Starr DA et al. (2002) Science "Role of ANC-1 in tethering nuclei to the actin cytoskeleton."

Han M, Starr DA

[Science, 2002]

Mutations in anc-1 (nuclear anchorage defective) disrupt the positioning of nuclei and mitochondria in Caenorhabditis elegans. ANC-1 is shown to consist of mostly coiled regions with a nuclear envelope localization domain (called the KASH domain) and an actin-binding domain; this structure was conserved with the Drosophila protein Msp-300 and the mammalian Syne proteins. Antibodies against ANC-1 localized cytoplasmically and were enriched at the nuclear periphery in an UNC-84 dependent manner. Overexpression of the KASH domain or the actin-binding domain caused a dominant negative anchorage defect. Thus, ANC-1 may connect nuclei to the cytoskeleton by interacting with UNC-84 at the nuclear envelope and with actin in the cytoplasm.

Starr DA (2011) Bioarchitecture "Watching nuclei move: Insights into how kinesin-1 and dynein function together."

Starr DA

[Bioarchitecture, 2011]

Moving nuclei to specific intracellular locations is central to many cell and developmental processes. However, the molecular mechanisms of nuclear migration are poorly understood. We took advantage of the ability to film nuclear migration events in Caenorhabditis elegans embryos to gain insights into the mechanisms of nuclear migration. Mutations in unc-83 blocked the initiation of nuclear migration. UNC-83 recruits kinesin-1 and dynein to the nuclear envelope. Live imaging of mutants showed that kinein-1 provides the major force to move nuclei. Dynein is responsible to move nuclei backwards or to mediate nuclear rolling to by pass cellular roadblocks that impede efficient migration. Live imaging was also used to analyze the microtubule network, which is highly polarized and dynamic. This detailed mechanism of nuclear migration may be applicable to nuclear migration in other systems and for the movement of other large cellular cargo.

Starr DA et al. (2001) Development "unc-83 encodes a novel component of the nuclear envelope and is essential for proper nuclear migration."

Horvitz HR, Fixsen W, Malone CJ, Priess JR, Hermann GJ, Han M, Starr DA

[Development, 2001]

Nuclear migration plays an essential role in the growth and development of a wide variety of eukaryotes. Mutations in unc-84, which encodes a conserved component of the nuclear envelope, have been shown to disrupt nuclear migration in two C. elegans tissues. We show that mutations in unc-83 disrupt nuclear migration in a similar manner in migrating P cells, hyp7 precursors and the intestinal primordium, but have no obvious defects in the association of centrosomes with nuclei or the structure of the nuclear lamina of migrating nuclei. We also show that unc-83 encodes a novel transmembrane protein. We identified three unc-83 transcripts that are expressed in a tissue-specific manner. Antibodies against UNC-83 co-localized to the nuclear envelope with lamin and UNC-84. Unlike UNC84, UNC-83 localized to only specific nuclei, many of which were migratory. UNC-83 failed to localize to the nuclear envelope in unc-84 mutants with lesions in the conserved SUN domain of UNC-84, and UNC-83 interacted with the SUN domain of UNC-84 in vitro, suggesting that these two proteins function together during nuclear migration. We favor a model in which UNC-84 directly recruits UNC-83 to the nuclear envelope where they help transfer force between the cytoskeleton and the nucleus.

Starr DA (2019) Exp Biol Med (Maywood) "A network of nuclear envelope proteins and cytoskeletal force generators mediates movements of and within nuclei throughout Caenorhabditis elegans development."

Starr DA

[Exp Biol Med (Maywood), 2019]

Harris TW et al. (2000) J Cell Biol "Mutations in synaptojanin disrupt synaptic vesicle recycling."

