The Chlamydomonas genome reveals the evolution of key animal and plant functions

Chlamydomonas reinhardtii is a unicellular green alga whose lineage diverged from land plants over 1 billion years ago. It is a model system for studying chloroplast-based photosynthesis, as well as the structure, assembly, and function of eukaryotic flagella (cilia), which were inherited from the common ancestor of plants and animals, but lost in land plants. We sequenced the approximately 120-megabase nuclear genome of Chlamydomonas and performed comparative phylogenomic analyses, identifying genes encoding uncharacterized proteins that are likely associated with the function and biogenesis of chloroplasts or eukaryotic flagella. Analyses of the Chlamydomonas genome advance our understanding of the ancestral eukaryotic cell, reveal previously unknown genes associated with photosynthetic and flagellar functions, and establish links between ciliopathy and the composition and function of flagella.

NUCLEAR PORE ANCHOR, the Arabidopsis homolog of Tpr/Mlp1/Mlp2/megator, is involved in mRNA export and SUMO homeostasis and affects diverse aspects of plant development

Vertebrate Tpr and its yeast homologs Mlp1/Mlp2, long coiled-coil proteins of nuclear pore inner basket filaments, are involved in mRNA export, telomere organization, spindle pole assembly, and unspliced RNA retention. We identified Arabidopsis thaliana NUCLEAR PORE ANCHOR (NUA) encoding a 237-kD protein with similarity to Tpr. NUA is located at the inner surface of the nuclear envelope in interphase and in the vicinity of the spindle in prometaphase. Four T-DNA insertion lines were characterized, which comprise an allelic series of increasing severity for several correlating phenotypes, such as early flowering under short days and long days, increased abundance of SUMO conjugates, altered expression of several flowering regulators, and nuclear accumulation of poly(A)+ RNA. nua mutants phenocopy mutants of EARLY IN SHORT DAYS4 (ESD4), an Arabidopsis SUMO protease concentrated at the nuclear periphery. nua esd4 double mutants resemble nua and esd4 single mutants, suggesting that the two proteins act in the same pathway or complex, supported by yeast two-hybrid interaction. Our data indicate that NUA is a component of nuclear pore-associated steps of sumoylation and mRNA export in plants and that defects in these processes affect the signaling events of flowering time regulation and additional developmental processes.

Novel plant SUN-KASH bridges are involved in RanGAP anchoring and nuclear shape determination

Inner nuclear membrane Sad1/UNC-84 (SUN) proteins interact with outer nuclear membrane (ONM) Klarsicht/ANC-1/Syne homology (KASH) proteins, forming linkers of nucleoskeleton to cytoskeleton conserved from yeast to human and involved in positioning of nuclei and chromosomes. Defects in SUN-KASH bridges are linked to muscular dystrophy, progeria, and cancer. SUN proteins were recently identified in plants, but their ONM KASH partners are unknown. Arabidopsis WPP domain-interacting proteins (AtWIPs) are plant-specific ONM proteins that redundantly anchor Arabidopsis RanGTPase-activating protein 1 (AtRanGAP1) to the nuclear envelope (NE). In this paper, we report that AtWIPs are plant-specific KASH proteins interacting with Arabidopsis SUN proteins (AtSUNs). The interaction is required for both AtWIP1 and AtRanGAP1 NE localization. AtWIPs and AtSUNs are necessary for maintaining the elongated nuclear shape of Arabidopsis epidermal cells. Together, our data identify the first KASH members in the plant kingdom and provide a novel function of SUN-KASH complexes, suggesting that a functionally diverged SUN-KASH bridge is conserved beyond the opisthokonts.

