Chromosomal integration is required for spatial regulation of expression from the β-phaseolin promoter

The stringency of spatial expression of phaseolin, the major storage protein of bean (Phaseolus vulgaris) seeds, has been rigorously evaluated using stable and transient transformation techniques. Transgenic tobacco plants known to be homozygous for the β-glucuronidase (gus) reporter sequence under the regulation of various lengths of the β-phaseolin gene (phas) promoter were shown to express gus only in developing seed tissues. No expression was detected in calli initiated from stems, leaves and immature seeds, showing that expression was not leaky in undifferentiated tissues. Control plants and cultures containing gus fused to the CaMV 35S promoter actively expressed gus under identical conditions. It was not possible to induce expression in phas/gus calli with ABA, GA or jasmonic acid. Treatment of the cultures with 5-azacytidine did not result in expression, excluding methyletlon as the major factor regulating the phas promoter. However, strong gus expression was detected in seed of plants regenerated from these callus cultures, confirming that neither gene rearrangements nor deletion were responsible for the lack of activity seen in tissues other than the developing seed. In contrast to the above observations, strong transient expression of gus was detected in tobacco, bean and soybean leaves following introduction of the phas/gus fusion constructs via biolistic approaches and in electroporated bean leaf and hypocotyl protoplasts. These experiments show unequi-vocally that the phas promoter is under rigorous spatial control when integrated into the genome, but lacks spatial control when present as extrachromosomal naked DNA. A putative model explaining these differences is presented.     

Developmental control of the β-phaseolin gene requires positive, negative, and temporal seed-specific transcriptional regulatory elements and a negative element for stem and root expression

To identify cis-acting regulatory elements responsible for developmental control of the common bean seed storage protein β-phaseolin, a series of 5′-deletion mutants of the 782 bp upstream sequence together with the coding and 3′-regions of the β-phaseolin gene were used to transform tobacco. One major positive regulatory element (?295/?228) and a putative minimal promoter (?64/?14) were indicated by large reductions in phaseolin mRNA and protein concentrations in seeds of plants deficient for these regions. In addition, minor negative (?422/?296) and positive (?782/?423) elements also influenced the level of phaseolin mRNA expression in seeds. One temporal element (?295/?107) governed late expression of phaseolin mRNA in seeds, and possibly a second (?64/?14) regulated early expression. The ?64/?14 promoter containing two TATA boxes conferred spatially regulated gene expression, and was sufficient for a low level of expression in root and stem. Significant levels of phaseolin mRNA and protein were detected in stem cortices and secondary roots of plants lacking the ?295/?107 negative element. No significant expression in leaf tissue was detected. Results demonstrate that developmental control of β-phaseolin requires a minimal promoter, one element for the suppression of expression in root and stem tissue, three elements governing quantitative expression in seeds, and at least one temporal element controlling expression in seeds.     

Positive and negative cis-acting DNA domains are required for spatial and temporal regulation of gene expression by a seed storage protein promoter.

Mutations affecting spatial and temporal regulation of a beta-phaseolin gene encoding the major storage protein of bean (Phaseolus vulgaris) were analyzed by stable and transient transformation approaches. The results substantiate the value of transient assays for rapid determination of the functionality of cis-acting sequences and the importance of stable transformation to identify tissue-specific determinants. Spatial information is specified primarily by two upstream activating sequences (UAS). UAS1 (-295 to -109) was sufficient for seed-specific expression from both homologous and heterologous (CaMV 35S) promoters. In situ localization of GUS expression in tobacco embryos demonstrated that UAS1 activity was restricted to the cotyledons and shoot meristem. A second positive domain, UAS2 (-468 to -391), extended gene activity to the hypocotyl. Temporal control of GUS expression was found to involve two negative regulatory sequences, NRS1 (-391 to -295) and NRS2 (-518 to -418), as well as the positive domain UAS1. The deletion of either negative element caused premature onset of GUS expression. These findings indicate combinatorial interactions between multiple sequence motifs specifying spatial information, and provide the first example of the involvement of negative elements in the temporal control of gene expression in higher plants.     

