Creating a chimeric clathrin heavy chain that functions independently of yeast clathrin light chain

Clathrin facilitates vesicle formation during endocytosis and sorting in the trans‐Golgi network (TGN)/endosomal system. Unlike in mammals, yeast clathrin function requires both the clathrin heavy (CHC) and clathrin light (CLC) chain, since Chc1 does not form stable trimers without Clc1. To further delineate clathrin subunit functions, we constructed a chimeric CHC protein (Chc‐YR) , which fused the N‐terminus of yeast CHC (1–1312) to the rat CHC residues 1318–1675, including the CHC trimerization region. The novel CHC‐YR allele encoded a stable protein that fractionated as a trimer. CHC‐YR also complemented chc1Δ slow growth and clathrin TGN/endosomal sorting defects. In strains depleted for Clc1 (either clc1Δ or chc1Δ clc1Δ), CHC‐YR, but not CHC1, suppressed TGN/endosomal sorting and growth phenotypes. Chc‐YR‐GFP (green fluorescent protein) localized to the TGN and cortical patches on the plasma membrane, like Chc1 and Clc1. However, Clc1‐GFP was primarily cytoplasmic in chc1Δ cells harboring pCHC‐YR, indicating that Chc‐YR does not bind yeast CLC. Still, some partial phenotypes persisted in cells with Chc‐YR, which are likely due either to loss of CLC recruitment or chimeric HC lattice instability. Ultimately, these studies have created a tool to examine non‐trimerization roles for the clathrin LC.     

A role for clathrin in the sorting of vacuolar proteins in the Golgi complex of yeast.

We have investigated the role of clathrin in vacuolar protein sorting using yeast strains harboring a temperature-sensitive allele of clathrin heavy chain (chc1-ts). After a 5 min incubation at the non-permissive temperature (37 degrees C), the chc1-ts strains displayed a severe defect in the sorting of lumenal vacuolar proteins. Sorting of a vacuolar membrane protein, alkaline phosphatase, and transport to the surface of a cell wall protein, was not affected at 37 degrees C. In chc1-ts cells incubated at 37 degrees C, secretion of the missorted lumenal vacuolar protein carboxypeptidase Y (CPY) was blocked by the sec1 mutation which prevents fusion of secretory vesicles to the plasma membrane. Unexpectedly, chc1-ts cells incubated for extended periods at 37 degrees C regained the ability to sort CPY. Cells carrying deletions of the CHC1 gene (chc1 delta) also sorted CPY to the vacuole even when subjected to temperature shifts. Vacuolar delivery of CPY in chc1 delta cells was not blocked by sec1 suggesting that transport does not occur by secretion and endocytosis. These results provide in vivo evidence that clathrin plays a role in the Golgi complex in sorting of vacuolar proteins from the secretory pathway. With time, however, yeast cells lacking functional clathrin heavy chains are able to adapt in a way that allows restoration of vacuolar protein sorting in the Golgi complex. These conclusions clarify previous studies of chc1 delta cells which raised the possibility that clathrin is not involved in vacuolar protein sorting.     

The Saccharomyces cerevisiae APS1 gene encodes a homolog of the small subunit of the mammalian clathrin AP-1 complex: evidence for functional interaction with clathrin at the Golgi complex.

Clathrin-associated protein (AP) complexes have been implicated in the assembly of clathrin coats and the selectivity of clathrin-mediated protein transport processes. We have identified a yeast gene, APS1, encoding a homolog of the small (referred to herein as sigma) subunits of the mammalian AP-1 complex. Sequence comparisons have shown that Aps1p is more similar to the sigma subunit of the Golgi-localized mammalian AP-1 complex than Aps2p, which is more related to the plasma membrane AP-2 sigma subunit. Like their mammalian counterparts, Aps1p and Aps2p are components of distinct, large (> 200 kDa) complexes and a significant portion of the Aps proteins co-fractionate with clathrin-coated vesicles during gel filtration chromatography. Unexpectedly, even though the evolutionary conservation of AP small subunits is substantial (50% identity between mammalian and yeast proteins), disruptions of APS1 (aps1 delta) and APS2 (aps2 delta), individually or in combination, elicit no detectable mutant phenotypes. These data indicate that the Aps proteins are not absolutely required for clathrin-mediated selective protein transport in cells expressing wild type clathrin. However, aps1 delta accentuated the slow growth and alpha-factor pheromone maturation defect of cells carrying a temperature-sensitive allele of clathrin heavy chain (Chc) (chc1-ts). In contrast, aps1 delta did not influence the effects of chc1-ts on vacuolar protein sorting or receptor-mediated endocytosis. The aps2 delta mutation resulted in a slight effect on chc1-ts cell growth but had no additional effects. The growth defect of cells completely lacking Chc was compounded by aps1 delta but not aps2 delta. These results comprise evidence that Aps1p is involved in a subset of clathrin functions at the Golgi apparatus. The effect of aps1 delta on cells devoid of clathrin function suggests that Aps1p also participates in clathrin-independent processes.     

