Human T cell leukemia virus envelope binding and virus entry are mediated by distinct domains of the glucose transporter GLUT1

The glucose transporter GLUT1, a member of the multimembrane-spanning facilitative nutrient transporter family, serves as a receptor for human T cell leukemia virus (HTLV) infection. Here, we show that the 7 amino acids of the extracellular loop 6 of GLUT1 (ECL6) placed in the context of the related GLUT3 transporter were sufficient for HTLV envelope binding. Glutamate residue 426 in ECL6 was identified as critical for binding. However, binding to ECL6 was not sufficient for HTLV envelope-driven infection. Infection required two additional determinants located in ECL1 and ECL5, which otherwise did not influence HTLV envelope binding. Moreover the single N-glycosylation chain located in ECL1 was not required for HTLV infection. Therefore, binding involves a discrete determinant in the carboxyl terminal ECL6, whereas post-binding events engage extracellular sequences in the amino and carboxyl terminus of GLUT1.     

Rodent models for mania: practical approaches

The scarcity of good animal models for bipolar disorder (BPD) and especially for mania is repeatedly mentioned as one of the rate-limiting factors in the process of gaining a better understanding into its pathophysiology and of developing better treatments. Standard models of BPD have some value but usually represent only one facet of the disease and have partial validity. A number of new approaches for modeling BPD and specifically mania have been suggested in the last few years and can be combined to improve models. These approaches include targeted mutation models representing reverse translation, the identification of advantageous strains for components of the disorder, a search for the most homologous species to address specific human pathology, and the exploration of individual differences of response including the separation between susceptible and resilient animals. Additionally, recent efforts have identified and developed new tests to distinguish between “normal” and “BPD-like” animals including the different utilization of known tests and novel tests such as the female-urine-sniffing test and behavior pattern monitor analysis. Additional tests relating to further domains of BPD are still needed. An ideal model for BPD that will encompass the entire disease and be useful for every demand will probably not become available until we have a full understanding of the pathophysiology of the disorder. However, the current advances in modeling should lead to better comprehension of the disorder and therefore to the gradual development of increasingly improved models.     

Enhanced formation of aromatic amino acids increases fragrance without affecting flower longevity or pigmentation in Petunia × hybrida

Purple Petunia × hybrida V26 plants accumulate fragrant benzenoid‐phenylpropanoid molecules and anthocyanin pigments in their petals. These specialized metabolites are synthesized mainly from the aromatic amino acids phenylalanine. Here, we studied the profile of secondary metabolites of petunia plants, expressing a feedback‐insensitive bacterial form of 3‐deoxy‐di‐arabino‐heptulosonate 7‐phosphate synthase enzyme (AroG*) of the shikimate pathway, as a tool to stimulate the conversion of primary to secondary metabolism via the aromatic amino acids. We focused on specialized metabolites contributing to flower showy traits. The presence of AroG* protein led to increased aromatic amino acid levels in the leaves and high phenylalanine levels in the petals. In addition, the AroG* petals accumulated significantly higher levels of fragrant benzenoid‐phenylpropanoid volatiles, without affecting the flowers' lifetime. In contrast, AroG* abundance had no effect on flavonoids and anthocyanins levels. The metabolic profile of all five AroG* lines was comparable, even though two lines produced the transgene in the leaves, but not in the petals. This implies that phenylalanine produced in leaves can be transported through the stem to the flowers and serve as a precursor for formation of fragrant metabolites. Dipping cut petunia stems in labelled phenylalanine solution resulted in production of labelled fragrant volatiles in the flowers. This study emphasizes further the potential of this metabolic engineering approach to stimulate the production of specialized metabolites and enhance the quality of various plant organs. Furthermore, transformation of vegetative tissues with AroG* is sufficient for induced production of specialized metabolites in organs such as the flowers.     

Genetic and chemical characterization of an EMS induced mutation in Cucumis melo CRTISO gene

In order to broaden the available genetic variation of melon, we developed an ethyl methanesulfonate mutation library in an orange-flesh ‘Charentais’ type melon line that accumulates β-carotene. One mutagenized M₂ family segregated for a novel recessive trait, a yellow–orange fruit flesh (‘yofI’). HPLC analysis revealed that ‘yofI’ accumulates pro-lycopene (tetra-cis-lycopene) as its major fruit pigment. The altered carotenoid composition of ‘yofI’ is associated with a significant change of the fruit aroma since cleavage of β-carotene yields different apocarotenoids than the cleavage of pro-lycopene. Normally, pro-lycopene is further isomerized by CRTISO (carotenoid isomerase) to yield all-trans-lycopene, which is further cyclized to β-carotene in melon fruit. Cloning and sequencing of ‘yofI’ CRTISO identified two mRNA sequences which lead to truncated forms of CRTISO. Sequencing of the genomic CRTISO identified an A–T transversion in ‘yofI’ which leads to a premature STOP codon. The early carotenoid pathway genes were up regulated in yofI fruit causing accumulation of other intermediates such as phytoene and ζ-carotene. Total carotenoid levels are only slightly increased in the mutant. Mutants accumulating pro-lycopene have been reported in both tomato and watermelon fruits, however, this is the first report of a non-lycopene accumulating fruit showing this phenomenon.     

