Label-free prehybridization DNA microarray imaging using photonic crystals for quantitative spot quality analysis.

Technical variability during DNA capture probe printing remains an important obstacle to obtaining high quality data from microarray experiments. While methods that use fluorescent labels for visualizing printed arrays prior to hybridization have been presented, the ability to measure spot density using label-free techniques would provide valuable information on spot quality without altering standard microarray protocols. In this study, we present the use of a photonic crystal biosensor surface and a high resolution label-free imaging detection instrument to generate prehybridization images of spotted oligonucleotide microarrays. Spot intensity, size, level of saturation, and local background intensity were measured from these images. This information was used for the automated identification of missed spots (due to mechanical failure or sample depletion) as well as the assignment of a score that reflected the quality of each printed feature. Missed spots were identified with >95% sensitivity. Furthermore, filtering based on spot quality scores increased pairwise correlation of posthybridization spot intensity between replicate arrays, demonstrating that label-free spot quality scores captured the variability in the microarray data. This imaging modality can be applied for the quality control of printed cDNA, oligonucleotide, and protein microarrays.

Processing and localization of bovine beta-casein expressed in transgenic soybean seeds under control of a soybean lectin expression cassette.

We have examined the processing and subcellular localization of a chimeric gene consisting of the bovine milk protein, beta-casein, under the control of a soybean seed lectin promoter and its 32 amino acid signal sequence in the seeds of transgenic soybean plants. The beta-casein expressed in developing soybean seeds is a doublet with apparent molecular weight slightly smaller than the bovine beta-casein and expression of the protein was highest in immature cotyledons. The casein proteins were purified from the immature soybean seeds by immunoaffinity chromatography and were analyzed by two-dimensional gel electrophoresis, blotting, and amino terminal sequencing. The N-terminal sequences of both of the doublet soybean casein polypeptides were identical to the N-terminal sequence of the bovine beta-casein indicating that the 32 amino acid lectin signal sequence was cleaved precisely from the chimeric protein in developing soybean seeds. Analysis of the purified soybean beta-casein polypeptides by mass spectrometry (MALDI-MS) showed that they are not phosphorylated. Absence of added phosphate groups is the cause of the size difference between the soybean beta-casein and native bovine beta-casein protein. Immunolocalization experiments showed that the casein protein was found in the protein storage vacuoles (PSV) in developing and mature soybean seeds. The precise removal of the 32 amino acid lectin amino terminal sequence from the chimeric lectin-casein fusion suggests that the lectin expression cassette can be used for production of pharmaceutical or other recombinant proteins of added value in the developing soybean seed.

A novel promoter from soybean that is active in a complex developmental pattern with and without its proximal 650 base pairs.

We report the isolation of a novel soybean gene, Msg, which is highly expressed in developing soybean pods. The gene shows significant homology to a family of fruit- and flower-specific genes, designated the major latex protein (MLP) homologues, so far reported in only a few species and whose functions are unknown. The MLPs are more distantly related to a group of pathogenesis-related proteins (IPR or PR-10) whose functions are likewise unknown. This is the first report of a MLP homologue in a plant for which there is already an IPR-protein reported. We performed an analysis of the Msg promoter with 14 different promoter fragments ranging from 0.65 kb to 2.26 kb, fused to the uidA (GUS) gene. High transient expression was obtained with all the constructs upon particle bombardment in soybean and green bean pods. Stable Arabidopsis transformants were obtained with the Agrobacterium vacuum infiltration method. The promoter is fully active in Arabidopsis only in plants transformed with the 2.26 kb fragment promoter, expressing GUS in nectaries, nodes, short style and in guard cells of the silique, pedicel and stem but not in mature leaves. Surprisingly, the proximal 650 bp TATA-containing region cannot function on its own in Arabidopsis and can be deleted without a change in expression pattern in both Arabidopsis and soybean. Thus, tissue-specific regions of the complex Msg promoter reside in the distal 5' regions upstream of a dispensable TATA box in contrast to many examples of tissue-specific elements that reside much closer to the TATA box.

A defective seed coat pattern (Net) is correlated with the post-transcriptional abundance of soluble proline-rich cell wall proteins.

