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Previous Article | Next Article
Volume 16, Number 24, Issue of December 15, 1996 pp. 7941-7949
Copyright ©1996 Society for NeuroscienceNeural Cell Type-Specific Expression of QKI Proteins Is Altered in quakingviable Mutant Mice
Rebecca J. Hardy1, Carrie L. Loushin2, Victor L. Friedrich Jr.1, Qi Chen2, Thomas A. Ebersole2, Robert A. Lazzarini1, and Karen Artzt2 1 Brookdale Center for Molecular Biology, Mount Sinai Medical Center, New York, New York 10029, and 2 Department of Zoology, University of Texas at Austin, Austin, Texas 78712-1064
ABSTRACT
qkI, a newly cloned gene lying immediately proximal to the deletion in the quakingviable mutation, is transcribed into three messages of 5, 6, and 7 kb. Antibodies raised to the unique carboxy peptides of the resulting QKI proteins reveal that, in the nervous system, all three QKI proteins are expressed strongly in myelin-forming cells and also in astrocytes. Interestingly, individual isoforms show distinct intracellular distributions: QKI-6 and QKI-7 are localized to perikaryal cytoplasm, whereas QKI-5 invariably is restricted to the nucleus, consistent with the predicted role of QKI as an RNA-binding protein. In quakingviable mutants, which display severe dysmyelination, QKI-6 and QKI-7 are absent exclusively from myelin-forming cells. By contrast, QKI-5 is absent only in oligodendrocytes of severely affected tracts. These observations implicate QKI proteins as regulators of myelination and reveal key insights into the mechanisms of dysmyelination in the quakingviable mutant.
Key words: myelination; dysmyelination; nucleus; RNA metabolism; oligodendrocyte; Schwann cell; quaking; STAR proteins
INTRODUCTION
quaking viable (qkv) is an autosomal recessive mutation in mice characterized by severe dysmyelination of the CNS (Sidman et al., 1964
). CNS myelin of qkv mice exhibits a reduced number of myelin lamellae, a lack of compaction of myelin sheaths, and abnormal production of cytoplasmic loops (Hogan and Greenfield, 1984
qkI is a newly cloned gene that lies 1.1 kb centrometric to the deletion in the qkv mutation on mouse chromosome 17 (Ebersole et al., 1992
ends and in their extensive 3
In this study, we have used specific antibodies to localize each of the three QKI proteins in nervous system tissue. We show that in wild-type mice all three QKI isoforms are abundant in myelinating cells of the central and peripheral nervous system but also are present in astrocytes. By contrast, in qkv mutants, the levels of QKI-6 and QKI-7 are reduced dramatically in myelinating cells, whereas that of the third isoform, QKI-5, is reduced only in severely affected regions of the brain. These observations reveal important insights into the possible function of QKI proteins in wild-type brain and also into the mechanisms of dysmyelination in the qkv mutant.
MATERIALS AND METHODS
Mice. Wild-type mice were B6D2F1. Mutant mice used were as follows: qkv/qkv mice from the Austin colony [maintained as previously described (Ebersole et al., 1996
Northern blot analysis. Total RNA from mouse brain was isolated by the use of LiCl/urea (Geliebter, 1987
QKI antibodies. Three peptides of the unique carboxy tails of QKI-5 (GAVATKVRRHDMRVHPYQRIV TADRAATGN), QKI-6 (GMAFPTKG), and QKI-7 (EWIEMPVMPDISAH) were conjugated to KLH by glutaraldehyde linkage and carbamide chemistry and used to immunize two rabbits for each peptide (Research Genetics, Huntsville, AL). Antisera generated by the duplicate rabbits gave identical immunolabeling results. Antisera were purified by immunoaffinity chromatography with the relevant peptide via the Affigel system (Bio-Rad, Hercules, CA), according to the manufacturer's instructions.
