Proteomic profiling of serum samples from chikungunya-infected patients provides insights into host response

Background

Chikungunya is a highly debilitating febrile illness caused by Chikungunya virus, a single-stranded RNA virus, which is transmitted by Aedes aegypti or Aedes albopictus mosquito species. The pathogenesis and host responses in individuals infected with the chikungunya virus are not well understood at the molecular level. We carried out proteomic profiling of serum samples from chikungunya patients in order to identify molecules associated with the host response to infection by this virus.

Results

Proteomic profiling of serum obtained from the infected individuals resulted in identification of 569 proteins. Of these, 63 proteins were found to be differentially expressed (≥ 2-fold) in patient as compared to control sera. These differentially expressed proteins were involved in various processes such as lipid metabolism, immune response, transport, signal transduction and apoptosis.

Conclusions

This is the first report providing a global proteomic profile of serum samples from individuals infected with the chikungunya virus. Our data provide an insight into the proteins that are involved as host response factors during an infection. These proteins include clusterin, apolipoproteins and S100A family of proteins.     

Single Quantum Dot Tracking Reveals that an Individual Multivalent HIV-1 Tat Protein Transduction Domain Can Activate Machinery for Lateral Transport and Endocytosis

The mechanisms underlying the cellular entry of the HIV-1 Tat protein transduction domain (TatP) and the molecular information necessary to improve the transduction efficiency of TatP remain unclear due to the technical limitations for direct visualization of TatP''s behavior in cells. Using confocal microscopy, total internal reflection fluorescence microscopy, and four-dimensional microscopy, we developed a single-molecule tracking assay for TatP labeled with quantum dots (QDs) to examine the kinetics of TatP initially and immediately before, at the beginning of, and immediately after entry into living cells. We report that even when the number of multivalent TatP (mTatP)-QDs bound to a cell was low, each single mTatP-QD first locally induced the cell''s lateral transport machinery to move the mTatP-QD toward the center of the cell body upon cross-linking of heparan sulfate proteoglycans. The centripetal and lateral movements were linked to the integrity and flow of actomyosin and microtubules. Individual mTatP underwent lipid raft-mediated temporal confinement, followed by complete immobilization, which ultimately led to endocytotic internalization. However, bivalent TatP did not sufficiently promote either cell surface movement or internalization. Together, these findings provide clues regarding the mechanisms of TatP cell entry and indicate that increasing the valence of TatP on nanoparticles allows them to behave as cargo delivery nanomachines.     

Interaction of alpha-lactalbumin with mini-alphaA-crystallin

A-Crystallin can function like a molecular chaperone. We have recently shown that residues 71-88 in A-crystallin represent the chaperone active site of the protein. A peptide containing the sequence of A-crystallin sequence DFVIFLDVKHFSPEDLTVK (mini A-crystallin) by itself displays the antiaggregation property of A-crystallin. We have prepared a complex of reduced -lactalbumin and mini-A-crystallin and investigated the nature, conformation, and properties of the complex by dynamic light scattering, HPLC analysis, CD spectroscopy, and fluorescence studies. Although mini-A was able to prevent the precipitation of reduced -lactalbumin, large aggregates (50-500 nm) of the complex were formed during the assay. Amino acid composition estimation revealed that -lactalbumin and mini-A-crystallin were present in 1:2 ratio in the aggregates. During our study significant red shift in the Trp fluorescence emission maximum and an increase in Bis-ANS binding to the mini A-crystallin-bound -lacatalbumin were observed. The CD spectra of the complex showed a significant loss of -helical content but the -sheet content appeared to be less affected, indicating the molten-globule state of the reduced lactalbumin in the complex. These data show that the active site of A-crystallin by itself can maintain a significantly denatured and unfolded protein in soluble form.     

