Length changes in the joining segment between domains 5 and 6 of a group II intron inhibit self-splicing and alter 3' splice site selection.

Domain 5 (D5) and domain 6 (D6) are adjacent folded hairpin substructures of self-splicing group II introns that appear to interact within the active ribozyme. Here we describe the effects of changing the length of the 3-nucleotide segment joining D5 to D6 [called J(56)3] on the splicing reactions of intron 5 gamma of the COXI gene of yeast mitochondrial DNA. Shortened variants J(56)0 and J(56)1 were defective in vitro for branching, and the second splicing step was performed inefficiently and inaccurately. The lengthened variant J(56)5 had a milder defect-splicing occurred at a reduced rate but with correct branching and a mostly accurate 3' splice junction choice. Yeast mitochondria were transformed with the J(56)5 allele, and the resulting yeast strain was respiration deficient because of ineffective aI5 gamma splicing. Respiration-competent revertants were recovered, and in one type a single joiner nucleotide was deleted while in the other type a nucleotide of D6 was deleted. Although these revertants still showed partial splicing blocks in vivo and in vitro, including a substantial defect in the second step of splicing, both spliced accurately in vivo. These results establish that a 3-nucleotide J(56) is optimal for this intron, especially for the accuracy of 3' splice junction selection, and indicate that D5 and D6 are probably not coaxially stacked.

Special effects of UDP-sugar binding to bovine liver uridine diphosphoglucose dehydrogenase.

The binding of NADH to uridine diphosphate glucose dehydrogenase has been examined by equilibrium dialysis. There is an absolute requirement for the presence of UDP-glucose for the binding of NADH. Other analogs such as UDPxylose, UDPgalactose and UDPglucuronic acid cannot replace UDPglucose as an effector of NADH binding. UDPxylose competes with UDPglucose for the UDP-sugar-binding site, and in so doing releases the bound NADH. The binding of NADH to UDPglucose dehydrogenase in the presence of UDPglucose reaches a saturation limit of 3 mol NADH bound per enzyme hexamer, and displays positive cooperativity, Hill number = 1.34. The effects of UDP-sugars on the fluorescence of UDPglucose dehydrogenase derivatized at the catalytic sites with a fluorophore have also been studied. Two classes of UDPxylose-binding site have been detected. One class has high affinity (Kdiss = 3 microM, determined by equilibrium dialysis) but does not affect fluorophore fluorescence, and the other has lower affinity (Kdiss = 120 microM) and leads to red-shifted fluorescence quenching, presumably by effecting exposure of the fluorophore to solvent. The high-affinity sites are identified as the UDP-sugar subsites of the underivatized catalytic sites, and the low-affinity sites as UDP-sugar subsites of the fluorophore-labeled catalytic sites.

Induced versus pre-existing asymmetry models for the half-of-the-sites reactivity effect in bovine liver uridine diphosphoglucose dehydrogenase.

Half-of-the-sites reactivity of the catalytic site thiol groups of UDPglucose dehydrogenase (UDPglucose:NAD+ 6-oxidoreductase, EC 1.1.1.22) can be ascribed either to the induction of conformational asymmetry following derivatization of one half of the subunits or to intrinsic conformational differences in the subunits of the native enzyme. If the half-sites reactivity behavior is due to induction effects, the magnitude of the induction could be expected to depend on the nature of the covalent modification. On the other hand, if the half-sites reactivity behavior is due to pre-existing asymmetry and there is no communication between catalytic centers, the properties of unmodified sub-units should be independent of the nature of the covalent derivative introduced on the modified subunits. According to the induced asymmetry hypothesis, the catalytic activity of half-sites modified enzyme might be different for different covalent modifications, whereas for the rigid pre-existing asymmetry hypothesis the catalytic activity of half-sites modified enzyme should be the same regardless of the modifying group. During the course of catalytic site thiol group modification by a number of thiol specific reagents, the loss of enzyme activity was equivalent to the degree of modification for most of the reagents employed. However, with iodoacetate and 5-(iodoacetamidoethyl)aminonaphthalene-1-sulfonic acid, half-sites modification of UDPglucose dehydrogenase reduced catalytic activity by 58 and 78%, respectively, of the initial activity. These observations are consistent with a model in which there is communication between catalytic sites. Electron microscopy shows that the six subunits of UDPglucose dehydrogenase are arranged as a hexagonal planar ensemble.

Kinetic analysis of the 5' splice junction hydrolysis of a group II intron promoted by domain 5.

