Biological Activities of the Methyl Ester of Gibberellin A73, a Novel and Principal Antheridiogen in Lygodium japonicum

The synthetic methyl ester of GA₇₃ (GA₇₃-Me) and the naturalantheridiogen of Lygodium japonicum showed almost the same activityto induce the formation of antheridia in dark-grown protonemataof L. japonicum at concentrations of 10^-14 M and higher. Thus,it appears that the principal antheridiogen in L. japonicumis GA₇₃-Me. GA₇₃-Me inhibited formation of ar-chegonia in light-grownprothallia of L. japonicum at concentrations of 10^-11 M andhigher and induced germination of spores in the dark in thisspecies at the same range of concentrations. GA₇₃(free acidform) promoted growth of seedlings of dwarf rice and hypocotylsof cucumber seedlings at dosages of and above 1 and 100 ng/plant,respectively. Eight compounds related to GA₇₃-Me, includingantheridiogens of Anemia phyllitidis and Anemia mexicana, wereactive in inducing an-theridial formation in L. japonicum, althoughtheir activities were considerably lower than that of GA₇₃-Me. (Received August 24, 1988; Accepted November 28, 1988)     

Experimental production of transgenic mice carrying human beta-globin genes

To produce transgenic mice carrying human beta-globin genes, we introduced the following two constructs of the genes to male pronuclei of fertilized mouse eggs: 4.4 kb Pst I/Pst I sequences of the human beta-globin gene (experiment 1) and the human beta-globin gene cluster (cosHG 28) containing G gamma, A gamma, delta and beta-globin genes and cosmid vector pJB8 (37.5 kb, experiment 2). In experiment 1, 25 mice were born, and four (one female and three males) carrying the injected gene sequences were identified. One of these mice carried the entire sequence of the human beta-globin gene but three others appeared to carry only a part of the entire sequence. The mouse with the entire sequence showed a slight increase in the minor component of the mouse beta-globin chain in the same position as the human beta-globin chain. In experiment 2, 61 mice were born, and nine (three females and six males) carried the sequences of the injected gene. However, from DNA analysis, no appropriate sequences present within the A gamma- or beta-globin gene were identified in any of the founder mice. In this case, DNA fragments of the gene cluster that were digested in the mouse nucleus after microinjection of the gene might be integrated into host DNA.     

Identification of the structures of multiple subspecies of protein kinase C expressed in rat brain

Synthesis and processing of radiolabelled rat insulin I and II were studied by pulse-labelling freshly isolated rat islets with [3H]leucine and chasing in 2 mM glucose for up to 270 min (which minimized insulin secretion, less than 1%/h). Islet samples were taken during the chase period and analyzed for their rat insulin I and II content by high-performance liquid chromatography. Prior to 60 min chase rat insulin I accounted for greater than 85% of the radiolabelled insulin present. With longer periods of chase, the relative percentage of rat insulin II progressively increased so that by completion of proinsulin to insulin processing the two labelled rat insulins were present in the same proportion as the relative immunoreactive content, approx. 60:40% insulin I/insulin II. Thus, although islets synthesize the two insulins in proportion to their relative immunoreactive content, rat insulin I and II are processed with different kinetics.     

Identification of Antheridic Acid as an Antheridiogen in Anemia rotundifolia and Anemia flexuosa

Antheridic acid was identified by retention time and full massspectra from GCMS analysis as an antheridiogen in Anemia rotundifoliaand A. flexuosa. In the dark spore germination assay, antheridicacid was active down to 10^–10 and 5 ? 10^–12g.ml^–1in A. rotundifolia and A.flexuosa, respectively. In the antheridiumformation assay, antheridic acid was active down to 10^–10g.ml^–1 in both A. rotundifolia and A.flexuosa (Received April 14, 1987; Accepted July 8, 1987)     

Multiple forms of cytochrome P-450 from kidney cortex microsomes of rabbits treated with phenobarbital

Two distinct forms of cytochrome P-450 (P-450), referred to as P-450a and P-450b, were separated and purified from kidney cortex microsomes of rabbits treated with phenobarbital. P-450a had a monomeric molecular weight of 53,000, and its CO-reduced difference spectral peak was at 450 nm. It catalyzed the omega-hydroxylation of prostaglandin A1 (PGA1), and the omega- and (omega-1)-hydroxylation of myristate, but it was inactive toward exogenous compounds tested. On the other hand, P-450b had a monomeric molecular weight of 49,000, and its CO-reduced difference spectral peak was at 451 nm. This cytochrome was not able to hydroxylate PGA1 at all. It hydroxylated myristate much more slowly than P-450a, and preferentially at the (omega-1)-position. Unlike P-450a, P-450b efficiently metabolized exogenous compounds such as benzphetamine, aminopyrine, 7-ethoxycoumarin and p-nitroanisole. It is suggested that P-450a and P-450b are specialized for the metabolism of PGA1 and exogenous compounds, respectively, in kidney cortex microsomes.     

