GABA(B) receptors mediate motility signals for migrating embryonic cortical cells.

During development, postmitotic neurons migrate from germinal regions into the cortical plate (cp), where lamination occurs. In rats, GABA is transiently expressed in the cp, near target destinations for migrating neurons. In vitro GABA stimulates neuronal motility, suggesting cp cells release GABA, which acts as a chemoattractant during corticogenesis. Pharmacological studies indicate GABA stimulates migration via GABA(B)-receptor (GABA(B)-R) activation. Using immunohistochemistry, RT-PCR and Western blotting, we examined embryonic cortical cell expression of GABA(B)-Rs in vivo. At E17, GABA(B)-R1(+) cells were identified in the ventricular zone (vz) and cp. RT-PCR and Western blotting demonstrated the presence of GABA(B)-R1a and GABA(B)-R1b mRNA and proteins. Using immuno- cytochemistry, GABA(B)-R expression was examined in vz and cp cell dissociates before and after migration to GABA in an in vitro chemotaxis assay. GABA-induced migration resulted in an increase of GABA(B)-R(+) cells in the migrated population. While <20% of each starting dissociate was GABA(B)-R(+), >70% of migrated cells were immunopositive. We used a microchemotaxis assay to analyze cp cell release of diffusible chemotropic factor(s). In vitro, cp dissociates induced vz cell migration in a cell density-dependent manner that was blocked by micromolar saclofen (a GABA(B)-R antagonist). HPLC demonstrated cp cells release micromolar levels of GABA and taurine in several hours. Micromolar levels of both molecules stimulated cell migration that was blocked by micromolar saclofen. Thus, migratory cortical cells express GABA(B)-Rs, cp cells release GABA and taurine, and both molecules stimulate cortical cell movement. Together these findings suggest GABA and/or taurine act as chemoattractants for neurons during rat cortical histogenesis via mechanisms involving GABA(B)-Rs.

Analysis of fractal dimension of O2A glial cells differentiating in vitro.

Fractal dimension is a quantitative measure of morphological complexity. Glial cells of the oligodendrocyte-type 2 astrocyte (O2A) lineage exhibit increasing morphological complexity as they differentiate in vitro. Enriched populations of O2A progenitor cells isolated from neonatal rat cerebral hemispheres or optic nerves were allowed to differentiate in vitro, and their fractal dimensions were measured over time. The fractal dimensions of the maturing cells correlated with perceived complexity; cells with elaborate process branching had larger fractal dimensions than cells with a simpler morphology. An analysis of changes in fractal dimension revealed distinct rates of growth for both oligodendrocytes and type 2 astrocytes. The fractal dimension remained constant over a 10-fold range in optical magnification, demonstrating that cultured O2A glial cells exhibit self-similarity, a defining characteristic of fractal objects. These results illustrate that fractal dimension analysis of maturing cell populations is a useful method for quantitatively describing the process of cell differentiation.

The expression of GAD67 isoforms in zebrafish retinal tissue changes over the light/dark cycle.

We show the levels of glutamic acid decarboxylase (GAD), the enzyme catalyzing the conversion of glutamic acid to GABA, changes in zebrafish retinal tissue during the light/dark cycle. Further, we identify two transcripts of the GAD67 gene, full-length GAD67 and the truncated 25 kDa alternative splice variant (ES), as the major GAD isoforms in this tissue. GAD-positive neurons were identified immunocytochemically by probing retinal sections with K2, an antibody to the GAD67 isoform, and with an antibody specific for the 25 kDa splice variant. For both antibodies, GAD-immunoreactivity was observed in horizontal cells in the distal retina and amacrine cells in the proximal retina, with both cell bodies and processes labeled. No apparent difference in K2 labeling pattern was observed in tissue harvested 8 hrs after light offset or onset, whereas ES label was identified in more structures in dark tissue. Quantification of GAD levels was determined by densitometry of Western Blots. The protein content of GAD67 and ES varied between tissue harvested during the light and the dark. ES expression was up-regulated in dark tissue; whereas, full-length GAD67 expression increased in light tissue. In vivo GABA content, measured with high performance liquid chromatography (HPLC), was found to increase in light tissue, paralleling the expression of full-length GAD67 transcripts. Expression of ES did not correlate with measured GABA levels, suggesting this isoform, which lacks the catalytic domain necessary for enzymatic activity, may have a different physiological role in retinal tissue. The inverse expression patterns of full-length GAD67 and ES suggest that alternative splicing of GAD67 may be triggered by the light and/or dark cycle, resulting in a change in inhibitory neurotransmitter content in retinal tissue.

