A 39-kD plasma membrane protein (IP39) is an anchor for the unusual membrane skeleton of Euglena gracilis.

The major integral plasma membrane protein (IP39) of Euglena gracilis was radiolabeled, peptide mapped, and dissected with proteases to identify cytoplasmic domains that bind and anchor proteins of the cell surface. When plasma membranes were radioiodinated and extracted with octyl glucoside, 98% of the extracted label was found in IP39 or the 68- and 110-kD oligomers of IP39. The octyl glucoside extracts were incubated with unlabeled cell surface proteins immobilized on nitrocellulose (overlays). Radiolabel from the membrane extract bound one (80 kD) of the two (80 and 86 kD) major membrane skeletal protein bands. Resolubilization of the bound label yielded a radiolabeled polypeptide identical in Mr to IP39. Intact plasma membranes were also digested with papain before or after radioiodination, thereby producing a cytoplasmically truncated IP39. The octyl glucoside extract of truncated IP39 no longer bound to the 80-kD membrane skeletal protein in the nitrocellulose overlays. EM of intact or trypsin digested plasma membranes incubated with membrane skeletal proteins under stringent conditions similar to those used in the nitrocellulose overlays revealed a partially reformed membrane skeletal layer. Little evidence of a membrane skeletal layer was found, however, when plasma membranes were predigested with papain before reassociation. A candidate 80-kD binding domain of IP39 has been tentatively identified as a peptide fragment that was present after trypsin digestion of plasma membranes, but was absent after papain digestion in two-dimensional peptide maps of IP39. Together, these data suggest that the unique peripheral membrane skeleton of Euglena binds to the plasma membrane through noncovalent interactions between the major 80-kD membrane skeletal protein and a small, papain sensitive cytoplasmic domain of IP39. Other (62, 51, and 25 kD) quantitatively minor peripheral proteins also interact with IP39 on the nitrocellulose overlays, and the possible significance of this binding is discussed.

Properties and topography of the major integral plasma membrane protein of a unicellular organism.

The cellular distribution, membrane orientation, and biochemical properties of the two major NaOH-insoluble (integral) plasma membrane proteins of Euglena are detailed. We present evidence which suggests that these two polypeptides (Mr 68 and 39 kD) are dimer and monomer of the same protein: (a) Antibodies directed against either the 68- or the 39-kD polypeptide bind to both 68- and 39-kD bands in Western blots. (b) Trypsin digests of the 68- and 39-kD polypeptides yield similar peptide fragments. (c) The 68- and 39-kD polypeptides interconvert during successive electrophoresis runs in the presence of SDS and beta-mercaptoethanol. (d) The 39-kD band is the only major integral membrane protein evident after isoelectric focusing in acrylamide gels. The apparent shift from 68 to 39 kD in focusing gels has been duplicated in denaturing SDS gels by adding ampholyte solutions directly to the protein samples. The membrane orientation of the 39-kD protein and its 68-kD dimer has been assessed by radioiodination in situ using intact cells or purified plasma membranes. Putative monomers and dimers are labeled only when the cytoplasmic side of the membrane is exposed. These results together with trypsin digestion data suggest that the 39-kD protein and its dimer have an asymmetric membrane orientation with a substantial cytoplasmic domain but with no detectable extracellular region. Immunolabeling of sectioned cells indicates that the plasma membrane is the only cellular membrane with significant amounts of 39-kD protein. No major 68- or 39-kD polypeptide bands are evident in SDS acrylamide gels or immunoblots of electrophoresed whole flagella or preparations enriched in flagellar membrane vesicles, nor is there a detectable shift in any flagellar polypeptide in the presence of ampholyte solutions. These findings are considered with respect to the well-known internal crystalline organization of the euglenoid plasma membrane and to the potential for these proteins to serve as anchors for membrane skeletal proteins.

Euglena gracilis cadmium-binding protein-II contains sulfide ion.

Sulfide ions are a constituent of the cadmium-binding protein-II in the alga Euglena gracilis. Their presence was demonstrated by the methylene blue assay, by acid labilization induced reductions in the Cd-S charge transfer band at 254 nm and by reactions with the thiol reagent, 5,5'-dithiobis-(2-nitrobenzoic acid) (DTNB). Direct reduction of DTNB by sulfide and precipitation of CdS yield a complex stoichiometry for the DTNB reaction. The S2-/Cd2+ ratios determined, 1.25 +/- 0.10 (methylene blue) and 1.37 +/- 0.16 (DTNB), are in good agreement.

