Monoclonal antibodies incorporated into Neotyphodium coenophialum fungal cultures: inhibition of fungal growth and stability of antibodies.

Three monoclonal antibodies (mAbs) produced against proteins from the tall fescue (Festuca arundinacea Schreb.) fungal endophyte Neotyphodium coenophialum hybridize exclusively to a fungal protein under denaturing conditions. The protein is approximately 88 kDa in size. These mAbs were individually incorporated into liquid medium to determine their effects on fungal growth in culture. Neotyphodium-specific mAbs inhibited fungal growth for the duration of the study. Fungal cultures grown in the presence of Neotyphodium-naive mAbs or in the absence of all mAbs grew unimpeded. Bright-field microscopy and immunohistochemical studies of cultures containing Neotyphodium-specific mAbs revealed a change in mycelia morphology with clumps exhibiting a gelatinous matrix containing sparse hyphae, while cultures receiving Neotyphodium-naive mAbs in medium demonstrated unrestricted growth with overlapping and branched hyphae. In liquid culture devoid of fungal isolates, mAbs were stable and detected throughout the experiment, but were below threshold detection levels within 15 min following inclusion in liquid cultures containing Neotyphodium spp., indicating rapid binding to fungal mycelia. Monoclonal antibodies may provide a new method to help control plant pathogenic fungi where chemical or genetic means are not feasible.

The plant kinetochore.

Kinetochores are large protein complexes that bind to centromeres. By interacting with microtubules and their associated motor proteins, kinetochores both generate and regulate chromosome movement. Kinetochores also function in the spindle checkpoint; a surveillance mechanism that ensures that metaphase is complete before anaphase begins. Although the ultrastructure of plant kinetochores has been known for many years, only recently have specific kinetochore proteins been identified. The recent data indicate that plant kinetochores contain homologs of many of the proteins implicated in animal and fungal kinetochore function, and that the plant kinetochore is a redundant structure with distinct biochemical subdomains.

A maize homolog of mammalian CENPC is a constitutive component of the inner kinetochore.

Genes for three maize homologs (CenpcA, CenpcB, and CenpcC) of the conserved kinetochore assembly protein known as centromere protein C (CENPC) have been identified. The C-terminal portion of maize CENPC shares similarity with mammalian CENPC and its yeast homolog Mif2p over a 23-amino acid region known as region I. Immunolocalization experiments combined with three-dimensional light microscopy demonstrated that CENPC is a component of the kinetochore throughout interphase, mitosis, and meiosis. It is shown that sister kinetochore separation occurs in two discrete phases during meiosis. A partial separation of sister kinetochores occurs in prometaphase I, and a complete separation occurs in prometaphase II. CENPC is absent on structures known as neocentromeres that, in maize, demonstrate poleward movement but lack other important features of centromeres/kinetochores. CENPC and a previously identified centromeric DNA sequence interact closely but do not strictly colocalize on meiotic chromosomes. These and other data indicate that CENPC occupies an inner domain of the maize kinetochore.

Neocentromere-mediated chromosome movement in maize.

Neocentromere activity is a classic example of nonkinetochore chromosome movement. In maize, neocentromeres are induced by a gene or genes on Abnormal chromosome 10 (Ab10) which causes heterochromatic knobs to move poleward at meiotic anaphase. Here we describe experiments that test how neocentromere activity affects the function of linked centromere/kinetochores (kinetochores) and whether neocentromeres and kinetochores are mobilized on the spindle by the same mechanism. Using a newly developed system for observing meiotic chromosome congression and segregation in living maize cells, we show that neocentromeres are active from prometaphase through anaphase. During mid-anaphase, normal chromosomes move on the spindle at an average rate of 0.79 micron/min. The presence of Ab10 does not affect the rate of normal chromosome movement but propels neocentromeres poleward at rates as high as 1.4 micron/min. Kinetochore-mediated chromosome movement is only marginally affected by the activity of a linked neocentromere. Combined in situ hybridization/immunocytochemistry is used to demonstrate that unlike kinetochores, neocentromeres associate laterally with microtubules and that neocentromere movement is correlated with knob size. These data suggest that microtubule depolymerization is not required for neocentromere motility. We argue that neocentromeres are mobilized on microtubules by the activity of minus end-directed motor proteins that interact either directly or indirectly with knob DNA sequences.