Niemann-Pick disease,type B with TRAP-positive storage cells and secondary sea blue histiocytosis

We present 2 cases of Niemann Pick disease, type B with secondary sea-blue histiocytosis. Strikingly, in both cases the Pick cells were positive for tartrate resistant acid phosphatase, a finding hitherto described only in Gaucher cells. This report highlights the importance of this finding as a potential cytochemical diagnostic pitfall in the diagnosis of Niemann Pick disease.Key words: Niemann pick disease, Gaucher disease, tartrate resistant acid phosphatase, sea blue histiocytosis.We present two unrelated patients who were referred to the Hematology OPD from Gastroenterology during work-up of long-standing splenomegaly 2 years apart and whose details are presented in

Metabolome-ionome-biomass interactions: What can we learn about salt stress by multiparallel phenotyping?

Long-term exposure of plants to saline soil results in mineral ion imbalance, altered metabolism and reduced growth. Currently, the interaction between ion content and plant metabolism under salt-stress is poorly understood. Here we present a multivariate correlation study on the metabolome, ionome and biomass changes of Lotus japonicus challenged by salt stress. Using latent variable models, we show that increasing salinity leads to reproducible changes of metabolite, ion and nutrient pools. Strong correlations between the metabolome and the ionome or biomass may allow one to estimate the degree of salt stress experienced by a plant based on metabolite profiles. Despite the apparently high predictive power of the models, it remains to be investigated whether such metabolite profiles of non- or moderately-stressed plants can be used by breeding programs as ideal ideotypes for the selection of enhanced salt-tolerant genotypes.Key words: acclimation, ionomic, lotus, metabolic, metabolomic, nutrients, salinity, salt stressAcclimation of plants to saline soils involves changes in the uptake, transport and/or partitioning of mineral ions.^1–3 These responses not only alter ion concentrations but also impair metabolism and growth.⁴ Exactly how metabolism as a whole changes in response to salinity is still unknown because of the complexity of the processes involved. Nevertheless, one might expect plant metabolism to respond in a predictable way to salt stress. With this in mind we carried out a multivariate correlation analysis of 137 metabolome and ionome profiles, and the corresponding biomass measurements, of shoot samples from Lotus japonicus exposed to two different salinity regimes.⁵Metabolome data obtained using GC/EI-TOF-MS technology were analyzed using the TagFinder software,⁶ resulting in a series of discrete metabolic-features. A metabolic-feature may be defined to represent a quantitative signal, measured by any analytical means or technology, which is distinct from analytical signals that arise as artefacts from electronic or chemical noise. A total of 1019 metabolic-features were obtained after filtering for those represented by 3 or more inter-correlated mass fragments.⁶ Corresponding ionomic data were obtained using ICP-AES technology and included measurements of Na and 10 macro- and micro-nutrients (K, Ca, S, P, Mg, B, Mn, Fe, Zn and Mo).⁵To integrate metabolomic and ionomic data, we used the statistical multivariate regression technique called orthogonal projections to latent structures (OPLS^7,8), which performs a regression of two matrices or a matrix versus a single variable and simultaneously corrects the resulting model for systematic, irrelevant variance. The metabolite profile matrix was regressed in three different models against the concentrations of Na, K and a matrix of all nutrients excluding K and Na. These regressions were designated metabolome-[ Na], metabolome-[K] and metabolome [nutrients-K] models, respectively. With OPLS it is possible to estimate how well associated the different metabolites are with the modeled variance of the different ions. The used measure is called the correlation loading and can be interpreted as a multivariate version of the standard Pearson correlation. In order to compare how the metabolic profiles may predict the different matrices, we regressed the correlation loadings vectors of the three different models amongst each other (Fig. 1). Remarkably, the loadings were highly correlated. Despite the high magnitude of change in K content compared to the other nutrients under salinity, the metabolome-[K] and metabolome-[nutrients-K] loadings were nearly identical, highlighting that K levels correlate strongly with the main metabolome correlated variance in the rest of the nutrient matrix. These observations suggest that salinity leads to reproducible changes in metabolite pools which match both the concentration of salt accumulated in the shoot and induced changes in the content of other elements.⁵ Since metabolome profiles have been considered a predictor of plant biomass under non-stressed growth conditions,⁹ a metabolome-biomass model was evaluated for the stress cue of our experimental setup. The metabolome data appeared to be correlated to shoot biomass in a manner similar to the predictability of [Na], [K] and [nutrients-K] (Fig. 2). Presumably, this observation reflects the property of the plant system to integrate in a highly interdependent process the nutritive elements, metabolism and growth.Open in a separate windowFigure 1Regression of the correlation loadings obtained from the models metabolome [Na], metabolome [K] and metabolome [nutrients-K].Open in a separate windowFigure 2Regression of the correlation loadings of the metabolome [Na], metabolome [K] and metabolome [nutrients-K] models with the metabolome biomass model.The correlation loadings of the models allowed a ranking of metabolite-features according to their contribution to the modeled regressions. We used the magnitude of the weight of each metabolic-feature to assess which metabolites may be more characteristic or diagnostic of salt stress, as determined by Na levels (Fig. 3).Open in a separate windowFigure 3Predictive power of the analysis, as revealed by a linear regression between the measured [Na] or biomass and the predicted [Na] or biomass from the models. The predictions were performed based on 10-fold crossvalidation, where in each segment the true values of Na content and biomass were held out and predicted from the corresponding metabolome data using the OPLS model.

Table 1

The top-most positively and negatively correlated metabolites of the metabolite [Na] regression model

Genome-wide analysis of lipoxygenase gene family in Arabidopsis and rice

The enzymes called lipoxygenases (LOXs) can dioxygenate unsaturated fatty acids, which leads to lipoperoxidation of biological membranes. This process causes synthesis of signaling molecules and also leads to changes in cellular metabolism. LOXs are known to be involved in apoptotic (programmed cell death) pathway, and biotic and abiotic stress responses in plants. Here, the members of LOX gene family in Arabidopsis and rice are identified. The Arabidopsis and rice genomes encode 6 and 14 LOX proteins, respectively, and interestingly, with more LOX genes in rice. The rice LOXs are validated based on protein alignment studies. This is the first report wherein LOXs are identified in rice which may allow better understanding the initiation, progression and effects of apoptosis, and responses to bitoic and abiotic stresses and signaling cascades in plants.Key words: apoptosis, biotic and abiotic stresses, genomics, jasmonic acid, lipidsLipoxygenases (linoleate:oxygen oxidoreductase, EC 1.13.11.-; LOXs) catalyze the conversion of polyunsaturated fatty acids (lipids) into conjugated hydroperoxides. This process is called hydroperoxidation of lipids. LOXs are monomeric, non-heme and non-sulfur, but iron-containing dioxygenases widely expressed in fungi, animal and plant cells, and are known to be absent in prokaryotes. However, a recent finding suggests the existence of LOX-related genomic sequences in bacteria but not in archaea.¹ The inflammatory conditions in mammals like bronchial asthama, psoriasis and arthritis are a result of LOXs reactions.² Further, several clinical conditions like HIV-1 infection,³ disease of kidneys due to the activation of 5-lipoxygenase,^4,5 aging of the brain due to neuronal 5-lipoxygenase⁶ and atherosclerosis⁷ are mediated by LOXs. In plants, LOXs are involved in response to biotic and abiotic stresses.⁸ They are involved in germination⁹ and also in traumatin and jasmonic acid biochemical pathways.^10,11 Studies on LOX in rice are conducted to develop novel strategies against insect pests¹² in response to wounding and insect attack,¹³ and on rice bran extracts as functional foods and dietary supplements for control of inflammation and joint health.¹⁴ In Arabidopsis, LOXs are studied in response to natural and stress-induced senescence,¹⁵ transition to flowering,¹⁶ regulation of lateral root development and defense response.¹⁷The arachidonic, linoleic and linolenic acids can act as substrates for different LOX isozymes. A hydroperoxy group is added at carbons 5, 12 or 15, when arachidonic acid is the substrate, and so the LOXs are designated as 5-, 12- or 15-lipoxygenases. Sequences are available in the database for plant lipoxygenases (EC:1.13.11.12), mammalian arachidonate 5-lipoxygenase (EC:1.13.11.34), mammalian arachidonate 12-lipoxygenase (EC:1.13.11.31) and mammalian erythroid cell-specific 15-lipoxygenase (EC:1.13.11.33). The prototype member for LOX family, LOX-1 of Glycine max L. (soybean) is a 15-lipoxygenase. The LOX isoforms of soybean (LOX-1, LOX-2, LOX-3a and LOX-3b) are the most characterized of plant LOXs.¹⁸ In addition, five vegetative LOXs (VLX-A, -B, -C, -D, -E) are detected in soybean leaves.¹⁹ The 3-dimensional structure of soybean LOX-1 has been determined.^20,21 LOX-1 was shown to be made of two domains, the N-terminal domain-I which forms a β-barrel of 146 residues, and a C-terminal domain-II of bundle of helices of 693 residues²¹ (Fig. 1). The iron atom was shown to be at the centre of domain-II bound by four coordinating ligands, of which three are histidine residues.²²Open in a separate windowFigure 1Three-dimensional structure of soybean lipoxygenase L-1. The domain I (N-terminal) and domain II (C-terminal) are indicated. The catalytic iron atom is embedded in domain II (PDB ID-1YGE).²¹This article describes identification of LOX genes in Arabidopsis and rice. The Arabidopsis genome encodes for six LOX proteins²³ (www.arabidopsis.org) (LocusAnnotationNomenclatureA^*B^*C^*AT1G55020lipoxygenase 1 (LOX1)LOX185998044.45.2049AT1G17420lipoxygenase 3 (LOX3)LOX3919103725.18.0117AT1G67560lipoxygenase family proteinLOX4917104514.68.0035AT1G72520lipoxygenase, putativeLOX6926104813.17.5213AT3G22400lipoxygenase 5 (LOX5)LOX5886101058.86.6033AT3G45140lipoxygenase 2 (LOX2)LOX2896102044.75.3177Open in a separate window^*A, amino acids; B, molecular weight; C, isoelectric point.Interestingly, the rice genome (rice.plantbiology.msu.edu) encodes for 14 LOX proteins as compared to six in Arabidopsis (​and22). Of these, majority of them are composed of ∼790–950 aa with the exception for loci, LOC_Os06g04420 (126 aa), LOC_Os02g19790 (297 aa) and LOC_Os12g37320 (359 aa) (Fig. 2).Open in a separate windowFigure 2Protein alignment of rice LOXs and vegetative lipoxygenase, VLX-B,²⁸ a soybean LOX (AA B67732). The 14 rice LOCs are indicated on left and sequence position on right. Gaps are included to improve alignment accuracy. Figure was generated using ClustalX program.

