Aversive state processing in the posterior insular cortex.

Triggering behavioral adaptation upon the detection of adversity is crucial for survival. The insular cortex has been suggested to process emotions and homeostatic signals, but how the insular cortex detects internal states and mediates behavioral adaptation is poorly understood. By combining data from fiber photometry, optogenetics, awake two-photon calcium imaging and comprehensive whole-brain viral tracings, we here uncover a role for the posterior insula in processing aversive sensory stimuli and emotional and bodily states, as well as in exerting prominent top-down modulation of ongoing behaviors in mice. By employing projection-specific optogenetics, we describe an insula-to-central amygdala pathway to mediate anxiety-related behaviors, while an independent nucleus accumbens-projecting pathway regulates feeding upon changes in bodily state. Together, our data support a model in which the posterior insular cortex can shift behavioral strategies upon the detection of aversive internal states, providing a new entry point to understand how alterations in insula circuitry may contribute to neuropsychiatric conditions.

Development of an activation tagging system for maize.

Activation Tagging, distributing transcriptional enhancers throughout the genome to induce transcription of nearby genes, is a powerful tool for discovering the function of genes in plants. We have developed a transposable element system to distribute a novel activation tagging element throughout the genome of maize. The transposon system is built from the Enhancer/Suppressor (En/Spm) transposon system and uses an engineered seed color marker to show when the transposon excises. Both somatic and germinal excision events can be detected by the seed color. The activation tagging element is in a Spm-derived non-autonomous transposon and contains four copies of the Sugarcane Bacilliform Virus-enhancer (SCBV-enhancer) and the AAD1 selectable marker. We have demonstrated that the transposon can give rise to germinal excision events that can re-integrate into non-linked genomic locations. The transposon has remained active for three generations and events displaying high rates of germinal excision in the T2 generation have been identified. This system can generate large numbers of activation tagged maize lines that can be screened for agriculturally relevant phenotypes.

Identification and use of the sugarcane bacilliform virus enhancer in transgenic maize.

BACKGROUND: Transcriptional enhancers are able to increase transcription from heterologous promoters when placed upstream, downstream and in either orientation, relative to the promoter. Transcriptional enhancers have been used to enhance expression of specific promoters in transgenic plants and in activation tagging studies to help elucidate gene function. RESULTS: A transcriptional enhancer from the Sugarcane Bacilliform Virus - Ireng Maleng isolate (SCBV-IM) that can cause increased transcription when integrated into the the genome near maize genes has been identified. In transgenic maize, the SCBV-IM promoter was shown to be comparable in strength to the maize ubiquitin 1 promoter in young leaf and root tissues. The promoter was dissected to identify sequences that confer high activity in transient assays. Enhancer sequences were identified and shown to increase the activity of a heterologous truncated promoter. These enhancer sequences were shown to be more active when arrayed in 4 copy arrays than in 1 or 2 copy arrays. When the enhancer array was transformed into maize plants it caused an increase in accumulation of transcripts of genes near the site of integration in the genome. CONCLUSIONS: The SCBV-IM enhancer can activate transcription upstream or downstream of genes and in either orientation. It may be a useful tool to activate enhance from specific promoters or in activation tagging.

Structural dynamics of the microtubule binding and regulatory elements in the kinesin-like calmodulin binding protein.

