A light-independent developmental mechanism potentiates flavonoid gene expression in Arabidopsis seedlings.

Throughout the plant kingdom expression of the flavonoid biosynthetic pathway is precisely regulated in response to developmental signals, nutrient status, and environmental stimuli such as light, heat and pathogen attack. Previously we showed that, in developing Arabidopsis seedlings, flavonoid genes are transiently expressed during germination in a light-dependent manner, with maximal mRNA levels occurring in 3-day-old seedlings. Here we describe the relationship between developmental and environmental regulation of flavonoid biosynthesis by examining phenylalanine ammonia-lyase (PAL), chalcone synthase (CHS), chalcone isomerase (CHI), and dihydroflavonol reductase (DFR) mRNA levels in germinating Arabidopsis seedlings as a function of light, developmental stage and temperature. We show that seedlings exhibit a transient potential for induction of these four genes, which is distinct from that observed for chlorophyll a/b-binding protein(CAB). The potential for flavonoid gene induction was similar in seedlings grown in darkness and red light, indicating that induction potential is not linked to cotyledon expansion or the development of photosynthetic capacity. The evidence for metabolic regulation of flavonoid genes during seedling development is discussed.

Analysis of Arabidopsis mutants deficient in flavonoid biosynthesis.

Eleven loci that play a role in the synthesis of flavonoids in Arabidopsis are described. Mutations at these loci, collectively named transparent testa (tt), disrupt the synthesis of brown pigments in the seed coat (testa). Several of these loci (tt3, tt4, tt5 and ttg) are also required for the accumulation of purple anthocyanins in leaves and stems and one locus (ttg) plays additional roles in trichome and root hair development. Specific functions were previously assigned to tt1-7 and ttg. Here, the results of additional genetic, biochemical and molecular analyses of these mutants are described. Genetic map positions were determined for tt8, tt9 and tt10. Thin-layer chromatography identified tissue- and locus-specific differences in the flavonols and anthocyanidins synthesized by mutant and wild-type plants. It was found that UV light reveals distinct differences in the floral tissues of tt3, tt4, tt5, tt6 and ttg, even though these tissues are indistinguishable under visible light. Evidence was also uncovered that tt8 and ttg specifically affect dihydroflavonol reductase gene expression. A summary of these and previously published results are incorporated into an overview of the genetics of flavonoid biosynthesis in Arabidopsis.

Laser cross-linking of proteins to nucleic acids. I. Examining physical parameters of protein-nucleic acid complexes.

Pulsed laser cross-linking results in efficient and rapid formation of covalent bonds between proteins and the nucleic acids to which they are bound, creating a "snapshot" of the protein-nucleic acid equilibrium existing at the moment of irradiation. The "frozen" equilibrium allows the determination of protein-nucleic acid binding constants, confirming both theoretical predictions and experimental determinations by standard physical chemical methods. Laser cross-linking results accurately reflect the alteration of protein-nucleic acid interactions induced by traditional methods such as increasing the salt concentration or by the addition of a nucleic acid that competes for binding of the protein. Thus this technique is very useful for the study of the association of proteins and protein complexes with nucleic acids under environmental conditions at which the reactions are not amenable to study by traditional physical chemical methods. In this paper we continue our calibration of the method, focusing primarily on interactions with single-stranded DNA-binding proteins and describe techniques for measuring quantitative interactions between nucleic acid constructs and single-protein or multiprotein complexes. Laser cross-linking can also provide direct evidence that binding correlates with functional activity.

Laser cross-linking of proteins to nucleic acids. II. Interactions of the bacteriophage T4 DNA replication polymerase accessory proteins complex with DNA.