Table 2

Genes encoding lipoxygenases in rice

Genome-wide analysis of thioredoxin fold superfamily peroxiredoxins in Arabidopsis and rice

A broad range of peroxides generated in subcellular compartments, including chloroplasts, are detoxified with peroxidases called peroxiredoxins (Prx). The Prx are ubiquitously distributed in all organisms including bacteria, fungi, animals and also in cyanobacteria and plants. Recently, the Prx have emerged as new molecules in antioxidant defense in plants. Here, the members which belong to Prx gene family in Arabidopsis and rice are been identified. Overall, the Prx members constitute a small family with 10 and 11 genes in Arabidopsis and rice respectively. The prx genes from rice are assigned to their functional groups based on homology search against Arabidopsis protein database. Deciphering the Prx functions in rice will add novel information to the mechanism of antioxidant defense in plants. Further, the Prx also forms the part of redox signaling cascade. Here, the Prx gene family has been described for rice.Key words: antioxidant defense, chloroplast, gene family, oxidative stress, reactive oxygen speciesThe formation of free radicals and reactive oxygen species (ROS) occur in several enzymatic and non-enzymatic reactions during cellular metabolism. The accumulation of these reactive and deleterious intermediates is suppressed by antioxidant defense mechanism comprised of low molecular weight antioxidants and enzymes. In photosynthetic organisms, the defense against the damage from free radicals and oxidative stress is crucial. For instance, the ROS production occurs in photosystem II with generation of singlet oxygen (¹O₂) and hydrogen peroxide (H₂O₂),^1,2 photosystem I from superoxide anion radicals (O₂⁻),³ and during photorespiration with generation of H₂O₂.⁴ ROS production may exceed under environmental stress conditions like excess light, low temperature and drought.⁵The antioxidant defense mechanism is activated by antioxidant metabolities and enzymes which detoxify ROS and lipid peroxides. The detoxification of ROS can occur in various cellular compartments such as chloroplasts, mitochondria, peroxisomes and cytosol.⁶ The enzymes like ascorbate peroxidase, catalase, glutathione peroxidase and superoxide dismutase are prominent antioxidant enzymes.⁶ The peroxiredoxins (Prx) emerged as new components in the antioxidant defense network of barley.^7,8 Later, Prx were studied in other plants.^9–14Prx can be classified into four different functional groups, PrxQ, 1-Cys Prx, 2-Cys Prx and Type-2 Prx.^15,16 They are members of the thioredoxin fold superfamily.^17,18 In this study, the prx genes found in Arabidopsis and rice genomes are been identified. The Arabidopsis genome encodes 10 prx genes classified into four functional categories, 1-Cys Prx, 2-Cys Prx, PrxQ and Type-2 Prx.¹³ Of these, one each of 1-Cys Prx and PrxQ, two of 2-Cys Prx (2-Cys PrxA and 2-Cys PrxB) and six Type-2 Prx (PrxA–F) are identified¹³ (LocusAnnotationSynonymA^*B^*C^*AT1G481301-Cysteine peroxiredoxin 1 (ATPER1)1-Cys Prx21624081.36.603AT1G60740Peroxiredoxin type 2Type-2 PrxD16217471.95.2297AT1G65970Thioredoxin-dependent peroxidase 2 (TPX2)Type-2 PrxC16217413.95.2297AT1G65980Thioredoxin-dependent peroxidase 1 (TPX1)Type-2 PrxB16217427.84.9977AT1G65990Type 2 peroxiredoxin-relatedType-2 PrxA55362653.66.4368AT3G06050Peroxiredoxin IIF (PRXIIF)Type-2 PrxF20121445.29.3905AT3G116302-Cys Peroxiredoxin A (2CPA, 2-Cys PrxA)2-Cys PrxA26629091.77.5686AT3G26060ATPRX Q, periredoxin QPrxQ21623677.810.0565AT3G52960Peroxiredoxin type 2Type-2 PrxE23424684.09.572AT5G062902-Cysteine Peroxiredoxin B (2CPB, 2-Cys PrxB)2-Cys PrxB27329779.55.414Open in a separate window^*A, amino acids; B, molecular weight; C, isoelectric point.In rice (rice.plantbiology.msu.edu/), there are 11 genomic loci which encode for Prx proteins (​and33). Interestingly, a new prx gene (LOC_Os07g15670) annotated as “peroxiredoxin, putative, expressed” is identified making the tally of prx genes to eleven in rice as compared to ten in Arabidopsis (​and22). The BLAST search has identified its counterpart in Arabidopsis which has been annotated as “antioxidant/oxidoreductase” (AT1G21350) in the TAIR database (www.arabidopsis.org). The rice LOC_Os07g15670 and Arabidopsis AT1G21350 share protein homology %68/78 for 236 amino acids (ChromosomeLocus IdPutative function/AnnotationA^*B^*C^*1LOC_Os01g16152peroxiredoxin, putative, expressed19920873.68.22091LOC_Os01g24740peroxiredoxin-2E-1, chloroplast precursor, putative10711591.56.79061LOC_Os01g48420peroxiredoxin, putative, expressed16317290.85.68282LOC_Os02g09940peroxiredoxin, putative, expressed22623179.56.5352LOC_Os02g33450peroxiredoxin, putative, expressed26228096.95.77094LOC_Os04g339702-Cys peroxiredoxin BAS1, chloroplast precursor, putative, expressed12213410.24.37056LOC_Os06g09610peroxiredoxin, putative, expressed2662892610.50976LOC_Os06g42000peroxiredoxin, putative, expressed23323688.39.20597LOC_Os07g15670peroxiredoxin, putative, expressed25327684.69.85457LOC_Os07g44440peroxiredoxin, putative, expressed22124232.65.36187LOC_Os07g44430peroxiredoxin, putative25627785.36.8544Open in a separate window^*A, amino acids; B, molecular weight; C, isoelectric point.

