Molecular insights into the regulation of rice kernel elongation.

A large number of rice agronomic traits are complex, multi factorial and polygenic. As the mechanisms and genes determining grain size and yield are largely unknown, the identification of regulatory genes related to grain development remains a preeminent approach in rice genetic studies and breeding programs. Genes regulating cell proliferation and expansion in spikelet hulls and participating in endosperm development are the main controllers of rice kernel elongation and grain size. We review here and discuss recent findings on genes controlling rice grain size and the mechanisms, epialleles, epigenomic variation, and assessment of controlling genes using genome-editing tools relating to kernel elongation.

The efficacy of molecular markers analysis with integration of sensory methods in detection of aroma in rice.

Allele Specific Amplification with four primers (External Antisense Primer, External Sense Primer, Internal Nonfragrant Sense Primer, and Internal Fragrant Antisense Primer) and sensory evaluation with leaves and grains were executed to identify aromatic rice genotypes and their F1 individuals derived from different crosses of 2 Malaysian varieties with 4 popular land races and 3 advance lines. Homozygous aromatic (fgr/fgr) F1 individuals demonstrated better aroma scores compared to both heterozygous nonaromatic (FGR/fgr) and homozygous nonaromatic (FGR/FGR) individuals, while, some F1 individuals expressed aroma in both leaf and grain aromatic tests without possessing the fgr allele. Genotypic analysis of F1 individuals for the fgr gene represented homozygous aromatic, heterozygous nonaromatic and homozygous nonaromatic genotypes in the ratio 20:19:3. Genotypic and phenotypic analysis revealed that aroma in F1 individuals was successfully inherited from the parents, but either molecular analysis or sensory evaluation alone could not determine aromatic condition completely. The integration of molecular analysis with sensory methods was observed as rapid and reliable for the screening of aromatic genotypes because molecular analysis could distinguish aromatic homozygous, nonaromatic homozygous and nonaromatic heterozygous individuals, whilst the sensory method facilitated the evaluation of aroma emitted from leaf and grain during flowering to maturity stages.

Genome characterization of a breeding line derived from a cross between Oryza sativa and Oryza rufipogon.

A preliminary screening was conducted on BC3F1 and BC4F1 backcross families developed from crossing Oryza sativa (MR219) and O. rufipogon (IRGC105491). Despite earlier results showing that O. rufipogon alleles (wild introgression) contributed to both number of panicles (qPPL-2) and tillers (qTPL-2) at loci RM250, RM208, and RM48 in line A20 of the BC2F2 population, we observed that wild introgression was lost at loci RM250 and RM208 but retained at locus RM48 in BC3F1 and BC4F1. Progeny tests conducted utilizing genotype and phenotype data on both BC4F1 and a reference population, BC2F7 (A20 line), did not show significant differences between groups having the MR219 allele and wild introgression at locus RM48. This suggests that there is no additive and transgressive effect of wild introgression in the BC3F1 and BC4F1 generated. The presence of wild introgression was largely due to gene contamination by cross-pollination during field breeding practices.

Regulation of proteins in the cholesterol side-chain cleavage system in JEG-3 and Y-1 cells.

The conversion of cholesterol to pregnenolone, the rate-limiting step in steroid hormone synthesis, occurs on mitochondrial cytochrome P450scc, which catalyzes this reaction by receiving electrons from NADPH via a flavoprotein [adrenodoxin reductase (AdRed)] and an iron sulfur protein [adrenodoxin (Adx)]. The behavior of the genes and mRNAs encoding these proteins has been studied in several systems, but little is known about the behavior of the human proteins. Using cloned cDNAs for human P450scc and AdRed, we constructed bacterial expression vectors to make milligram quantities of the corresponding proteins. These, plus purified human Adx similarly prepared by Dr. L. Vickery, were injected into rabbits to raise antiserum to each of the proteins. Each antiserum was highly specific and did not cross-react with other mitochondrial proteins detectable by Western blotting. Human JEG-3 choriocarcinoma cells and mouse Y-1 adrenocortical carcinoma cells were then incubated for 0-24 h with 1 mM 8-bromo-cAMP (8Br-cAMP) or 30 nM phorbol 12-myristate 13-acetate (PMA; phorbol ester) plus 1 microM A23187 (calcium ionophore) to activate the protein kinase-A and -C pathways, respectively. In JEG-3 cells, 8Br-cAMP increased and PMA/A23187 slightly decreased the abundance of P450scc and Adx, but neither treatment had a detectable effect on AdRed. The production of pregnenolone by these cells increased 3-fold in response to 8Br-cAMP and fell to one third in response to PMA/A23187. In Y-1 cells, 8Br-cAMP increased the abundance of all three proteins, while PMA/A23187 decreased the abundance of P450scc and Adx. The production of pregnenolone by these cells increased 9-fold in response to 8Br-cAMP and was unaffected by TPA/A23187. These studies show that the three proteins of the cholesterol side-chain cleavage system behave in response to 8Br-cAMP and PMA/A23187 as predicted from the study of their genes and mRNAs, indicating that the chronic regulation of steroidogenesis in these cell systems is regulated principally at the level of mRNA abundance.

Construction and function of fusion enzymes of the human cytochrome P450scc system.

