Acetylenic bonds are present in more than 600 naturally occurring compounds. Plant enzymes that catalyze the formation of the Delta12 acetylenic bond in 9-octadecen-12-ynoic acid and the Delta12 epoxy group in 12,13-epoxy-9-octadecenoic acid were characterized, and two genes, similar in sequence, were cloned. When these complementary DNAs were expressed in Arabidopsis thaliana, the content of acetylenic or epoxidated fatty acids in the seeds increased from 0 to 25 or 15 percent, respectively. Both enzymes have characteristics similar to the membrane proteins containing non-heme iron that have histidine-rich motifs.
A more sensitive version of ExaVir Load, a test that utilizes reverse transcriptase (RT) activity from virions in plasma to determine HIV-1 viral load, is described. The virions were immobilized on a gel that was washed, followed by lysis of the virions, elution of purified RT, and finally RT activity determination. The changes made to the original test were: (1) improved washing of the immobilized virions by addition of a non-lytic detergent to the wash buffer, (2) improved virion lysis procedure, including changes in salt, detergent and pH, (3) the use of larger sample volumes in the RT assay, and (4) prolonged RT reaction time. The alterations gave a tenfold increased sensitivity compared to the original version. The correlation between RT load by the current test and RNA PCR was the same as previously (r=0.90). Using colorimetric product detection, the average detection limit in a panel of 262 patient plasma from Stockholm was 0.5 fg RT/ml, corresponding to approximately 170 RNA copies/ml. None of 54 HIV-1 RNA negative samples exhibited RT. The amount of RT load positive samples were 19% for samples containing 50-400 RNA, 71% for samples with 400-1,500, and 100% among samples with >8,000 copies/ml (according to Roche Amplicor). The sensitivity could be increased further using fluorimetric detection. In conclusion, the modifications of the test described result in an important increase in sensitivity. It can now be regarded as a competitive alternative method for HIV viral load determinations.
Recently, we purified to homogeneity and characterized a low-molecular-weight calcium-dependent phospholipase A2 (PLA2) from developing elm seed endosperm. This represented the first purified and characterized PLA2 from a plant tissue. The full sequences of two distinct but homologous rice (Oryza sativa) cDNAs are given here. These encode mature proteins of 1 19 amino acids (PLA2-I, preceded by a 19 amino acid signal peptide) and 128 amino acids (PLA2-II. preceded by a 25 amino acid signal peptide), and were derived from four expressed sequence tag (EST) clones. Both proteins were homologous to the N-terminal amino acid sequence of the elm PLA2. They contained twelve conserved cysteine residues and sequences that are likely to represent the Ca(2+)-binding loop and active-site motif, which are characteristic of animal secretory PLA2s. A soluble PLA2s activity was purified 145 000-fold from green rice shoots. This had the same biochemical characteristics as the elm and animal secretory PLA2s. The purified rice PLA2 consisted of two proteins, with a molecular weight of 12 440 and 12 920, that had identical N-terminal amino acid sequences. This sequence was different from but homologous to the PLA2-I and PLA2-II sequences. Taken together, the results suggest that at least three different low-molecular-weight PLA2s are expressed in green rice shoots. Southern blot analysis suggested that multiple copies of such genes are likely to occur in the rice and in other plant genomes.