A domain unique to plant RanGAP is responsible for its targeting to the plant nuclear rim

Ran is a small signaling GTPase that is involved in nucleocytoplasmic transport. Two additional functions of animal Ran in the formation of spindle asters and the reassembly of the nuclear envelope in mitotic cells have been recently reported. In contrast to Ras or Rho, Ran is not associated with membranes. Instead, the spatial sequestering of its accessory proteins, the Ran GTPase-activating protein RanGAP and the nucleotide exchange factor RCC1, appears to define the local concentration of RanGTP vs. RanGDP involved in signaling. Mammalian RanGAP is bound to the nuclear pore by a mechanism involving the attachment of small ubiquitin-related modifier protein (SUMO) to its C terminus and the subsequent binding of the SUMOylated domain to the nucleoporin Nup358. Here we show that plant RanGAP utilizes a different mechanism for nuclear envelope association, involving a novel targeting domain that appears to be unique to plants. The N-terminal WPP domain is highly conserved among plant RanGAPs and the small, plant-specific nuclear envelope-associated protein MAF1, but not present in yeast or animal RanGAP. Confocal laser scanning microscopy of green fluorescent protein (GFP) fusion proteins showed that it is necessary for RanGAP targeting and sufficient to target the heterologous protein GFP to the plant nuclear rim. The highly conserved tryptophan and proline residues of the WPP motif are necessary for its function. The 110-aa WPP domain is the first nuclear-envelope targeting domain identified in plants. Its fundamental difference to its mammalian counterpart implies that different mechanisms have evolved in plants and animals to anchor RanGAP at the nuclear surface.

Anchorage of Plant RanGAP to the Nuclear Envelope Involves Novel Nuclear-Pore-Associated Proteins

The Ran GTPase controls multiple cellular processes including nucleocytoplasmic transport, spindle assembly, and nuclear envelope (NE) formation [1-4]. Its roles are accomplished by the asymmetric distribution of RanGTP and RanGDP enabled by the specific locations of the Ran GTPase-activating protein RanGAP and the nucleotide exchange factor RCC1 [5-8]. Mammalian RanGAP1 targeting to the NE and kinetochores requires interaction of its sumoylated C-terminal domain with the nucleoporin Nup358/RanBP2 [9-14]. In contrast, Arabidopsis RanGAP1 is associated with the NE and cell plate, mediated by an N-terminal, plant-specific WPP domain [15-18]. In the absence of RanBP2 in plants, the mechanism for spatially sequestering plant RanGAP is unknown. Here, Arabidopsis WPP-domain interacting proteins (WIPs) that interact with RanGAP1 in vivo and colocalize with RanGAP1 at the NE and cell plate were identified. Immunogold labeling indicates that WIP1 is associated with the outer NE. In a wip1-1/wip2-1/wip3-1 triple mutant, RanGAP1 is dislocated from the NE in undifferentiated root-tip cells, whereas NE targeting in differentiated root cells and targeting to the cell plate remain intact. We propose that WIPs are novel plant nucleoporins involved in RanGAP1 NE anchoring in specific cell types. Our data support a separate evolution of RanGAP targeting mechanisms in different kingdoms.

Coiled-coil protein composition of 22 proteomes--differences and common themes in subcellular infrastructure and traffic control

Background

Long alpha-helical coiled-coil proteins are involved in diverse organizational and regulatory processes in eukaryotic cells. They provide cables and networks in the cyto- and nucleoskeleton, molecular scaffolds that organize membrane systems and tissues, motors, levers, rotating arms, and possibly springs. Mutations in long coiled-coil proteins have been implemented in a growing number of human diseases. Using the coiled-coil prediction program MultiCoil, we have previously identified all long coiled-coil proteins from the model plant Arabidopsis thaliana and have established a searchable Arabidopsis coiled-coil protein database.

Results

Here, we have identified all proteins with long coiled-coil domains from 21 additional fully sequenced genomes. Because regions predicted to form coiled-coils interfere with sequence homology determination, we have developed a sequence comparison and clustering strategy based on masking predicted coiled-coil domains. Comparing and grouping all long coiled-coil proteins from 22 genomes, the kingdom-specificity of coiled-coil protein families was determined. At the same time, a number of proteins with unknown function could be grouped with already characterized proteins from other organisms.

