Cell surface- and rho GTPase-based auxin signaling controls cellular interdigitation in Arabidopsis

Auxin is a multifunctional hormone essential for plant development and pattern formation. A nuclear auxin-signaling system controlling auxin-induced gene expression is well established, but cytoplasmic auxin signaling, as in its coordination of cell polarization, is unexplored. We found a cytoplasmic auxin-signaling mechanism that modulates the interdigitated growth of Arabidopsis leaf epidermal pavement cells (PCs), which develop interdigitated lobes and indentations to form a puzzle-piece shape in a two-dimensional plane. PC interdigitation is compromised in leaves deficient in either auxin biosynthesis or its export mediated by PINFORMED 1 localized at the lobe tip. Auxin coordinately activates two Rho GTPases, ROP2 and ROP6, which promote the formation of complementary lobes and indentations, respectively. Activation of these ROPs by auxin occurs within 30 s and depends on AUXIN-BINDING PROTEIN 1. These findings reveal Rho GTPase-based auxin-signaling mechanisms, which modulate the spatial coordination of cell expansion across a field of cells.     

A Theoretical Model for ROP Localisation by Auxin in Arabidopsis Root Hair Cells

Background

Local activation of Rho GTPases is important for many functions including cell polarity, morphology, movement, and growth. Although a number of molecules affecting Rho-of-Plants small GTPase (ROP) signalling are known, it remains unclear how ROP activity becomes spatially organised. Arabidopsis root hair cells produce patches of ROP at consistent and predictable subcellular locations, where root hair growth subsequently occurs.

Methodology/Principal Findings

We present a mathematical model to show how interaction of the plant hormone auxin with ROPs could spontaneously lead to localised patches of active ROP via a Turing or Turing-like mechanism. Our results suggest that correct positioning of the ROP patch depends on the cell length, low diffusion of active ROP, a gradient in auxin concentration, and ROP levels. Our theory provides a unique explanation linking the molecular biology to the root hair phenotypes of multiple mutants and transgenic lines, including OX-ROP, CA-rop, aux1, axr3, tip1, eto1, etr1, and the triple mutant aux1 ein2 gnom ^eb.

Conclusions/Significance

We show how interactions between Rho GTPases (in this case ROPs) and regulatory molecules (in this case auxin) could produce characteristic subcellular patterning that subsequently affects cell shape. This has important implications for research on the morphogenesis of plants and other eukaryotes. Our results also illustrate how gradient-regulated Turing systems provide a particularly robust and flexible mechanism for pattern formation.     

Developmental changes in spatial distribution of in vivo fluorescence and epidermal UV absorbance over Quercus petraea leaves

Background and Aims

Epidermal phenolic compounds (mainly flavonoids) constitute a vital screen that protects the leaf from damage by natural ultraviolet (UV) radiation. The effectiveness of epidermal UV-screening depends on leaf anatomy, the content of UV-screening compounds and their spatial uniformity over the leaf area. To investigate in vivo the spatial pattern of the epidermal UV-screen during leaf development, a fluorescence imaging method was developed to map the epidermal UV-absorbance at a microscopic scale. This study was done on oak (Quercus petraea) leaves that were used as a model of woody dicotyledonous leaves.

Methods

The leaf development of 2-year-old trees, grown outdoors, was monitored, at a macroscopic scale, by in vivo measurements of chlorophyll content per unit area and epidermal UV-absorbance using two optical leaf-clip meters. The distribution of pigments within leaves was assessed in vivo spectroscopically. The microscopic images of UV-induced fluorescence and UV-absorbance acquired in vivo during leaf development were interpreted from spectral characteristics of leaves.

Key Results

At a macroscopic scale, epidermal UV-absorbance was high on the upper leaf side during leaf development, while it increased on the lower leaf side during leaf expansion and reached the adaxial value at maturity. At a microscopic scale, in immature leaves, for both leaf sides, the spatial distribution of epidermal UV-absorbance was heterogeneous, with a pattern depending on the flavonoid content of vacuoles in developing epidermal cells. At maturity, epidermal UV-absorbance was uniform.