The pigmented seed coats of several soybean (Glycine max (L.) Merr.) plant introductions and isolines have unusual defects that result in cracking of the mature seed coat exposing the endosperm and cotyledons. It has previously been shown that the T (tawny) locus that controls the color of trichomes on stems and leaves also has an effect on both the structure and pigmentation of the seed coat. Distribution of pigmentation on the seed coat is controlled by alleles of the I (inhibitor) locus. It was also found that total seed coat proteins were difficult to extract from pigmented seed coats with i T genotypes because they have procyanidins that exhibit tannin properties. We report that the inclusion of poly-L-proline in the extraction buffer out-competes proteins for binding to procyanidins. Once this problem was solved, we examined expression of the proline-rich cell wall proteins PRP1 and PRP2 in pigmented genotypes with the dominant T allele. We found that both homozygous i T and i t genotypes have reduced soluble PRP1 levels. The epistatic interaction of the double recessive genotype at both loci is necessary to produce the pigmented, defective seed coat phenotype characteristic of seed coats with the double recessive i and t alleles. This implies a novel effect of an enzyme in the flavonoid pathway on seed coat structure in addition to its effect on flavonoids, anthocyanidins, and proanthocyanidins. No soluble PRP1 polypeptides were detectable in pigmented seed coats (i T genotypes) of isolines that also display a net-like pattern of seed coat cracking, known as the Net defect. PRP2 was also absent in one of the these lines. However, both PRP1 and PRP2 cytoplasmic mRNAs were found in the Net-defective seed coats. Together with in vitro translation studies, these results suggest that the absence of soluble PRP polypeptides in the defective Net lines is post-translational and could be due to a more rapid or premature insolubilization of PRP polypeptides within the cell wall matrix.

Duplications That Suppress and Deletions That Restore Expression from a Chalcone Synthase Multigene Family.

Seed coat color in soybean is determined by four alleles of the classically defined / (inhibitor) locus that controls the presence or absence as well as the spatial distribution of anthocyanin pigments in the seed coat. By analyzing spontaneous mutations of the / locus, we demonstrated that the / locus is a region of chalcone synthase (CHS) gene duplications. Paradoxically, deletions of CHS gene sequences allow higher levels of CHS mRNAs and restore pigmentation to the seed coat. The unusual nature of the / locus suggests that its dominant alleles may represent naturally occurring examples of homology-dependent gene silencing and that the spontaneous deletions erase the gene-silencing phenomena. Specifically, mutations from the dominant ii allele (yellow seed coats with pigmented hila) to the recessive i allele (fully pigmented) can be associated with the absence of a 2.3-kb Hindlll fragment that carries CHS4, a member of the multigene CHS family. Seven independent mutations exhibit deletions in the CHS4 promoter region. The dominant / allele (yellow seed coats) exhibits an extra 12.1-kb Hindlll fragment that hybridizes with both the CHS coding region and CHS1 promoter-specific probes. Mutations of the dominant / allele to the recessive i allele (pigmented seed coats) give rise to 10.4- or 9.6-kb Hindlll CHS fragments that have lost the duplicated CHS1 promoter. Finally, gene expression analysis demonstrated that heterozygous plants (I/i) with yellow seed coats have reduced mRNA levels, indicating that the 12.1-kb Hindlll CHS fragment associated with the dominant / allele inhibits pigmentation in a trans-dominant manner. Moreover, CHS gene-specific expression in seed coats shows that multiple CHS genes are expressed in seed coats.

Genetic length polymorphisms create size variation in proline-rich proteins of the cell wall.