Clathrin Functions in the Absence of the Terminal Domain Binding Site for Adaptor-associated Clathrin-Box Motifs

Clathrin is involved in vesicle formation in the trans-Golgi network (TGN)/endosomal system and during endocytosis. Clathrin recruitment to membranes is mediated by the clathrin heavy chain (HC) N-terminal domain (TD), which forms a seven-bladed β-propeller. TD binds membrane-associated adaptors, which have short peptide motifs, either the clathrin-box (CBM) and/or the W-box; however, the importance of the TD binding sites for these motifs has not been tested in vivo. We investigated the importance of the TD in clathrin function by generating 1) mutations in the yeast HC gene (CHC1) to disrupt the binding sites for the CBM and W-box (chc1-box), and 2) four TD-specific temperature-sensitive alleles of CHC1. We found that TD is important for the retention of resident TGN enzymes and endocytosis of α-factor; however, the known adaptor binding sites are not necessary, because chc1-box caused little to no effect on trafficking pathways involving clathrin. The Chc1-box TD was able to interact with the endocytic adaptor Ent2 in a CBM-dependent manner, and HCs encoded by chc1-box formed clathrin-coated vesicles. These data suggest that additional or alternative binding sites exist on the TD propeller to help facilitate the recruitment of clathrin to sites of vesicle formation.     

Selective and immediate effects of clathrin heavy chain mutations on Golgi membrane protein retention in Saccharomyces cerevisiae

The role of clathrin in retention of Golgi membrane proteins has been investigated. Prior work showed that a precursor form of the peptide mating pheromone alpha-factor is secreted by Saccharomyces cerevisiae cells which lack the clathrin heavy chain gene (CHC1). This defect can be accounted for by the observation that the Golgi membrane protein Kex2p, which initiates maturation of alpha-factor precursor, is mislocalized to the cell surface of mutant cells. We have examined the localization of two additional Golgi membrane proteins, dipeptidyl aminopeptidase A (DPAP A) and guanosine diphosphatase (GDPase) in clathrin-deficient yeast strains. Our findings indicate that DPAP A is aberrantly transported to the cell surface but GDPase is not. In mutant cells carrying a temperature-sensitive allele of CHC1 (chc1-ts), alpha-factor precursor appears in the culture medium within 15 min, and Kex2p and DPAP A reach the cell surface within 30 min, after imposing the nonpermissive temperature. In contrast to these immediate effects, a growth defect is apparent only after 2 h at the nonpermissive temperature. Also, sorting of the vacuolar membrane protein, alkaline phosphatase, is not affected in chc1-ts cells until 2 h after the temperature shift. A temperature-sensitive mutation which blocks a late stage of the secretory pathway, sec1, prevents the appearance of mislocalized Kex2p at the cell surface of chc1-ts cells. We propose that clathrin plays a direct role in the retention of specific proteins in the yeast Golgi apparatus, thereby preventing their transport to the cell surface.     

Characterization of the clathrin heavy chain from Dictyostelium discoideum.

We report the cloning and analysis of a clathrin heavy-chain cDNA from the eukaryotic microorganism, Dictyostelium discoideum. A single gene, designated chcA, for the clathrin heavy chain encoded a protein of 1,694 amino acids with a molecular mass of 193,618 daltons. Comparison of the amino acid sequence with the rat and with the yeast sequence showed that the highly conserved protein was more similar to the mammalian clathrin heavy chain (57% identity) than to the yeast heavy chain (45% identity). The mRNA for the clathrin heavy chain was regulated during development. mRNA levels were highest during vegetative growth and declined as the cells progressed through the 24-hr developmental cycle. The concentration of clathrin heavy-chain protein was the same in cells grown in liquid media (high rates of pinocytosis) as in cells grown with bacteria (low rates of pinocytosis), which suggests that regulation of pinocytosis in these cells is not achieved by altering the concentration of clathrin.     