Conclusions

The spatial pattern of epidermal UV-screen over the area of oak leaves is related to leaf anatomy during development. In vivo spectroscopy and fluorescence imaging of the leaf surface showed the distribution of pigments within the leaf and hence can provide a tool to monitor optically the leaf development in nature.Key words: Blue-green fluorescence, chlorophyll fluorescence, epidermis, flavonoids, leaf development, microscopic imaging, polyphenols, Quercus petraea     

SPIKE1 Activates the GTPase ROP6 to Guide the Polarized Growth of Infection Threads in Lotus japonicus

In legumes, rhizobia attach to root hair tips and secrete nodulation factor to activate rhizobial infection and nodule organogenesis. Endosymbiotic rhizobia enter nodule primordia via a specialized transcellular compartment known as the infection thread (IT). The IT elongates by polar tip growth, following the path of the migrating nucleus along and within the root hair cell. Rho-family ROP GTPases are known to regulate the polarized growth of cells, but their role in regulating polarized IT growth is poorly understood. Here, we show that LjSPK1, a DOCK family guanine nucleotide exchange factor (GEF), interacts with three type I ROP GTPases. Genetic analyses showed that these three ROP GTPases are involved in root hair development, but only LjROP6 is required for IT formation after rhizobia inoculation. Misdirected ITs formed in the root hairs of Ljspk1 and Ljrop6 mutants. We show that LjSPK1 functions as a GEF that activates LjROP6. LjROP6 enhanced the plasma membrane localization LjSPK1 in Nicotiana benthamiana leaf cells and Lotus japonicus root hairs, and LjSPK1 and LjROP6 interact at the plasma membrane. Taken together, these results shed light on how the LjROP6-LjSPK1 module mediates the polarized growth of ITs in L. japonicus.     

Arabidopsis ROP9 and ROP10 GTPases differentially regulate auxin and ABA responses

Auxin and abscisic acid (ABA) are major plant hormones that act together to modulate numerous aspects of plant growth and development, including seed germination, primary root elongation, and lateral root formation. In this study, we analyzed the loss-of-function mutants of two closely related ROP (Rho of plants) GTPases, ROP9 and ROP10, and found that these ROP GTPases differentially regulate the auxin and ABA responses. rop9 and rop10 mutations enhanced the ABA-induced suppression of seed germination, primary root growth, and lateral root formation and the expression of ABA-responsive genes, whereas rop9 but not rop10 suppressed auxin-induced root phenotypes and auxin-responsive gene expression. These results suggest that both ROP9 and ROP10 function as negative regulators of ABA signaling, and that ROP9, but not ROP10, functions as a positive regulator of auxin signaling. Previously, ROPinteractive CRIB motif-containing protein 1 (RIC1) was reported to participate in auxin and ABA responses, and to have a similar effect as ROP9 and ROP10 on gene expression, root development, and seed germination. Because RIC proteins mediate ROP GTPase signaling, our results suggest that ROP9 and ROP10 GTPases function upstream of RIC1 in auxin- and ABA-regulated root development and seed germination.     

ROP GTPase-dependent actin microfilaments promote PIN1 polarization by localized inhibition of clathrin-dependent endocytosis

Cell polarization via asymmetrical distribution of structures or molecules is essential for diverse cellular functions and development of organisms, but how polarity is developmentally controlled has been poorly understood. In plants, the asymmetrical distribution of the PIN-FORMED (PIN) proteins involved in the cellular efflux of the quintessential phytohormone auxin plays a central role in developmental patterning, morphogenesis, and differential growth. Recently we showed that auxin promotes cell interdigitation by activating the Rho family ROP GTPases in leaf epidermal pavement cells. Here we found that auxin activation of the ROP2 signaling pathway regulates the asymmetric distribution of PIN1 by inhibiting its endocytosis. ROP2 inhibits PIN1 endocytosis via the accumulation of cortical actin microfilaments induced by the ROP2 effector protein RIC4. Our findings suggest a link between the developmental auxin signal and polar PIN1 distribution via Rho-dependent cytoskeletal reorganization and reveal the conservation of a design principle for cell polarization that is based on Rho GTPase-mediated inhibition of endocytosis.     