GABA receptor antagonists modulate postmitotic cell migration in slice cultures of embryonic rat cortex.

Recent studies indicate that GABA acts as a chemoattractant during rat cortical histogenesis. In vivo, GABA localizes in appropriate locations for a chemoattractant, along migratory routes and near target destinations for migrating cortical neurons. In vitro, GABA induces dissociated embryonic cortical neurons to migrate. Here, embryonic rat cortical slices were cultured in the presence or absence of GABA receptor (GABA-R) antagonists to assess GABA's effects on neuronal migration in situ. Gestational day 18 (E18) cortical slices were incubated overnight in bromodeoxyuridine (BrdU)-containing medium to label ventricular zone (vz) cells as they underwent terminal mitosis. The slices were then cultured in BrdU-free medium with or without GABA-R antagonists. In control slices, most BrdU(+) cells were observed in the cortical plate (cp) after 48 h. In contrast, cultures maintained in either saclofen (a GABA(B)-R antagonist) or picrotoxin (a GABA(A/C)-R antagonist) had few BrdU-labeled cp cells. However, the effects of the two antagonists were distinct. In the picrotoxin-treated slices, nearly half of all BrdU(+) cells remained in the vz and subventricular zone (svz), whereas saclofen treatment resulted in an accumulation of BrdU(+) cells in the intermediate zone (iz). Bicuculline, a GABA(A)-R antagonist, did not block, but rather enhanced migration of BrdU(+) cells into the cp. These results provide evidence that picrotoxin-sensitive receptors promote the migration of vz/svz cells into the iz, while saclofen-sensitive receptors signal cells to migrate into the cp. Thus, as cortical cells differentiate, changing receptor expression appears to modulate migratory responses to GABA.

Immunocytochemical localization of excitatory and inhibitory neurotransmitters in the zebrafish retina.

The patterns of glutamate, gamma-aminobutyric acid (GABA), and glycine distribution in the zebrafish retina were determined using immunocytochemical localization of antisera at the light-microscope level. The observed GABA immunoreactivity (GABA-IR) patterns were further characterized using antibodies to both isoforms of glutamic acid decarboxylase (GAD65 and GAD67), the synthetic enzyme for GABA. Glutamate-IR was observed in all retinal layers with photoreceptors, bipolar cells, and ganglion cells prominently labeled. Bipolar cells displayed the most intense glutamate-IR and bipolar cell axon terminals were clearly identified as puncta arranged in layers throughout the inner plexiform layer (IPL). These findings suggest the presence of multiple subtypes of presumed OFF- and ON-bipolar cells, including some ON-bipolar cells characterized by a single, large (9 microm X 6 microm) axon terminal. GABA-, GAD-, and glycine-IR were most intense in the inner retina. In general, the observed labeling patterns for GABA, GAD65, and GAD67 were similar. GABA- and GAD-IR were observed in a population of amacrine cells, a few cells in the ganglion cell layer, throughout the IPL, and in horizontal cells. In the IPL, both GABA- and GAD-IR structures were organized into two broad bands. Glycine-IR was observed in amacrine cells, interplexiform cells, and in both plexiform layers. Glycine-positive terminals were identified throughout the IPL, with a prominent band in sublamina 3 corresponding to an immunonegative region observed in sections stained for GAD and GABA. Our results show the distribution of neurons in the zebrafish retina that use glutamate, GABA, or glycine as their neurotransmitter. The observed distribution of neurotransmitters in the inner retina is consistent with previous studies of other vertebrates and suggests that the advantages of zebrafish for developmental studies may be exploited for retinal studies.

Glutamate acting at NMDA receptors stimulates embryonic cortical neuronal migration.

