Regulation of loblolly pine (Pinus taeda L.) arginase in developing seedling tissue during germination and post-germinative growth.

After seed germination, hydrolysis of storage proteins provides a nitrogen source for the developing seedling. In conifers the majority of these reserves are located in the living haploid megagametophyte tissue. In the developing loblolly pine (Pinus taeda L.) seedling an influx of free amino acids from the megagametophyte accompanies germination and early seedling growth. The major component of this amino acid pool is arginine, which is transported rapidly and efficiently to the seedling without prior conversion. This arginine accounts for nearly half of the total nitrogen entering the cotyledons and is likely a defining factor in early seedling nitrogen metabolism. In the seedling, the enzyme arginase is responsible for liberating nitrogen, in the form of ornithine and urea, from free arginine supplied by the megagametophyte. In this report we investigate how the seedling uses arginase to cope with the large arginine influx. As part of this work we have cloned an arginase cDNA from a loblolly pine expression library. Analysis of enzyme activity data, accumulation of arginase protein and mRNA abundance indicates that increased arginase activity after seed germination is due to de novo synthesis of the enzyme. Our results suggest that arginase is primarily regulated at the RNA level during loblolly pine seed germination and post-germinative growth.

Amino Acid Utilization in Seeds of Loblolly Pine during Germination and Early Seedling Growth (I. Arginine and Arginase Activity).

The mobilization and utilization of the major storage proteins in loblolly pine (Pinus taeda L.) seeds following imbibition were investigated. Most of the seed protein reserves were contained within the megagametophyte. Breakdown of these proteins occurred primarily following radicle emergence and correlated with a substantial increase in the free amino acid pool in the seedling; the majority of this increase appeared to be the result of export from the megagametophyte. The megagametophyte was able to break down storage proteins and export free amino acids in the absence of the seedling. Arginine (Arg) was the most abundant amino acid among the principal storage proteins of the megagametophyte and was a major component of the free amino acid pools in both the seedling and the megagametophyte. The increase in free Arg coincided with a marked increase in arginase activity, mainly localized within the cotyledons and epicotyl of the seedling. Arginase activity was negligible in isolated seedlings. Experiments with phenylphosphorodiamidate, a urease inhibitor, supported the hypothesis that arginase participates in Arg metabolism in the seedling. The results of this study indicate that Arg could play an important role in the nutrition of loblolly pine during early seedling growth.

Regulation of two loblolly pine (Pinus taeda L.) isocitrate lyase genes in megagametophytes of mature and stratified seeds and during postgerminative growth.

Two full-length cDNAs encoding the glyoxysomal enzyme isocitrate lyase (ICL) were isolated from a lambda ZAP cDNA library prepared from megagametophyte mRNAs extracted from seeds imbibed at 30 degrees C for 8 days. The cDNAs, designated Ptbs ICL 8 and Ptbs ICL 12, have open reading frames of 1740 and 1719 bp, with deduced amino acid sequences of 580 and 573 residues, respectively. The predicted amino acid sequences of Ptbs ICL 8 and Ptbs ICL 12 exhibit a 79% identity with each other, and have a greater than 75% identity with ICLs from various angiosperm species. The C-termini of Ptbs ICL 8 and Ptbs ICL 12 terminate with the tripeptide Ser-Arg-Met and Ala-Arg-Met, respectively, both being conserved variants of the type 1 peroxisomal targeting signal. RNA blot and slot analysis revealed that Ptbs ICL 8 and Ptbs ICL 12 mRNAs were present at low levels in the megagametophyte of the mature and stratified seeds, and that the level of both transcripts increased markedly upon seed germination. Protein blot analysis indicated that the steady-state level of ICL was low in the mature and stratified seed, then increased rapidly upon seed germination, peaking at around 8-10 days after imbibition (DAI). Changes in the level of ICL activity in cell-free extracts was similar to the steady-state protein content with the exception that ICL activity was not detected in megagametophyte extracts of mature or stratified seeds. From 10-12 DAI when the megagametophyte tissue senesced, ICL activity decreased rapidly to near undetectable levels. In contrast, steady-state levels of ICL protein and mRNA remained relatively constant during megagametophyte senescence. In vivo synthesis of ICL protein was measured to shed light on these differences. ICL immunoselected from [(35)S]-methionine labelled proteins indicated that ICL was synthesized at very low levels during megagametophyte senescence. Together, the results show that loblolly pine ICL gene expression is complex. While temporal regulation appears to be primarily transcriptional, it also involves a number of post-transcriptional processes including at least one translational and/or post-translational mechanism.