ROP3 GTPase Contributes to Polar Auxin Transport and Auxin Responses and Is Important for Embryogenesis and Seedling Growth in Arabidopsis

ROP GTPases are crucial for the establishment of cell polarity and for controlling responses to hormones and environmental signals in plants. In this work, we show that ROP3 plays important roles in embryo development and auxin-dependent plant growth. Loss-of-function and dominant-negative (DN) mutations in ROP3 induced a spectrum of similar defects starting with altered cell division patterning during early embryogenesis to postembryonic auxin-regulated growth and developmental responses. These resulted in distorted embryo development, defective organ formation, retarded root gravitropism, and reduced auxin-dependent hypocotyl elongation. Our results showed that the expression of AUXIN RESPONSE FACTOR5/MONOPTEROS and root master regulators PLETHORA1 (PLT1) and PLT2 was reduced in DN-rop3 mutant embryos, accounting for some of the observed patterning defects. ROP3 mutations also altered polar localization of auxin efflux proteins (PINs) at the plasma membrane (PM), thus disrupting auxin maxima in the root. Notably, ROP3 is induced by auxin and prominently detected in root stele cells, an expression pattern similar to those of several stele-enriched PINs. Our results demonstrate that ROP3 is important for maintaining the polarity of PIN proteins at the PM, which in turn ensures polar auxin transport and distribution, thereby controlling plant patterning and auxin-regulated responses.     

Rho of Plant GTPase Signaling Regulates the Behavior of Arabidopsis Kinesin-13A to Establish Secondary Cell Wall Patterns

Plant cortical microtubule arrays determine the cell wall deposition pattern and proper cell shape and function. Although various microtubule-associated proteins regulate the cortical microtubule array, the mechanisms underlying marked rearrangement of cortical microtubules during xylem differentiation are not fully understood. Here, we show that local Rho of Plant (ROP) GTPase signaling targets an Arabidopsis thaliana kinesin-13 protein, Kinesin-13A, to cortical microtubules to establish distinct patterns of secondary cell wall formation in xylem cells. Kinesin-13A was preferentially localized with cortical microtubules in secondary cell wall pits, areas where cortical microtubules are depolymerized to prevent cell wall deposition. This localization of Kinesin-13A required the presence of the activated ROP GTPase, MICROTUBULE DEPLETION DOMAIN1 (MIDD1) protein, and cortical microtubules. Knockdown of Kinesin-13A resulted in the formation of smaller secondary wall pits, while overexpression of Kinesin-13A enlarged their surface area. Kinesin-13A alone could depolymerize microtubules in vitro; however, both MIDD1 and Kinesin-13A were required for the depolymerization of cortical microtubules in vivo. These results indicate that Kinesin-13A regulates the formation of secondary wall pits by promoting cortical microtubule depolymerization via the ROP-MIDD1 pathway.     

The small GTPase AtRAC2/ROP7 is specifically expressed during late stages of xylem differentiation in Arabidopsis

The RAC/ROP family of small GTPases are central regulators of important cellular processes in plants. AtRAC2/ROP7 is an ancient member of the RAC/ROP gene family in Arabidopsis thaliana whose functions are generally unknown. In order to study the spatial expression pattern of the AtRAC2/ROP7 gene, transgenic plants expressing GUS or GFP under the control of the AtRAC2/ROP7 promoter were analysed. Functional analysis of AtRAC2/ROP7 was done using transgenic plants overexpressing wild-type and constitutively activated AtRAC2/ROP7 (Val15Gly), and an AtRAC2/ROP7T-DNA insertion mutant. The AtRAC2/ROP7 promoter directs a highly specific xylem-specific expression in the root, hypocotyl, stem, and leaves. The expression is developmentally limited to the late stages of xylem differentiation, and coincides with the formation of secondary cell walls. Leaf epidermal cells of transgenic plants overexpressing constitutively active AtRAC2/ROP7 exhibited highly impaired lobe formation, suggesting that AtRAC2/ROP7 is able to regulate polar cell expansion. Finally, GFP-AtRAC2/ROP7 fusion proteins were localized to the plasma membrane. The results indicate a role for AtRAC2/ROP7 in the development of secondary cell walls of xylem vessels.     