Novel polymorphisms in the bovine β-lactoglobulin gene and their effects on β-lactoglobulin protein concentration in milk

The aim of our study was to detect new polymorphisms in the bovine β-lactoglobulin ( β-LG ) gene with significant effects on β-LG protein concentration. Genomic DNA samples from 22 proven bulls were screened for polymorphisms in the coding and promoter regions of the β-LG gene. In total, 50 polymorphisms were detected. Two single nucleotide polymorphisms (SNPs) (g.1772G>A and g.3054C>T) lead to amino acid changes and are the causal genetic polymorphisms of β-LG protein variants A and B. Forty-two polymorphisms were in complete linkage disequilibrium (LD) with β-LG protein variants A and B. Any of these 42 polymorphisms can be involved in the differential expression of the respective A and B alleles of the β- LG gene. The eight polymorphisms not in complete LD with β-LG protein variants A and B and the two polymorphisms causing the amino acid changes were genotyped in a set of 208 cows: 106 animals homozygous for β-LG protein variant A and 102 animals homozygous for β-LG protein variant B. Of these eight polymorphisms, six SNPs segregated only within the cows homozygous for β-LG protein variant A and two SNPs segregated only within the cows homozygous for β-LG protein variant B. One of the eight polymorphisms had a significant effect on β-LG protein concentration. This SNP, g.-731G>A, segregated only within the 106 cows homozygous for β-LG protein variant A. Within these cows, adjusted relative β-LG protein concentration was reduced by 1.22% (w/w) in animals homozygous g.-731AA compared with animals homozygous g.-731GG.     

Formaldehyde kills spores of Bacillus subtilis by DNA damage and small, acid-soluble spore proteins of the ααααααα/βββββββ-type protect spores against this DNA damage

Killing of wild-type spores of Bacillus subtilis with formaldehyde also caused significant mutagenesis; spores (termed α⁻β⁻) lacking the two major α/β-type small, acid-soluble spore proteins (SASP) were more sensitive to both formaldehyde killing and mutagenesis. A recA mutation sensitized both wild-type and α⁻β⁻ spores to formaldehyde treatment, which caused significant expression of a recA - lacZ fusion when the treated spores germinated. Formaldehyde also caused protein–DNA cross-linking in both wild-type and α⁻β⁻ spores. These results indicate that: (i) formaldehyde kills B. subtilis spores at least in part by DNA damage and (b) α/β-type SASP protect against spore killing by formaldehyde, presumably by protecting spore DNA.     

The α-amylase inhibitor of bean seed: two-step proteolytic maturation in the protein storage vacuoles of the developing cotyledon

In the nitrogen fixing symbiosis between Nostoc and the angiosperm Gunnera , the cyanobiont is found in stem glands and is thought to have a heterotrophic mode of nutrition. To investigate whether the photosynthetic machinery in the cyanobiont is down-regulated in the symbiosis, the presence of the phycobiliproteins, phycoerythrin and phycocyanin, and ribulose-1,5-bisphosphate carboxylase oxygenase (Rubisco, EC 4.1.1.39) in cyanobionts of Gunnera magellanica Lam. and in a free-living (cultured) isolate of the cyanobacterium was studied by immunoelectron microscopy. Carboxysomes were numerous in all vegetative cells (ca 3.5 per cell section), and on an area basis they showed a high Rubisco label compared to the cytoplasm; but recalculation on a volume basis demonstrated that the carboxysomal fraction of Rubisco decreased in the cyanobiont along the plant stem. Along the whole Gunnera stem both types of phycobiliproteins were present in the symbiotic Nostoc and in amounts equivalent to or above those detected in the free-living isolate. As the symbiotic Nostoc is located intracellularly, out of reach of light in the plant stem, the findings indicate a lack of regulation of the photosynthetic protein synthesis in the symbiotic state.     

Albumin storage proteins in the protein bodies of castor bean

Of the total protein in the protein bodies of castor bean (Ricinus communis L.), approximately 40% is represented by a group of closely related albumins localized in the matrix of the organelle. This group of albumins has a sedimentation value of 2S and is resolved into several proteins of molecular weight around 12,000 daltons by sodium dodecyl sulfate-acrylamide gel electrophoresis. It has a high content of glutamate/glutamine and undergoes rapid degradation during the early stage of germination. In view of the abundance and ubiquitous occurrence of albumins in various seeds, we suggest that albumins, in addition to globulins, glutelins, and prolamines, are important storage proteins in seeds.     

