Susan Lindquist: Visionary scientist and peerless mentor

The science universe is dimmer after one of our brightest stars, Susan Lee Lindquist, was taken by cancer on October 27, 2016. Sue was an innovative, creative, out-of-the-box scientific thinker. She had unique biological intuition—an instinct for both the way things worked and the right questions to ask to uncover new research insights. Her wide-ranging career began with the study of protein folding and molecular chaperones, and she went on to show that protein folding can have profound and unexpected biological effects on such diverse processes as cancer, evolution, and neurodegenerative disease. As Sue's laboratory manager, I would like to offer a ground-floor perspective on what made her an exceptional scientist, mentor, and leader. She created a harmonious, collegial environment where collaborative synergy fueled meaningful progress that will impact science for decades to come.

Functional links between Aβ toxicity, endocytic trafficking, and Alzheimer's disease risk factors in yeast

Aβ (beta-amyloid peptide) is an important contributor to Alzheimer's disease (AD). We modeled Aβ toxicity in yeast by directing the peptide to the secretory pathway. A genome-wide screen for toxicity modifiers identified the yeast homolog of phosphatidylinositol binding clathrin assembly protein (PICALM) and other endocytic factors connected to AD whose relationship to Aβ was previously unknown. The factors identified in yeast modified Aβ toxicity in glutamatergic neurons of Caenorhabditis elegans and in primary rat cortical neurons. In yeast, Aβ impaired the endocytic trafficking of a plasma membrane receptor, which was ameliorated by endocytic pathway factors identified in the yeast screen. Thus, links between Aβ, endocytosis, and human AD risk factors can be ascertained with yeast as a model system.

Morphogenesis signaling components influence cell cycle regulation by cyclin dependent kinase

BACKGROUND

The yeast cell cycle is largely controlled by the cyclin-dependent kinase (CDK) Cdc28. Recent evidence suggests that both CDK complex stability as well as function during mitosis is determined by precise regulation of Swe1, a CDK inhibitory kinase and cyclin binding partner. A model of mitotic progression has been provided by study of filamentous yeast. When facing nutrient-limited conditions, Ras2-mediated PKA and MAPK signaling cascades induce a switch from round to filamentous morphology resulting in delayed mitotic progression.

RESULTS

To delineate how the dimorphic switch contributes to cell cycle regulation, temperature sensitive cdc28 mutants exhibiting constitutive filamentation were subjected to epistasis analyses with RAS2 signaling effectors. It was found that Swe1-mediated inhibitory tyrosine phosphorylation of Cdc28 during filamentous growth is in part mediated by Ras2 activation of PKA, but not Kss1-MAPK, signaling. This pathway is further influenced by Cks1, a conserved CDK-binding partner of elusive function with multiple proposed roles in CDK activation, transcriptional regulation and ubiquitin-mediated proteasome degradation.

CONCLUSION

The dynamic balance between Cks1- and Swe1-dependent regulation of Cdc28 and, thereby, the timing of mitosis during yeast dimorphism is regulated in part by Ras2/cAMP-mediated PKA signaling, a key pathway controlling filamentous growth.

Golgi maturation visualized in living yeast

The Golgi apparatus is composed of biochemically distinct early (cis, medial) and late (trans, TGN) cisternae. There is debate about the nature of these cisternae. The stable compartments model predicts that each cisterna is a long-lived structure that retains a characteristic set of Golgi-resident proteins. In this view, secretory cargo proteins are transported by vesicles from one cisterna to the next. The cisternal maturation model predicts that each cisterna is a transient structure that matures from early to late by acquiring and then losing specific Golgi-resident proteins. In this view, secretory cargo proteins traverse the Golgi by remaining within the maturing cisternae. Various observations have been interpreted as supporting one or the other mechanism. Here we provide a direct test of the two models using three-dimensional time-lapse fluorescence microscopy of the yeast Saccharomyces cerevisiae. This approach reveals that individual cisternae mature, and do so at a consistent rate. In parallel, we used pulse-chase analysis to measure the transport of two secretory cargo proteins. The rate of cisternal maturation matches the rate of protein transport through the secretory pathway, suggesting that cisternal maturation can account for the kinetics of secretory traffic.

De novo formation of transitional ER sites and Golgi structures in Pichia pastoris

Transitional ER (tER) sites are ER subdomains that are functionally, biochemically and morphologically distinct from the surrounding rough ER. Here we have used confocal video microscopy to study the dynamics of tER sites and Golgi structures in the budding yeast Pichia pastoris. The biogenesis of tER sites is tightly linked to the biogenesis of Golgi, and both compartments can apparently form de novo. tER sites often fuse with one another, but they maintain a consistent average size through shrinkage after fusion and growth after de novo formation. Golgi dynamics are similar, although late Golgi elements often move away from tER sites towards regions of polarized growth. Our results can be explained by assuming that tER sites give rise to Golgi cisternae that continually mature.

