Plant uptake of 14C-EDTA, 14C-Citrate, and 14C-Histidine from chelator-buffered and conventional hydroponic solutions

Chelator-buffered hydroponic solutions provide low and buffered free-metal concentrations and allow the easy calculation of nutrient species expected in these solutions. Some researchers suspect that the solutions allow plant uptake of chelates and that this uptake explains the failure of the free-ion activity model using these solutions. To determine the amount and method of chelate uptake, swiss chard was grown in solution culture in growth chambers for about three wks and then transferred to solutions containing ¹⁴C-EDTA, ¹⁴C-citrate, or ¹⁴C-L-histidine for a 21-hour assay. Much higher root and shoot ¹⁴C were found from treatments containing metabolites histidine (2706097 shoot Bq ¹⁴C) or citrate (2241953 shoot Bq ¹⁴C) than EDTA (280110 shoot Bq ¹⁴C). Passive transpirational flow could explain all of the EDTA uptake, but active uptake would be required to explain most of the citrate and histidine uptake even assuming some adsorption of ligand bound to roots. Swiss chard grown in solutions with the same total EDTA concentrations, but different amounts of Fe bound to EDTA, had 3-fold differences in root and shoot ¹⁴C concentrations. In a second experiment, swiss chard roots removed more EDTA from solutions containing mostly M-EDTA⁰ than M-EDTA^1- or M-EDTA^2- (288140, 245051, and 192559 Bq ¹⁴C, respectively) suggesting plant selectivity for EDTA and a non-apoplastic route of uptake or an effect resulting from root cell-wall adsorption. Results indicated buffering of metals by ligands allowed some ligand uptake with much more uptake occurring with metabolites citrate and histidine than EDTA. A passive or indiscriminate form of uptake does not appear to explain all EDTA uptake with a selectivity by swiss chard for M-EDTA complexes of lower charge.     

Metabolism of 14C-Chlorobenzilate and 14C-Chloropropylate by Rhodotorula gracilis

Rhodotorula gracilis metabolizes Chlorobenzilate (ethyl 4,4'-dichlorobenzilate) and Chloropropylate (isopropyl 4,4'-dichlorobenzilate) to several metabolites in a basal medium supplemented by sucrose and by several intermediates of the citric acid cycle. Three identified metabolites resulting from the degradation of either acaricide, were 4,4'-dichlorobenzilic acid, 4,4'-dichlorobenzophenone, and carbon dioxide. Chlorobenzilate, i.e., ethyl ester of 4,4'-dichlorobenzilic acid, was more easily hydrolyzed than Chloropropylate, i.e., isopropyl ester of this acid, so that larger amounts of carbon dioxide and 4,4'-dichlorobenzophenone were obtained from Chlorobenzilate degradation. Regardless of acaricides used, longer incubation caused a higher accumulation of 4,4'-dichlorobenzophenone. The probable steps of the degradation pathway are: Chlorobenzilate (or Chloropropylate) --> 4,4'-dichlorobenzilic acid --> 4,4'-dichlorobenzophenone plus carbon dioxide. It appears that the decarboxylation of 4,4'-dichlorobenzilic acid to 4,4'-dichlorobenzophenone was hindered by alpha-ketoglutarate and enhanced by succinate.     

Ring-14 and trisomy 14q in the same child

The case of a male child with three cell lines is described: one cell line with ring chromosome 14, another trisomic for 14q, due to a derived metacentric 14q;14q, and a third one with a normal male karyotype. The clinical findings are compatible with those of the r(14) syndrome.     

CD14 and apoptosis

In addition to its role as a mediator of innate pro-inflammatory responses following bacterial lipopolysaccharide (LPS) binding, the 55kDa glycosyl-phosphatidylinositol-linked macrophage plasma membrane glycoprotein CD14 is now also known to play a role in phagocytic clearance of apoptotic cells. Although apoptotic cell-associated ligand(s) for CD14 await definition, initial findings suggest that ligand binding occurs close to, or at the same site as, LPS binding. Significantly, in contrast to LPS clearance and in keeping with the non-phlogistic nature of apoptosis, CD14-dependent engulfment of apoptotic cells fails to elicit pro-inflammatory cytokine release from macrophages. Therefore CD14 may be regarded as an innate immune receptor both for microbial products—after binding which activates inflammatory responses—and for self components, which either fail to induce, or alternatively actively suppress, inflammatory responses. Here we review current knowledge of the structure and functions of CD14, its ligands, its possible modes of signal transduction and its place in the panoply of macrophage molecules implicated in apoptotic-cell clearance.     