Conclusion

MultiCoil predicts proteins with extended coiled-coil domains (more than 250 amino acids) to be largely absent from bacterial genomes, but present in archaea and eukaryotes. The structural maintenance of chromosomes proteins and their relatives are the only long coiled-coil protein family clearly conserved throughout all kingdoms, indicating their ancient nature. Motor proteins, membrane tethering and vesicle transport proteins are the dominant eukaryote-specific long coiled-coil proteins, suggesting that coiled-coil proteins have gained functions in the increasingly complex processes of subcellular infrastructure maintenance and trafficking control of the eukaryotic cell.

Scaffolds, levers, rods and springs: diverse cellular functions of long coiled-coil proteins

Long alpha-helical coiled-coil proteins are involved in a variety of organizational and regulatory processes in eukaryotic cells. They provide cables and networks in the cyto- and nucleoskeleton, molecular scaffolds that organize membrane systems, motors, levers, rotating arms and possibly springs. A growing number of human diseases are found to be caused by mutations in long coiled-coil proteins. This review summarizes our current understanding of the multifaceted group of long coiled-coil proteins in the cytoskeleton, nucleus, Golgi and cell division apparatus. The biophysical features of coiled-coil domains provide first clues toward their contribution to the diverse protein functions and promise potential future applications in the area of nanotechnology. Combining the power of fully sequenced genomes and structure prediction algorithms, it is now possible to comprehensively summarize and compare the complete inventory of coiled-coil proteins of different organisms.

Control of expression of the Tn10-encoded tetracycline resistance genes. Equilibrium and kinetic investigation of the regulatory reactions

The transposon Tn10-encoded TET repressor controls the expression of tetracycline resistance as well as its own synthesis. The antibiotic tetracycline functions as an inducer for both genes, which are transcribed in divergent directions from a common start area. The interaction of the TET repressor with the regulatory sequence of the tetracycline resistance operon is investigated by equilibrium and kinetic methods. The wild-type control sequence contains two nearly identical operators separated by only ten base-pairs. A deletion mutant lacking one of the operators is constructed by controlled digestion with exonuclease Bal31. It serves to prove that the two TET operators are each occupied by a TET repressor dimer in the wild-type tet operon regulatory sequence. The association constants are approximately identical for both operators between 10(12) and 10(13) M-1 as derived from kinetic data. The half-life of the TET repressor--tet operator complex is 12 minutes when competed with tet operator DNA and two minutes when competed with the inducer tetracycline. The dissociation of the repressor--operator complex has no apparent activation enthalpy but has an activation entropy of -320 J/mol K, indicating the involvement of solvent or counterion condensation. The dissociation rate constant of the tetracycline--TET repressor complex depends strongly on temperature. The activation enthalpy is 160 kJ/mol, indicating extremely strong binding of the drug. This result is discussed with respect to the necessary sensitivity of a regulated resistance gene. The native structure of the TET repressor is a dimer, as demonstrated by molecular exclusion chromatography. The elution behavior of the TET repressor--tetracycline complex indicates clearly that the repressor--inducer complex remains a dimer. The results are discussed with respect to the regulatory functions of the components.

MFP1 is a thylakoid-associated, nucleoid-binding protein with a coiled-coil structure

Plastid DNA, like bacterial and mitochondrial DNA, is organized into protein-DNA complexes called nucleoids. Plastid nucleoids are believed to be associated with the inner envelope in developing plastids and the thylakoid membranes in mature chloroplasts, but the mechanism for this re-localization is unknown. Here, we present the further characterization of the coiled-coil DNA-binding protein MFP1 as a protein associated with nucleoids and with the thylakoid membranes in mature chloroplasts. MFP1 is located in plastids in both suspension culture cells and leaves and is attached to the thylakoid membranes with its C-terminal DNA-binding domain oriented towards the stroma. It has a major DNA-binding activity in mature Arabidopsis chloroplasts and binds to all tested chloroplast DNA fragments without detectable sequence specificity. Its expression is tightly correlated with the accumulation of thylakoid membranes. Importantly, it is associated in vivo with nucleoids, suggesting a function for MFP1 at the interface between chloroplast nucleoids and the developing thylakoid membrane system.

