9 alpha,11 beta-prostaglandin F2 formation in various bovine tissues. Different isozymes of prostaglandin D2 11-ketoreductase, contribution of prostaglandin F synthetase and its cellular localization

9 alpha,11 beta-prostaglandin F2 was formed from prostaglandin D2 by its 11-ketoreductases in 100,000 x g supernatants of various bovine tissues in the presence of an NADPH-generating system. The reductase activities were high in liver (51.09 nmol/h/mg of protein), lung (24.99), and spleen (14.20); moderate in heart and pancreas (3.09-3.61); weak in stomach, intestine, colon, kidney, uterus, adrenal gland, and thymus (0.11-2.63); and undetectable in brain, retina, carotid artery, and blood (less than 0.10). No formation of prostaglandin F2 alpha from prostaglandin D2 was detected in all tissues. In immunotitration analyses with a polyclonal antibody specific for prostaglandin F synthetase, the reductase activities in lung and spleen showed identical titration curves to that of the purified synthetase and decreased to less than 15% of the initial activity under the condition of antibody excess. Prostaglandin F synthetase-immunoreactive protein in these two tissues showed peptide fingerprints identical to that of the purified enzyme after partial digestion with Staphylococcus aureus V8 protease. The antibody was partially cross-reactive to the reductase in liver (about 20% of that to the synthetase) but not to the reductase(s) in other tissues. The Km value for prostaglandin D2 of the reductase activity was the same in lung and spleen as that of the purified prostaglandin F synthetase (120 microM) but differed in liver (6 microM), heart, and pancreas (15 microM). The predominant distribution of prostaglandin F synthetase in lung and spleen was confirmed by radioimmunoassay (2.8 and 1.0 micrograms/mg protein, respectively) and Northern blot analyses. In immunoperoxidase staining, this enzyme was localized in alveolar interstitial cells and nonciliated epithelial cells in lung, histiocytes and/or dendritic cells in spleen, and a few interstitial cells in kidney and adrenal cortex.     

Biochemical and immunological characterization of rat spleen prostaglandin D synthetase

Rat spleen prostaglandin D synthetase (Christ-Hazelhof, E., and Nugteren, D. H. (1979) Biochim. Biophys. Acta 572, 43-51) is very similar to rat brain prostaglandin D synthetase (Urade, Y., Fujimoto, N., and Hayaishi O. (1985) J. Biol. Chem. 260, 12410-12415) as judged by their pI (4.7-5.2), Mr (26,000-27,000), and self-inactivation during the isomerase reaction from prostaglandin H2 to prostaglandin D2. However, the amino acid compositions of these two enzymes were quite different. Furthermore, the spleen enzyme was associated with the glutathione S-transferase activity, differing from the brain enzyme. The synthetase and transferase activities of the spleen enzyme showed almost identical pH and glutathione dependencies, the optimum pH = 8.0 and Km for glutathione = 300 microM. The Km values for prostaglandin H2 and 1-chloro-2,4-dinitrobenzene (a substrate for the transferase) were about 200 microM and 5 mM, respectively. The synthetase activity was dose-dependently inhibited by 1-chloro-2,4-dinitrobenzene (IC50: approximately 5 mM) and more strongly by nonsubstrate ligands, such as bilirubin and indocyanine green (IC50: 150 and 2 microM, respectively). Both the synthetase and transferase activities of the purified enzyme dose-dependently decreased and showed identical immunotitration curves by incubation with antibody against this enzyme, but remained unchanged when treated with antibody against the brain enzyme. The antibody specific for the spleen enzyme absorbed almost all of the synthetase activity and about 10% of the transferase activity in the spleen, but not the transferase activity in the liver, heart, and testis. These results show that the two types of prostaglandin D synthetase are similar but different enzymes and that the spleen enzyme is a unique glutathione S-transferase differing from other isozymes and their subunits reported previously.     

