Blockade of endogenous ligands of trkB inhibits formation of ocular dominance columns

We have examined the hypothesis that the segregation of LGN axon terminals into ocular dominance (OD) patches in layer 4 of the visual cortex requires neurotrophins, acting as signals to modulate the pattern of synaptic connectivity. Neurotrophin receptor antagonists, composed of the extracellular domain of each member of the trk family of neurotrophin receptors fused to a human Fc domain, were infused directly into visual cortex during the peak phase of OD column formation. Infusion of trkB-IgG, which binds BDNF and NT-4/5, inhibited the formation of OD patches within layer 4, while trkA-IgG and trkC-IgG, which preferentially bind NGF and NT-3, respectively, had no effect. The autoradiographic labeling of LGN terminals in cortical layer 4 was reduced by trkB-IgG, in contrast with the increased labeling observed following NT-4/5 infusion. These data suggest that an endogenous ligand of trkB, normally present in limiting amounts within visual cortex, is necessary for the selective growth and remodeling of LGN axons into eye-specific patches.

Changing patterns of expression and subcellular localization of TrkB in the developing visual system

Neurotrophins play important roles in the survival, differentiation, and maintenance of CNS neurons. To begin to investigate specific roles for these factors in the mammalian visual system, we have examined the cellular localization of the neurotrophin receptor trkB within the developing cerebral cortex and thalamus of the ferret using extracellular domain-specific antibodies. At prenatal ages (gestation is 41 d), trkB-immunostained fibers were observed in the internal capsule and as two distinct fascicles within the intermediate zone of the cerebral cortex. The staining of these fiber tracts declined with increasing age, whereas soma and dendrite staining of cortical neurons was first evident in early postnatal life and increased during subsequent development. Staining of subplate neurons [by prenatal day 5 (P5)] was followed by staining of cortical layer 5 neurons (at P10). By P31, trkB immunoreactivity was particularly prominent in layers 3 and 5 but was absent from subplate neurons. Staining included cells, especially pyramidal neurons, in all cortical layers by P45, and this pattern was maintained into adulthood. The optic tract and fibers within the lateral geniculate nucleus (LGN) were also strongly trkB immunoreactive at prenatal ages. Cellular staining of a subset of LGN neurons, those within the C-layers and perigeniculate nucleus, was apparent by P10 and maintained until P45, when the adult pattern of highly trkB-immunoreactive neurons in all layers of the LGN first appeared. The pattern of trkB immunoreactivity suggests that specific subsets of cortical and thalamic neurons may respond to neurotrophins such as brain-derived neurotrophic factor and/or NT-4/5 at discrete developmental times and locations. The appearance of trkB on axon fibers early in development and then on cell bodies and dendritic processes later is consistent with roles for both long-range and local, including autocrine and/or paracrine, delivery of neurotrophins in cell survival and maturation.

Inhibition of ocular dominance column formation by infusion of NT-4/5 or BDNF

During the development of the visual system of higher mammals, axons from the lateral geniculate nucleus (LGN) become segregated into eye-specific patches (the ocular dominance columns) within their target, layer 4 of the primary visual cortex. This occurs as a consequence of activity-dependent synaptic competition between axons representing the two eyes. The possibility that this competition could be mediated through neurotrophin-receptor interactions was tested. Infusion of neurotrophin-4/5 (NT-4/5) or brain-derived neurotrophic factor (BDNF) into cat primary visual cortex inhibited column formation within the immediate vicinity of the infusion site but not elsewhere in the visual cortex. Infusion of nerve growth factor, neurotrophin 3 (NT-3), or vehicle solution did not affect column formation. These observations implicate TrkB, the common receptor for BDNF and NT-4/5, in the segregation of LGN axons into ocular dominance columns in layer 4. Moreover, they suggest that in addition to their better known roles in the prevention of cell death, neurotrophins may also mediate the activity-dependent control of axonal branching during development of the central nervous system.

Regulation of neurotrophin receptors during the maturation of the mammalian visual system

Cell division, cell death, and remodeling of connections are major features of the construction of the mammalian CNS. We have begun to address the role of neurotrophins in these events through characterization of the expression of their receptors in the developing ferret visual system. By use of chemical cross-linking of iodinated neurotrophins, proteins corresponding to trkB, trkC, and p75 were identified as receptors for brain-derived neurotrophic factor (BDNF) and neurotrophin-3 (NT-3) throughout development. BDNF was also cross-linked to a truncated form of trkB that lacks the tyrosine kinase domain (trkB. T1) in retinal target tissues and in cortex. At the earliest developmental age examined (E24), the ratio of full-length to truncated trkB is > > 1 in the retinal target tissues, LGN and superior colliculus. During the ensuing period of retinal ganglion cell death and segregation into eye-specific layers, the amount of truncated trkB increases markedly relative to full-length trkB. By P27, truncated trkB is the predominant receptor for BDNF in the retinal target tissues and this pattern is maintained into adulthood. Within all subdivisions of visual cortex including the ventricular zone (VZ), intermediate zone (IZ), and cortical plate (CP), similar profiles of bands are observed. The developmental increase in abundance of truncated trkB relative to full-length occurs earliest in the VZ, with a major increase between E30 and P3. In the IZ, this shift to a predominance of truncated trkB occurs between P15 and P30, while in the CP the shift is even further delayed, not occurring until after P30. Within each subdivision of cortex, the shift to a predominance of truncated trkB occurs at times that correlate with the onset of cell death and maturation of axonal connections. This study demonstrates that members of the trk family, previously identified in the CNS on the basis of mRNA transcripts, are present as receptors with specific binding affinities for BDNF and NT-3. Moreover, the correspondence between the developmental shift from full-length to truncated trkB and the critical periods for cell fate determination, cell death, and axonal remodeling suggests an important role for neurotrophic factors in the development of the visual system.