Table 3

Identification of rice homologs of peroxiredoxins in A. thaliana

Cell Biology of Mitotic Recombination

Homologous recombination provides high-fidelity DNA repair throughout all domains of life. Live cell fluorescence microscopy offers the opportunity to image individual recombination events in real time providing insight into the in vivo biochemistry of the involved proteins and DNA molecules as well as the cellular organization of the process of homologous recombination. Herein we review the cell biological aspects of mitotic homologous recombination with a focus on Saccharomyces cerevisiae and mammalian cells, but will also draw on findings from other experimental systems. Key topics of this review include the stoichiometry and dynamics of recombination complexes in vivo, the choreography of assembly and disassembly of recombination proteins at sites of DNA damage, the mobilization of damaged DNA during homology search, and the functional compartmentalization of the nucleus with respect to capacity of homologous recombination.Homologous recombination (HR) is defined as the homology-directed exchange of genetic information between two DNA molecules (Fig. 1). Mitotic recombination is often initiated by single-stranded DNA (ssDNA), which can arise by several avenues (Mehta and Haber 2014). They include the processing of DNA double-strand breaks by 5′ to 3′ resection, during replication of damaged DNA, or during excision repair (Symington 2014). The ssDNA is bound by replication protein A (RPA) to control its accessibility to the Rad51 recombinase (Sung 1994, 1997a; Sugiyama et al. 1997; Morrical 2014). The barrier to Rad51-catalyzed recombination imposed by RPA can be overcome by a number of mediators, such as BRCA2 and Rad52, which serve to replace RPA with Rad51 on ssDNA, and the Rad51 paralogs Rad55-Rad57 (RAD51B-RAD51C-XRCC2-XRCC3) and the Psy3-Csm2-Shu1-Shu2 complex (SHU) (RAD51D-XRCC2-SWS1), which stabilize Rad51 filaments on ssDNA (see Sung 1997b; Sigurdsson et al. 2001; Martin et al. 2006; Bernstein et al. 2011; Liu et al. 2011; Qing et al. 2011; Amunugama et al. 2013; Zelensky et al. 2014). The Rad51 nucleoprotein filament catalyzes the invasion into a homologous duplex to produce a displacement loop (D-loop) (Fig. 1). At this stage, additional antirecombination functions are exerted by Srs2 (FBH1, PARI), which dissociates Rad51 filaments from ssDNA, and Mph1 (FANCM), which disassembles D-loops (see Daley et al. 2014). Upon Rad51-catalyzed strand invasion, the ATP-dependent DNA translocase Rad54 enables the invading 3′ end to be extended by DNA polymerases to copy genetic information from the intact duplex (Li and Heyer 2009). Ligation of the products often leads to joint molecules (JMs), such as single- or double-Holliday junctions (s/dHJs) or hemicatenanes (HCs), which must be processed to allow separation of the sister chromatids during mitosis. JMs can be dissolved by the Sgs1-Top3-Rmi1 complex (STR) (BTR, BLM-TOP3α-RMI1-RMI2) (see Bizard and Hickson 2014) or resolved by structure-selective nucleases, such as Mus81-Mms4 (MUS81-EME1), Slx1-Slx4, and Yen1 (GEN1) (see Wyatt and West 2014). Mitotic cells favor recombination events that lead to noncrossover events likely to avoid potentially detrimental consequences of loss of heterozygosity and translocations.Open in a separate windowFigure 1.Primary pathways for homology-dependent double-strand break (DSB) repair. Recombinational repair of a DSB is initiated by 5′ to 3′ resection of the DNA end(s). The resulting 3′ single-stranded end(s) invade an intact homologous duplex (in red) to prime DNA synthesis. For DSBs that are repaired by the classical double-strand break repair (DSBR) model, the displaced strand from the donor duplex pairs with the 3′ single-stranded DNA (ssDNA) tail at the other side of the break, which primes a second round of DNA synthesis. After ligation of the newly synthesized DNA to the resected 5′ strands, a double-Holliday junction (dHJ) intermediate is generated. The dHJ can be either dissolved by branch migration (indicated by arrows) into a hemicatenane (HC) leading to noncrossover (NCO) products or resolved by endonucleolytic cleavage (indicated by triangles) to produce NCO (positions 1, 2, 3, and 4) or CO (positions 1, 2, 5, and 6) products. Alternatively to the double-strand break repair (DSBR) pathway, the invading strand is often displaced after limited synthesis and the nascent complementary strand anneals with the 3′ single-stranded tail of the other end of the DSB. After fill-in synthesis and ligation, this pathway generates NCO products and is referred to as synthesis-dependent strand annealing (SDSA).

Table 1.

Evolutionary conservation of homologous recombination proteins between Saccharomyces cerevisiae and Homo sapiens

Efflux of hydraulically lifted water from mycorrhizal fungal hyphae during imposed drought

Apart from improving plant and soil water status during drought, it has been suggested that hydraulic lift (HL) could enhance plant nutrient capture through the flow of mineral nutrients directly from the soil to plant roots, or by maintaining the functioning of mycorrhizal fungi. We evaluated the extent to which the diel cycle of water availability created by HL covaries with the efflux of HL water from the tips of extramatrical (external) mycorrhizal hyphae, and the possible effects on biogeochemical processes. Phenotypic mycorrhizal fungal variables, such as total and live hyphal lengths, were positively correlated with HL efflux from hyphae, soil water potential (dawn), and plant response variables (foliar ¹⁵N). The efflux of HL water from hyphae was also correlated with bacterial abundance and soil enzyme activity (P), and the moistening of soil organic matter. Such findings indicate that the efflux of HL water from the external mycorrhizal mycelia may be a complementary explanation for plant nutrient acquisition and survival during drought.Key words: hydraulic lift, nitrogen, phosphorus, microbial abundance, mycorrhizal hyphae, QuercusIn environments that experience seasonal or extended drought, plant productivity, resource partitioning, and competition are limited by the availability of water and mineral nutrients. One mechanism that is important to whole plant water balance in these environments is hydraulic lift (HL), a passive process driven by gradients in water potential among soils layers. Soil water is transported upwards from deep moist soils and released into the nutrient-rich upper soil layers by root systems accessing both deep and shallow soil layers.¹ HL water may improve the lifespan and activity of fine roots in a wide variety of plant life forms.²Hydraulic lift may also have a second ecological function in facilitating plant nutrient acquisition.² It been hypothesized that HL water could enhance the supply of nutrients to roots through mass flow or diffusion,³ or trigger episodes of soil biotic activity such as microbe-mediated nutrient transformations^4,5 that are analogous to the increased inflow of nitrogen (N) into roots and flushes of carbon (C) and N mineralization respectively that follow precipitation events.^4,6 However, few data currently exist with which to test these possibilities.Hydraulically lifted water also sustains mycorrhizal fungi,^7,8 a mutualism that enhances the acquisition of water and mineral nutrients in many terrestrial plant species. Mycorrhizal fungal hyphae provide comprehensive exploration and rapid access to small-scale or temporary nutrient flushes that may not be available to plant roots.⁹ This resource flow has often been assumed to be a unidirectional flux whereby resources are moved from source (soil) into the sink (plant) by the fungal hyphae. However, there is now evidence to suggest that the physiological plasticity of the peripheral extramatrical hyphae, and in particular the hyphal tips, permits the exudation, and subsequent reabsorption, of water and solutes.^10,11 Laboratory experiments using pure cultures have demonstrated that water may be exuded from the hyphal tips, especially in fungal species with hydrophobic hyphae, along with a variety of organic molecules, such as free amino acids.^10–13 At the same time, water, mobile minerals, amino acids and other low-molecular weight metabolites may be selectively and actively reabsorbed by mycorrhizal fungal hyphae.¹¹ However, quantitative data on the environmental impact of hyphal exudation and reabsorption is still largely lacking.We ask: could the diel cycle of water availability created by HL produce a water efflux from hyphal tips and if so, would this be sufficient to impact biogeochemical processes? Is there also an opposite rhythm driven by plant transpiration so that any resultant soil solution is pulled towards hyphal tips and consequently, the host plant? By imposing drought on seedlings of Quercus agrifolia Nee (coast live oak; Fagaceae) grown in mesocosms (Fig. 1), we identified a composite of feedbacks that could influence nutrient capture with HL (Fig. 2). Our analyses provide support for the key predictions of the HL-nutrient cycling scenario including the efflux of HL water from the extramatrical hyphae (Fig. 3), moistening of soil organic matter (Figs. 3 and ​and4),4), and the maintenance of soil microbial activity and nutrient capture (N, P; Open in a separate windowFigure 1Quercus mesocosms demonstrating the plant, root, and hyphal compartments. Details of soil conditions, plant inoculation protocol, mycorrhizal fungi and dye injection methods are detailed in previous work (ref. 7) Point 1 (tap root compartment) denotes the region in which fluorescent tracer dyes were injected into the mesocosm at dusk to track the path of HL water. Point 2 (hyphal chamber) denotes spots adjacent to or distant from the mesh screen into which a small volume (200 µl) of fluorescent and ¹⁵N tracers (99% as ¹⁵NH₄¹⁵NO₃) were injected at dawn to measure water and nutrient uptake by the external hyphae.Open in a separate windowFigure 2Path analysis of the influence of different soil and mycorrhizal factors on nutrient capture with HL, and resultant model showing the significant path coefficients among variables in the Q. agrifolia mesocosms. Lines with a single arrow denote possible cause-effect relationships. The partial correlation coefficients adjacent to each line indicate the strength of the association between the individual factors. Thick lines are statistically significant (p < 0.05) whereas thin lines indicate no significant relationship between parameters (p > 0.05) and only significant coefficients are given (p < 0.05).Open in a separate windowFigure 3Fluorescently-labeled structures recovered from the hyphal chamber of Quercus microcosms following 80 days of soil drying and with nocturnal hydraulic lift. Yellow-green fluorescence indicates samples labeled with Lucifer yellow CH (LYCH), blue fluorescence denotes samples labeled with Cascade blue (CB) hydrazide. (A) CB-labeled leaf litter from the soil and (B) soil particle; (C) LYCH-labeled root fragment in the soil mixture with adherent extramatrical hyphae; (D) LYCH tracer dye fluorescence in labeled extramatrical hyphae and in efflux (arrow) from the hyphal tip onto organic matter; (E and F) external hyphae filled with LYCH (influx; arrow) and (G) background fluorescence in non-labeled extramatrical hyphae.Open in a separate windowFigure 4Measurements of hyphal efflux and influx based on the quantitative analysis of LYCH fluorescence intensity in soil solution. Fluorescent intensity values were converted to LYCH concentration using a standard curve generated for the dye since fluorescent intensity correlates with the number of fluorescent molecules in solution. Influx is the uptake of LYCH by hyphae as driven by plant transpiration demands (day), and measured efflux is the passive loss of LYCH from hyphae into the surrounding soil during HL (night). Vertical bars indicate the standard error of the means.