A novel ROP/RAC GTPase effector integrates plant cell form and pattern formation

ROPs/RACs are the only known signaling Ras superfamily small GTPases in plants. As such they have been suggested to function as central regulators of diverse signaling cascades. The ROP/RAC signaling networks are largely unknown, however, because only few of their effector proteins have been identified. In a paper that was published in the June 5, 2007 issue of Current Biology we described the identification of a novel ROP/RAC effector designated ICR1 (Interactor of Constitutive active ROPs 1). We demonstrated that ICR1 functions as a scaffold that interacts with diverse but specific group of proteins including SEC3 subunit of the exocyst vesicle tethering complex. ICR1-SEC3 complexes can interact with ROPs in vivo and are thereby recruited to the plasma membrane. ICR1 knockdown or silencing leads to cell deformation and loss of the root stem cells population, and ectopic expression of ICR1 phenocopies activated ROPs/RACs. ICR1 presents a new paradigm in ROP/RAC signaling and integrates mechanisms regulating cell form and pattern formation at the whole plant level.Key words: Rho, auxin, root development, vesicle trafficking, RAC, ROP, polarity, Arabidopsis, exocyst     

Plant small monomeric G-proteins (RAC/ROPs) of barley are common elements of susceptibility to fungal leaf pathogens,cell expansion and stomata development