Viability of clathrin heavy-chain-deficient Saccharomyces cerevisiae is compromised by mutations at numerous loci: implications for the suppression hypothesis.

The gene encoding clathrin heavy chain in Saccharomyces cerevisiae (CHC1) is not essential for growth in most laboratory strains tested. However, in certain genetic backgrounds, a deletion of CHC1 (chc1) results in cell death. Lethality in these chc1 strains is determined by a locus designated SCD1 (suppressor of clathrin deficiency) which is unlinked to CHC1 (S. K. Lemmon and E. W. Jones, Science 238:504-509, 1987). The lethal allele of SCD1 has no effect on cell growth when the wild-type version of CHC1 is present. This result led to the proposal that most yeast strains are viable in the absence of clathrin heavy chain because they possess the SCD1 suppressor. Discovery of another yeast strain that cannot grow without clathrin heavy chain has allowed us to perform a genetic test of the suppressor hypothesis. Genetic crosses show that clathrin-deficient lethality in the latter strain is conferred by a single genetic locus (termed CDL1, for clathrin-deficient lethality). By constructing strains in which CHC1 expression is regulated by the GAL10 promoter, we demonstrate that the lethal alleles of SCD1 and CDL1 are recessive. In both cases, very low expression of CHC1 can allow cells to escape from lethality. Genetic complementation and segregation analyses indicate that CDL1 and SCD1 are distinct genes. The lethal CDL1 allele does not cause a defect in the secretory pathway of either wild-type or clathrin heavy-chain-deficient yeast. A systematic screen to identify mutants unable to grow in the absence of clathrin heavy chain uncovered numerous genes similar to SCD1 and CDL1. These findings argue against the idea that viability of chc1 cells is due to genetic suppression, since this hypothesis would require the existence of a large number of unlinked genes, all of which are required for suppression. Instead, lethality appears to be a common, nonspecific occurrence when a second-site mutation arises in a strain whose cell growth is already severely compromised by the lack of clathrin heavy chain.     

Suppressors of clathrin deficiency: overexpression of ubiquitin rescues lethal strains of clathrin-deficient Saccharomyces cerevisiae.

Clathrin-mediated vesicular transport is important for normal growth of the yeast Saccharomyces cerevisiae. Previously, we identified a genetic locus (SCD1) that influences the ability of clathrin heavy-chain-deficient (Chc-) yeast cells to survive. With the scd1-v allele, Chc- yeast cells are viable but grow poorly; with the scd1-i allele, Chc- cells are inviable. To identify the SCD1 locus and other genes that can rescue chc1 delta scd1-i cells to viability, a multicopy suppressor selection strategy was developed. A strain of scd1-i genotype carrying the clathrin heavy-chain gene under GAL1 control (GAL1:CHC1) was transformed with a YEp24 yeast genomic library, and colonies that could grow on glucose were selected. Plasmids from six distinct genetic loci, none of which encoded CHC1, were recovered. One of the suppressor loci was shown to be UBI4, the polyubiquitin gene. UBI4 rescues only in high copy number and is not allelic to SCD1. The conjugation of ubiquitin to intracellular proteins can mediate their selective degradation. Since UBI4 is required for survival of yeast cells under stress and is induced during starvation, ubiquitin expression in GAL1:CHC1 cells was examined. After a shift to growth on glucose to repress synthesis of clathrin heavy chains, UBI4 mRNA levels were elevated > 10-fold, whereas the quantity of free ubiquitin declined severalfold relative to that of Chc+ cells. In addition, novel higher-molecular-weight ubiquitin conjugates appeared in clathrin-deficient cells. We suggest that higher levels of ubiquitin are required for turnover of mislocalized or improperly processed proteins that accumulate in the absence of clathrin and that ubiquitin may play a general role in turnover of proteins in the secretory or endocytic pathway.     

Suppressors of YCK-encoded yeast casein kinase 1 deficiency define the four subunits of a novel clathrin AP-like complex.

