Skeletal Muscle Type Comparison of Subsarcolemmal Mitochondrial Membrane Phospholipid Fatty Acid Composition in Rat

The phospholipid composition of membranes can influence the physiological functioning of the cell or subcellular organelle. This association has been previously demonstrated in skeletal muscle, where cellular or subcellular membrane, specifically mitochondria, phospholipid composition is linked to muscle function. However, these observations are based on whole mixed skeletal muscle analysis, with little information on skeletal muscles of differing fiber-type compositions. These past approaches that used mixed muscle may have misidentified outcomes or masked differences. Thus, the purpose of this study was to compare the phospholipid fatty acid composition of subsarcolemmal (SS) mitochondria isolated from slow-twitch postural (soleus), fast-twitch highly oxidative glycolytic locomotory (red gastrocnemius), and fast-twitch oxidative glycolytic locomotory (plantaris) skeletal muscles. The main findings of the study demonstrated unique differences between SS mitochondrial membranes from postural soleus compared to the other locomotory skeletal muscles examined, specifically lower percentage mole fraction of phosphatidylcholine (PC) and significantly higher percentage mole fraction of saturated fatty acids (SFA) and lower n6 polyunsaturated fatty acids (PUFA), resulting in a lower unsaturation index. We also found that although there was no difference in the percentage mole fraction of cardiolipin (CL) between skeletal muscle types examined, CL of soleus mitochondrial membranes were approximately twofold more SFA and approximately two-thirds less PUFA, resulting in a 20–30% lower unsaturation and peroxidation indices. Thus, the results of this study indicate unique membrane lipid composition of mitochondria isolated from different skeletal muscle types, a potential consequence of their respective duty cycles.     

Selection of a Rare Neutralization-Resistant Variant following Passive Transfer of Convalescent Immune Plasma in Equine Infectious Anemia Virus-Challenged SCID Horses

