Function of the delipidated beta-adrenergic receptor appears to require a fatty acid or a neutral lipid in addition to phospholipids

Detergent-solubilized preparations of the beta-adrenergic receptor (R) and of the guanyl nucleotide binding proteins (Gs) were extensively treated to remove phospholipids and cholesterol. Reconstitution of an R-Gs system was subsequently performed in the presence of a mixture of natural phosphatidylethanolamine, phosphatidylcholine and phosphatidylserine or the synthetic dioleoyl derivatives of the same phospholipids. In both cases, an additional lipid was required for the agonist-dependent activation of Gs. The requirement could be fulfilled by alpha-tocopherol, or by unsaturated fatty acids such as oleic acid. Inclusion of this non-phosphorylated lipid in the reconstituted system enhanced the isoproterenol-dependent activation of Gs by guanosine 5'-O-[gamma-thio]triphosphate 16-33-fold. The rate of activation was largely dependent on the addition of the agonist. Efficient functional reconstitution of R-Gs was thus achieved in a totally defined lipid system. Additional studies of the reconstituted system and of the native membrane led to the notion that the non-phosphorylated lipid plays a role in the function of the hormone-R complex.     

Molecular mechanisms of hormone controlled gene expression in the breast

In a meritorious effort H. de Rothschild compiled in 1899 all publications on mammary gland development and milk – a grand total of 8375 [1]. In the preface to this publication Duclaux states: ‘Such a discrepancy between the tremendous efforts and the paltriness of the results – hundreds of scientists and thousands of research years, just to create 200 or 300 pages of truth’. The number of papers added since then must be enormous. Rather than reviewing a vast literature, I will take the liberty and focus on research which, in my opinion, shaped our understanding of hormone controlled gene expression in the developing breast. This revised version was published online in August 2006 with corrections to the Cover Date.     

Indole-3-ethanol oxidase in Phycomyces blakesleeanus. Is indole-3-ethanol a “storage pool” for IAA?

Indole-3-ethanol (IEt) was extracted from Phycomyces blakesleeanus Bgff. and purified by TLC and HPLC. Identification was performed by mass spectrum. The HPLC-purified compound showed an UV-spectrum typical for indoles, with absorption maxima at 220 and 281 nm. The IEt content varied between 1.5 nmol (g fresh weight)⁻¹ and 5.6 nmol (g fresh weight)⁻¹. The observed variations were strongly correlated with certain developmental stages of the fungus. Furthermore, the decrease of IEt between 60 and 84 h of fungal development coincides with a high IEt oxidase activity. The product of the enzyme reaction was indole-3-acetaldehyde, which was identified by co-chromatography with an authentic standard in several TLC and HPLC systems and by chemical conversion to indole-3-acetaldoxime.     

Spontaneous epimerization of (S)-deoxycoformycin and interaction of (R)-deoxycoformycin, (S)-deoxycoformycin, and 8-ketodeoxycoformycin with adenosine deaminase

(R)-Deoxycoformycin (pentostatin), (S)-deoxycoformycin, and 8-ketodeoxycoformycin were compared as inhibitors of calf intestine adenosine deaminase. In contrast to (R)-deoxycoformycin, which had been demonstrated as a tight-binding inhibitor with a dissociation constant of 2.5 X 10(-12) M [Agarwal, R. P., Spector, T., & Parks, R. E., Jr. (1977) Biochem. Pharmacol. 26, 359-367], (S)-deoxycoformycin and 8-ketodeoxycoformycin are slope-linear competitive inhibitors with respect to adenosine. The kinetic constants are 33 microM for inhibition by (S)-deoxycoformycin, 43 microM for 8-ketodeoxycoformycin, and 16 microM for the Km for adenosine. The stereochemistry of carbon 8 of the diazepine ring therefore causes a (1.3 X 10(7]-fold change in the affinity for the enzyme which is specific for the R configuration. This difference is attributed to an induced conformational change which cannot be initiated by the S isomer or the 8-keto analogue of (R)-deoxycoformycin. The studies were complicated by the need to remove traces of tight-binding inhibitor(s) from (S)-deoxycoformycin, since as little as 0.001% of the R isomer causes significant inhibition. The R and S isomers of deoxycoformycin are unstable in neutral or mildly acidic aqueous solutions. Isomerization of the secondary hydroxyl at carbon 8 of the diazepine ring is one of the reactions, resulting in S to R and R to S conversions for deoxycoformycins. Opening of the aglycon is also a major reaction. The tight-binding inhibitor generated from (S)-deoxycoformycin was identified as (R)-deoxycoformycin by high-pressure liquid chromatography, spectroscopy, circular dichroism, and chemical criteria.(ABSTRACT TRUNCATED AT 250 WORDS)     

Two-dimensional electron microscopic analysis of the chalice form of phosphorylase kinase