Effects of iron-, manganese-, or magnesium-deficiency on the growth and morphology of Euglena gracilis.

Iron-, manganese-, or magnesium-deficiency has been induced in Euglena gracilis. Each arrests cell proliferation, decreases the intracellular content of the deficient metal, and increases that of several other metals. Light and electron microscopy of stationary phase cells reveal that Fe-deficient (-Fe) cells are similar in size and shape to control organisms. Magnesium-deficient (-Mg) cells, however, are larger, and approximately 14% are multilobed, containing 2 to 12 lobes of equal size emanating from a central region. Individual (-Mg) cells and each lobe of multilobed cells contain a single nucleus. Manganese-deficient (-Mn) organisms are morphologically more heterogeneous than (-Fe) or (-Mg) cells. Most are spherical and larger than controls. Approximately 15% are multilobed but, unlike (-Mg) cells, contain lobes of unequal size with either zero, one, or several nuclei present in each. Nuclei of (-Mn) cells differ in size and shape from those of control, (-Fe), or (-Mg) cells. All three deficient cell types accumulate large quantities of paramylon. Other cytoplasmic structures, however, appear normal. Addition of Fe, Mn, or Mg to the respective deficient stationary phase cultures reverses growth arrest and restores normal morphology. The results suggest that Fe-, Mn-, and Mg-deficiencies affect different stages of the E. gracilis cell cycle.

Regulation of cell shape in Euglena gracilis. IV. Localization of actin, myosin and calmodulin.

The immunofluorescence patterns for actin, myosin, calmodulin and tubulin were observed in Euglena gracilis Klebs strain Z during the biological clock-controlled shape changes observed with division-synchronized cells, and during two shock responses that induce cell rounding. The fluorescence patterns for actin, myosin, calmodulin and tubulin show a high degree of coincidence and are visualized as lines running parallel to, and having the same spacing as, the pellicle strips beneath the plasma membrane. The fluorescence patterns remain intact during the daily shape changes, implying that the shape changes do not result from cycles of polymerization and depolymerization of the microtubules and microfilaments. Resuspension of cells in Ca2+-free medium induces cell rounding of many of the cells. The actin and calmodulin patterns are partially disrupted by the Ca2+-free resuspension, while the myosin pattern is almost totally disrupted. Microtubules are unaffected by this treatment. Prior exposure of cells to the calmodulin antagonist trifluoperazine or to the microfilament-stabilizing peptide phalloidin stabilize the actin, myosin and calmodulin patterns against disruption by the Ca2+-free resuspension and other shock responses. The possibility of an actomyosin contractile system controlled by calmodulin is discussed.

Euglena gracilis chloroplast elongation factor Tu. Purification and initial characterization.

The chloroplast protein synthesis elongation factor Tu (EF-Tuchl) has been purified to near homogeneity from Euglena gracilis. Chromatography of the postribosomal supernatant of light-induced Euglena on DEAE-Sephadex reveals two forms of EF-Tuchl. Further purification has shown that one species consists of a complex between EF-Tuchl and a factor that stimulates its activity. The other species consists of free EF-TUchl. The factor has been purified from both chromatographic forms by taking advantage of the molecular weight shift that occurs upon disruption of the complex between EF-Tuchl and the stimulatory factor. EF-Tuchl consists of a single polypeptide chain with a molecular weight of about 50,000. EF-Tuchl is as active on Escherichia coli ribosomes as it is on its homologous ribosomes but displays no detectable activity on eukaryotic cytoplasmic ribosomes. It is stimulated in polymerization by E. coli EF-Ts and will form a complex with the prokaryotic factor that can be isolated by gel filtration chromatography. Like E. coli EF-Tu, it is sensitive to modification by N-ethylmaleimide and is inhibited by the antibiotic kirromycin. Thus, the chloroplast factor has many features that reflect the close relationship between prokaryotic and chloroplast translational systems.

Composition and structure of zinc-deficient Euglena gracilis chromatin.