Cruciferin (12s globulin) is the major seed protein in Brassica napus (oil seed rape). It is synthesized during seed development and consists of six subunit pairs. Each of these pairs is synthesized as a precursor containing one CI and one p chain. At least three different precursors exist (P1 -3), giving rise to four different mature subunits (crul -4). Several cruciferin clones were isolated from a seed mRNA cDNA library. Comparison of the deduced amino acid sequences of these clones to amino acid sequences of purified cruciferin chains and peptides identified them as coding for cru2/3 and cru4 subunits. From the amino acid sequences deduced from two overlapping cDNA clones, the precursor of the cru4 subunit was shown to consist of 465 amino acid residues. Comparison of cruciferin and cruciferin-related sequences from B. napus and Arabidopsis thaliana, respectively, suggested that early during evolution the Brassicaceae family only possessed two types of 11-12s globulin genes, like the presentday Fabaceae.During their development, plant seeds accumulate large amounts of storage proteins that serve as a source of nitrogen, sulphur and carbon for the plantlet during seed germination [l]. In B. napus (oil seed rape), as in several other dicotyledonous species, the dominating storage protein is an 11-12s globulin with an approximate relative molecular mass of 300000 -350000 [2, 31. These globulins are hexameric complexes with variable stoichiometry [4-61 where each subunit consists of a heavy CI chain (Mr approximately 30000) and a light / 3 chain (Mr approximately 20000), disulfide-linked to each other. The CI and p chains are generated by proteolytic cleavage of a precursor polypeptide that is synthesized on rough endoplasmic reticulum. The storage globulin in B. napus (cruciferin) shares these features with other 11-12s globulins and has been characterized in some detail [3, 5-71. Two cDNA clones encoding different cruciferin precursors (equivalent to the crul and cru2/3 subunits) and one corresponding genomic sequence have been isolated and sequenced [8 -101. Translation of B. napus mRNA in vitro has shown the presence of at least three different cruciferin precursors, P1-3. The relationship between these precursors and mature subunits has been established showing that P1 gives rise to al-pl chains (subunit crul), P2 to C I~/~-~~,~ chains (subunits cru2 and cru3), and P3 to a4-p4 chains (subunit cru4) [7]. The reason why precursor P2 generates two different, although very similar subunits (a2-p2 and a3-p3) might be alternative proteolytic processing of a common precursor. Alternatively, two different but highly similar precursors might comigrate at the position of P2 on SDS/PAGE. These results are supported by data from com-
A gene encoding a subunit of the 12S storage globulin, cruciferin, in Brassica napus (oilseed rape) has been isolated and characterized. The gene consists of about 2200 bp including three short intervening sequences. Primer extension analysis showed that the major transcription start site is located 30 bp 5' of the predicted ATG start codon. This gene belongs to one of three different major families encoding cruciferin subunits. By use of gene-family-specific probes and Southern blotting analysis the number of genes of the three different cruciferin subtypes in B. napus was estimated.
The major storage protein in seeds of Brassica napus, the 12S globulin cruciferin, is composed of three different groups of subunits; cru1, cru2/3 and cru4. By using gene family-specific probes, we have investigated the accumulation, rate of synthesis and spatial distribution of transcripts corresponding to the different groups of cruciferin subunits in developing seeds. Cruciferin transcripts derived from different gene families accumulate coordinately to comparable amounts during seed development. The corresponding gene families are, however, transcribed at different rates. Investigation of the spatial distribution of transcripts corresponding to each group of cruciferin subunits in the developing seed by in situ hybridization, revealed that mRNAs of all three types accumulate in both axis and cotyledons. Transcripts derived from cru1 and cru4 gene families show a similar cell specificity and accumulate in a similar spatial manner during seed development. In contrast, mRNAs corresponding to the cru2/3 gene family are expressed with a partly different cell specificity and show a slightly different pattern of accumulation in the axis and cotyledons, with a delayed accumulation in epidermal cells. In the cotyledons, the initial accumulation of this type of cruciferin mRNAs is also distinguished from the two other types. The differences in cell specificity are seen in the root cap and in provascular cells, where mRNAs belonging to the cru2/3 family are absent.
To define sequences in the cruciferin gene cru1 promoter of importance for expression, tobacco (Nicotina tabacum L.) plants were transformed with constructs in which the cru1 promoter, in front of the intact cru1 structural gene, was truncated at -1216, -974, -736, -515, -306, -46 and -17 bp relative to the cap-site. Cru1 expression in tobacco seeds was studied by Northern analysis, Western analysis and in-situ hybridizations. Comparisons of the Northern analysis of RNA from tobacco seeds harvested at 18 d after pollination with the Western analysis of protein from mature seeds showed that the regions between -974 to -736 and -306 to -46 were important for the expression of cru1 at an early developmental stage, whereas the regions -736 to -515 and -515 to -306 were important for expression throughout embryogenesis. By investigating the mRNA levels in transgenic seeds at different stages of development, indications were obtained that the two latter regions exerted their effects during the later stages. The in-situ hybridization showed that cru1 mRNA was distributed in parenchyma cells throughout the embryo in seeds expressing constructs -974 and -736. Constructs -515 and -306 showed an expression restricted to the axis or axis and parts of the cotyledons. Sequence comparisons of the cru1 promoter with other storage-protein gene promoters, identified several motifs implicated in gene regulation.(ABSTRACT TRUNCATED AT 250 WORDS)
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