During cortical development, embryonic neurons migrate from germinal zones near the ventricle into the cortical plate, where they organize into layers. Mechanisms that direct neuronal migration may include molecules that act as chemoattractants. In rats, GABA, which localizes near the target destination for migrating cortical neurons, stimulates embryonic neuronal migration in vitro. In mice, glutamate is highly localized near the target destinations for migrating cortical neurons. Glutamate-induced migration of murine embryonic cortical cells was evaluated in cell dissociates and cortical slice cultures. In dissociates, the chemotropic effects of glutamate were 10-fold greater than the effects of GABA, demonstrating that for murine cortical cells, glutamate is a more potent chemoattractant than GABA. Thus, cortical chemoattractants appear to differ between species. Micromolar glutamate stimulated neuronal chemotaxis that was mimicked by microM NMDA but not by other ionotropic glutamate receptor agonists (AMPA, kainate, quisqualate). Responding cells were primarily derived from immature cortical regions [ventricular zone (vz)/subventricular zone (svz)]. Bromodeoxyuridine (BrdU) pulse labeling of cortical slices cultured in NMDA antagonists (microM MK801 or APV) revealed that antagonist exposure blocked the migration of BrdU-positive cells from the vz/svz into the cortical plate. PCR confirmed the presence of NMDA receptor expression in vz/svz cells, whereas electrophysiology and Ca2+ imaging demonstrated that vz/svz cells exhibited physiological responses to NMDA. These studies indicate that, in mice, glutamate may serve as a chemoattractant for neurons in the developing cortex, signaling cells to migrate into the cortical plate via NMDA receptor activation.

Platelet-derived growth factor induces chemotaxis of neuroepithelial stem cells.

The ability of differentiating cells to migrate within the developing central nervous system (CNS) depends on extrinsic guidance signals, some of which are growth factors. In this study we have investigated the chemotactic response of cultured stem cells from the embryonic rat cortex to platelet-derived growth factor (PDGF). Nestin-positive stem cells from the developing CNS can be maintained and expanded in vitro under serum-free conditions in the presence of basic fibroblast growth factor (bFGF). Northern blot analysis of PDGF receptor expression revealed both alpha- and beta-receptors on bFGF-treated neural stem cells. Both PDGF-AA and PDGF-BB readily induced directed migration of cultured neuroepithelial cells as measured in a microchemotaxis assay. Blocking of the migratory response was achieved by incubation with PDGF isoform-specific antibodies. More than 90% of the migrating cells were nestin-positive and incorporation of BrdU was also seen suggesting the cells to be immature and not yet committed to a specific cell lineage. These findings suggest a role for PDGF in cell migration in the developing cortex.

Differential response of cortical plate and ventricular zone cells to GABA as a migration stimulus.

A microdissection technique was used to separate differentiated cortical plate (cp) cells from immature ventricular zone cells (vz) in the rat embryonic cortex. The cp population contained >85% neurons (TUJ1(+)), whereas the vz population contained approximately 60% precursors (nestin+ only). The chemotropic response of each population was analyzed in vitro, using an established microchemotaxis assay. Micromolar GABA (1-5 microM) stimulated the motility of cp neurons expressing glutamic acid decarboxylase (GAD), the rate-limiting enzyme in GABA synthesis. In contrast, femtomolar GABA (500 fM) directed a subset of GAD- vz neurons to migrate. Thus, the two GABA concentrations evoked the motility of phenotypically distinct populations derived from different anatomical regions. Pertussis toxin (PTX) blocked GABA-induced migration, indicating that chemotropic signals involve G-protein activation. Depolarization by micromolar muscimol, elevated [K+]o, or micromolar glutamate arrested migration to GABA or GABA mimetics, indicating that migration is inhibited in the presence of excitatory stimuli. These results suggest that GABA, a single ligand, can promote motility via G-protein activation and arrest attractant-induced migration via GABAA receptor-mediated depolarization.

Neurotrophins stimulate chemotaxis of embryonic cortical neurons.