Table 1

Summary of soil, microbial, mycorrhizal and plant parameters in plant or hyphal compartments

Human Genetic Disorders of Axon Guidance

This article reviews symptoms and signs of aberrant axon connectivity in humans, and summarizes major human genetic disorders that result, or have been proposed to result, from defective axon guidance. These include corpus callosum agenesis, L1 syndrome, Joubert syndrome and related disorders, horizontal gaze palsy with progressive scoliosis, Kallmann syndrome, albinism, congenital fibrosis of the extraocular muscles type 1, Duane retraction syndrome, and pontine tegmental cap dysplasia. Genes mutated in these disorders can encode axon growth cone ligands and receptors, downstream signaling molecules, and axon transport motors, as well as proteins without currently recognized roles in axon guidance. Advances in neuroimaging and genetic techniques have the potential to rapidly expand this field, and it is feasible that axon guidance disorders will soon be recognized as a new and significant category of human neurodevelopmental disorders.The human brain is highly organized and contains a myriad of axon tracts that follow precise pathways and make predictable connections. Model organism research has provided tremendous advances in our understanding of the principles and molecules governing axon growth and guidance. Remarkably, however, only a handful of human disorders resulting from primary errors in these processes have been identified.Traditional tools of the physician have limited sensitivity and specificity to detect human disorders of axon guidance. In particular, congenital synkinesis may be the only physical examination finding that has been attributed to such disorders. Synkinesis is the involuntary and pathological contraction of a muscle simultaneously with contraction of the intended muscle, and is typically reported with hand/finger or eye/eyelid movements and confirmed by electrophysiological studies. Mirror movement synkinesis refers to the contraction of homologous hand/finger muscles bilaterally when one attempts to move only one hand (Schott and Wyke 1981). In humans, 75%–90% of corticospinal tract (CST) fibers normally decussate in the lower medulla. Mirror movement synkinesis occurs in several human disorders with pathological, neuroimaging, and/or electrophysiological evidence of reduced CST decussation, including Joubert, Kallmann, and Klippel-Feil syndromes (Vulliemoz et al. 2005; Cincotta and Ziemann 2008). In some individuals with mirror movements, electrophysiological data are also consistent with bilateral engagement of the motor corticies (Leinsinger et al. 1997). Ocular synkinesis refers to aberrant patterns of eye movement and accompanies various congenital cranial dysinnervation disorders (CCDDs) (Gutowski et al. 2003; Engle 2007), including CFEOM, Duane syndrome, and Marcus Gunn jaw-winking phenomenon (Fig. 1). Finger and ocular movements require precise motor control, and errors in innervation of these muscles may be more easily detected than errors in the wiring of larger muscle groups. If true, this suggests that the clinical exam could fail to recognize many guidance errors in both the peripheral and central nervous system.Open in a separate windowFigure 1.Ocular synkinesis. (A) Child with CFEOM1 and Marcus Gunn jaw-winking phenomenon harboring a KIF21A mutation. His superior branch of the oculomotor nerve is hypoplastic/absent, resulting in bilateral ptosis from lack of appropriate innervation of the levator palpebrae superioris (LPS) muscle, and a downward position of each eye from absent innervation of the superior rectus muscle (left). Marcus Gunn phenomenon (right) is seen as the synkinetic elevation of the left eyelid with a subtle change in jaw position associated with a volitional increase in pterygoid muscle tension. This results from aberrant innervation of the LPS by axons from the motor branch of the trigeminal nerve that also innervates the intended ipsilateral pterygoid muscle. (B) Adult with Duane retraction syndrome harboring a CHN1 mutation. Central gaze reveals mild exotropia (middle). On attempted right gaze (left) and left gaze (right), there is limited horizontal excursion with globe retraction and secondary palpebral fissure narrowing of the adducting eye. Globe retraction results from synkinesis of the medial and lateral recti muscles. (A) Modified with permission from Yamada et al. 2005. Copyright © (2005) American Medial Association. All rights reserved. (B) Modified from Demer et al. 2007. Copyright © (2007) Association for Research in Vision and Ophthalmology. All rights reserved.The physician’s ability to detect disorders of axon guidance has been augmented by classical pathological, radiological, and electrophysiological techniques. Diagnostic radiologic and postmortem neuropathological studies detect overall changes in white matter volume and major abnormalities of axon tracts demarcated from the background such as the corpus callosum, anterior and posterior commissures, optic chiasm, and cerebellar peduncles. Neuropathological studies can also detect absence of axons that normally cross the midline at many points in the brain stem and spinal cord, which are more difficult to visualize by standard magnetic resonance imaging (MRI). Electrophysiological studies such as evoked potentials can reveal aberrant central connections of peripheral sensory or motor nerves.The genetic disorders with aberrant axon connectivity presented in this article have been defined primarily using traditional approaches described above. Exciting advances in neuroimaging and genetics, however, are revolutionizing the ability to define axon guidance disorders, and it is likely that these syndromes are only the first of an important new category of such human neurodevelopmental disorders. Detailed fiber tract anatomy can now be visualized using noninvasive tractography such as diffusion tensor imaging (DTI) and diffusion spectrum imaging (DSI). These techniques provide tract orientation by determining the anisotropic properties of water diffusion, and can be used to reconstruct the trajectories of fiber systems in three-dimensional space (Tovar-Moll et al. 2007; Wahl et al. 2009). Tractography has successfully confirmed aberrant projections in several of the disorders discussed below (Fig. 2). At the same time, human genetics now provides an unbiased approach to identify the etiologies of disorders with aberrant axon tracts. For some syndromes, animal and in vitro studies have confirmed that the encoded protein has a primary role in axon guidance. For others, such studies reveal a primary role in neuronal specification and/or migration rather than, or in addition to, a role in axon guidance. Finally, some neurodevelopmental disorders without clinical, pathologic, or radiologic evidence of aberrant axon tracts have been found to result from mutations in genes that contribute to axon guidance in animal models.Open in a separate windowFigure 2.Tractography studies in patients with partial agenesis of the corpus callosum (pACC). T1-weighted anatomic images and DTI tractography of six subjects with pACC (top panels) and two representative controls (bottom panel). Axial (left) and midline sagittal (middle) T1 sections are shown for each subject. Callosal fragments are identified with yellow arrows, and heterotopic fibers visible on T1-weighted images are denoted by red arrows. Midline sagittal DTI color maps are shown with segmented callosal fibers (right). For subjects with pACC, connectivity ranged from anterior frontal connections (subject 3) to only posterior frontal and occipitotemporal connections (subject 4). One individual (subject 5) displayed a discontinuous set of homotopic callosal connections, with anterior frontal and occipitotemporal connectivity without any posterior frontal or parietal connections. Control subjects (bottom panel) display normal callosal morphology and tractography results. Tracts are segmented and colored according to their cortical projections: homotopic anterior frontal, blue; homotopic posterior frontal, orange; homotopic parietal, pink; homotopic occipitotemporal, green; heterotopic left anterior-right posterior, yellow; heterotopic right anterior-left posterior, red. (Reprinted, with permission, from Wahl et al. 2009 [© AJNR].)The major human genetic disorders that result, or are proposed to result, from defective axon guidance are ordered below from rostral to caudal based on the location of the aberrant axons tracts. These include genetic mutations that alter axon growth cone ligands and receptors, downstream signaling molecules, and axon transport, as well as proteins without currently recognized roles in axon guidance (Fig. 3) (Open in a separate windowFigure 3.Schematic representation of gene products implicated in human disorders of axon guidance. KAL1 (anosmin) and PROK2 are shown as secreted ligands. ROBO3, L1, and PROKR2 are shown as transmembrane receptors on the growth cone. CHN1 is depicted with 3 green domains (SH2, C1, RacGAP), responding to an unknown activated receptor and altering a microtubule, which is depicted as a brown line. KIF21A dimers are depicted walking down MTs. The OCA/OA and JSRD gene products are not depicted. Note: these gene products are not necessarily expressed in the same neurons or function in the same pathways.

