Genetic and biochemical analyses of yeast RNase MRP

RNase MRP cleaves the yeast pre-rRNA at a site in internal transcribed spacer 1 (ITS1) and this cleavage can be reproducedin vitro by the highly purified enzyme. Two protein components (Pop1p and Pop2p) have been identified which are common to yeast RNase MRP and RNase P. Moreover, purified RNase P can also cleave the pre-rRNA substratein vitro, underlining the similarities between these particles. Genetic evidence suggests that RNase MRP functionally interacts with the snoRNPs which are required for other pre-rRNA processing reactions.Abbreviations pre-rRNA ribosomal RNA precursor - snoRNA small nucleolar RNA - snoRNP small nucleolar ribonucleoprotein particle     

Hybrid Ia antigens: Genetic,serologic, and biochemical analyses

Ia specificities 22 and 23 were found to be determinants on hybrid Ia molecules, formed by the noncovalent binding of a 26,000–28,000 dalton beta polypeptide chain (A_e) coded by the I-A subregion and a 32,000–35,000 dalton alpha chain (E_α) coded by the I-E subregion. For expression of Ia. 23 the A_e chain, coded by the I-A subregion, must be derived from the H-2^d haplotype, while A^b, A^s, or A^k can provide the complementing beta chain for the expression of Ia. 22. For expression of Ia. 22 and Ia. 23, most Ia. 7 positive strains can provide the complementing alpha chain (E_α), with the one exception of B 10. PL (E^u), which is Ia. 7 positive but will not complement with A^d to express Ia. 23. Antisera were also produced against hybrid Ia antigens by immunizing with F₁ cells expressing Ia. 22 or Ia. 23 generated by transcomplementation. These antisera detect the same specificities as conventional anti-Ia. 22 and anti-Ia. 23 sera produced against cis-complementing Ia antigens. It is postulated that hybrid Ia determinants are involved in recognition and generation of immune response to antigens under dual Ir gene control. It is also suggested that there are 2 types of Ia specificities: (1) allotypic Ia specificities expressed on the alpha or beta chains (for example, Ia. 7 on the E_α chain) and (2) hybrid Ia specificities, which are unique interaction determinants formed by the association of alpha and beta chains (for example, Ia. 22 and Ia. 23). These interaction gene products may be involved in antigen recognition and presentation.     

Genetic and biochemical analyses of Pfh1 DNA helicase function in fission yeast

The Schizosaccharomyces pombe pfh1⁺ gene (PIF1 homolog) encodes an essential enzyme that has both DNA helicase and ATPase activities and is implicated in lagging strand DNA processing. Mutations in the pfh1⁺ gene suppress a temperature-sensitive allele of cdc24⁺, which encodes a protein that functions with Schizosaccharomyces pombe Dna2 in Okazaki fragment processing. In this study, we describe the enzymatic properties of the Pfh1 helicase and the genetic interactions between pfh1 and cdc24, dna2, cdc27 or pol 3, all of which are involved in the Okazaki fragment metabolism. We show that a full-length Pfh1 fusion protein is active as a monomer. The helicase activity of Pfh1 displaced only short (<30 bp) duplex DNA regions efficiently in a highly distributive manner and was markedly stimulated by the presence of a replication-fork-like structure in the substrate. The temperature-sensitive phenotype of a dna2-C2 or a cdc24-M38 mutant was suppressed by pfh1-R20 (a cold-sensitive mutant allele of pfh1) and overexpression of wild-type pfh1⁺ abolished the ability of the pfh1 mutant alleles to suppress dna2-C2 and cdc24-M38. Purified Pfh1-R20 mutant protein displayed significantly reduced ATPase and helicase activities. These results indicate that the simultaneous loss-of-function mutations of pfh1⁺ and dna2⁺ (or cdc24⁺) are essential to restore the growth defect. Our genetic data indicate that the Pfh1 DNA helicase acts in concert with Cdc24 and Dna2 to process single-stranded DNA flaps generated in vivo by pol δ-mediated lagging strand displacement DNA synthesis.     