Vaccines preventing HIV-1 infection will likely elicit antibodies that neutralize diverse strains. However, the capacity for lentiviruses to escape broadly neutralizing antibodies (NAbs) is not completely understood, nor is it known whether NAbs alone can control heterologous infection. Here, we determined that convalescent immune plasma from a horse persistently infected with equine infectious anemia virus (EIAV) neutralized homologous virus and several envelope variants containing heterologous principal neutralizing domains (PND). Plasma was infused into young horses (foals) affected with severe combined immunodeficiency (SCID), followed by challenge with a homologous EIAV stock. Treated SCID foals were protected against clinical disease, with complete prevention of infection occurring in one foal. In three SCID foals, a novel neutralization-resistant variant arose that was found to preexist at a low frequency in the challenge inoculum. In contrast, SCID foals infused with nonimmune plasma developed acute disease associated with high levels of the predominant challenge virus. Following transfer to an immunocompetent horse, the neutralization-resistant variant induced a single febrile episode and was subsequently controlled in the absence of type-specific NAb. Long-term control was associated with the presence of cytotoxic T lymphocytes (CTL). Our results demonstrate that immune plasma with neutralizing activity against heterologous PND variants can prevent lentivirus infection and clinical disease in the complete absence of T cells. Importantly, however, rare neutralization-resistant envelope variants can replicate in vivo under relatively broad selection pressure, highlighting the need for protective lentivirus vaccines to elicit NAb responses with increased breadth and potency and/or CTL that target conserved epitopes.Development of an effective vaccine will be critical in the efforts to control the human immunodeficiency virus type 1 (HIV-1) pandemic. Unfortunately, vaccines evaluated in completed human efficacy trials have shown moderate to no protective effects, and, clearly, much more work is needed to define the correlates of lentivirus immune protection. Although these correlates are still not entirely known, vaccine strategies that elicit antibodies with broad neutralizing activity are currently of considerable interest, and it is widely believed that HIV-1 envelope glycoproteins that induce broadly neutralizing antibodies (NAbs) will be critical components of a protective vaccine (21, 28, 53, 63).Equine infectious anemia virus (EIAV) is a macrophage-tropic lentivirus that causes persistent infection in horses worldwide and serves as an important large-animal translational model in which to dissect basic correlates of protective lentiviral immunity (9, 31, 33, 38, 57). EIAV is a naturally occurring lentivirus, and infection results in a predictable course of recurrent episodes of plasma viremia and clinical disease. As with HIV-1 and simian immunodeficiency virus (SIV), EIAV infection is not cleared. However, infected horses eventually control viral replication and clinical disease to remain persistently infected inapparent carriers. Adaptive immune responses, including NAbs, are required for EIAV control since young horses (foals) with severe combined immunodeficiency (SCID), unlike normal foals, fail to eliminate the initial viremia following challenge (46). Equine SCID is caused by a frameshift mutation in the gene encoding the catalytic subunit of DNA-dependent protein kinase (DNA-PKcs) (55, 60) and has an autosomal recessive mode of inheritance (47). The equine SCID defect is more severe than its murine counterpart in that SCID foals are incapable of forming either coding or signal joints (55). Adoptive transfer of EIAV-specific T and B lymphocytes to a SCID foal results in functional cytotoxic T lymphocytes (CTL) and NAb activity and is protective against homologous EIAV challenge (33).During acute EIAV infection, each recurrent episode coincides with the emergence of an antigenically distinct EIAV variant as defined by type-specific NAb, which neutralizes virus isolated during early disease episodes but not virus isolated during subsequent disease episodes (2, 20, 22, 43, 52). Amino acid variation primarily occurs within hypervariable regions V1 to V8 of the envelope gp90 surface unit (SU) and particularly within the V3/principal neutralizing domain (PND) region (1, 19, 24, 25, 57). Our work with EIAV-infected SCID foals indicates that significant envelope diversification does not occur in the absence of NAbs but that rapid envelope diversification occurs when adaptive immune responses are reconstituted (35). Thus, adaptive immunity, including NAb, drives selection of EIAV envelope variants during acute infection. Amino acid changes occur primarily within the V3 to V7 hypervariable SU regions, and many changes affect potential N-linked glycosylation sites (PNLGS) (35). Importantly, however, CTL also target the SU, and variants that escape CTL recognizing an EIAV V3/PND epitope have been identified (37, 38). Thus, both NAbs and CTL are capable of contributing to the selection of EIAV SU variants, but the relative contributions of each to such selection are not known.Recently, SU variation was evaluated in an immunocompetent pony experimentally inoculated with the virulent wild-type Wyoming strain of EIAV (57). Seventy-one distinct V3 variants that partitioned into five major nonoverlapping groups were identified and designated PND1 to PND5. Neutralization assays using chimeric infectious molecular clones containing these PNDs suggested a transition from type-specific NAb responses toward more broadly reactive immune responses during the course of infection and indicated that genetic changes conferring resistance to broadly NAbs lead to recrudescence of clinical disease following a lengthy clinically quiescent period (57). Thus, the NAb response broadens significantly during long-term persistent EIAV infection, and broadly NAbs play a critical role in EIAV immune control.Studies of nonhuman primates have provided important information regarding the protective effects of NAbs. Passive immunization of macaques with purified immunoglobulin from chimpanzees infected with several different HIV-1 isolates results in complete protection from homologous chimeric simian/human immunodeficiency virus (SHIV) infection when the immunoglobulin is given 24 h prior to challenge (54). Passive transfer of a triple combination of broadly neutralizing human monoclonal antibodies directed against the envelope of a primary HIV-1 isolate results in complete protection against SHIV infection in some macaques while others become infected but exhibit decreased plasma viremia (29). The contribution of T cells to partial protection in these studies is not clear, and the presence or absence of viral escape variants in the unprotected macaques has not been evaluated. In neonatal macaques, various combinations of broadly neutralizing human monoclonal antibodies directed against conserved HIV envelope epitopes administered before and after SHIV challenge result in protection against persistent systemic infection in some animals, but clinical disease develops in others (12-14). Virus-specific T-cell proliferative responses are detected in some of the protected animals, indicating that cellular immune responses occur and likely contribute to protection by eliminating infected cells (13).Despite the fact that NAbs can block experimental SHIV infection, selection pressure exerted by NAbs plays a critical role in HIV-1 and SIV envelope evolution during infection, and evasion of NAb responses is an important mechanism of HIV-1 and SIV persistence (11, 16, 27, 48, 59). The maturation of a type-specific NAb response in SIV-infected rhesus macaques significantly correlates with diversification in the V1/V2 region of the SIV envelope (50). In HIV-1, NAbs are detectable within the first 2 months postinfection and result in an early and significant selection force on the virus population (49). Escape from NAbs involves many amino acid substitutions with little cross-neutralization between closely related strains, and NAb responses drive the diversification of the HIV-1 envelope during the early stages of infection (16). The early appearance of NAbs in patients with acute HIV-1 infection results in the replacement of neutralization-sensitive virus by successive populations of resistant virus, and virus escape primarily involves changes in N-linked glycosylation (59). Thus, overcoming neutralization escape constitutes a significant barrier to the ultimate efficacy of any NAb-eliciting HIV-1 vaccine.Because the SCID defect occurs naturally in the horse, it provides a powerful and unique opportunity to finely dissect the protective effects of immune interventions against a naturally occurring lentivirus independent of other de novo adaptive immune responses. This level of dissection is not possible in other lentivirus model systems. The goal of the current study was to determine if broadly NAbs could protect against lentivirus challenge in the complete absence of T lymphocytes and other adaptive immune responses. We hypothesized that convalescent immune plasma from a long-term persistently infected inapparent carrier horse containing antibodies capable of neutralizing homologous and several heterologous EIAV SU PND variants would provide complete protection when infused into SCID foals before experimental virus inoculation. This plasma was administered to four SCID foals 24 h prior to challenge, and four control SCID foals received normal horse plasma. Clinical outcome, plasma viral load, and serum neutralization activity were analyzed in all foals. Although complete protection was achieved in one treated foal, infection occurred in the others. In foals that became viremic, the SU sequence and neutralization phenotype of the breakthrough virus were determined. As part of these experiments, blood containing this virus was inoculated into a naive immunocompetent horse, and the adaptive immune responses associated with its control were further evaluated.     