Primary structure of rat brain prostaglandin D synthetase deduced from cDNA sequence

The amino acid sequence of rat brain prostaglandin D synthetase (Urade, Y., Fujimoto, N., and Hayaishi, O. (1985) J. Biol. Chem. 260, 12410-12415) was determined by a combination of cDNA and protein sequencing. cDNA clones specific for this enzyme were isolated from a lambda gt11 rat brain cDNA expression library. Nucleotide sequence analyses of cloned cDNA inserts revealed that this enzyme consisted of a 564- or 549-base pair open reading frame coding for a 188- or 183-amino acid polypeptide with a Mr of 21,232 or 20,749 starting at the first or second ATG. About 60% of the deduced amino acid sequence was confirmed by partial amino acid sequencing of tryptic peptides of the purified enzyme. The recognition sequence for N-glycosylation was seen at two positions of amino acid residues 51-53 (-Asn-Ser-Ser-) and 78-80 (-Asn-Leu-Thr-) counted from the first Met. Both sites were considered to be glycosylated with carbohydrate chains of Mr 3,000, since two smaller proteins with Mr 23,000 and 20,000 were found during deglycosylation of the purified enzyme (Mr 26,000) with N-glycanase. The prostaglandin D synthetase activity was detected in fusion proteins obtained from lysogens with recombinants coding from 34 and 19 nucleotides upstream and 47 and 77 downstream from the first ATG, indicating that the glycosyl chain and about 20 amino acid residues of N terminus were not essential for the enzyme activity. The amino acid composition of the purified enzyme indicated that about 20 residues of hydrophobic amino acids of the N terminus are post-translationally deleted, probably as a signal peptide. These results, together with the immunocytochemical localization of this enzyme to rough-surfaced endoplasmic reticulum and other nuclear membrane of oligodendrocytes (Urade, Y., Fujimoto, N., Kaneko, T., Konishi, A., Mizuno, N., and Hayaishi, O. (1987) J. Biol. Chem. 262, 15132-15136) suggest that this enzyme is a membrane-associated protein.     

Mast cells contain spleen-type prostaglandin D synthetase

Prostaglandin D synthetase activity in the cytosol (100,000 x g, 1-h supernatant) fraction of peritoneal mast cells of adult rats (105.0 nmol/min/mg protein) was the highest among such activities in various rat tissues and cells. As judged by the absolute requirement for glutathione for the reaction (Km = 300 microM), the Km value for prostaglandin H2 (200 microM), and insensitivity of the activity to 1 mM 1-chloro-2,4-dinitrobenzene, the enzyme in mast cells was similar to rat spleen prostaglandin D synthetase and differed from rat brain prostaglandin D synthetase or glutathione S-transferase, all of which catalyze the isomerase reaction from prostaglandin H2 to prostaglandin D2. In immunotitration analyses, the activity in mast cells showed a titration curve exactly identical with that of the purified spleen-type enzyme and almost completely absorbed by an excess amount of antibody against this enzyme, but it remained unchanged after incubation with antibodies against the brain-type enzyme and glutathione S-transferase isozymes thus far purified. In Western blot after two-dimensional electrophoresis of crude extracts of mast cells, a single immunoreactive spot was observed with antibody against the spleen-type enzyme at the same position as that of the purified enzyme (Mr = 26,000, pI = 5.2). Furthermore, the immunoreactive protein obtained from mast cells showed the same peptide fingerprints as those of the purified spleen-type enzyme, after partial digestion with Staphylococcus aureus V8 protease or trypsin. In immunoperoxidase staining, the immunoreactivity of the spleen-type enzyme was found in the cytosol of tissue mast cells in various organs such as thymus, intestine, stomach, and skin of adult rats. These findings indicate that prostaglandin D2 is produced by the spleen-type synthetase in mast cells of various tissues.     

Identification, expression and tissue distribution of cytidine 5′-monophosphate N-acetylneuraminic acid synthetase activity in the rat

We report the postnatal developmental profiles of N-acetylneuraminic acid cytidylyltransferase (EC 2.7.7.43) (CMP-Neu5Ac synthetase) in different rat tissues. This enzyme, which catalyses the activation of NeuAc to CMP-Neu5Ac, was detected in brain, kidney, heart, spleen, liver, stomach, intestine, lung, thymus, prostate and urinary bladder but not in skeletal muscle. Comparative analysis of the different specific activity profiles obtained shows that the expression of CMP Neu5Ac synthetase is tissue-dependent and does not seem to be embryologically determined. Changes in the level of sialylation during development were also found to be intimately related to variations in the expression of this enzyme, at least in brain, heart, kidney, stomach, intestine and lung.     

