Temperature- and acceptor-specificity of cell-free vesicular transfer from transitional endoplasmic reticulum to the cis Golgi apparatus.

The temperature dependence and specificity of transfer of membrane constituents from donor transitional endoplasmic reticulum to the cis Golgi apparatus were investigated using a cell-free system from rat liver. The radiolabelled transitional endoplasmic reticulum donors were prepared from slices of rat liver prelabelled with [14C]leucine. The acceptor Golgi apparatus elements were unlabelled and immobilized on nitrocellulose. When Golgi apparatus stacks were separated by preparative free-flow electrophoresis into subfractions enriched in cisternae derived from the cis, medial and trans portions of the stack respectively, efficient specific transfer was observed only to cis elements. Trans elements were devoid of specific acceptor capacity. Similarly, when transfer was determined as a function of temperature, a transition was observed in transfer activity between 12 degrees C and 18 degrees C similar to that seen in vivo for formation of the so-called 16 degrees C cis Golgi-located membrane compartment. Transfer at temperatures below 16 degrees C and transfer to trans Golgi apparatus compartments at temperatures either above or below 16 degrees C was similar and unspecific. The unspecific transfer at low temperature was pH independent, whereas specific transfer was greatest at the physiological pH of 7, and was reduced to 10% and 18% of that occurring at pH 8 and pH 5.5 respectively. These findings show that the cell-free system derived from rat liver exhibits a high degree of fidelity to transfer in vivo, an efficiency approaching that observed in vivo, and a nearly absolute acceptor specificity for cis Golgi apparatus. The acceptor-, temperature- and pH-specificity of the cell-free transfer, as well as the saturation kinetics exhibited with respect to acceptor Golgi apparatus, support the concept of transition-vesicle-specific docking sites of finite number associated with cis Golgi apparatus cisternae.

Retinoid modulation of cell-free membrane transfer between endoplasmic reticulum and Golgi apparatus.

Cell-free transfer of radiolabeled membrane proteins from part-rough, part-smooth transitional elements of the endoplasmic reticulum to Golgi apparatus immobilized to nitrocellulose in the presence of nucleoside triphosphate, an ATP-regenerating system and a cytosol fraction was promoted by retinol. At an optimum concentration of 1 microgram/ml, the rate and amount of transfer was approximately doubled over 1 to 2 h of incubation in the cell-free system. The transition vesicles induced to form in the cell-free system were concentrated by preparative free-flow electrophoresis in order to study separately the steps of vesicle formation from transitional endoplasmic reticulum and the steps of vesicle fusion with Golgi apparatus. The retinol effect was on vesicle formation as evidenced by an approx. 2-fold increase in transition vesicle numbers, as determined by electron microscope morphometry, and amount from protein determinations on the isolated fractions enriched in transition vesicles. The retinol response in the complete transfer could be eliminated by addition of concentrated cytosol, including cytosol depleted of retinol. An interaction of retinol with some component of the vesicle formation process, possibly involving guanine nucleotides, is indicated.

Isolation of purified plasma membranes from cultured cells and hepatomas by two-phase partition and preparative free-flow electrophoresis.

This report describes and documents the isolation of plasma membranes from hepatomas and tissue culture cells by aqueous two-phase partition. The method used previously for normal liver was effective, rapid, and reproducible. Preparations from both cells and hepatomas were more than 90% plasma membrane-derived based on electron microscope morphometry and assays of marker enzyme activities. Relative enrichments over starting homogenates were near theoretical as determined by electron microscope morphometry of starting cells and tissues. Recoveries were about 10% or greater. Briefly, the membranes to be separated were mixed with a combination of two different polymers that themselves separated into two phases. For tissue culture cells and hepatomas, a mixture of 6.6% (w/w) dextran and 6.6% (w/w) polyethylene glycol containing 0.25 M sucrose and 5 mM potassium phosphate (pH 7.2) was used. A potassium-stimulated, ouabain-inhibited, p-nitrophenylphosphatase was employed as a plasma membrane marker to monitor yield and recovery. In combination with free-flow electrophoresis, the preparations of plasma membranes from cultured cells were resolved further into fractions enriched in vesicles of right side-out or inside-out orientations. Unlike centrifugation methods, the same type of two-phase separations provided useful plasma membrane fractions when applied to different types of cultured cells as well as to solid tumors and normal tissues. The lower phase membranes, after two-phase partition, provided a plasma membrane-depleted source of membranes other than plasma membrane for use as reference fractions. The procedures should find wide application to problems of cancer research where facile and decisive separations of surface and internal membranes may be required.