In Saccharomyces cerevisiae, the redundant YCK1 and YCK2 genes (Yeast Casein Kinase 1) are required for viability. We describe here the molecular analysis of four mutations that eliminate the requirement for Yck activity. These mutations alter proteins that resemble the four subunits of clathrin adaptors (APs), with highest sequence similarity to those of the recently identified AP-3 complex. The four yeast subunits are associated in a high-molecular-weight complex. These proteins have no essential function and are not redundant for function with other yeast AP-related proteins. Combination of suppressor mutations with a clathrin heavy chain mutation (chc1-ts) confers no synthetic growth defects. However, a yck(ts) mutation shows a strong synthetic growth defect with chc1-ts. Moreover, endocytosis of Ste3p is dramatically decreased in yck(ts) cells and is partially restored by the AP suppressor mutations. These results suggest that vesicle trafficking at the plasma membrane requires the activity of Yck protein kinases, and that the new AP-related complex may participate in this process.     

Vps10p cycles between the TGN and the late endosome via the plasma membrane in clathrin mutants

Clathrin-coated vesicles mediate the transport of the soluble vacuolar protein CPY from the TGN to the endosomal/prevacuolar compartment. Surprisingly, CPY sorting is not affected in clathrin deletion mutant cells. Here, we have investigated the clathrin-independent pathway that allows CPY transport to the vacuole. We find that CPY transport is mediated by the endosome and requires normal trafficking of its sorting receptor, Vps10p, the steady state distribution of which is not altered in chc1 cells. In contrast, Vps10p accumulates at the cell surface in a chc1/end3 double mutant, suggesting that Vps10p is rerouted to the cell surface in the absence of clathrin. We used a chimeric protein containing the first 50 amino acids of CPY fused to a green fluorescent protein (CPY-GFP) to mimic CPY transport in chc1. In the absence of clathrin, CPY-GFP resides in the lumen of the vacuole as in wild-type cells. However, in chc1/sec6 double mutants, CPY-GFP is present in internal structures, possibly endosomal membranes, that do not colocalize with the vacuole. We propose that Vps10p must be transported to and retrieved from the plasma membrane to mediate CPY sorting to the vacuole in the absence of clathrin-coated vesicles. In this circumstance, precursor CPY may be captured by retrieved Vps10p in an early or late endosome, rather than as it normally is in the trans-Golgi, and delivered to the vacuole by the normal VPS gene-dependent process. Once relieved of cargo protein, Vps10p would be recycled to the trans-Golgi and then to the cell surface for further rounds of sorting.     

Genetic analysis of clathrin function in yeast

The use of yeast mutants to study the function and dynamics of clathrin-coated membranes has offered new insights into clathrin's role in the secretory pathway and has raised additional questions. Most strains of yeast can incur a disruption of clathrin heavy or light chain genes and remain viable. However, in rare cases, alleles of genes other than clathrin affect the viability of clathrin-deficient cells. The relationship of the products of these genes to clathrin awaits clarification. Phenotypic characterization of clathrin-deficient yeast mutants suggests that clathrin is not essential for the generation of secretory pathway transport vesicles at the ER or the Golgi complex but is required for the intracellular retention of a Golgi membrane protein, Kex2p. With this genetic evidence for clathrin's function in vivo, biochemical and genetic experiments can be designed to address the mechanism by which clathrin effects retention of Kex2p. Clathrin-deficient yeast carry out protein secretion, receptor-mediated endocytosis of mating pheromone, and efficient targeting of newly synthesized vacuolar proteins. These observations challenge aspects of clathrin's proposed involvement in protein transport through the secretory pathway and to lysosomes in mammalian cells. However, the differences are beginning to recede in the face of additional experiments; the formation of clathrin coated vesicles is no longer commonly thought to be obligately coupled to transport through the secretory pathway in mammalian cells (Rothman 1986; Brodsky, 1988), and the role of clathrin in retaining a Golgi membrane protein in yeast may have its precedents in receptor-mediated endocytosis by mammalian cells or in secretory granule formation in endocrine cells. A unified theory of clathrin function is emerging (Brodsky, 1988) which suggests that the clathrin coat assemblage (clathrin heavy and light chains and the associated proteins) acts as a facilitator of intracellular protein transport by sorting and concentrating cargo molecules. The results from studies of clathrin-deficient yeast support this theory. Future experiments will determine whether clathrin provides its functions at different transport stages in different organisms or whether all eukaryotic cells employ clathrin at the same stages of intracellular protein transport.     

