Role of epididymal receptor HE6 in the regulation of sperm microenvironment.

HE6 (GPR64) is a highly conserved, tissue-specific heptahelical receptor of the human epididymis. The seven transmembrane (TM7) domains are a hallmark of G-protein-coupled receptors (GPCRs) which have a proven history of being excellent therapeutic targets. Of all currently marketed drugs, >30% are modulators of specific heptahelical receptors, emphasizing the potential of HE6 as a target for pharmaceutical intervention. Targeted mutation of the mouse HE6 counterpart resulted in male infertility, further emphasizing its role as a candidate target for male contraception. However, the precise function of HE6, together with its potential ligand(s), and signal transduction pathways have remained largely unknown. On the basis of shared sequence motifs within the TM7 region, HE6 has been grouped into the B class of GPCRs. Within this class, HE6 belongs to the 'large N-termini' family-B seven-transmembrane (LNB-TM7) receptors, also termed the adhesion-GPCRs. Members of this subgroup are 'orphan' receptors, and they all seem to be cleaved within a conserved GPCR proteolytic site (GPS) domain. The biological significance of the two-subunit architecture is still unknown. Clues to the function of HE6 within the epithelium of male excurrent ducts may come from its co-localisation with the apical actin cytoskeleton and from the down-regulation in "knockout" male mice of various proteins specific to the initial segment.

Microtubule oscillations. Role of nucleation and microtubule number concentration.

Microtubules are capable of performing synchronized oscillations of assembly and disassembly which has been explained by reaction mechanisms involving tubulin subunits, oligomers, microtubules, and GTP. Here we address the question of how microtubule nucleation or their number concentration affects the oscillations. Assembly itself requires a critical protein concentration (Cc), but oscillations require in addition a critical microtubule number concentration (CMT). In spontaneous assembly this can be achieved with protein concentrations Cos well above the critical concentration Cc because this enhances the efficiency of nucleation. Seeding with microtubules can either generate oscillations or suppress them, depending on how the seeds alter the effective microtubule number concentration. The relative influence of microtubule number and total protein concentrations can be varied by the rate at which assembly conditions are induced (e.g. by a temperature rise): Fast T-jumps induce oscillations because of efficient nucleation, slow ones do not. Oscillations become damped for several reasons. One is the consumption of GTP, the second is a decrease in microtubule number, and the third is that the ratio of microtubules in the two phases (growth-competent and shrinkage-competent) approach a steady state value. This ratio can be perturbed, and the oscillations restarted, by a cold shock, addition of seeds, addition of GTP, or fragmentation. Each of these is equivalent to a change in the effective microtubule number concentration.