The baseless mutant links protein phosphatase 2A with basal cell identity in the brown alga Ectocarpus.

The first mitotic division of the initial cell is a key event in all multicellular organisms and is associated with the establishment of major developmental axes and cell fates. The brown alga Ectocarpus has a haploid-diploid life cycle that involves the development of two multicellular generations: the sporophyte and the gametophyte. Each generation deploys a distinct developmental programme autonomously from an initial cell, the first cell division of which sets up the future body pattern. Here, we show that mutations in the BASELESS (BAS) gene result in multiple cellular defects during the first cell division and subsequent failure to produce basal structures during both generations. BAS encodes a type B″ regulatory subunit of protein phosphatase 2A (PP2A), and transcriptomic analysis identified potential effector genes that may be involved in determining basal cell fate. The bas mutant phenotype is very similar to that observed in distag (dis) mutants, which lack a functional Tubulin-binding co-factor Cd1 (TBCCd1) protein, indicating that TBCCd1 and PP2A are two essential components of the cellular machinery that regulates the first cell division and mediates basal cell fate determination.

Independent parental contributions initiate zygote polarization in Arabidopsis thaliana.

Embryogenesis of flowering plants is initiated by polarization of the zygote, a prerequisite for correct axis formation in the embryo. The daughter cells of the asymmetric zygote division form the pro-embryo and the mostly extra-embryonic suspensor.1 The suspensor plays a pivotal role in nutrient and hormone transport and rapid growth of the embryo.2,3 Zygote polarization is controlled by a MITOGEN-ACTIVATING PROTEIN (MAP) kinase signaling pathway including the MAPKK kinase (MAP3K) YODA (YDA)4 and the upstream membrane-associated proteins BRASINOSTEROID SIGNALING KINASE 1 (BSK1) and BSK2.5,6 Furthermore, suspensor development is controlled by cysteine-rich peptides of the EMBRYO SURROUNDING FACTOR 1 (ESF1) family.7 While they act genetically upstream of YDA, the corresponding receptor to perceive these potential ligands is unknown. In other developmental processes, such as stomata development, YDA activity is controlled by receptor kinases of the ERECTA family (ERf).8-12 While the receptor kinases upstream of BSK1/2 in the embryo have so far not been identified,1 YDA is in part activated by the sperm cell-derived BSK family member SHORT SUSPENSOR (SSP) that represents a naturally occurring, constitutively active variant of BSK1.5,13 It has been speculated that SSP might be a paternal component of a parental tug-of-war controlling resource allocation toward the embryo.2,13 Here, we show that in addition to SSP, the receptor kinase ERECTA plays a crucial role in zygote polarization as a maternally contributed part of the embryonic YDA pathway. We conclude that two independent parental contributions initiate zygote polarization and control embryo development.

Constitutive Activation of Leucine-Rich Repeat Receptor Kinase Signaling Pathways by BAK1-INTERACTING RECEPTOR-LIKE KINASE3 Chimera.

Receptor kinases with extracellular leucine-rich repeat domains (LRR-RKs) form the largest group of membrane signaling proteins in plants. LRR-RKs can sense small molecule, peptide, or protein ligands and may be activated by ligand-induced interaction with a shape complementary SOMATIC EMBRYOGENESIS RECEPTOR-LIKE KINASE (SERK) coreceptor kinase. We have previously shown that SERKs can also form constitutive, ligand-independent complexes with the LRR ectodomains of BAK1-INTERACTING RECEPTOR-LIKE KINASE3 (BIR3) receptor pseudokinases, negative regulators of LRR-RK signaling. Here, we report that receptor chimera in which the extracellular LRR domain of BIR3 is fused to the cytoplasmic kinase domains of the SERK-dependent LRR-RKs BRASSINOSTEROID INSENSITIVE1, HAESA and ERECTA form tight complexes with endogenous SERK coreceptors in the absence of ligand stimulus. Expression of these chimeras under the control of the endogenous promoter of the respective LRR-RK leads to strong gain-of-function brassinosteroid, floral abscission, and stomatal patterning phenotypes, respectively. Importantly, a BIR3-GASSHO1 (GSO1)/SCHENGEN3 (SGN3) chimera can partially complement sgn3 Casparian strip formation phenotypes, suggesting that SERK proteins also mediate GSO1/SGN3 receptor activation. Collectively, our protein engineering approach may be used to elucidate the physiological functions of orphan LRR-RKs and to identify their receptor activation mechanism in single transgenic lines.