Nucleotide Variability and Translation Efficiency of the 5′ Untranslated Region of Hepatitis A Virus: Update from Clinical Isolates Associated with Mild and Severe Hepatitis

Mutations in the internal ribosome entry site (IRES) of hepatitis A virus (HAV) have been associated with enhanced in vitro replication and viral attenuation in animal models. To address the possible role of IRES variability in clinical presentation, IRES sequences were obtained from HAV isolates associated with benign (n = 8) or severe (n = 4) hepatitis. IRES activity was assessed using a bicistronic dual-luciferase expression system in adenocarcinoma (HeLa) and hepatoma (HuH7) cell lines. Activity was higher in HuH7 than in HeLa cells, except for an infrequently isolated genotype IIA strain. Though globally low, significant variation in IRES-dependent translation efficiency was observed between field isolates, reflecting the low but significant genetic variability of this region (94.2% ± 0.5% nucleotide identity). No mutation was exclusive of benign or severe hepatitis, and variations in IRES activity were not associated with a clinical phenotype, indirectly supporting the preponderance of host factors in determining the clinical presentation.Hepatitis A virus (HAV) is a nonenveloped RNA virus of the Picornaviridae family. The viral genome consists of an approximately 7,500-nucleotide (nt)-long, positive-stranded RNA divided in three parts: a 5′ untranslated region (5′ UTR), a single open reading frame that encodes both structural and nonstructural proteins, and a 3′ UTR with a short poly(A) tail. By sequencing of the VP1-2A junction and the VP1 gene, 3 genotypes (I, II, and III) divided into A and B subtypes have been described in humans (7, 27). HAV is the main cause of acute viral hepatitis worldwide. The majority of cases follow a benign course, but some may be present with fulminant forms, characterized by acute liver failure (factor V levels of <50% and encephalopathy). HAV-induced liver disease appears to result primarily from immunologic mechanisms, chiefly on the basis of in vitro studies. Most HAV strains have no detectable cytopathic effect in cell culture and no apparent effect on cell growth or metabolism (16), and HAV-infected cells are lysed by cytotoxic T cells isolated from the liver of acutely infected patients (30, 31). Clinical studies have suggested that host factors such as age and underlying liver disease were involved in the severity of liver diseases (32, 33) and that the host immune response also played a role in the fulminant forms of hepatitis A, as evidenced by markedly low viral loads (26).Nevertheless, the existence of viral determinants of hepatitis A severity is suggested by both experimental and clinical studies. Indeed, mutations within the VP1-2A and 2C genes have been shown to enhance virulence in tamarins (9). It has also been suggested that 5′ UTR mutations associated with viral adaptation to cell culture were also responsible for viral attenuation in vivo (15). The 5′ UTR of HAV is about 735 nucleotides long and is considered the most conserved region of the genome. The 5′ UTR is involved in genome replication and translation initiation. Folding predictions and biochemical probing showed that this region forms a highly ordered secondary structure containing a pyrimidine-rich tract (PRT) and an internal ribosomal entry site (IRES) with 10 to 12 AUG triplets upstream of the initiator codon (18). The IRES allows the initiation of the cap-independent translation of the viral genome. Most knowledge of HAV IRES activity is derived from studies of the HM-175 reference strain and its cell culture-adapted variants (4, 5, 36). These experiments have shown that HAV presents the lowest IRES-dependent translation initiation activity among picornaviruses both in reticulocyte lysates and in a variety of cell lines, including the human hepatoma cell line HepG2 (type III IRES) (3, 6). These features have been attributed to a lower affinity of the HAV 5′ UTR for translation factors (6). The hypothesis that the slow growth of HAV in cell culture could be related to this inefficient translation is supported by the emergence of 5′ UTR mutations in cell culture-adapted variants with enhanced viral replication (8). The finding that these mutations were associated with viral attenuation in vivo supports the hypothesis of viral determinants of virulence in the 5′ UTR (15). Among the few clinical studies which have addressed this question, Fujiwara et al., by comparing full-length HAV genomes obtained from Japanese patients with benign or fulminant hepatitis, found less nucleotide variation in the 5′ UTRs from patients with fulminant hepatitis (12, 13) and suggested that two IRES mutations (G324A and C372G/T) might influence the course of HAV infection (14).The aim of the present study was to further examine the genetic variability of 5′ UTR sequences from field isolates, to assess the potential impact of nucleotide variations on IRES activity by using validated techniques, and to search for a relationship with disease severity by comparing isolates obtained from patients with benign or fulminant forms of hepatitis A.     