The Arabidopsis Rho of Plants GTPase AtROP6 Functions in Developmental and Pathogen Response Pathways

How plants coordinate developmental processes and environmental stress responses is a pressing question. Here, we show that Arabidopsis (Arabidopsis thaliana) Rho of Plants6 (AtROP6) integrates developmental and pathogen response signaling. AtROP6 expression is induced by auxin and detected in the root meristem, lateral root initials, and leaf hydathodes. Plants expressing a dominant negative AtROP6 (rop6^DN) under the regulation of its endogenous promoter are small and have multiple inflorescence stems, twisted leaves, deformed leaf epidermis pavement cells, and differentially organized cytoskeleton. Microarray analyses of rop6^DN plants revealed that major changes in gene expression are associated with constitutive salicylic acid (SA)-mediated defense responses. In agreement, their free and total SA levels resembled those of wild-type plants inoculated with a virulent powdery mildew pathogen. The constitutive SA-associated response in rop6^DN was suppressed in mutant backgrounds defective in SA signaling (nonexpresser of PR genes1 [npr1]) or biosynthesis (salicylic acid induction deficient2 [sid2]). However, the rop6^DN npr1 and rop6^DN sid2 double mutants retained the aberrant developmental phenotypes, indicating that the constitutive SA response can be uncoupled from ROP function(s) in development. rop6^DN plants exhibited enhanced preinvasive defense responses to a host-adapted virulent powdery mildew fungus but were impaired in preinvasive defenses upon inoculation with a nonadapted powdery mildew. The host-adapted powdery mildew had a reduced reproductive fitness on rop6^DN plants, which was retained in mutant backgrounds defective in SA biosynthesis or signaling. Our findings indicate that both the morphological aberrations and altered sensitivity to powdery mildews of rop6^DN plants result from perturbations that are independent from the SA-associated response. These perturbations uncouple SA-dependent defense signaling from disease resistance execution.Rho of Plants (ROPs), also known as RACs (for clarity, the ROP nomenclature will be used throughout this article), comprise a plant-specific group of Rho family small G proteins. Like other members of the Ras superfamily of small G proteins, ROPs function as molecular switches, existing in a GTP-bound “on” state and a GDP-bound “off” state. In the GTP-bound state, ROPs interact with specific effectors that transduce downstream signaling or function as scaffolds for interaction with additional effector molecules (Berken and Wittinghofer, 2008). Conserved point mutations in the G1 (P loop) Gly-15 or the G3 (switch II) Gln-64, which abolish GTP hydrolysis, or the G1 Thr-20 or G4 Asp-121 that compromise GDP/GTP exchange, can form either constitutively active or dominant negative mutants, respectively (Feig, 1999; Berken et al., 2005; Berken and Wittinghofer, 2008; Sorek et al., 2010). Primarily based on studies with neomorphic mutants, ROPs have been implicated in the regulation of cytoskeleton organization and dynamics, vesicle trafficking, auxin transport and response, abscisic acid (ABA) response, and response to pathogens (Nibau et al., 2006; Yalovsky et al., 2008; Yang, 2008; Lorek et al., 2010; Wu et al., 2011; and refs. therein).In Arabidopsis (Arabidopsis thaliana), there are 11 ROP proteins (Winge et al., 1997). Assigning specific functions to individual members of this family is difficult, however, because ROPs are functionally redundant. A ROP10 loss-of-function mutant was reported to be ABA hypersensitive (Zheng et al., 2002), displaying enhanced expression of tens of genes in response to ABA treatments (Xin et al., 2005). However, in the absence of exogenous ABA, gene expression in the rop10 mutant was similar to that in wild-type plants (Xin et al., 2005). Loss of leaf epidermis pavement cell polarity was reported for rop4 rop2-RNAi (for RNA interference) double mutant plants (Fu et al., 2005). Mild changes in pavement and hypocotyl cell structure and microtubule (MT) organization were reported for a rop6 loss-of-function mutant (Fu et al., 2009).The involvement of ROPs in auxin-regulated development has been addressed in several studies (Wu et al., 2011). Ectopic expression of a dominant negative ROP2 (rop2^DN) mutant under regulation of the 35S promoter resulted in a loss of apical dominance and a reduction in the number of lateral roots. In contrast, ectopic expression of constitutively active ROP2 (rop2^CA) caused an increase in the number of lateral roots and an enhanced decrease in primary root length in response to auxin. Consistent with these findings, the expression of a constitutively active NtRAC1 in tobacco (Nicotiana tabacum) protoplasts induced the expression of auxin-regulated genes in the absence of auxin and promoted the formation of protein nuclear bodies containing components of the proteasome and COP9 signalosome (Tao et al., 2002, 2005; Wu et al., 2011). The ROP effector ICR1 (for interactor of constitutively active ROP1) regulates polarized secretion and is required for polar auxin transport (Lavy et al., 2007; Bloch et al., 2008; Hazak et al., 2010; Hazak and Yalovsky, 2010). In the root, local auxin gradients induce the accumulation of ROPs in trichoblasts at the site of future root hair formation (Fischer et al., 2006). Recently, it was shown that interdigitation of leaf epidermis pavement cells depends on Auxin-Binding Protein1 (ABP1)-mediated ROP activation (Xu et al., 2010). Taken together, these data indicate that ROPs are involved in both mediating the auxin response and facilitating directional auxin transport. It is still unclear, however, which ROPs function in these processes.ROP function was linked to plant defense responses in several studies. In rice (Oryza sativa), OsRAC1 is a positive regulator of the hypersensitive response, possibly through interactions with the NADPH oxidase RbohB, Required for Mla12 Resistance, and Heat Shock Protein90 (Ono et al., 2001; Thao et al., 2007; Wong et al., 2007). Interestingly, other members of the rice ROP family, namely RAC4 and RAC5, are negative regulators of resistance to the rice blast pathogen Magnaporthe grisea (Chen et al., 2010). Similar to rice, when expressed in tobacco, dominant negative OsRAC1 suppressed the hypersensitive response (Moeder et al., 2005). In barley (Hordeum vulgare), several constitutively active ROP/RAC mutants and a MT-associated ROPGAP1 loss-of-function mutant enhanced susceptibility to the powdery mildew Blumeria graminis f. sp. hordei (Bgh). The activated ROP-enhanced susceptibility to Bgh was attributed to disorganization of the actin cytoskeleton and was shown to depend on Mildew Resistance Locus O (MLO; Schultheiss et al., 2002, 2003; Opalski et al., 2005; Hoefle et al., 2011). In barley, three ROP proteins, HvRACB, HvRAC1, and HvRAC3, were linked to both development and pathogen response (Schultheiss et al., 2005; Pathuri et al., 2008; Hoefle et al., 2011).We have analyzed the function of the Arabidopsis AtROP6 (ROP6) by characterizing its expression pattern and its regulation by auxin and the phenotype of plants that express rop6^DN under the regulation of its endogenous promoter. The utilization of the dominant negative mutant overcame functional redundancy, while expression under the regulation of the endogenous promoter enabled the analysis of ROP6 function in a developmental context. Phenotypic and gene expression analyses indicate that ROP6 functions in developmental, salicylic acid (SA)-dependent, and SA-independent defense response pathways.     