Plant homeodomain protein involved in transcriptional regulation of a pathogen defense-related gene

Transcription of the parsley pr2 gene, encoding pathogenesis-related protein 2 (PR2), is rapidly stimulated by fungal or bacterial elicitors. Previous work has revealed a 125-bp region within the pr2 promoter; this region encompasses all important cis-regulatory elements required for fungal elicitor-mediated expression. We now report the identification of a functionally relevant 11-bp DNA motif (CTAATTGTTTA) contained within this region; it specifically binds to factors present in both parsley and Arabidopsis nuclear protein extracts. From both plant species, full-length cDNA clones were isolated that encode proteins with high affinity fo this DNA motif. The proteins from both species contain stretches of 61 amino acids that are characteristic of homeodomain (HD) proteins. Binding studies and use of a polyclonal antiserum raised against a fusion polypeptide of glutathione S-transferase with the HD portion of the parsley protein indicated that the 11-bp DNA motif is a potential in vivo target site and that the HD protein is contained within the observed complex formed between the DNA motif and nuclear protein extracts. Transient expression studies using the authentic and a mutated target site suggested a functional role of the HD-DNA interaction in the regulation of the pr2 gene expression.

A proteomic study of the arabidopsis nuclear matrix

The eukaryotic nucleus has been proposed to be organized by two interdependent nucleoprotein structures, the DNA-based chromatin and the RNA-dependent nuclear matrix. The functional composition and molecular organization of the second component have not yet been resolved. Here, we describe the isolation of the nuclear matrix from the model plant Arabidopsis, its initial characterization by confocal and electron microscopy, and the identification of 36 proteins by mass spectrometry. Electron microscopy of resinless samples confirmed a structure very similar to that described for the animal nuclear matrix. Two-dimensional gel electrophoresis resolved approximately 300 protein spots. Proteins were identified in batches by ESI tandem mass spectrometry after resolution by 1D SDS-PAGE. Among the identified proteins were a number of demonstrated or predicted Arabidopsis homologs of nucleolar proteins such as IMP4, Nop56, Nop58, fibrillarins, nucleolin, as well as ribosomal components and a putative histone deacetylase. Others included homologs of eEF-1, HSP/HSC70, and DnaJ, which have also been identified in the nucleolus or nuclear matrix of human cells, as well as a number of novel proteins with unknown function. This study is the first proteomic approach towards the characterization of a higher plant nuclear matrix. It demonstrates the striking similarities both in structure and protein composition of the operationally defined nuclear matrix across kingdoms whose unicellular ancestors have separated more than one billion years ago.

The tomato I-box binding factor LeMYBI is a member of a novel class of myb-like proteins

The RBCS3A gene of tomato belongs to a small gene family consisting of five members. Although the RBCS1, RBCS2 and RBCS3A promoters contain closely related cis regulatory sequences, the expression patterns of the genes are different. Whereas the RBCS1 and RBCS2 genes are expressed in both leaves and young fruit, the RBCS3A promoter is highly active in leaves, but not in young fruit. This lack of transcription could be due to a mutation in the RBCS3A promoter creating the so-called F-box, a protein binding site located between the activating cis elements, the I-box and G-box. In order to identify proteins that bind to the RBCS3A I-box/F-box region, the yeast one-hybrid system was used. One clone, LeMYBI was isolated which contains strong similarity to plant myb transcription factors. The encoded LeMYBI protein is at least 188 amino acids in length and contains two myb-like domains located at the amino terminus and close to the carboxy terminus, separated by a negatively charged domain. The protein contains a SHAQKYF amino acid signature motif in the second myb-like repeat, which is highly conserved in a number of recently identified plant myb-related genes, thus defining a new class of plant DNA-binding proteins. LeMYBI binds specifically to the I-box sequence of the RBCS1, RBCS2 and RBCS3A promoters, therefore representing the first cloned I-box binding factor. LeMYBI acts as a transcriptional activator in yeast and plants, and binds to the I-box with a DNA-binding domain located in the carboxyterminal domain.