Quantitation and immunohistochemical localization of cathepsins E and D in rat tissues and blood cells

The distribution of cathepsins E and D in various rat tissues and blood cells was determined by immunoprecipitation and by immunohistochemistry with discriminative antibodies specific for each enzyme. While cathepsin D was detected in all of the tissues and blood cells tested (except for erythrocytes), cathepsin E had a relatively limited distribution. The cathepsin E content was highest in the stomach and was succeeded in the following order by the urinary bladder, thymus, spleen, cervical lymph node and bone marrow. Significant amounts of cathepsin E were also found in the colon, rectum, jejunum, skin, lung, kidney and submandibular gland. The other tissues tested had little or no detectable cathepsin E content. Of the blood cells tested, lymphocytes and peritoneal neutrophils contained high levels of cathepsin E. Erythrocytes had cathepsin E only as aspartic proteinases. When the subcellular localization of cathepsin E in the neutrophils was investigated by fractionation of the postnuclear supernatants, the enzyme behaved as a soluble cytosolic enzyme. In contrast, cathepsin D was mainly associated with the granular fraction. The immunohistochemical localization of cathepsins E and D was clearly different in the stomach, large intestines, kidney and urinary bladder, but was similar in the lymph node and spleen. The tissue-fixed macrophages, which were notable in the skeletal and cardiac muscle tissues, submucosal layers of the gastrointestinal tracts, salivary gland, lung and trachea, also exhibited similar intense immunoreactivities demonstrative of both cathepsins E and D.     

The enhancer domain of the human cytomegalovirus major immediate-early promoter determines cell type-specific expression in transgenic mice.

The human cytomegalovirus (HCMV) major immediate-early promoter (MIEP) is one of the first promoters to activate upon infection. To examine HCMV MIEP tissue-specific expression, transgenic mice were established containing the lacZ gene regulated by the MIEP (nucleotides -670 to +54). In the transgenic mice, lacZ expression was demonstrated in 19 of 29 tissues tested by histochemical and immunochemical analyses. These tissues included brain, eye, spinal cord, esophagus, stomach, pancreas, kidney, bladder, testis, ovary, spleen, salivary gland, thymus, bone marrow, skin, cartilage, and cardiac, striated and smooth muscles. Although expression was observed in multiple organs, promoter activity was restricted to specific cell types. The cell types which demonstrated HCMV MIEP expression included retinal cells of the eye, ductile cells of the salivary gland, exocrine cells of the pancreas, mucosal cells of the stomach and intestine, neuronal cells of the brain, muscle fibers, thecal cells of the corpus luteum, and Leydig and sperm cells of the testis. These observations indicate that the HCMV MIEP is not a pan-specific promoter and that the majority of expressing tissues correlate with tissues naturally infected by the virus in the human host.     

Postnatal changes in the localization of prostaglandin D synthetase from neurons to oligodendrocytes in the rat brain

Prostaglandin D synthetase (Urade, Y., Fujimoto, N., and Hayaishi, O. (1985) J. Biol. Chem. 260, 12410-12415) in the brain of 2- and 8-week-old rats was biochemically indistinguishable as judged by Mr (26,000), pI values (4.35-4.75), Km for prostaglandin H2 (approximately 20 microM), and requirement of sulfhydryl compounds. Furthermore, the enzyme was immunologically the same at both ages, as judged by immunotitration, Ouchterlony immunodiffusion, and immunoblotting analyses using a polyclonal and two monoclonal antibodies specific for the enzyme. However, the cellular localization of the enzyme was markedly different between the two ages, as examined by immunoperoxidase staining with the specific antibodies. The immunoreactivity was found in many neurons in 2-week-old rats but was not detected in most neurons in 8-week-old rats except for multipolar neurons in layers I-II of the neocortex and several clusters of dendrites in the pyriform cortex. In the adult rat, the immunoreactivity was mainly localized in oligodendrocytes. By immunoelectron microscopy, the immunoreactive deposits were seen in rough-surfaced endoplasmic reticulum and outer nuclear membrane of the glial cells.     

A monoclonal antibody that defines basal cells of stratified epithelia in various human and rabbit tissues

Summary Monoclonal antibodies were produced against monkey lung lavage fluid by using a mouuse hybridoma technique. One monoclonal antibody, KP8D4, specifically reacted with basal cells in human bronchial epithelia by immunohistological staining of acetone-fixed, frozen sections and it recognized a protein with an apparent molecular weight of 84000, as determined by gel immunoblotting. The distribution of this protein was immunohistochemically examined in various human tissues (lung, tongue, esophagus, stomach, intestine, liver, pancreas, salivary gland, spleen, thymus, heart, aorta, vena cava, prostate, breast, kidney, urinary bladder, thyroid, brain, skin, striated muscle) and various tissues of rats, rabbits and pigs. The results showed a specific affinity of KP8D4 to basal cells of stratified epithelia in the various human and rabbit tissues. This antibody may be a useful tool for studies of normal development and diverse pathological disorders.     