Harris TW, Hartweig EA, Jorgensen EM, Horvitz HR

[J Cell Biol, 2000]

Synaptojanin is a polyphosphoinositide phosphatase that is found at synapses and binds to proteins implicated in endocytosis. For these reasons, it has been proposed that synaptojanin is involved in the recycling of synaptic vesicles. Here, we demonstrate that the unc-26 gene encodes the Caenorhabditis elegans ortholog of synaptojanin. unc-26 mutants exhibit defects in vesicle trafficking in several tissues, but most defects are found at synaptic termini. Specifically, we observed defects in the budding of synaptic vesicles from the plasma membrane, in the uncoating of vesicles after fission, in the recovery of vesicles from endosomes, and in the tethering of vesicles to the cytoskeleton. Thus, these results confirm studies of the mouse synaptojanin 1 mutants, which exhibit defects in the uncoating of synaptic vesicles (Cremona, O., G. Di Paolo, M.R. Wenk, A. Luthi, W.T. Kim, K. Takei, L. Daniell, Y. Nemoto, S.B. Shears, R.A. Flavell, D.A. McCormick, and P. De Camilli. 1999. Cell. 99:179-188), and further demonstrate that synaptojanin facilitates multiple steps of synaptic vesicle recycling.

Gregory, Ellen Faith et al. (2020) MicroPubl Biol

Gregory, Ellen Faith, Starr, Daniel Aaron

[MicroPubl Biol, 2020]

Human TMEM258 is involved in stress pathways and has been implicated in inflammatory intestinal disorders (Graham et al., 2016). The Drosophila ortholog Kuduk consists of a transmembrane and an intramembrane domain and localizes to the outer nuclear membrane, where it regulates myonuclear positioning and morphology (Ding et al., 2017). Kuduk is the first characterized cytoplasmic regulator of the LINC (linker of nucleoskeleton and cytoskeleton) complex. LINC complexes are conserved throughout eukaryotes and consist of SUN (Sad-1 and UNC-84) proteins, which localize to the inner nuclear membrane and bind to lamin, and KASH proteins (Klarsicht, ANC-1, Syne homology) that span the outer nuclear membrane and interact with cytoskeletal elements. KASH and SUN bind in the perinuclear space to bridge the nucleus and cytoskeleton and transfer force across the nuclear envelope (Starr, 2009). Drosophila Kuduk has been shown to help anchor the nucleus in place via the LINC complex, but the molecular mechanisms it uses to carry out nuclear migration remain unknown. We hypothesized that tmem-258 (formally Y57E12AM.1) is required for nuclear positioning and migration in C. elegans. We used CRISPR-Cas9 to introduce non-specific mutations in tmem-258 and generated two frameshift mutants, yc63 and yc66, which created early stop codons (Fig. 1A-D). We then assayed nuclear migration in two different tissues. First, nuclei migrate across the dorsal midline in hypodermal (hyp7) precursors during normal C. elegans embryogenesis (Fridolfsson et al., 2018). If hyp7 nuclear migration fails, ectopic nuclei can be seen in the dorsal cord. For example, in an unc-84(n369) null line, an average of 15.0 nuclei were abnormally in the dorsal cord (Malone et al 1999). Neither tmem-258(yc63) nor tmem-258(yc66) animals exhibited mislocalized nuclei, suggesting hyp7 nuclear migration was successful (Fig. 1F). Second, we quantified P-cell nuclear migration in L1 larvae. P-cell nuclei migrate from the lateral to the ventral side of the worm where they divide and differentiate to form the vulva and GABA neurons. At 25C, unc-84(n369) mutants typically are missing 6.50.60 GABA neurons (Bone et al., 2016). To determine whether tmem-258 mutants enhance the P-cell nuclear migration defect of unc-84, we crossed tmem-258(yc63) worms to unc-84(n369) and quantified P-cell nuclear migration failure at 15C by counting GABA neurons with UNC-47::GFP. The tmem-258(yc63); unc-84(n369) double mutant were missing an average of 0.700.3 (mean 95% CI, n=25) GABA neurons, equal to the 0.600.4 GABA neurons of the unc-84(n369) single mutant at 15C. Finally, we tested whether tmem-258 is required for nuclear anchorage in C. elegans by counting the number of syncytial hyp7 nuclei clustering together in adults. The tmem-258 mutants had no significant nuclear anchorage defects (Fig. 1E). We therefore conclude that tmem-258 is not required for nuclear positioning in C. elegans hyp7 cells.