AlphaA-crystallin interacting regions in the small heat shock protein, alphaB-crystallin

Amino acid sequences of alphaB-crystallin, involved in interaction with alphaA-crystallin, were determined by using peptide scans. Positionally addressable 20-mer overlapping peptides, representing the entire sequence of alphaB-crystallin, were synthesized on a PVDF membrane. The membrane was blocked with albumin and incubated with purified alphaA-crystallin. Probing the membrane with alphaA-crystallin-specific antibodies revealed residues 42-57, 60-71, and 88-123 in alphaB-crystallin to interact with alphaA-crystallin. Residues 42-57 and 60-71 interacted more strongly with alphaA-crystallin than the 88-123 sequence of alphaB-crystallin. Binding of one of the alphaB peptides (42-57) to alphaA-crystallin was also confirmed by gel filtration studies and HPLC analysis. The alphaB-crystallin sequences involved in interaction with alphaA-crystallin were distinct from the chaperone sites reported earlier as binding of the alphaB sequence from residues 42-57 does not alter the chaperone-like function of alphaA-crystallin. To identify the critical residues involved in interaction with alphaA-crystallin, R50G and P51A mutants of alphaB-crystallin were made and tested for their ability to interact with alphaA-crystallin. The oligomeric size and hydrophobicity of the mutants were similar. Circular dichroism studies showed that the P51A mutation increased the alpha-helical content of the protein. While the alphaBR50G mutant showed chaperone-like activity similar to wild-type alphaB, alphaBP51A showed reduced chaperone function. Fluorescence resonance energy transfer studies showed that the P51A mutation decreased the rate of subunit exchange with alphaA by 63%, whereas the R50G mutation reduced the exchange rate by 23%. Similar to wild-type alphaB, alphaB-crystallin peptide (42-57) effectively competed with alphaBP51A and alphaBR50G for interaction with alphaA. Thus, our studies showed that the alphaB-crystallin sequence (42-57) is one of the interacting regions in alphaB and alphaA oligomer formation.     

A Dominant Mutation in the Light-Oxygen and Voltage2 Domain Vicinity Impairs Phototropin1 Signaling in Tomato