During mammalian cortical development, neuronal precursors proliferate within ventricular regions then migrate to their target destinations in the cortical plate, where they organize into layers. In the rat, most cortical neuronal migration occurs during the final week of gestation (Bayer et al, 1991; Jacobson, 1991). At this time (E15-E21), reverse transcriptase-polymerase chain reaction demonstrated that cortical homogenates contain mRNA encoding brain derived neurotrophic factor (BDNF) and the catalytic form of its high-affinity receptor, TrkB. Immunocytochemistry and in situ hybridization of sections revealed that the catalytic TrkB receptors predominantly localize to regions containing migratory cells. Many TrkB+ cells exhibited the classic morphology of migrating neurons, suggesting that TrkB ligands play a role in cortical neuronal migration. We analysed whether TrkB ligands influence the motility of embryonic cortical cells (from E15-E21) using a quantitative in vitro chemotaxis assay. High-affinity TrkB ligands (BDNF and NT4/5) stimulated chemotaxis (directed migration) of embryonic neurons at concentrations ranging from 1 to 100 ng/ml. NT-3, a low-affinity TrkB ligand, only stimulated significant migration at high concentrations (> or =100 ng/ml). Peak migration to BDNF was observed at gestational day 18 (E18). BDNF-induced chemotaxis was blocked by either tyrosine kinase inhibitor, K252a, or the Ca2+-chelator, BAPTA-AM, suggesting that BDNF-induces motility via autophosphorylation of TrkB receptor proteins and involves Ca2+-dependent mechanisms. BDNF-stimulation of increased cytosolic Ca2+ was confirmed with optical recordings of E18 cortical cells loaded with Ca2+ indicator dye. Thus, signal transduction through the TrkB receptor complex directs neuronal migration, suggesting that, in vivo, BDNF exerts chemotropic effects that are critical to morphogenesis of the cortex.

GABA stimulates chemotaxis and chemokinesis of embryonic cortical neurons via calcium-dependent mechanisms.

During rat cortical development, when neurons migrate from the ventricular zone to the cortical plate, GABA localizes within the target destinations of migratory neurons. At this time, cells in germinal zones and along migratory pathways express GABA receptor subunit transcripts, implying that in vivo, GABA may be a chemoattractant. We used an in vitro strategy to study putative chemotropic effects of GABA on embryonic rat cortical cells. GABA stimulated neuronal migration in vitro at embryonic day 15 (E15). From E16 onward, two concentration ranges (fM and microM) induced motility. Femtomolar GABA primarily stimulated chemotaxis (migration along a chemical gradient), whereas micromolar GABA predominantly initiated chemokinesis (increased random movement). These effects were mimicked by structural analogs of GABA with relative specificity at GABAA (muscimol), GABAB (R-baclofen), and GABAC (trans- or cis-4-aminocrotonic acid) receptors. Antagonists of GABAB (saclofen) and GABAC (picrotoxin) receptors partially inhibited responses to both femto- and micromolar GABA; however, only responses to femtomolar GABA were partially blocked by bicuculline, a well established antagonist of GABA at GABAA receptors. Hence, chemotactic responses to femtomolar GABA seem to involve all three classes of GABA receptor proteins, whereas chemokinetic responses to micromolar GABA involve GABAB and GABAC receptor proteins. GABA-induced motility was blocked by loading the cells with the Ca(2+)-chelating molecule bis(2-aminophenoxy)ethane-N,N,N',N'-tetra-acetic acid, suggesting that intracellular Ca2+ mediates GABA-induced cell movement. Optical recordings of cells loaded with Ca2+ indicator dye revealed that both femto- and micromolar GABA evoked increases in intracellular Ca2+. Thus, GABA-stimulated increases in intracellular Ca2+ may mediate both chemotactic and chemokinetic responses in embryonic cortical cells.

GABA-induced motility of spinal neuroblasts develops along a ventrodorsal gradient and can be mimicked by agonists of GABAA and GABAB receptors.

During embryogenesis, neuroblasts proliferate within germinal zones, then migrate to their final positions. Although many neurons migrate along radial glial fibers, evidence suggests that environmental factors, as yet unidentified, also influence neuroblast movement. In vivo, nerve growth factor (NGF) and gamma-aminobutyric acid (GABA) colocalize near target destinations of migratory neuroblasts. In vitro, embryonic spinal neurons migrate towards NGF and GABA (Behar et al.: J Neurosci 14:29-38, 1994), implying that the molecules may act as chemoattractants in vivo. Here, we have used an in vitro assay of migration to show that migratory responses to these attractants develop along a ventrodorsal gradient that parallels terminal mitosis during cord development, and that GABA stimulates chemokinesis (motility without a gradient) via heterogeneous receptors involving separate signalling pathways. Both GABAA (muscimol) and GABAB (baclofen) agonists mimicked the effects of GABA in stimulating chemokinesis. Muscimol-induced motility was only blocked by GABAA antagonists (bicuculline or picrotoxin), whereas migration to baclofen was blocked by antagonists of both GABAA and GABAB (2-hydroxysaclofen) receptors. Migration to baclofen, but not muscimol, was abolished in the presence of 8-bromo cAMP or pertussis toxin, indicating that the former, but not the latter, attractant may stimulate motility via Gi/Go GTP binding proteins, and that PKA may modulate migratory responses to baclofen. Migration to GABA was partially attenuated by each of the GABA receptor antagonists. These results lead us to conclude that the natural ligand stimulates neuroblast motility via heterogeneous receptors coupled to different signalling mechanisms.

