Lactoferrin and host defense.

Lactoferrin is a multifunctional member of the transferrin family of nonheme iron-binding glycoproteins. Lactoferrin is found at the mucosal surface where it functions as a prominent component of the first line of host defense against infection and inflammation. The protein is also an abundant component of the specific granules of neutrophils and can be released into the serum upon neutrophil degranulation. While the iron-binding properties were originally believed to be solely responsible for the host defense properties ascribed to lactoferrin, it is now known that other mechanisms contribute to the broad spectrum anti-infective and anti-inflammatory roles of this protein. In this article, current information on the functions and mechanism of action of lactoferrin are reviewed, with particular emphasis on the activities that contribute to this protein's role in host defense. In addition, studies demonstrating that lactoferrin inhibits allergen-induced skin inflammation in both mice and humans, most likely secondary to TNF-alpha (tumor necrosis factor alpha) production, are summarized. Collectively, these results suggest that lactoferrin functions as a key component of mammalian host defense at the mucosal surface.     

Modelling of the flows and partitioning of carbon and nitrogen in the holoparasite Cuscuta reflexa Roxb. and its host Lupinus albus L.: II. Flows between host and parasite and within the parasitized host

A recently developed empirically based modelling technique wasused to quantify uptake, flow and utilization of C and N inLupinus albus L., uninfected and parasitized by Cuscuta reflexaRoxb. plants over a 12 d period during flowering and early fruitsetting of the host. The modelling combined data on molar C:Nratios in host phloem and pressure-induced xylem sap, net incrementsof C and N in host and parasite plant parts and respiratorylosses of C. The modelling of the solute transfer between hostand Cuscuta was achieved by assuming non-specific intake fromthe xylem. The models predicted that Cuscuta derived 99.5% ofits carbon and 93.6% of its nitrogen demand from the host phloem.The overriding sink strength of the parasite diverted most ofthe basipetally translocated host assimilates and massivelycompeted with the host root and inhibited fruit setting. Carbonincorporation in Cuscuta consumed 56%, respiration 24% and secretionby extrafloral nectaries 1.8% of the current host photosynthate.Root respiration was inhibited by 59% and carbon was mobilizedfrom host root and leaves. Competition by the parasite for Nwas even more severe and Cuscuta incorporated nitrogen equalling223% of current fixation, but N₂ fixation of the host was severelyrestricted to 37%. Withdrawal of N from host phloem led to severelosses of N from leaves and the root and marked decreases inN concentration. It required massive xylem-to-phloem transferof N, because the xylem as the major supply route for N wasnot exploited substantially by Cuscuta. The results are discussedin relation to likely causes for parasite-induced pathogeniceffects, suggesting that Cuscuta affected the host adverselyby depriving it mainly of its nitrogen, but that causal to incipientnitrogen deficiency and restricted N2 fixation was the superiorsink potential of Cuscuta, which prevented adequate supply ofassimilates to the nodulated root. The dominating sink potentialof Cuscuta is compared with the similarly strong sink competitionexerted by fruits at the stage of seed filling in annual plants. Key words: Cuscuta reflexa, Lupinus albus, parasitism, carbon, nitrogen, phloem, xylem, transport     

Parasite host range and the evolution of host resistance

Parasite host range plays a pivotal role in the evolution and ecology of hosts and the emergence of infectious disease. Although the factors that promote host range and the epidemiological consequences of variation in host range are relatively well characterized, the effect of parasite host range on host resistance evolution is less well understood. In this study, we tested the impact of parasite host range on host resistance evolution. To do so, we used the host bacterium Pseudomonas fluorescens SBW25 and a diverse suite of coevolved viral parasites (lytic bacteriophage Φ2) with variable host ranges (defined here as the number of host genotypes that can be infected) as our experimental model organisms. Our results show that resistance evolution to coevolved phages occurred at a much lower rate than to ancestral phage (approximately 50% vs. 100%), but the host range of coevolved phages did not influence the likelihood of resistance evolution. We also show that the host range of both single parasites and populations of parasites does not affect the breadth of the resulting resistance range in a naïve host but that hosts that evolve resistance to single parasites are more likely to resist other (genetically) more closely related parasites as a correlated response. These findings have important implications for our understanding of resistance evolution in natural populations of bacteria and viruses and other host–parasite combinations with similar underlying infection genetics, as well as the development of phage therapy.     