Table 1

Summary of major human genetic disorders resulting, or hypothesized to result, from errors in axon growth and guidance

Aluminum induced proteome changes in tomato cotyledons

Cotyledons of tomato seedlings that germinated in a 20 µM AlK(SO₄)₂ solution remained chlorotic while those germinated in an aluminum free medium were normal (green) in color. Previously, we have reported the effect of aluminum toxicity on root proteome in tomato seedlings (Zhou et al.¹). Two dimensional DIGE protein analysis demonstrated that Al stress affected three major processes in the chlorotic cotyledons: antioxidant and detoxification metabolism (induced), glyoxylate and glycolytic processes (enhanced), and the photosynthetic and carbon fixation machinery (suppressed).Key words: aluminum, cotyledons, proteome, tomatoDifferent biochemical processes occur depending on the developmental stages of cotyledons. During early seed germination, before the greening of the cotyledons, glyoxysomes enzymes are very active. Fatty acids are converted to glucose via the gluconeogenesis pathway.^2,3 In greening cotyledons, chloroplast proteins for photosynthesis and leaf peroxisomal enzymes in the glycolate pathway for photorespiration are metabolized.^2–4 Enzymes involved in regulatory mechanisms such as protein kinases, protein phosphatases, and mitochondrial enzymes are highly expressed.^3,5,6The chlorotic cotyledons are similar to other chlorotic counterparts in that both contains lower levels of chlorophyll, thus the photosynthetic activities are not as active. In order to understand the impact of Al on tomato cotyledon development, a comparative proteome analysis was performed using 2D-DIGE following the as previously described procedure.¹ Some proteins accumulated differentially in Al-treated (chlorotic) and untreated cotyledons (Fig. 1). Mass spectrometry of tryptic digestion fragments of the proteins followed by database search has identified some of the differentially expressed proteins (Open in a separate windowFigure 1Image of protein spots generated by Samspot analysis of Al treated and untreated tomato cotyledons proteomes separated on 2D-DIGE.

Table 1

Proteins identified from tomato cotyledons of seeds germinating in Al-solution

Immunomodulation by Mesenchymal Stem Cells in Veterinary Species

Mesenchymal stem cells (MSC) are adult-derived multipotent stem cells that have been derived from almost every tissue. They are classically defined as spindle-shaped, plastic-adherent cells capable of adipogenic, chondrogenic, and osteogenic differentiation. This capacity for trilineage differentiation has been the foundation for research into the use of MSC to regenerate damaged tissues. Recent studies have shown that MSC interact with cells of the immune system and modulate their function. Although many of the details underlying the mechanisms by which MSC modulate the immune system have been defined for human and rodent (mouse and rat) MSC, much less is known about MSC from other veterinary species. This knowledge gap is particularly important because the clinical use of MSC in veterinary medicine is increasing and far exceeds the use of MSC in human medicine. It is crucial to determine how MSC modulate the immune system for each animal species as well as for MSC derived from any given tissue source. A comparative approach provides a unique translational opportunity to bring novel cell-based therapies to the veterinary market as well as enhance the utility of animal models for human disorders. The current review covers what is currently known about MSC and their immunomodulatory functions in veterinary species, excluding laboratory rodents.Abbreviations: AT, adipose tissue; BM, Bone marrow; CB, umbilical cord blood; CT, umbilical cord tissue; DC, dendritic cell; IDO, indoleamine 2;3-dioxygenase; MSC, mesenchymal stem cells; PGE₂, prostaglandin E2; VEGF, vascular endothelial growth factorMesenchymal stem cells (MSC, alternatively known as mesenchymal stromal cells) were first reported in the literature in 1968.³⁹ MSC are thought to be of pericyte origin (cells that line the vasculature)^21,22 and typically are isolated from highly vascular tissues. In humans and mice, MSC have been isolated from fat, placental tissues (placenta, Wharton jelly, umbilical cord, umbilical cord blood), hair follicles, tendon, synovial membrane, periodontal ligament, and every major organ (brain, spleen, liver, kidney, lung, bone marrow, muscle, thymus, pancreas, skin).^23,121 For most current clinical applications, MSC are isolated from adipose tissue (AT), bone marrow (BM), umbilical cord blood (CB), and umbilical cord tissue (CT; 11,87,99 Clinical trials in human medicine focus on the use of MSC both for their antiinflammatory properties (graft-versus-host disease, irritable bowel syndrome) and their ability to aid in tissue and bone regeneration in combination with growth factors and bone scaffolds (clinicaltrials.gov).¹³¹ For tissue regeneration, the abilities of MSC to differentiate and to secrete mediators and interact with cells of the immune system likely contribute to tissue healing (Figure 1). The current review will not address the specific use of MSC for orthopedic applications and tissue regeneration, although the topic is covered widely in current literature for both human and veterinary medicine.^57,62,90

Table 1.

Tissues from which MSC have been isolated

Biochemical Characterization of Haloalkane Dehalogenases DrbA and DmbC,Representatives of a Novel Subfamily

