Biochemical and molecular analysis of the beta-globin gene and LCR region on Saudi β-thalassemia patients

IntroductionBeta-thalassemias are a group of inherited blood disorders caused by reduced or absent synthesis of beta chain of hemoglobin resulting in variable phenotypes ranging from clinically asymptomatic individuals to severe anemia symptoms. The objective of this study is to screen for the whole beta gene globulin and the LCR region and its clinical relevance in β-Thalassemia patients.MethodsIn this study, we collected 140 blood patients' samples with beta-thalassemia from different areas of Saudi Arabia. DNA was then extracted then the molecular scanning for the whole β-globin gene and the Locus control region (β-LCR) for patients' samples, was run using PCR.ResultsSixty one mutations found in this study, including 22 new mutations not recorded in the database before. These deletions including: (*C-1960-1961 ca/-- del in hbb5) and (*c-519C<T homo, *c-390C<T homo in hbb6) were the highest among beta-thalassemia in the study, which indicates a strong sign of injury associated with the disease. Meanwhile, There are other mutations found most common among patients and was linked with the severity of clinical symptoms including: (c-1960-1961 ca/-- del in hbb5), (c-519C<T homo, c-390C<T homo, c-160 G<A het in hbb6), (c.315+282 G<A het, c.316-225G<A het, c.315+342 G > A het in hbb9). Interestingly, the highest percentage in gene deletion occurred in exon 03A by ∼33% of the samples, while the highest percentage in gene addition of the gene occurred in exon 03B by ∼25%.ConclusionThis study was unique to show several new mutations that would help in diagnosis and treatment. These results should be taken further to set up better management strategies to improve outcomes.     

Fine mapping and candidate gene analysis of a green-revertible albino gene gra（t） in rice

Green-revertible albino is a novel type of chlorophyll deficiency in rice （Oryza sativa L.）, which is helpful for further research in chlorophyll synthesis and chloroplast development to illuminate their molecular mechanism. In the previous study, we had reported a single recessive gene, gra（t）, controlling this trait on the long arm of chromosome 2. In this paper, we mapped the gra（t） gene using 1,936 recessive individuals with albino phenotype in the F2 population derived from the cross between themo-photoperiod-sensitive genic male-sterile （T/PGMS） line Pei＇ai 64S and the spontaneous mutant Qiufeng M. Eventually, it was located to a confined region of 42.4 kb flanked by two microsatellite markers RM2-97 and RM13553. Based on the annotation results of RiceGAAS system, 11 open reading frames （ORFs） were predicted in this region. Among them, ORF6 was the most possible gene related to chloroplast development, which encoded the chloroplast protein synthesis elongation factor Tu in rice. Therefore, we designated it as the candidate gene of gra（t）. Sequence analysis indicated that only one base substitution C to T occurred in the coding region, which caused a missense mutation （Thr to Ile） in gra（t） mutant. These results are very valuable for further study on gra（t） gene.     

Sclerotial development in Sclerotinia sclerotiorum: awakening molecular analysis of a “Dormant” structure

Sclerotia are hard, asexual, resting structures which can survive for years in soil. In Sclerotinia sclerotiorum, which provides a good model system for studying sclerotial development, sclerotial development has been traditionally divided to three macroscopically distinct stages (initiation, development and maturation). However, additional phases (which can be visualized microscopically) indicate a complex, multi-step, process is involved. Environmental changes, primary metabolism and secondary messengers have been well documented factors affecting sclerotial development, yet analysis of the molecular mechanisms involved in sclerotial development is in its infancy. Here, we review the current status of the known molecular components involved in sclerotial development, with an emphasis on phosphorylative regulation of sclerotial development in S. sclerotiorum. Components such as cAMP-dependent protein kinase, ERK-like mitogen-activated protein kinase and Ser/Thr phosphatases type 2A and 2B, shown to regulate other developmental processes in fungi, have recently been shown to also be involved in regulation of sclerotium development. Reversible protein phosphorylation, as well as additional regulatory mechanisms of gene expression such as DNA methylation and ribosome inactivation, most likely function in concert with secondary metabolites, reactive oxygen species, pH and light in order to regulate sclerotial development in different fungi. The diversity of sclerotium-producing fungi promises to yield exciting variations into the molecular mechanisms regulating this developmental process in different species.     

