Volume 93, Issue 7, Pages (June 1998)

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Volume 93, Issue 7, Pages 1147-1158 (June 1998) Targeted Disruption of Mouse Conventional Kinesin Heavy Chain kif5B, Results in Abnormal Perinuclear Clustering of Mitochondria  Yosuke Tanaka, Yoshimitsu Kanai, Yasushi Okada, Shigenori Nonaka, Sen Takeda, Akihiro Harada, Nobutaka Hirokawa  Cell  Volume 93, Issue 7, Pages 1147-1158 (June 1998) DOI: 10.1016/S0092-8674(00)81459-2

Figure 1 Targeted Disruption of the Mouse kif5B Gene (A) Targeting strategy with conventional positive-negative selection. Strategy of genomic Southern blotting for screening for the homologous recombinant ES clones was also included. SA, splicing acceptor; Pau, RNA polymerase II pausing signal; Closed boxes, P-1, P, P+1, respective exons around the P-loop; SI, SacI; A, ApaI; RI, EcoRI; RV, EcoRV; Hc, HincII; Hd, HindIII; Xb, XbaI. (B) Southern blotting analyses of targeted ES clones digested respectively with EcoRI and SacI. Lane 1, clone G32; lane 2, clone I15; lane 3, a nonhomologous recombinant. (C) Southern blotting analysis of 9.5 dpc embryonic DNA digested by EcoRI. Lane 1, kif5B−/−; lane 2, kif5B+/−; lane 3, kif5B+/+. (D) Sequence electropherogram of a mutated mRNA clone amplified by RT-PCR. Note that the exon P was skipped to result in a stop codon just after the junctional region. (E) Immunoblotting analysis against KIF5B (lanes 1–3) and the corresponding protein staining (lanes 4–6). Lanes 1 and 4, control embryo; lanes 2 and 5, control extraembryonic membrane; lanes 3 and 6, whole crude extract of a homozygous mutant. Note the absence of KIF5B band in lane 3, where total protein was applied of an amount approximately three times higher than in the control lanes. (F) The survival curve. Embryos were produced by heterozygous intercrosses and genotyped by PCR. Percentages of each genotype in all examined living embryos at each developmental stage were plotted together. (G) Scattered plot of the crown-rump lengths of 133 embryos at 9.5 dpc together with an assessment of turning. Note that the null mutants were unturned and significantly smaller than the controls (*, p < 0.0001 by Wilcoxon's rank sum test), while the difference between the two controls was not significant. Cell 1998 93, 1147-1158DOI: (10.1016/S0092-8674(00)81459-2)

Figure 2 Abnormal Perinuclear Clustering of Mitochondria in Cells Lacking KIF5B (A–F and H) Double immunofluorescence of untreated primary culture of 9.5 dpc extraembryonic membrane of the controls (A, C, and E) and the null mutants (B, D, F, and H). (A and B) Anti-α-tubulin indirect immunofluorescence staining. (C and D) Mitochondrial labeling with Mitotracker. (E and F) Merged image of mitochondria and microtubules. Bar, 10 μm. (G) Quantitation of the dispersion of mitochondria. Each spot represents one cell. Mito, mitochondrial area; Tub, overall cell area calculated from the tubulin image. (H) Merged image of (F) in a higher magnification. Bar, 5 μm. Note that colocalization of mitochondria with MTs is still preserved in the null mutants. (I) Electronmicrograph of perinuclear region of a null mutant extraembryonic cell, indicating a microtubule (arrows) associated with a mitochondrion (Mt). Bar, 200 nm (J–L) Double immunofluorescence study of a nocodazole-treated null-mutant extraembryonic cells. (J) Mitochondria. (K) Tubulin staining. (L) Merged image. During the treatment for 18 hr, the microtubules were depolymerized and the mitochondria dispersed throughout the cytoplasm. Bar, 10 μm. Cell 1998 93, 1147-1158DOI: (10.1016/S0092-8674(00)81459-2)

