We are currently looking at the role that other kinesin genes play in both meiosis and mitosis. For example, ATK1 plants have no gross phenotype in sporophytic cells, but mitosis is a bit unusual. We are interested in knowing the mechanisms by which mitotic cells are able to escape the mutant phenotype even though their spindles are unusual.

Plant Mitosis
The ancestral function of mitosis is to segregate chromosomes and, like most other eukaryotes, plants use spindle microtubules to affect karyokinesis. However, there are some differences that are unique to plants (and some algae), which are notable. First, the assembly of the spindle is preceded by the formation of a cortical band of microtubules, termed the pre-prophase band. This band of microtubules has at least three functions: it positions the G2/prophase nucleus; it affects the polarity of the early spindle; it predicts the site of the future cell plate. We are using a stably transformed tobacco cell line, harboring a microtubule binding domain::Green Fluorescent Protein chimeric gene, to gain insight into the role the PPB plays in early mitosis. Using a dsRed::Golgi marker, we have shown that Golgi to accumulate at the PPB site, but that Golgi secretion is not involved in "marking" the PPB site for future cell plate positioning. Ongoing experiments are aimed at understanding how the PPB communicates with the nascent spindle and the nature of the "mark" that assigns the position for the future cell plate.

Cell Elongation
Cellular elongation is an important aspect of plant morphogenesis. Plants use the isotropic force of turgor to affect elongation by preferentially reinforcing their walls with cellulose microfibrils. Like hoops around a barrel, cellulose microfibrils constrain lateral growth while allowing the cell to elongate along an axis perpendicular to the aligned cellulose. Cortical microtubules play a role by somehow affecting the ordered deposition of nascent cellulose microfibrils.
The traditional textbook view of microtubules controlling the orientation of newly synthesized cellulose microfibrils is too simple. We now know that cellulose synthesis, itself, is required for the orientation of cortical microtubules. The available information is therefore consistent with the presence of cross-talk between cellulose microfibrils and cortical microtubules. In essence, the cortical microtubules, the plasma membrane, and the cellulose microfibrils comprise a functional continuum that acts to self-rectify the wall to insure proper elongation during plant growth.
The mechanistic details surrounding this continuum remain incompletely described. The lab is currently testing the hypothesis that biophysical forces, that arise as a consequence to growth, play a role in conveying this information. Microtubule alignment in growing epidermal tissues correlates with high (or accelerating growth rates), rather than deaccellerating growth rates. Thus, the biophysical signal may not be a simple first order strain sensor, rather one that responds in a second order fashion (i.e., an accelerometer).