Two genes, Prp1 and Prp2, encode proline-rich proteins that are found in different stages of developing seed coats, hypocotyls, and roots of soybeans (Glycine max (L.) Merr.). PRP1 is found in young seed coats and PRP2 is found later during seed desiccation. In some soybean varieties, both proteins are smaller as determined by immunoblotting seed coat proteins separated by sodium dodecyl sulfate polyacrylamide gel electrophoresis. It was found that Prp1 and Prp2 genes are linked to each other by testing seed coat protein extracts from an F2 population of a cross between the cultivar Richland, which exhibits the larger PRP proteins, and Blackhawk, which has the smaller PRP proteins. The Prp1 and Prp2 genes were separated by approximately 13% recombination. Simultaneous expression of soluble PRP2 polypeptides in the maternal seed coat and underlying aleurone layer of the embryo was found. The molecular basis for the size difference between the two varieties was examined using polymerase chain reaction to isolate the Prp genes from Blackhawk, the variety that exhibited the smaller proteins. Both of the genes from Blackhawk contained length polymorphisms that result in omission of some of the repeat units (pro pro val tyr lys) from the proteins. In Prp1, there were two separate deletions in different parts of the gene, each being two tandem repeats in length. In Prp2, there was only one deletion of two tandem repeats. These deletions occur within the coding regions in a manner that conserves the reading frame. The results are the first description of genetic variation in cell wall proteins and its molecular basis.(ABSTRACT TRUNCATED AT 250 WORDS)

Chalcone synthase mRNA and activity are reduced in yellow soybean seed coats with dominant I alleles.

The seed of all wild Glycine accessions have black or brown pigments because of the homozygous recessive i allele in combination with alleles at the R and T loci. In contrast, nearly all commercial soybean (Glycine max) varieties are yellow due to the presence of a dominant allele of the I locus (either I or i) that inhibits pigmentation in the seed coats. Spontaneous mutations to the recessive i allele occur in these varieties and result in pigmented seed coats. We have isolated a clone for a soybean dihydroflavonol reductase (DFR) gene using polymerase chain reaction. We examined expression of DFR and two other genes of the flavonoid pathway during soybean seed coat development in a series of near-isogenic isolines that vary in pigmentation as specified by combinations of alleles of the I, R, and T loci. The expression of phenylalanine ammonia-lyase and DFR mRNAs was similar in all of the gene combinations at each stage of seed coat development. In contrast, chalcone synthase (CHS) mRNA was barely detectable at all stages of development in seed coats that carry the dominant I allele that results in yellow seed coats. CHS activity in yellow seed coats (I) was also 7- to 10-fold less than in the pigmented seed coats that have the homozygous recessive i allele. It appears that the dominant I allele results in reduction of CHS mRNA, leading to reduction of CHS activity as the basis for inhibition of anthocyanin and proanthocyanin synthesis in soybean seed coats. A further connection between CHS and the I locus is indicated by the occurrence of multiple restriction site polymorphisms in genomic DNA blots of the CHS gene family in near-isogenic lines containing alleles of the I locus.

Pigmented Soybean (Glycine max) Seed Coats Accumulate Proanthocyanidins during Development.

The dominant I gene inhibits accumulation of anthocyanin pigments in the epidermal layer of soybean (Glycine max) seed coats. Seed-coat color is also influenced by the R locus and by the pubescence color alleles (T, tawny; t, gray). Protein and RNA from cultivars with black (i,R,T) and brown (i,r,T) seed coats are difficult to extract. To determine the nature of the interfering plant products, we examined seed-coat extracts from Clark isogenic lines for flavonoids, anthocyanins, and possible proanthocyanidins by thin-layer chromatography. We show that yellow seed-coat varieties (I) do not accumulate anthocyanins (anthocyanidin glycosides) or proanthocyanidins (polymeric anthocyanidins). Mature, black (i,R,T) and imperfect-black (i,R,t) seed coats contained anthocyanins, whereas mature, brown (i,r,T) and buff (i,r,t) seed coats did not contain anthocyanins. In contrast, all colored (i) genotypes tested positive for the presence of proanthocyanidins by butanol/ HCl and 0.5% vanillin assays. Immature, black (i,R,T) and brown (i,r,T) seed coats contained significant amounts of procyanidin, a 3[prime],4[prime]-hydroxylated proanthocyanidin. Immature, black (i,R,T) or brown (i,r,T) seed-coat extracts also tested positive for the ability to precipitate proteins in a radial diffusion assay and to bind RNA in vitro. Imperfect-black (i,R,t) or buff (i,r,t) seed coats contained lesser amounts of propelargonidin, a 4[prime]-hydroxylated proanthocyanidin. Seed-coat extracts from these genotypes did not have the ability to precipitate protein or bind to RNA. In summary, the dominant I gene controls inhibition of not only anthocyanins but also proanthocyanidins in soybean seed coats. In homozygous recessive i genotypes, the T-t gene pair determines the types of proanthocyanidins present, which is consistent with the hypothesis that the T locus encodes a microsomal 3[prime]-flavonoid hydroxylase.