In higher plants, blue light (BL) phototropism is primarily controlled by the phototropins, which are also involved in stomatal movement and chloroplast relocation. These photoresponses are mediated by two phototropins, phot1 and phot2. Phot1 mediates responses with higher sensitivity than phot2, and phot2 specifically mediates chloroplast avoidance and dark positioning responses. Here, we report the isolation and characterization of a Nonphototropic seedling1 (Nps1) mutant of tomato (Solanum lycopersicum). The mutant is impaired in low-fluence BL responses, including chloroplast accumulation and stomatal opening. Genetic analyses show that the mutant locus is dominant negative in nature. In dark-grown seedlings of the Nps1 mutant, phot1 protein accumulates at a highly reduced level relative to the wild type and lacks BL-induced autophosphorylation. The mutant harbors a single glycine-1484-to-alanine transition in the Hinge1 region of a phot1 homolog, resulting in an arginine-to-histidine substitution (R495H) in a highly conserved A′α helix proximal to the light-oxygen and voltage2 domain of the translated gene product. Significantly, the R495H substitution occurring in the Hinge1 region of PHOT1 abolishes its regulatory activity in Nps1 seedlings, thereby highlighting the functional significance of the A′α helix region in phototropic signaling of tomato.Being sessile in nature, plants have developed diverse sets of sensory mechanisms, integrating external cues such as light, water, and temperature to adapt their growth and development to the ambient environment. Plants have evolved a cohort of photoreceptors such as red/far-red light-sensing phytochromes (Chen and Chory, 2011), UV-A/blue light (BL)-sensing phototropins (Christie, 2007; Holland et al., 2009; Suetsugu and Wada, 2013), cryptochromes (Yu et al., 2010; Liu et al., 2011), Zeitlupe (ZTL)/Flavin-binding, Kelch repeat, F-box protein1/light-oxygen and voltage (LOV)-kelch protein2 members of the ZTL/ADAGIO putative family of photoreceptors (Suetsugu and Wada, 2013), and UV-B light-sensing UV-B resistance8 (Heijde and Ulm, 2012), enabling them to sense nearly the full range of the solar spectrum. One of the most visually obvious photoresponses of flowering plants involves the growth and orientation of organs toward or away from light, particularly during the early stages of growth and the establishment of seedlings (Iino, 1990) and during gap-filling situations in dense canopy conditions (Ballaré, 1999) for optimizing photosynthesis and interspecies/intraspecies competition. Several studies involving the relative effectiveness of different wavelengths of the solar spectrum as well as monitoring of lateral differences in light intensity revealed that the directional growth of plants is specifically mediated by the UV-A/blue region of the visible spectrum. Molecular genetic analysis of Arabidopsis (Arabidopsis thaliana) mutants inhibited in hypocotyl curvature toward BL revealed that, among the UV-A light-/BL-specific photoreceptors, the phototropins perceive ambient light as a cue for directional growth (Liscum and Briggs, 1995; Kagawa et al., 2001).Phototropins have been identified in several plant species, ranging from the green alga Chlamydomonas reinhardtii to higher plants (Briggs et al., 2001). To date, two members of the phototropins have been reported from higher plants, phot1 and phot2, which share sequence homology (Sakai et al., 2001). Physiological analyses with Arabidopsis mutants lacking phot1 and phot2 have revealed that, in addition to regulating the hypocotyl curvature of seedlings toward BL (Huala et al., 1997; Christie et al., 1998), phototropins also regulate a diverse range of responses in flowering plants (Christie and Murphy, 2013; Hohm et al., 2013). These responses include chloroplast movements (Sakai et al., 2001), nuclear positioning (Iwabuchi et al., 2007), stomatal opening (Kinoshita et al., 2001), sun tracking (Inoue et al., 2008b), leaf expansion (Ohgishi et al., 2004), leaf movements (Inoue et al., 2005), leaf photomorphogenesis (Kozuka et al., 2011), leaf flattening (Sakamoto and Briggs, 2002), and the rapid inhibition of the growth of etiolated hypocotyls (Folta and Spalding, 2001).While both phot1 and phot2 overlap in function in regulating phototropism, chloroplast accumulation, leaf expansion, and stomatal opening, they also exhibit differential photosensitivity to BL, where phot1 is more sensitive to low-fluence BL than phot2. Both phot1 and phot2 redundantly regulate the chloroplast accumulation toward low-fluence BL, and phot2 exclusively regulates the chloroplast avoidance from high-fluence BL (Jarillo et al., 2001; Kagawa et al., 2001), while phot1 solely mediates the rapid inhibition of the elongation of etiolated hypocotyls (Folta and Spalding, 2001). Analysis of mutants downstream of blue light perception by phototropins revealed that the phototropin signaling branches out at an early step, and phot1 and phot2 trigger distinct photoresponses recruiting multiple signaling partners (Christie and Murphy, 2013; Hohm et al., 2013).Molecular characterizations have shown that phototropins are plasma membrane-associated Ser/Thr kinases containing a photosensory domain (Briggs and Christie, 2002) in the N-terminal region composed of two LOV domains (LOV1 and LOV2) and the kinase domain at the C-terminal end. The LOV1 and LOV2 domains bind the FMN as chromophore and are responsible for BL sensing by phototropin. Although phototropins characteristically possess two LOV domains, the photoregulation of phototropin activity is predominantly mediated by LOV2 (Christie, 2007). The exposure to BL also causes adduct formation between the FMN and the Cys residue in LOV domains and leads to the phosphorylation of phototropin, which is believed to be the primary step in the transmission of phototropic signals (Christie et al., 1998; Sakai et al., 2000). To decipher the functions of different domains of phototropins, many different substitution mutants of phototropins have been generated, which have enabled the elucidation of the functional significance of the different domains (Matsuoka and Tokutomi, 2005; Jones et al., 2007; Kong et al., 2007; Inoue et al., 2008a). Inoue et al. (2008a) showed that the BL-induced autophosphorylation of Ser-851 in the C-terminal kinase domain of phototropin is the primary step for initiating stomatal opening, phototropism, chloroplast accumulation, and leaf flattening. Mutational studies also revealed that the photosensory N-terminal domain of phototropin acts as a kinase inhibitor, where the LOV2 domain inhibits the activity of kinase domain by binding to it, and BL exposure is required for the dissociation of the LOV2 domain, enabling phosphorylation of the kinase domain (Matsuoka and Tokutomi, 2005; Jones et al., 2007).While our current understanding of phototropism has been greatly facilitated by the isolation of phototropins and their signaling mutants, the phot mutants identified to date are loss-of-function alleles. The lack of dominant-negative alleles or alleles with increased sensitivity to phototropic stimulus has hindered exploration into the roles of different domains of phot proteins in regulating phototropic signaling. In addition, the dearth of mutants defective in phototropin or phototropin-mediated responses has been a major bottleneck in furthering our understanding of the function of phototropins in crop species. Although phototropin homologs have been identified from a variety of crop species, including oat (Avena sativa; Zacherl et al., 1998), rice (Oryza sativa; Kanegae et al., 2000), and tomato (Solanum lycopersicum; Sharma et al., 2007; Sharma and Sharma, 2007), only the coleoptile phototropism1 mutant of rice has been isolated, which is defective in BL phototropism (Haga et al., 2005).Here, we report that in a mutant screen for nonphototropic seedlings under continuous BL, we recovered a strong dominant-negative mutation of phot1. The dominant-negative mutations are useful to elucidate redundant functions, as mutant protein in addition to suppressing its own functions can also suppress the function of its partners. The characterization of this new phot1 mutant revealed that the dominant activity is caused by the substitution of an Arg residue located in the A′α helix in the Hinge1 region between the LOV1 and LOV2 domains. Our study shows the functional importance of the A′α helix (Halavaty and Moffat, 2007) in regulating phot1-mediated signaling in tomato.     