Correlation of gp140trk expression and NGF-induced neuroblast chemotaxis in the embryonic rat spinal cord.

During rat embryogenesis, fibers containing nerve growth factor (NGF) are present near the target destinations of migratory spinal neuroblasts, suggesting that diffusible gradients of NGF provide signals to newly generated neurons in the developing cord. In vitro, pM concentrations of NGF induce neuroblast chemotaxis (directed migration along a chemical gradient), indicating evoked motility is mediated by high-affinity receptors. Binding of 125I-labelled NGF to fetal cord cells provides additional evidence that rat spinal neuroblasts express the high-affinity receptors; however, their presence has not been directly demonstrated. In the present study, we used immunocytochemistry to show that the high-affinity NGF receptor protein, gp140trk (trk) is detectable in embryonic spinal tissue sections and in cord dissociates. Correlation of trk expression with NGF-induced chemotaxis revealed that both the receptor protein expression and functional responses to NGF develop along a ventro-dorsal gradient that parallels the in vivo pattern of neurogenesis and migration. Analysis of the temporal changes in trk immunoreactivity demonstrated that expression of gp140trk is bimodal, possibly reflecting multiple effects of NGF during development. Chemotaxis to NGF was blocked by nM concentrations of the kinase inhibitor, K252a, suggesting that NGF stimulates motility via high-affinity receptors coupled to kinase activity. Elevated 3',5'-cyclic adenosine monophosphate (cAMP) also attenuated NGF-induced chemotaxis, presenting preliminary evidence that protein kinase A (PKA) may regulate motility responses to NGF.

GABA-induced chemokinesis and NGF-induced chemotaxis of embryonic spinal cord neurons.

During CNS development, neuroblasts proliferate within germinal zones of the neuroepithelium, and then migrate to their final positions. Although many neurons are thought to migrate along processes of radial glial fibers, increasing evidence suggests environmental factors also influence nerve cell movement. Extracellular matrix molecules are thought to be involved in guiding neuronal migration, and molecules such as NGF and GABA exert trophic effects on immature neurons. The nature of the signals that initiate and direct neuroblast migration, however, is unknown. In vitro, NGF and GABA promote neurite outgrowth from cultured cells, and NGF induces axonal chemotaxis (directed migration along a chemical gradient). At earlier developmental stages, these molecules could influence neuroblast movement. Therefore, we investigated whether these molecules induce embryonic neuronal migration. Using an in vitro microchemotaxis assay, we show that rat embryonic spinal cord neurons migrate toward picomolar NGF and femtomolar GABA beginning at embryonic day 13 (E13). Cells exhibit chemotactic responses to NGF while GABA stimulates chemokinesis (increased random movement). GABA effects are mimicked by muscimol and inhibited by bicuculline and picrotoxin, suggesting GABA motility signals are mediated by GABA receptor proteins. Expression of GABA receptors by embryonic cord cells has been previously reported (Mandler et al., 1990; Walton et al., 1993). We used polymerase chain reaction analysis to demonstrate the presence of NGF and trk mRNA in E13 and E14 cord cells, indicating the cells express message for both NGF and high-affinity NGF receptors. Immunohistochemistry of E13 spinal cord sections indicates that NGF and GABA colocalize in fibers close to the target destinations of migrating neurons, suggesting diffusible gradients of these molecules provide chemoattractant signals to migratory cells. Thus, in vitro, neuroblast migration is induced by specific signaling molecules that are present in the developing spinal cord, and may stimulate migration of embryonic neurons prior to synaptogenesis.

Comparative fractal analysis of cultured glia derived from optic nerve and brain demonstrate different rates of morphological differentiation.