Variation of proline rich cell wall proteins in soybean lines with anthocyanin mutations.

The I locus controls inhibition of anthocyanin accumulation in the epidermal cells of the soybean seed coat and affects abundance of PRP1, a proline-rich cell wall protein in the seed coat. Saline-soluble PRP1 is abundant in the developing seed coats of cultivar Richland (homozygous I, yellow), while it is significantly decreased in the pigmented isogenic mutant T157 (homozygous i, imperfect black). In this report, we examined soluble PRP1 in several cultivars containing alleles of the I locus which affect spatial distribution of pigmentation in the seed coat. We also characterized PRP1 in isolines with allelic variants of several other loci involved in seed coat pigmentation, including T and Im. The T gene is pleiotropic and affects both pubesence color and seed coat pigmentation and structure. Soluble PRP1 was abundant in the developing seed coats of lines with yellow seed (I or ii alleles) regardless of pubescence color, just as in Richland. Likewise, soluble PRP1 was decreased in pigmented seed coats (ik or i alleles) with grey (t) pubescence, as in T157. However, the total seed coat proteins were not extractable from pigmented seed coats with tawny pubescence (i, T genotypes) because they have proanthocyanidins that exhibit tannin properties. The dominant Im allele inhibits seed coat mottling (irregular patches of pigmentation) that occurs if plants are infected with soybean mosaic virus. PRP1 was 35 kDa in mottled (im) isolines and 34 kDa in non-mottled (Im) isolines. PRP2, which is expressed later in seed coat development and in the hypocotyl hooks of soybean seedlings, was also smaller in Im isolines. In summary, some of the anthocyanin mutations affect the quantity of soluble PRP1 polypeptides. while others correlate with structural changes in developmentally regulated proline-rich proteins.

Fluorescent in situ hybridization to soybean metaphase chromosomes.

Repetitive DNA sequences were detected directly on somatic metaphase chromosome spreads from soybean root tips using fluorescent in situ hybridization. Methods to spread the forty small metaphase chromosomes substantially free of cellular material were developed using protoplasts. The specific DNA probe was a 1.05 kb internal fragment of a soybean gene encoding the 18S ribosomal RNA subunit. Two methods of incorporating biotin residues into the probe were compared and detection was accomplished with fluorescein-labeled avidin. The rDNA probe exhibits distinct yellow fluorescent signals on only two of the forty metaphase chromosomes that have been counterstained with propidium iodide. This result agrees with our previous analyses of soybean pachytene chromosomes showing that only chromosome 13 is closely associated with the nucleolus organizer region. Fluorescent in situ hybridization with the rDNA probe was detected on three of the forty-one metaphase chromosomes in plants that are trisomic for chromosome 13.

A soybean cell wall protein is affected by seed color genotype.

The dominant I gene inhibits accumulation of anthocyanin pigments in epidermal cells of the soybean seed coat. We compared saline-soluble proteins extracted from developing seed coats and identified a 35-kilodalton protein that was abundant in Richland (genotype I/I, yellow) and much reduced in an isogenic mutant line T157 (genotype i/i, imperfect black seed coats). We purified the 35-kilodalton protein by a novel procedure using chromatography on insoluble polyvinylpolypyrrolidone. The 35-kilodalton protein was composed primarily of proline, hydroxyproline, valine, tyrosine, and lysine. Three criteria (N-terminal amino acid sequence, amino acid composition, and sequence of a cDNA) proved that the seed coat 35-kilodalton protein was PRP1, a member of a proline-rich gene family expressed in hypocotyls and other soybean tissues. The levels of soluble PRP1 polypeptides and PRP1 mRNA were reduced in young seed coats with the recessive i/i genotype. These data demonstrated an unexpected and novel correlation between an anthocyanin gene and the quantitative levels of a specific, developmentally regulated cell wall protein. In contrast, PRP2, a closely related cell wall protein, was synthesized later in seed coat development and was not affected by the genotype of the I locus.

