Genomic Analysis of the Opi− Phenotype

Hancock, Leandria C.; Behta, Ryan P; Lopes, John M.

doi:10.1534/genetics.106.057489

Cited by 38 publications

(50 citation statements)

References 97 publications

(125 reference statements)

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“…In this regard, MRPL49, the homolog of NFD1 in yeast, appears to be required for phosphatidylcholine (PC) biosynthesis (Hancock et al, 2006). At this time, it is unclear whether mrpl49 mutants are affected in PC biosynthesis directly or indirectly through an effect on mitochondria.…”

Section: Discussionmentioning

confidence: 99%

NUCLEAR FUSION DEFECTIVE1 Encodes the Arabidopsis RPL21M Protein and Is Required for Karyogamy during Female Gametophyte Development and Fertilization

et al. 2006

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Karyogamy, or nuclear fusion, is essential for sexual reproduction. In angiosperms, karyogamy occurs three times: twice during double fertilization of the egg cell and the central cell and once during female gametophyte development when the two polar nuclei fuse to form the diploid central cell nucleus. The molecular mechanisms controlling karyogamy are poorly understood. We have identified nine female gametophyte mutants in Arabidopsis (Arabidopsis thaliana), nuclear fusion defective1 (nfd1) to nfd9, that are defective in fusion of the polar nuclei. In the nfd1 to nfd6 mutants, failure of fusion of the polar nuclei is the only defect detected during megagametogenesis. nfd1 is also affected in karyogamy during double fertilization. Using transmission electron microscopy, we showed that nfd1 nuclei fail to undergo fusion of the outer nuclear membranes. nfd1 contains a T-DNA insertion in RPL21M that is predicted to encode the mitochondrial 50S ribosomal subunit L21, and a wildtype copy of this gene rescues the mutant phenotype. Consistent with the predicted function of this gene, an NFD1-green fluorescent protein fusion protein localizes to mitochondria and the NFD1/RPL21M gene is expressed throughout the plant. The nfd3, nfd4, nfd5, and nfd6 mutants also contain T-DNA insertions in genes predicted to encode proteins that localize to mitochondria, suggesting a role for this organelle in nuclear fusion.

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Section: Discussionmentioning

confidence: 99%

NUCLEAR FUSION DEFECTIVE1 Encodes the Arabidopsis RPL21M Protein and Is Required for Karyogamy during Female Gametophyte Development and Fertilization

et al. 2006

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“…As discussed above, enrichment of PA at the ER upon PAH1 inactivation prevents Opi1 repression of UAS INO -regulated genes. Derepressed levels of INO1 and OPI3, among other UAS INO -regulated genes, were reported for both fld1 and ldb16 cells, suggesting that the absence of the seipin complex perturbs PA homeostasis and interferes with Opi1 function (51,59,63). However, unrestricted PL synthesis might not be the only cause for abnormal nuclear ER because opi1 cells exhibit wild-type nuclear ER (as well as normal LD morphology).…”