Yaba virus-specific DNA in the host cell nucleus.

DNA-DNA hybridization studies show that Yaba virus-specific DNA is present in the host cell nucleus late in the infection cycle. The nuclear DNA appears to exist as a complete genome, not convalently linked to host cell DNA, as demonstrated by sedimentation analyses. The DNA apperas to be synthesized in the nucleus, since its level of incorporation of label is ten times the background incorporation detectable in the cytoplasm. Extraction of the nuclei by treatment with SDS and EDTA after precipitation with 1 M NaCl separates most of cellular DNA from the Yaba virus-specific DNA.     

Genetics of host response to malaria.

A comprehension of the genetics of host resistance to malaria is essential to understanding the complex host/parasite interaction. Current research is directed towards the genetic dissection of both the murine and human host responses to the disease. Significant progress has been made towards the mapping of novel murine resistance loci. In addition, the role of the major histocompatibility complex in the host response has been examined in both animal models and human populations. Several large segregation analyses, association studies and, more recently, linkage analyses have been conducted in different African populations to examine the role of host genetics in both mild and severe malaria. The results of these studies have been collated within this review. The cloning of genes involved in malarial resistance will lead not only to a greater understanding of this complex disease but, potentially, to the development of effective medical intervention.     

How the immune system protects the host from infection.

The immune system is made up of sets of interacting cells. The first to respond in all cases are the antigen-presenting cells (APCs), which are equipped with receptors for microbial patterns. Engagement of these receptors induces co-stimulatory molecules on the surface of the APCs, and allows it to stimulate potent CD4 T-cell responses, and also CD8 T-cell responses. This in turn leads to B-cell-derived antibody responses. The entire response is controlled by suppressor T cells, as predicted many years ago by Richard Gershon.     

土壤和植物对冬虫夏草寄主昆虫规模化饲养的影响

冬虫夏草大量人工培植的关键之一是寄主昆虫的规模化饲养,本文对西藏林芝地区冬虫夏草生境中不同土壤基质在室内对蝙蝠蛾幼虫生长的影响以及寄主幼虫对5种植物的取食行为、嗅觉反应进行了系统研究。结果表明蝙蝠蛾幼虫偏好土质疏松、渗透性好的土壤,土壤因子中湿度和有机质含量与蝙蝠蛾幼虫存活率成正相关。蝙蝠蛾3龄幼虫对适生地植物的取食选择性与嗅觉反应趋性顺序为鹅绒委陵菜>珠芽蓼>小大黄>圆穗蓼>羊角天麻;进一步Spearman相关分析显示,幼虫对各植物的选择系数与可溶性糖（R=0.850,P<0.05）和粗蛋白（R=0.898,P<0.05）都存在显著的正相关关系,而与粗纤维（R=-0.952,P<0.05）有着显著的负相关关系,与粗灰分（R=-0.391,P=0.516）之间没有显著的相关关系;取食鹅绒委陵菜、珠芽蓼后的幼虫单头虫重显著大于取食其他植物的幼虫。这一研究结果为冬虫夏草寄主昆虫规模化饲养提供了理论依据。     

寄主利它素对稻螟赤眼蜂寄生行为的影响

对稻螟赤眼蜂Trichogrammajaponicum(Ashmead)在寄主定位过程中所利用的寄主利它素的存在部位、作用方式及其应用效果作了初步研究。生测结果表明 :寄主利它素存在于三化螟Tryporyzaincertu las(Walker)卵块盖毛和成虫鳞片中 ,其中以盖毛中利它素含量最高 ,雌蛾鳞片次之 ,雄蛾鳞片含量最少。结果还表明盖毛在卵块上的完整性对稻螟赤眼蜂的寄主搜索行为有明显影响。室内应用效果表明利它素可以使稻螟赤眼蜂对寄主卵寄生率提高 1 0 %以上。     

A baseline model for the apparent competition between many host strains: the evolution of host resistance to microparasites.