Kinesins are molecular motors that power cell division and transport of various proteins and organelles. Their motor activity is driven by ATP hydrolysis and depends on interactions with microtubule tracks. Essential steps in kinesin movement rely on controlled alternate binding to and detaching from the microtubules. The conformational changes in the kinesin motors induced by nucleotide and microtubule binding are coordinated by structural elements within their motor domains. Loop L11 of the kinesin motor domain interacts with the microtubule and is implicated in both microtubule binding and sensing nucleotide bound to the active site of kinesin. Consistent with its proposed role as a microtubule sensor, loop L11 is rarely seen in crystal structures of unattached kinesins. Here, we report four structures of a regulated plant kinesin, the kinesin-like calmodulin binding protein (KCBP), determined by X-ray crystallography. Although all structures reveal the kinesin motor in the ATP-like conformation, its loop L11 is observed in different conformational states, both ordered and disordered. When structured, loop L11 adds three additional helical turns to the N-terminal part of the following helix alpha4. Although interactions with protein neighbors in the crystal support the ordering of loop L11, its observed conformation suggests the conformation for loop L11 in the microtubule-bound kinesin. Variations in the positions of other features of these kinesins were observed. A critical regulatory element of this kinesin, the calmodulin binding helix positioned at the C-terminus of the motor domain, is thought to confer negative regulation of KCBP. Calmodulin binds to this helix and inserts itself between the motor and the microtubule. Comparison of five independent structures of KCBP shows that the positioning of the calmodulin binding helix is not decided by crystal packing forces but is determined by the conformational state of the motor. The observed variations in the position of the calmodulin binding helix fit the regulatory mechanism previously proposed for this kinesin motor.

Novel transgenic rice overexpressing anthocyanidin synthase accumulates a mixture of flavonoids leading to an increased antioxidant potential.

In addition to their plant-associated functions, flavonoids act as antioxidants against harmful free radicals in animals. Genetic engineering of food crops for a mix of antioxidant flavonoids is highly beneficial in promoting human health. Anthocyanidin synthase (ANS) is one of the four dioxygenases (DOX) of the flavonoid biosynthetic pathway that catalyzes the formation of anthocyanidins from leucoanthocyanidins. To investigate whether ANS mediates different DOX reactions of the pathway and produces a mix of flavonoids, the rice ANS cDNA was cloned and overexpressed in a rice mutant Nootripathu (NP). This mutant accumulates proanthocyanidins exclusively in pericarp and absolutely no anthocyanins in any tissue. In silico sequence analysis revealed that ANS contains a double-stranded beta helix and shows high sequence similarity with other DOXs of the pathway including flavonol synthase, flavonone 3beta-hydroxylase and flavone synthase I. Bacterially expressed ANS protein converted dihydroquercetin to quercetin and Pro(35S):ANS complemented the maize a2 mutant in producing anthocyanins in aleurone, suggesting that ANS functions as a DOX with different flavonoid substrates. Similarly, transgenic NP plants overexpressing Pro(MAS):ANS channeled the proanthocaynidin precursors to the production of anthocyanins in pericarp. Transgenics showed approximately ten and four-fold increase in the ANS transcripts and enzyme activity, respectively. As a result, these plants showed an increased accumulation of a mixture of flavonoids and anthocyanins, with a concomitant decrease in proanthocyanidins, suggesting that ANS may act directly on different flavonoid substrates of DOX reactions. Thus, overexpression of ANS in a rice mutant resulted in novel transgenic rice with a mixture of flavonoids and an enhanced antioxidant potential.

Proteomics of calcium-signaling components in plants.

Calcium functions as a versatile messenger in mediating responses to hormones, biotic/abiotic stress signals and a variety of developmental cues in plants. The Ca(2+)-signaling circuit consists of three major "nodes"--generation of a Ca(2+)-signature in response to a signal, recognition of the signature by Ca2+ sensors and transduction of the signature message to targets that participate in producing signal-specific responses. Molecular genetic and protein-protein interaction approaches together with bioinformatic analysis of the Arabidopsis genome have resulted in identification of a large number of proteins at each "node"--approximately 80 at Ca2+ signature, approximately 400 sensors and approximately 200 targets--that form a myriad of Ca2+ signaling networks in a "mix and match" fashion. In parallel, biochemical, cell biological, genetic and transgenic approaches have unraveled functions and regulatory mechanisms of a few of these components. The emerging paradigm from these studies is that plants have many unique Ca2+ signaling proteins. The presence of a large number of proteins, including several families, at each "node" and potential interaction of several targets by a sensor or vice versa are likely to generate highly complex networks that regulate Ca(2+)-mediated processes. Therefore, there is a great demand for high-throughput technologies for identification of signaling networks in the "Ca(2+)-signaling-grid" and their roles in cellular processes. Here we discuss the current status of Ca2+ signaling components, their known functions and potential of emerging high-throughput genomic and proteomic technologies in unraveling complex Ca2+ circuitry.