Antibodies. Rat monoclonal antibodies to glial fibrillary acidic protein (GFAP) were a gift of Dr V. M. Lee (Lee et al., 1984
Immunoblotting. Brain homogenates were made from wild-type mice by homogenizing tissue in 2% SDS in 20 mM Tris, pH 7.6 (or without SDS for use on nondenaturing gels). For denaturing gels, 15 µg of brain/well was diluted in loading buffer (final concentration: 0.25 M Tris, pH 6.8, 10% glycerol, 1% SDS, 100 mM DTT, and 0.05% bromophenol blue) and subjected to SDS discontinuous polyacrylamide gel electrophoresis (10% polyacrylamide gel). For nondenaturing gels, brain homogenate was diluted in loading buffer in the absence of SDS, centrifuged to remove insoluble proteins, and run on a 10% polyacrylamide gel in the absence of SDS. For both types of gel, proteins then were transferred to Immobilon P membrane (Millipore, Bedford, MA) and detected by QKI antibodies at 1:10,000-1:50,000 dilution, followed by alkaline phosphatase-conjugated donkey anti-rabbit secondary antibody (Jackson Immunologicals) diluted 1:5000, with the nitro blue tetrazolium and 5-bromo-4-chloro-3-indolyl phosphate detection system. In peptide inhibition experiments, QKI antisera diluted 1:10,000 was incubated with 1 µg of immunizing or nonspecific peptide for 1 hr before incubation with membrane. Immunoreactivity of affinity-purified antisera could be eliminated by previous incubation with 100 ng of specific peptide (data not shown).
Tissue preparation and immunocytochemistry. P14 wild-type, qkv, shiverer, or jimpy mutant mice were perfused through the left ventricle with 4% paraformaldehyde in 0.1 M phosphate buffer, pH 7.4. Tissue to be cryostat-sectioned was dissected out and cryoprotected in 30% sucrose in 0.1 M phosphate buffer, pH 7.4, overnight at 4°C, embedded in OCT compound (Miles Scientific, Elkhart, IN), and snap-frozen. Sections (5-10 µm) were thaw-mounted onto Superfrost slides (Fisher Scientific, Pittsburgh, PA) and refrozen for storage at 20°C.
Tissue sections were treated as follows, depending on the antigen: methanol, 5 min at 4°C (MBP, GAP-43); 0.1% Triton X-100 in 0.5 M Tris, pH 7.6, 10 min at room temperature (GFAP, neurofilaments, histones). Neither treatment was necessary for, nor adversely affected, immunolabeling with QKI antibodies. Then all sections were blocked in 10% normal goat serum, 1% gelatin, 5% BSA, and 0.05% sodium azide in 0.5 M Tris, pH 7.6, for 30 min at room temperature. They were incubated overnight with primary antibodies diluted in the same solution and then in fluorochrome- or biotin-conjugated species or subclass-specific secondary antibodies for 3 hr at room temperature, followed by fluorochrome-conjugated streptavidin for 1 hr at room temperature. Each of these steps was followed by three washes in 0.5 M Tris, pH 7.6 (20 min each). QKI primary antibodies were used at a dilution of 1:1000. For peptide inhibition experiments, QKI antisera, at a dilution of 1:1000, were incubated with 1 µg of immunizing or nonspecific peptide before overnight incubation with sections. Then sections were mounted on slides and coverslipped with 2.5% diazabicyclo-octane in glycerol/0.5 M Tris, pH 8.6 (9:1). Slides were analyzed with a Leica TCS confocal microscope. Composite figures were assembled in Adobe PhotoShop and printed on a dye sublimation photoprinter.
RESULTS
qkI messages are regulated developmentally in brain
We have demonstrated previously that the three distinct qkI messages are expressed in adult wild-type whole-mouse brain (Ebersole et al., 1996
Fig. 1. a, Northern blot analysis of qkI messages during brain development. A single Northern blot of total brain RNA from whole brain of mice aged P2 to adult was hybridized with a cDNA probe specific for qkI 5 kb transcript and a cDNA that recognizes the qkI 6 and qkI 7 kb transcripts. Ethidium bromide staining is shown as a loading control. All three qkI messages are expressed throughout postnatal development and into adulthood. Levels of the 5 kb transcript decline dramatically after the second postnatal week, whereas levels of the 6 and 7 kb transcripts, although maximal at P14, decline only modestly thereafter. b, Production of anti-QKI peptide antisera. Peptides were manufactured with sequences from the C-terminal tails unique to each QKI isoform, as indicated by the shaded areas. c, Immunoblot analysis of QKI antisera with P14 mouse brain. Lanes 1-3, QKI-6, nondenaturing gel; lanes 4-6, QKI-5, nondenaturing gel; lanes 7, 8, QKI-5, denaturing gel. Antisera raised against QKI-6 C-terminal peptide recognize a tight doublet on nondenaturing gels (lane 1). Reactivity for these bands can be eliminated by previous incubation with QKI-6 immunizing peptide (lane 2), but not QKI-5 immunizing peptide (lane 3). Antisera raised against the QKI-5 C-terminal peptide recognize a single, yet distinct, band on nondenaturing gels (lane 4). QKI-5 immunizing peptide (lane 5), but not QKI-6 immunizing peptide (lane 6), can compete away reactivity to this band. The single band recognized by QKI-5 antisera can be resolved into two bands of 45 and 38 kd on SDS-denaturing gels (lane 7). Reactivity to both bands can be competed away by previous incubation with QKI-5 immunizing peptide (lane 8).