Cell Biology of the Plant Nucleus

The eukaryotic nucleus is enclosed by the nuclear envelope, which is perforated by the nuclear pores, the gateways of macromolecular exchange between the nucleoplasm and cytoplasm. The nucleoplasm is organized in a complex three-dimensional fashion that changes over time and in response to stimuli. Within the cell, the nucleus must be viewed as an organelle (albeit a gigantic one) that is a recipient of cytoplasmic forces and capable of morphological and positional dynamics. The most dramatic reorganization of this organelle occurs during mitosis and meiosis. Although many of these aspects are less well understood for the nuclei of plants than for those of animals or fungi, several recent discoveries have begun to place our understanding of plant nuclei firmly into this broader cell-biological context.

Identification of unique SUN-interacting nuclear envelope proteins with diverse functions in plants

Although a plethora of nuclear envelope (NE) transmembrane proteins (NETs) have been identified in opisthokonts, plant NETs are largely unknown. The only known NET homologues in plants are Sad1/UNC-84 (SUN) proteins, which bind Klarsicht/ANC-1/Syne-1 homology (KASH) proteins. Therefore, de novo identification of plant NETs is necessary. Based on similarities between opisthokont KASH proteins and the only known plant KASH proteins, WPP domain-interacting proteins, we used a computational method to identify the KASH subset of plant NETs. Ten potential plant KASH protein families were identified, and five candidates from four of these families were verified for their NE localization, depending on SUN domain interaction. Of those, Arabidopsis thaliana SINE1 is involved in actin-dependent nuclear positioning in guard cells, whereas its paralogue SINE2 contributes to innate immunity against an oomycete pathogen. This study dramatically expands our knowledge of plant KASH proteins and suggests that plants and opisthokonts have recruited different KASH proteins to perform NE regulatory functions.

A 125 bp promoter fragment is sufficient for strong elicitor-mediated gene activation in parsley

We describe the nucleotide sequence and some structural characteristics of a single copy gene encoding pathogenesis-related protein 2 (PR2) in parsley (Petroselinum crispum). Transcriptional activation of this gene in cultured parsley cells treated with fungal elicitor leads to a rapid, large and transient accumulation of PR2 mRNA. The deduced PR2 protein belongs to a novel class of evolutionarily conserved polypeptides which are closely related to disease resistance in plants. Functional analysis of a series of truncated PR2 promoter fusions with the beta-glucuronidase reporter gene, using parsley protoplasts for transient expression studies, identified a 5' upstream element between positions -168 and -52 necessary for strong elicitor responsiveness. This small promoter fragment is active in conjunction with its own TATA box region as well as with the corresponding region from a heterologous promoter. The PR2 regulatory region exhibits no sequence similarity to any other elicitor-responsive promoter known to date.

Adding pieces to the puzzling plant nuclear envelope

The nuclear envelope (NE) and the nuclear pores are important structures that both separate and selectively connect the nucleoplasm and the cytoplasm. NE and nuclear pore research in plants have recently seen an elevated level of interest. This is based both on new findings demonstrating the importance of nucleocytoplasmic trafficking for several signal transduction events, and on increasing evidence that NE and nuclear pore components play important roles during plant cell division. Here, we review the most recent reports in the field and compare them to the more advanced knowledge about yeast and animal model systems. They deal with the refined ultrastructure of the NE and NPC, with the discovery of novel NE components, and, importantly, with novel roles and fates of NE-associated and NPC-associated proteins during plant mitosis and cytokinesis.

