological function of ceramides.     

Characterization of Cholylglycine Hydrolase from a Bile-Adapted Strain of Xanthomonas maltophilia and Its Application for Quantitative Hydrolysis of Conjugated Bile Salts

Purified bile salt hydrolase from bile-adapted Xanthomonas maltophilia displays Michaelis-Menten kinetics on cholylglycine and cholyltaurine and hydrolyzes bile salts also in crude bovine bile. The protein is a dimer and is resistant to proteinases and to heating at 55 to 60°C for up to 60 min, in agreement with calorimetric data.     

Assessing the maternal origin in the polyploid complex of <Emphasis Type="Italic">Camellia reticulata</Emphasis> based on the chloroplast <Emphasis Type="Italic">rpl</Emphasis>16 intron sequences: implications for camellia cross breeding

Camellia reticulata is a well-known woody ornamental species endemic to Southwest China. It represents a polyploid complex with diploids, allotetraploids, and allohexaploids. The parentage of the allotetraploids and allohexaploids has been reported by genomic in situ hybridization, but the maternal parents still remain unknown. In this study, sequences of the chloroplast rpl16 intron of 105 cultivars of C. reticulata and 7 congeneric species were used to infer the maternal origin of the allopolyploids. The results showed that (1) the allotetraploids were derived from C. pitardii as the maternal parental species and the diploid C. reticulata as the paternal parental species; (2) the allohexaploid C. reticulata was derived from the allotetraploid C. reticulata as the maternal parent and C. saluenensis as the paternal parent; and (3) the C. reticulata cultivars were derived from hexaploid C. reticulata as the maternal parents. These results indicated that C. pitardii, the allotetraploid and allohexaploid C. reticulata may serve as good potential maternal parents for the cross breeding of Camellia.     

Mitochondrial control-region sequences in two shorebird species, the turnstone and the dunlin, and their utility in population genetic studies

We determined the mitochondrial control-region sequences of five turnstones (Arenaria interpres) and three dunlins (Calidris alpina). Comparisons revealed that the central part (part II) is conserved relative to much more variable parts at the beginning (part I) and the end (part III). This pattern of sequence conservation is also found in the control regions of other vertebrates. The average sequence divergence between turnstone and dunlin was 21.8% for part I, 7.5% for part II, and 29.5% for part III. Within-species sequence divergence over the entire control region was much lower, at 0.9% for turnstones and 2.0% for dunlins. In both shorebird species, part III contains a repetitive sequence composed only of A and C nucleotides, which has not been found in the control regions of other birds. A survey of the part I sequences of 25 turnstones and 25 dunlins sampled around the world revealed that these species have very different population genetic structures. Dunlins are not only much more differentiated in their sequences but also have a strongly subdivided population genetic structure. Pleistocene vicariant events combined with strong natal philopatry and high mutation rates of the sequences are likely responsible for this population genetic subdivision. Conversely, part I sequences of turnstones are weakly differentiated and are geographically unstructured. We argue that this is not the result of global gene flow but that, instead turnstones have recently expanded from a refugial population that was bottlenecked.      

Amyloid fibril formation and disaggregation of fragment 1-29 of apomyoglobin: insights into the effect of pH on protein fibrillogenesis

The N-terminal fragment 1-29 of horse heart apomyoglobin (apoMb(1-29)) is highly prone to form amyloid-like fibrils at low pH. Fibrillogenesis at pH 2.0 occurs following a nucleation-dependent growth mechanism, as evidenced by the thioflavin T (ThT) assay. Transmission electron microscopy (TEM) confirms the presence of regular amyloid-like fibrils and far-UV circular dichroism (CD) spectra indicate the acquisition of a high content of beta-sheet structure. ThT assay, TEM and CD highlight fast and complete disaggregation of the fibrils, if the pH of a suspension of mature fibrils is increased to 8.3. It is of interest that amyloid-like fibrils form again if the pH of the solution is brought back to 2.0. While apoMb(1-29) fibrils obtained at pH 2.0 are resistant to proteolysis by pepsin, the disaggregated fibrils are easily cleaved at pH 8.3 by trypsin and V8 protease, and some of the resulting fragments aggregate very quickly in the proteolysis mixture, forming amyloid-like fibrils. We show that the increase of amyloidogenicity of apoMb(1-29) following acidification or proteolysis at pH 8.3 can be attributed to the decrease of the peptide net charge following these alterations. The results observed here for apoMb(1-29) provide an experimental basis for explaining the effect of charge and pH on amyloid fibril formation by both unfolded and folded protein systems.