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QKI antisera
To determine the localization of each of the three QKI proteins in murine nervous system, we raised rabbit polyclonal antibodies against C-terminal peptides specific to each of the QKI proteins (Fig. 1b). In immunoblot analysis of nondenaturing polyacrylamide gels, antisera to QKI-5 and QKI-6 each strongly recognized distinct bands in homogenates of P14 brain (Fig. 1c). Reactivity against these bands could be eliminated by previous incubation of antisera with immunizing peptide, but not nonspecific peptide (Fig. 1c). Peptide-inhibited antisera gave no immunolabeling on brain sections (see below).
Under denaturing conditions, antisera raised to the C-terminal peptide of QKI-5 reacts with two proteins of 45 and 38 kDa in P14 brain (Fig. 1c). Reactivity against both proteins could be eliminated by preabsorption of QKI-5 antisera with immunizing peptide. However, only the 45 kDa protein was recognized by affinity-purified QKI-5 antisera (data not shown). Because affinity-purified and crude QKI-5 antisera gave identical immunolabeling patterns on frozen brain sections (see below), the significance of the 38 kDa band is not clear at present.
Antisera raised against the C-terminal peptide of QKI-6 reacts with multiple proteins under denaturing conditions (data not shown), presumably because immunoreactive epitopes not available for binding to antibody in native proteins become exposed after denaturation. Because the QKI-6 C-terminal peptide consists of only eight amino acids, cross-reactivity with similar sequences in other proteins is not surprising. However, because the antisera recognize only a tight doublet on native gels, to which reactivity can be competed by immunizing peptide (Fig. 1c), and also exhibit strikingly restricted patterns of immunoreactivity in brain sections (see below), we believe that the antisera is specific for QKI-6 under nondenaturing conditions. Affinity-purified antisera raised against the QKI-7 C-terminal peptide weakly recognized a 43 kDa protein on immunoblots of denaturing gels (data not shown). Both crude and affinity-purified QKI-7 antisera gave similar immunolabeling patterns to QKI-6 antisera, and this immunoreactivity could be eliminated by previous incubation with the QKI-7 immunizing peptide, but not the QKI-6 or QKI-5 peptides (see below). QKI proteins are abundant in oligodendrocytes
QKI antisera were used to determine the localization of each of the QKI isoforms in P14 wild-type murine brain. We chose to study P14 animals, because all three qkI transcripts are abundant at this stage of development (Fig. 1a). Parasagittal or coronal 10 µm frozen sections of paraformaldehyde-fixed P14 mouse brain were immunolabeled with each of the QKI antisera. In all cases, antisera raised to QKI-7 peptide gave similar immunolabeling patterns to those raised to QKI-6 peptide, and so for clarity, only results for QKI-6 are mentioned in the text.
QKI immunoreactivity was found throughout the entire brain but was particularly prominent in cells lying in white matter tracts. Double immunolabeling that used antibodies to the MBP and QKI isoforms revealed that QKI+ cells are abundant among myelinated axons (Fig. 2). Here, QKI-6+ cells have ovoid perikarya and are found in interfascicular rows, characteristic of white matter oligodendrocytes (Fig. 2b). Figure 2d shows a cell, adjacent to striatal axon bundles, in which QKI-6 is localized to proximal processes contiguous with an MBP+ myelin sheath, thus confirming its identity as a myelin-forming oligodendrocyte. In oligodendrocytes, QKI-6 immunoreactivity was concentrated in perikaryal cytoplasm but was also apparent at lower levels in the nucleus. By contrast, QKI-5, which is localized to the same population of cells, was restricted, strikingly, to the nucleus (Fig. 2c). Note that under our labeling conditions the myelin sheaths themselves show no QKI immmunoreactivity. 