Rapidly maturing variants of the Discosoma red fluorescent protein (DsRed)

The red fluorescent protein DsRed has spectral properties that are ideal for dual-color experiments with green fluorescent protein (GFP). But wild-type DsRed has several drawbacks, including slow chromophore maturation and poor solubility. To overcome the slow maturation, we used random and directed mutagenesis to create DsRed variants that mature 10-15 times faster than the wild-type protein. An asparagine-to-glutamine substitution at position 42 greatly accelerates the maturation of DsRed, but also increases the level of green emission. Additional amino acid substitutions suppress this green emission while further accelerating the maturation. To enhance the solubility of DsRed, we reduced the net charge near the N terminus of the protein. The optimized DsRed variants yield bright fluorescence even in rapidly growing organisms such as yeast.

Vector for pop-in/pop-out gene replacement in Pichia pastoris

Gene replacement in yeast is often accomplished by using a counterselectable marker such as URA3. Although ura3 strains of Pichia pastoris have been generated, these strains are inconvenient to work with because they grow slowly, even in the presence of uracil. To overcome this limitation, we have developed an alternative counterselectable marker that can be used in any P. pastoris strain. This marker is the T-urf13 gene from the mitochondrial genome of male-sterile maize. Previous work showed that expression of a mitochondrially targeted form of T-urf13 in Saccharomyces cerevisiae rendered the cells sensitive to the insecticide methomyl, and similar results have now been obtained with P. pastoris. We have incorporated T-urf13 into a vector that also contains an ARG4 marker for positive selection. The resulting plasmid allows for pop-in/pop-out gene replacement in P. pastoris.

A role for actin, Cdc1p, and Myo2p in the inheritance of late Golgi elements in Saccharomyces cerevisiae

In Saccharomyces cerevisiae, Golgi elements are present in the bud very early in the cell cycle. We have analyzed this Golgi inheritance process using fluorescence microscopy and genetics. In rapidly growing cells, late Golgi elements show an actin-dependent concentration at sites of polarized growth. Late Golgi elements are apparently transported into the bud along actin cables and are also retained in the bud by a mechanism that may involve actin. A visual screen for mutants defective in the inheritance of late Golgi elements yielded multiple alleles of CDC1. Mutations in CDC1 severely depolarize the actin cytoskeleton, and these mutations prevent late Golgi elements from being retained in the bud. The efficient localization of late Golgi elements to the bud requires the type V myosin Myo2p, further suggesting that actin plays a role in Golgi inheritance. Surprisingly, early and late Golgi elements are inherited by different pathways, with early Golgi elements localizing to the bud in a Cdc1p- and Myo2p-independent manner. We propose that early Golgi elements arise from ER membranes that are present in the bud. These two pathways of Golgi inheritance in S. cerevisiae resemble Golgi inheritance pathways in vertebrate cells.

Isolation of Pichia pastoris genes involved in ER-to-Golgi transport

Pichia pastoris has discrete transitional ER sites and coherent Golgi stacks, making this yeast an ideal system for studying the organization of the early secretory pathway. To provide molecular tools for this endeavour, we isolated P. pastoris homologues of the SEC12, SEC13, SEC17, SEC18 and SAR1 genes. The P. pastoris SEC12, SEC13, SEC17 and SEC18 genes were shown to complement the corresponding S. cerevisiae mutants. The SEC17 and SAR1 genes contain introns at the same relative positions in both P. pastoris and S. cerevisiae, whereas the SEC13 gene contains an intron in P. pastoris but not in S. cerevisiae. Intron structure is similar in the two yeasts, although the favoured 5' splice sequence appears to be GTAAGT in P. pastoris vs. GTATGT in S. cerevisiae. The predicted amino acid sequences of Sec13p, Sec17p, Sec18p and Sar1p show strong conservation in the two yeasts. By contrast, the predicted lumenal domain of Sec12p is much larger in P. pastoris, suggesting that this domain may help localize Sec12p to transitional ER sites. A comparison of the SEC12 loci in various budding yeasts indicates that the SEC12-related gene SED4 is probably unique to the Saccharomyces lineage.

Golgi structure correlates with transitional endoplasmic reticulum organization in Pichia pastoris and Saccharomyces cerevisiae

Golgi stacks are often located near sites of "transitional ER" (tER), where COPII transport vesicles are produced. This juxtaposition may indicate that Golgi cisternae form at tER sites. To explore this idea, we examined two budding yeasts: Pichia pastoris, which has coherent Golgi stacks, and Saccharomyces cerevisiae, which has a dispersed Golgi. tER structures in the two yeasts were visualized using fusions between green fluorescent protein and COPII coat proteins. We also determined the localization of Sec12p, an ER membrane protein that initiates the COPII vesicle assembly pathway. In P. pastoris, Golgi stacks are adjacent to discrete tER sites that contain COPII coat proteins as well as Sec12p. This arrangement of the tER-Golgi system is independent of microtubules. In S. cerevisiae, COPII vesicles appear to be present throughout the cytoplasm and Sec12p is distributed throughout the ER, indicating that COPII vesicles bud from the entire ER network. We propose that P. pastoris has discrete tER sites and therefore generates coherent Golgi stacks, whereas S. cerevisiae has a delocalized tER and therefore generates a dispersed Golgi. These findings open the way for a molecular genetic analysis of tER sites.