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35 results on '"Hinz, Giselbert"'

30. Phosphorylation of a 51-kDa envelope membrane polypeptide involved in protein translocation into chloroplasts.

Author

Hinz, Giselbert and Flügge, Ulf Ingo

Subjects
*PHOSPHORYLATION, *PEPTIDE hormones, *CHLOROPLASTS, *MEMBRANE proteins, *ADENOSINE triphosphate, *CHROMOSOMAL translocation
Abstract

In this report we demonstrate that a 51-kDa outer-envelope membrane protein (P51) is involved in protein translocation into chloroplasts. Furthermore it is shown that phosphorylation of P51 is functionally related to the process of binding and/or importing precursor proteins into chloroplasts. Several lines of evidence have been obtained supporting this suggestion. First, protein import into chloroplasts was inhibited by the membraneimpermeable agent pyridoxal Y-phosphate, which has been shown to react with a component of the proteinimport apparatus. Phosphorylation of envelope membrane polypeptides using [γ-32P]ATP in the presence of pyridoxal 5'-phosphate resulted in an increased incorporation of 32P radiolabel into a 51-kDa membrane polypeptide (P51). A close correlation between the inhibition of protein import and the increase in the phosphorylation state of P51, both as a function of PLP concentration, was observed. Second, binding of purified precursor proteins to chloroplasts resulted in a specific increase in the phosphorylation state of P51. This effect was not exerted by the mature form of the precursor protein lacking the presequence. Third, internally generated ATP was able to compete specifically with externally added [γ-32P]ATP for the phosphorylation of P51. Fourth, digestion of the outer-envelope membrane with low amounts of thermolysin resulted in a loss of protein import activity, which was associated with the removal of the phosphorylation site of P51. Phosphorylation of P51 proceeds with an apparent Km (ATP) of about 5 µM, which is much lower than the ATP concentration required for the protein translocation itself. We suggest that two different ATP-dependent processes are involved in protein translocation into chloroplasts. P51 represent presumably a regulatory component of the protein-import apparatus or the protein receptor itself. [ABSTRACT FROM AUTHOR]

Published
1988
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31. Energy dependence of protein translocafion into chloroplasts.

Author

Flügge, U. Ingo and Hinz, Giselbert

Subjects
*CHLOROPLASTS, *PROTEINS, *BIOMOLECULES, *SPINACH, *PHOSPHORYLATION
Abstract

The translocation of in vitro synthesized precursor proteins into intact spinach chloroplasts was investigated with respect to its energy requirement. It was demonstrated that MgATP itself, and not a transmembrane electrochemical gradient across the envelope membrane, promotes protein import. By manipulating the external and the stromal level of MgATP, we provided evidence that MgATP energized the protein import not within the chloroplast but at the outside of the envelope membrane. It is postulated that an MgATP-dependent phosphorylation/dephosphorylation cycle at the outer membrane face was involved in the course of protein translocation into the chloroplast. [ABSTRACT FROM AUTHOR]

Published
1986
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32. The molecular characterization of transport vesicles.

Author

Robinson, David, Hinz, Giselbert, and Holstein, Susanne

Abstract

Secretion, endocytosis and transport to the lytic compartment are fundamental, highly coordinated features of the eukaryotic cell. These intracellular transport processes are facilitated by vesicles, many of which are small (100 nm or less in diameter) and ‘coated’ on their cytoplasmic surface. Research into the structure of the coat proteins and how they interact with the components of the vesicle membrane to ensure the selective packaging of the cargo molecules and their correct targeting, has been quite extensive in mammalian and yeast cell biology. By contrast, our knowledge of the corresponding types of transport vesicles in plant cells is limited. Nevertheless, the available data indicate that a considerable homology between plant and non-plant coat polypeptides exists, and it is also suggestive of a certain similarity in the mechanisms underlying targeting in all eukaryotes. In this article we shall concentrate on three major types of transport vesicles: clathrin-coated vesicles, COP-coated vesicles, and ‘dense’ vesicles, the latter of which are responsible for the transport of vacuolar storage proteins in maturing legume cotyledons. For each we will summarize the current literature on animal and yeast cells, and then present the relevant data derived from work on plant cells. In addition, we briefly review the evidence in support of the ‘SNARE’ hypothesis, which explains how vesicles find and fuse with their target membrane. [ABSTRACT FROM AUTHOR]

Published
1998
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33. One Vacuole or two Vacuoles: Do Protein Storage Vacuoles Arise de novoduring Pea Cotyledon Development?