Constitutive signaling activity of a receptor-associated protein links fertilization with embryonic patterning in Arabidopsis thaliana.

In flowering plants, the asymmetrical division of the zygote is the first hallmark of apical-basal polarity of the embryo and is controlled by a MAP kinase pathway that includes the MAPKKK YODA (YDA). In Arabidopsis, YDA is activated by the membrane-associated pseudokinase SHORT SUSPENSOR (SSP) through an unusual parent-of-origin effect: SSP transcripts accumulate specifically in sperm cells but are translationally silent. Only after fertilization is SSP protein transiently produced in the zygote, presumably from paternally inherited transcripts. SSP is a recently diverged, Brassicaceae-specific member of the BRASSINOSTEROID SIGNALING KINASE (BSK) family. BSK proteins typically play broadly overlapping roles as receptor-associated signaling partners in various receptor kinase pathways involved in growth and innate immunity. This raises two questions: How did a protein with generic function involved in signal relay acquire the property of a signal-like patterning cue, and how is the early patterning process activated in plants outside the Brassicaceae family, where SSP orthologs are absent? Here, we show that Arabidopsis BSK1 and BSK2, two close paralogs of SSP that are conserved in flowering plants, are involved in several YDA-dependent signaling events, including embryogenesis. However, the contribution of SSP to YDA activation in the early embryo does not overlap with the contributions of BSK1 and BSK2. The loss of an intramolecular regulatory interaction enables SSP to constitutively activate the YDA signaling pathway, and thus initiates apical-basal patterning as soon as SSP protein is translated after fertilization and without the necessity of invoking canonical receptor activation.

A simple and versatile cell wall staining protocol to study plant reproduction.

KEY MESSAGE: The optical brightener SCRI Renaissance 2200 can be used as versatile dye to study various aspects of plant reproduction by confocal laser scanning microscopy. The study of sexual reproduction of plants has traditionally relied on light microscopy in combination with a variety of staining methods. Transgenic lines that label specific cell or tissue types with fluorescent proteins in combination with confocal laser scanning microscopy were an important development to visualize gametophyte development, the fertilization process, and to follow cell differentiation in the early embryo. Staining the cell perimeter to identify surrounding tissue is often a necessary prerequisite to put the fluorescent signal in the right context. Here, we present SCRI Renaissance 2200 (SR2200) as a versatile dye to study various aspects of plant reproduction ranging from pollen tube growth, guidance and reception to the early patterning process in the developing embryo of Arabidopsis thaliana. Furthermore, we demonstrate that SR2200 can be combined with a wide variety of fluorescent proteins. If spectral information can be recorded, even double labeling with dyes that have very similar emission spectra such as 4',6-diamidin-2-phenylindol (DAPI) is possible. The presented staining method can be a single, easy-to-use alternative for a range of other staining protocols commonly used for microscopic analyses in plant reproductive biology.

Cell type-specific transcriptome analysis in the early Arabidopsis thaliana embryo.

In multicellular organisms, cellular differences in gene activity are a prerequisite for differentiation and establishment of cell types. In order to study transcriptome profiles, specific cell types have to be isolated from a given tissue or even the whole organism. However, whole-transcriptome analysis of early embryos in flowering plants has been hampered by their size and inaccessibility. Here, we describe the purification of nuclear RNA from early stage Arabidopsis thaliana embryos using fluorescence-activated nuclear sorting (FANS) to generate expression profiles of early stages of the whole embryo, the proembryo and the suspensor. We validated our datasets of differentially expressed candidate genes by promoter-reporter gene fusions and in situ hybridization. Our study revealed that different classes of genes with respect to biological processes and molecular functions are preferentially expressed either in the proembryo or in the suspensor. This method can be used especially for tissues with a limited cell population and inaccessible tissue types. Furthermore, we provide a valuable resource for research on Arabidopsis early embryogenesis.