Biochemical,cellular and molecular identification of DNA polymerase α in yeast mitochondria

DNA replication occurs in various compartments of eukaryotic cells such as the nuclei, mitochondria and chloroplasts, the latter of which is used in plants and algae. Replication appears to be simpler in the mitochondria than in the nucleus where multiple DNA polymerases, which are key enzymes for DNA synthesis, have been characterized. In mammals, only one mitochondrial DNA polymerase (pol γ) has been described to date. However, in the mitochondria of the yeast Saccharomyces cerevisiae, we have found and characterized a second DNA polymerase. To identify this enzyme, several biochemical approaches such as proteinase K treatment of sucrose gradient purified mitochondria, analysis of mitoplasts, electron microscopy and the use of mitochondrial and cytoplasmic markers for immunoblotting demonstrated that this second DNA polymerase is neither a nuclear or cytoplasmic contaminant nor a proteolytic product of pol γ. An improved purification procedure and the use of mass spectrometry allowed us to identify this enzyme as DNA polymerase α. Moreover, tagging DNA polymerase α with a fluorescent probe demonstrated that this enzyme is localized both in the nucleus and in the organelles of intact yeast cells. The presence of two replicative DNA polymerases may shed new light on the mtDNA replication process in S. cerevisiae.     

Cytogenetic analysis of variegation suppressors and a dominant temperature-sensitive lethal in region 23–26 of chromosome 2L in Drosophila melanogaster

Three suppressor loci for position-effect variegation, one dominant temperature-sensitive (DTS), three Minute genes, and two recessive visible mutants (ed, tkv) have been cytogenetically localized by using duplications and deficiencies in regions 23-25 of chromosome arm 2L of Drosophila melanogaster. Two of the suppressor loci studied proved to represent haplo-abnormal genes localized in regions 23A6-23F6 and 24E2-25A1, respectively. The third one is a strong triplo-abnormal suppressor mapping in 25F4-26B9 which affects white variegation in wm4h when present in three doses. The l(2)2DTS mutation, which belongs to a group of noncomplementing dominant temperature-sensitive mutations, is localized in the 25A4-B1 region. Furthermore, two Minute genes have been localized in region 24 that are included in Df(2L)M11 and can be separated employing translocation (Y;2)P8 (24E2-4): M(2)LS2 in 24D3-4-24E2-4, and M(2)z in 24E4-5-24F5-7. A third Minute gene (M(2)S1) is localized in 25C3-8-25C9-D1. The usefulness of the isolated chromosomal rearrangements for further genetic studies of region 23-26 is discussed.     

Prediction of mutant activity and its application in molecular design of tumor necrosis factor-α

Two models for prediction of the activity and stability of site-directed mutagenesis on tumor necrosis factor-α are established. The models are based on straightforward structural considerations, which do not require the elaboration of sitedirected mutagenesis on the protein core and the hydrophobic surface area by analyzing the pmperties of the mutated amino acid residues. The reliabilities of the models have been tested by analyzing the mutants of tumor necrosis factor-α (TNF-α) whose two leucine residues (L29, L157) were mutated. Based on these models, a TNFα mutant with high activity was created by molecular design.     