Genetic and biochemical analyses of pantothenate biosynthesis in Escherichia coli and Salmonella typhimurium.

Pantothenate (pan) auxotrophs of Escherichia coli K-12 and Salmonella typhimurium LT2 were characterized by enzymatic and genetic analyses. The panB mutants of both organisms and the pan-6 ("panA") mutant of S. typhimurium are deficient in ketopantoate hydroxymethyltransferase, whereas the panC mutants lack pantothenate synthetase. panD mutants of E. coli K-12 were previously shown to be deficient in aspartate 1-decarboxylase. All mutants showed only a single enzyme defect. The finding that the pan-6 mutant was deficient in ketopantoate hydroxymethyltransferase indicates that the genetic lesion is a panB allele. The pan-6 mutant therefore is deficient in the utilization of alpha-ketoisovalerate rather than the synthesis of alpha-ketoisovalerate, as originally proposed. The order of the pan genes of E. coli K-12 was determined by phage P1-mediated three-factor crosses. The clockwise order was found to be aceF panB panD panC tonA on the genetic map of E. coli K-12. The three-factor crosses were greatly facilitated by use of a closely linked Tn10 transposon as the outside marker. We also found that supplementation of E. coli K-12 auxotrophs with a high concentration of pantothenate or beta-alanine increased the intracellular coenzyme A level two- to threefold above the normal level. Supplementation with pantoate or ketopantoate resulted in smaller increases.     

Structural and biochemical analyses of hemimethylated DNA binding by the SeqA protein

The Escherichia coli SeqA protein recognizes the 11 hemimethylated G-^mA-T-C sites in the oriC region of the chromosome, and prevents replication over-initiation within one cell cycle. The crystal structure of the SeqA C-terminal domain with hemimethylated DNA revealed the N⁶-methyladenine recognition mechanism; however, the mechanism of discrimination between the hemimethylated and fully methylated states has remained elusive. In the present study, we performed mutational analyses of hemimethylated G-^mA-T-C sequences with the minimal DNA-binding domain of SeqA (SeqA_71–181), and found that SeqA_71–181 specifically binds to hemimethylated DNA containing a sequence with a mismatched ^mA:G base pair [G-^mA(:G)-T-C] as efficiently as the normal hemimethylated G-^mA(:T)-T-C sequence. We determined the crystal structures of SeqA_71–181 complexed with the mismatched and normal hemimethylated DNAs at 2.5 and 3.0 Å resolutions, respectively, and found that the mismatched ^mA:G base pair and the normal ^mA:T base pair are recognized by SeqA in a similar manner. Furthermore, in both crystal structures, an electron density is present near the unmethylated adenine, which is only methylated in the fully methylated state. This electron density, which may be due to a water molecule or a metal ion, can exist in the hemimethylated state, but not in the fully methylated state, because of steric clash with the additional methyl group.     

Genetic and biochemical characterization of the yeast spo12 protein

We have performed a genetic and biochemical analysis of the SPO12 gene, which regulates meiotic nuclear divisions in budding yeast. When sporulated, spo12 mutants undergo a single meiotic nuclear division most closely resembling meiosis II. We observed that Spo12 protein is localized to the nucleus during both meiotic divisions and that Clb1-Cdc28, Clb3-Cdc28, Clb4-Cdc28, and Clb5-Cdc28 kinase activities during meiosis were not affected by a spo12 mutation. Using two-hybrid analysis, we identified several genes, three of which are meiotically induced, that may code for proteins that interact with Spo12p. We also observed that two genes, BNS1 (Bypasses Need for Spo12p), which has homology to SPO12, and SPO13, whose mutant phenotype is like that of spo12, can partially suppress the meiotic defect of spo12 mutants when overexpressed. We found that Spo12p is also localized to the nucleus in vegetative cells and that its level peaks during G2/M. We observed that a spo12 mutation is synthetically lethal in vegetative cells with a mutation in HCT1, a gene necessary for cells to exit mitosis, suggesting that Spo12p may have a role in exit from mitosis.     