Thromboelastographic phenotypes of fibrinogen and its variants: clinical and non-clinical implications.

INTRODUCTION: Thromboelastography (TEG), a widely used clinical point of care coagulation test, is poorly understood. To investigate its fibrin determinants we used normal and variant fibrinogen isolates. MATERIALS AND METHODS: We focused mainly on the TEG maximum signal amplitude (MA), a shear modulus and clot stiffness indicator. Isolates included normal des-αC, cord, and abnormal congenital variants with amino acid substitutions or deletions that impaired fibrin polymerization. Heterophenotypic congenital isolates were from cryoprecipitate-depleted plasma owing to their more diminished clot MA than their cryoprecipitate counterparts. By colorimetric assay, the amount of fibrinogen adsorbed by untreated TEG cups was 83.5±12.4 pM/cm(2), n=18. Thrombin-induced clots were obtained at pH6.4 or 7.4, the latter containing 8mM CaCl2, and 14% afibrinogenemic plasma with and without gel-sieved platelets. RESULTS AND CONCLUSIONS: Measured by the water droplet contact angle, >90% reduction of surface hydrophobicity by exposure of TEG cup and pin to ozone plasma decreased MA by 74%. Increasing normal fibrinogen or thrombin concentrations progressively increased MA. Platelets increased MA further ~2 fold, except for ≥10 fold for des-αC clots. Examined in the absence of platelets, MA of heterophenotypic fibrin variants averaged 21%, n=15. The results imply that essential MA determinants include hydrophobic fibrinogen/fibrin adsorption and each polymerization contact site, with substantial enhancement by platelets. Also, cryoprecipitate-harvested soluble fibrinogen/fibrin complexes contained mostly normal molecules, while cryoprecipitate-depleted plasma contained mostly variant molecules. Moreover, significantly decreased MA by fibrinogen anomalies and/or low level thrombin generation can potentially impact clinical interpretation of MA.

Suspensor length determines developmental progression of the embryo in Arabidopsis.

The first structure that differentiates during plant embryogenesis is the extra-embryonic suspensor that positions the embryo in the lumen of the seed. A central role in nutrient transport has been ascribed to the suspensor in species with prominent suspensor structures. Little is known, however, about what impact the size of the rather simple Arabidopsis (Arabidopsis thaliana) suspensor has on embryogenesis. Here, we describe mutations in the predicted exo-polygalacturonase gene NIMNA (NMA) that lead to cell elongation defects in the early embryo and markedly reduced suspensor length. Mutant nma embryos develop slower than wild-type embryos, and we could observe a similar developmental delay in another mutant with shorter suspensors. Interestingly, for both genes, the paternal allele has a stronger influence on the embryonic phenotype. We conclude that the length of the suspensor is crucial for fast developmental progression of the embryo in Arabidopsis.

Inherited dysfibrinogenemia: clinical phenotypes associated with five different fibrinogen structure defects.

Hereditary dysfibrinogenemia is a rare clotting disorder, which results from mutations in at least one of the three fibrinogen genes. We examined the frequency of hemostatic clinical and laboratory anomalies at presentation of 37 probands from 12 unrelated families with five different defects (Aalpha R16C, gamma A357T, gamma318-319 del, gamma M310T, and Aalpha R16S), among. The median age was 51 years (11-86 years). Among 62% who were women three (13%) had experienced one or more spontaneous abortion. More than half of the probands had experienced one or more undue bleeding episode, easy bruising being by far the most common. In 19% of probands (9/37, all above age of 50 years), had experienced at least one episode of arterial or venous thrombosis. Among these, were two (7%) with deep venous thrombosis, seven with arterial thrombosis, and five (14%) had experienced both. We propose that the higher frequency of prolonged PT than aPTT, in ours and in other reported studies, reflects the polymerization delay, which in aPTT is attenuated owing to contact activation prior to calcium addition.