Sequence and structure of a phenylalanine ammonia-lyase gene from Glycine max.

The gene encoding a key enzyme in anthocyanin biosynthesis, phenylalanine ammonia-lyase (PAL), was cloned from soybean (Glycine max). The purpose was to obtain a molecular probe to study the organization of this gene family in soybean and to examine novel regulatory mechanisms present in the anthocyanin biosynthetic pathway of this system. A soybean genomic library was constructed in the bacteriophage vector lambda Charon 35. A PAL cDNA clone from Phaseolus vulgaris was used in screening the library, and two PAL genes were isolated. One gene was sequenced entirely and analyzed by sequence homology to the PAL2 gene of Phaseolus vulgaris. Genomic analysis indicates that PAL sequences of Glycine max exist as a small gene family consisting of only two to three members. The representative PAL gene sequenced (PAL1) has a coding region of 2142 basepairs divided among two exons. The single intron is 1519 basepairs and splits the 131st codon.

Expression of soybean lectin gene deletions in tobacco.

A series of constructs containing the developmentally regulated soybean lectin gene (Le1) were used to transform tobacco plants in order to assess developmental and quantitative regulation conferred by flanking sequences. The largest of the lectin constructs contained approximately 3,000 base pairs (bp) of Le1 5 flanking region and 1,500 bp of the 3 flanking region. The smallest construct contained no 5 flanking region and 194 bp of the 3 flanking region. ELISA assays of lectin in individual tobacco seeds and Southern blot analyses confirmed that most constructs were inherited as unique insertion events. Maximal expression of Le1 required more than 338 bp of 5 sequence, indicating that far upstream factors are involved in quantitative control of lectin expression. Lectin expression declined more than 80% between deletions with 1,700 versus 338 bp of 5 flanking sequence. In contrast, developmental control of lectin expression was maintained by Le1 inserts with only 190 bp of 5 sequence. The lectin promoter offers a potential means to target high levels of gene expression to the developing seeds of soybean or other dicotyledonous plants.

Unstable expression of a soybean gene during seed coat development.

The R gene of soybean is involved in anthocyanin synthesis in the seed coat, and its r-m allele conditions a variegated distribution of black spots and/or concentric rings of pigment superimposed on an otherwise brown seed coat. We describe an unusual feature of r-m that causes expression at the R locus to switch between active and inactive phases both somatically and germinally. Non-heritable somatic changes of the allele produce single plants containing mixtures of seed with different coat colors (black+striped or brown+striped). Heritable changes of the r-m allele are manifested in progeny plants which produce all black seed or all brown seed. Surprisingly, subsequent generations from revertant sublines show continued instability of the allele such that brown revertants (r*/r*) or homozygous black seed revertants (R*/R*) can give rise to striped or striped+black-seeded plants. Thus, the revertants produced by the r-m allele are not stable but interconvert between all three forms (R*, r*, and r-m) at detectable frequencies. Mutability of the r-m allele in a different genetic background has also been found after inter-crossing various soybean genotypes.

Organization of the Tgm family of transposable elements in soybean.

We have compared the organization of six Tgm elements that were selected from a genomic library of soybean DNA on the basis of hybridization with subcloned regions of Tgm 1 (transposon, Glycine max) from the seed lectin gene. These elements ranged in size from 1.6 kbp to greater than 12 kbp. Tgm2, Tgm3, Tgm4 and Tgm5 represent partial isolates in which the genomic clone contained a 3' but not a 5' terminus of the element; while Tgm6 and Tgm7, like Tgm1, were small isolates flanked by both 5' and 3' nonelement sequences. Cross-hybridization studies between subcloned portions of these seven elements identified regions of homology which suggest that the Tgm transposable elements of soybean form a family of deletion derivatives. In addition to internal deletion events, numerous deletions and base substitutions are also present within the borders of these elements which are comprised of the same tandemly repeated sequence. The 39% amino acid homology between a 1 kb portion of an open reading frame in Tgm4 and Tgm5 and ORF1, an open frame from the first intron of the maize Enhancer (Suppressor-mutator) transposable element, suggests that both elements encode a common function that requires a high degree of protein conservation.

