Project description:Caryopses of barley grains become firmly adhered to the glumes of the husk during grain development through a cuticular cementing layer on the caryopsis surface. The quality of this attachment varies among cultivars, with poor quality adhesion causing “skinning”, an economically significant grain quality defect for the malting industry. Malting cultivars encompassing a range of husk adhesion qualities were grown under a misting treatment known to induce skinning. Changes in gene expression during adhesion development were examined with a custom barley microarray. The abundance of transcripts involved early in cuticular lipid biosynthesis, including acetyl-CoA carboxylase, and all four members of the fatty acid elongase complex of enzymes was significantly higher early in caryopsis development than later. Members of the subsequent cuticular lipid biosynthetic pathways were also higher early in development including the decarbonylation and reductive pathways, and sterol biosynthesis.

Project description:The epidermis of plants forms a protective barrier against biotic and abiotic stress. Little is known about how breaches in the epidermis are repaired, especially those of mature leaves. Here, we investigated wound healing in the mature leaves of Arabidopsis. We discover a novel wound protection mechanism comprising a multi-layered ligno-suberized barrier covered with cuticular wax. This barrier is formed by mesophyll cells that adopt an epidermal fate. This cell fate transition is regulated in two steps by ATML1, a key transcription factor in epidermal specification. First, mesophyll cells of protective layer 1 (P1), just beneath the wound, transition into epidermal cells, sealing the wound by depositing cuticle, a mechanism that involves signaling through ethylene and reactive oxygen species produced by RBOHE. This signaling also promotes P1 cell death, ensuring wax accumulation on the surface. Second, the underlying protective layer 2 (P2) undergoes ligno-suberization, driven by jasmonic acid and RBOHD, forming a cork-like layer on the leaf surface. ATML1 regulates this process in P2 as well. Thus, wound healing in mature leaves involves integration of ethylene and jasmonic acid signaling with ATML1-mediated epidermal cell specification to coordinate cell layer-specific functions, including cuticular wax formation and ligno-suberization. This novel protective mechanism also occurs in the leaves of tobacco and Capsella, suggesting it is widespread.

Project description:Mollusk secretes a periostracum layer prior to the underlying calcified shell. This organic membrane serves as the first line of protection and primary template for shell orchestration. However, the chemical composition and formation mechanism of the periostracum layer is largely unknown. In this study, we applied transcriptomic, proteomics, physical and chemical analysis to unravel the mysteries of the periostracum formation in the green mussel Perna viridis (Linnaeus). Scanning electron microscopy examination and FTIR analysis showed that the periostracum layer was a multilayered organic membrane composed of polysaccharides, lipids and proteins. Interestingly, proteomic study identified components enriched in tyrosine and some enzymes evolved in tyrosine oxidation, indicating that tyrosine oxidation might play an important role in the periostracum formation. Moreover, comparative transcriptomics suggested that tyrosine-rich proteins were intensively synthesize in the periostracum groove. After being secreted, the periostracum proteins were gradually tanned by oxidation in the sea water, and the level of crosslink increased significantly as revealed by the ATR-FTIR. Our present study sheds light on the chemical composition and putative tanning mechanism of the periostracum layer in bivalve mollusk.

Project description:Ixodes scapularis and other hard ticks are long-term blood feeders. This feeding behavior is facilitated by a tick secreted bio adhesive (tick cement) that attaches tick mouthparts to skin tissue and prevents the host from dislodging the tick from its feeding site. Understanding tick cement formation is highly sought after as its disruption will prevent tick feeding. This study describes proteins that form the inner core layer of I. scapularis tick cement as disrupting these will stop formation of the outer cortical layer. As the inner core cement layer completes forming by 24 h of attachment, we used laser capture to isolate cement from cryosections of 6 h and 24 h tick attachment sites and to distinguish between early and late inner core cement proteins. LC-MS/MS analysis identified 138 tick cement proteins (TCPs) of which 37 and 35 were unique in cement of 6 and 24 h respectively, and 66 shared proteins. The 138 TCPs are classified in 14 functional categories: cuticular protein (16%), tick specific proteins of unknown function, cytoskeletal proteins, and enzymes (at 13% each), enzymes (10%), antioxidant, glycine rich, scaffolding, heat shock, histone, histamine binding, proteases and protease inhibitors, and miscellaneous (at 3-6% each). Gene ontology analysis confirm that TCPs are enriched for bio adhesive properties. Our data offer insights into yet unknown tick cement bonding patterns and set the foundation for understanding the molecular basis of I. scapularis tick cement formation.