The purpose of this article is to establish and analyse a baseline model for the apparent competition between many host strains attempting to avoid a uniform microparasitic population. The model is formulated and analysed using invasion criteria in the main text. The results are verified by more formal methods in the appendix. Cases in which the microparasite can invade are distinguished geometrically from those in which it cannot using threshold and strain composition conditions. A major result obtained when the pathogen persists is a competitive exclusion principle for host resistance. For non-lethal infections, the winning strain is that which affords the pathogen maximum threshold density; for possibly lethal infections, a somewhat generalized version of this criterion is presented and discussed. The tension is highlighted between these results and the baseline behaviour of many pathogen strains and a uniform host population-here the winning pathogen strain is that with minimum threshold density.     

Macrophages in host defence--an overview.

The importance of macrophages in host defence is well documented. They are distributed in various tissues where they perform functions in normal steady state as well as in diseased condition. Macrophages secrete a number of enzymes, plasma proteins, complement and coagulation factors which regulate the effector functions of the macrophages. Exposure of macrophages to pathogens results in further metabolic changes which activate the former to secrete oxygen metabolites leading to their augmented microbicidal activity. Macrophages respond to the external stimuli by expressing a large repertoire of surface receptors which play an important role in the activation, recognition and endocytosis of foreign microorganisms. A large number of intracellular pathogens are harboured in the macrophages which can reside and replicate in them. A variety of strategem has been employed to target drugs to vacuolar apparatus of the macrophages in order to combat intracellular pathogens. This review covers some of these aspects particularly in relation to hose defence and methods by which therapeutic agents could be specifically delivered to macrophages.     

The behaviour of the donor melanoblasts in the non-pigmented host embryos.

The behaviour of the donor melanoblasts from the leg bud mesoderm of Silver Campine implanted into White Leghorn embryos has been studied. Their schedule of migration from intracoelomic grafts to various parts of hosts is worked out. Different hypotheses for differentiation of grafted spherical melanoblasts in various tissues of hosts have been investigated.     

The morphology of green hydra endosymbionts as influenced by host strain and host environment.

The ultrastructure of Chlorella-like algal endosymbionts from the Florida and English strains of green hydra was compared under different host feeding and photoperiodic regimes. Under standard conditions (host fed daily, 12-h photoperiod) the algae from the 2 strains exhibited considerable differences. The English symbionts had a pyrenoid, compact chloroplast membranes and vesiculated polyphosphate bodies. By comparison, Florida symbionts lacked a pyrenoid, had chloroplasts with less compact membranes and exhibited spherical polyphosphate bodies. When maintained in the dark, algae from English hydra lost their pyrenoids, showed great compaction of the chloroplast and developed large, shield-shaped, electron-dense bodies. In contrast, algae from Florida hosts did not exhibit gross ultrastructural modification. Reciprocal cross-transfers of symbionts were made by placing Florida algae in English aposymbiotic (algal-free) hosts and vice versa. After residence in Florida hosts, English symbionts appeared to undergo ultrastructural modifications resulting in a morphology indistinguishable from the native Florida symbionts. Florida algae showed no modifications resulting from residence in English hosts. It thus appears that the English symbiont has great morphological plasticity, as its structure is greatly modified depending upon the host in which it resides and the conditions under which the host is maintained. The results of these studies are discussed and compared with published accounts of free-living Chlorella and with reports dealing with other Chlorella symbionts.