A monoclonal antibody that defines basal cells of stratified epithelia in various human and rabbit tissues

Monoclonal antibodies were produced against monkey lung lavage fluid by using a mouse hybridoma technique. One monoclonal antibody, KP8D4, specifically reacted with basal cells in human bronchial epithelia by immunohistological staining of acetone-fixed, frozen sections and it recognized a protein with an apparent molecular weight of 84000, as determined by gel immunoblotting. The distribution of this protein was immunohistochemically examined in various human tissues (lung, tongue, esophagus, stomach, intestine, liver, pancreas, salivary gland, spleen, thymus, heart, aorta, vena cava, prostate, breast, kidney, urinary bladder, thyroid, brain, skin, striated muscle) and various tissues of rats, rabbits and pigs. The results showed a specific affinity of KP8D4 to basal cells of stratified epithelia in the various human and rabbit tissues. This antibody may be a useful tool for studies of normal development and diverse pathological disorders.     

Tartrate-resistant acid phosphatase (Acp 5): identification in diverse human tissues and dendritic cells.

Histochemical demonstration of tartrate-resistant acid phosphatase (TRAP) is used for the specific identification of osteoclasts. The enzyme, which we have shown to be critical for normal bone development in mice, is also characteristic of monohistiocytes, including alveolar macrophages, and is associated with diverse pathological conditions such as Gaucher's disease and hairy cell leukemia. TRAP activity is enhanced in serum when bone resorption is increased, and the activity is used routinely to monitor treatment responses in Gaucher's disease. We have lately shown widespread expression of the enzyme in murine tissues with particular reference to the skin, thymus, gut epithelia, and isolated dendritic cells, suggesting a possible role in immunity. To further clarify the significance of TRAP in human physiology, we have examined its distribution in non-skeletal human tissues and in CD34+ -derived human dendritic cells. TRAP mRNA determined by Northern blotting analysis was expressed abundantly in spleen, liver, colon, lung, small intestine, kidney, stomach, testis, placenta, lymph node, thymus, peripheral blood leukocyte, bone marrow, and fetal liver. Expression of TRAP protein was investigated by immunohistochemistry, with which the enzyme was identified in multiple tissues. Histochemical staining detected enzymatically active protein in spleen, lung, skin, colon, stomach, and ileum. Active TRAP was identified in CD34+ -derived immature dendritic cells and co-localized to intracellular CD63 positive organelles. When these cells were matured by induction with LPS, the TRAP activity increased fivefold and remained within the cell during the phase associated with CD63 surface expression. Our findings demonstrate widespread expression of TRAP in human tissues. Its abundant expression in epithelia and dendritic cells suggests a potential role in antigen processing and in immune responses.     

Tissue distribution of the 1,25-dihydroxyvitamin D3 receptor in the male rat.

Tissue distribution of 1,25-dihydroxyvitamin D3 receptors was studied in male rats using a quantitative immunoradiometric assay. Extracts were prepared from 16 different rat tissues and assayed for 1,25-dihydroxyvitamin D3 receptor. Measurable levels of receptor were detected in intestine, stomach, kidney, bone thyroid/parathyroid, skin, liver, spleen, heart and lung. The highest levels were found in the proximal small intestine and colon, containing over 1000 fmol/mg total protein, while ileum and kidney contained one-half and one-fourth of this amount, respectively. Other parts of the vitamin D endocrine system, including bone, thyroid/parathyroid and skin, contained moderate levels of receptor of 40 to 80 fmol/mg, while lung, heart, stomach, spleen and liver had levels at or below 20 fmol/mg. No 1,25-dihydroxyvitamin D3 receptor was detected in cerebrum, cerebellum or skeletal muscle. The data support a wide-spread role for 1,25-dihydroxyvitamin D3 on cellular processes and suggest a more important role for vitamin D in colon.     