Immunological and biochemical analysis of a null mutant of α-glycerolphosphate dehydrogenase from Drosophila melanogaster

Summary A Drosophila null mutant(BO-1-4) of -glycerolphosphate dehydrogenase induced by ethylmethane sulfonate(EMS) was analyzed by double immunodiffusion, enzyme immuno-inactivation, immunoelectrophoresis and two-dimensional electrophoresis. Based on all the immunological evidence, this mutant appears to express no protein that can cross-react with the antiserum specific to -glycerolphosphate dehydrogenase. A protein spot corresponding to -glycerolphosphate dehydrogenase was identified on two-dimensional gels of the soluble fly homogenates. The absence of this protein spot on two-dimensional gels of this null mutant further supported the immunological data. The activities of seven other enzymes in the related metabolic pathways were determined for the mutant and the control Drosophila. The null mutant does not show significant alterations in activities of these enzymes. The relationship between the deficiency of this enzyme and the inability for the sustained flight of the null mutant was discussed in terms of cellular metabolic regulations.Abbreviations used -GPD -glycerolphosphate dehydrogenase (EC 1.1.1.8) - EMS ethylmethane sulfonate - TEMED N,N,N,N-tetramethylene diamine - pI isolectric point - CRM immunological cross-reacting material     

Biochemical and molecular characterization of Saccharomyces cerevisiae strains obtained from sugar-cane juice fermentations and their impact in cachaça production

Saccharomyces cerevisiae strains from different regions of Minas Gerais, Brazil, were isolated and characterized aiming at the selection of starter yeasts to be used in the production of cachaça, the Brazilian sugar cane spirit. The methodology established took into account the screening for biochemical traits desirable in a yeast cachaça producer, such as no H₂S production, high tolerance to ethanol and high temperatures, high fermentative capacity, and the abilities to flocculate and to produce mycocins. Furthermore, the yeasts were exposed to drugs such as 5,5′,5"-trifluor-d,l-leucine and cerulenin to isolate those that potentially overproduce higher alcohols and esters. The utilization of a random amplified polymorphic DNA-PCR method with primers based on intron splicing sites flanking regions of the COX1 gene, as well as microsatellite analysis, was not sufficient to achieve good differentiation among selected strains. In contrast, karyotype analysis allowed a clear distinction among all strains. Two selected strains were experimentally evaluated as cachaça producers. The results suggest that the selection of strains as fermentation starters requires the combined use of biochemical and molecular criteria to ensure the isolation and identification of strains with potential characteristics to produce cachaça with a higher quality standard.Cachaça (pronounced “kha-sha-ssa”), the sugar cane spirit, is the most popular distilled beverage produced in Brazil. The annual production reaches 1.3 billion liters, with 15% being produced in more than 8,500 distilleries in the state of Minas Gerais.Traditional cachaça production relies on a spontaneous fermentative process that is mediated by the microbiota present in the cane juice wort and on the surface of equipments used in the productive process. It has been already demonstrated that in such systems there occurs a succession of yeasts, with Saccharomyces cerevisiae being the predominant species. Cachaça quality depends on the ecology of the microbial populations during an initial spontaneous fermentation (18, 29, 31, 32, 39). The fermentative process occurs through a continuously open fermentative process which is completed within 24 h and generally takes place from May to November, corresponding to the sugar cane harvesting period.Considering the conditions of production usually found in the cachaça distilleries, fermenting yeast populations have to face different types of stress (osmotic, high temperature, and high ethanol concentration). Besides, they might also present some characteristics such as a good fermentative power, no H₂S production, killer activity, flocculation ability, and production of flavoring compounds. Taking all of these factors into account, we have developed a strategy to select yeast strains with appropriated characteristics to produce cachaça with potentially higher-quality standards (52).Parallel to the selection and development of S. cerevisiae strains toward ethanolic fermentations, molecular methods were developed and validated to study the evolution of yeast flora in spontaneous but also in inoculated fermentations. Chromosomal karyotyping by pulsed-field gel electrophoresis is a complex and time-consuming process but is very efficient for the delimitation of S. cerevisiae strains since it makes it possible to distinguish strains at both the intra- and the interspecies levels. Numerous other methods of typing based on DNA polymorphism allow differentiating closely related yeast strains (8, 36, 43, 50). Restriction fragment length polymorphism (RFLP) analysis of mitochondrial DNA (mtDNA) is faster and easier than other methods (23, 31). Digestion of mtDNA with restriction enzymes such as HinfI or RsaI is associated with a high rate of polymorphism and has been used to study the authenticity of commercial wine yeast strains (14, 40, 41). A PCR method based on variations found on the mitochondrial COX1 (a gene coding for cytochrome oxidase) intron number and position has been validated to distinguish S. cerevisiae strains allowing researchers to monitor the evolution of wine fermentations conducted by commercial active dry yeast (27). Moreover, in many other studies, RAPD [random(ly) amplified polymorphic DNA]-PCR with different primers such as EL1 and LA1 has been successfully used to discriminate between wine yeast strains (2) and for differentiation of Saccharomyces species isolated in Brazil (18). In the last few years, fingerprinting of microsatellite or simple sequence repeat loci, short (1 to 10 nucleotides) DNA tandem repeats dispersed throughout the genome and with a high degree of variability, has proven to be useful for distinguishing S. cerevisiae strains (16, 20, 34, 40, 45). These loci exhibit a substantial level of polymorphism and have been used in humans for paternity tests and forensic medicine but also for the demonstration of population structures among indigenous S. cerevisiae strains (24, 42, 43).We describe here the isolation and characterization of S. cerevisiae strains from cachaça and the use of two of these strains in cachaça production. The strains were isolated from local producers and characterized by growth in high-alcohol, high-sugar environments and in the presence of 5,5′,5"-trifluor-d,l-leucine (TFL) and cerulenin to detect overproducers of flavor compounds. We also used molecular methods to evaluate the polymorphisms of yeast strains in the fermentative process. Our results demonstrate that some methodologies based on DNA polymorphism are insufficient to evaluate the diversity of S. cerevisiae population during the cachaça production. The utilization of specific biochemical tests is necessary in order to permit a more precise characterization of the dynamics of the selected strains during the fermentative process. Only by combining biochemical and molecular methods were we able to select strains that showed a suitable profile to be used as starters. The cachaça produced with these strains was also evaluated, and the results demonstrate that the quality of the final product is better than that obtained with a commercial strain also used to produce cachaça.     