Host response profile of human brain proteome in toxoplasma encephalitis co-infected with HIV

Background

Toxoplasma encephalitis is caused by the opportunistic protozoan parasite Toxoplasma gondii. Primary infection with T. gondii in immunocompetent individuals remains largely asymptomatic. In contrast, in immunocompromised individuals, reactivation of the parasite results in severe complications and mortality. Molecular changes at the protein level in the host central nervous system and proteins associated with pathogenesis of toxoplasma encephalitis are largely unexplored. We used a global quantitative proteomic strategy to identify differentially regulated proteins and affected molecular networks in the human host during T. gondii infection with HIV co-infection.

Results

We identified 3,496 proteins out of which 607 proteins were differentially expressed (≥1.5-fold) when frontal lobe of the brain from patients diagnosed with toxoplasma encephalitis was compared to control brain tissues. We validated differential expression of 3 proteins through immunohistochemistry, which was confirmed to be consistent with mass spectrometry analysis. Pathway analysis of differentially expressed proteins indicated deregulation of several pathways involved in antigen processing, immune response, neuronal growth, neurotransmitter transport and energy metabolism.

Conclusions

Global quantitative proteomic approach adopted in this study generated a comparative proteome profile of brain tissues from toxoplasma encephalitis patients co-infected with HIV. Differentially expressed proteins include previously reported and several new proteins in the context of T. gondii and HIV infection, which can be further investigated. Molecular pathways identified to be associated with the disease should enhance our understanding of pathogenesis in toxoplasma encephalitis.

Electronic supplementary material

The online version of this article (doi:10.1186/1559-0275-11-39) contains supplementary material, which is available to authorized users.     