GALNT14与肿瘤

在过去的一个多世纪,许多肿瘤标志物被发现,其中包括多肽N-乙酰半乳糖胺基转移酶(polypeptide N-acetylgalactosaminyltransferase,ppGALNAc-T,简称GALNT)家族中的多个成员。GALNT家族是催化黏蛋白O-糖基化修饰的起始酶,其能够影响黏蛋白的O-糖基化,从而影响肿瘤细胞的发生、预后、增殖与迁移等。GALNT14是该家族中最新发现的成员之一,近年的研究发现,GALNT14在多种肿瘤中表达异常,并与肿瘤细胞的发生、侵袭、转移和凋亡等有关。本文主要对GALNT14蛋白的结构特点及其在肿瘤中的作用进行综述,为进一步研究GALNT14与肿瘤发病机制的关系以及作为潜在的药物靶点提供参考。     

Electric birefringence of recombinant spectrin segments 14, 14-15, 14-16, and 14-17 from Drosophila alpha-spectrin

Members of the spectrin protein family can be found in many different cells and organisms. In all cases studied, the major functional role of these proteins is believed to be structural rather than enzymatic. All spectrin proteins are highly elongated and consist mainly of homologous repeats that constitute rigid segments connected in tandem. It is commonly believed that the details of the spectrin function depend critically on the flexibility of the links between the segments. Here we report on a work addressing this question by studying the transient electric birefringence of recombinant spectrin fragments consisting of segments 14, 14-15, 14-16, and 14-17, respectively, from Drosophila alpha-spectrin. Transient electric birefringence depends sharply on both molecular length and flexibility. We found that the birefringence relaxation time of segment 14 measured at 4 degrees C, but scaled to what is expected at 20 degrees C, equals 16 ns (+/-15%) at pH 7.5 and ionic strength 6 mM. This is consistent with this single segment being rigid, 5 nm long and having an axial ratio equal to about two. Under the same conditions, segments 14-15, 14-16 and 14-17 show relaxation times of 45, 39 and 164 ns (all +/-20%), respectively, scaled to what is expected at 20 degrees C. When the temperature is increased to 37 degrees C the main relaxation time for each of these multisegment fragments, scaled to what is expected at 20 degrees C, increased to 46, 80, and 229 ns (all +/-20%), respectively. When the ionic strength and the Debye shielding is low, the dynamics of these short fragments even at physiological temperature is nearly the same as for fully extended weakly bending rods with the same lengths and axial ratios. When the ionic strength is increased to 85 mM, the main relaxation time for each of these multisegment fragments is reduced 20-50% which suggests that at physiological salt and temperature conditions the links in 2-4-segment-long fragments exhibit significant thermally induced flexing. Provided that the recombinant spectrin fragments can serve as a model for native spectrin, this implies that, at physiological conditions, the overall conformational dynamics of a native spectrin protein containing 20-40 segments equals that of a flexible polymer.     

Mammalian Pex14p: membrane topology and characterisation of the Pex14p-Pex14p interaction

Peroxisomal biogenesis is a complex process requiring the action of numerous peroxins. One central component of this machinery is Pex14p, an intrinsic peroxisomal membrane protein probably involved in the docking of Pex5p, the receptor for PTS1-containing proteins (peroxisomal targeting signal 1-containing proteins). In this work the membrane topology of mammalian Pex14p was studied. Using a combination of protease protection assays and CNBr cleavage, we show that the first 130 amino acid residues of Pex14p are highly protected from exogenously added proteases by the peroxisomal membrane itself. Data indicating that this domain is responsible for the strong interaction of Pex14p with the organelle membrane are presented. All the other Pex14p amino acid residues are exposed to the cytosol. The properties of recombinant human Pex14p were also characterised. Heterologous expressed Pex14p was found to be a homopolymer of variable stoichiometry. Finally, in vitro binding assays indicate that homopolymerisation of Pex14p involves a domain comprising amino acid residues 147-278 of this peroxin.     

New data on clonal anomalies of chromosome 14 in ataxia telangiectasia: tct (14;14) and inv(14)

Summary From a series of 53 patients with ataxia telangiectasia, two large clones with a t tan or tct(14;14) and two with an inv(14) were observed among phytohaemagglutinin (PHA)-stimulated lymphocytes. Smaller clones with the same inv(14) were observed in two other cases. Similar breakpoints may exist, both for t(14;14) and inv(14): q11.1/q11.2 and q32, and it is postulated that the rearrangements are related to a recombination of the -chain of the T-cell receptor and IgH clusters of genes.     

Assimilative Pathway of Methanol in Candida sp. Incorporation of 14C-Methanol, 14C-Formaldehyde, 14C-Formate and 14C-Bicarbonate into Cell Constituents

1. The incorporation of ¹⁴C-methanol, ¹⁴C-formaldehyde, ¹⁴C-formate and ¹⁴C-bicarbonate into a methanol-utilizing yeast, Candida N–16, was examined by paper-chromato-graphy and radioautography.

2. At the earliest time period examined, the highest percentage of radioactivity fixed from ¹⁴C-methanol or ¹⁴C-formaIdehyde into methanol-grown cells was found in fructose phosphate. The percentage distribution of radioactivity in fructose phosphate decreased as time elapsed. The radioactivity fixed from these compounds into glucose-grown cells was negligible compared with that fixed into methanol-grown cells.