Biochemical characterization of recombinant β-glucosyltransferase and analysis of global 5-hydroxymethylcytosine in unique genomes

5-Hydroxymethylcytosine (5-hmC) is an enzymatic oxidative product of 5-methylcytosine (5-mC). The Ten Eleven Translocation (TET) family of enzymes catalyze the conversion of 5-mC to 5-hmC. Phage-encoded glucosyltransferases are known to glucosylate 5-hmC, which can be utilized to detect and analyze the 5-hmC as an epigenetic mark in the mammalian epigenome. Here we have performed a detailed biochemical characterization and steady-state kinetic parameter analysis of T4 phage β-glucosyltransferase (β-GT). Recombinant β-GT glucosylates 5-hmC DNA in a nonprocessive manner, and binding to either 5-hmC DNA or uridine diphosphoglucose (UDP-glucose) substrates is random, with both binary complexes being catalytically competent. Product inhibition studies with β-GT demonstrated that UDP is a competitive inhibitor with respect to UDP-glucose and a mixed inhibitor with respect to 5-hmC DNA. Similarly, the glucosylated-5-hmC (5-ghmC) DNA is a competitive inhibitor with respect to 5-hmC DNA and mixed inhibitor with respect to UDP-glucose. 5-hmC DNA binds ~10 fold stronger to the β-GT enzyme when compared to its glucosylated product. The numbers of 5-hmC on target sequences influenced the turnover numbers for recombinant β-GT. Furthermore, we have utilized recombinant β-GT to estimate global 5-hmC content in a variety of genomic DNAs. Most of the genomic DNAs derived from vertebrate tissue and cell lines contained 5-hmC. DNA from mouse, human, and bovine brains displayed 0.5-0.9% of the total nucleotides as 5-hmC, which was higher compared to the levels found in other tissues. A comparison between cancer and healthy tissue genomes suggested a lower percentage of 5-hmC in cancer, which may reflect the global hypomethylation of 5-mC observed during oncogenesis.     