Small monomeric RAC/ROP GTPases act as molecular switches in signal transduction processes of plant development and stress responses. They emerged as crucial players in plant-pathogen interactions either by supporting susceptibility or resistance. In a recent publication, we showed that constitutively activated (CA) mutants of different barley (Hordeum vulgare) RAC/ROPs regulate susceptibility to barley fungal leaf pathogens of different life style in a contrasting way. This illustrates the distinctive signalling roles of RAC/ROPs for different plant-pathogen combinations. We also reported the involvement of RAC/ROPs in plant epidermis development in a monocotyledonous plant. Here we further discuss a failure of CA HvRAC/ROP-expressing barley to normally develop stomata.Key words: Hordeum vulgare, G-proteins, RAC, ROP, cell expansion, stomata, transpirationMembers of the RHO family of small G-proteins in plants (RAC/ROPs) regulate signal transduction processes at the plasma membrane.¹ They act as multifunctional signalling switches in plant development and a variety of stress responses. RAC/ROP GTPases play regulatory roles in polar growth and cell morphogenesis in several cell systems including pollen tubes, developing root hairs and leaf pavement cells.²In a recent publication,³ we showed that constitutively activated (CA) mutants of different barley (Hordeum vulgare) RAC/ROPs support susceptibility to the barley powdery mildew fungus Blumeria graminis f.sp. hordei (Bgh). CA HvRAC1 supported susceptibility to biotrophic Bgh but resistance to hemibiotrophic Magnaporthe oryzae in barley at the penetration level in both cases. Additionally, CA HvRAC1 supported local callose deposition at sites of attack from Bgh and a secondary H₂O₂ burst in whole non-penetrated epidermal cells. This supports a regulatory function of RAC/ROPs in plant defence¹ and the potential corruption of defence pathways in susceptibility to Bgh. Because the rice ortholog of HvRAC1, OsRAC1, can regulate an H₂O₂ burst via activation of the plasma membrane NADPH oxidase OsRBOHB,⁴ one can speculate that the secondary H₂O₂ burst in CA HvRAC1 barley could also be caused by over-activation of an NADPH oxidase. However, CA HvRAC1 barley was also more susceptible to fungal penetration, and penetrated cells did not show an H₂O₂ burst. Hence, CA HvRAC1 did not contribute to penetration resistance, and the H₂O₂ burst might have been suppressed by Bgh after successful penetration. Interestingly, Bgh secretes a catalase during interaction with the plant.⁵The involvement of RAC/ROPs in plant development has been widely studied in the dicots Arabidopsis and tobacco. In Arabidopsis, CA AtRAC/ROPs disturb root hair tip growth and epidermal cell morphogenesis.^6,7 We showed similar developmental aberrations as a result of CA HvRAC/ROP expression in monocotyledonous barley. Root hair polarity disruption and enhanced leaf epidermal cell expansion was observed in CA HvRAC/ROP expressing barley. Here, we further report on reduced or abnormal development of stomata as an effect of CA HvRAC/ROP expression.In barley, stomata and short epidermal cells alternate in a row of leaf epidermal cells (Fig. 1A). The number of stomata number was significantly reduced in three CA HvRAC/ROP (CA HvRACB, CAHvRAC3, CA HvRAC1) expressing barley genotypes when compared to azygous controls (barley siblings that lost the transgene due to segregation) (Fig. 1E). In part, this could be explained by enhanced length of epidermal cells intercalated between stomata (Fig. 1B). The presence of longer epidermal cells in all CA HvRAC/ROP-barleys further supports that RAC/ROPs are operating in epidermal cell expansion.³Open in a separate windowFigure 1Stomatal abnormalities observed in CA HvROPexpressing transgenic barley leaves. (A) Wild type leaf adaxial epidermis with alternating stomata complexes (arrows) and short epidermal cells (asterisk). (B) Presence of more than one short epidermal cell in between two stomata. Arrows point the stomata. Double headed arrows highlight intercalated cells with enhanced cell length (C) Two stomata lacking an intercalated short epidermal cell. (D) Stoma failed to develop and left an abnormal blank cell. (E) Average number of stomata present in 5 cm of a stomatal row in transgenic plants expressing distinct CA barley CA HvRAC/ROPs. For all samples, stomatal rows present on either side of the mid rib were counted in the leaf upper epidermis. Fully expanded leaves of 3-weeks-old barley plants were used for counting stomata. Error bars show 95% confidence intervals. Repetition of the experiment led to similar results. Scale bars = 50 µm.Previously, we carried out porometry experiments to measure stomata conductivity in CA HvRACB expressing barley leaves.⁸ The CA HvRACB leaves showed up to 50% less transpiration than azygous controls without any treatment. Additionally, CA HvRACB leaves were less responsive to abscisic acid (ABA) and subsequently they could not effectively reduce transpiration when treated with ABA or when cut-off from water supply.⁸ Our data on numbers of stomata per leaf segment could now explain the lower rates of transpiration in non-stressed CA HvRACB barley when compared to wild type.Apart from the stomata number, developmental abnormalities were observed in the arrangement of epidermal cells. Generally, the shape of epidermal cells was less regular in CA HvRAC/ROP barley.³ We also observed the presence of more than one short epidermal cell in between two stomata (Fig. 1B) or two stomata lacking an intercalated short epidermal cell (Fig. 1C), or stomata failed to develop, which ended up in an abnormally short epidermal cell (Fig. 1D). Although such abnormalities were also rarely observed in wild type plants, all three CA HvRAC/ROP-barley leaves exhibited a clearly higher frequency of abnormalities in a given length of a stomata row. Together, CA HvRAC/ROPs had an effect on both the number and development of stomata. These observations suggest that RAC/ROPs are not only operating in cell expansion but also in barley cell differentiation for stomata development.     

Rho family GTPases: Making it to the third dimension

The role of Rho family GTPases in controlling the actin cytoskeleton and thereby regulating cell migration has been well studied for cells migrating on 2D surfaces. In vivo, cell migration occurs within three-dimensional matrices and along aligned collagen fibers with rather different spatial requirements. Recently, a handful of studies coupled with new approaches have demonstrated that Rho GTPases have unique regulation and roles during cell migration within 3D matrices, along collagen fibers, and in vivo. Here we propose that migration on aligned matrices facilitates spatial organization of Rho family GTPases to restrict and stabilize protrusions in the principle direction of alignment, thereby maintaining persistent migration. The result is coordinated cell movement that ultimately leads to higher rates of metastasis in vivo.     