Catabolism of l–methionine in the formation of sulfur and other volatiles in melon (Cucumis melo L.) fruit

Sulfur‐containing aroma volatiles are important contributors to the distinctive aroma of melon and other fruits. Melon cultivars and accessions differ in the content of sulfur‐containing and other volatiles. l –methionine has been postulated to serve as a precursor of these volatiles. Incubation of melon fruit cubes with ¹³C‐ and ²H‐labeled l –methionine revealed two distinct catabolic routes into volatiles. One route apparently involves the action of an l ‐methionine aminotransferase and preserves the main carbon skeleton of l ‐methionine. The second route apparently involves the action of an l ‐methionine‐γ–lyase activity, releasing methanethiol, a backbone for formation of thiol‐derived aroma volatiles. Exogenous l ‐methionine also generated non‐sulfur volatiles by further metabolism of α–ketobutyrate, a product of l ‐methionine‐γ–lyase activity. α–Ketobutyrate was further metabolized into l –isoleucine and other important melon volatiles, including non‐sulfur branched and straight‐chain esters. Cell‐free extracts derived from ripe melon fruit exhibited l ‐methionine‐γ–lyase enzymatic activity. A melon gene (CmMGL) ectopically expressed in Escherichia coli, was shown to encode a protein possessing l ‐methionine‐γ–lyase enzymatic activity. Expression of CmMGL was relatively low in early stages of melon fruit development, but increased in the flesh of ripe fruits, depending on the cultivar tested. Moreover, the levels of expression of CmMGL in recombinant inbred lines co‐segregated with the levels of sulfur‐containing aroma volatiles enriched with +1 m/z unit and postulated to be produced via this route. Our results indicate that l ‐methionine is a precursor of both sulfur and non‐sulfur aroma volatiles in melon fruit.