Fig. 2. QKI proteins are present in oligodendrocytes in P14 brain. Double immunolabeling of P14 mouse striatum with antisera to MBP (red) and QKI-6 (green, a, b, d) or QKI-5 (green, c). Numerous QKI-6+ cells can be seen among the MBP+-myelinated fibers of the striatum (a) and at higher magnification (b). These cells are located in rows between myelinated axons, characteristic of interfascicular oligodendrocytes. The same population of cells also is immunolabeled by QKI-5 antisera (c); by contrast, QKI-5 immunoreactivity is restricted to the nucleus. d, A cell lying adjacent to myelinated striatal fibers has QKI-6 immunoreactivity in perikaryal cytoplasm but also in proximal processes that are contiguous with an MBP+ myelin sheath (arrows).
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QKI proteins were detected in oligodendrocytes throughout the brain in both gray and white matter, including cerebellum (Fig. 3) and optic nerve (Fig. 4). All patterns of immunoreactivity seen with crude antisera were identical to those seen with affinity-purified antibodies (data not shown). Preincubation of crude serum with immunizing peptide completely abolished all immunoreactivity on frozen sections, but immunolabeling was unaffected after preincubation of antisera with unrelated peptide. 
Fig. 3. QKI proteins also are present in astrocytes in P14 brain but are absent from CNS neurons. a, Double immunolabeling of P14 mouse cerebellum with antibodies to neurofilaments (NF; red) and QKI-6 (green). QKI-6 immunoreactivity is seen in oligodendrocytes of the cerebellar white matter (arrowheads) but is also found in cells of the Purkinje cell layer. NF immunolabeling demonstrates that, whereas Purkinje neurons (p) are devoid of QKI-6, the adjacent Bergmann glia are QKI-6+. In the cerebellar granule cell layer (gc), granule neurons are QKI-6, but some weakly QKI-6+ astrocytes can be seen. b, Double immunolabeling with antisera to GFAP (red) and QKI-5 (green) shows that astrocytes of the granule cell layer are also QKI-5+. c, In the cerebral cortex, oligodendrocytes are strongly QKI-7+ (green, arrowheads), whereas astrocytes are more weakly QKI-7+. Pyramidal neurons visualized by NF immunoreactivity (red) are QKI-7
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Fig. 4. QKI proteins are distributed differentially within oligodendrocytes and astrocytes. Double immunolabeling of P14 mouse optic nerve with antisera against QKI-6 (a) or QKI-5 (c) and GFAP (b, d). a, b, GFAP
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QKI proteins also are expressed by Bergmann glia and other astrocytes
In addition to the strong QKI immunoreactivity in oligodendrocytes, we also saw QKI immunolabeling in other CNS cell types. For example, in the cerebellum, the Bergmann glia of the Purkinje cell layer contained levels of QKI-5 and QKI-6 comparable to those in oligodendrocytes (Fig. 3a). Purkinje cells themselves, detected with antibodies to neurofilaments, were devoid of QKI immunoreactivity, as were all other cerebellar neurons. In fact, no immunoreactivity for any of the three QKI proteins was seen in any CNS neurons (Fig. 3c).
To determine whether QKI is localized to other astrocyte populations, we double-labeled sections with antibodies to QKI and the astrocyte protein GFAP. We found that astrocytes of the cerebellum (Figs. 3b, 7a) as well as hippocampus, cerebral cortex, and all white matter tracts (Fig. 3d-f), including the optic nerve (Fig. 4), all contain moderate amounts of QKI. As in oligodendrocytes, QKI-6 was found in astrocyte cytoplasm as well as in nuclei (Figs. 3d-f, 4a,b). However, QKI-5 immunoreactivity, which in oligodendrocytes is always restricted to the nucleus, was also often found in proximal processes of astrocytes (Fig. 4c,d). 