The 5' splice junction (5'SJ) of Group II intron transcripts is subject to a specific hydrolysis reaction (SJH). This reaction occurs either within a single transcript containing intron sequences through domain 5 (D5) or by cooperation of two separate transcripts, one bearing the 5'SJ and another contributing D5 (1). In this report we describe the latter reaction in terms of its kinetic parameters. A minimal D5 RNA of 36 nts (GGD5) was sufficient to promote SJH of a second transcript containing the 5' exon plus intron domains 1, 2, and 3 (E1:123). Equimolar production of two RNAs, the 5' exon (E1) and an intron fragment containing domains 1, 2, and 3 (123) was observed. The kinetic coefficients were evaluated by an excess GGD5 approach. The apparent Km was complex, varying with GGD5 concentration. This behavior indicates heterogeneity in E1:123 with respect to GGD5 binding. The binding heterogeneity may result from formation of E1:123 dimers or from nicks in some molecules of each E1:123 preparation. The heterogeneity was always evident, but to a variable degree, regardless of the procedure by which E1:123 was isolated. The system may be described in terms of parameters analogous to kcat and Km. At infinite dilution of GGD5, the characterizing values were: k2 degrees (the analog of kcat) = 0.0055 min-1 and Km degrees = 0.22 microM. In the limit of GGD5 saturation, the values were: k2 infinity = 0.012 min-1 and Km infinity = 4.5 microM. A natural variant D5, representing the sequence from intron 1 of the yeast cytochrome-b gene, was also functional in SJH. This GGD5b1 was governed by similar Km degrees and Km infinity values, but was only one-third as active over the entire D5 concentration range. A different D5 isomer was entirely ineffective for SJH.

Isolation, characterization, and stability of the 30S ribosomal RNA complex from HeLa cells.

The HeLa 30S rRNA molecule (historically designated 28S rRNA) can be dissociated into two components, a 7S rRNA and a large rRNA component which we call 29S rRNA. To evaluate conformational differences between the 30S rRNA complex and the isolated 29S rRNA component of the complex, viscosity, sedimentation velocity, circular dichroism, and ultraviolet absorption measurements with the two species were performed. Sedimentation equilibrium studies were also carried out with the 30S rRNA complex. In addition, the kinetics of the reaction which dissociates the 30S rRNA complex were characterized. The removal of glycogen-like molecules by cetyltrimethylammonium bromide prescipitation of the rRNA and the preequilibration of rRNA with solvent by Sephadex column chromatography were found to be essential for reproducibility. The s20,2o values for the 30S rRNA complex and the isolated 29S rRNA were determined from the experimental data obtained at various rRNA concentrations as 29.89 plus or minus 0.40 and 29.09 plus or minus 0.14, respectively. The corresponding intrinsic viscosity values were 74 plus or minus 5 and 67 plus or minus 5 cm3/g, respectively. The optical properties of the 30S rRNA and 29S rRNA were not significantly different. These results indicate that there is no significant conformational difference between 30S rRNA and 29S rRNA under the conditions studied. We conclude from the sedimentation equilibrium data that the molecular weight of 30S rRNA is 2.1 x 10-6. From the kinetic data, the 30S rRNA dissociation appears to be an irreversible, cooperative, and ionic strength dependent reaction which at an ionic strength of 0.051 has an activation enthalpy of 123.5 kcal/mol and an activation entropy of 0.21 kcal/(mol deg).

Half-sites oxidation of bovine liver uridine diphosphate glucose dehydrogenase.

6,6-Dithiodinicotinate shows half-of-the-sites reactivity towards the six catalytic-site thiol groups of bovine liver UDP-glucose dehydrogenase. The reagent introduces three intrasubunit disulphide linkages between catalytic-site thiol groups and non-catalytic-site thiol groups and abrogates 60% of the catalytic activity of the hexameric enzyme; excess 2-mercaptoethanol rapidly restores full catalytic activity. These results show the half-of-the-sites behaviour of the enzyme with the reagent and the presence of a non-catalytic-site thiol group capable of forming a disulphide linkage with a catalytic-site thiol group on the same subunit without irreversible denaturation.

Thermal activation of a group II intron ribozyme reveals multiple conformational states.

Conformational changes often accompany biological catalysis. Group II introns promote a variety of reactions in vitro that show an unusually sharp temperature dependence. This suggests that the chemical steps are accompanied by the conversion of a folded-but-inactive form to a differently folded active state. We report here the kinetic analysis of 5'-splice-junction hydrolysis (SJH) by E1:12345, a transcript containing the 5'-exon plus the first five of six intron secondary structure domains. The pseudo-first-order SJH reaction shows (1) activation by added KCl to 1.5 M; (2) cooperative activation by added MgCl2, nHill = 4.1-4.3, and [MgCl2]vmax/2 approximately 0.040 M; and (3) a rather high apparent activation energy, Ea approximately 50 kcal mol-l. In contrast, the 5'-terminal phosphodiester bond of a domain 5 transcript (GGD5) was hydrolyzed with Ea approximately 30 kcal mol-1 under SJH conditions; the 5'-GG leader dinucleotide presumably lacks secondary structure constraints. The effect of adding the chaotropic salt tetraethylammonium chloride (TEA) was also investigated. TEA reduced the melting temperatures of GGD5 and E1:12345. TEA also shifted the profile of rate versus temperature for SJH by E1:12345 toward lower temperatures without affecting the maximum rate. TEA had little effect on the rate of hydrolysis of the 5'-phosphodiester bond of GGD5. The high apparent activation enthalpy and entropy for SJH along with the effect of TEA on these parameters imply that conversion of an inactive form of E1:12345 to an active conformation accompanies enhanced occupation of the transition state as the temperature is raised to that for maximum SJH. Analytical modeling indicates that either a two-state model (open and disordered, with open being active) or a three-state model (compact, open, and disordered) could account for the temperature dependence of kSJH. However, the three-state model is clearly preferable, since it does not require that the activation parameters for phosphodiester bond hydrolysis exhibit exceptional values or that the rates for the chemical steps of SJH respond directly to TEA addition.