Clathrin facilitates the internalization of seven transmembrane segment receptors for mating pheromones in yeast

The role of clathrin in endocytosis of the yeast phermone receptors was examined using strains expressing a temperature-sensitive clathrin heavy chain. The yeast phermone receptors belong to the family of seven transmembrane segment, G-protein-coupled receptors. A rapid and reversible defect in uptake of radiolabeled alpha-factor pheromone occurred when the cells were transferred to the nonpermissive temperature. Constitutive, pheromone-independent internalization of newly synthesized a-factor phermone receptor was also rapidly inhibited in mutant strains at the nonpermissive temperature. In both cases residual endocytosis, 30-50% of wild-type levels, was detected in the absence of functional clathrin heavy chain. Once internalized, the a- factor receptor was delivered to the vacuole at comparable rates in chc1-ts and wild-type cells at the nonpermissive temperature. Clathrin heavy chain was also required for maximal uptake of a mutant a-factor receptor which is dependent on pheromone for internalization. In the presence of a-factor, the internalization rate of the mutant receptor in chc1-ts cells at the nonpermissive temperature was 2.5 times slower than the rate observed for endocytosis of the mutant receptor in wild- type cells. These experiments provide in vivo evidence that clathrin plays an important role in the endocytosis of the seven trans-membrane segment pheromone receptors in yeast.     

Differential control of clathrin subunit dynamics measured with EW-FRAP microscopy

The clathrin triskelion is composed of three light chain (LC) and three heavy chain (HC) subunits. Cellular control of clathrin function is thought to be aimed at the LC subunit, mainly on the basis of structural information. To test this hypothesis in vivo, we used evanescent-wave photobleaching recovery to study clathrin exchange from single pits using LC (LCa and LCb) and HC enhanced green fluorescent protein fusion constructs. The recovery signal was corrected for cytosolic diffusional background, yielding the pure exchange reaction times. For LCa, we measured an unbinding time constant tau(LEa) = 18.9 +/- 1.0 seconds at room temperature, faster than previously published; for LCb, we found tau(LCb) = 10.6 +/- 1.9 seconds and for HC tau(HC) = 15.9 +/- 1.0 seconds. Sucrose treatment, ATP or Ca(2+) depletion blocked exchange of LCa completely, but only partially of HC, lowering its time constant to tau = 10.0 +/- 0.9 seconds, identical to the one for LCb exchange. The latter was also not blocked by Ca(2+) depletion or sucrose. We conclude that HCs bound both to LCa and to LCb contribute side by side to pit formation in vivo, but the affinity of LCa-free HC in pits is reduced, and the Ca(2+)- and ATP-mediated control of clathrin function is lost.     

Inactivation of clathrin heavy chain inhibits synaptic recycling but allows bulk membrane uptake

Synaptic vesicle reformation depends on clathrin, an abundant protein that polymerizes around newly forming vesicles. However, how clathrin is involved in synaptic recycling in vivo remains unresolved. We test clathrin function during synaptic endocytosis using clathrin heavy chain (chc) mutants combined with chc photoinactivation to circumvent early embryonic lethality associated with chc mutations in multicellular organisms. Acute inactivation of chc at stimulated synapses leads to substantial membrane internalization visualized by live dye uptake and electron microscopy. However, chc-inactivated membrane cannot recycle and participate in vesicle release, resulting in a dramatic defect in neurotransmission maintenance during intense synaptic activity. Furthermore, inactivation of chc in the context of other endocytic mutations results in membrane uptake. Our data not only indicate that chc is critical for synaptic vesicle recycling but they also show that in the absence of the protein, bulk retrieval mediates massive synaptic membrane internalization.     

Synthetic genetic interactions with temperature-sensitive clathrin in Saccharomyces cerevisiae. Roles for synaptojanin-like Inp53p and dynamin-related Vps1p in clathrin-dependent protein sorting at the trans-Golgi network