3. The incorporation of ¹⁴C-formate into methanol-grown cells was extremely low. The highest percentage of radioactivity fixed for short time incubation was found in serine. The incorporation pattern of glucose-grown cells was similar to that of methanol-grown cells.

4. At the earliest time period, over 70% of radioactivity fixed from ¹⁴C-bicarbonate into methanol- or glucose-grown cells was found in aspartate.

5. These results suggest that in Candida N–16 methanol is specifically assimilated by a route with hexose phosphate as a primary stable intermediate.

     

Storage Pools and Turnover Systems in Growing and Non-growing Cells: Experiments with 14C-Sucrose, 14C-Glutamine, and 14C-Asparagine

¹⁴C-labelled sucrose, glutamine, and asparagine have been suppliedto aseptically cultured carrot explants that either grew rapidlyby cell division or, by contrast, only slowly by cell expansion.The radioactive substrates were supplied in a brief ‘pulse’followed by a much longer period during which the tissues weresupplied with ¹²C-substrates. The passage of ¹⁴C through thevarious soluble compounds of the tissue and into the proteinwas followed. Alternatively, the ¹⁴C-labelled compound was suppliedthroughout the entire period of an experiment while the tissuealso received ¹²C-sucrose. The pulse-labelling experiments demonstrateturnover and the fate of the breakdown products, as well asthe emphasis placed on this kind of metabolism by cells at differentlevels of activity in their growth. The long-term labellingexperiments show the different ways in which carbon from varioussources may be used and how these pathways are affected by growth.The amount of ¹⁴C present in the various free (ethanol soluble)and combined (ethanol insoluble, acid-hydrolysable compounds—proteins)was determined, as well as the specific activity of the carbonin each compound. The fate of ¹⁴C supplied as sucrose had muchin common with ¹⁴C supplied as glutamine, with respect to theease with which it entered both the protein being synthesizedand the carbon dioxide evolved, but it was very different from¹⁴C supplied as asparagine. To interpret these data, compartmentsor pools of metabolites are postulated in the organized cell;exogenous ¹⁴C-sucrose and ¹⁴C-glutamine readily furnish carbonfor pools of amino-acids en route to protein, which are protectedfrom both the stored compounds and those which arise after proteinbreakdown. However, exogenous ¹⁴C-asparagine enters, is accumulated,and persists in the pool of stored compounds which also receivethe nitrogen-rich substances that arise from protein breakdown.The kinetic data and the specific activities of the carbon inits various forms require that protein breakdown and re-synthesisoccur concomitantly, that the stimulus to grow, exerted by coconutmilk, accentuates protein synthesis and also the pace of itsturnover, that some respired carbon dioxide arises from protein,and that this moiety of the respiration is increased by thecoconut-milk stimulus as it accentuates the pace of cyclicalturnover. In similar experiments with free cells from differentplants, the same general conclusions apply, but the rates ofturnover of protein are greater in free cells than in tissueexplants. Some specific differences, however, exist. Cells ofArachis, the only legume investigated, permit ¹⁴C-asparagineto contribute, like ¹⁴C-glutamine, to both protein synthesisand respired ¹⁴CO₂; it is not merely segregated in a storagepool. Thus, by virtue of their organization, plant cells maintainthe same substances simultaneously in distinct phases or compartments,where they play distinctive roles, without mingling. Geneticsendows each cell with the information that makes its biochemicalreactions feasible; the organization of the cells determineshow far the feasible becomes practised in cells in any givensituation.     

Comparative diffusion of 14C-ethionine and 14C-methionine in rat tissue]

The pancreas is the tissue which traps the most intensively the trace-dosis injected ethionine -14C; 30 min after the injection, the pancreas fixes the labelled product twice more than the liver and five times more than the stomach. This trapping might explain the pancreatic modifications occuring during the intoxication. In the same experimental conditions, the pancreas fixes the ethionine -14C twice less than methionine. Urinary excretion of ethionine is faster and more important than that of methionine.     

Preparation of L-tyrosine-ring- 14 C, L-DOPA-ring- 14 C and related metabolites

The reversibility of the tyrosine phenol-lyase reaction has been utilized to develop a simple system in which phenol-¹⁴C is incorporated into l-tyrosine in high yield. By use of mushroom tyrosinase, catechol-¹⁴C can be prepared from phenol-¹⁴C and l-DOPA-¹⁴C from l-tyrosine-¹⁴C. Catechol-¹⁴C can also be incorporated into l-DOPA-¹⁴C by use of tyrosine phenol-lyase, giving the possibility of preparing DOPA with two labeling patterns in the ring when starting with phenol-¹⁴C. Two further tyrosine metabolites, para-coumaric acid and homogentisic acid, have also been enzymatically prepared with ¹⁴C in the ring.