Genetic analyses of yeast protein serine/threonine phosphatases

Abstract Protein phosphorylation is an important regulatory phenomenon in yeasts just as in other eukaryotic cells and controls a wide variety of cellular processes. The importance of protein phosphatases as well as protein kinases as key elements in such control is becoming increasingly clear. Over the past four years since the first yeast protein phosphatase gene was isolated, many more such genes have been described and the number of genes encoding protein phosphatase catalytic subunits in Saccharomyces cerevisiae has comfortably entered double figures. Given the genetic approaches available, yeasts offer powerful systems for addressing the cellular roles of these enzymes. This review summarises the results of genetic studies aimed at determining the functions of protein serine/threoninc phosphatases in yeast.     

Genetic and biochemical analyses of receptor and cofactor determinants for T-cell-tropic feline leukemia virus infection

Entry by retroviruses is mediated through interactions between the viral envelope glycoprotein and the host cell receptor(s). We recently identified two host cell proteins, FeLIX and Pit1, that are necessary for infection by cytopathic, T-cell-tropic feline leukemia viruses (FeLV-T). Pit1 is a classic multiple transmembrane protein used as a receptor by several other simple retroviruses, including subgroup B FeLV (FeLV-B), and FeLIX is a secreted cellular protein expressed from endogenous FeLV-related sequences (enFeLV). FeLIX is nearly identical to FeLV-B envelope sequences that encode the N-terminal half of the viral surface unit (SU), because these FeLV-B sequences are acquired by recombination with enFeLV. FeLV-B SUs can functionally substitute for FeLIX in mediating FeLV-T infection. Both of these enFeLV-derived cofactors can efficiently facilitate FeLV-T infection only of cells expressing Pit1, not of cells expressing the related transport protein Pit2. We therefore have used chimeric Pit1/Pit2 receptors to map the determinants for cofactor binding and FeLV-T infection. Three distinct determinants appear to be required for cofactor-dependent infection by FeLV-T. We also found that Pit1 sequences within these same domains were required for binding by FeLIX to the Pit receptor. In contrast, these determinants were not all required for receptor binding by the FeLV-B SU cofactors used in this study. These data indicate that cofactor binding is not sufficient for FeLV-T infection and suggest that there may be a direct interaction between FeLV-T and the Pit1 receptor.     

Structural and biochemical analyses of a surface array protein of Campylobacter fetus.

Electron microscopic examination of ultrathin sections and freeze-etched and shadow cast preparations of a bovine prepuce isolate of Campylobacter fetus VC119 showed an S layer with subunits in an apparent linear arrangement. Surface radioiodination, enzyme digestion, low-pH extraction, and Western immunoblotting showed that the layer was composed mainly of one protein which is the predominant protein antigen of C. fetus. This protein was purified to homogeneity by gel filtration, ion-exchange chromatography, and high-performance liquid chromatography. Sodium dodecyl sulfate-polyacrylamide gel electrophoresis showed an apparent molecular weight of 131,000 for this protein with a pI of 6.35, and no carbohydrate could be detected by a variety of techniques. Amino acid composition analysis showed that the protein contained approximately 1,304 residues per molecule, 41.2% of which were hydrophobic and approximately 22% of which were acidic. Cysteine and histidine were absent. Circular dichroism spectra showed that the prominent structure of the S layer protein was a beta-pleated sheet (36%) with aperiodic foldings (31%); a moderate amount of alpha-helix (28%) and a low amount of beta-turn (5%) were also present. The N-terminal amino acid sequence was determined for the first 18 residues. No sequence homology with other S layer proteins was found.     