Functional Dissection of the Conjugative Coupling Protein TrwB

The conjugative coupling protein TrwB is responsible for connecting the relaxosome to the type IV secretion system during conjugative DNA transfer of plasmid R388. It is directly involved in transport of the relaxase TrwC, and it displays an ATPase activity probably involved in DNA pumping. We designed a conjugation assay in which the frequency of DNA transfer is directly proportional to the amount of TrwB. A collection of point mutants was constructed in the TrwB cytoplasmic domain on the basis of the crystal structure of TrwBΔN70, targeting the nucleotide triphosphate (NTP)-binding region, the cytoplasmic surface, or the internal channel in the hexamer. An additional set of transfer-deficient mutants was obtained by random mutagenesis. Most mutants were impaired in both DNA and protein transport. We found that the integrity of the nucleotide binding domain is absolutely required for TrwB function, which is also involved in monomer-monomer interactions. Polar residues surrounding the entrance and inside the internal channel were important for TrwB function and may be involved in interactions with the relaxosomal components. Finally, the N-terminal transmembrane domain of TrwB was subjected to random mutagenesis followed by a two-hybrid screen for mutants showing enhanced protein-protein interactions with the related TrwE protein of Bartonella tribocorum. Several point mutants were obtained with mutations in the transmembranal helices: specifically, one proline from each protein may be the key residue involved in the interaction of the coupling protein with the type IV secretion apparatus.Bacterial conjugation can be viewed mechanistically as a rolling-circle replication system linked to a type IV secretion process. The two processes come into contact through the activity of a protein that couples the plasmid replication machinery to the export system in the membrane, allowing horizontal dissemination of the replicating DNA molecule (35). This key protein is called “coupling protein” (here “T4CP” for “type IV CP”). It is present in all conjugative systems as well as in many type IV secretion systems (T4SS) involved in bacterial virulence (16). The secreted substrate in bacterial conjugation is the relaxase or pilot protein, attached to the DNA strand. The shoot-and-pump model for bacterial conjugation proposes that, after secretion of the protein through the T4SS, the T4CP works as a motor for export of the rest of the DNA molecule (36). In addition to its presumed role as a DNA transporter, TrwB is also required for transport of relaxase TrwC in the absence of DNA transfer (15).In accordance with its proposed coupling activity, early genetic experiments made patent that the function of conjugative T4CPs depended on interactions with both the cytoplasmic substrate complex (the relaxosome) and the T4SS (6, 7). Thus, T4CP interactions with other conjugation proteins are a key aspect of their function. There have been several reports of interactions between T4CPs from conjugative plasmids and either relaxosomal components—such as F-TraD with TraM (14, 38), RP4-TraG with TraI (49), and pCF10-PcfC with PcfF and PcfG (11)—or T4SS components such as R27-TraG with TrhB (17). T4CP-T4SS interactions have also been reported for the VirB/D4 T4SS involved in DNA transfer from Agrobacterium tumefaciens to plant cells (1, 9). Both sets of interactions have only been concurrently shown for TrwB, the T4CP of plasmid R388. TrwB interacts with proteins TrwA and TrwC, which form the R388 relaxosome, and with the R388 T4SS component TrwE (37). While the interaction with the relaxosome is highly specific for its cognate system (24, 37, 48), the interaction between the T4CP and the T4SS is less specific: a single T4CP can interact functionally with several conjugative T4SS. Interestingly, a correlation was observed between the strength of the T4CP-TrwE-like interaction and the efficiency of DNA transfer (37). T4CPs also interact with TrwE-like components of T4SS involved in virulence (13). In the case of the highly related Trw T4SS systems of plasmid R388 and the human pathogen Bartonella, it was further demonstrated that R388 TrwE could be functionally replaced by the Bartonella tribocorum TrwE homolog, TrwE_Bt (13).T4CPs are integral membrane proteins anchored to the inner membrane by an N-terminal transmembrane domain (TMD). The soluble cytoplasmic domain of TrwB (TrwBΔN70), lacking this TMD, has been biochemically and structurally analyzed in detail. It retains the ability to bind NTPs and to unspecifically bind DNA (42). The characterization of its DNA-dependent ATPase activity (53) strengthened the possibility that T4CPs work as DNA motors. This activity is also stimulated by the oriT-binding protein TrwA (52).The determination of the three-dimensional (3D) structure of TrwBΔN70 indicated a quaternary structure consisting of hexamers that form an almost spherical, orange-shaped structure with a 20-Å inner channel (ICH) (18, 19). Each monomer is composed of two main structural domains: the nucleotide-binding domain (NBD) and the all-alpha domain (AAD). The NBD has α/β topology and is reminiscent of RecA and DNA ring helicases. The AAD is facing the cytoplasmic side and bears significant structural similarity to the N-terminal domain of site-specific recombinase XerD and also to a 40-residue segment of the DNA binding domain of protein TraM, the component of the relaxosome of F-like plasmids that interacts with its cognate T4CP, TraD. The structure of the hexamer as a whole resembles that of the F₁-ATPase, raising interesting perspectives into the possible way of action of coupling proteins as molecular motors in conjugation (5).There have been several attempts to functionally dissect T4CPs. In F-TraD, it was determined that its C terminus is essential for relaxosomal specificity, probably through an interaction with TraM (4, 39, 48). The cytoplasmic domain of the related TraD protein of plasmid R1 stimulates both transesterase and helicase activities of its cognate relaxase, TraI (41, 51). A series of random mutations were shown to affect TraD oligomerization (23). In VirD4, the T4CP of the VirB T4SS of A. tumefaciens, both the periplasmic domain plus key residues of the NBD are required for its location at the cell poles (31); its interaction with the T4SS protein substrate VirE2 does not require the N-terminal TMD (2). Mutational analysis of R27 TraG showed that the periplasmic residues are essential for interaction with the T4SS (22). An N-terminal deletion variant of PcfC, the T4CP of the Enterococcus plasmid pCF10, loses its membrane localization but retains its ability to bind relaxosomal components (11). Biochemical analysis of full-length R388 TrwB showed that the N-terminal TMD stabilizes the protein, aids oligomerization, and affects nucleotide selection (25-27). This region is essential for T4SS interaction, but TrwBΔN70 retains the ability to interact with the relaxosomal components TrwA and TrwC (37). Taken together, these analyses suggested that the N-terminal TMD of the T4CPs is necessary for T4SS interaction, oligomerization, and cellular location and that the C-terminal cytoplasmic domain is necessary for relaxosomal interactions and ATPase activity associated with DNA transport.In this study, we set up different assays to search for mutants affecting TrwB function in DNA and protein transfer. We constructed a series of TrwB point mutants based on the 3D structure of TrwBΔN70. Most selected residues were essential for TrwB function in conjugation, especially under conditions where TrwB was in limiting quantities. We analyzed the in vivo properties of selected mutants with a battery of in vivo assays to map functional domains. Also, random mutants in the TMD were screened for improved interactions with the T4SS, which allowed mapping of the TrwB-TrwE interaction domain.     