This study focuses on two representatives of experimentally uncharacterized haloalkane dehalogenases from the subfamily HLD-III. We report biochemical characterization of the expression products of haloalkane dehalogenase genes drbA from Rhodopirellula baltica SH1 and dmbC from Mycobacterium bovis 5033/66. The DrbA and DmbC enzymes show highly oligomeric structures and very low activities with typical substrates of haloalkane dehalogenases.Haloalkane dehalogenases (EC 3.8.1.5.) acting on halogenated aliphatic hydrocarbons catalyze carbon-halogen bond cleavage, leading to an alcohol, a halide ion, and a proton as the reaction products (7). Haloalkane dehalogenases originating from various bacterial strains have potential for application in bioremediation technologies (4, 6, 22), construction of biosensors (2), decontamination of warfare agents (17), and synthesis of optically pure compounds (19). Recent evolutionary study of haloalkane dehalogenase sequences revealed the existence of three subfamilies, denoted HLD-I, HLD-II, and HLD-III (3). In contrast to subfamilies HLD-I and HLD-II, the subfamily HLD-III is currently lacking experimentally characterized proteins. We have therefore focused on the isolation and study of two selected representatives of the HLD-III subfamily, DrbA and DmbC.The drbA gene was amplified by PCR using the cosmid pircos.a3g10 originating from marine bacterium Rhodopirellula baltica SH1, and the dmbC gene was amplified from DNA originating from obligatory pathogen Mycobacterium bovis 5033/66. Six-histidine tails were added to the C termini of DrbA and DmbC in a cloning step, enabling single-step purification using Ni-nitrilotriacetic acid resin. Haloalkane dehalogenase DrbA was expressed under the T7 promoter and purified, with a resulting yield of 0.1 mg of protein per gram of cell mass. Haloalkane dehalogenase DmbC was obtained by expression in Mycobacterium smegmatis, with a yield of 0.07 mg of purified protein per gram of cell mass.The correct folding and secondary structures of the newly prepared enzymes were verified by circular dichroism (CD) spectroscopy. Far-UV CD spectra were recorded for DrbA and DmbC enzymes and other, related haloalkane dehalogenases. All enzymes tested exhibited CD spectra with two negative features at 208 and 222 nm and one positive peak at 195 nm, which are characteristic of α-helical content (Fig. ​(Fig.1).1). This suggested that both new enzymes, DrbA and DmbC, were folded correctly. However, DmbC exhibited more intense negative maxima which differed from other haloalkane dehalogenases in the θ₂₂₂/θ₂₀₈ ratio. This finding indicated a slight variation in the arrangement of secondary structure elements of the DmbC enzyme. Thermally induced denaturations of DrbA and DmbC were tested in parallel. Both enzymes showed changes in ellipticity during increasing temperature. The melting temperatures calculated from these curves were 45.8 ± 0.4°C for DmbC and 39.4 ± 0.1°C for DrbA. The thermostability results obtained for DrbA and DmbC were in good agreement with the range of melting temperatures determined for other, related haloalkane dehalogenases.Open in a separate windowFIG. 1.Far-UV CD spectra of DrbA, DmbC, and seven different biochemically characterized haloalkane dehalogenases. Protein concentration used for far-UV CD spectrum measurement was 0.2 mg/ml.The sizes of the purified proteins were estimated by electrophoresis under native conditions conducted using a 10% polyacrylamide gel (Fig. ​(Fig.2).2). More precise determination of the sizes of DrbA and DmbC was achieved by gel filtration chromatography performed on Sephacryl S-500 HR (GE Healthcare, Uppsala, Sweden), calibrated with blue dextran 2000, thyroglobulin (669 kDa), ferritin (440 kDa), catalase (240 kDa), conalbumin (75 kDa), and ovalbumin (43 kDa) (Fig. ​(Fig.3A).3A). Both DrbA and DmbC were eluted from the column in the fraction prior to blue dextran, indicating that both enzymes form oligomeric complexes of a size larger than 2,000 kDa (Fig. 3B and C). The haloalkane dehalogenases which have been biochemically characterized so far form monomers, except for DbjA isolated from Bradyrhizobium japonicum USDA110 (21), which shows monomeric, dimeric, and tetrameric forms according to the pH of the buffer (R. Chaloupkova, submitted for publication).Open in a separate windowFIG. 2.Native protein electrophoresis of DrbA and DmbC. Lane 1, carbonic anhydrase (29 kDa); lane 2, ovalbumin (43 kDa); lane 3, bovine albumin (67 kDa); lane 4, conalbumin (75 kDa); lane 5, catalase (240 kDa); lane 6, ferritin (440 kDa); lane 7, DrbA; lane 8, DmbC.Open in a separate windowFIG. 3.Gel filtration chromatogram of DrbA and DmbC. (A) The following calibration kit samples (0.5 ml of a concentration of 2 mg/ml protein loaded) were analyzed using 50 mM Tris-HCl with 150 mM NaCl, pH 7.5, as elution buffer: blue dextran (line 1, 9.6-ml fraction), thyroglobulin (line 2, 15.95-ml fraction), ferritin (line 3, 16.78-ml fraction), ovalbumin (line 4, 18.55-ml fraction), and RNase A (line 5, 20.08-ml fraction). (B and C) Haloalkane dehalogenase DrbA eluted in the 9.03-ml fraction (B), and haloalkane dehalogenase DmbC in the 9.31-ml fraction (C).The substrate specificities of DrbA and DmbC were investigated with a set of 30 selected chlorinated, brominated, and iodinated hydrocarbons. Standardized specific activities related to 1-chlorobutane (summarized in Table ​Table1)1) were compared with the activity profiles of other haloalkane dehalogenases (Fig. ​(Fig.4).4). DrbA and DmbC displayed similar activity patterns, with catalytic activities approximately two orders of magnitude lower than those of other known haloalkane dehalogenases (1, 5, 8-11, 13-16, 18, 20, 23). HLD-III subfamily enzymes showed a restricted specificity range and a preference for iodinated short-chain hydrocarbons. Both phenomena may be related to the composition of the catalytic pentad Asp-His-Asp+Asn-Trp, which is unique to the members of the HLD-III subfamily (3). The preference for substrates carrying an iodine substituent can be related to a pair of halide-binding residues and their spatial arrangement with the catalytic triad. These residues make up the catalytic pentad, playing a critical role in substrate binding, formation of the transition states, and the reaction intermediates of the dehalogenation reaction (12).Open in a separate windowFIG. 4.Substrate specificity profiles of DrbA, DmbC, and seven different biochemically characterized haloalkane dehalogenases. Activities were determined using a consistent set of 30 halogenated substrates (see Table ​Table1).1). Data were standardized by dividing each value by the sum of all activities determined for individual enzymes in order to mask the differences in absolute activities. Specific activities (in μmol·s⁻¹·mg⁻¹) with 1-chlorobutane are 0.0003 (DrbA), 0.0001 (DmbC), 0.0003 (DatA), 0.0133 (DbjA), 0.0010 (DbeA), 0.0128 (DhaA), 0.0231 (LinB), 0.0171 (DmbA), and 0.0117 (DhlA).

TABLE 1.

Specific activities of haloalkane dehalogenases DrbA and DmbC toward a set of 30 halogenated hydrocarbons^a

The Golgin Coiled-Coil Proteins of the Golgi Apparatus

A number of long coiled-coil proteins are present on the Golgi. Often referred to as “golgins,” they are well conserved in evolution and at least five are likely to have been present in the last common ancestor of all eukaryotes. Individual golgins are found in different parts of the Golgi stack, and they are typically anchored to the membrane at their carboxyl termini by a transmembrane domain or by binding a small GTPase. They appear to have roles in membrane traffic and Golgi structure, but their precise function is in most cases unclear. Many have binding sites for Rab family GTPases along their length, and this has led to the suggestion that the golgins act collectively to form a tentacular matrix that surrounds the Golgi to capture Rab-coated membranes in the vicinity of the stack. Such a collective role might explain the lack of cell lethality seen following loss of some of the genes in human familial conditions or mouse models.Coiled-coils are widely occurring protein structural motifs in which two or more α-helices wind around each other to form an extended rod-like structure. Proteins containing such structures are found in many parts of the cell, and play diverse roles including organizing centrosomes, chromatin, and synapses, or serving as molecular motors. As such there may seem little reason to consider them collectively beyond an interest in the structural and biophysical properties of the coiled-coil itself. However, the Golgi is unique amongst the cellular compartments in that several different large coiled-coil proteins are present on its cytoplasmic surface (Gillingham and Munro 2003; Lupashin and Sztul 2005; Short et al. 2005; Ramirez and Lowe 2009). A number of these share a similar organization in that most of the protein is predicted to form a coiled-coil, and that their carboxyl termini mediate attachment to Golgi membranes. They are generally ubiquitously expressed and well conserved in evolution, but their coiled-coil regions are relatively poorly conserved suggesting that much of their length serves as spacer. Given that 500 residues of coiled-coil is ∼75 nm in length then the proteins could extend for ∼100–400 nm. Some of the proteins have regions which appear likely to be unstructured and hence could serve as extensions or hinges to increase the proteins’ reach and flexibility (Oas and Endow 1994; Yamakawa et al. 1996). These shared features suggest that the proteins serve related functions on the Golgi. The term “golgin” is often applied to these proteins having been coined in early studies when several were found as human autoantigens (Fritzler et al. 1993), but the term lacks a clear definition. To provide a focus to this article, I will concentrate on “golgins” as defined by being a protein that is found primarily, if not exclusively, on the Golgi and is predicted to form a homodimeric parallel coiled-coil over most of its length. Proteins with shorter regions of coiled-coil are more likely to have roles distinct to the golgins, especially if further domains are present.Golgin coiled-coil proteins are found on the cis-face of the Golgi, around the rims of the stack and on the trans-face of the Golgi (Fig. 1). The human golgins are summarized in Open in a separate windowFigure 1.The golgin coiled-coil proteins of humans.Schematic representations of known human golgins. Regions predicted to form coiled-coils are shown in gray, and known domains involved in protein function or subcellular targeting are indicated.

Table 1.

The canonical golgins of the human Golgi and their orthologs.