Regulation of nucleocytoplasmic trafficking in plants

The timing and position of molecular components within the cell are clearly important in the context of signal transduction. One challenge in attaining correct cellular positioning is the nuclear envelope, which separates the cell into two fundamentally different compartments. Molecular passaging from one to the other is highly selective due to the required recognition by the nucleocytoplasmic transport machinery. It is becoming increasingly clear that a highly diverse set of mechanisms have developed to allow environmental (biotic and abiotic) and endogenous signals to alter the nucleocytoplasmic partitioning of key molecules. In many cases this occurs by adjusting the access of the regulated species to the canonical import/export machinery. Recent studies are uncovering the sophistication and complexity of the processes that use the canonical transport machinery in the service of a diversity of signaling pathways.

Two distinct interacting classes of nuclear envelope-associated coiled-coil proteins are required for the tissue-specific nuclear envelope targeting of Arabidopsis RanGAP

Ran GTPase plays essential roles in multiple cellular processes, including nucleocytoplasmic transport, spindle formation, and postmitotic nuclear envelope (NE) reassembly. The cytoplasmic Ran GTPase activating protein RanGAP is critical to establish a functional RanGTP/RanGDP gradient across the NE and is associated with the outer surface of the NE in metazoan and higher plant cells. Arabidopsis thaliana RanGAP association with the root tip NE requires a family of likely plant-specific nucleoporins combining coiled-coil and transmembrane domains (CC-TMD) and WPP domain-interacting proteins (WIPs). We have now identified, by tandem affinity purification coupled with mass spectrometry, a second family of CC-TMD proteins, structurally similar, yet clearly distinct from the WIP family, that is required for RanGAP NE association in root tip cells. A combination of loss-of-function mutant analysis and protein interaction data indicates that at least one member of each NE-associated CC-TMD protein family is required for RanGAP targeting in root tip cells, while both families are dispensable in other plant tissues. This suggests an unanticipated complexity of RanGAP NE targeting in higher plant cells, contrasting both the single nucleoporin anchor in metazoans and the lack of targeting in fungi and proposes an early evolutionary divergence of the underlying plant and animal mechanisms.

Differential regulation of the Tn10-encoded tetracycline resistance genes tetA and tetR by the tandem tet operators O1 and O2

The Tn10-encoded tet transcriptional control sequence consists of bidirectional, overlapping promoters which are superimposed by a tandem operator arrangement. Three mutations have been constructed by oligonucleotide-directed mutagenesis which reduce binding of Tet repressor to either one or both of the tandem tet operators 1000-fold as determined by DNAseI footprinting in vitro. The affinity of Tet repressor for mutant tet operators is not affected by the presence of an already occupied neighbouring wild-type operator, indicating little or no cooperativity. The regulation of the divergently oriented tet promoters PA and PR by the tet operators O1 and O2 and Tet repressor provided in trans is determined using transcriptional fusions of the promoters to lacZ and galK indicator genes located with different polarity on the same plasmid. The results demonstrate that expression of the resistance gene tetA is regulated by Tet repressor bound to either O1 or O2. Expression of the repressor gene tetR is only marginally reduced when Tet repressor is bound to O2. This result is discussed with respect to the double promoter structure found for PR. Occupation of O1 with Tet repressor turns off transcription from PR completely. The implications of these findings on the establishment of tetracycline resistance upon induction are discussed.

How plants LINC the SUN to KASH

Linkers of the nucleoskeleton to the cytoskeleton (LINC) complexes formed by SUN and KASH proteins are conserved eukaryotic protein complexes that bridge the nuclear envelope (NE) via protein-protein interactions in the NE lumen. Revealed by opisthokont studies, LINC complexes are key players in multiple cellular processes, such as nuclear and chromosomal positioning and nuclear shape determination, which in turn influence the generation of gametes and several aspects of development. Although comparable processes have long been known in plants, the first plant nuclear envelope bridging complexes were only recently identified. WPP domain-interacting proteins at the outer NE have little homology to known opisthokont KASH proteins, but form complexes with SUN proteins at the inner NE that have plant-specific properties and functions. In this review, we will address the importance of LINC complex-regulated processes, describe the plant NE bridging complexes and compare them to opisthokont LINC complexes.