Heat-shock response of Pinus and Picea seedlings.

The effect of a short period of elevated temperature, or heat shock, on protein synthesis was investigated in 2-day-old seedlings of jack pine (Pinus banksiana Lamb.), loblolly pine (P. taeda L.), lodgepole pine (P. contorta Dougl.), black spruce (Picea mariana (Mill.) BSP), and white spruce (P. glauca (Moench) Voss.). In all species, heat shock led to increased [(35)S]methionine incorporation into heat-shock proteins (hsp's) with molecular masses of 83 and 72 kDA. Heat shock also induced synthesis of several low molecular weight proteins that were absent from control seedlings. The low molecular weight hsp's produced by pine seedlings had molecular masses of 27, 24.6, 20.5 and 17.5 kDa, whereas those produced by spruce seedlings had molecular masses of 27.2, 19.8, 18.4, 17.2 and 16.0 kDa. All of the low molecular weight hsp's showed isoelectric variants. Heat shock led to increased [(35)S]methionine incorporation into a group of low molecular weight hsp's that were also present in control seedlings.

Purification and Characterization of Catalase from Loblolly Pine (Pinus taeda L.) Megagametophytes.

Catalase (EC 1.11.1.6) was purified to near homogeneity from isolated megagametophytes of germinated loblolly pine (Pinus taeda L.) seeds, and monospecific antibodies were elicited in rabbits. Following a procedure that involved acetone extraction, (NH4)2SO4 fractionation, and four chromatographic steps (i.e. DE-52 cellulose, Superdex-200, hydroxylapatite, and phenyl-Sepharose CL-4B), catalase was purified about 140-fold to a final specific activity of 2215 mmol min-1 mg-1 of protein. Cotton isocitrate lyase antibodies were used, and protein immunoblots revealed that the resolution on hydroxylapatite and phenyl-Sepharose allowed for the complete separation of catalase from contaminating isocitrate lyase. The molecular masses of the native enzyme and its subunit are 235 and 59 kD, respectively, indicating that the pine holoenzyme is a homotetramer. Loblolly pine catalase exists as multiple isoforms. When megagametophytes taken 7 d after imbibition at 30[deg]C were extracted, subjected to nondenaturing isoelectric focusing, and stained for catalase activity, at least four catalase isoforms were observed, including one dominant form with an isoelectric point of 6.87. Purified pine catalase is not a glycoprotein and has a ratio of absorbance at 208 nm to absorbance at 405 nm of 1.5. When probed with loblolly pine catalase antibodies, protein blots of cell-free extracts from megagametophytes of mature, stratified, and germinated loblolly pine seeds, the megagametophyte glyoxysomal fraction, and purified loblolly pine catalase all revealed one immunoreactive 59-kD polypeptide. This indicates that no detectable change in the enzyme's monomeric molecular mass occurs during seed stratification and germination, early seedling growth, and purification.

Heat Shock Proteins in Two Lines of Zea mays L. That Differ in Drought and Heat Resistance.

Synthesis of heat shock proteins (HSPs) in the leaves of a drought- and heat-resistant (line ZPBL 1304), and a drought- and heat-sensitive (line ZPL 389) line of maize (Zea mays L.) was studied under two environmental stress treatments: (a) soil drying and high temperature and (b) high temperature. In the first treatment 13-day-old plants were exposed to 7-day soil drying followed by high temperature stress (45 degrees C), and in the second treatment 20-day-old plants were exposed to high temperature stress (45 degrees C). Second leaves were labeled with [(35)S]methionine. During the labeling period line ZPBL 1304 showed no signs of leaf dehydration under soil drying and high temperature stress conditions. In contrast, line ZPL 389 was dehydrated 23%, as determined by relative water content. Incorporation of [(35)S]methionine into protein was greater in the resistant than in the sensitive line in both treatments. The pattern of synthesis of HSPs in the two lines was similar in treatments 1 and 2. Both lines synthesized a high molecular mass set and a low molecular mass set of HSPs. Proteins from both sets from both lines of maize appeared similar to each other, with respect to the molecular mass. Heated plants of the drought- and heat-resistant line ZPBL 1304 synthesized a band of HSP(s) of approximately 45 kilodaltons which was not found in heated plants of the drought and heat sensitive line ZPL 389. This is the first report on qualitative intraspecific difference in the synthesis of HSPs in maize.