Fine-Tuning of the Actin Cytoskeleton and Cell Adhesion During Drosophila Development by the Unconventional Guanine Nucleotide Exchange Factors Myoblast City and Sponge

The evolutionarily conserved Dock proteins function as unconventional guanine nucleotide exchange factors (GEFs). Upon binding to engulfment and cell motility (ELMO) proteins, Dock–ELMO complexes activate the Rho family of small GTPases to mediate a diverse array of biological processes, including cell motility, apoptotic cell clearance, and axon guidance. Overlapping expression patterns and functional redundancy among the 11 vertebrate Dock family members, which are subdivided into four families (Dock A, B, C, and D), complicate genetic analysis. In both vertebrate and invertebrate systems, the actin dynamics regulator, Rac, is the target GTPase of the Dock-A subfamily. However, it remains unclear whether Rac or Rap1 are the in vivo downstream GTPases of the Dock-B subfamily. Drosophila melanogaster is an excellent genetic model organism for understanding Dock protein function as its genome encodes one ortholog per subfamily: Myoblast city (Mbc; Dock A) and Sponge (Spg; Dock B). Here we show that the roles of Spg and Mbc are not redundant in the Drosophila somatic muscle or the dorsal vessel. Moreover, we confirm the in vivo role of Mbc upstream of Rac and provide evidence that Spg functions in concert with Rap1, possibly to regulate aspects of cell adhesion. Together these data show that Mbc and Spg can have different downstream GTPase targets. Our findings predict that the ability to regulate downstream GTPases is dependent on cellular context and allows for the fine-tuning of actin cytoskeletal or cell adhesion events in biological processes that undergo cell morphogenesis.     

喀纳斯自然保护区6种藓类植物的解剖学研究

应用石蜡切片技术及扫描电镜方法,对喀纳斯自然保护区生长的6种藓类植物茎、叶的内部结构及其表面的角质层纹饰、疣、孔等进行比较研究,结果表明:垂枝藓(Rhytidium rugosum(Hedw.)Kindb.)叶背、腹面表皮细胞外壁均有细疣状突起,而纵列相邻细胞的壁表面角质层纹饰长,成束状平行排列;山羽藓(Abietinella abietina(hedw.)fleisch.)茎的中轴不明显,中肋背部具棘刺状突起的疣,叶背、腹面的疣倒向凹陷的细胞壁,呈遮盖状;直叶珠藓(Bartramia ithphyllaBrid.)叶背、腹面表皮细胞外壁具泡状隆起,孔不凹陷,孔口被角质层纹饰所遮盖;沼泽皱蒴藓(Aulacomnium palustre(Hedw.)Schwagr.)叶背面的粗疣由凹陷细胞壁中突出,角质层纹饰呈带状,叶腹面孔大,并多在细胞壁相交处呈张开状;塔藓(Hylocommium splendens(Hedw.)B.S.G.)叶背部粗疣呈宽刺状,叶背、腹面粗疣高,上端倒向凹陷的细胞壁;角齿藓(Ceratodon purpureus(hedw.)Brid.)叶背、腹面细胞凹陷不规则,相邻细胞壁厚,具密集的细疣。     