MAF1, a novel plant protein interacting with matrix attachment region binding protein MFP1, is located at the nuclear envelope

The interaction of chromatin with the nuclear matrix via matrix attachment region (MAR) DNA is considered to be of fundamental importance for chromatin organization in all eukaryotic cells. MAR binding filament-like protein 1 (MFP1) from tomato is a novel plant protein that specifically binds to MAR DNA. Its filament protein-like structure makes it a likely candidate for a structural component of the nuclear matrix. MFP1 is located at nuclear matrix-associated, specklelike structures at the nuclear envelope. Here, we report the identification of a novel protein that specifically interacts with MFP1 in yeast two-hybrid and in vitro binding assays. MFP1 associated factor 1 (MAF1) is a small, soluble, serine/threonine-rich protein that is ubiquitously expressed and has no similarity to known proteins. MAF1, like MFP1, is located at the nuclear periphery and is a component of the nuclear matrix. These data suggest that MFP1 and MAF1 are in vivo interaction partners and that both proteins are components of a nuclear substructure, previously undescribed in plants, that connects the nuclear envelope and the internal nuclear matrix.

Plant nuclear shape is independently determined by the SUN-WIP-WIT2-myosin XI-i complex and CRWN1

Nuclei undergo dynamic shape changes during plant development, but the mechanism is unclear. In Arabidopsis, Sad1/UNC-84 (SUN) proteins, WPP domain-interacting proteins (WIPs), WPP domain-interacting tail-anchored proteins (WITs), myosin XI-i, and CROWDED NUCLEI 1 (CRWN1) have been shown to be essential for nuclear elongation in various epidermal cell types. It has been proposed that WITs serve as adaptors linking myosin XI-i to the SUN-WIP complex at the nuclear envelope (NE). Recently, an interaction between Arabidopsis SUN1 and SUN2 proteins and CRWN1, a plant analog of lamins, has been reported. Therefore, the CRWN1-SUN-WIP-WIT-myosin XI-i interaction may form a linker of the nucleoskeleton to the cytoskeleton complex. In this study, we investigate this proposed mechanism in detail for nuclei of Arabidopsis root hairs and trichomes. We show that WIT2, but not WIT1, plays an essential role in nuclear shape determination by recruiting myosin XI-i to the SUN-WIP NE bridges. Compared with SUN2, SUN1 plays a predominant role in nuclear shape. The NE localization of SUN1, SUN2, WIP1, and a truncated WIT2 does not depend on CRWN1. While crwn1 mutant nuclei are smooth, the nuclei of sun or wit mutants are invaginated, similar to the reported myosin XI-i mutant phenotype. Together, this indicates that the roles of the respective WIT and SUN paralogs have diverged in trichomes and root hairs, and that the SUN-WIP-WIT2-myosin XI-i complex and CRWN1 independently determine elongated nuclear shape. This supports a model of nuclei being shaped both by cytoplasmic forces transferred to the NE and by nucleoplasmic filaments formed under the NE.

Adenocarcinoma of the esophagogastric junction: the pattern of metastatic lymph node dissemination as a rationale for elective lymphatic target volume definition

PURPOSE

Regional nodal metastasis after neoadjuvant chemoradiation of adenocarcinoma of the esophagogastric junction (AEG) predicts survival. We aimed to clarify the lymph node (LN) distribution of AEG according to location of the tumor mass and invasion of neighboring areas for the selection of radiotherapy planning target volume (PTV) margins.