Project description:The layered compartmentalization of functionally-related synaptic connections, a common feature of nervous systems, underlies proper connectivity between neurons and enables parallel processing of neural information. However, the stepwise development of layered neuronal connections is not well understood. The medulla neuropil of the Drosophila melanogaster visual system is comprised of 10 discrete layers (M1-M10), within which neural computations underlying distinct visual features are processed. As such, the Drosophila medulla neuropil serves as a model system for understanding layered compartmentalization of synaptic connectivity. The first step leading to the establishment of neurite layer specificity in the outer medulla (M1-M6) is the innervation of one of two broad, primordial domains that will subsequently expand and transform into the M1-M6 layers. We previously found that the transcription factor dFezf cell-autonomously directs L3 neurons to their proper early broad domain before they innervate and form synapses specifically within the M3 layer of the mature medulla. Here, we examined the transcriptomes of wild type and dFezf mutant L3 neurons by RNA-seq and identified downstream target genes that are regulated by dFezf. We show that dFezf controls L3 layer specificity through temporally precise transcriptional repression of the transcription factor slp1 (sloppy paired 1). During the period of broad domain selection, dFezf limits slp1 expression in L3 neurons. Slp1 is upregulated in dFezf-null L3 neurons, and ablation of slp1 fully rescues the targeting defect observed in dFezf-null L3 growth cones. Surprisingly, L3 innervation of the M3 layer after broad domain selection requires early slp1 expression. DFezf thus functions as a transcriptional repressor to coordinate the temporal dynamics of a transcriptional cascade that orchestrates sequential steps of layer-specific synapse formation. Moreover, we performed ATAC-seq in wild type L3 neurons and identified the accessible regions in the L3 genome, where dFezf may directly bind and regulate gene expression.

Project description:The layered compartmentalization of functionally-related synaptic connections, a common feature of nervous systems, underlies proper connectivity between neurons and enables parallel processing of neural information. However, the stepwise development of layered neuronal connections is not well understood. The medulla neuropil of the Drosophila melanogaster visual system is comprised of 10 discrete layers (M1-M10), within which neural computations underlying distinct visual features are processed. As such, the Drosophila medulla neuropil serves as a model system for understanding layered compartmentalization of synaptic connectivity. The first step leading to the establishment of neurite layer specificity in the outer medulla (M1-M6) is the innervation of one of two broad, primordial domains that will subsequently expand and transform into the M1-M6 layers. We previously found that the transcription factor dFezf cell-autonomously directs L3 neurons to their proper early broad domain before they innervate and form synapses specifically within the M3 layer of the mature medulla. Here, we examined the transcriptomes of wild type and dFezf mutant L3 neurons by RNA-seq and identified downstream target genes that are regulated by dFezf. We show that dFezf controls L3 layer specificity through temporally precise transcriptional repression of the transcription factor slp1 (sloppy paired 1). During the period of broad domain selection, dFezf limits slp1 expression in L3 neurons. Slp1 is upregulated in dFezf-null L3 neurons, and ablation of slp1 fully rescues the targeting defect observed in dFezf-null L3 growth cones. Surprisingly, L3 innervation of the M3 layer after broad domain selection requires early slp1 expression. DFezf thus functions as a transcriptional repressor to coordinate the temporal dynamics of a transcriptional cascade that orchestrates sequential steps of layer-specific synapse formation. Moreover, we performed ATAC-seq in wild type L3 neurons and identified the accessible regions in the L3 genome, where dFezf may directly bind and regulate gene expression.