Developmental and cell-specific expression of ZWICHEL is regulated by the intron and exon sequences of its gene.

Functional studies with ZWICHEL ( ZWI ), which encodes a Ca(2+)-calmodulin-regulated kinesin, have shown its involvement in trichome morphogenesis and cell division. To identify regulatory regions that control the ZWI expression pattern, we generated transgenic Arabidopsis plants with a GUS reporter driven by different lengths of the ZWI gene 5' region alone or 5' and 3' regions together. The 5' fusions contain varying lengths of the coding and non-coding regions of beta - HYDROXYISOBUTYRYL-CoA HYDROLASE 1 ( CHY1 ), which is upstream of ZWI, and a 162 bp intergenic region. In transgenic plants with 5' 460::GUS, GUS activity was observed primarily in the root hairs whereas transgenic plants with an additional 5' 266 bp region from the CHY1 gene (5' 726::GUS) showed strong GUS accumulation in the entire root including root hairs and root tip, calli and at various developmental stages in trichomes and pollen. However, very little GUS accumulation was detected in roots of dark-grown or root tips of cold-treated seedlings with 5' ZWI constructs. These results were further confirmed by quantifying GUS enzyme activity and transcripts in these seedlings. Calli and pollen transformed with the 5' distal 268 bp fused in antisense orientation to the proximal 460 bp did not show GUS expression. Further, IAA-treated dark-grown seedlings with 726::GUS, but not with 460::GUS, showed high GUS expression in specific regions (outer layer 2a cells) at the base of the lateral roots. The ZWI 3' region (3 kb) did not influence the GUS expression pattern driven by the 5' 726 bp. The absence of CHY1 transcripts in the chy1-2 mutant did not alter either ZWI expression or ZWI-mediated trichome morphogenesis. Thus, our data suggest that the 3' part of the CHY1 gene contains regulatory elements that control ZWI gene expression in dividing cells and other cells that exhibit polarized growth such as root hairs, pollen and trichomes. This is the first evidence that the regulatory regions conferring developmental and cell-specific expression of a gene reside in the introns and exons of its upstream protein-coding gene.

Crystal structure of kinesin regulated by Ca(2+)-calmodulin.

Kinesins orchestrate cell division by controlling placement of chromosomes. Kinesins must be precisely regulated or else cell division fails. Calcium, a universal second messenger in eukaryotes, and calmodulin regulate some kinesins by causing the motor to dissociate from its biological track, the microtubule. Our focus was the mechanism of calcium regulation of kinesin at atomic resolution. Here we report the crystal structure of kinesin-like calmodulin-binding protein (KCBP) from potato, which was resolved to 2.3 A. The structure reveals three subdomains of the regulatory machinery located at the C terminus extension of the kinesin motor. Calmodulin that is activated by Ca2+ ions binds to an alpha-helix positioned on the microtubule-binding face of kinesin. A negatively charged segment following this helix competes with microtubules. A mimic of the conventional kinesin neck, connecting the calmodulin-binding helix to the KCBP motor core, links the regulatory machine to the kinesin catalytic cycle. Together with biochemical data, the crystal structure suggests that Ca(2+)-calmodulin inhibits the binding of KCBP to microtubules by blocking the microtubule-binding sites on KCBP.

KIC, a novel Ca2+ binding protein with one EF-hand motif, interacts with a microtubule motor protein and regulates trichome morphogenesis.