Molecular and biochemical analyses of human immunodeficiency virus type 1 vpu protein.

We have performed a detailed analysis of the biochemical properties of the human immunodeficiency virus (HIV) type 1 vpu gene product to elucidate its function during virus replication. Our data suggest that vpu is posttranslationally modified by phosphorylation, since a 16-kilodalton phosphoprotein can be specifically immunoprecipitated with both a serum from an HIV-positive individual (HIV-positive serum) and a vpu-specific antiserum. In contrast, our results suggest that vpu is not glycosylated, even though the protein contains a potential glycosylation site. In vitro translation studies demonstrated that vpu is cotranslationally integrated into microsomal membranes, suggesting that vpu is an integral membrane protein. While vpu was found in significant quantities in virus-producing cells, the protein could not be detected in cell-free culture fluids and is therefore most likely not viron associated. Processing of viral precursor proteins was unaffected by the absence of vpu, and no differences were detected in the protein compositions of wild-type and mutant virions. However, virus release from cultures producing vpu-defective virus was found to be delayed, resulting in the intracellular accumulation of viral proteins. Our data suggest that vpu has a function in the release of virus particles from infected cells.     

Fucosylated protein of retinal cone photoreceptor outer segments: morphological and biochemical analyses

Cone outer segments (OS) of the goldfish retina are diffusely labeled after intravitreal injection of [(3)H]fucose while rod OS remain unlabeled. By electron microscopic radioautography, the OS of red- and blue-sensitive cones are heavily labeled while green- sensitive cone OS are lightly labeled. The time-course and pattern of OS labeling in all cone types from 30 min to 24 h resemble that of incorporation of other sugars into rhodopsin in rod OS. The nature of the cone OS-specific fucosylated component(s) was examined using biochemical techniques. Cone OS were prelabeled by intravitreal injection of [(3)H]fucose 24 h before sacrifice. Photoreceptor OS were isolated using a discontinuous sucrose density gradient and it was verified by electron microscopic radioautography that the only source of radioactivity in the preparations was cone OS. The different cone types could be recognized by the heaviness of labeling, characteristic membrane spacing, and 'staining' of green cone OS in vitro with horseradish peroxidase. After acid hydrolysis of prelabeled photoreceptor membranes, 90 percent of the counts were in the neutral sugar fraction which was analyzed by thin-layer chromatography. Approximately 70 percent of the radioactivity co-chromatographed with authentic fucose. SDS-PAGE/fluorography of prelabeled photoreceptor membranes revealed a single radioactive component that was lightly stained with coomassie blue and showed an apparent molecular weight of 33,000. This cone-derived band was separated from unlabeled rod opsin which was well stained and showed an apparent mol wt of 38,000. Isoelectric focusing under denaturing conditions produced two major and one minor band of radioactivity with isoelectric points of 8.2, 8.6, and 8.8 respectively. No radioactivity was found in association with a stained band corresponding in isoelectric point to that of bovine opsin (pl, 6.2). The fucosylated component was readily digested by pronase, indicating its protein nature. Washing of the isolated OS with isotonic and hypotonic buffers failed to extract major amounts of the radioactivity, suggesting that the fucosylated component is an integral membrane protein. The presence of a fucosylated protein thus represents a major difference between cone and rod OS in the goldfish and has enabled us to identify cone OS in preparations of isolated photoreceptor membranes and to demonstrate the separation of a cone-derived glycoprotein from rod opsin.     

Genetic techniques for enhancing biochemical and structural characterization of Dictyostelium myosin II

Myosin mutants and their suppressors can provide information about conformational states of the myosin motor and their biochemical properties. Appropriate mutations can give rise to motors that arrest or overoccupy otherwise inaccessible states in the motor cycle. Intragenic (in the same gene) suppressor mutations that counteract mutations of known properties represent "fixes" or counters to the defect of the starting mutation and thus contain information about driving transitions or stabilizing states of the motor. Due to its variety of myosin-dependent phenotypes, Dictyostelium is a powerful tool for the identification of conditional mutants as well as selection of large numbers of intragenic revertants of a mutant of interest. Techniques are presented that allow isolation and identification of cold-sensitive myosin mutants in Dictyostelium as well as facile selection of revertants and identification of their suppressing mutation.     