Project description:Tropomyosin 3 variant causing adult onset distal myopathy

Project description:Exosomes are secreted into the intercellular space and carry a diverse cargo of proteins, mRNA and miRNA that have important roles in cell-to-cell communication. We found that exosomes from primary human leukaemic B-cells contain a population of miRNAs that has been selected from the general cellular pool to be enriched in miR-323-3p, miR-374b, miR-363 and miR-494. Gene targets of these miRNA are found within the TGFM-NM-2 pathway, but we noted that CD69, a protein that is essential for the regulation of normal lymphocyte egress from lymph nodes was the top predicted target of miR-363. Utilising luciferase reporter assays we demonstrate that CD69 is a target of miR-363. The interaction between miR-363 and CD69 is functionally important as demonstrated by repression of CD69 expression by a miR-363 mimic in the Jurkat T-cell line. MicroRNA expression profiles of isolated exosomes and CLL cells cultured on CD154/IL-4 feeder layers for 24 hours were determined using Taqman low-density miRNA (TLDA) arrays. Patient samples were layered on Ficoll and centrifuged for 20 minutes at 2500 rpm following which the interface layer conatining mononuclear cells was removed. The cells were washed in PBS and cultured on a feeder layer of mouse fibroblasts transfected with human CD154 in the presence of IL-4 (10 ng/ml) for 24 hours MiRNA extracts were made using a miRvana miRNA isolation kit (Applied Biosystems, Paisley, UK), and reverse transcribed using MegaPlex RT Primers and a TaqMan MicroRNA Reverse Transcription Kit (Applied Biosystems). Equal amounts of RNA were added to each microarray plate. Human microRNA Array (A) plates (containing assays for 377 miRNA) were used (Applied Biosystems, #4398965) and reactions carried out on a 7900HT Real Time PCR system. MiRNA expression was compared in paired samples of chronic lymphocytic leukaemia cells and exosomes utilising Taqman Real-Time PCR.

Project description:Choroid plexus secretes cerebrospinal fluid important for brain development and homeostasis. The OTX2 homeoprotein is critical for choroid plexus development and remains highly expressed in adult choroid plexus. Through RNA sequencing analyses of constitutive and conditional knockdown adult mouse models, we reveal putative roles for OTX2 in choroid plexus function, including cell signaling and adhesion, and show that it regulates the expression of factors secreted into cerebrospinal fluid, notably transthyretin. We also show that Otx2 expression impacts choroid plexus immune and stress responses, and also affects splicing which leads to changes in mRNA isoforms of proteins implicated in oxidative stress response and DNA repair. Through mass spectrometry analysis of OTX2 protein partners in the choroid plexus, and in known non-cell autonomous target regions such as visual cortex and subventricular zone, we identified putative targets involved in cell adhesion, chromatin structure and RNA processing. Thus, OTX2 retains important roles in choroid plexus function and brain homeostasis throughout life.

Project description:Secreted bacterial RNAs have recently emerged as a novel host-pathogen interaction mode. Naked RNA molecules are highly labile in the extracellular environment and must be protected by packaging into membrane vesicles or into complexes with RNA binding proteins. RNA secretion through membrane vesicles has been shown for several bacterial species but, surprisingly, proteins that bind and stabilize bacterial RNAs in the extracellular environment have not been reported yet. Here, we show that the bacterial pathogen L. monocytogenes secretes a small RNA binding protein that we named Zea. We show that Zea binds and stabilizes a subset of L. monocytogenes RNA, causing its accumulation in the extracellular medium. Zea modulates L. monocytogenes in vivo. Furthemore, Zea binds the mammalian non-self-RNA innate immunity sensor RIG-I and potentiates RIG-I-signaling during infection. This study provides a mechanism for the stability of extracellular RNA and unveils how secreted bacterial RNAs participate in the host-pathogen crosstalk.