Kinesin-like calmodulin binding protein (KCBP) is a microtubule motor protein involved in the regulation of cell division and trichome morphogenesis. Genetic studies have shown that KCBP is likely to interact with several other proteins. To identify KCBP-interacting proteins, we used the C-terminal region of KCBP in a yeast two-hybrid screen. This screening resulted in the isolation of a novel KCBP-interacting Ca2+ binding protein (KIC). KIC, with its single EF-hand motif, bound Ca2+ at a physiological concentration. Coprecipitation with bacterially expressed protein and native KCBP, gel-mobility shift studies, and ATPase assays with the KCBP motor confirmed that KIC interacts with KCBP in a Ca2+-dependent manner. Interestingly, although both Ca2+-KIC and Ca2+-calmodulin were able to interact with KCBP and inhibit its microtubule binding activity, the concentration of Ca2+ required to inhibit the microtubule-stimulated ATPase activity of KCBP by KIC was threefold less than that required for calmodulin. Two KIC-related Ca2+ binding proteins and a centrin from Arabidopsis, which contain one and four EF-hand motifs, respectively, bound Ca2+ but did not affect microtubule binding and microtubule-stimulated ATPase activities of KCBP, indicating the specificity of Ca2+ sensors in regulating their targets. Overexpression of KIC in Arabidopsis resulted in trichomes with reduced branch number resembling the zwichel/kcbp phenotype. These results suggest that KIC modulates the activity of KCBP in response to changes in cytosolic Ca2+ and regulates trichome morphogenesis.

Differential expression of genes encoding calmodulin-binding proteins in response to bacterial pathogens and inducers of defense responses.

Calmodulin (CaM) plays an important role in sensing and transducing changes in cellular Ca2+ concentration in response to several biotic and abiotic stresses. Although CaM is implicated in plant-pathogen interactions, its molecular targets and their role in defense signaling pathway(s) are poorly understood. To elucidate the signaling pathways that link CaM to defense responses, we screened a cDNA library constructed from bean leaves undergoing a hypersensitive response (HR) with radiolabeled CaM isoforms. A total of 26 putative CBPs were identified. Sequencing of the cDNAs revealed that they represent 8 different genes. They are homologues of previously identified CaM-binding proteins (CBPs) in other systems. However, some CBPs are novel members of known CBP families. The proteins encoded by these clones bound CaM in a Ca2+-dependent manner. To determine if these CBPs are involved in plant defense responses, we analyzed their expression in bean leaves inoculated with compatible, incompatible and nonpathogenic bacterial strains. Expression of three CBPs including an isoform of cyclic nucleotide-gated channels (PvCNGC-A) and two hypothetical proteins (PvCBP60-C and PvCBP60-D) was induced whereas the expression of two other isoforms of CNGCs (PvCNGC-B and PvCNGC-C) was repressed in response to incompatible pathogens. The expression of the rest, a small auxin up RNA (PvSAUR1) and two hypothetical proteins (PvCBP60-A and PvCBP60-B), was not changed. The expression of most of the pathogen-regulated genes was also affected by salicylic acid, jasmonic acid, hydrogen peroxide and a fungal elicitor, which are known to induce defense responses. Our results strongly suggest that at least five bean CBPs are involved in plant defense responses.

Characterization of a pathogen-induced calmodulin-binding protein: mapping of four Ca2+-dependent calmodulin-binding domains.