In this paper we examine the interactions of the polymerase accessory proteins subassembly of the bacteriophage T4 DNA replication complex, using single-pulse ultraviolet laser excitation to induce protein-nucleic acid cross-links. The laser-induced cross-linking permits effective "freezing" of the instantaneous equilibrium state of the complex and thus provides a mechanism to dissect the individual protein-nucleic acid interactions involved in complex assembly. We find that the binding of the gene 44, 62, and 45 proteins is dependent not only on the presence of each of the other proteins, but also on the presence of adenine nucleotide cofactors. We find that the nonhydrolyzable analogs of ATP often behave more like ADP than ATP in these experiments. Gene 45 protein is able to induce an increase in cross-linking of the gp44/62 complex to nucleic acids, and this increased cross-linking correlates with changes in the apparent Km of the gp44/62 complex for polynucleotides and with changes in Vmax during ATP hydrolysis. Our results suggest that the enhanced DNA binding is predominately through the gene 62 protein and not the ATPase catalytic subunit (gene 44 protein). Thus the gene 62 protein seems to play an integral role in gp45-mediated enhancement of the ATP hydrolytic activity of gp44. These results are summarized and integrated in the form of a model for the multiple interactions of the accessory proteins with DNA and one another in the presence of mononucleotide cofactors and substrates.

Laser cross-linking of proteins to nucleic acids: photodegradation and alternative photoproducts of the bacteriophage T4 gene 32 protein.

Pulsed laser cross-linking provides a means of introducing a covalent bond between proteins and the nucleic acids to which they are bound. This rapid cross-linking effectively traps the equilibrium that exists at the moment of irradiation and thus allows examination of the protein-nucleic acid interactions that existed. Laser irradiation may also induce photodestruction of protein and we have used the bacteriophage T4 gene 32 protein to investigate this phenomenon. Our results show that both nonspecific and specific photoproducts can occur, specifically at wavelengths where the peptide backbone of proteins is known to absorb. These results demonstrate that nonspecific photodegradation can be correlated with the formation of a specific photodegradation product. The formation of this product was monitored to show that product yield is nonlinearly dependent on laser power and wavelength. We have also investigated an unexpected photoproduct whose formation is dependent on the length of the polynucleotide to which the gene 32 protein binds and that further demonstrates the complexities of analyzing protein-nucleic acid interactions through the use of UV laser cross-linking. These data provide essential information for the establishment of appropriate conditions for future studies that use UV cross-linking of protein-nucleic acid complexes.

Regulation of Flavonoid Biosynthetic Genes in Germinating Arabidopsis Seedlings.

Many higher plants, including Arabidopsis, transiently display purple anthocyanin pigments just after seed germination. We observed that steady state levels of mRNAs encoded by four flavonoid biosynthetic genes, PAL1 (encoding phenylalanine ammonia-lyase 1), CHS (encoding chalcone synthase), CHI (encoding chalcone isomerase), and DFR (encoding dihydroflavonol reductase), were temporally regulated, peaking in 3-day-old seedlings grown in continuous white light. Except for the case of PAL1 mRNA, mRNA levels for these flavonoid genes were very low in seedlings grown in darkness. Light induction studies using seedlings grown in darkness showed that PAL1 mRNA began to accumulate before CHS and CHI mRNAs, which, in turn, began to accumulate before DFR mRNA. This order of induction is the same as the order of the biosynthetic steps in flavonoid biosynthesis. Our results suggest that the flavonoid biosynthetic pathway is coordinately regulated by a developmental timing mechanism during germination. Blue light and UVB light induction experiments using red light- and dark-grown seedlings showed that the flavonoid biosynthetic genes are induced most effectively by UVB light and that blue light induction is mediated by a specific blue light receptor.

Cryoelectron microscopic visualization of functional subassemblies of the bacteriophage T4 DNA replication complex.