Phosphorylase kinase (Mr 1.3 X 10(6], a Ca2+-calmodulin-dependent protein kinase, plays a key role in the initiation of glycogenolysis. After purification on hydroxylapatite, the negatively stained enzyme was used for electron microscopy. In electron micrographs, phosphorylase kinase shows two major molecular forms: a butterfly form (approx. 60%) and a chalice form (approx. 40%). Images of the chalice form of the enzyme were computer-averaged by the method of single particle averaging. The following apparent molecular dimensions were obtained from the averages: total height, 20 nm; maximal width, 18 nm. The chalice form of phosphorylase kinase consists of a major structure termed the cup (11 nm X 18 nm), containing a large accessible cleft, and a minor structure termed the stem (8 nm X 9 nm). A closer examination of the images by averaging of molecular parts revealed two subpopulations of the cup part: a flexed (closed) type and an extended (open) type. The orifice, which can be closed partly by two protrusions (I, I'), is about 6 nm wide when the protrusions are flexed and 9 nm wide when they are extended. It is suggested that the substrates, e.g. phosphorylase b, may be accommodated in the large cleft of the enzyme. While the orientation of the protrusions (I, I') is the most obvious difference between the two types, more structural differences can be detected, suggesting a concerted movement of the protein domains against each other.     

Evidence for an association between calmodulin and membrane patches containing gonadotropin-releasing hormone — receptor complexes in cultured gonadotropes

Summary Participation of calmodulin, clathrin, and actin in receptor mediated endocytosis of gonadotropin-releasing hormone (GnRH) was studied in an in vitro system of dispersed pituitary cells with a triple staining procedure. Cells were incubated in D-Lys⁶-Pro⁹-Des¹⁰-GnRH-biotin and stained with avidin-peroxidase-diaminobenzidine. Calmodulin, clathrin, and actin as well as luteinizing hormone were identified by indirect immunofluorescence with FITC- and rhodamine-labeled second antibody. The results indicate a close spatial association of calmodulin, but not of clathrin and actin, with GnRH-containing plasma membrane patches.Supported by PHS grants NIH NS1761401, HS 09914, and HD 19899     

Synthesis and characterization of lipid-linked mannosyl oligosaccharides in Volvox carteri f. nagariensis

Particulate membrane fractions from Volvox carteri catalyze the transfer of mannose from GDP-mannose to dolichyl diphosphate-[¹⁴C]chitobiose to form lipid-linked oligosaccharides up to a dolichyl diphospnate-chitobiose-(mannose)₅ structure. Mannosylation of the chitobiosyl lipid requires divalent cations and detergents as solubilizing agents. Depending on the nature of the detergent, the oligosaccharide pattern differs markedly: With deoxycholate or the zwitterionic detergent 314 a lipid-linked trisaccharide accumulates. The nonionic Triton X-100, however, gives rise to a spectrum of compounds up to a heptasaccharide. Enzyme digestion of the tri- and pentasaccharide structure, obtained after mild acid hydrolysis of the corresponding [¹⁴C]glycolipids, revealed that the first mannose is bound via a β-glycosidic linkage to the chitobiosyl core, whereas the outer mannose residues are linked as α-mannosides. Our studies indicate that, in agreement with recent findings in other organisms, the innermost α-mannosidic residues are donated directly from GDP-mannose. The structure of oligosaccharides synthesized by Volvox membranes is thus consistent with results from other eucaryotic species, suggesting a common pathway of N-glycosylation of glycoproteins.     

Nuclear magnetic resonance studies of amino acids and proteins. Rotational correlation times of proteins by deuterium nuclear magnetic resonance spectroscopy

We show that measurement of the spin-lattice (T1) and spin-spin (T2) relaxation times (or line widths) of irrotationally bound 2H nuclei in macromolecules undergoing isotropic rotational motion outside of the extreme narrowing limit (i.e., for the case omega 02 tau R2 much greater than 1) permits determination of both the rotational correlation time (tau R) of the macromolecule and the electric quadrupole coupling constant (e2qQ/h) of the 2H label. The technique has the advantage over 13C nuclear magnetic resonance (NMR) that no assumptions about bond lengths (which appear to the sixth power in 13C relaxation studies) or relaxation mechanisms need to be made, since relaxation will always be quadrupolar, even for aromatic residues at high field. Asymmetry parameter (eta) uncertainties are shown to cause negligible effects on tau R determinations, and in any case it is shown that both e2qQ/h and eta may readily be determined in separate solid-state experiments. By way of example, we report 2H NMR results on aqueous lysozyme (EC 3.2.1.17) at 5.2 and 8.5 T (corresponding to 2H-resonance frequencies of 34 and 55 MHz). Interpretation of the results in terms of the isotropic rigid-rotor model yields e2qQ/h values of approximately equal to 170 or approximately equal to 190 kHz, respectively, for the imidazolium and free-base forms of [epsilon 1-2H] His-15 lysozyme in solution, in excellent agreement with e2qQ/h values of approximately 167 and approximately 190 kHz obtained for the free amino acids in the solid state. In principle, the method may in suitable cases permit comparison between the dynamic structures of proteins in solution and in the crystalline solid state.