METHODS AND MATERIALS

Patterns of regional spread were analyzed in pathology reports of 326 patients patients with AEG who had undergone primary resection, with > or = 15 lymph nodes examined. Tumors were classified into AEG types based on endoscopy and pathology reports. Fisher's exact test was used to compare nodal disease and tumor characteristics. Pulmonary dose-volume histograms were tested in 8 patients.

RESULTS

Nodes were positive in 81% of T2 to T4 tumors. Type of AEG, tumor size, lymphovascular invasion, and grading significantly influenced nodal distribution. We found that marked esophageal invasion of AEG II/III significantly correlated with paraesophageal nodal disease, and T3 to T4 AEG II/III had a significant rate of splenic hilum/artery nodes. Middle and lower paraesophageal nodes should be treated in T2 to T4 AEG I and AEG II with > or = 15 mm involvement above the Z-line, and T3 to T4 AEG II. The splenic hilum and artery nodes can be spared in T2 AEG tumors, especially Type I tumors. The influence of paraesophageal nodal treatment on the risk of postoperative pulmonary complications can be estimated from dose-volume histograms.

CONCLUSIONS

Accurate pretherapeutic staging predicts the risk of subclinical nodal disease and should be used to select the appropriate radiotherapeutic PTV. Careful selection of the PTV can be used to maximize the therapeutic window in multimodal therapy for AEG.

Novel conserved sequence motifs in plant G-box binding proteins and implications for interactive domains

The G-box is a cis-acting DNA sequence present in several plant promoters that are regulated by diverse signals such as UV irradiation, anaerobiosis, abscissic acid and light. Several basic/leucine zipper (bZIP) proteins from different plant species have been identified as high affinity G-box binding proteins. Although their capability to enhance transcription has been demonstrated, their precise function in transcriptional activation is still unknown. We have isolated three cDNAs from young tomato fruit that encode bZIP G-box binding proteins (GBF4, GBF9 and GBF12). They bind to the G-box sequence in the tomato rbcS1, rbcS2 and rbcS3A promoters. GBF9 binding resulted in a DNase I footprint identical to that obtained with tomato nuclear extract and different from the DNase I protection obtained with GBF4 and GBF12. The mRNAs of all three GBFs were most abundant in tomato fruit and seeds, moderately abundant in root and least abundant in leaves. Protein sequences outside of the bZIP domains were compared with the known GBFs from other plants and seven conserved motifs of seven to 35 amino acids length have been identified. Based on the presence of these motifs, three classes of GBFs can be defined that are conserved among plant species. GBF9, the predominantly expressed tomato GBF, is the first member of its class isolated from dicot plants. Three conserved motifs from two of the classes are highly hydrophilic and are predicted to be exposed on the surface of the proteins. These motifs likely define novel interactive domains in the different classes of GBFs that could provide a new tool to determine how distinct regulatory signals are transmitted through GBFs to activate transcription.

Subunit structure and organization of the genes of the A1A0 ATPase from the Archaeon Methanosarcina mazei Gö1

The proton-translocating A1A0 ATP synthase/hydrolase of Methanosarcina mazei Gö1 was purified and shown to consist of six subunits of molecular masses of 65, 49, 40, 36, 25, and 7 kDa. Electron microscopy revealed that this enzyme is organized in two domains, the hydrophilic A1 and the hydrophobic A0 domain, which are connected by a stalk. Genes coding for seven hydrophilic subunits were cloned and sequenced. From these data it is evident that the 65-, 49-, 40- and 25-kDa subunits are encoded by ahaA, ahaB, ahaC, and ahaD, respectively; they are part of the A1 domain or the stalk. In addition there are three more genes, ahaE, ahaF, and ahaG, encoding hydrophilic subunits, which were apparently lost during the purification of the protein. The A0 domain consists of at least the 7-kDa proteolipid and the 36-kDa subunit for which the genes have not yet been found. In summary, it is proposed that the A1A0 ATPase of Methanosarcina mazei Gö1 contains at least nine subunits, of which seven are located in A1 and/or the stalk and two in A0.