Fig. 7. QKI proteins are absent from oligodendrocytes in qkv mice. Double immunolabeling of P14 mouse cerebellum (a, b) or anterior commissure (c, d) with antisera against QKI-6 (green, a, b) and GFAP (red, a, b) or QKI-5 (green, c, d) and histones (red, c, d). In wild-type cerebellum, antisera against QKI-6 label the Bergmann glia of the Purkinje cell layer (p), some GFAP+ astrocytes in the granule cell layer (gc) and white matter (wm), as well as GFAP
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QKI proteins are abundant in myelinating Schwann cells
Because the QKI proteins are restricted to neuroglia in the CNS, we were interested to see whether they also are expressed in PNS glia. Double immunolabeling with QKI antibodies and antibodies to growth-associated protein 43 (GAP-43), which in peripheral nerve is restricted to nonmyelinating Schwann cells (Curtis et al., 1992
Fig. 5. Double immunolabeling of P14 mouse sciatic nerve with antisera against QKI-6 (a, e) or QKI-5 (c, g) and GAP-43 (b, d, f, h). a-d, QKI proteins are present in wild-type peripheral nervous system glia. Both QKI-6 (a, b) and QKI-5 (c, d) are found in GAP-43
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QKI-6 and QKI-7 proteins are absent from myelin-forming cells in qkv mutants
qkI transcripts have been detected previously in total brain RNA of qkv mice (Ebersole et al., 1996
In wild-type optic nerve, QKI proteins are found in both oligodendrocytes and astrocytes (Figs. 4, 6a); in fact, almost all cells of normal optic nerve are QKI+ (Fig. 6d). By contrast, in qkv mice, although astrocytes contain levels of QKI-6 expression comparable to normal mice, qkv oligodendrocytes completely lack detectable levels of QKI-6 (Fig. 6a,b). Previous studies have shown that qkv optic nerve actually contains an elevated number of oligodendrocytes (Friedrich, 1975 
Fig. 6. QKI-6, but not QKI-5, is absent from oligodendrocytes in qkv optic nerve. Double immunolabeling of P14 mouse optic nerve with antisera against QKI-6 (green, a, b, d, e) or QKI-5 (green, c, f) and GFAP (red, a-c) or histones (red, d, e, g). a, In wild-type optic nerve, QKI-6 is located in GFAP
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In the cerebellum of qkv mice, QKI-6 is present in astrocytes and also at high levels in Bergmann glia, as is the case in normal littermates (Fig. 7). However, in agreement with data from optic nerve, QKI-6 is not detectable in oligodendrocytes in the cerebellar white matter of qkv mice (Fig. 7, compare a and b). Our immunocytochemical analysis failed to reveal any detectable levels of QKI-6 and QKI-7 in oligodendrocytes anywhere in the qkv mutant mouse brain.
In the PNS, the dysmyelinating phenotype in qkv mice is mild (Suzuki and Zagoren, 1977 QKI-5 expression varies with severity of dysmyelination
Hence, in qkv mice, myelin-forming cells of both the CNS and PNS are devoid of QKI-6 and QKI-7, whereas astrocytes seem to have normal levels of both of these QKI isoforms. However, we found that the situation for QKI-5 was more complex and that there was a striking systematic regional variation in the levels of QKI-5 in qkv oligodendrocytes. qkv is unusual among dysmyelinating mouse mutants in that qkv mice exhibit a rostral-caudal gradient in the severity of dysmyelination, with the greatest deficiency of myelin in forebrain tracts, such as the anterior commissure (Friedrich, 1975Abnormalities in QKI expression are specific to qkv mice
We wondered whether the changes observed in QKI levels in myelinating cells in qkv mice are a general feature of dysmyelinating mutants. We therefore examined the immunolocalization of QKI proteins in the brains of two other dysmyelinating mouse mutants: shiverer and jimpy. These mutants display a dysmyelinating phenotype as a consequence of mutations in the genes encoding the myelin proteins MBP and proteolipid protein (PLP), respectively (Roach et al., 1983
Fig. 8. QKI proteins are present in both oligodendrocytes and astrocytes in shiverer and jimpy mutant mice. Double immunolabeling of P14 shiverer (a, b) or jimpy (c, d) mice with antibodies to QKI-6 (green, a, c) or QKI-5 (green, b, d) and NF (red, a, b) or MBP (red, c, d). a, As in wild-type mice, oligodendrocytes of the subcortical white matter (swm) and cerebral cortex (cx) of shiverer mice are immunolabeled strongly with antisera to QKI-6 (a) and QKI-5 (b). Similarly, in jimpy mice, cerebellar white matter oligodendrocytes are immunolabeled strongly by QKI-6 (c) and QKI-5 (d) antisera. Bergmann glia of the Purkinje cell layer (p) and astrocytes of the granule cell layer (gc) also are immunolabeled.