Soybean lectin and related proteins in seeds and roots of le and le soybean varieties.

The localizations of soybean lectin (SBL) and antigenically related proteins in cotyledons and roots of lectin positive (Le(+)) and lectin negative (Le(-)) soybean cultivars were compared by light level immunocytochemistry using antibodies produced against the 120 kilodalton (kD) native seed lectin tetramer or its subunits. Lectin is present in the protein bodies of cotyledons cells as are two other seed proteins, the Kunitz trypsin inhibitor and the storage protein glycinin. Analysis of single seed extracts by immunoblotting of sodium dodecyl sulfate-polyacrylamide gels using the same antibodies, reveals up to 4 milligrams of the 30 kD seed lectin protein is present per seed in the Le(+) varieties. There is no detectable lectin in the protein bodies of Le(-) cotyledons as determined by immunocytochemistry and immunoblotting. Enzyme-linked immunosorbent assay confirmed this result to a sensitivity of less than 20 nanograms per seed. In contrast, the roots of both Le(+) and Le(-) plants bind the seed lectin antibody during immunocytochemistry, with fluorescence mainly localized in vacuole-like bodies in the epidermis. Root extracts contain a 33 kD polypeptide that binds anti-SBL antibody at an estimated minimal level of 20 nanograms per 4-day seedling, or 2.0 nanograms per primary root tip. This polypeptide is also present in the embryo axis and in leaves. The latter also contain a 26 kD species that binds seed lectin antibody. The 30 kD seed lectin subunit, however, is not detectable in roots or leaves.

Highly structured sequence homology between an insertion element and the gene in which it resides.

The recessive allele for soybean seed lectin results from the insertion of a DNA segment (designated Tgm1) into the coding region of the gene. The termini of Tgm1 display structural features characteristic of a transposable element. The complete sequence of Tgm1 contains 3550 base pairs (bp) and can be divided into three regions (left arm, mid-section, and right arm). No large open reading frames were found, but an extensive, highly structured border with homology to the lectin gene was revealed. The left border (726 bp) comprising most of the left arm and extreme right border (144 bp) of the right arm consist of various forms of a basic 54-bp repeating unit. This 54-bp unit is comprised of a stem-loop structure and interhairpin sequence that occurs 13 times in the left arm and 2 times in the right arm of Tgm1. Progressively degenerate forms of this repeating unit appear toward the termini of Tgm1, but the dyad symmetry remains highly conserved. Seven nucleotides (A-C-A-T-C-G-G and its complement) maintained within the stem also appear as a subset of inverted repeats found at nearly equal distances from the target site in the lectin gene. Together with the inverted repeat termini and a duplication in the left arm, this 7-bp sequence occurs a total of 33 times in Tgm1. We infer that the dyad symmetries containing this sequence are involved in target gene selection. The repeating unit format of Tgm1 describes a distinct class of eukaryotic elements that includes representatives known to be mobile in snapdragon and maize.

cA lectin gene insertion has the structural features of a transposable element.

The single gene Le1, coding for soybean seed lectin, was compared to le1, a naturally occurring mutant allele containing a 3.4 kb insertion within its coding region. Le1 is devoid of introns and produces a 1.0 kb mRNA. It codes for a signal sequence of 32 amino acids and a mature protein of 253 amino acids. With the exception of six single-base substitutions, the coding and flanking sequences in le1 are identical with those in the uninterrupted gene. The insertion termini are imperfect inverted repeats flanked by a 3 bp duplication of lectin target DNA. Inverted repeats within the lectin gene are located symmetrically with respect to the insertion site and are homologous to a region of the insertion termini. These molecular traits conform with the structural aspects of transposable elements in other organisms and imply some degree of site specificity.