Colorimetric analysis with N,N-dimethyl-p-phenylenediamine of the uptake of intravenously injected horseradish peroxidase by various tissues of the rat

1. A method is described for the colorimetric determination of peroxidase with N,N-dimethyl-p-phenylenediamine. The amount of red pigment formed by peroxidase is proportional to the concentration of enzyme and to the time of incubation during the first 40 to 90 seconds. The influence of the concentration of enzyme, N,N-dimethyl-p-phenylenediamine, H(2)O(2), the time of incubation, pH, the temperature, and the possible interference by oxidizing and reducing agents of tissues has been tested. 2. The method has been used to follow the uptake of intravenously injected horseradish peroxidase by 18 different tissues of the rat over a period of 30 hours. The highest concentration of the injected tracer enzyme was found in extracts of kidney, liver, bone marrow, thymus, and spleen. Considerable amounts were taken up by pancreas, prostate, epididymis, and small intestine. Lower concentrations were found in extracts of lung, stomach, heart, and skeletal muscle, aorta, skin, and connective tissue. No uptake was observed by brain and peripheral nerve tissue. 3. Tissue homogenates containing high concentrations of the injected peroxidase, in general also showed high or average activity of acid phosphatase. 4. Six hours after intravenous administration, the liver contained 27 per cent, the kidney 12 per cent, and the spleen, 1.4 per cent of the injected dose. 5. Approximately 20 per cent of the injected peroxidase was excreted in the urine during the first 6 hours, and the concentration of peroxidase in blood serum and urine fell exponentially during this time. After 6 hours, only low concentrations were excreted in the urine but low enzyme activity was still detectable after 30 hours. Approximately 6 per cent of the injected dose was excreted in the feces from 6 to 20 hours after administration. 6. After feeding through a stomach tube, low concentrations of peroxidase were found in blood serum and urine. Considerable variations in the extent of absorption from the gastrointestinal tract were observed in individual rats.     

Deoxyuridine triphosphate nucleotidohydrolase: distribution of the enzyme in various rat tissues

The distribution of deoxyuridine triphosphate nucleotidohydrolase (dUTPase) [EC 3.6.1.23] in the cytosol of various rat tissues was investigated by measuring the enzyme activity and by immunochemical analyses. Among nine rat tissues, thymus, and spleen showed the highest activities of the enzyme per gram of tissue, while intestine, stomach, lung and liver showed very low levels. Rabbit antibodies directed against purified dUTPase of anemic rat spleen showed reactivity with partially purified dUTPases from other rat tissues such as thymus, testis, or regenerating liver. Immunotitration and immunoblot experiments also indicated that the dUTPases in various rat tissues had very similar antigenicity and apparently the same subunit molecular size (Mr = 19,500), suggesting that the enzyme lacks organ-specificity. Immunoblot analysis of dUTPase protein with crude extracts from various rat tissues showed a similar distribution to that of the enzyme activity. No immuno-reactive band corresponding to the dUTPase was detected in intestine, although intestinal mucosa has been recognized as an actively proliferating tissue.     

Immunochemical characteristics of the peroxidases of several mouse tissues]

Enzymes catalyzing peroxidase reaction of a lysosomal fraction in bone marrow, leucocytes, spleen, thyroid gland, stomach, kidney, heart, lungs, brain and skeletal muscle of mice were investigated by immunochemical methods. A high level of peroxidase activity was discovered in leucocytes, bone marrow, spleen, heart and lung, a lower activity appeared to be characteristic of liver, thyroid gland and kidney. The peroxidase activities in brain, skeletal muscle and stomach were low. The reaction of immunoprecipitation with myeloperoxidase-specific antiserum revealed considerable antigenic distinctions between the enzymes catalysing peroxidase reaction in various tissues of mice.     

版纳微型猪近交系CD46基因克隆、序列及组织表达分析

根据猪NM_213888及EST序列,设计特异引物扩增BMI CD46基因,并进行克隆、测序和生物信息学分析。同时应用半定量RT-PCR技术对BMI 30个重要组织进行表达谱分析。获得了BMI CD46 1 092 bp的编码区序列（Gen Bank登录号：KJ513478）,编码363个氨基酸。分析表明,CD46蛋白质分子量（Mw）为39.60 k D,等电点（p I）为5.39,存在4个保守域和1个跨膜结构域,N端有信号肽序列;其N末端疏水,C末端亲水;亚细胞定位显示,该蛋白位于细胞周质的概率是56.7%。活性位点分析表明,BMI CD46蛋白有6类活性位点。系统进化分析表明,BMI与牛的亲缘关系最近。BMI 30种组织表达分析表明,CD46基因在十二指肠中高表达;在睾丸、胸腺、甲状腺、附睾、肺、淋巴结、空肠、回肠、结肠、小脑及舌下腺中中度表达;在颌下腺、肝、肾上腺、盲肠、直肠、食管、垂体及脑干中低表达;在心、脾、肾、肌肉、胰脏、胃、皮肤、大脑、下丘脑及脊髓中不表达。该结果为进一步研究基因功能奠定基础。     