Biochemical and molecular characterization of secreted α-xylosidase from Aspergillus niger

α-Linked xylose is a major component of xyloglucans in the cell walls of higher plants. An α-xylosidase (AxlA) was purified from a commercial enzyme preparation from Aspergillus niger, and the encoding gene was identified. The protein is a member of glycosyl hydrolase family 31. It was active on p-nitrophenyl-α-d-xyloside, isoprimeverose, xyloglucan heptasaccharide (XXXG), and tamarind xyloglucan. When expressed in Pichia pastoris, AxlA had activity comparable to the native enzyme on pNPαX and IP despite apparent hyperglycosylation. The pH optimum of AxlA was between 3.0 and 4.0. AxlA together with β-glucosidase depolymerized xyloglucan heptasaccharide. A combination of AxlA, β-glucosidase, xyloglucanase, and β-galactosidase in the optimal proportions of 51:5:19:25 or 59:5:11:25 could completely depolymerize tamarind XG to free Glc or Xyl, respectively. To the best of our knowledge, this is the first characterization of a secreted microbial α-xylosidase. Secreted α-xylosidases appear to be rare in nature, being absent from other tested commercial enzyme mixtures and from the genomes of most filamentous fungi.     

ζ-Carotene and other carotenes in a Phycomyces mutant

Strain S442, a new mutant of the fungus Phycomyces blakesleeanus, has a greenish colour and a distinct green fluorescence under long-UV light. Carotene analyses reveal the presence of phytoene, ζ-carotene, phytofluene, an unidentified compound, and neurosporene (in descending order of abundance). Genetic analysis shows that the new mutation occurs at gene carB, whose protein product catalyses the four dehydrogenations of phytoene to lycopene via phytofluene, ζ-carotene, and neurosporene. S442 offers no indication of a specific ζ-carotene dehydrogenase. The residual dehydrogenase activity in S442 is inhibited by diphenylamine. The high ζ-carotene content makes S442 a good source of this compound.     

Dynamics of Ecological–Biochemical Characteristics of Sea Ice in Coastal Waters of the White Sea

The distribution of salinity, silicon and phosphorus contents, and hydrolytic enzyme activities along a sea–coast transect was studied in melted ice cores and water samples taken from under the ice cover in the periods of active ice formation and melting in the Kandalaksha Bay, White Sea. The species list of identified algae was compiled, which included 170 species and varieties (90% of them belonged to diatoms). Strong correlations were revealed between the salinity of water samples and the content of silicon, protease activity, and the species composition of algae. Preliminary estimations of the rate of photosynthetic processes in individual cells of algae belonging to the mass species of the ice flora are discussed.     

Thiamine requirement in relation to cytokinin in “normal” and “mutant” strains of tobacco callus

Summary High concentrations of kinetin (400–2,000 g/l) permit continuous growth of tobacco callus cultures (Nicotiana tabacum, var. Wisconsin No. 38) in the absence of exogenous thiamine. On the optimum concentration (1,000 g/l) the tissue has been maintained through 21 bimonthly passages without change in vigor or other growth characteristics.The effect of kinetin is general, not mutagenic, because tissue returned to low-kinetin, thiamine-free medium failed to grow.Kinetin-thiamine interactions in cytokinin mutant strains which were grown without cytokinin in light and darkness suggest that the endogenous content of cytokinins may markedly affect the requirement for thiamine and possibly the tissue content of this vitamin and other growth factors.The viability of tissue on low-kinetin media in enhanced by thiamine, but the addition of this vitamin does not eliminate the requirement for a cytokinin.The great divergence in minimum kinetin concentrations required for growth of the tissue in the presence and absence of thiamine indicates that the growth promoting action of cytokinin must be different in the two cases.     