Isolation of a vesicular intermediate in the cell-free transfer of membrane from transitional elements of the endoplasmic reticulum to Golgi apparatus cisternae of rat liver.

Preparations enriched in part-smooth (lacking ribosomes), part-rough (with ribosomes) transitional elements of the endoplasmic reticulum when incubated with ATP plus a cytosol fraction responded by the formation of blebbing profiles and approximately 60-nm vesicles. The 60-nm vesicles formed resembled closely transition vesicles in situ considered to function in the transfer of membrane materials between the endoplasmic reticulum and the Golgi apparatus. The transition elements following incubation with ATP and cytosol were resolved by preparative free-flow electrophoresis into fractions of differing electronegativity. The main fraction contained the larger vesicles of the transitional membrane elements, while a less electronegative minor shoulder fraction was enriched in the 60-nm vesicles. If the vesicles concentrated by preparative free-flow electrophoresis were from material previously radiolabeled with [3H]leucine and then added to Golgi apparatus immobilized to nitrocellulose, radioactivity was transferred to the Golgi apparatus membranes. The transfer was rapid (T1/2 of about 5 min), efficient (10-30% of the total radioactivity of the transition vesicle preparations was transferred to Golgi apparatus), and independent of added ATP but facilitated by cytosol. Transfer was specific and apparently unidirectional in that Golgi apparatus membranes were ineffective as donor membranes and endoplasmic reticulum vesicles were ineffective as recipient membranes. Using a heterologous system with transition vesicles from rat liver and Golgi apparatus isolated from guinea pig liver, coalescence of the small endoplasmic reticulum-derived vesicles with Golgi apparatus membranes was demonstrated using immunocytochemistry. Employed were polyclonal antibodies directed against the isolated rat transition vesicle preparations. When localized by immunogold procedures at the electron microscope level, regions of rat-derived vesicles were found fused with cisternae of guinea pig Golgi apparatus immobilized to nitrocellulose strips. Membrane transfer was demonstrated from experiments where transition vesicle membrane proteins were radioiodinated by the Bolton-Hunter procedure. Additionally, radiolabeled peptide bands not present initially in endoplasmic reticulum appeared following coalescence of the derived vesicles with Golgi apparatus. These bands, indicative of processing, required that both Golgi apparatus and transition vesicles be present and did not occur in incubated endoplasmic reticulum preparations or on nitrocellulose strips to which no Golgi apparatus were added.(ABSTRACT TRUNCATED AT 400 WORDS)

Intracellular membrane flow: reconstitution of transition vesicle formation and function in a cell-free system.

Transfer of membrane between endoplasmic reticulum and Golgi apparatus in situ is considered to occur via 60-nm transition vesicles derived from part-rough, part-smooth transition elements of the endoplasmic reticulum. A procedure is described for the isolation of a fraction enriched in these transition elements from rat liver. The isolated fraction generates small vesicles morphologically resembling transition vesicles when incubated with nucleoside triphosphate at 37 degrees C. In the cell-free system consisting of a donor fraction enriched in transition elements and an acceptor fraction consisting of intact Golgi apparatus immobilized on nitrocellulose strips, transfer in vitro of radiolabeled membranes was demonstrated. Nucleoside triphosphates were required for transfer, and transfer was facilitated by a cytosol fraction of Mr greater than 10,000. In the presence of both nucleoside triphosphate and cytosol, radiolabeled proteins were transferred in a manner dependent upon both time and temperature. Transfer appeared to be both vectorial and specific in that, with Golgi apparatus (or endoplasmic reticulum) as both donor and acceptor, only negligible time and temperature-dependent transfer was observed. The test system described is expected to facilitate further investigation of the transfer process and to provide a convenient assay to guide transition vesicle isolation and characterization.