In vivo and in vitro analysis of ptl1, a yeast ts mutant with a membrane-associated defect in protein translocation.

Mutants defective in the ability to translocate proteins across the membrane of the endoplasmic reticulum were selected in Trp- Saccharomyces cerevisiae on the basis of their ability to retain a fusion protein in the cytosol. The fusion comprised the prepro region of prepro-alpha-factor (MF alpha 1) N-terminal to phosphoribosyl anthranilate isomerase (TRP1). The first of the protein translocation mutations, called ptl1, results in temperature-sensitivity of growth and protein translocation. At the non-permissive temperature, precursors to several secretory proteins accumulate in the cytosol. Using this mutant, we demonstrate that the prepro-carboxypeptidase Y that had been accumulated in the cytosol at the non-permissive temperature could be post-translationally translocated into the endoplasmic reticulum when cells were returned to the permissive temperature. This result indicates that post-translational translocation of preproteins across endoplasmic reticulum membranes can occur in vivo. We have also determined that the temperature-sensitive component is membrane-associated in ptl1, and that the membranes derived from this strain show a reversible temperature-sensitive translocation phenotype in vitro.     

Further studies on a mutant mammalian cell line defective in mitosis

Experiments have been performed on a temperature-sensitive hamster cell line, ts-546. After the cells are switched to the non-permissive temperature, interphase cells continue through the cell cycle until the cells enter metaphase. Normal mitotic events then fail to occur. Metaphase chromosomes in the cells condense and coalesce into chromatin aggregates. Nuclear membrane re-forms around the aggregates resulting in the formation of mono-, bi- or multi-nucleate interphase-like cells. The conversion of mitotic cells to interphase-like states is completed within a few hours. The initial characterization of the mutant cell line was based on the observation that rounded-up cells accumulate in culture at the non-permissive temperature. The mitotic roundingup process may be utilized as a useful marker for selective isolation of mutant cell lines defective in mitosis.     

Components of the Salmonella flagellar export apparatus and classification of export substrates

Until now, identification of components of the flagellar protein export apparatus has been indirect. We have now identified these components directly by establishing whether mutants defective in putative export components could translocate export substrates across the cytoplasmic membrane into the periplasmic space. Hook-type proteins could be exported to the periplasm of rod mutants, indicating that rod protein export does not have to precede hook-type protein export and therefore that both types of proteins belong to a single export class, the rod/hook-type class, which is distinct from the filament-type class. Hook-capping protein (FlgD) and hook protein (FlgE) required FlhA, FlhB, FliH, FliI, FliO, FliP, FliQ, and FliR for their export to the periplasm. In the case of flagellin as an export substrate, because of the phenomenon of hook-to-filament switching of export specificity, it was necessary to use temperature-sensitive mutants and establish whether flagellin could be exported to the cell exterior following a shift from the permissive to the restrictive temperature. Again, FlhA, FlhB, FliH, FliI, and FliO were required for its export. No suitable temperature-sensitive fliQ or fliR mutants were available. FliP appeared not to be required for flagellin export, but we suspect that the temperature-sensitive FliP protein continued to function at the restrictive temperature if incorporated at the permissive temperature. Thus, we conclude that these eight proteins are general components of the flagellar export pathway. FliJ was necessary for export of hook-type proteins (FlgD and FlgE); we were unable to test whether FliJ is needed for export of filament-type proteins. We suspect that FliJ may be a cytoplasmic chaperone for the hook-type proteins and possibly also for FliE and the rod proteins. FlgJ was not required for the export of the hook-type proteins; again, because of lack of a suitable temperature-sensitive mutant, we were unable to test whether it was required for export of filament-type proteins. Finally, it was established that there is an interaction between the processes of outer ring assembly and of penetration of the outer membrane by the rod and nascent hook, the latter process being of course necessary for passage of export substrates into the external medium. During the brief transition stage from completion of rod assembly and initiation of hook assembly, the L ring and perhaps the capping protein FlgD can be regarded as bona fide export components, with the L ring being in a formal sense the equivalent of the outer membrane secretin structure of type III virulence factor export systems.     

The E. coli divE mutation, which differentially inhibits synthesis of certain proteins, is in tRNASer1.

The temperature-sensitive divE mutant of Escherichia coli cannot synthesize certain membrane and cytoplasmic proteins at a non-permissive temperature. Growth of the mutant cells is arrested at a specific stage of the cell cycle when exposed to the non-permissive conditions, suggesting that the divE mutant possesses a defect in cell division control. From sequence determination of a cloned 1.35-kbp DNA fragment that complements the temperature-sensitive divE42 mutation, we characterized two genes in the segment ; one for tRNASer1 and the other for a 23 500 dalton protein. In parallel experiments we cloned the homologous 1.35-kbp DNA fragment from the divE42 mutant and determined its entire nucleotide sequence. Comparison of the two sequences showed that the mutation site is located not in the protein gene, but in the tRNA gene, where A10 is replaced by G10 in the D-stem. Lambda transducing phages carrying the subcloned tRNASer1 gene complemented the divE42 mutation, thereby confirming the conclusion obtained from sequence analyses of the fragments. This finding indicates that tRNASer1 is specifically involved in regulation of cell cycle-specific protein synthesis, coupled with an important step in the process of cell division, or that usage of serine tRNA is functionally specific for the biosynthesis of certain proteins.     