Real‐time PCR assays for rapid detection of Zeugodacus cucumis and Bactrocera jarvisi (Diptera: Tephritidae) for quarantine application

Zeugodacus cucumis and Bactrocera jarvisi are pests of fruit and vegetable crops and cause damage to horticulture industries. Immature stages of these two fruit fly species have been intercepted in New Zealand a number of times. Identification to species was not possible using morphological characters; thus, it is important to develop an assay for their species‐level identification. Here, the real‐time PCR assays for rapid identification of Z. cucumis and B. jarvisi were developed and validated. The PCR protocols demonstrated their specificity by amplifying the two target species successfully, with no cross‐reactions observed in the tested tephritid species. The in silico test of the primer and probe binding sites of the two assays also demonstrated the assays’ specificity by no mismatches present in the binding regions of the target species, but 1–4 mismatches in the binding regions of the non‐target fruit fly species. The thresholds of detection for the two assays are as low as 10 copies/µl of the target DNA, indicating that the assays have a very high sensitivity. The application of the real‐time PCR assays has greatly assisted in routine pest identifications at the New Zealand border and surveillance programme. Therefore, the assays have the potential to be used by diagnostic agencies and research organizations worldwide.     

Hsp70 Inhibits Aggregation of IAPP by Binding to the Heterogeneous Prenucleation Oligomers

Molecular chaperone Hsp70 plays important roles in the pathology of amyloid diseases by inhibiting aberrant aggregation of proteins. However, the biophysical mechanism of the interaction of Hsp70 with the intrinsically disordered proteins (IDPs) is unclear. Here, we report that Hsp70 inhibits aggregation of islet amyloid polypeptide (IAPP) at substoichiometric concentrations under diverse solution conditions, including in the absence of ATP. The inhibitory effect is strongest if Hsp70 is added in the beginning of aggregation but progressively less if added later, indicating a role for Hsp70 in preventing nucleation of IAPP. However, ensemble measurement of the binding affinity suggests poor interactions between Hsp70 and IAPP. Therefore, we hypothesize that the interaction must involve a rare species (e.g., the oligomeric intermediates of IAPP). Size exclusion chromatography and field flow fractionation are then used to fractionate the constituent species. Multiangle light scattering and fluorescence correlation spectroscopy measurements indicate that the dominant fraction in size exclusion chromatography contains a few nanomolar Hsp70-IAPP complexes amid several μmoles of free Hsp70. Using single-particle two-color coincidence detection measurements, we detected a minor fraction that exhibits fluorescence bursts arising from heterogeneous oligomeric complexes of IAPP and Hsp70. Taken together, our results indicate that Hsp70 interacts poorly with the monomers but strongly with oligomers of IAPP. This is likely a generic feature of the interactions of Hsp70 chaperones with the amyloidogenic IDPs. Whereas high-affinity interactions with the oligomers prevent aberrant aggregation, poor interaction with the monomers averts interference with the physiological functions of the IDPs.     

Quantitative analysis of condensation/decondensation status of pDNA in the nuclear sub-domains by QD-FRET

Recent studies indicate that controlling the nuclear decondensation and intra-nuclear localization of plasmid DNA (pDNA) would result in an increased transfection efficiency. In the present study, we established a technology for imaging the nuclear condensation/decondensation status of pDNA in nuclear subdomains using fluorescence resonance energy transfer (FRET) between quantum dot (QD)-labeled pDNA as donor, and rhodamine-labeled polycations as acceptor. The FRET-occurring pDNA/polycation particle was encapsulated in a nuclear delivery system; a tetra-lamellar multifunctional envelope-type nano device (T-MEND), designed to overcome the endosomal membrane and nuclear membrane via step-wise fusion. Nuclear subdomains (i.e. heterochromatin and euchromatin) were distinguished by Hoechst33342 staining. Thereafter, Z-series of confocal images were captured by confocal laser scanning microscopy. pDNA in condensation/decondensation status in heterochromatin or euchromatin were quantified based on the pixel area of the signals derived from the QD and rhodamine. The results obtained indicate that modulation of the supra-molecular structure of polyrotaxane (DMAE-ss-PRX), a condenser that is cleaved in a reductive environment, conferred euchromatin-preferred decondensation. This represents the first demonstration of the successful control of condensation/decondensation in specific nuclear sub-domain via the use of an artificial DNA condenser.