The effect of non-permissive temperature on met-tRNA synthetase in Saccharomyces cerevisiae temperature-sensitive mutant ts 7–45

The effects of incubation of yeast spheroplasts at elevated temperature (40°C) on a number of activities involved in protein biosynthesis have been examined in preparations obtained from wild-type cells (wt A364A) and a temperature-sensitive mutant (ts 7–45) derived from it. With wild-type cells, preincubation of spheroplasts at the elevated temperature had little or no effect on the following: (1) the ribosomal subunit-polysome pattern; (2) the translation of exogenous natural mRNA in postpolysomal extracts devoid of endogenous mRNA; (3) the translation of poly(U) in postpolysomal extracts; (4) the incorporation of methionine into 40 S preinitiation and 80 S initiation complexes; (5) the synthesis of Met-tRNA in postribosomal (cytosol) extracts; and (6) the formation of eIF-2·GTP·Met-tRNA_f ternary complex in the cytosol. With temperature-sensitive spheroplasts that had not been preincubated at the elevated temperature, the concentration of free, native 40 S subunits appeared to be lower and that of 60 S subunits higher than in wild-type cells; translation of exogenous natural mRNA in postpolysomal extracts was somewhat lower than in wild-type preparations, but all of the other reactions and components measured were comparable to those in wild-type preparations. Preincubation of temperature-sensitive spheroplasts at 40°C resulted in: (1) a further decrease in the level of 40 S subunits; (2) disaggregation of polysomes; (3) loss of ability to translate natural mRNA but not poly(U); (4) decreased ability to form 40 S preinitiation intermediates; and (5) production of an activity, found in the cytosol, that inhibited Met-tRNA synthetase reversibly. The inhibitor had the characteristics of a protein and did not appear to be a proteinase, nuclease, or nucleotidase.     

Composition and photoinduced biosynthesis of the carotenoids of a protoplast-like Neurospora crass “slime” mutant

A spheroplast-like slime mutant of Neurospora crassa (lacking a rigid cell wall) was found to synthesize an identical spectrum of carotenoids as wild type strains except for -carotene. Furthermore strict photoregulation of the biosynthesis of these pigments as well as the characteristics of photoinduced carotenogenesis were also nearly identical in the mutant and in the wild type.     

Characterization of a transient unfolding intermediate in a core mutant of γS-crystallin

In many age-related and neurological diseases, formerly native proteins aggregate via formation of a partially unfolded intermediate. γS-Crystallin is a highly stable structural protein of the eye lens. In the mouse Opj cataract, a non-conservative F9S mutation in the N-terminal domain core of γS allows the adoption of a native fold but renders the protein susceptible to temperature- and concentration-dependent aggregation, including fibril formation. Hydrogen/deuterium exchange and denaturant unfolding studies of this mutant protein (Opj) have suggested the existence of a partially unfolded intermediate in its aggregation pathway. Here, we used NMR and fluorescence spectroscopy to obtain evidence for this intermediate. In 3.5 M urea, Opj forms a stable and partially unfolded entity that is characterized by an unstructured N-terminal domain and a largely intact C-terminal domain. Under physiologically relevant conditions, Carr-Purcell-Meiboom-Gill T₂-relaxation dispersion experiments showed that the N-terminal domain residues were in conformational exchange with a loosely structured intermediate with a population of 1-2%, which increased with temperature. This provides direct evidence for a model in which proteins of native fold can explore an intermediate state with an increased propensity for formation of aggregates, such as fibrils. For the crystallins, this shows how inherited sequence variants or environmentally induced modifications can destabilize a well-folded protein, allowing the formation of intermediates able to act as nucleation sites for aggregation and the accumulation of light-scattering centers in the cataractous lens.     

Division and DNA distribution in ribosome-deficient plastids of the barley mutant “albostrians”

The ribsome-deficient plastids of the albino leaves of the barley mutant albostrians divide at about the same rate as normal plastids and contain similar levels of plastids DNA to the normal plastids. Double-ring structures were observed around the neck of constricting dumbbell-shaped, ribosome-deficient plastids in the basal intercalary meristem of albino leaves. In the distal region of albino leaves the ribosome-deficient plastids contain a rudimentary thylakoid system often closely associated with DNA nucleoids. It is suggested that nuclear coded proteins synthesized within the cytoplasm are responsible for the formation of the double-ring structures and the rudimentary thylakoids of albino plastids.