Relationship of Bdellovibrio elongation and fission to host cell size.

The extent of Bdellovibrio growth, and hence progeny produced in infected cells, appears to depend upon host cell size as determined from the ratio of ultimitate length of Bdellovibrio to host cell area calculated from light microscopy.     

Growth of host dependent Bdellovibrio in host cell free system

A particulate, subcellular fraction of Escherichia coli was shown to promote the growth of host dependent (H-D) Bdellovibrio in the absence of host cells. The growth promoting activity was enhanced by both cations and trypsin, and destroyed by pronase. During the axenic growth unipolar spheres appear in the elongating Bdellovibrio forms. Thymidine monophosphate was more readily incorporated than thymidine into the Bdellovibrio DNA during growth in the host free system.     

Interactions between Toxoplasma gondii and its mammalian host cells

Toxoplasma is a protozoan parasite that is uniquely adapted for invading and surviving within a wide range of host cells. The parasite actively invades the cell, forming a novel vacuole that originates from the host cell plasma membrane. The vacuole membrane is rapidly modified to remove host cell proteins and this compartment subsequently resists fusion with all other host cell endocytic compartments. Shortly after invasion, the parasite secretes a variety of proteins by a process of regulation exocytosis and elaborates an extensive array of membranous tubules that form a network connecting with the vacuolar membrane. Understanding the formation and modification of this unique vacuole may reveal novel mechanisms for subverting host cell endocytic pathways that lead to intracellular survival.     

Interactions between Leishmania parasites and host cells.

Several species of protozoa belonging to the genus Leishmania are pathogenic for humans, causing visceral and cutaneous diseases. They are transmitted by phlebotomine sandflies as flagellated promastigotes to mammals hosts, where they live as aflagellated amastigotes mainly within macrophages. Studies performed on mice infected with Leishmania major demonstrated that host defence against this infection depends on the interleukin-12-driven expansion of the T helper 1 cell subset, with production of cytokines such as interferon-gamma, which activate macrophages for parasite killing through the release of nitric oxide. The parasitocidal role of this radical is now emerging also in the human and canine model. Healing or progression of the infection is related to the genetic and immune status of the host, and to the virulence of different species and strains of Leishmania. The parasite survival ultimately depends on the ability to evade the host immune response by several mechanisms. Among them, inhibition of the signal transduction pathway of the host cells is particularly important. In fact, promastigotes inhibit protein kinase C activation, cause Ca++ influx into the host cell and decrease the levels of myristoylated alanine-rich C kinase substrate-related proteins, which are substrates for PKC. In addition, Leishmania infection blocks IFN-gamma-induced tyrosine kinase phosphorylation, with consequent impairment of signalling for IL-12 and nitric oxide production. Finally, Leishmania activates protein phosphotyrosine phosphatases, which down-regulate mitogen-activated protein kinase signalling and c-fos and nitric oxide synthase expression. New pharmacological applications, including protein tyrosine phosphatase and protein farnesyltransferase inhibitors, are being evaluated against leishmaniosis in vitro and in vivo in the murine model.     

Interactions between encapsulated Neisseria meningitidis and host cells.

A major feature of Neisseria meningitidis is its ability to invade human brain meninges. To access the meninges, the bacteria must cross the blood-brain barrier (BBB), which is one of the tightest barriers in the body. Therefore, N. meningitidis must have evolved some type of sophisticated means to bypass the physical properties of this cellular barrier. As N. meningitidis is encapsulated when present in the bloodstream, this review will focus on the mechanisms that encapsulated N. meningitidis has developed to interact with host cells and will suggest ways in which these mechanisms may be helpful for crossing the BBB.     