Figure 3 A Rescue Experiment of the Mitochondrial Phenotype (A) The construct of the KIF5B expression vector. (B and D) Double immunofluorescence against KIF5B (B) and mitochondria (D) in a rescued null mutant cell microinjected with this construct. Note the recovery of mitochondrial dispersion radiating from the cell center after microinjecting the plasmid. (C and E) A negative control experiment in null mutant cells microinjected with fluorescein-BSA. (C) Merged image of green fluorescence and the Nomarski image. Only the cell on the right was microinjected. (E) Mitochondrial staining of the same area as shown in (C). Note that mitochondria remained to be perinuclearly clustered. Bar, 10 μm. Cell 1998 93, 1147-1158DOI: (10.1016/S0092-8674(00)81459-2)

Figure 4 Association of KIF5B with Mitochondria (A) Pellets from differential centrifugation probed with anti-KIF5B antibody. Lane 1, heavy mitochondrial pellet (P2); lane 2, light mitochondrial pellet (P2'); lane 3, microsomal pellet (P3); lane 4, soluble fraction (S3). (B) Further purification of mitochondria by a sucrose step density gradient centrifugation starting from the postnuclear supernatant (lane 1). COX I, anti-cytochrome oxidase I staining as a mitochondrial marker. Lane 2, mitochondria-rich fraction. Lane 3, miscellaneous membrane fraction. (C) Adult liver mitochondria floatation analysis. Note the good correlation between the content of KIF5B and COX I in top five floating fractions, which is distinct from the catalase peak indicating the distribution of the peroxisomes. In the layer applied the starting material (50%), some signal was detected from the remaining population that may represent the aggregated mitochondria during the pelleting to recover the crude mitochondrial fraction. (D) Embryonic mitochondria floatation analysis. Although the mitochondrial peak was broader than (C), KIF5B was exactly copurified to it. (E) Electronmicrograph of a mitochondrial pellet prepared from the KIF5B peak fractions indicated by a bracket in (D). Bar, 200 nm. Cell 1998 93, 1147-1158DOI: (10.1016/S0092-8674(00)81459-2)

Figure 5 The Lysosomal Phenotype in the KIF5B-Deficient Cells (A–D) Lysosomes were labeled by an anti-LAMP-2 antibody for control (A and C) and null mutant (B and D) extraembryonic cells. (A and B) Perinuclear clustering of lysosomes was induced by an alkaline treatment similarly in both cells. (C and D) Lysosomal dispersion assay by a subsequent acidification of the culture medium. In this pH-rebound condition, an impaired centrifugal motility of the lysosomes was observed in the null mutant cells (D). Bar, 20 μm. Cell 1998 93, 1147-1158DOI: (10.1016/S0092-8674(00)81459-2)

Figure 6 Apparently Normal Golgi-to-ER Traffic in the KIF5B-Deficient Cells (A) The ER meshwork labeled by DiOC6(3). The cytoplasmic reticular meshwork of ER was apparently normal. Bar, 10 μm. (B–D) BFA-induced Golgi dispersion study. In each step, the cells were labeled against a medial Golgi marker, CTR433, and represented in a same scale. (B) The Golgi apparatus of untreated cells presenting no significant changes by the depletion of KIF5B. (C) Initial step of Golgi breakdown facilitated with 1 μg/ml of BFA for 10 min. Arrowhead, the Golgi tubulation suggesting the remaining motor activity. (D) Redistribution of the Golgi components into an ER-like pattern by a stronger BFA treatment of 5 μg/ml for 1 hr. Bar, 20 μm. Cell 1998 93, 1147-1158DOI: (10.1016/S0092-8674(00)81459-2)

Figure 7 Estimation of the KIF mRNA Levels by Comparative RT-PCR Amplifications Dilution chains of the cDNA prepared from the null mutant extraembryonic membranes (Mutant), the control littermate extraembryonic membranes (Control), adult heart (Heart), and adult brain (Brain) were amplified by the primers indicated. As a negative control, a sample was treated simultaneously without reverse transcriptase (w/o RTase). (A) Calibration of mRNA content in each sample with β-actin primers. (B) Three-fold more abundant transcription of kif1B gene was detected in the brain compared to that in the extraembryonic membrane and in the heart. No apparent up-regulation by the disruption of kif5B was observed here. (C) A brain conventional KHC, kif5A was up-regulated more than 10-fold by the disruption only to 1/1000 of the level in the wild-type adult brain. (D) Another brain conventional KHC, kif5C, was also up-regulated approximately ten times, only to 1/30 of its level in the adult brain. Cell 1998 93, 1147-1158DOI: (10.1016/S0092-8674(00)81459-2)