Erratum to: How do UV radiation, temperature, and zooplankton influence the dynamics of alpine phytoplankton communities?

Plankton in mountain lakes are confronted with generally higher levels of incident ultraviolet radiation (UVR), lower temperatures, and shorter growing seasons than their lower elevation counterparts. The direct inhibitory effects of high UVR and low temperatures on montane phytoplankton are widely recognized. Yet little is known about the indirect effects of these two abiotic factors on phytoplankton, and more specifically whether they alter zooplankton grazing rates which may in turn influence phytoplankton. Here, we report the results of field microcosm experiments that examine the impact of temperature and UVR on phytoplankton growth rates and zooplankton grazing rates (by adult female calanoid copepods). We also examine consequent changes in the absolute and relative abundance of the four dominant phytoplankton species present in the source lake (Asterionella formosa, Dinobryon sp., Discostella stelligera, and Fragilaria crotonensis). All four species exhibited higher growth rates at higher temperatures and three of the four species (all except Dinobryon) exhibited lower growth rates in the presence of UVR versus when shielded from UVR. The in situ grazing rates of zooplankton had significant effects on all species except Asterionella. Lower temperatures significantly reduced grazing rates on Fragilaria and Discostella, but not Dinobryon. While UVR had no effect on zooplankton grazing on any of the four species, there was a significant interaction effect of temperature and UVR on zooplankton grazing on Dinobryon. Discostella and Dinobryon increased in abundance relative to the other species in the presence of UVR. Colder temperatures, the presence of zooplankton, and UVR all had consistently negative effects on rates of increase in overall phytoplankton biomass. These results demonstrate the importance of indirect as well as direct effects of climate forcing by UVR and temperature on phytoplankton community composition in mountain lakes, and suggest that warmer climates and higher UVR levels may favor certain species over others.     