Interactions between a seed-borne strain of cucumber mosaic cucumovirus and its lupin host

The relationship between time of inoculation with cucumber mosaic cucumovirus (CMV) and the growth, seed production and rate of seed transmission of virus in lupin (Lupinus angustifolius cv. Illyarrie) was studied in field-grown plants. Plants inoculated at the seedling stage (2 days post-emergence) showed 45% mortality. Plants infected through the seed were more stunted than plants inoculated at the seedling stage. Plants inoculated up to the mid-vegetative growth stage (58 days post-emergence) yielded ≤ 27% of the dry matter and ≤ 9% of the seed of healthy plants. Late inoculation (114 days post-emergence) did not affect dry matter yield, but reduced seed yield to 75% of that of healthy plants. Rate of seed transmission depended on the time of inoculation of plants. The maximum rate was 24.5% for plants that were inoculated at the mid-vegetative growth stage (58 days post-emergence). However, early inoculation caused a large reduction in seed yield, and it was shown that plants inoculated at the beginning of flowering (94 days post-emergence) produced greater numbers of infected progeny than plants inoculated at earlier or later times. No relationship was observed between seed weight and transmission of CMV. Infectious CMV was recovered from the embryo, but not from the testa. A simple seed transmission model was used to evaluate several hypothetical epidemics and to determine the time of inoculation which results in greatest rates of seed transmission of CMV. For example, when fewer than 73% of plants in a crop become infected with CMV, then the rate of transmission of virus in crop seeds will be greatest when inoculations are at the beginning of flowering.     

Interactions between Listeria monocytogenes and host mammalian cells

Bacterial pathogens have developed a variety of strategies to induce their own internalization into mammalian cells which are normally nonphagocytic. The Gram-positive bacterium Listeria monocytogenes enters into many cultured cell types using two bacterial surface proteins, InlA (internalin) and InlB. In both cases, entry takes place after engagement of a receptor and induction of a series of signaling events.     

Interactions of the malaria parasite and its mammalian host

A hallmark of Plasmodium development inside its mammalian victim is the remarkable restriction to the host species. Adaptation to an intracellular life style in specific target cells is determined by multiple parasite-host interactions. The first line of crosstalk occurs during intradermal sporozoite injection by an Anopheles mosquito. The following expansion in the liver is highly efficient and leads to successful establishment of the parasite population. During the periodic waves of fevers and chills the parasite destroys and re-infects red blood cells. Recent advances in experimental genetics and imaging techniques begin to expose the complex interactions at the changing parasite-host interfaces. Understanding the cellular and molecular mechanisms of target cell recognition, nutrient acquisition, and hijacking of cellular and immune functions may ultimately explain the elaborate biology of a medically important single cell eukaryote.     

Interactions between mycoplasma lipoproteins and the host immune system

Mycoplasmas typically have a number of distinct lipoproteins anchored on the outer face of the plasma membrane. These surface antigens have a potent modulin activity and are preferential targets of the host immune response. However, the variation of some of these lipoproteins provides mycoplasmas with an effective means of evading the host immune defence system.     

Interactions between Verticillium dahliae and its host: vegetative growth,pathogenicity, plant immunity

Verticillium dahliae is a soil-borne phytopathogenic fungus that causes vascular wilt diseases in a wide variety of crop plants, resulting in extensive economic losses. In the past 5 years, progress has been made in elaborating the interaction between this hemibiotrophic fungus and its host plants. Some genes responsible for the vegetative growth and/or pathogenicity in V. dahliae have been identified. Plants have accrued a series of defense mechanisms, including inducible defense signaling pathways and some resistant genes to combat V. dahliae infection. Here, we have reviewed the progress in V. dahliae–plant interaction research.     

Periplasmic enzymes in Bdellovibrio bacteriovorus and Bdellovibrio stolpii.