Clathrin is involved in selective protein transport at the Golgi apparatus and the plasma membrane. To further understand the molecular mechanisms underlying clathrin-mediated protein transport pathways, we initiated a genetic screen for mutations that display synthetic growth defects when combined with a temperature-sensitive allele of the clathrin heavy chain gene (chc1-521) in Saccharomyces cerevisiae. Mutations, when present in cells with wild-type clathrin, were analyzed for effects on mating pheromone alpha-factor precursor maturation and sorting of the vacuolar protein carboxypeptidase Y as measures of protein sorting at the yeast trans-Golgi network (TGN) compartment. By these criteria, two classes of mutants were obtained, those with and those without defects in protein sorting at the TGN. One mutant with unaltered protein sorting at the TGN contains a mutation in PTC1, a type 2c serine/threonine phosphatase with widespread influences. The collection of mutants displaying TGN sorting defects includes members with mutations in previously identified vacuolar protein sorting genes (VPS), including the dynamin family member VPS1. Striking genetic interactions were observed by combining temperature-sensitive alleles of CHC1 and VPS1, supporting the model that Vps1p is involved in clathrin-mediated vesicle formation at the TGN. Also in the spectrum of mutants with TGN sorting defects are isolates with mutations in the following: RIC1, encoding a product originally proposed to participate in ribosome biogenesis; LUV1, encoding a product potentially involved in vacuole and microtubule organization; and INP53, encoding a synaptojanin-like inositol polyphosphate 5-phosphatase. Disruption of INP53, but not the related INP51 and INP52 genes, resulted in alpha-factor maturation defects and exacerbated alpha-factor maturation defects when combined with chc1-521. Our findings implicate a wide variety of proteins in clathrin-dependent processes and provide evidence for the selective involvement of Inp53p in clathrin-mediated protein sorting at the TGN.     

The effects of clathrin inactivation on localization of Kex2 protease are independent of the TGN localization signal in the cytosolic tail of Kex2p.

Localization of Kex2 protease (Kex2p) to the yeast trans-Golgi network (TGN) requires a TGN localization signal (TLS) in the Kex2p C-terminal cytosolic tail. Mutation of the TLS accelerates transport of Kex2p to the vacuole by an intracellular (SEC1-independent) pathway. In contrast, inactivation of the clathrin heavy-chain gene CHC1 results in transport of Kex2p and other Golgi membrane proteins to the cell surface. Here, the relationship of the two localization defects was assessed by examining the effects of a temperature-sensitive CHC1 allele on trafficking of wild-type (WT) and TLS mutant forms of Kex2p. Inactivation of clathrin by shifting chc1-ts cells to 37 degrees C caused WT and TLS mutant forms of Kex2p to behave identically. All forms of Kex2p appeared at the plasma membrane within 30-60 min of the temperature shift. TLS mutant forms of Kex2p were stabilized, their half-lives increasing to that of wild-type Kex2p. After inactivation of clathrin heavy chain, vacuolar protease-dependent degradation of all forms of Kex2p was blocked by a sec1 mutation, which is required for secretory vesicle fusion to the plasma membrane, indicating that transport to the cell surface was required for degradation by vacuolar proteolysis. Finally, after clathrin inactivation, all forms of Kex2p were degraded in part by a vacuolar protease-independent pathway. After inactivation of both chc1-ts and sec1-ts, Kex2 was degraded exclusively by this pathway. We conclude that the effects of clathrin inactivation on Kex2p localization are independent of the Kex2p C-terminal cytosolic tail. Although these results neither prove nor rule out a direct interaction between the Kex2 TLS and a clathrin-dependent structure, they do imply that clathrin is required for the intracellular transport of Kex2p TLS mutants to the vacuole.     

Adaptor complex-independent clathrin function in yeast

Clathrin-associated adaptor protein (AP) complexes are major structural components of clathrin-coated vesicles, functioning in clathrin coat assembly and cargo selection. We have carried out a systematic biochemical and genetic characterization of AP complexes in Saccharomyces cerevisiae. Using coimmunoprecipitation, the subunit composition of two complexes, AP-1 and AP-2R, has been defined. These results allow assignment of the 13 potential AP subunits encoded in the yeast genome to three AP complexes. As assessed by in vitro binding assays and coimmunoprecipitation, only AP-1 interacts with clathrin. Individual or combined disruption of AP-1 subunit genes in cells expressing a temperature-sensitive clathrin heavy chain results in accentuated growth and alpha-factor pheromone maturation defects, providing further evidence that AP-1 is a clathrin adaptor complex. However, in cells expressing wild-type clathrin, the same AP subunit deletions have no effect on growth or alpha-factor maturation. Furthermore, gel filtration chromatography revealed normal elution patterns of clathrin-coated vesicles in cells lacking AP-1. Similarly, combined deletion of genes encoding the beta subunits of the three AP complexes did not produce defects in clathrin-dependent sorting in the endocytic and vacuolar pathways or alterations in gel filtration profiles of clathrin-coated vesicles. We conclude that AP complexes are dispensable for clathrin function in S. cerevisiae under normal conditions. Our results suggest that alternative factors assume key roles in stimulating clathrin coat assembly and cargo selection during clathrin-mediated vesicle formation in yeast.     