Support perfusion for liver transplantation.

Addenbrooke's Hospital, Cambridge, UK, has had an ongoing orthotopic liver transplant programme since 1968. Various support bypass techniques have been used intermittently since 1977. In 1990 bypass was needed for 38% of adult liver transplants, and bypass standby was provided for a further 25%. Adult liver recipients (high-risk) are selected for bypass in accordance with a number of surgical and anaesthetic criteria in order to maximize patient benefit and minimize risk. Before the start of the operation two cannulae (8 or 10 Fg) are placed into left and right internal jugular veins and/or the left brachial vein for rapid volume replacement. Femoral and portal vein cannulation (16 to 22 Fg) can quickly be achieved for splanchnic venous drainage to a heparin coated Biomedicus bypass system. This technique provides flows of 1.5 to 2.5 litres per minute with modest perfusion pressures (around 120mmHg) and provides adequate surgical venous decompression and circulatory support during the anhepatic phase.

Protein synthetic patterns in immature and mature human oocytes.

A preliminary study of protein synthesis and amino acid transport in human oocytes was initiated. Qualitative patterns or protein synthesis were examined in individual oocytes cultured in medium containing radiolabeled methionine. The protein synthetic profile of immature oocytes, resolved by one-dimensional electrophoresis and fluorography, was observed to change markedly following germinal vesicle breakdown and oocyte maturation. No further differences in the one-dimensional protein synthetic patterns were observed in mature oocytes maintained in culture from 10 hours up to as long as 50 hours. The protein synthetic pattern of follicular cells was observed to be distinct from that of oocytes and was characterized by the predominant synthesis of a polypeptide with Mr = 44,000. Based on the specific activity of the methionine precursor, the absolute rate of synthesis was calculated to be about 50 pg protein/oocyte/hour. Total protein content was measured to be about 150 ng/egg. Competition of methionine uptake by leucine, efflux of radiolabeled methionine from preloaded oocytes into medium containing methionine and uptake of methionine in medium with low sodium ion concentration was observed. These findings are consistent with the presence of an L (leucine-preferring) system for neutral amino acid transport, similar to that in mouse and rabbit eggs. These studies provide basic data for further analysis of oocytes and perhaps preimplantation-stage embryos in the future.

Protein synthesis in mature human oocytes.

As a first step toward understanding control of gene expression in early human development, an analysis of protein synthesis and amino-acid transport in unfertilized mature oocytes was initiated. Qualitative patterns of protein synthesis were examined in individual oocytes cultured in medium containing radiolabeled methionine. No differences in synthetic pattern of proteins, resolved by one-dimensional electrophoresis and fluorography, were observed in oocytes analyzed from times varying from 12 to 52 hr following collection by laparoscopy. Contamination by follicular or corona radiata cells was readily distinguished on the basis of increased relative synthesis of a polypeptide with Mr = 44,000, a dominant product of synthesis in follicular cells. Based on the specific activity of the methionine precursor, the absolute rate of synthesis was measured to be about 50 pg/oocyte/hr, a value higher than in mouse unfertilized eggs. No difference in protein synthetic rate was observed in oocytes analyzed at 12 hr postcollection versus later times up to 50 hr postcollection. Competition of methionine uptake by leucine, efflux of radiolabeled methionine from preloaded oocytes into medium containing methionine and uptake of methionine in medium with low sodium ion concentration was observed. These findings are consistent with the presence of an L (leucine-preferring) system for neutral amino acid transport, similar to that in mouse and rabbit eggs. Total protein was measured to be about 150 ng/oocyte, a value five times that of the mouse. These studies provide basic data for further analysis of oocytes and perhaps preimplantation stage embryos in the future.