新疆大帽藓属6种植物茎及叶的比较解剖学研究

运用石蜡切片和电镜技术,对新疆的6种大帽藓属（Encalypta Hedw.）植物的茎和叶进行解剖学观察。结果表明：高山大帽藓（E.alpina Smith.）疣多呈菱形或“柱状”密集着生在叶表面,疣上纹饰呈纵棱和小疙瘩状;裂瓣大帽藓（E.ciliata Hedw.）茎横切面为五角形, 中轴细胞角隅加厚,叶腹面的粗疣大部分集中分布在凹陷的表面细胞壁上;剑叶大帽藓（E.spathulata C.Mull.）茎横切面没出现中柱鞘,疣在基部分叉丛生,叶腹面的表皮细胞壁不凹陷;钝叶大帽藓（E.vulgaris Hedw.）没有叶尖,中肋导水细胞大,叶表面细胞壁较光滑且强烈凹陷,其壁上的乳突不明显;天山大帽藓（E.tianschanica j.c.Zhao,R.L.Hu et S.He）茎内外皮层区分明显,内皮层细胞质浓,叶背面的分叉状粗疣呈密集生长在叶腹面的星状粗疣大多集中分布在稍下陷的细胞壁上;西藏大帽藓（E.tibetana C.Mull）中肋细胞壁加厚,叶片具层层叠叠的、密集的、不规则分叉的粗疣,叶背面有些部位被带状附属物所覆盖。这6种植物叶的背、腹面均具不同程度的分叉粗疣,但粗疣的大小、着生位置、呈现的状态、疣上不同的纹饰却各不相同;中肋细胞的层数、及导水主细胞的大小、状态也大不相同,这些细微特征的观察研究可作为大帽藓属植物分类学的依据之一。     

Actin pedestal formation by enteropathogenic Escherichia coli and intracellular motility of Shigella flexneri are abolished in N-WASP-defective cells

In mammalian cells, actin dynamics is tightly controlled through small GTPases of the Rho family, WASP/Scar proteins and the Arp2/3 complex. We employed Cre/loxP-mediated gene targeting to disrupt the ubiquitously expressed N-WASP in the mouse germline, which led to embryonic lethality. To elucidate the role of N-WASP at the cellular level, we immortalized embryonic fibroblasts and selected various N-WASP-defective cell lines. These fibroblasts showed no apparent morphological alterations and were highly responsive to the induction of filopodia, but failed to support the motility of Shigella flexneri. In addition, enteropathogenic Escherichia coli were incapable of inducing the formation of actin pedestals in N-WASP-defective cells. Our results prove the essential role of this protein for actin cytoskeletal changes induced by these bacterial pathogens in vivo and in addition show for the first time that N-WASP is dispensible for filopodia formation.     

Drosophila pupal macrophages – A versatile tool for combined ex vivo and in vivo imaging of actin dynamics at high resolution

Molecular understanding of actin dynamics requires a genetically traceable model system that allows live cell imaging together with high-resolution microscopy techniques. Here, we used Drosophila pupal macrophages that combine many advantages of cultured cells with a genetic in vivo model system. Using structured illumination microscopy together with advanced spinning disk confocal microscopy we show that these cells provide a powerful system for single gene analysis. It allows forward genetic screens to characterize the regulatory network controlling cell shape and directed cell migration in a physiological context. We knocked down components regulating lamellipodia formation, including WAVE, single subunits of Arp2/3 complex and CPA, one of the two capping protein subunits and demonstrate the advantages of this model system by imaging mutant macrophages ex vivo as well as in vivo upon laser-induced wounding.     

栒子属（Cotoneaster Medikus）植物叶表皮微形态特征及其分类学意义

在光学显微镜和扫描电镜下,对栒子属（Cotoneaster Medikus）2组15种植物的叶表皮特征进行了观察,发现疏花组（Sect. Cotoneaster）植物叶表皮细胞多为多边形,垂周壁一般为平直—弓形,气孔均为无规则型;单花组（Sect. Uniflos）植物叶表皮细胞常不规则型,垂周壁多浅波状,气孔除无规则型（anomocytic）外还兼有十字型（staurocytic）、四分体型（tetracytic）和等三体型（isotricytic）。依据气孔周围角质膜特征等叶表皮性状,把15种植物分为W型、S型和I型,其中W型是S型的特化类型,疏花组的种类为W型或S型,单花组的种类为I型。叶表皮微形态特征可以为栒子属植物组及种的分类学处理提供解剖学资料。