Distribution of apolipoprotein A-I, C-II, C-III, and E mRNA in fetal human tissues. Time-dependent induction of apolipoprotein E mRNA by cultures of human monocyte-macrophages

Recently developed molecular probes for human apolipoprotein (apo) genes have been used to study the specificity of human tissue expression of the apo A-I, apo C-II, apo C-III, and apo E genes. We have found that apo E mRNA was present in all tissues examined. On the basis of total RNA concentration the relative abundance of apo E mRNA expressed as a percentage of the liver value is as follows: adrenal gland and macrophages, 74-100%; gonads and kidney, 12-15%; spleen, brain, thymus, ovaries, intestine, and pancreas, 3-9%; heart, 1.5%; stomach, striated muscle, and lung, less than 1%. The relative concentration of apo E mRNA in cultures of human peripheral blood monocyte-macrophages increases dramatically as a function of time in culture, and after 5 days, it compares to that of liver. The human tissues shown to synthesize apo E mRNA were also examined for their ability to synthesize apo A-I, apo C-II, and apo C-III mRNA. The relative abundance of apo A-I, apo C-III, and apo C-II mRNA expressed as a percentage of the liver value is as follows: apo A-I, intestine, 50%; apo A-I, pancreas and gonads, 12%; apo A-I, kidney, 4%; apo A-I, adrenal, 2.5%; apo A-I, ovaries and heart, 1%; apo A-I, stomach and thymus, less than 1%; apo C-III, intestine, 62%; apo C-III, pancreas, 7%; apo C-II, intestine, 3%; apo C-II, pancreas, less than 1%. The knowledge of tissue specificities in the synthesis of apolipoproteins is important for our understanding of the regulation of apolipoproteins and lipoprotein metabolism.     

肝细胞生长因子mRNA在成年小鼠和人胎儿不同器官中的表达

本实验从成年小鼠和胎龄４－５月的人胎儿不同器官中分离总ＲＮＡ。经斑点印迹分析显示,肝细胞生长因子（ＨＧＦ）ｍＲＮＡ在成年ＫＭ小鼠多种器官中表达,其表达水平由高到低依次为：肺、肝、肾、卵巢、睾丸、大脑和胃;在脾、心、骨髓、小肠和骨骼肌组织中以ＨＧＦｍＲＮＡ。在胎龄４－５月的人胎儿中,ＨＧＦｍＲＮＡ表达水平由高到低依次为：大脑、肝、腮腺、胃、小肠、肾、心和骨骼肌;肺和脾组织为阴性。由此可见,ＨＧＦ在成     

Glutamine synthetase activity in the organs of fed and 24-hours fasted rats

Glutamine synthetase activity in several rat tissues had been measured. Liver contains the highest specific activity followed by stomach, brain, kidneys, intestine, skin, adipose tissue and striated muscle - that had the lowest specific activity both with regard to tissue, protein and DNA weight. Per unit of animal weight, liver and muscle contain similar activities, 24 Hours of fasting induced a significant decrease in liver, stomach, intestine and skin glutamine synthetase, compensated by an increase in muscle activity. During fasting, the splanchnic glutamine synthetase activity is lowered and that of peripheral tissues is increased, thus favoring a net glutamine flux from peripheral to splanchnic organs.     

白芍总苷在正常大鼠体内的组织分布研究

探讨白芍总苷在正常大鼠体内的组织分布特点,为预测其药理作用及不良反应提供依据.正常大鼠按2.82 g/kg灌胃给予TGP药液后1、3、6h取心、肝、脾、肺、肾、胃、小肠、大肠等组织,各组织匀浆后,将匀浆液制成冻干粉,HPLC法测定冻干粉中芍药苷和芍药内酯苷浓度,计算各组织中两者浓度.结果显示1h各组织中均能测到芍药苷和芍药内酯苷,3h除胃和小肠外,其他各组织中两者浓度均达到最大值,小肠、胃、大肠及肾、脾、肝中浓度较高,6h小肠、大肠、胃中浓度较高,其他各组织中浓度较低.说明灌胃TGP后组织分布迅速且广泛,胃、小肠、大肠及肾、脾、肝是主要分布器官,容易在胃肠蓄积,其他组织中蓄积较少,为进一步研究白芍总苷的药理作用及作用机理提供了指导,同时为白芍归经理论提供了一定的现代科学依据.