Characterization of membrane-associated and soluble states of SecA protein from wild-type and SecA51(TS) mutant strains of Escherichia coli

The subcellular localization of SecA, a protein essential for the catalysis of general protein export, was studied to better understand its state(s) and function(s) within Escherichia coli cells. In a wild-type strain approximately half of the cellular SecA content was found to be associated with the inner membrane, while the remainder was soluble. Association of SecA protein with the inner membrane required the presence of anionic phospholipids and was modulated by ATP. A fraction of the membrane-bound SecA was found to be integrally associated with the membrane. In the secA51(Ts) mutant 75-95% of SecA protein was found to be membrane associated, independent of the protein export status of the cell, implying that the partitioning of this protein between the cell membrane and cytoplasm may play an important role in its function. secA-lacZ fusions were used to map a membrane association determinant to the amino-terminal quarter of SecA protein sequence. When this portion of SecA protein was expressed within cells, it was found solely in membrane fractions and complemented the growth and protein secretion defect of the secA51(Ts) mutant. This indicates that the membrane is the site of the limiting defect in this mutant and suggests that either SecA functions can be divided into at least two separable activities or that productive interaction between SecA and the amino-terminal fragment can occur in vivo.

Azide-resistant mutants of Escherichia coli alter the SecA protein, an azide-sensitive component of the protein export machinery

Escherichia coli azi mutants, whose growth is resistant to millimolar concentrations of sodium azide, were among the earliest E. coli mutants isolated. Genetic complementation, mapping, and DNA sequence analysis now show that these mutations are alleles of the secA gene, which is essential for protein export across the E. coli plasma membrane. We have found that sodium azide is an extremely rapid and potent inhibitor of protein export in vivo and that azi mutants are more resistant to such inhibition. Furthermore, SecA-dependent in vitro protein translocation and ATPase activities are inhibited by sodium azide, and SecA protein prepared from an azi mutant strain is more resistant to such inhibition. These studies point to the utility of specific inhibitors of protein export, such as sodium azide, in facilitating the dissection of the function of individual components of the protein export machinery.

SecA protein: autoregulated initiator of secretory precursor protein translocation across the E. coli plasma membrane

Several classes of secA mutants have been isolated which reveal the essential role of this gene product for E. coli cell envelope protein secretion. SecA-dependent, in vitro protein translocation systems have been utilized to show that SecA is an essential, plasma membrane-associated, protein translocation factor, and that SecA's ATPase activity appears to play an essential but as yet undefined role in this process. Cell fractionation studies suggested that SecA protein is in a dynamic state within the cell, occurring in soluble, peripheral, and integral membraneous states. These data have been used to argue that SecA is likely to promote the initial insertion of secretory precursor proteins into the plasma membrane in a manner dependent on ATP hydrolysis. The protein secretion capability of the cell has been shown to translationally regulate secA expression with SecA protein serving as an autogenous repressor, although the exact mechanism and purpose of this regulation need to be defined further.

SecA protein is required for secretory protein translocation into E. coli membrane vesicles

The soluble and membrane components of an E. coli in vitro protein translocation system prepared from a secA amber mutant, secA13[Am], contain reduced levels of SecA and are markedly defective in both the cotranslational and posttranslational translocation of OmpA and alkaline phosphatase into membrane vesicles. Moreover, the removal of SecA from soluble components prepared from a wild-type strain by passage through an anti-SecA antibody column similarly abolishes protein translocation. Translocation activity is completely restored by addition of submicrogram amounts of purified SecA protein, implying that the observed defects are solely related to loss of SecA function. Interestingly, the translocation defect can be overcome by reconstitution of SecA into SecA-depleted membranes, suggesting that SecA is an essential, membrane-associated translocation factor.

Evaluation of the negative cooperativity model for fat cell beta-adrenergic receptors

Cooperative site-to-site interactions among beta-adrenergic receptors of fat cell membranes are probed with the potent beta-adrenergic antagonist (-)-[3H]dihydroalprenolol according to the kinetic method of De Meyts et al. (De Meyts, P., Roth, J., Neville, Jr., D.M., Gavin, III, J.R., and Lesniak, M.A. (1973) Biochem. Biophys. Res. Commun. 55, 154--161). Dissociation of specific (-)-[3H]dihydroalprenolol binding from fat cell membranes following a 100-fold dilution was rapid at 37 degrees C; only 40% of the initial equilibrium binding remained 30 s after dilution. Dissociation of (-)-[3H]dihydroalprenolol bound under conditions yielding approximately 20% initial occupancy was performed in the absence and in the presence of a large molar excess of beta-adrenergic agonist ((-)-isoproterenol) or beta-adrenergic antagonist ((-)-alprenolol or (-)-propanalol). Neither agonists nor antagonists influenced the rate of (-)-[3H]dihydroalprenolol dissociation from fat cell membranes performed at 4, 22 or 37 degrees C. Although analysis of the steady-state binding of (-)-[3H]dihydroalprenolol to fat cell membranes yields Hill coefficients, nH, less than 1.0, the present study indicates that these fat cell beta-adrenergic receptors display no cooperative site-to-site interactions.