Game Vertebrate Densities in Hunted and Nonhunted Forest Sites in Manu National Park,Peru

Manu National Park of southern Peru is one of the most renowned protected areas in the world, yet large-bodied vertebrate surveys conducted to date have been restricted to Cocha Cashu Biological Station, a research station covering <0.06 percent of the 1.7 Mha park. Manu Park is occupied by >460 settled Matsigenka Amerindians, 300–400 isolated Matsigenka, and several, little-known groups of isolated hunter–gatherers, yet the impact of these native Amazonians on game vertebrate populations within the park remains poorly understood. On the basis of 1495 km of standardized line-transect censuses, we present density and biomass estimates for 23 mammal, bird, and reptile species for seven lowland and upland forest sites in Manu Park, including Cocha Cashu. We compare these estimates between hunted and nonhunted sites within Manu Park, and with other Neotropical forest sites. Manu Park safeguards some of the most species-rich and highest biomass assemblages of arboreal and terrestrial mammals ever recorded in Neotropical forests, most likely because of its direct Andean influence and high levels of soil fertility. Relative to Barro Colorado Island, seed predators and arboreal folivores in Manu are rare, and generalist frugivores specializing on mature fruit pulp are abundant. The impact of such a qualitative shift in the vertebrate community on the dynamics of plant regeneration, and therefore, on our understanding of tropical plant ecology, must be profound. Despite a number of external threats, Manu Park continues to serve as a baseline against which other Neotropical forests can be gauged. Abstract in Spanish is available at http://www.blackwell-synergy.com/loi/btp .     

Cytokine release of human NK cells solely triggered with Poly I:C

Natural killer (NK) cells play a crucial role in innate immunity as effectors against tumor cells and pathogen-infected cells. Our data show for the first time that NK cells produce high levels of cytokines interferon-γ (IFN-γ), tumor necrosis factor-α (TNF-α) and interleukin-6 (IL-6) in response to stimulation with the artificial RNA analogue Poly I:C without additional cytokines or contact to other types of immune cells. An incubation period of 48 h is necessary to induce cytokine release by Poly I:C. These data suggest Poly I:C as a competent direct activator and immunomodulator of NK cell functions.     

Structure–function relationships of the antigenicity of mycolic acids in tuberculosis patients

Cell wall mycolic acids (MA) from Mycobacterium tuberculosis (M.tb) are CD1b presented antigens that can be used to detect antibodies as surrogate markers of active TB, even in HIV coinfected patients. The use of the complex mixtures of natural MA is complicated by an apparent antibody cross-reactivity with cholesterol. Here firstly we report three recombinant monoclonal scFv antibody fragments in the chicken germ-line antibody repertoire, which demonstrate the possibilities for cross-reactivity: the first recognized both cholesterol and mycolic acids, the second mycolic acids but not cholesterol, and the third cholesterol but not mycolic acids. Secondly, MA structure is experimentally interrogated to try to understand the cross-reactivity. Unique synthetic mycolic acids representative of the three main functional classes show varying antigenicity against human TB patient sera, depending on the functional groups present and on their stereochemistry. Oxygenated (methoxy- and keto-) mycolic acid was found to be more antigenic than alpha-mycolic acids. Synthetic methoxy-mycolic acids were the most antigenic, one containing a trans-cyclopropane apparently being somewhat more antigenic than the natural mixture. Trans-cyclopropane-containing keto- and hydroxy-mycolic acids were also found to be the most antigenic among each of these classes. However, none of the individual synthetic mycolic acids significantly and reproducibly distinguished the pooled serum of TB positive patients from that of TB negative patients better than the natural mixture of MA. This argues against the potential to improve the specificity of serodiagnosis of TB with a defined single synthetic mycolic acid antigen from this set, although sensitivity may be facilitated by using a synthetic methoxy-mycolic acid.     

Sphingolipid topology and the dynamic organization and function of membrane proteins

When acquiring internal membranes and vesicular transport, eukaryotic cells started to synthesize sphingolipids and sterols. The physical differences between these and the glycerophospholipids must have enabled the cells to segregate lipids in the membrane plane. Localizing this event to the Golgi then allowed them to create membranes of different lipid composition, notably a thin, flexible ER membrane, consisting of glycerolipids, and a sturdy plasma membrane containing at least 50% sphingolipids and sterols. Besides sorting membrane proteins, in the course of evolution the simple sphingolipids obtained key positions in cellular physiology by developing specific interactions with (membrane) proteins involved in the execution and control of signaling. The few signaling sphingolipids in mammals must provide basic transmission principles that evolution has built upon for organizing the specific regulatory pathways tuned to the needs of the different cell types in the body.