Catalytically critical nucleotide in domain 5 of a group II intron.

Domain 5 (D5) is a small hairpin structure within group II introns. A bimolecular assay system depends on binding by D5 to an intron substrate for self-splicing activity. In this study, mutations in D5 identify two among six nearly invariant nucleotides as being critical for 5' splice junction hydrolysis but unimportant for binding. A mutation at another site in D5 blocks binding. Thus, mutations can distinguish two D5 functions: substrate binding and catalysis. The secondary structure of D5 may resemble helix I formed by the U2 and U6 small nuclear RNAs in the eukaryotic spliceosome. Our results support a revision of the previously proposed correspondence between D5 and helix I on the basis of the critical trinucleotide 5'-AGC-3' present in both. We suggest that this trinucleotide plays a similar role in promoting the chemical reactions for both splicing systems.

Amino acid sequence of the tryptic peptide containing the catalytic-site thiol group of bovine liver uridine diphosphate glucose dehydrogenase.

The catalytic-site thiol groups of UDP-glucose dehydrogenase from bovine liver were carboxymethylated with iodo[2-14C]acetate or with iodoacetamidofluorescein. After the residual thiol groups were carboxymethylated with iodoacetate, the proteins were digested with trypsin. The 14C-labelled peptide from the carboxymethylated enzyme was purified to homogeneity by successive thick-layer chromatography on silica gel, paper electrophoresis and chromatography, and column chromatography on Bio-Gel P-6. Homogeneous fluoresceincarboxamidomethylated peptide was prepared from a tryptic digest of fluoresceincarboxamidomethylated enzyme by specific adsorption--desorption from Sephadex G-25. The sequences of either peptide determined by the manual Edman dansyl procedure is: Ala-Ser-Val-Gly-Phe-Gly-Gly-Ser-Cys-Phe-Glx-Glx-Gly-Lys.

Domain 5 binds near a highly conserved dinucleotide in the joiner linking domains 2 and 3 of a group II intron.

Photocrosslinking has identified the joiner between domains 2 and 3 [J(23)] as folding near domain 5 (D5), a highly conserved helical substructure of group II introns required for both splicing reactions. D5 RNAs labeled with the photocrosslinker 4-thiouridine (4sU) reacted with highly conserved nucleotides G588 and A589 in J(23) of various intron acceptor transcripts. These conjugates retained some ribozyme function with the lower helix of D5 crosslinked to J(23), so they represent active complexes. One partner of the gamma x gamma' tertiary interaction (A587 x U887) is also in J(23); even though gamma x gamma' is involved in step 2 of the splicing reaction, D5 has not previously been found to approach gamma x gamma'. Similar crosslinking patterns between D5 and J(23) were detected both before and after step 1 of the reaction, indicating that the lower helix of D5 is positioned similarly in both conformations of the active center. Our results suggest that the purine-rich J(23) strand is antiparallel to the D5 strand containing U32 and U33. Possibly, the interaction with J(23) helps position D5 correctly in the ribozyme active site; alternatively, J(23) itself might participate in the catalytic center.

Domain 5 interacts with domain 6 and influences the second transesterification reaction of group II intron self-splicing.

The role of domain 5 (d5) from the self-splicing group II intron 5 gamma of the COXI gene of yeast mitochondrial DNA in branching and 3' splice site utilization has been studied using a substrate transcript lacking d5 (delta d5 RNA). This RNA is completely unreactive in vitro, but releases 5' exon by hydrolysis under various reaction conditions when d5 RNA is added in trans. Under an extreme reaction condition, some accurate branching and splicing occur. Much more efficient use of a 3' splice site is obtained when delta d5 RNA is complemented by a transcript containing the wild-type domains 5 and 6 plus the 3' exon. While most delta d5 RNA molecules in that protocol still react by hydrolysis at the 5' splice site, the branching that occurs uses only the d6 tethered to d5 that is provided in trans. The use of this d6 and the 3' splice site also linked to d5, along with the observed indifference to the other d6 and 3' splice site resident in the delta d5 RNA, indicates that d5 plays a key role in positioning d6 for the first reaction step as well as in 3' splice site use. Two models for the manner by which d5 interacts with d6 are discussed.