Immunohistochemical Localization of G Protein β1, β2, β3, β4, β5, and γ3 Subunits in the Adult Rat Brain

Abstract: The regional distributions of the G protein β subunits (Gβ1–β5) and of the Gγ3 subunit were examined by immunohistochemical methods in the adult rat brain. In general, the Gβ and Gγ3 subunits were widely distributed throughout the brain, with most regions containing several Gβ subunits within their neuronal networks. The olfactory bulb, neocortex, hippocampus, striatum, thalamus, cerebellum, and brainstem exhibited light to intense Gβ immunostaining. Negative immunostaining was observed in cortical layer I for Gβ1 and layer IV for Gβ4. The hippocampal dentate granular and CA1–CA3 pyramidal cells displayed little or no positive immunostaining for Gβ2 or Gβ4. No anti-Gβ4 immunostaining was observed in the pars compacta of the substantia nigra or in the cerebellar granule cell layer and Purkinje cells. Immunoreactivity for Gβ1 was absent from the cerebellar molecular layer, and Gβ2 was not detected in the Purkinje cells. No positive Gγ3 immunoreactivity was observed in the lateral habenula, lateral septal nucleus, or Purkinje cells. Double-fluorescence immunostaining with anti-Gγ3 antibody and individual anti-Gβ1–β5 antibodies displayed regional selectivity with Gβ1 (cortical layers V–VI) and Gβ2 (cortical layer I). In conclusion, despite the widespread overlapping distributions of Gβ1–β5 with Gγ3, specific dimeric associations in situ were observed within discrete brain regions.     

Differential in vitro DNA binding activity to a promoter element of the gn1β-1,3-glucanase gene in hypersensitively reacting tobacco plants

In a hypersensitive reaction to pathogen infection, expression of the β-1,3-glucanase gn1 gene is induced in cells surrounding the necrotic lesions. The 5′-flanking sequence of gn1 was examined to investigate the molecular basis controlling activation of gene expression during this plant defense response. Studies on transgenic tobacco plants containing gn1 promoter deletions fused to the β-glucuronidase reporter gene revealed the presence of negative and positive regulatory sequences mediating both the level and the spatial distribution of gn1 expression. Promoter sequences to ?138 bp were sufficient to confer increased gene expression around the necrotic lesions produced in response to Pseudomonas syringae pv. syringae inoculation. It is demonstrated by electrophoretic mobility shift assays that nuclear proteins in both healthy and hypersensitively reacting tobacco leaves interact with DNA sequences within the regulatory elements identified. Among the binding sequences characterized, the promoter region extending from ?250 to ?217 bp contained the DNA motif -GGCGGC- found to be conserved in most if not all promoters of genes encoding pathogenesis-related basic proteins. The activity bound by this promoter sequence was stronger in hypersensitively responding tissues than in healthy untreated tobacco leaves.     

Electrophoretic analysis of DNA-binding proteins during induction of 3α,20β- and 3β,17β-hydroxysteroid dehydrogenase in wild type and mutants of Streptomyces hydrogenans

Abstract Treatment of the wild-type strain HY 0 of Streptomyces hydrogenans with estradiol, a specific inducer of 3β,17β-hydroxysteroid dehydrogenase (17β-HSD) formation, caused several soluble proteins to bind to DNA-cellulose with altered affinity. Hydrocortisone which induces biosynthesis of 3α,20β-hydroxysteroid dehydrogenase (20β-HSD), and progesterone which induces production of both 17β- and 20β-HSD, had no effect on DNA-binding properties of the proteins. In mutants with altered activity/inducibility of 17β- and 20β-HSD only one DNA-binding protein (protein 23) still showed an altered DNA affinity in response to estradiol-treatment and this in only one strain. In other mutants the DNA affinity was not altered during induction with estradiol but the DNA affinity of protein 23 varied between low, low-and-high, and high affinity, depending on the strain. In the mutant where DNA affinity was altered by estradiol treatment the change was opposite to that found in the wild type.     

Evidence that the castor bean allergens are the albumin storage proteins in the protein bodies of castor bean

The well characterized castor bean (Ricinus communis L.) allergens were identified as the low molecular weight albumin storage proteins in the matrix of the protein bodies in the endosperm. The methods of identification involved molecular weight estimation, amino acid composition, stability at 100° C, solubility in various solvents, gel electrophoresis, and immunological techniques. The finding explains the wide distribution of allergens in various seeds.