Decreased plasmin resistance by clots of a homophenotypic Aalpha R 16H fibrinogen (Kingsport, slower fibrinopeptide A than fibrinopeptide B release).

Reported evidence of a role in fibrinolysis by fibrinopeptide (Fp)B-dependent intermolecular fibrin polymerization contacts and of reversed FpA/FpB release sequence from fibrinogen Kingsport led us to investigate the fibrinolytic properties of Kingsport clots. Clot lysis was induced by either plasmin (pH 7.4) or by a mixture of plasminogen and recombinant tissue plasminogen activator and measured by lysis time and by turbidity (350 nm) time course. Clots were formed by thrombin from plasminogen-free fibrinogen (pH 7.4, 8 mmol/l CaCl2), with or without 40 nmol/l factor XIII or 20% afibrinogenemic plasma. Displaying no differences from corresponding normal controls were (a) lysis of repolymerized fibrin clots, and (b) chromogenic measurements of fibrin-stimulated Glu-plasminogen activation by recombinant tissue plasminogen activator. By contrast, thrombin-induced fine and coarse network clots (n = 7) displayed faster turbidity loss than corresponding normal controls and shorter lysis times ranging 31-55% of controls. Comparison of clots of fibrinogen fractions lacking approximately 90% of their alpha chain carboxyl terminal regions, n = 2, also displayed faster plasmin-induced lysis than corresponding controls. To assess the role of FpB release-dependent intermolecular polymerization contacts, clots were prepared in the presence of three molar excess antibeta 15-42 immunoglobulin G, n = 2, and displayed no differences in plasmin-induced lysis from nonimmune immunoglobulin G controls. The reversed FpA/FpB release sequence from Kingsport fibrinogen resulted in clots with decreased resistance to plasmin. We suggest that both markedly slow polymerization and decreased plasmin resistance played causative roles in the hemorrhagic diathesis associated with this dysfibrinogen.

Homophenotypic Aalpha R16H fibrinogen (Kingsport): uniquely altered polymerization associated with slower fibrinopeptide A than fibrinopeptide B release.

We detail for the first time the uniquely altered fibrin polymerization of homophenotypic Aalpha R16H dysfibrinogen. By polymerase chain reaction amplification and DNA sequencing, our new proposita's genotype consisted of a G>A transition encoding for Aalpha R16H, and an 11 kb Aalpha gene deletion. High-performance liquid chromatography disclosed fibrinopeptide A release approximately six times slower than its fibrinopeptide B. Turbidimetric analyses revealed unimpaired fibrin repolymerization, and abnormal thrombin-induced polymerization (1-7 mumol/l fibrinogen, > 96% coagulable), consisting of a prolonged lag time, slow rate, and abnormal clot turbidity maxima, all varying with thrombin concentration. For example, at 0.2-3 U/ml, the resulting turbidity maxima ranged from lower to higher than normal control values. By scanning electron microscopy, clots formed by 0.3 and 3 thrombin U/ml displayed mean fibril diameters 42 and 254% of the respective control values (n = 400). Virtually no such differences from control values were demonstrable, however, when clots formed in the presence of high ionic strength (micro = 0.30) or of monoclonal antibeta(15-42)IgG. The latter also prolonged the thrombin clotting time approximately three-fold. Additionally, thrombin-induced clots displayed decreased elastic moduli, with G' values of clots induced by 0.3, 0.7 and 3 thrombin U/ml corresponding to 11, 34, and 45% of control values. The results are consistent with increased des-BB fibrin monomer generation preceding and during polymerization. This limited the inherent gelation delay, decreased the clot stiffness, and enabled a progressively coarser, rather than finer, network induced by increasing thrombin concentrations. We hypothesize that during normal polymerization these constitutive des-BB fibrin monomer properties attenuate their des-AA fibrin counterparts.