O-2A progenitor cells derived from neonatal rat cerebral hemispheres or optic nerves, were induced to differentiate in culture into either oligodendrocytes or type 2 astrocytes. The fractal dimensions, a measure of morphological complexity, of the differentiating glial cells were measured over time. Analysis of the changes in fractal dimension (D) with respect to time revealed specific rates of growth for each glial phenotype and a specific final D. The time course of these changes is well fit by a simple mathematical model. While brain-derived oligodendrocytes matured faster than the astrocytes, they ultimately attained comparable levels of complexity, with similar maximum fractal dimensions. Oligodendrocytes from nerve also matured faster than nerve derived astrocytes, in contrast, however, they attained a greater morphological complexity than nerve astrocytes. While the brain-derived oligodendrocytes showed a faster rate of maturation than their optic nerve counterparts, astrocytes from both regions had similar rates of morphological differentiation. Self-similarity, a defining property of fractal objects was investigated, by determining the fractal dimension of cells over a range of magnifications. The calculated fractal dimension remained constant over a 10-fold range in optical magnification, illustrating that cultured glial cells exhibit this important characteristic of fractal objects. In addition, we analyzed the branching patterns of glial processes by the Sholl method and found that the results were not as interpretable or meaningful as those of fractal analysis.

A fractal analysis of cultured rat optic nerve glial growth and differentiation.

Fractal dimension can be used as a quantitative measure of morphological complexity. Separate, enriched populations of oligodendrocytes or type 2 astrocytes derived from neonatal rat optic nerves were allowed to differentiate in vitro. Fractal dimensions of differentiating glial cells were measured over time. The fractal dimension correlated with perceived complexity and increased in value as the glial cells matured. Analysis of the changes in fractal dimension with time revealed unique rates of growth and differentiation for each glial phenotype.

The timely expression of myelin basic protein gene in cultured rat brain oligodendrocytes is independent of continuous neuronal influences.

The developmental expression of the myelin basic protein (MBP) gene was studied in rat cultured oligodendrocytes using immunofluorescence and in situ hybridization. In newborn rat brain cultures, which contain only glial cells, large amounts of MBP-specific mRNA (as assayed by grain counts in autoradiograms) abruptly accumulated within immature oligodendrocytes 5 to 6 days postnatal. MBP always emerged 6 to 8 days after birth; thus, a week after, galactocerebroside (GC), an early oligodendrocyte marker, had appeared. The percentage of MBP mRNA and MBP-positive cells peaked at about 15 days postnatal and decreased thereafter. The time of emergence of MBP in these cultured oligodendrocytes appears to be determined at a very early stage in their development and independent of continuous neuronal influences. There is a striking correspondence between the times of appearance of MBP in cultured oligodendrocytes and those in the intact animal. Thus, primary cultures made from 5-day prenatal, newborn, and 2-day postnatal animals all express MBP at about the same developmental stage, namely, after 14, 8, and 6 days in culture, respectively. Furthermore, cultured oligodendrocytes obtained from the spinal cord express MBP before those obtained from midbrain or hemispheres, as they would in the intact animal. Thus, the developmental expression of the MBP gene occurs in a similar time frame in vitro and in vivo. In oligodendrocyte-enriched cultures, where 60% to 80% of the cells express MBP, in situ hybridization with the cDNA clone revealed MBP-specific mRNA in the cell body and sometimes in the processes of the differentiated oligodendrocytes.(ABSTRACT TRUNCATED AT 250 WORDS)

Monospecific antibody to the haemagglutinin of measles virus.

A hybrid between a murine myeloma cell line and spleen cells from a mouse immunized with measles has been produced. Two stable clones produce antibody with identical immunochemical and biological properties. This antibody reacts with the 76,000 mol. wt. protein present in the lysates and on the surface of cells persistently infected with measles. It exhibits HAI and neutralizing activity.

Detection of B cell antigens in multiple sclerosis. Use of serum from multiparous women.

Sera from two multiparous wives of patients with multiple sclerosis (MS) were used to detect B cell antigens in other patients. With serum X, 11 of 16 patients were positive as compared with ten of 16 controls (.05 less than P less than .1). With serum Y, a positive response was found in 11 of 16 patients and two of 23 controls (P less than .0005). Ten of the 11 patients who were positive with serum Y were also HLA-Dw2, which suggests that the B cell antigen detected by this serum is linked to Dw2. Three of four Dw2-positive controls were negative with serum Y, which raises two alternative hypothetical possibilities concerning the B cell antigen. These findings indicate that serum from multiparous wives may be an important tool in the investigation of the genetic components associated with MS.