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DISCUSSION
We have shown that three gene products of the qkI gene are abundant in myelinating cells of the central and peripheral nervous system. These proteins also are located in Bergmann glia and other astrocytes but are absent from all CNS neurons. In addition, we show that the QKI proteins are distributed differentially within the cell: QKI-6 and QKI-7 are located primarily in the cytoplasm of the perikaryon and proximal processes, with moderate levels within the nucleus, whereas QKI-5 is found almost exclusively in the nucleus. We also have examined the localization of QKI proteins in the dysmyelinating qkv mutant and have found dramatic changes in their levels in myelinating cells: oligodendrocytes and myelin-forming Schwann cells are devoid of QKI-6 and QKI-7. In addition, the presence of QKI-5 in oligodendrocytes correlates with the severity of the dysmyelinating phenotype: in mildly affected regions of the CNS, QKI-5 is abundant in oligodendrocytes, but it is absent in oligodendrocytes of more severely affected tracts. Oligodendrocytes from two other dysmyelinating mouse mutants, shiverer and jimpy, have wild-type levels and distributions of the QKI proteins, suggesting that the effect seen in the qkv mice may be quite specific to that mutation.QKI proteins and myelination
Although the physiological function or functions of the QKI proteins are not known at present, the results presented here implicate the QKI proteins as regulators of myelination. All three QKI isoforms are abundant in both oligodendrocytes and myelinating Schwann cells, indicating that they function in both central and peripheral nervous system myelin formation. The regulation of CNS and PNS myelination remains poorly understood, but despite key differences in the molecular composition of CNS and PNS myelin (Norton and Cammer, 1984
However, the widespread expression of qkI mRNAs and proteins indicates that QKI proteins have a still more universal role. qkI mRNAs also can be detected outside the nervous system in heart, lung, and testes (Ebersole et al., 1996 QKI isoforms are distributed differentially within the cell
Although in the nervous system all three QKI isoforms are expressed in the same populations of cells, we observed a striking difference in the intracellular distribution of the individual isoforms. In oligodendrocytes and Schwann cells, QKI-5 is always restricted to the nucleus, whereas QKI-6 and QKI-7, although also present in the nucleus, are concentrated in the perikaryal cytoplasm. Because the three isoforms are known to differ only in their C-terminal tails, these probably confer the distinct subcellular localizations observed. For example, the highly basic C terminus of QKI-5 most probably acts as a nuclear localization signal. The predicted amino acid sequences also indicate that all three QKI isoforms contain a KH domain, which in other proteins is known to be associated with RNA binding (Musco et al., 1996The qkv deletion affects QKI protein distribution
The apparent absence of QKI proteins we have observed in myelinating cells of qkv mice are far more dramatic than any alterations in levels of myelin proteins, mRNAs, or lipid metabolism reported previously for qkv (reviewed in Hogan and Greenfield, 1984
However, it is not yet clear in molecular terms how the qkv deletion leads to alterations of the cell type-specific expression of the QKI proteins or to alterations in the relative levels of the QKI isoforms. One intriguing possibility is that some other protein deleted or truncated by the qkv deletion normally acts as a regulator of qkI. qkII, tentatively identified as a second novel gene and the mRNA of which is truncated in qkv (Ebersole et al., 1996 qkv mice exhibit abnormalities in RNA metabolism
The dramatic reduction in QKI expression in qkv myelin-forming cells is intriguing in light of the putative role of QKI as an RNA binding protein and several previous reports of abnormalities in RNA metabolism in qkv mice. First, myelin-associated glycoprotein (MAG), which is found in both CNS and PNS myelin-forming cells, displays several abnormalities in qkv mice, most notably alterations in levels of alternatively spliced isoforms (Frail and Braun, 1985
FOOTNOTES
Received Aug. 6, 1996; revised Sept. 24, 1996; accepted Oct. 1, 1996.
This work was supported by National Institutes of Health Grant NS33165 to V.L.F. and R.A.L. and National Institute of Child Health and Human Development Grants HD10668 and HD30658 to K.A. We thank Stephane Zaffran and Michel Semeriva for sharing their Drosophila sequence before publication. This is manuscript 227 from the Brookdale Center for Molecular Biology.
Correspondence should be addressed to Dr. Rebecca Hardy, Brookdale Center for Molecular Biology, Mount Sinai Medical Center, Box 1126, 1 Gustave L. Levy Place, New York, NY 10029.
Dr. Chen's present address: Genentech, 460 Point San Bruno Boulevard, South San Francisco, CA 94080.
Dr. Ebersole's present address: Department of Genetics, Cambridge University, Cambridge CB2 3EH, UK.
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ABSTRACT