Ca2+ and calmodulin (CaM), a key Ca2+ sensor in all eukaryotes, have been implicated in defense responses in plants. To elucidate the role of Ca2+ and CaM in defense signaling, we used 35S-labeled CaM to screen expression libraries prepared from tissues that were either treated with an elicitor derived from Phytophthora megasperma or infected with Pseudomonas syringae pv. tabaci. Nineteen cDNAs that encode the same protein, pathogen-induced CaM-binding protein (PICBP), were isolated. The PICBP fusion proteins bound 35S-CaM, horseradish peroxidase-labeled CaM and CaM-Sepharose in the presence of Ca2+ whereas EGTA, a Ca2+ chelator, abolished binding, confirming that PICBP binds CaM in a Ca2+-dependent manner. Using a series of bacterially expressed truncated versions of PICBP, four CaM-binding domains, with a potential CaM-binding consensus sequence of WSNLKKVILLKRFVKSL, were identified. The deduced PICBP protein sequence is rich in leucine residues and contains three classes of repeats. The PICBP gene is differentially expressed in tissues with the highest expression in stem. The expression of PICBP in Arabidopsis was induced in response to avirulent Pseudomonas syringae pv. tomato carrying avrRpm1. Furthermore, PICBP is constitutively expressed in the Arabidopsis accelerated cell death2-2 mutant. The expression of PICBP in bean leaves was also induced after inoculation with avirulent and non-pathogenic bacterial strains. In addition, the hrp1 mutant of Pseudomonas syringae pv. tabaci and inducers of plant defense such as salicylic acid, hydrogen peroxide and a fungal elicitor induced PICBP expression in bean. Our data suggest a role for PICBP in Ca2+-mediated defense signaling and cell-death. Furthermore, PICBP is the first identified CBP in eukaryotes with four Ca2+-dependent CaM-binding domains.

Analysis of EF-hand-containing proteins in Arabidopsis.

BACKGROUND: In plants, calcium (Ca2+) has emerged as an important messenger mediating the action of many hormonal and environmental signals, including biotic and abiotic stresses. Many different signals raise cytosolic calcium concentration ([Ca2+]cyt), which in turn is thought to regulate cellular and developmental processes via Ca2+-binding proteins. Three out of the four classes of Ca2+-binding proteins in plants contain Ca2+-binding EF-hand motif(s). This motif is a conserved helix-loop-helix structure that can bind a single Ca2+ ion. To identify all EF-hand-containing proteins in Arabidopsis, we analyzed its completed genome sequence for genes encoding EF-hand-containing proteins. RESULTS: A maximum of 250 proteins possibly having EF-hands were identified. Diverse proteins, including enzymes, proteins involved in transcription and translation, protein- and nucleic-acid-binding proteins and a large number of unknown proteins, have one or more putative EF-hands. Phylogenetic analysis identified six major groups that contain some families of proteins. CONCLUSIONS: The presence of EF-hand motif(s) in a diversity of proteins is consistent with the involvement of Ca2+ in regulating many cellular and developmental processes. Thus far, only 47 of the possible 250 EF-hand proteins have been reported in the literature. Various domains that we identified in many of the uncharacterized EF-hand-containing proteins should help in elucidating their cellular role(s). Our analyses suggest that the Ca2+ messenger system is widely used in plants and that EF-hand-containing proteins are likely to be the key transducers mediating Ca2+ action.

The calmodulin-binding domain from a plant kinesin functions as a modular domain in conferring Ca2+-calmodulin regulation to animal plus- and minus-end kinesins.

Plant kinesin-like calmodulin-binding protein (KCBP) is a novel member of the kinesin superfamily that interacts with calmodulin (CaM) via its CaM-binding domain (CBD). Activated CaM (Ca(2+)-CaM) has been shown to inhibit KCBP interaction with microtubules (MTs) thereby abolishing its motor- and MT-dependent ATPase activities. To test whether the fusion of CBD to non-CaM-binding kinesins confers Ca(2+)-CaM regulation, we fused the CBD of KCBP to the N or C terminus of a minus-end (non-claret disjunction) or C terminus of a plus-end (Drosophila kinesin) motor. Purified chimeric kinesins bound CaM in a Ca(2+)-dependent manner whereas non-claret disjunction, Drosophila kinesin, and KCBP that lack a CBD did not. As in the case of KCBP with CBD, the interaction of chimeric motors with MTs, as well as their MT-stimulated ATPase activity, was inhibited by Ca(2+)-CaM. The presence of a spacer between the motor and CBD did not alter Ca(2+)-CaM regulation. However, KCBP interaction with MTs and its MT-stimulated ATPase activity were not inhibited when the motor domain and CBD were added separately, suggesting that Ca(2+)-CaM regulation of CaM-binding motors occurs only when the CBD is attached to the motor domain. These results show that the fusion of the CBD to animal motors confers Ca(2+)-CaM regulation and suggest that the CBD functions as a modular domain in disrupting motor-MT interaction. Our data also support the hypothesis that CaM-binding kinesins may have evolved by addition of a CBD to a kinesin motor domain.