A specific complex of proteins involved in bacteriophage T4 replication has been visualized by cryoelectron microscopy as distinctive structures in association with DNA. Formation of these structures, which we term "hash-marks" for their characteristic appearance in association with DNA, requires the presence of the T4 polymerase accessory proteins (the products of T4 genes 44, 45 and 62), ATP and appropriate DNA cofactors. ATP hydrolysis by the DNA-stimulated ATPase activity of the accessory proteins is required for visualization of the hash-mark structures. If ATP hydrolysis is stopped by chelation of Mg2+, by dilution with a non-hydrolyzable ATP analogue, or by exhaustion of the ATP supply, the DNA-associated structures disappear within seconds to minutes, indicating that they have a finite and relatively short lifetime. The labile nature of the structures makes their study by more conventional methods of electron microscopy, as well as by most other structural approaches, difficult if not impossible. Addition of T4 gene 32 protein increases the number of hash-mark structures, as well as increasing the rate of ATP hydrolysis. Using plasmid DNA in either a native (supercoiled) or enzymatically modified state, we have shown that nicked or gapped DNA is required as a cofactor for hash-mark formation. Stimulation of the ATPase activity of the accessory proteins has a similar cofactor requirement. These conditions for the formation and visualization of the structures parallel those required for the action of these complexes in promoting the enzymatic activity of the T4 DNA polymerase, as well as the transcription of late T4 genes. Substructure in the hash-marks has been examined by image analysis, which reveals a variation in the projected density of the subunits comprising the structures. The three-dimensional size of the hash-marks, modeled as a solid ellipsoid, is consistent with that of the gene 44/62 protein subcomplex. Density variations suggest an arrangement of subunits, either tetragonal or trigonal, viewed from a variety of angles about the DNA axis. The hash-mark structures often appear in clusters, even in DNA that has a single nick. We interpret this distribution as the result of one-dimensional translocation of the hash-marks along the DNA after their ATP-dependent initial association with, and injection into, the DNA at nicks or gaps.

Antibody production in baculovirus-infected insect cells.

We have employed the baculovirus expression system for the production of a mouse monoclonal IgG antibody directed against lipoprotein I of Pseudomonas aeruginosa. Both light and heavy chain cDNAs were introduced into the baculovirus genome in a single step of homologous recombination. Insect cells that were infected with the recombinant virus stably secreted antigen-binding and glycosylated antibody molecules capable of binding the complement component C1q.

Environmentally induced conformational changes in B-type DNA: comparison of the conformation of the oligonucleotide d(TCGCGAATTCGCG) in solution and in its crystalline complex with the restriction nuclease EcoRI.

Raman spectroscopic analysis of the secondary structure of the crystalline restriction endonuclease EcoRI, the oligonucleotide d(TCGCGAATTCGCG) in solution, and the corresponding crystalline EcoRI-oligonucleotide complex reveals structural differences between the complexed and uncomplexed protein and oligonucleotide components that appear to be linked to complex formation. Structural differences that are spectroscopically identified include (1) an increase in the population of furanose rings adopting the C3'-endo conformation and (2) spectroscopically observed changes in base stacking which are probably associated with the crystallographically observed distortion of the phosphate backbone about positions C(3)-G(4) and C(9)-G(10) and unwinding between the symmetry-related segments GAA-TTC which make up the central recognition core (McClarin et al., 1986). Changes in base stacking due to distortions and unwinding along the oligonucleotide result in differences in the base vibrational region between the spectra of the complex and the oligonucleotide in solution. The spectroscopic analysis indicates that the C2'-endo population is similar for the oligonucleotide in solution and in the complex. The additional C3'-endo population in the complex appears to arise from the conversion of rings adopting alternative conformations such as C1'-exo and O1'-endo. Analysis of the vibrational bands derived from guanine indicates that the population of guanine residues associated with furanose rings in a C2'-endo conformation is similar for the oligonucleotide in solution and in the crystalline complex. This implies that the increase in C3'-endo population is not associated with guanine residues. Large conformational distortions such as those observed in the crystal distortions are not observed in either the crystal or the solution of the oligomer d(CGCGAATTCGCG).(ABSTRACT TRUNCATED AT 250 WORDS)

Raman spectra of the model B-DNA oligomer d(CGCGAATTCGCG)2 and of the DNA in living salmon sperm show that both have very similar B-type conformations.