Protein transport to the vacuole and receptor-mediated endocytosis by clathrin heavy chain-deficient yeast

Clathrin heavy chain-deficient mutants (chcl) of Saccharomyces cerevisiae are viable but exhibit compromised growth rates. To investigate the role of clathrin in intercompartmental protein transport, two pathways have been monitored in chcl cells: transport of newly synthesized vacuolar proteins to the vacuole and receptor-mediated uptake of mating pheromone. Newly synthesized precursors of the vacuolar protease carboxypeptidase Y (CPY) were converted to mature CPY with similar kinetics in mutant and wild-type cells. chcl cells did not aberrantly secrete CPY and immunolocalization techniques revealed most of the CPY in chcl cells within morphologically identifiable vacuolar structures. Receptor-mediated internalization of the mating pheromone alpha-factor occurred in chcl cells at 36-50% wild-type levels. The mutant cells were fully competent to respond to pheromone-induced cell-cycle arrest. These results argue that in yeast, clathrin may not play an essential role either in vacuolar protein sorting and delivery or in receptor-mediated endocytosis of alpha-factor. Alternative mechanisms ordinarily may execute these pathways, or be activated in clathrin-deficient cells.     

A modulatory role for clathrin light chain phosphorylation in Golgi membrane protein localization during vegetative growth and during the mating response of Saccharomyces cerevisiae

The role of clathrin light chain phosphorylation in regulating clathrin function has been examined in Saccharomyces cerevisiae. The phosphorylation state of yeast clathrin light chain (Clc1p) in vivo was monitored by [32P]phosphate labeling and immunoprecipitation. Clc1p was phosphorylated in growing cells and also hyperphosphorylated upon activation of the mating response signal transduction pathway. Mating pheromone-stimulated hyperphosphorylation of Clc1p was dependent on the mating response signal transduction pathway MAP kinase Fus3p. Both basal and stimulated phosphorylation occurred exclusively on serines. Mutagenesis of Clc1p was used to map major phosphorylation sites to serines 52 and 112, but conversion of all 14 serines in Clc1p to alanines [S(all)A] was necessary to eliminate phosphorylation. Cells expressing the S(all)A mutant Clc1p displayed no defects in Clc1p binding to clathrin heavy chain, clathrin trimer stability, sorting of a soluble vacuolar protein, or receptor-mediated endocytosis of mating pheromone. However, the trans-Golgi network membrane protein Kex2p was not optimally localized in mutant cells. Furthermore, pheromone treatment exacerbated the Kex2p localization defect and caused a corresponding defect in Kex2p-mediated maturation of the alpha-factor precursor. The results reveal a novel requirement for clathrin during the mating response and suggest that phosphorylation of the light chain subunit modulates the activity of clathrin at the trans-Golgi network.     

Compromise of clathrin function and membrane association by clathrin light chain deletion

While clathrin heavy chains from different species are highly conserved in amino acid sequence, clathrin light chains are much more divergent. Thus clathrin light chain may have different functions in different organisms. To investigate clathrin light chain function, we cloned the clathrin light chain, clcA, from Dictyostelium and examined clathrin function in clcA– mutants. Phenotypic deficiencies in development, cytokinesis, and osmoregulation showed that light chain was critical for clathrin function in Dictyostelium . In contrast with budding yeast, we found the light chain did not influence steady-state levels of clathrin, triskelion formation, or contribute to clathrin over-assembly on intracellular membranes. Imaging GFP-CHC in clcA– mutants showed that the heavy chain formed dynamic punctate structures that were remarkably similar to those found in wild-type cells. However, clathrin light chain knockouts showed a decreased association of clathrin with intracellular membranes. Unlike wild-type cells, half of the clathrin in clcA– mutants was cytosolic, suggesting that the absence of light chain compromised the assembly of triskelions onto intracellular membranes. Taken together, these results suggest a role for the Dictyostelium clathrin light chain in regulating the self-assembly of triskelions onto intracellular membranes, and demonstrate a crucial contribution of the light chain to clathrin function in vivo .