Extraadrenal expression of steroid 21-hydroxylase and 11β-hydroxylase by a benign testicular leydig cell tumor

We present an unusual case with bilateral testicular Leydig cell tumors displaying extraadrenal expression of steroid 21-hydroxylase and 11β-hydroxylase. Histological examination of a 38-yr-old man infertile due to azoospermia showed him to have bilateral testicular Leydig cell tumors. The in vitro steroidogenic potential of the tumors and their adjacent testicular tissue was evaluated using organ culture. Tumor tissue was found to secrete deoxycorticosterone (DOC), corticosterone (B) and cortisol, which are not produced in normal adult testis, into the medium, while testicular tissue adjacent to the tumors secreted a small amount of DOC and B. Northern blot analysis with cytochrome P-450_C21 complementary DNA (cDNA) and P-450_11β cDNA as probes revealed that the tumor contained a considerable amount of mRNA for P-450_C21 and P-450_11β, while the mRNAs were not detected in the testicular tissues adjacent to the tumors. It is suggested that the high local levels of estrogen and/or progesterone within the Leydig cell tumors and their adjacent testicular tissues induced extraadrenal expression of steroid 21-hydroxylase and 11β-hydroxylase by the tumors and their adjacent testicular tissues.     

Electrophoretic analysis of pancreatic proteases and zymogen-activating factors in the mouse

Mouse pancreatic proteases were analyzed by one- and two-dimensional electrophoresis. Active proteases that existed in the luminal fluid were separated into at least eight bands in 8% polyacrylamide gel. Pancreatic proteases activated by intestinal extract were separated into at least seven bands. The mobilities of these bands were exactly the same as those of proteases in the luminal fluid except for those of the most cathodal band. Two kinds of trypsin (Try-I group and Try-II) and one kind of chymotrypsin (Chy-I) were determined by specific and nonspecific protease staining. Try-I group and Try-II were derived from different trypsinogens (Try G-I group and Try G-II), whereas Chy-I was derived from a single chymotrypsinogen (Chy G). Although Try G-II was activated by both intestinal extract and by bovine trypsin, Try G-I group activated only by intestinal extract. Intestinal-activating factors were analyzed by two-dimensional electrophoresis. Mouse enterokinase (enteropeptidase EC 3.4.4.8), which can activate bovine trypsinogen, had a slow mobility. In the intestine of the mouse there are several activating factors in addition to enterokinase. Although it is unclear what intestinal-activating factors can activate Chy G, there is a factor that can convert chymotrypsinogen into chymotrypsin directly. These data suggest that intestinal-activating factors play an important role in the activating mechanisms of mouse pancreatic zymogens.     

Characterization of protein kinase C from normal and transformed cultured murine fibroblasts

Protein kinase C of normal and ras-transformed NIH 3T3 cells was purified by chromatography on TSK DEAE-5PW, threonine-Sepharose, and TSK phenyl-5PW columns. Comparison of the fibroblast enzyme with several types of rat brain protein kinase C by chromatography on a hydroxyapatite column and by immunoblotting, indicates that both normal and transformed fibroblasts possess only one of the four subspecies of protein kinase C which have been identified in brain tissues. This subspecies presumably has the structure encoded by alpha-sequence or a closely related sequence. No significant difference was seen between those enzymes purified from normal and transformed fibroblasts.     

Structure of a New Nor-kaurenolide from Gibberella fujikuroi

A novel metabolite from Gibberella fujikuroi was isolated and its structure was elucidated as 4β,7β-dihydroxy-18-norkaurenolide (I).     

Catalytic properties of yeast protein kinase C: difference between the yeast and mammalian enzymes.

With bovine myelin basic protein as a model common substrate, protein kinases C (PKC) purified from yeast (Saccharomyces cerevisiae) and mammalian tissue (rat brain) were shown to exhibit clearly different catalytic properties. The major sites of phosphorylation in bovine myelin basic protein by the yeast PKC were identified: Thr-19, Thr-34, and Thr-65. These sites are distinctly different from those for the mammalian PKC: Ser-8, Ser-46, Ser-55, Ser-110, Ser-132, Ser-151, and Ser-161, which were previously identified [Kishimoto, A., Nishiyama, K., Nakanishi, H., Uratsuji, Y., Nomura, H., Takeyama, Y., & Nishizuka, Y. (1985) J. Biol. Chem. 160, 12492-12499]. The results suggest that the yeast and mammalian enzymes may play distinct roles in cellular regulation. No evidence is available, however, that a yeast-type PKC exists in mammalian tissues. An oligopeptide containing the sequence around Thr-19 of bovine myelin basic protein, Lys-Tyr-Leu-Ala-Ser-Ala-Ser-Thr(19)-Met-Asp-His-Ala, can be used as a substrate for selective assaying of the yeast PKC.