How motor proteins influence microtubule polymerization dynamics.

The interplay between microtubules and microtubule-based motors is fundamental to basic aspects of cellular function, such as the intracellular transport of organelles and alterations in cellular morphology during cell locomotion and division. Motor proteins are unique in that they couple nucleotide hydrolysis to force production that can do work. The force transduction by proteins belonging to the kinesin and dynein superfamilies has been thought only to power movement of these motors along the surface of microtubules; however, a growing body of evidence, both genetic and biochemical, suggests that motors can also directly influence the polymerization dynamics of microtubules. For example, at the vertebrate kinetochore, motors interact directly with microtubule ends and modulate polymerization dynamics to orchestrate chromosome movements during mitosis. Although a role for motors in regulating microtubule length has been established, the mechanisms used by motors to promote microtubule growth or shrinkage are unclear, as is an understanding of why cells might choose motors to control dynamics rather than a variety of non-motor proteins known to affect microtubule stability. Elucidation of the exact mechanisms by which motors alter the exchange of tubulin subunits at microtubule ends in vitro may shed light on how microtubule stability is regulated to produce the array of dynamic behavior seen in cells.

The kinetochore of higher eucaryotes: a molecular view.

This review summarizes results concerning the molecular nature of the higher eucaryotic kinetochore. The first major section of this review includes kinetochore proteins whose general functions remain to be determined, precluding their entry into a discrete functional category. Many of the proteins in this section, however, are likely to be involved in kinetochore formation or structure. The second major section is concerned with how microtubule motor proteins function to cause chromosome movement. The microtubule motors dynein, CENP-E, and MCAK have all been observed at the kinetochore. While their precise functions are not well understood, all three are implicated in chromosome movement during mitosis. Finally, the last section deals with kinetochore components that play a role in the spindle checkpoint; a checkpoint that delays mitosis until all kinetochores have attached to the mitotic spindle. Brief reviews of kinetochore morphology and of an important technical breakthrough that enabled the molecular dissection of the kinetochore are also included.

Mitotic centromere-associated kinesin is important for anaphase chromosome segregation.

Mitotic centromere-associated kinesin (MCAK) is recruited to the centromere at prophase and remains centromere associated until after telophase. MCAK is a homodimer that is encoded by a single gene and has no associated subunits. A motorless version of MCAK that binds centromeres but not microtubules disrupts chromosome segregation during anaphase. Antisense-induced depletion of MCAK results in the same defect. MCAK overexpression induces centromere-independent bundling and eventual loss of spindle microtubule polymer suggesting that centromere-associated bundling and/or depolymerization activity is required for anaphase. Live cell imaging indicates that MCAK may be required to coordinate the onset of sister centromere separation.

Multiplex display polymerase chain reaction amplifies and resolves related sequences sharing a single moderately conserved domain.

We present a technique, multiplex display polymerase chain reaction (MD-PCR), that amplifies and resolves coding sequences from messenger RNAs sharing only a single moderately conserved domain encoding eight or nine amino acids. The technique, a form of single-sided PCR, allows detection of known and novel genes in a family by using one degenerate primer complementary to a gene family-specific domain. A second common primer is complementary to an oligonucleotide ligated to a nearby restriction enzyme cleavage site. Uniquely, restriction enzyme digestion of single-stranded cDNA, a technique never previously performed to useful advantage, is used to increase the specificity and sensitivity of the technique. Up to several hundred bases of coding sequence are amplified simultaneously from many (potentially from all) genes in a specific family, yielding products of different sizes from different genes, and allowing amplified products to be resolved electrophoretically. Typically, more than 50% of the amplified sequences are from the targeted gene family and many of the amplified products are novel sequences. mRNAs representing less than 1 in 100,000 messages can be detected. The method allows the focused yet open-ended examination of genes in families known to be important in both normal cellular homeostasis and the etiology of many diseases.

Widespread expression of beta1 integrins in the developing chick retina: evidence for a role in migration of retinal ganglion cells.

During extension of axons, critical neuronal interactions with extracellular matrix (ECM) and other cells are thought to be mediated in part by heterodimeric beta1 integrin receptors. In this report, we examine the expression and function of beta1 integrins in the developing chick retina. Expression of the beta1 subunit, assayed by in situ hybridization and antibody staining of dissociated cells, was widespread in undifferentiated neuroepithelial cells, before the initiation of axons. Expression persisted in most retinal cell layers throughout embryonic development, during and after axon extension. The repertoire of beta1-associated alpha subunits was examined using reverse transcription-polymerase chain reaction. In addition to the alpha6 and alpha8 subunits previously reported, chick homologues of the alpha2 and alpha4 subunits were detected. Developmental Northern blots revealed varying patterns of integrin subunit expression and showed that expression of beta1 and the mRNAs of its associated alpha subunits are not always coregulated during retinal development. The timing and distribution of expression suggested that beta1 integrins may be involved in other developmental events in addition to axon extension. To address functions carried out by beta1 integrins in the early retina, explanted eye cups were incubated in the presence of function blocking anti-beta1 antibody and migration of newly born retinal ganglion cells (RGCs) was assessed. RGC migration from the ventricular zone to the vitreal border was significantly inhibited, suggesting that beta1 integrins play a role in neuroblast migration in the retina.