Events in the endoplasmic reticulum abrogate the temperature sensitivity of Sindbis virus mutant ts23.

Temperature-sensitive mutations in proteins produced at or heated to a nonpermissive temperature render the proteins defective in some aspect of their maturation into functional entities. The characterization of temperature-sensitive mutations in model proteins, such as virus membrane proteins, has allowed the elucidation of critical events in the maturation of virus membranes as well as in the intracellular folding, processing, and transport of membrane proteins in general. We have used a transport-defective, temperature-sensitive mutant of Sindbis virus, ts23, which has two amino acid changes in the envelope protein E1, to further examine requirements placed upon the glycoproteins for their export to the plasma membrane. Pulse-chase experiments in which we utilized the transport inhibitors monensin and brefeldin A allowed us to synthesize and assemble the glycoproteins of ts23 into export-competent heterodimers at the permissive temperature while concurrently blocking their export to the cell surface. After removal of the inhibitors and a shift to the nonpermissive temperature, we assayed for protein transport, cell-cell fusion, and infectious-particle production. Taken together, the data show that the irreversible loss of the temperature-sensitive phenotype of ts23 can be correlated with the folding of E1 and the formation of export-competent PE2-E1 heterodimers in the endoplasmic reticulum. Furthermore, we have found that E1 pairs with PE2 to form the heterodimer prior to the completion of E1 folding.     

A role for unsaturated fatty acids in mitochondrial movement and inheritance

Yeast cells with the mdm2 mutation display temperature-sensitive growth and defective intracellular mitochondrial movement at the non-permissive temperature. The latter phenotype includes both an absence of mitochondrial transfer into daughter buds of mitotically growing cells and an aberrant mitochondrial distribution in cells exposed to mating pheromone. The wild-type MDM2 gene was cloned by complementation, and DNA sequence analysis revealed a large open reading frame encoding a putative protein of 58.4 kD. The predicted protein sequence is identical to that reported for the yeast OLE1 gene encoding fatty acid desaturase. Unsaturated fatty acid levels are substantially decreased in mdm2 cells after a prolonged incubation at the non-permissive temperature. The addition of oleic acid complements the temperature-sensitive growth and mitochondrial distribution defects of the mutant cells. These results indicate that mdm2 is a temperature-sensitive allele of OLE1 and demonstrate an essential role for unsaturated fatty acids in mitochondrial movement and inheritance.     

Characterization of a Temperature-Sensitive Vertebrate Clathrin Heavy Chain Mutant as a Tool to Study Clathrin-Dependent Events In Vivo

Clathrin and clathrin-dependent events are evolutionary conserved although it is believed that there are differences in the requirement for clathrin in yeast and higher vertebrates. Clathrin is a long-lived protein and thus, with clathrin knockdowns only long-term consequences of clathrin depletion can be studied. Here, we characterize the first vertebrate temperature-sensitive clathrin heavy chain mutant as a tool to investigate responses to rapid clathrin inactivation in higher eukaryotes. Although we created this mutant using a clathrin cryo-electron microscopy model and a yeast temperature-sensitive mutant as a guide, the resulting temperature-sensitive clathrin showed an altered phenotype compared to the corresponding yeast temperature-sensitive clathrin. First, it seemed to form stable triskelions at the non-permissive temperature although endocytosis was impaired under these conditions. Secondly, as a likely consequence of the stable triskelions at the non-permissive temperature, clathrin also localized correctly to its target membranes. Thirdly, we did not observe missorting of the lysosomal enzyme beta-glucuronidase which could indicate that the temperature-sensitive clathrin is still operating at the non-permissive temperature at the Golgi or, that, like in yeast, more than one TGN trafficking pathway exists. Fourthly, in contrast to yeast, actin does not appear to actively compensate in general endocytosis. Thus, there seem to be differences between vertebrates and yeast which can be studied in further detail with this newly created tool.     

Isolation and analysis of a mammalian temperature-sensitive mutant defective in G2 functions

A temperature-sensitive (ts) mutant, designated tsFT210, was isolated from a mouse mammary carcinoma cell line, FM3A. The tsFT210 cells grew normally at 33 degrees C (permissive temperature), but more than 80% of the cells were arrested at the G2 phase at 39 degrees C (non-permissive temperature) as revealed by flow-microfluorimetric analysis. DNA replication and synthesis of other macromolecules by this mutant seemed to be normal at 39 degrees C for at least 10 h. However, in this mutant, hyperphosphorylation of H1 histone from the G2 to M phase, which occurs in the normal cell cycle, could not be detected at the non-permissive temperature. This suggests that a gene product which is temperature-sensitive in tsFT210 cells is necessary for hyperphosphorylation of H1 histone and that this gene product may be related to chromosome condensation.