Ho J et al. (2018) MicroPubl Biol "Characterizing Dyneins Role in P-cell Nuclear Migration using an Auxin-Induced Degradation System"

Ma L, Ho J, Starr DA, Valdez VA

[MicroPubl Biol, 2018]

Nuclear migration limits the rate of cellular migration through narrow spaces due to the large size and stiffness of the nucleus (Ungricht and Kutay, 2017). Using Caenorhabditis elegans as a model organism, we can observe P-cell nuclear migration in vivo. During the mid-L1 stage, P-cell nuclei that are about 3-4&#956;m in diameter must migrate from a lateral to ventral position. This migration occurs through a constricted space ~ 200nm wide, about 5% of the diameter of the relaxed nucleus, between body wall muscle and cuticle (Cox and Hardin, 2004). If this migration succeeds, P-cells develop into vulval cells and GABA neurons. Failure of P-cell nuclear migration leads to cell death and missing P-cell lineages, leading to egg laying defective (Egl) and uncoordinated (Unc) animals because of missing vulval cells and GABA neurons, respectively (Sulston and Horvitz, 1981). Two proteins that are known to be involved in P-cell nuclear migration are UNC-84 and UNC-83. These proteins make up the LINC complex to form a bridge between the nucleus and the cytoplasm. Disruption of the LINC complex leads to nuclear migration defects in P-cells (Starr et al., 2001). Previously, our lab showed that P-cell nuclei migrate towards the minus ends of microtubules through the microtubule motor, dynein. Dynein is essential in embryogenesis (Gonczy et al., 1999), therefore our research was previously limited to viable, partial loss-of-function alleles of dynein or dynein-interacting proteins. Animals expressing a hypomorphic allele of dynein, dhc-1(js319), had an average of ~3 P-cells that failed to migrate (Bone et al., 2016).Here, we tested the hypothesis that the unc-83/unc-84 pathway works through dynein to move P-cell nuclei using the auxin-inducible degradation system (AID) to knock down dynein specifically during P-cell nuclear migration (Zhang et al., 2015). The Arabidopsis thaliana TIR1 gene was expressed downstream of the C. elegans P-cell specific hlh-3 promoter (Bone et al., 2016) in the strain UD550 (oxIs12[unc-47::GFP]; ycEx253[phlh-3::TIR-1::mRuby; odr-1::rfp]). Next, UD550 was crossed to a strain with dhc-1(ie28[dhc-1::degron::GFP]) (Zhang et al., 2015) to make UD551 (dhc-1(ie28[dhc-1::degron::GFP]) I; oxIs12[unc-47::GFP] X; ycEx253[phlh-3::TIR-1::mRuby; odr-1::rfp]). UD550 and UD551 animals were synchronized to mid L1 as previously described (Bone et al., 2016) and exposed to 1mM auxin for five hours at 25C. P-cell nuclear migration defects were quantified by counting GABA neurons marked with UNC-47::GFP by fluorescence microscopy in L4 animals after the auxin treatment. Wild-type animals have 19 GABA neurons and missing GABA neurons indicate that P-cell nuclear migration failed (Chang et al., 2013; Bone et al., 2016). As a negative control, UD550 animals, which lack the dhc-1 degron tag, had no P-cell nuclear migration defects when exposed to auxin. This result is similar to UD551 animals that were not exposed to auxin (Figure 1). In support of our hypothesis, larvae exposed to auxin that expressed both the TIR1 gene in P cells and the dhc-1 degron tag (UD551) had an average of 12.3 GABA neurons compared to sibling larvae not exposed to auxin that had an average of 18.1 GABA neurons (Figure 1). Thus, the dynein-degraded larvae had an average of 5.8 missing GABA neurons (p<0.0001), indicative of a severe P-cell nuclear migration defect. These results further strengthen our model that dynein plays a major role in generating forces to move nuclei in P-cells through constricted spaces. Finally, the phlh-3::TIR1 line will be a valuable reagent to knock down other essential proteins to determine their roles during P-cell nuclear migration.