Genetic and biochemical analysis of in vivo protein folding and subunit assembly

The in vivo pathway of folding and subunit assembly of a trimeric bacteriophage protein has been studied by characterizing precursors to the native protein and by analyzing temperature-sensitive mutations that kinetically block the pathway. The native trimer is formed via an intermediate composed of three partially folded chains, the protrimer. At 39°C, temperature-sensitive mutations prevent the formation of both the native trimer and the protrimer, possibly by destabilizing earlier intermediates. However, the mutations do not affect the stability of the native protein, formed at 30°C. Thus, these mutations identify amino acid residues involved in interactions that determine the folding pathway.     

Structural and biochemical analyses of regio- and stereospecificities observed in a type II polyketide ketoreductase

Type II polyketides include antibiotics such as tetracycline and chemotherapeutics such as daunorubicin. Type II polyketides are biosynthesized by the type II polyketide synthase (PKS) that consists of 5-10 stand-alone domains. In many type II PKSs, the type II ketoreductase (KR) specifically reduces the C9-carbonyl group. How the type II KR achieves such a high regiospecificity and the nature of stereospecificity are not well understood. Sequence alignment of KRs led to a hypothesis that a well-conserved 94-XGG-96 motif may be involved in controlling the stereochemistry. The stereospecificity of single-, double-, and triple-mutant combinations of P94L, G95D, and G96D were analyzed in vitro and in vivo for the actinorhodin KR (actKR). The P94L mutation is sufficient to change the stereospecificity of actKR. Binary and ternary crystal structures of both wild-type and P94L actKR were determined. Together with assay results, docking simulations, and cocrystal structures, a model for stereochemical control is presented herein that elucidates how type II polyketides are introduced into the substrate pocket such that the C9-carbonyl can be reduced with high regio- and stereospecificities. The molecular features of actKR important for regio- and stereospecificities can potentially be applied in biosynthesizing new polyketides via protein engineering that rationally controls polyketide keto reduction.     

Combined biochemical and immunocytochemical analyses of postmortem protein deimination in the rat spinal cord

Immunocytochemical staining of citrulline-containing proteins, i.e. products of endogenous peptidylarginine deiminase (EC 3.5.3.15) reaction, has been performed by chemical modification of citrulline residues in situ, followed by probing with IgG specific to the modified residues. Rat spinal cords that had been preincubated in vitro to accelerate the enzyme reaction were used as samples. Not only astrocytes but also the cytoplasm of some large neurons were stained. Usefulness of the method for studying nervous tissue damage was suggested.     

Genetic,phytochemical and biochemical analyses as tools for biodiversity evaluation of wild accessions of Solanum commersonii

Genetic fingerprint profiles, the type and content of glycoalkaloids (GAs) and hemagglutination (HAG) activity against red cells were analysed in accessions of Solanum commersonii, collected from different locations in the south of Uruguay. Thirty-nine accessions from 21 geographically distinct areas were studied. Random Amplified Polymorphic DNA (RAPD) analysis revealed a high degree of genetic diversity among the accessions used in the study and effectively discriminated among all of the accessions analysed. There was a very high diversity in the type as well as the concentration of GAs in the samples. Strong HAG activity against rabbit red cells was detected in all the S. commersonii tuber extracts analysed. Such activity was specifically inhibited by N,N′-diacetylchitobiose and N,N′,N″-triacetylchitotriose. Differences in the levels of specific HAG activities were found in the different extracts, which might indicate different levels of the lectin specific for N-acetylglucosamine (Glc-NAc) and its oligomers, in the tubers. It is shown that the three different approaches used in this work successfully discriminate between the accessions of this species and thus, they constitute interesting tools to analyse biodiversity within one species. In addition, they allow selection of those accessions with potential to be used in crop programs.     