Type I cytochrome P450 enzyme systems are found in mitochondria and consist of three components, a flavoprotein (adrenodoxin reductase, AdRed), an iron-sulfur protein (adrenodoxin, Adx), and the cytochrome P450; Type II P450 enzymes in the endoplasmic reticulum consist of only two components, P450 reductase and the P450. Genetically engineered fusion proteins of Type II cytochromes P450 (such as steroid 17 alpha- and 21-hydroxylases) produce enzymes with increased activity. To test the consequences of constructing fusions of Type I enzymes, we built fusion proteins based on the cholesterol side-chain cleavage enzyme, P450scc. We constructed expression vectors for three fusion proteins: NH2-P450scc-AdRed-COOH, P450-AdRed-Adx, and P450scc-Adx-AdRed. The various components were assembled from cassette-like cDNA fragments modified and amplified by polymerase chain reaction (PCR), subcloned into a specially tailored vector, and linked by DNA segments encoding hydrophilic linker peptides. The final vectors were transfected into COS-1 cells, incubated with 22R-hydroxycholesterol, and assayed by the secretion of pregnenolone into the culture medium. Triple transfection of three individual vectors expressing P450scc, AdRed, and Adx yielded more pregnenolone than did transfection with P450scc alone. The P450scc-AdRed and P450scc-Adx-AdRed fusion proteins produced levels of pregnenolone similar to the control triple transfection. However, the P450scc-AdRed-Adx fusion produced substantially more pregnenolone, having an apparent Vmax of 9.1 ng of pregnenolone produced per milliliter of medium per 24 hr, compared to a Vmax of 1.7 ng/ml per day for the triple transfection.(ABSTRACT TRUNCATED AT 250 WORDS)

Determination of chromosome copy numbers in Saccharomyces cerevisiae strains via integrative probe and blot hybridization techniques.

Methods have been devised for analyzing chromosome copy numbers in S. cerevisiae strains that may be polyploid or aneuploid, as is apparent in the case of many industrial strains. The initial step involved transformation of a strain with an integrative "ploidy probe" transplacement fragment that enabled the copy number of the targeted chromosomal locus to be determined via genomic Southern blotting and quantitative probe hybridization. Dual probe co-hybridization to Southern genomic DNA blots was used to extend such locus copy number determinations to other loci within the same chromosome, thereby screening for internal consistency along the length of the chromosome. This approach was also used to extend the analysis to other chromosomes in the genome. The method was established and verified with euploid series laboratory strains and then used to examine chromosome copy numbers in three industrial strains. One brewing strain apparently contained three copies of the chromosomes tested, whilst another brewing and a baking strain showed evidence of aneuploidy.

Missense mutation serine106----proline causes 17 alpha-hydroxylase deficiency.

Steroid 17 alpha-hydroxylase deficiency is caused by defects in cytochrome P450c17, the single enzyme that has 17-alpha hydroxylase and 17,20-lyase activities. We describe a rapid and efficient polymerase chain reaction tactic for identifying these genetic lesions and identify Ser106----Pro as the cause of 17 alpha-hydroxylase deficiency in two unrelated homozygous patients from Guam. We used site-directed mutagenesis of the normal P450c17 cDNA to construct the Pro106 mutant, and expressed both the normal and mutant sequences in monkey COS-1 cells and in yeast. Expression of the normal sequence permitted the cells to convert pregnenolone to 17-OH pregnenolone, progesterone to 17-OH progesterone, and 17-OH pregnenolone to dehydroepiandrosterone, showing the normal sequence conferred both 17 alpha-hydroxylase and 17,20-lyase activities. Expression of the mutant sequence generated P450c17 mRNA, but conferred none of these activities, proving that the Ser106----Pro mutation abolished the 17 alpha-hydroxylase and 17,20-lyase activities. An HhaI restriction site created by the mutation should permit screening of large populations.

The mitochondrial environment is required for activity of the cholesterol side-chain cleavage enzyme, cytochrome P450scc.

Steroidogenesis is initiated by the conversion of cholesterol to pregnenolone by mitochondrial cytochrome P450scc [cholesterol, reduced-adrenal-ferredoxin:oxygen oxidoreductase (side-chain-cleaving); EC 1.14.15.6]. Several subsequent steroidal conversions occur in the endoplasmic reticulum (ER), but the last step in the production of glucocorticoids and mineralocorticoids again occurs in the mitochondria. Although cellular compartmentalization of steroidogenic enzymes appears to be a feature of all steroidogenic pathways, some reports indicate that cholesterol can be converted to pregnenolone outside the mitochondria. To investigate whether P450scc can function outside the mitochondria, we constructed vectors producing P450scc and various fusion enzymes of P450scc with electron-transport proteins and directed their expression to either the ER or the mitochondria. Whether targeted to mitochondria or to the ER, plasmid vectors encoding P450scc and fusion proteins of P450scc with either mitochondrial or microsomal electron-transport proteins produced immunodetectable protein. When expressed in mitochondria, all of these constructions converted 22-hydroxycholesterol to pregnenolone, but when expressed in the ER none of them produced pregnenolone. These results show that P450scc can function only in the mitochondria. Furthermore, it appears to be the mitochondrial environment that is required, rather than the specific mitochondrial electron-transport intermediates.