Raman spectra were obtained from aqueous solutions of the deoxyoligonucleotide d(CGCGAATTCGCG)2 (I), which has been suggested as a model for B-type DNA conformation. These spectra were compared with the Raman spectra of the aqueous solutions of several DNAs of natural origin taken under identical solution conditions. Since the model sequence has a high percent GC (66%), the Raman spectrum was compared with the Raman spectrum of the DNA from Micrococcus lysodeikticus (72% GC), and the spectra of the two different DNAs were found to be rather similar in both 50 mM salt and 6 M salt solutions. Computer-aided band-shape analysis of the backbone vibrational region of the Raman spectra shows the existence of several bands corresponding to different furanose ring puckers. This appears to indicate a heterogeneity of furanose ring pucker in both the model dodecamer and the native DNA. Significant differences were found in the intensity of the conformational marker band at 810 cm-1, which indicates corresponding differences in furanose ring pucker heterogeneities in these two high GC content DNAs. The Raman spectrum of the dodecamer (I) was used to analyze the Raman spectrum of the DNA inside the head of living intact salmon sperm. Sperm spectra were taken with both our conventional Raman spectrograph and a newly developed intracavity laser Raman microscope system. Although the DNA in the sperm head is required by packing considerations to be in a highly compact and condensed state, the Raman spectra of the intact sperm are almost identical with that of the model dodecamer (I) if the difference in base composition is taken into account.(ABSTRACT TRUNCATED AT 250 WORDS)

Laser cross-linking of nucleic acids to proteins. Methodology and first applications to the phage T4 DNA replication system.

Single-pulse (approximately 8 ns) ultraviolet laser excitation of protein-nucleic acid complexes can result in efficient and rapid covalent cross-linking of proteins to nucleic acids. The reaction produces no nucleic acid-nucleic acid or protein-protein cross-links, and no nucleic acid degradation. The efficiency of cross-linking is dependent on the wavelength of the exciting radiation, on the nucleotide composition of the nucleic acid, and on the total photon flux. The yield of cross-links/laser pulse is largest between 245 and 280 nm; cross-links are obtained with far UV photons (200-240 nm) as well, but in this range appreciable protein degradation is also observed. The method has been calibrated using the phage T4-coded gene 32 (single-stranded DNA-binding) protein interaction with oligonucleotides, for which binding constants have been measured previously by standard physical chemical methods (Kowalczykowski, S. C., Lonberg, N., Newport, J. W., and von Hippel, P. H. (1981) J. Mol. Biol. 145, 75-104). Photoactivation occurs primarily through the nucleotide residues of DNA and RNA at excitation wavelengths greater than 245 nm, with reaction through thymidine being greatly favored. The nucleotide residues may be ranked in order of decreasing photoreactivity as: dT much greater than dC greater than rU greater than rC, dA, dG. Cross-linking appears to be a single-photon process and occurs through single nucleotide (dT) residues; pyrimidine dimer formation is not involved. Preliminary studies of the individual proteins of the five-protein T4 DNA replication complex show that gene 43 protein (polymerase), gene 32 protein, and gene 44 and 45 (polymerase accessory) proteins all make contact with DNA, and can be cross-linked to it, whereas gene 62 (polymerase accessory) protein cannot. A survey of other nucleic acid-binding proteins has shown that E. coli RNA polymerase, DNA polymerase I, and rho protein can all be cross-linked to various nucleic acids by the laser technique. The potential uses of this procedure in probing protein-nucleic acid interactions are discussed.

Ultraviolet resonance Raman excitation profiles of nucleic acid bases with excitation from 200 to 300 nanometers.

Raman spectra are presented for dilute aqueous solutions of the four ribonucleotides AMP, GMP, UMP, and CMP obtained with laser excitation at 299, 266, 253, 240, 229, 218, 209, and 200 nm. Distinct evidence of strong, selective resonance enhancement is obtained. Low-resolution excitation profiles have been constructed for the strongest bands by using the phosphate band at 994 cm-1 as an internal reference. The excitation spectra for many of the vibrational bands are dominated by a peak corresponding to the lowest-energy electronic transition near 260 nm. Smaller peaks are seen for higher-energy electronic transitions. For some modes, the resonance enhancement is dominated by the higher-energy transitions. It is clear from these new data that a full description of the resonance Raman profiles of the nucleic acids will have to include several excited electronic states. Two examples are given of cases where ionic species can be distinguished easily by using far-UV excitation, but these species are indistinguishable with 266-nm excitation. This demonstrates the utility of far-UV resonance Raman spectroscopy for obtaining structural information.