Cell cycle phosphorylation of mitotic exit network (MEN) proteins

Phosphorylation of proteins is an important mechanism used to regulate most cellular processes. Recently, we completed an extensive phosphoproteomic analysis of the core proteins that constitute the Saccharomyces cerevisiae centrosome. Here, we present a study of phosphorylation sites found on the mitotic exit network (MEN) proteins, most of which are associated with the cytoplasmic face of the centrosome. We identified 55 sites on Bfa1, Cdc5, Cdc14 and Cdc15. Eight sites lie in cyclin-dependent kinase motifs (Cdk, S/T-P), and 22 sites are completely conserved within fungi. More than half of the sites were found in centrosomes from mitotic cells, possibly in preparation for their roles in mitotic exit. Finally, we report phosphorylation site information for other important cell cycle and regulatory proteins.Key words: in vivo phosphorylation, yeast centrosome, mitotic exit network (MEN), cell cycle, protein kinase, Cdk (cyclin-dependent kinase)/Cdc28, Plk1 (polo-like kinase)/Cdc5Reversible protein phosphorylation leads to changes in targeting, structure and stability of proteins and is used widely to modulate biochemical reactions in the cell. We are interested in phosphoregulation of centrosome duplication and function in the yeast Saccharomyces cerevisiae. Centrosomes nucleate microtubules and, upon duplication during the cell cycle, form the two poles of the bipolar mitotic spindle used to segregate replicated chromosomes into the two daughter cells. Timing and spatial cues are highly regulated to ensure that elongation of the mitotic spindle and separation of sister chromatids occur prior to progression into late telophase and initiation of mitotic exit. The mitotic exit network (MEN) regulates this timing through a complex signaling cascade activated at the centrosome that triggers the end of mitosis, ultimately through mitotic cyclin-dependent kinase (Cdk) inactivation (reviewed in ref. ¹).The major components of the MEN pathway (Fig. 1) are a Ras-like GTPase (Tem1), an activator (Lte1) with homology to nucleotide exchange factors, a GTPase-activating protein (GAP) complex (Bfa1/Bub2), several protein kinases [Cdc5 (Plk1 in humans), Cdc15 and Dbf2/Mob1] and Cdc14 phosphatase (reviewed in ref. ^2–5). Tem1 initiates the signal for the MEN pathway when switched to a GTP-active state. Prior to activation at anaphase, it is held at the centrosome in an inactive GDP-bound state by an inhibiting GAP complex, Bfa1/Bub2.⁶ The Bfa1/Bub2 complex and the inactive Tem1 are localized at the mother centrosome destined to move into the budded cell upon chromosome segregation, whereas the activator Lte1 is localized at the tip of the budded cell. These separate localizations ensure that Lte1 and Tem1 only interact in late anaphase, when the mitotic spindle elongates.^7,8 Lte1 has been thought to activate Tem1 as a nucleotide exchange factor, although more recent evidence suggests that it may instead affect Bfa1 localization.⁹ In addition, full activation of Tem1 is achieved through Cdc5 phosphorylation of the negative regulator Bfa1 ¹⁰ and potentially through phosphorylation of Lte1. GTP-bound Tem1 is then able to recruit Cdc15 to the centrosome, allowing for Dbf2 activation.³ The final step in the MEN pathway is release of Cdc14 from the nucleolus, which is at least partially due to phosphorylation by Dbf2¹¹ an leads to mitotic cyclin degradation and inactivation of the mitotic kinase.²Open in a separate windowFigure 1Schematic representation of the MEN proteins and pathway. MEN protein localization is shown within a metaphase cell when mitotic exit is inhibited and in a late anaphase cell when mitotic exit is initiated. Primary inhibition and activation events are described below the cells.Recently, we performed a large-scale analysis of phosphorylation sites on the 18 core yeast centrosomal proteins present in enriched centrosomal preparations.¹² In total, we mapped 297 sites on 17 of the 18 proteins and described their cell cycle regulation, levels of conservation and demonstrated defects in centrosome assembly and function resulting from mutating selected sites. MEN proteins were also identified in the centrosome preparations. This was expected, because Nud1, one of the 18 core centrosome components, is known to recruit several MEN proteins to the centrosome¹³ as part of its function in mitotic exit.^14,15 As phosphorylation is essential to several steps in the MEN pathway, beginning with recruitment of Bfa1/Bub2 by phosphorylated Nud1,¹⁵ we were interested in mapping in vivo phosphorylation sites on the MEN proteins associated with centrosomes and identifying when they occur during the cell cycle.We combined centrosome enrichment with mass spectrometry analysis to examine phosphorylation from asynchronously growing cells.¹² Centrosomes were also prepared from cells arrested in G₁ and mitosis¹² to monitor potentially cell cycle-regulated sites. We obtained significant coverage of a number of the MEN proteins, several of which have human homologs (​and33, column 1), of which eight sites lie within Cdk/Cdc28 motifs [S/T(P)], (23 Mob1 and Dbf2 are known phosphoproteins²⁴ for which we observed peptide coverage but no phosphorylation. Surprisingly, we did not detect phosphorylation on Bub2 despite the high peptide coverage; it is possible that the mitotic centrosome preparations (using a Cdc20 depletion protocol) affect the phosphorylation state of Bub2, as Bub2 is required for mitotic exit arrest in cdc20 mutants.²⁵ Additionally, specific phosphorylation sites have not been mapped on Bub2, suggesting that modifications on this protein may be difficult to observe by mass spectrometry. Lte1 does not localize to the centrosome, and we did not recover Lte1 peptides in our preparations. Many phosphorylation events on MEN proteins were observed in mitotic centrosomal preparations, most likely in preparation for their subsequent role in exit from mitosis (MEN ProteinSequence CoverageTotal SitesS/T (P) SitesHuman HomologsBfa198%352N/ACdc1480%102CDC14A, 14B2Cdc1512%31MST1, STK4Cdc541%73PLK1, PLK2, PLK3Bub267%--N/ATem118%--RAB22, RAB22AMob113%--MOB1B, 1A, 2A, 2BDbf22%--STK38, LATS1TOTAL558Open in a separate window