Section: The Contribution Of Er-ld Contact Sites To Ld Formation and mentioning

confidence: 97%

Lipid synthesis and membrane contact sites: a crossroads for cellular physiology

Fernández-Murray

McMaster

2016

Journal of Lipid Research

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high throughput analyses, makes this yeast a powerful organism to unveil the intricacies of this field. The yeast S. cerevisiae has played a foundational role in the field of molecular and cellular biology of lipids, including the identification of membrane contact sites (MCSs) and how they link lipid metabolism with organelle dynamics. We present advances in two topics where extensive and outstanding contributions have recently been made where their relevance transcends the yeast lipid field. We first review new information about the phosphatidic acid (PA) phosphatase, Pah1, the yeast homolog of human lipin, and its role in directing lipid flux into membrane synthesis or storage. We review the contribution of Pah1 to lipid droplet (LD) formation and its interaction with the seipin complex, Fld1/Ldb16, to regulate endoplasmic reticulum (ER)-LD contact site dynamics. Second, we recapitulate recent developments revealing MCS connections between the ER and mitochondria with other cellular compartments, and how these intersect with the maintenance of lipid homeostasis. Furthermore, we explore MCS redundancies that allow cells to cope with changing metabolic demand. PA METABOLISM CO-COORDINATES MEMBRANE AND LD SYNTHESISPA is the common precursor for the synthesis of membrane phospholipids (PLs) and the major component of The pervasive importance of lipids in cell biology has become evident. From structural roles defining cellular compartments and surfaces with specific biological properties to functional roles in signal transduction processes and modulation of regulatory networks, the involvement of lipids in varied cellular functions is well-established. Concurrently, we have gained a broad understanding about the repertoire of proteins involved in synthesis, degradation, transport, and sensing of lipids, as well as the regulatory mechanisms that interconnect lipid metabolism with other cellular processes. The amenability of Saccharomyces cerevisiae to classical approaches of molecular genetics, and toThe work on the science described in this review was supported by a Discovery Grant from the Canadian Network for Research and Innovation in Machining Technology, Natural Sciences and Engineering Research Council of Canada to C.R.M. Manuscript received 19 July 2016 and in revised form 6 August 2016. Published, JLR Papers in Press, August 12, 2016 DOI 10.1194 Lipid synthesis and membrane contact sites: a crossroads for cellular physiology Abbreviations: cER, cortical endoplasmic reticulum; ChiMERA, construct helping in mitochondria-endoplasmic reticulum association; CL, cardiolipin; DAG, diacylglycerol; EMC, endoplasmic reticulum membrane protein complex; ER, endoplasmic reticulum; ERMES, endoplasmic reticulum-mitochondria encounter structure; HOPS, homotypic fusion and vacuole protein sorting; Lam, lipid transfer protein anchored at a membrane contact site; LD, lipid droplet; Ltc, lipid transfer at contact site; LTP, lipid transfer protein; Mcp, maintenance of mitochondrial morphology 10 complementing protein; M...

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“…NFD1 has a homolog in yeasts ( MRPL49 ) involved in phosphatidylcholine (PC) biosynthesis (Hancock et al, 2006). PC is the main lipid constituent of the plant nuclear envelope (Philipp et al, 1976) and is known to stabilize lipid membranes so that in PC-rich membranes fusion is inhibited (Duzgunes et al, 1981).…”

Section: Looking For Cellular and Molecular Basis Of Nuclear Fusionmentioning

confidence: 99%

Pathways to doubled haploidy: chromosome doubling during androgenesis

Seguí-Simarro

Nuez

2008

Cytogenet Genome Res

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Production of doubled haploid (DH) plants through androgenesis induction is a promising and convenient alternative to conventional selfing techniques for the generation of pure lines for breeding programs. This process comprises two main steps: induction of androgenesis and duplication of the haploid genome. Such duplication is sometimes indirectly induced by the treatments used to promote androgenic development. But usually, an additional step of direct chromosome doubling must be included in the protocol. Duplication of the haploid genome of androgenic individuals has been thought to occur through three mechanisms: endoreduplication, nuclear fusion and c-mitosis. In this review we will revise and analyze the evidences supporting each of the proposed mechanisms and their relevance during androgenesis induction, embryo/callus development and plant regeneration. Special attention will be devoted to nuclear fusion, whose evidences are accumulating in the last years.

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Genomic Analysis of the Opi− Phenotype

Cited by 38 publications

References 97 publications

NUCLEAR FUSION DEFECTIVE1 Encodes the Arabidopsis RPL21M Protein and Is Required for Karyogamy during Female Gametophyte Development and Fertilization

NUCLEAR FUSION DEFECTIVE1 Encodes the Arabidopsis RPL21M Protein and Is Required for Karyogamy during Female Gametophyte Development and Fertilization

Lipid synthesis and membrane contact sites: a crossroads for cellular physiology

Pathways to doubled haploidy: chromosome doubling during androgenesis

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