When cells of either Bdellovibrio bacteriovorus 109J or Bdellovibrio stolpii UKi2 were subjected to osmotic shock by treatment with sucrose-EDTA and MgCl2 solutions, only trace amounts of proteins or enzyme activities were released into the shock fluid. In contrast, when nongrowing cells were converted to motile, osmotically stable, peptidoglycan-free spheroplasts by penicillin treatment, numerous proteins were released into the suspending fluid. For both species, this suspending fluid contained substantial levels of 5'-nucleotidase, purine phosphorylase, and deoxyribose-phosphate aldolase. Penicillin treatment also released aminoendopeptidase N from B. bacteriovorus, but not from B. stolpii. Penicillin treatment did not cause release of cytoplasmic enzymes such as malate dehydrogenase. The data indicated that bdellovibrios possess periplasmic enzymes or peripheral enzymes associated with the cell wall complex. During intraperiplasmic bdellovibrio growth, periplasmic and cytoplasmic enzymes of the Escherichia coli substrate cell were not released upon formation of the spherical bdelloplast during bdellovibrio penetration. Most of the E. coli enzymes were retained within the bdelloplast until later in the growth cycle, when they became inactivated or released into the suspending buffer or both.     

Interactions of human retroviruses with the host cell cytoskeleton

As obligate cell parasites, viruses have evolved into professional manipulators of host cell functions. Accordingly, viruses often remodel the cytoskeleton of target cells in order to convert one of the cell's barriers to viral replication into a vehicle for the virus that facilitates the generation of infectious progeny. Surprisingly little is known about the mechanisms employed by two major human pathogens, HIV and human T-cell leukaemia virus (HTLV), to exploit host cell cytoskeletal dynamics. New studies have begun to unravel how these retroviruses remodel cytoskeletal structures to facilitate entry into, transport within and egress from target cells. Exciting progress has been made in understanding how HIV and HTLV polarize actin and also control microtubule organization to spread from donor to target cells in close cell-contacts termed virological synapses.     

Interactions and DNA transfer between Agrobacterium tumefaciens, the Ti-plasmid and the plant host.

Agrobacterium tumefaciens is a gram-negative bacterium with the unique capacity to induce neoplasmic transformations in dicotyledonous plants. Recently, both the mechanism and the biological significance of this transformation have been elucidated. Agrobacterium tumefaciens strains contain a large extrachromosomal DNA plasmid (the Ti-plasmid). This Ti-plasmid is responsible for the oncogenic properties of Agrobacterium strains. A particular segment of the Ti-plasmid, containing information determining the tumorous growth pattern and the synthesis of so-called 'opines', e.g. octopine (N-alpha-(D-1-carboxyethyl)-L-arginine) and nopaline (N-alpha-(1,3-dicarboxypropyl)-L-argine), is transferred and stably maintained and expressed in the transformed plant cells. This phenomenon can be understood as a 'genetic colonization' of the plant cells by bacterial plasmid DNA so that the transformed plant cells will produce and secrete into the medium amino acid derivatives (the opines) that Ti-plasmid carrying agrobacteria can selectively use as carbon and nitrogen sources.     

Cavity spot of carrots: Interactions between the host and pathogen, related to the cell wall

This study investigates the structural aspects of cavity spot pathogenesis. Different Pythium spp. isolated from infected carrots, apples and melons were cultured on agar in Petri dishes and used for inoculation of uninfected carrots. Only slow-growing Pythium spp. (< 15 mm day^-1), such as P. violae and P. sulcatum caused cavity spot lesions. It is suggested that slow-growing species are able to penetrate, albeit slowly, into the plant tissue for 3 to 4 days before a hypersensitive reaction develops. Fast-growing species, however, did not cause lesions. Based on ultrastructural observations, we suggest that the following sequence of events occurs between the plant and the pathogen: The fungus infects the walls and grows for several days, during which time small amounts of wall-degrading enzymes are secreted. Phenylalanine ammonia lyase (PAL) activity and phenols increase linearly immediately upon inoculation. There was a lag phase of about 5 days before lignin began to increase linearly for about a month. Dissolution of wall components decreases the solute potential and water potential in the apoplast. Thus, water moves from the symplast into the apoplast, the turgor pressure gradually dissipates, and the cells shrink and eventually die.