Author

Robinson, David G., Hoh, Birgit, Hinz, Giselbert, and Jeong, Byung-Kap

Abstract

Using improved fixation procedures for both conventional and immuno-electron microscopy, we have reinvestigated the problem of protein storage vacuole (PSV) biogenesis in developing pea (Pisum sativumL.) cotyledons. Our results show that PSV develop de novoand the vegetative vacuoles degenerate. The PSV appear to arise from the rough ER as judged by the presence of osmiophilic substances in the lumen of rER cisternae and by the detection of a BiP analogue in the storage protein deposits contained in the young PSV. These results are discussed in terms of the involvement of other endomembrane compartments (Golgi apparatus and clathrin coated vesicles) in the intracellular transport of storage proteins in legumes.

Published
1995
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34. Transport of storage proteins to the vacuole is mediated by vesicles without a clathrin coat

Author

Hohl, Inge, Robinson, David G., Chrispeels, Maarten J., and Hinz, Giselbert

Abstract

Storage parenchyma cells of developing legume cotyledons actively transport large amounts of storage proteins to protein storage vacuoles (PSV). These proteins are synthesized on the endoplasmic reticulum and pass through the Golgi apparatus. Clathrin coated vesicles (CCV) and small electron dense vesicles found near the trans-Golgi network (TGN) have both been implicated in the Golgi-to-vacuole transport step. Recent findings that protein storage cells contain more than one type of vacuole have necessitated a re-examination of the role of both types of vesicles in vacuolar protein transport. Immunoblots of highly purified CCV preparations and immunogold labelling with antibodies to the storage proteins vicilin and legumin, indicate that the dense vesicles, but not the CCV, are involved in storage protein transport in pea cotyledons. This result is supported by the finding that α-TIP, a protein characteristic of the PSV membrane, is absent from CCV. In addition, complex glycoproteins appear to be carried by CCV but are not detectable in the PSV. We suggest on the basis of these data that storage proteins and other vacuolar proteins such as acid hydrolases are not sorted by the same mechanism and are transported by different types of vesicles to different types of vacuoles.

Published
1996
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35. Protein storage vacuoles form de novo during pea cotyledon development

Author

Hoh, Birgit, Hinz, Giselbert, Jeong, Byung-Kap, and Robinson, David G.

Abstract

We have investigated the formation of protein storage vacuoles in peas (Pisum sativum L.) in order to determine whether this organelle arises de novo during cotyledon development. A comparison of different stages in cotyledon development indicates that soluble protease activities decline and the amounts of storage proteins and the integral membrane protein of the protein body, α-TIP, increase during seed maturation. On linear sucrose density gradients we have been able to distinguish between two separate vesicle populations: one enriched in α-TIP, and one in TIP-Ma 27, a membrane protein characteristic of vegetative vacuoles. Both vesicle populations possess, however, PPase and V-ATPase activities. Conventionally fixed cotyledonary tissue at an intermediate stage in cotyledon development reveals the presence of a complex tubular-cisternal membrane system that seems to surround the pre-existing vacuoles. The latter gradually become compressed as a result of dilation of the former membrane system. This was confirmed immunocytochemically with the TIP-Ma 27 antiserum. Deposits of the storage proteins vicilin and legumin in the lumen, and the presence of α-TIP in the membranes of the expanding membrane system provide evidence of its identity as a precursor to the protein storage vacuole.

Published
1995
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