Genes encoding calmodulin-binding proteins in the Arabidopsis genome.

Analysis of the recently completed Arabidopsis genome sequence indicates that approximately 31% of the predicted genes could not be assigned to functional categories, as they do not show any sequence similarity with proteins of known function from other organisms. Calmodulin (CaM), a ubiquitous and multifunctional Ca(2+) sensor, interacts with a wide variety of cellular proteins and modulates their activity/function in regulating diverse cellular processes. However, the primary amino acid sequence of the CaM-binding domain in different CaM-binding proteins (CBPs) is not conserved. One way to identify most of the CBPs in the Arabidopsis genome is by protein-protein interaction-based screening of expression libraries with CaM. Here, using a mixture of radiolabeled CaM isoforms from Arabidopsis, we screened several expression libraries prepared from flower meristem, seedlings, or tissues treated with hormones, an elicitor, or a pathogen. Sequence analysis of 77 positive clones that interact with CaM in a Ca(2+)-dependent manner revealed 20 CBPs, including 14 previously unknown CBPs. In addition, by searching the Arabidopsis genome sequence with the newly identified and known plant or animal CBPs, we identified a total of 27 CBPs. Among these, 16 CBPs are represented by families with 2-20 members in each family. Gene expression analysis revealed that CBPs and CBP paralogs are expressed differentially. Our data suggest that Arabidopsis has a large number of CBPs including several plant-specific ones. Although CaM is highly conserved between plants and animals, only a few CBPs are common to both plants and animals. Analysis of Arabidopsis CBPs revealed the presence of a variety of interesting domains. Our analyses identified several hypothetical proteins in the Arabidopsis genome as CaM targets, suggesting their involvement in Ca(2+)-mediated signaling networks.

Isolation and characterization of a novel calmodulin-binding protein from potato.

Tuberization in potato is controlled by hormonal and environmental signals. Ca(2+), an important intracellular messenger, and calmodulin (CaM), one of the primary Ca(2+) sensors, have been implicated in controlling diverse cellular processes in plants including tuberization. The regulation of cellular processes by CaM involves its interaction with other proteins. To understand the role of Ca(2+)/CaM in tuberization, we have screened an expression library prepared from developing tubers with biotinylated CaM. This screening resulted in isolation of a cDNA encoding a novel CaM-binding protein (potato calmodulin-binding protein (PCBP)). Ca(2+)-dependent binding of the cDNA-encoded protein to CaM is confirmed by (35)S-labeled CaM. The full-length cDNA is 5 kb long and encodes a protein of 1309 amino acids. The deduced amino acid sequence showed significant similarity with a hypothetical protein from another plant, Arabidopsis. However, no homologs of PCBP are found in nonplant systems, suggesting that it is likely to be specific to plants. Using truncated versions of the protein and a synthetic peptide in CaM binding assays we mapped the CaM-binding region to a 20-amino acid stretch (residues 1216-1237). The bacterially expressed protein containing the CaM-binding domain interacted with three CaM isoforms (CaM2, CaM4, and CaM6). PCBP is encoded by a single gene and is expressed differentially in the tissues tested. The expression of CaM, PCBP, and another CaM-binding protein is similar in different tissues and organs. The predicted protein contained seven putative nuclear localization signals and several strong PEST motifs. Fusion of the N-terminal region of the protein containing six of the seven nuclear localization signals to the reporter gene beta-glucuronidase targeted the reporter gene to the nucleus, suggesting a nuclear role for PCBP.