The histone content of zinc-deficient (-Zn) Euglena gracilis decreases while, concomitantly, DNA content increases and the transcription rate is reduced markedly [Mazus, B., Falchuk, K. H., & Vallee, B. L. (1983) Biochemistry (in press); Falchuk, K. H., Fawcett, D. W., & Vallee, B. L. (1975) J. Cell Sci. 17, 57-78]. The effects on major constituents of the genome have been examined by studying the rate and extent of hydrolysis of +Zn and -Zn chromatin by micrococcal nuclease, DNase I, or DNase II. The size of hydrolyzed DNA fragments suggests similarity of the +Zn E. gracilis chromatin organization to that of other eukaryotes. The major protein constituent of -Zn chromatin is a polypeptide of less than 3000 daltons whose electrophoretic mobility differs from that of any known histone components of chromatin, the latter described elsewhere (K. H. Falchuk et al., unpublished results). This protein profoundly affects the structure of -Zn chromatin, which is about 10-30-fold more resistant to micrococcal nuclease hydrolysis than +Zn chromatin. Moreover, the resultant DNA fragments [2000 base pairs (bp)], are much larger than those of +Zn cells. Under conditions which hydrolyze +Zn chromatin into DNA fragments smaller than 50 bp, only 50% of -Zn chromatin is digested into fragments less than 2000 bp, i.e., in the range of those expected for oligonucleosomes. Removal of the low molecular weight protein from -Zn chromatin reverses its enhanced resistance to nucleolysis and results in extensive hydrolysis. Conversely, addition of the low molecular weight protein to +Zn chromatin increases the resistance of this complex to digestion.(ABSTRACT TRUNCATED AT 250 WORDS)

1H-NMR studies of the coordination geometry at the heme iron and the electronic structure of the heme group in cytochrome c-552 from Euglena gracilis.

The 1H-NMR lines of heme c in reduced and oxidized cytochrome c-552 from Euglena gracilis were individually assigned and the coordination geometry of the axial ligands was investigated. The electronic structure of the heme and the chirality of the axially bound methionine were found to be of the same type as in mammalian cytochrome c, but different from cytochrome c-551 from Pseudomonas aeruginosa. These results provide additional support for a previously proposed correlation between the chirality of attachment of the axial methionine and the electronic wave functions in oxidized cytochromes of the c type. Comparison of mammalian cytochrome c, cytochrome c-551 and cytochrome c-552 indicates that the chirality of the axially bound methionine is not linked with the evolutionary increase of the polypeptide chain length.

Absolute DNA determinations by flow microfluorometry.

The DNA content of Euglena gracilis and murine leukemic cell line L-1210 were varied by growth under abnormal conditions. DNA measurements by colormetry and by flow microfluorometry were compared and absolute calibration of the flow device was established.

The characterization of Euglena gracilis DNA by its reassociation kinetics.

The reassociation kinetics of Euglena gracilis DNA were carried out to determine the Cot 1/2 of the unique DNA (2000). The Cot 1/2 of the unique DNA and the amount of DNA per cell were used to show that this alga is not polyploid. Three kinetically definable classes of DNA were observed: a highly repetitive fraction, a middle repetitive fraction, and a non-repetitive fraction. Each fraction of DNA was characterized by its melting properties (Tm).

The purification and amino acid sequence of cytochrome C-552 from Euglena gracilis.

Cytochrome c-552 from Euglena gracilis was purified and the amino acid sequence determined. The protein is a single peptide chain of 87 residues with the haem prosthetic group bound through two thioether linkages to two cysteine residues near the amino-terminal region. The amino acid sequence shows some similarities to mitochondrial cytochrome c and to two prokaryote c-type cytochromes. The sequence, taken with the known characteristics of cytochrome c-552, indicates that it is an f-type cytochrome. The possible functional and evolutionary significance of these features in common is discussed. Detailed evidence for the amino acid sequence of Euglena cytochrome f has been deposited as Supplementary Publication SUP 50027 at the British Library, Lending Division (formerly the National Lending Library for Science and Technology), Boston Spa, Yorks. LS23 7QB, U.K., from whom copies can be obtained on the terms indicated in Biochem. J. (1973) 131, 5.