Table 2

Cell cycle regulators of MEN proteins

Endocytosis: Past,Present, and Future

Endocytosis may have been a driving force behind the evolution of eukaryotic cells. It plays critical roles in cell biology (e.g., signal transduction) and in organismal physiology (e.g., tissue morphogenesis).Endocytosis, the process of cellular ingestion, may have been the driving force behind evolution of the eucaryotic cell (de Duve 2007). Acquiring the ability to internalize macromolecules and digest them intracellularly would have allowed primordial cells to move out from their food sources and pursue a predatory existence; one that might have led to the development of endosymbiotic relationships with mitochondria and plastids. Thus, it is fitting that endocytosis was first discovered and named as the processes of cell “eating” and “drinking.” In 1883, the developmental biologist Ilya Metchnikoff coined the term phagocytosis, from the Greek “phagos” (to eat) and “cyte” (cell), after observing motile cells in transparent starfish larva surround and engulf small splinters that he had inserted (Tauber 2003). Decades later, in 1931, Warren H. Lewis, one of the earliest cell “cinematographers” coined the term pinocytosis, from the Greek “pinean” (to drink), after observing the uptake of surrounding media into large vesicles in cultured macrophages, sarcoma cells, and fibroblasts by time-lapse imaging (Lewis 1931; Corner 1967).Importantly, these pioneering studies also revealed that the function of endocytosis goes well beyond eating and drinking. Indeed, Metchnikoff, considered one of the founders of modern immunology, realized that the phagocytic behavior of the mesodermal amoeboid cells he had observed under the microscope could serve as a general defense system against invasive parasites, in the larva as in man. This revolutionary concept, termed the phagocytic theory, earned Metchnikoff the 1908 Nobel Prize in Physiology or Medicine for his work on phagocytic immunity, which he shared with Paul Ehrlich who discovered the complementary mechanisms of humoral immunity that led to the identification of antibodies (Vaughan 1965; Tauber 2003; Schmalstieg and Goldman 2008). The phagocytic theory was a milestone in immunology and cell biology, and formally gave birth to the field of endocytosis.Key discoveries over the intervening years, aided in large part by the advent of electron microscopy, revealed multiple pathways for endocytosis in mammalian cells that fulfill multiple critical cellular functions (Fig. 1). These mechanistically and morphologically distinct pathways, and their discoverers, include clathrin-mediated endocytosis (Roth and Porter 1964), caveolae uptake (Palade 1953; Yamada 1955), cholesterol-sensitive clathrin- and caveolae-independent pathways (Moya et al. 1985; Hansen et al. 1991; Lamaze et al. 2001), and, more recently, the large capacity CLIC/GEEC pathway (Kirkham et al. 2005). In place of Metchnikoff’s splinters, many of these discoveries resulted from the detection and tracking of internalized HRP-, ferritin-, or gold-conjugated ligands by electron microscopy. These electron-dense tracers allowed researchers to identify cellular structures associated with the uptake and intracellular sorting of receptor-bound ligands. A particularly striking example is the pioneering work of Roth and Porter, who in 1964 observed the uptake of yolk proteins into mosquito oocytes. To synchronize uptake, they killed female mosquitos at timed intervals after a blood feed and observed the sequential appearance of electron-dense yolk granules in coated pits, coated and uncoated vesicles, and progressively larger vesicles. Their remarkable observations accurately described coated vesicle budding, uncoating, homo- and heterotypic fusion events, as well as the emergence of tubules from early endosomes (Fig. 2), all of which are now known hallmarks of the early endocytic trafficking events.Open in a separate windowFigure 1.Time line for discoveries of endocytic pathways and their discoverers. Boxes are color-coded by pathway. *, Nobel laureate. HRP, horseradish peroxidase; CCVs, clathrin-coated vesicles; CCPs, clathrin-coated pits; EGFR, epidermal growth factor receptor; PM, plasma membrane; ER, endoplasmic reticulum; CLIC/GEEC, clathrin-independent carriers/GPI-enriched endocytic compartments.Open in a separate windowFigure 2.Fiftieth anniversary of the discovery of clathrin-mediated endocytosis by Roth and Porter (1964). The image is the hand-drawn summary of observations made by electron microscopic examination of the trafficking of yolk proteins in a mosquito oocyte. Note the many details, later confirmed and mechanistically studied over the intervening 50 years. These include the growth, invagination, and pinching off of coated pits (1,2), which concentrate cargo taken up by coated vesicles (3), the rapid uncoating of nascent-coated vesicles (4), homotypic fusion of nascent endocytic vesicles in the cell periphery (5), the formation of tubules from early endosomes (7), and changes in the intraluminal properties of larger endosomes (6). Finally, yolk proteins are stored in granules as crystalline bodies (8). (From Roth and Porter 1964; reprinted, with express permission, from Rockefeller University Press © 1964, The Journal of Cell Biology 20: 313–332, doi: 10.1083/jcb.20.2.313.)Another milestone in the field of endocytosis was the discovery of the lysosome by Christian de Duve (Appelmans et al. 1955). Whereas the finding of phagocytosis and other endocytic pathways was possible through microscopy, the discovery of lysosomes originated from a biochemical approach (Courtoy 2007), which benefited from the invention of the ultracentrifuge. de Duve and coworkers observed that preparations of acid phosphatase obtained by subcellular fractionation had an unusual behavior: contrary to most enzymatic activities, the activity of acid phosphatase increased rather than decreased with time, freezing–thawing of the fractions and the presence of detergents. Interestingly, the same was true for other hydrolases, which depended on acidic pH for their optimal activity. This led him to postulate that the acid hydrolases were contained in acidified membrane-bound vesicles. In collaboration with Alex Novikoff, he visualized these vesicles, the lysosomes, by electron microscopy (Beaufay et al. 1956) and later showed their content of acid phosphatase (Farquhar et al. 1972). In 1974, de Duve was awarded the Nobel Prize for Physiology or Medicine for his seminal finding of the lysosomes and peroxisomes. He shared it with Albert Claude and George E. Palade “for their discoveries concerning the structural and functional organization of the cell.” The importance of this work lies also in the significant therapeutic applications that followed. The discovery by Elizabeth Neufeld and collaborators of uptake of lysosomal enzymes by cells provided the foundation for enzyme replacement therapy for lysosomal storage disorders (Neufeld 2011).In the 1970s, research in endocytosis entered the molecular era. Using de Duve and Albert Claude-like methods of subcellular fractionation, Barbara M. Pearse purified clathrin-coated vesicles from pig brain (Pearse 1975). A year later, she isolated a major protein species of 180 kDa, which she named clathrin “to indicate the lattice-like structures which it forms” (Pearse 1976). It was a breakthrough that inaugurated the molecular dissection of clathrin-mediated endocytosis.Over the intervening years, the continued application of microscopy (which now spans from electron cryotomography to live cell, high-resolution fluorescence microscopy), genetics (in particular, in yeast, Caenorhabditis elegans and Drosophila melanogaster), biochemistry (including cell-free reconstitution of endocytic membrane trafficking events), as well as molecular and structural biology have revealed a great deal about the cellular machineries and mechanisms that govern trafficking along the endocytic pathway. A partial, and because of space limitations, necessarily incomplete list of milestones (YearMechanistic milestonesDiscoverers1973Identification of shibirets (dynamin) mutant in DrosophilaD. Suzuki and C. Poodry1974–1976Zipper mechanism for phagocytosisS. Silverstein1975–1976Isolation of CCVs, purification of clathrinB. Pearse1982–1984Phosphomannose, M6PR, and lysosomal targetingW. Sly, S. Kornfeld, E. Neufeld, G. Sahagian1983–1984Isolation of clathrin adapters/localization to distinct membranesJ. Keen, B. Pearse, M. Robinson1986Isolation of endocytosis mutants (End) in yeastH. Riezman1986–1987Isolation of vacuolar protein sorting mutants in yeastS. Emr, T. Stevens1986Endosome fusion in vitroJ. Gruenberg and K. Howell1986EGF and insulin receptor signaling from endosomesJ. Bergeron and B. Posner1986Macropinocytosis induced in stimulated cellsD. Bar-Sagi and J. Feramisco1987Endocytic sorting motifs (FxNPxY, YxxF)M. Brown and J. Goldstein, I. Trowbridge, T. McGraw1987–1989Cloning of CHC, CLC, AP2T. Kirchhausen, M. Robinson1988Isolation of biochemically distinct early and late endosomesS. Schmid and I. Mellman1989–1991Clathrin-mediated endocytosis reconstituted in vitroE. Smythe, G. Warren, S. Schmid1990Localization of endosomal Rab5 and Rab7P. Chavrier, R. Parton, M. Zerial1991Endosome to trans-Golgi network (TGN) transport reconstituted in vitroS. Pfeffer1992Rab5 and Rab4 as early endocytic regulators in vivoM. Zerial, R. Parton, I. Mellman1992–1995Caveolin/VIP21 identified as caveolar coat proteinR. Anderson, T. Kurzchalia, R. Parton, K. Simons1992Vacuolar fusion reconstituted in vitroW. Wickner1992–1994Trigger mechanism for phagocytosis of bacteriaS. Falkow, J. Galán, J. Swanson1993Actin’s role in endocytosis in yeastH. Riezman1993Isolation of autophagy mutants (Atg) in yeastY. Ohsumi1993PI3 kinase activity (PI3P) and endosome functionS. Emr1993Dynamin’s role in clathrin-mediated endocytosisR. Vallee, S. Schmid1995Dynamin assembles into ringsS. Schmid, P. De Camilli1996Clathrin-mediated endocytosis requirement for signalingS. Schmid1996Long distance retrograde transport of signaling endosomes in neuronsW. Mobley1996PI5 phosphatase activity (PI(4,5)P₂) and clathrin-mediated endocytosisP. De Camilli1996Ubiquitin-dependent sorting in endocytosisR. Haguenauer-Tsapis; L. Hicke and H. Riezman1997AP3 and endosomal/lysosomal sortingJ. Bonifacino, S. Robinson1998FYVE fingers bind to PI3PH. Stenmark1998LBPA in MVB biogenesisT. Kobayashi, R. Parton, J. Gruenberg1997–1998Sorting nexinsG. Gill, S. Emr1998Structural basis for Y-based sorting signal recognitionD. Owen1998Retromer coat and endosome to TGN sortingS. Emr1998β-Propeller structure of clathrin heavy chain terminal domainT. Kirchhausen and S. Harrison1998Cargo-specific subpopulations of clathrin-coated pitsM. von Zastrow1999Structure of the clathrin coat protein superhelical motifsJ. Ybe and F. Brodsky1999Imaging green fluorescent protein–clathrin in living cellsJ. Keen1999Biochemical purification of Rab5 effectorsS. Christoforidis and M. Zerial1999Genetic screen for endocytosis mutants in C. elegansB. Grant2000Role of endocytosis in establishing morphogenic gradientsM. Gonzalez-Gaitan, S.M. Cohen2000Identification of GGA coats and lysosomal sortingJ. Bonifacino, S. Kornfeld, M. Robinson2000Identification of endosomal sorting complex required for transport (ESCRT) machinery for multivesicular body (MVB) formationS. Emr2001Ubiquitin-dependent sorting into MVBsR. Piper, S. Emr, H. Pelham2002Structure of the AP2 coreD. Owen2003Lipid conjugation of LC3/Atg8Y. Ohsumi2003–2004siRNA studies of endocytic componentsS. Robinson, E. Ungewickell, A. Sorkin2004BAR domains and membrane curvature generationH. McMahon, P. De Camilli20048-Å structure of a complete clathrin coatT. Kirchhausen and S. Harrison2005Modular design of yeast endocytosis machineryD. Drubin and M. Kaksonen2005Kinome-wide RNAi analysis of clathrin-mediated endocytosis (CME) and clathrin-independent endocytosis (CIE)M. Zerial and L. Pelkmans2006–2008Reconstitution of dynamin-mediated membrane fissionA. Roux, P. De Camilli, S. Schmid, J. Zimmerberg, V. Frolov2007Glycosphingolipid-induced endocytosisL. Johannes2009Reconstitution of Rab- and SNARE-dependent vacuolar and endosome fusion from purified componentsW. Wickner, M. Zerial2010Cavins as major caveolae coat componentsR. Parton; B. Nichols2010Reconstitution of ESCRT-dependent internal vesicle formationT. Wollert and J. Hurley2012Reconstitution of CCV formation from minimal componentsE. UngewickellOpen in a separate window