Expression of the major heat shock protein (hsp 70) family during early mouse embryo development.

Stress or heat shock proteins (hsp) are synthesized by most cells in response to adverse environmental conditions. In mammalian cells, the major proteins synthesized in response to stress have relative molecular weights (Mr) in the range of 68 to 74 kilodaltons (kD) and are encoded by a small multi-gene family collectively referred to as hsp 70 genes. In unfertilized mouse eggs, no members of the hsp 70 family appear to be synthesized under normal or stressful (heat shock) conditions. At the two-cell stage, two proteins with Mr = 74 kD and Mr = 70 kD are expressed as a consequence of developmentally activated transcription of these hsp 70 genes. No stress-induced synthesis in response to heat shock is observed at this stage. At the eight-cell stage, constitutive synthesis of the 70-kD protein continues, but, as in the two-cell embryo, no heat shock induced synthesis of a novel heat shock protein is observed. By the blastocyst stage, however, an inducible protein with Mr = 68 kD is synthesized in response to heat shock in addition to constitutive synthesis of the 70-kD protein. The constitutively synthesized cognate proteins are coded for by a set of mRNAs about 2,000 nucleotides in length. The induced hsp 68 proteins are coded for by mRNAs of larger size (about 2,600 nucleotides). Only the smaller mRNA class is detectable on Northern blots of RNA extracted from control or heat shock cleavage stage embryos and control blastocysts. As predicted from protein synthetic studies, both classes are resolved in RNA preparations derived from heat-shocked blastocysts.

Synthesis of the crystalloid protein complex in vivo in the endosperm of developing castor bean seeds.

The synthesis of subunit polypeptides of the crystalloid protein complex has been examined in endosperm from developing castor bean (Ricinus communis L. cv Hale) seeds. Pulse-label and -chase studies in vivo have shown that synthesis initially involves the formation of high molecular weight precursors (50 to 60 kilodaltons) comprising peptide-linked acidic and basic polypeptides. Precursor processing involves the posttranslational cleavage of the peptide bond to yield authentic and polypeptides. This processing has a half-life of 35 to 40 minutes and is preceded by a 45- to 60-minute lag period. Both precursor and subunit polypeptides are shown to exhibit similar molecular weight and pI heterogeneity, and this is suggested to be due to the expression of a multigene family.

An analysis of the subunit structure of the crystalloid protein complex from castor bean endosperm.

Chromatographic and electrophoretic studies have shown that the subunits of the crystalloid protein, isolated from mature castor bean (Ricinus communis L. cv Hale) seed endosperm protein bodies, are heterogeneous with molecular weights in the range 49 to 53.5 kilodaltons (kD), and are quantitatively in unequal amounts. Each subunit comprises an alphabeta polypeptide pair which are reduced by 2-mercaptoethanol in two subgroups with molecular weights in the 29 to 34 kD and 20.5 to 23.5 kD ranges. Subunits and corresponding polypeptide pairs are also seen to be heterogeneous in pI following isoelectric focusing. In general, large polypeptides are acidic (pI 4.8-6.2) and small polypeptides basic (pI 7.4-9.4), although overlap of some isoelectric isomers does occur, notably in polypeptides derived from subunits which are quantitatively present in smaller amounts.

Deposition of Matrix and Crystalloid Storage Proteins during Protein Body Development in the Endosperm of Ricinus communis L. cv. Hale Seeds.

Protein bodies within the endosperm of castor bean (Ricinus communis L. cv. Hale) seeds arise from numerous small vacuoles which progressively become filled with storage protein, of which the crystalloid proteins make up approximately 70%. Sodium dodecyl sulfate-polyacrylamide gel electrophoresis (SDS-PAGE) shows that the crystalloids are a family of at least four proteins which reduce to two complementary groups after 2-mercaptoethanol treatment. The matrix, which comprises the remainder, has two major components, the soluble albumins and the lectins. The lectins are the only glycoproteins within the mature protein body. Both cytochemical staining and SDS-PAGE indicate that the synthesis of the crystalloid and the majority of matrix proteins begins some 20 days after pollination. Additionally, the crystalloid proteins are synthesized concurrently, whereas there is temporal variation in the synthesis of matrix proteins.