Genetic and biochemical analyses of Escherichia coli mutants altered in the temperature-dependent regulation of membrane lipid composition

We have previously studied two mutants of Escherichia coli altered in the regulation of membrane lipid composition by temperature. One class (represented by the fabFl allele) fails to regulate upon temperature shift and is defective in cis-vaccenic acid synthesis owing to the lack of the fatty acid elongation enzyme beta-ketoacyl-acyl carrier protein synthase II(EC 2.3.1.41). A second class of mutant, given the phenotypic designation Vtr, overproduces cis-vaccenic acid at all temperatures and hence is altered in temperature regulation. In this paper we report evidence for the following conclusions. (i) The Vtr and fabFl mutations show very tight genetic linkage. (ii) The Vtr lesion is allelic to the fabFl mutation since the presence of the fabFl mutation in merodiploid strains carrying the Vtr or fabF(+) alleles results in fatty acid compositions intermediate between those of the two monoploid strains. Merodiploids carrying both the fabF(+) and Vtr alleles likewise show an intermediate composition. These results indicate intra-allelic complementation. (iii) The two E. coli proteins recently discovered by Rock (J. Bacteriol. 152:1298-1300, 1982) that form mixed disulfide cross-links to acyl carrier protein are directly demonstrated to be beta-ketoacyl-acyl carrier protein synthases I and II. (iv) The fabFl strains produce a synthase II band of altered electrophoretic mobility, indicating that the fabF locus is the structural gene for synthase II. (v) The synthase II of Vtr strains is abnormally sensitive to cerulenin, an antibiotic that specifically inhibits synthases I and II. This increased sensitivity is readily demonstrated in vivo, but in vitro we failed to detect an increased sensitivity of the Vtr synthase II to cerulenin, nor have we detected any other kinetic or structural alteration in the enzyme. We interpret these results in terms of specific interactions of synthase II with other cellular components which occur in vivo but are not duplicated in vitro.     

Crystallographic and biochemical analyses of the metal-free Haemophilus influenzae Fe3+-binding protein.

The crystal structure of the iron-free (apo) form of the Haemophilus influenzae Fe(3+)-binding protein (hFbp) has been determined to 1.75 A resolution. Information from this structure complements that derived from the holo structure with respect to the delineation of the process of iron binding and release. A 21 degrees rotation separates the two structural domains when the apo form is compared with the holo conformer, indicating that upon release of iron, the protein undergoes a change in conformation by bending about the central beta-sheet hinge. A surprising finding in the apo-hFbp structure was that the ternary binding site anion, observed in the crystals as phosphate, remained bound. In solution, apo-hFbp bound phosphate with an affinity K(d) of 2.3 x 10(-3) M. The presence of this ternary binding site anion appears to arrange the C-terminal iron-binding residues conducive to complementary binding to Fe(3+), while residues in the N-terminal binding domain must undergo induced fit to accommodate the Fe(3+) ligand. These observations suggest a binding process, the first step of which is the binding of a synergistic anion such as phosphate to the C-terminal domain. Next, iron binds to the preordered half-site on the C-terminal domain. Finally, the presence of iron organizes the N-terminal half-site and closes the interdomain hinge. The use of the synergistic anion and this iron binding process results in an extremely high affinity of the Fe(3+)-binding proteins for Fe(3+) (nFbp K'(eff) = 2.4 x 10(18) M(-1)). This high-affinity ligand binding process is unique among the family of bacterial periplasmic binding proteins and has interesting implications in the mechanism of iron removal from the Fe(3+)-binding proteins during FbpABC-mediated iron transport across the cytoplasmic membrane.